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authorKelly Rauchenberger <fefferburbia@gmail.com>2016-11-27 13:04:05 -0500
committerKelly Rauchenberger <fefferburbia@gmail.com>2016-11-27 13:04:05 -0500
commitd90a1e74c77ba67f25a812609fd49d479bc464dd (patch)
treeb6825b15157996e1a2df25b498b1dd85b888ad71 /vendor
parentfebadca7d4e0460aa78f95b53b5e36e51fd2f97d (diff)
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Removed nlohmann/json submodule
The submodule contained around 73MB of benchmarks and tests that are not necessary for inclusion in this project. Thus, the submodule has been removed, and the 2.0.7 release of nlohmann/json has been added to the repository.
Diffstat (limited to 'vendor')
m---------vendor/json0
-rw-r--r--vendor/json/json.hpp10794
2 files changed, 10794 insertions, 0 deletions
diff --git a/vendor/json b/vendor/json deleted file mode 160000
Subproject 507322e6f2f63d028c68b2a666aefe902b77f66
diff --git a/vendor/json/json.hpp b/vendor/json/json.hpp new file mode 100644 index 0000000..4447412 --- /dev/null +++ b/vendor/json/json.hpp
@@ -0,0 +1,10794 @@
1/*
2 __ _____ _____ _____
3 __| | __| | | | JSON for Modern C++
4| | |__ | | | | | | version 2.0.7
5|_____|_____|_____|_|___| https://github.com/nlohmann/json
6
7Licensed under the MIT License <http://opensource.org/licenses/MIT>.
8Copyright (c) 2013-2016 Niels Lohmann <http://nlohmann.me>.
9
10Permission is hereby granted, free of charge, to any person obtaining a copy
11of this software and associated documentation files (the "Software"), to deal
12in the Software without restriction, including without limitation the rights
13to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
14copies of the Software, and to permit persons to whom the Software is
15furnished to do so, subject to the following conditions:
16
17The above copyright notice and this permission notice shall be included in all
18copies or substantial portions of the Software.
19
20THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
21IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
22FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
23AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
24LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
25OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
26SOFTWARE.
27*/
28
29#ifndef NLOHMANN_JSON_HPP
30#define NLOHMANN_JSON_HPP
31
32#include <algorithm>
33#include <array>
34#include <cassert>
35#include <cctype>
36#include <ciso646>
37#include <cmath>
38#include <cstddef>
39#include <cstdint>
40#include <cstdlib>
41#include <cstring>
42#include <functional>
43#include <initializer_list>
44#include <iomanip>
45#include <iostream>
46#include <iterator>
47#include <limits>
48#include <locale>
49#include <map>
50#include <memory>
51#include <numeric>
52#include <sstream>
53#include <stdexcept>
54#include <string>
55#include <type_traits>
56#include <utility>
57#include <vector>
58
59// exclude unsupported compilers
60#if defined(__clang__)
61 #define CLANG_VERSION (__clang_major__ * 10000 + __clang_minor__ * 100 + __clang_patchlevel__)
62 #if CLANG_VERSION < 30400
63 #error "unsupported Clang version - see https://github.com/nlohmann/json#supported-compilers"
64 #endif
65#elif defined(__GNUC__)
66 #define GCC_VERSION (__GNUC__ * 10000 + __GNUC_MINOR__ * 100 + __GNUC_PATCHLEVEL__)
67 #if GCC_VERSION < 40900
68 #error "unsupported GCC version - see https://github.com/nlohmann/json#supported-compilers"
69 #endif
70#endif
71
72// disable float-equal warnings on GCC/clang
73#if defined(__clang__) || defined(__GNUC__) || defined(__GNUG__)
74 #pragma GCC diagnostic push
75 #pragma GCC diagnostic ignored "-Wfloat-equal"
76#endif
77
78// allow for portable deprecation warnings
79#if defined(__clang__) || defined(__GNUC__) || defined(__GNUG__)
80 #define JSON_DEPRECATED __attribute__((deprecated))
81#elif defined(_MSC_VER)
82 #define JSON_DEPRECATED __declspec(deprecated)
83#else
84 #define JSON_DEPRECATED
85#endif
86
87/*!
88@brief namespace for Niels Lohmann
89@see https://github.com/nlohmann
90@since version 1.0.0
91*/
92namespace nlohmann
93{
94
95
96/*!
97@brief unnamed namespace with internal helper functions
98@since version 1.0.0
99*/
100namespace
101{
102/*!
103@brief Helper to determine whether there's a key_type for T.
104
105Thus helper is used to tell associative containers apart from other containers
106such as sequence containers. For instance, `std::map` passes the test as it
107contains a `mapped_type`, whereas `std::vector` fails the test.
108
109@sa http://stackoverflow.com/a/7728728/266378
110@since version 1.0.0, overworked in version 2.0.6
111*/
112template<typename T>
113struct has_mapped_type
114{
115 private:
116 template <typename U, typename = typename U::mapped_type>
117 static int detect(U&&);
118
119 static void detect(...);
120 public:
121 static constexpr bool value =
122 std::is_integral<decltype(detect(std::declval<T>()))>::value;
123};
124
125/*!
126@brief helper class to create locales with decimal point
127
128This struct is used a default locale during the JSON serialization. JSON
129requires the decimal point to be `.`, so this function overloads the
130`do_decimal_point()` function to return `.`. This function is called by
131float-to-string conversions to retrieve the decimal separator between integer
132and fractional parts.
133
134@sa https://github.com/nlohmann/json/issues/51#issuecomment-86869315
135@since version 2.0.0
136*/
137struct DecimalSeparator : std::numpunct<char>
138{
139 char do_decimal_point() const
140 {
141 return '.';
142 }
143};
144
145}
146
147/*!
148@brief a class to store JSON values
149
150@tparam ObjectType type for JSON objects (`std::map` by default; will be used
151in @ref object_t)
152@tparam ArrayType type for JSON arrays (`std::vector` by default; will be used
153in @ref array_t)
154@tparam StringType type for JSON strings and object keys (`std::string` by
155default; will be used in @ref string_t)
156@tparam BooleanType type for JSON booleans (`bool` by default; will be used
157in @ref boolean_t)
158@tparam NumberIntegerType type for JSON integer numbers (`int64_t` by
159default; will be used in @ref number_integer_t)
160@tparam NumberUnsignedType type for JSON unsigned integer numbers (@c
161`uint64_t` by default; will be used in @ref number_unsigned_t)
162@tparam NumberFloatType type for JSON floating-point numbers (`double` by
163default; will be used in @ref number_float_t)
164@tparam AllocatorType type of the allocator to use (`std::allocator` by
165default)
166
167@requirement The class satisfies the following concept requirements:
168- Basic
169 - [DefaultConstructible](http://en.cppreference.com/w/cpp/concept/DefaultConstructible):
170 JSON values can be default constructed. The result will be a JSON null value.
171 - [MoveConstructible](http://en.cppreference.com/w/cpp/concept/MoveConstructible):
172 A JSON value can be constructed from an rvalue argument.
173 - [CopyConstructible](http://en.cppreference.com/w/cpp/concept/CopyConstructible):
174 A JSON value can be copy-constructed from an lvalue expression.
175 - [MoveAssignable](http://en.cppreference.com/w/cpp/concept/MoveAssignable):
176 A JSON value van be assigned from an rvalue argument.
177 - [CopyAssignable](http://en.cppreference.com/w/cpp/concept/CopyAssignable):
178 A JSON value can be copy-assigned from an lvalue expression.
179 - [Destructible](http://en.cppreference.com/w/cpp/concept/Destructible):
180 JSON values can be destructed.
181- Layout
182 - [StandardLayoutType](http://en.cppreference.com/w/cpp/concept/StandardLayoutType):
183 JSON values have
184 [standard layout](http://en.cppreference.com/w/cpp/language/data_members#Standard_layout):
185 All non-static data members are private and standard layout types, the class
186 has no virtual functions or (virtual) base classes.
187- Library-wide
188 - [EqualityComparable](http://en.cppreference.com/w/cpp/concept/EqualityComparable):
189 JSON values can be compared with `==`, see @ref
190 operator==(const_reference,const_reference).
191 - [LessThanComparable](http://en.cppreference.com/w/cpp/concept/LessThanComparable):
192 JSON values can be compared with `<`, see @ref
193 operator<(const_reference,const_reference).
194 - [Swappable](http://en.cppreference.com/w/cpp/concept/Swappable):
195 Any JSON lvalue or rvalue of can be swapped with any lvalue or rvalue of
196 other compatible types, using unqualified function call @ref swap().
197 - [NullablePointer](http://en.cppreference.com/w/cpp/concept/NullablePointer):
198 JSON values can be compared against `std::nullptr_t` objects which are used
199 to model the `null` value.
200- Container
201 - [Container](http://en.cppreference.com/w/cpp/concept/Container):
202 JSON values can be used like STL containers and provide iterator access.
203 - [ReversibleContainer](http://en.cppreference.com/w/cpp/concept/ReversibleContainer);
204 JSON values can be used like STL containers and provide reverse iterator
205 access.
206
207@invariant The member variables @a m_value and @a m_type have the following
208relationship:
209- If `m_type == value_t::object`, then `m_value.object != nullptr`.
210- If `m_type == value_t::array`, then `m_value.array != nullptr`.
211- If `m_type == value_t::string`, then `m_value.string != nullptr`.
212The invariants are checked by member function assert_invariant().
213
214@internal
215@note ObjectType trick from http://stackoverflow.com/a/9860911
216@endinternal
217
218@see [RFC 7159: The JavaScript Object Notation (JSON) Data Interchange
219Format](http://rfc7159.net/rfc7159)
220
221@since version 1.0.0
222
223@nosubgrouping
224*/
225template <
226 template<typename U, typename V, typename... Args> class ObjectType = std::map,
227 template<typename U, typename... Args> class ArrayType = std::vector,
228 class StringType = std::string,
229 class BooleanType = bool,
230 class NumberIntegerType = std::int64_t,
231 class NumberUnsignedType = std::uint64_t,
232 class NumberFloatType = double,
233 template<typename U> class AllocatorType = std::allocator
234 >
235class basic_json
236{
237 private:
238 /// workaround type for MSVC
239 using basic_json_t = basic_json<ObjectType, ArrayType, StringType,
240 BooleanType, NumberIntegerType, NumberUnsignedType, NumberFloatType,
241 AllocatorType>;
242
243 public:
244 // forward declarations
245 template<typename Base> class json_reverse_iterator;
246 class json_pointer;
247
248 /////////////////////
249 // container types //
250 /////////////////////
251
252 /// @name container types
253 /// The canonic container types to use @ref basic_json like any other STL
254 /// container.
255 /// @{
256
257 /// the type of elements in a basic_json container
258 using value_type = basic_json;
259
260 /// the type of an element reference
261 using reference = value_type&;
262 /// the type of an element const reference
263 using const_reference = const value_type&;
264
265 /// a type to represent differences between iterators
266 using difference_type = std::ptrdiff_t;
267 /// a type to represent container sizes
268 using size_type = std::size_t;
269
270 /// the allocator type
271 using allocator_type = AllocatorType<basic_json>;
272
273 /// the type of an element pointer
274 using pointer = typename std::allocator_traits<allocator_type>::pointer;
275 /// the type of an element const pointer
276 using const_pointer = typename std::allocator_traits<allocator_type>::const_pointer;
277
278 /// an iterator for a basic_json container
279 class iterator;
280 /// a const iterator for a basic_json container
281 class const_iterator;
282 /// a reverse iterator for a basic_json container
283 using reverse_iterator = json_reverse_iterator<typename basic_json::iterator>;
284 /// a const reverse iterator for a basic_json container
285 using const_reverse_iterator = json_reverse_iterator<typename basic_json::const_iterator>;
286
287 /// @}
288
289
290 /*!
291 @brief returns the allocator associated with the container
292 */
293 static allocator_type get_allocator()
294 {
295 return allocator_type();
296 }
297
298
299 ///////////////////////////
300 // JSON value data types //
301 ///////////////////////////
302
303 /// @name JSON value data types
304 /// The data types to store a JSON value. These types are derived from
305 /// the template arguments passed to class @ref basic_json.
306 /// @{
307
308 /*!
309 @brief a type for an object
310
311 [RFC 7159](http://rfc7159.net/rfc7159) describes JSON objects as follows:
312 > An object is an unordered collection of zero or more name/value pairs,
313 > where a name is a string and a value is a string, number, boolean, null,
314 > object, or array.
315
316 To store objects in C++, a type is defined by the template parameters
317 described below.
318
319 @tparam ObjectType the container to store objects (e.g., `std::map` or
320 `std::unordered_map`)
321 @tparam StringType the type of the keys or names (e.g., `std::string`).
322 The comparison function `std::less<StringType>` is used to order elements
323 inside the container.
324 @tparam AllocatorType the allocator to use for objects (e.g.,
325 `std::allocator`)
326
327 #### Default type
328
329 With the default values for @a ObjectType (`std::map`), @a StringType
330 (`std::string`), and @a AllocatorType (`std::allocator`), the default
331 value for @a object_t is:
332
333 @code {.cpp}
334 std::map<
335 std::string, // key_type
336 basic_json, // value_type
337 std::less<std::string>, // key_compare
338 std::allocator<std::pair<const std::string, basic_json>> // allocator_type
339 >
340 @endcode
341
342 #### Behavior
343
344 The choice of @a object_t influences the behavior of the JSON class. With
345 the default type, objects have the following behavior:
346
347 - When all names are unique, objects will be interoperable in the sense
348 that all software implementations receiving that object will agree on
349 the name-value mappings.
350 - When the names within an object are not unique, later stored name/value
351 pairs overwrite previously stored name/value pairs, leaving the used
352 names unique. For instance, `{"key": 1}` and `{"key": 2, "key": 1}` will
353 be treated as equal and both stored as `{"key": 1}`.
354 - Internally, name/value pairs are stored in lexicographical order of the
355 names. Objects will also be serialized (see @ref dump) in this order.
356 For instance, `{"b": 1, "a": 2}` and `{"a": 2, "b": 1}` will be stored
357 and serialized as `{"a": 2, "b": 1}`.
358 - When comparing objects, the order of the name/value pairs is irrelevant.
359 This makes objects interoperable in the sense that they will not be
360 affected by these differences. For instance, `{"b": 1, "a": 2}` and
361 `{"a": 2, "b": 1}` will be treated as equal.
362
363 #### Limits
364
365 [RFC 7159](http://rfc7159.net/rfc7159) specifies:
366 > An implementation may set limits on the maximum depth of nesting.
367
368 In this class, the object's limit of nesting is not constraint explicitly.
369 However, a maximum depth of nesting may be introduced by the compiler or
370 runtime environment. A theoretical limit can be queried by calling the
371 @ref max_size function of a JSON object.
372
373 #### Storage
374
375 Objects are stored as pointers in a @ref basic_json type. That is, for any
376 access to object values, a pointer of type `object_t*` must be
377 dereferenced.
378
379 @sa @ref array_t -- type for an array value
380
381 @since version 1.0.0
382
383 @note The order name/value pairs are added to the object is *not*
384 preserved by the library. Therefore, iterating an object may return
385 name/value pairs in a different order than they were originally stored. In
386 fact, keys will be traversed in alphabetical order as `std::map` with
387 `std::less` is used by default. Please note this behavior conforms to [RFC
388 7159](http://rfc7159.net/rfc7159), because any order implements the
389 specified "unordered" nature of JSON objects.
390 */
391 using object_t = ObjectType<StringType,
392 basic_json,
393 std::less<StringType>,
394 AllocatorType<std::pair<const StringType,
395 basic_json>>>;
396
397 /*!
398 @brief a type for an array
399
400 [RFC 7159](http://rfc7159.net/rfc7159) describes JSON arrays as follows:
401 > An array is an ordered sequence of zero or more values.
402
403 To store objects in C++, a type is defined by the template parameters
404 explained below.
405
406 @tparam ArrayType container type to store arrays (e.g., `std::vector` or
407 `std::list`)
408 @tparam AllocatorType allocator to use for arrays (e.g., `std::allocator`)
409
410 #### Default type
411
412 With the default values for @a ArrayType (`std::vector`) and @a
413 AllocatorType (`std::allocator`), the default value for @a array_t is:
414
415 @code {.cpp}
416 std::vector<
417 basic_json, // value_type
418 std::allocator<basic_json> // allocator_type
419 >
420 @endcode
421
422 #### Limits
423
424 [RFC 7159](http://rfc7159.net/rfc7159) specifies:
425 > An implementation may set limits on the maximum depth of nesting.
426
427 In this class, the array's limit of nesting is not constraint explicitly.
428 However, a maximum depth of nesting may be introduced by the compiler or
429 runtime environment. A theoretical limit can be queried by calling the
430 @ref max_size function of a JSON array.
431
432 #### Storage
433
434 Arrays are stored as pointers in a @ref basic_json type. That is, for any
435 access to array values, a pointer of type `array_t*` must be dereferenced.
436
437 @sa @ref object_t -- type for an object value
438
439 @since version 1.0.0
440 */
441 using array_t = ArrayType<basic_json, AllocatorType<basic_json>>;
442
443 /*!
444 @brief a type for a string
445
446 [RFC 7159](http://rfc7159.net/rfc7159) describes JSON strings as follows:
447 > A string is a sequence of zero or more Unicode characters.
448
449 To store objects in C++, a type is defined by the template parameter
450 described below. Unicode values are split by the JSON class into
451 byte-sized characters during deserialization.
452
453 @tparam StringType the container to store strings (e.g., `std::string`).
454 Note this container is used for keys/names in objects, see @ref object_t.
455
456 #### Default type
457
458 With the default values for @a StringType (`std::string`), the default
459 value for @a string_t is:
460
461 @code {.cpp}
462 std::string
463 @endcode
464
465 #### String comparison
466
467 [RFC 7159](http://rfc7159.net/rfc7159) states:
468 > Software implementations are typically required to test names of object
469 > members for equality. Implementations that transform the textual
470 > representation into sequences of Unicode code units and then perform the
471 > comparison numerically, code unit by code unit, are interoperable in the
472 > sense that implementations will agree in all cases on equality or
473 > inequality of two strings. For example, implementations that compare
474 > strings with escaped characters unconverted may incorrectly find that
475 > `"a\\b"` and `"a\u005Cb"` are not equal.
476
477 This implementation is interoperable as it does compare strings code unit
478 by code unit.
479
480 #### Storage
481
482 String values are stored as pointers in a @ref basic_json type. That is,
483 for any access to string values, a pointer of type `string_t*` must be
484 dereferenced.
485
486 @since version 1.0.0
487 */
488 using string_t = StringType;
489
490 /*!
491 @brief a type for a boolean
492
493 [RFC 7159](http://rfc7159.net/rfc7159) implicitly describes a boolean as a
494 type which differentiates the two literals `true` and `false`.
495
496 To store objects in C++, a type is defined by the template parameter @a
497 BooleanType which chooses the type to use.
498
499 #### Default type
500
501 With the default values for @a BooleanType (`bool`), the default value for
502 @a boolean_t is:
503
504 @code {.cpp}
505 bool
506 @endcode
507
508 #### Storage
509
510 Boolean values are stored directly inside a @ref basic_json type.
511
512 @since version 1.0.0
513 */
514 using boolean_t = BooleanType;
515
516 /*!
517 @brief a type for a number (integer)
518
519 [RFC 7159](http://rfc7159.net/rfc7159) describes numbers as follows:
520 > The representation of numbers is similar to that used in most
521 > programming languages. A number is represented in base 10 using decimal
522 > digits. It contains an integer component that may be prefixed with an
523 > optional minus sign, which may be followed by a fraction part and/or an
524 > exponent part. Leading zeros are not allowed. (...) Numeric values that
525 > cannot be represented in the grammar below (such as Infinity and NaN)
526 > are not permitted.
527
528 This description includes both integer and floating-point numbers.
529 However, C++ allows more precise storage if it is known whether the number
530 is a signed integer, an unsigned integer or a floating-point number.
531 Therefore, three different types, @ref number_integer_t, @ref
532 number_unsigned_t and @ref number_float_t are used.
533
534 To store integer numbers in C++, a type is defined by the template
535 parameter @a NumberIntegerType which chooses the type to use.
536
537 #### Default type
538
539 With the default values for @a NumberIntegerType (`int64_t`), the default
540 value for @a number_integer_t is:
541
542 @code {.cpp}
543 int64_t
544 @endcode
545
546 #### Default behavior
547
548 - The restrictions about leading zeros is not enforced in C++. Instead,
549 leading zeros in integer literals lead to an interpretation as octal
550 number. Internally, the value will be stored as decimal number. For
551 instance, the C++ integer literal `010` will be serialized to `8`.
552 During deserialization, leading zeros yield an error.
553 - Not-a-number (NaN) values will be serialized to `null`.
554
555 #### Limits
556
557 [RFC 7159](http://rfc7159.net/rfc7159) specifies:
558 > An implementation may set limits on the range and precision of numbers.
559
560 When the default type is used, the maximal integer number that can be
561 stored is `9223372036854775807` (INT64_MAX) and the minimal integer number
562 that can be stored is `-9223372036854775808` (INT64_MIN). Integer numbers
563 that are out of range will yield over/underflow when used in a
564 constructor. During deserialization, too large or small integer numbers
565 will be automatically be stored as @ref number_unsigned_t or @ref
566 number_float_t.
567
568 [RFC 7159](http://rfc7159.net/rfc7159) further states:
569 > Note that when such software is used, numbers that are integers and are
570 > in the range \f$[-2^{53}+1, 2^{53}-1]\f$ are interoperable in the sense
571 > that implementations will agree exactly on their numeric values.
572
573 As this range is a subrange of the exactly supported range [INT64_MIN,
574 INT64_MAX], this class's integer type is interoperable.
575
576 #### Storage
577
578 Integer number values are stored directly inside a @ref basic_json type.
579
580 @sa @ref number_float_t -- type for number values (floating-point)
581
582 @sa @ref number_unsigned_t -- type for number values (unsigned integer)
583
584 @since version 1.0.0
585 */
586 using number_integer_t = NumberIntegerType;
587
588 /*!
589 @brief a type for a number (unsigned)
590
591 [RFC 7159](http://rfc7159.net/rfc7159) describes numbers as follows:
592 > The representation of numbers is similar to that used in most
593 > programming languages. A number is represented in base 10 using decimal
594 > digits. It contains an integer component that may be prefixed with an
595 > optional minus sign, which may be followed by a fraction part and/or an
596 > exponent part. Leading zeros are not allowed. (...) Numeric values that
597 > cannot be represented in the grammar below (such as Infinity and NaN)
598 > are not permitted.
599
600 This description includes both integer and floating-point numbers.
601 However, C++ allows more precise storage if it is known whether the number
602 is a signed integer, an unsigned integer or a floating-point number.
603 Therefore, three different types, @ref number_integer_t, @ref
604 number_unsigned_t and @ref number_float_t are used.
605
606 To store unsigned integer numbers in C++, a type is defined by the
607 template parameter @a NumberUnsignedType which chooses the type to use.
608
609 #### Default type
610
611 With the default values for @a NumberUnsignedType (`uint64_t`), the
612 default value for @a number_unsigned_t is:
613
614 @code {.cpp}
615 uint64_t
616 @endcode
617
618 #### Default behavior
619
620 - The restrictions about leading zeros is not enforced in C++. Instead,
621 leading zeros in integer literals lead to an interpretation as octal
622 number. Internally, the value will be stored as decimal number. For
623 instance, the C++ integer literal `010` will be serialized to `8`.
624 During deserialization, leading zeros yield an error.
625 - Not-a-number (NaN) values will be serialized to `null`.
626
627 #### Limits
628
629 [RFC 7159](http://rfc7159.net/rfc7159) specifies:
630 > An implementation may set limits on the range and precision of numbers.
631
632 When the default type is used, the maximal integer number that can be
633 stored is `18446744073709551615` (UINT64_MAX) and the minimal integer
634 number that can be stored is `0`. Integer numbers that are out of range
635 will yield over/underflow when used in a constructor. During
636 deserialization, too large or small integer numbers will be automatically
637 be stored as @ref number_integer_t or @ref number_float_t.
638
639 [RFC 7159](http://rfc7159.net/rfc7159) further states:
640 > Note that when such software is used, numbers that are integers and are
641 > in the range \f$[-2^{53}+1, 2^{53}-1]\f$ are interoperable in the sense
642 > that implementations will agree exactly on their numeric values.
643
644 As this range is a subrange (when considered in conjunction with the
645 number_integer_t type) of the exactly supported range [0, UINT64_MAX],
646 this class's integer type is interoperable.
647
648 #### Storage
649
650 Integer number values are stored directly inside a @ref basic_json type.
651
652 @sa @ref number_float_t -- type for number values (floating-point)
653 @sa @ref number_integer_t -- type for number values (integer)
654
655 @since version 2.0.0
656 */
657 using number_unsigned_t = NumberUnsignedType;
658
659 /*!
660 @brief a type for a number (floating-point)
661
662 [RFC 7159](http://rfc7159.net/rfc7159) describes numbers as follows:
663 > The representation of numbers is similar to that used in most
664 > programming languages. A number is represented in base 10 using decimal
665 > digits. It contains an integer component that may be prefixed with an
666 > optional minus sign, which may be followed by a fraction part and/or an
667 > exponent part. Leading zeros are not allowed. (...) Numeric values that
668 > cannot be represented in the grammar below (such as Infinity and NaN)
669 > are not permitted.
670
671 This description includes both integer and floating-point numbers.
672 However, C++ allows more precise storage if it is known whether the number
673 is a signed integer, an unsigned integer or a floating-point number.
674 Therefore, three different types, @ref number_integer_t, @ref
675 number_unsigned_t and @ref number_float_t are used.
676
677 To store floating-point numbers in C++, a type is defined by the template
678 parameter @a NumberFloatType which chooses the type to use.
679
680 #### Default type
681
682 With the default values for @a NumberFloatType (`double`), the default
683 value for @a number_float_t is:
684
685 @code {.cpp}
686 double
687 @endcode
688
689 #### Default behavior
690
691 - The restrictions about leading zeros is not enforced in C++. Instead,
692 leading zeros in floating-point literals will be ignored. Internally,
693 the value will be stored as decimal number. For instance, the C++
694 floating-point literal `01.2` will be serialized to `1.2`. During
695 deserialization, leading zeros yield an error.
696 - Not-a-number (NaN) values will be serialized to `null`.
697
698 #### Limits
699
700 [RFC 7159](http://rfc7159.net/rfc7159) states:
701 > This specification allows implementations to set limits on the range and
702 > precision of numbers accepted. Since software that implements IEEE
703 > 754-2008 binary64 (double precision) numbers is generally available and
704 > widely used, good interoperability can be achieved by implementations
705 > that expect no more precision or range than these provide, in the sense
706 > that implementations will approximate JSON numbers within the expected
707 > precision.
708
709 This implementation does exactly follow this approach, as it uses double
710 precision floating-point numbers. Note values smaller than
711 `-1.79769313486232e+308` and values greater than `1.79769313486232e+308`
712 will be stored as NaN internally and be serialized to `null`.
713
714 #### Storage
715
716 Floating-point number values are stored directly inside a @ref basic_json
717 type.
718
719 @sa @ref number_integer_t -- type for number values (integer)
720
721 @sa @ref number_unsigned_t -- type for number values (unsigned integer)
722
723 @since version 1.0.0
724 */
725 using number_float_t = NumberFloatType;
726
727 /// @}
728
729
730 ///////////////////////////
731 // JSON type enumeration //
732 ///////////////////////////
733
734 /*!
735 @brief the JSON type enumeration
736
737 This enumeration collects the different JSON types. It is internally used
738 to distinguish the stored values, and the functions @ref is_null(), @ref
739 is_object(), @ref is_array(), @ref is_string(), @ref is_boolean(), @ref
740 is_number() (with @ref is_number_integer(), @ref is_number_unsigned(), and
741 @ref is_number_float()), @ref is_discarded(), @ref is_primitive(), and
742 @ref is_structured() rely on it.
743
744 @note There are three enumeration entries (number_integer,
745 number_unsigned, and number_float), because the library distinguishes
746 these three types for numbers: @ref number_unsigned_t is used for unsigned
747 integers, @ref number_integer_t is used for signed integers, and @ref
748 number_float_t is used for floating-point numbers or to approximate
749 integers which do not fit in the limits of their respective type.
750
751 @sa @ref basic_json(const value_t value_type) -- create a JSON value with
752 the default value for a given type
753
754 @since version 1.0.0
755 */
756 enum class value_t : uint8_t
757 {
758 null, ///< null value
759 object, ///< object (unordered set of name/value pairs)
760 array, ///< array (ordered collection of values)
761 string, ///< string value
762 boolean, ///< boolean value
763 number_integer, ///< number value (signed integer)
764 number_unsigned, ///< number value (unsigned integer)
765 number_float, ///< number value (floating-point)
766 discarded ///< discarded by the the parser callback function
767 };
768
769
770 private:
771
772 /// helper for exception-safe object creation
773 template<typename T, typename... Args>
774 static T* create(Args&& ... args)
775 {
776 AllocatorType<T> alloc;
777 auto deleter = [&](T * object)
778 {
779 alloc.deallocate(object, 1);
780 };
781 std::unique_ptr<T, decltype(deleter)> object(alloc.allocate(1), deleter);
782 alloc.construct(object.get(), std::forward<Args>(args)...);
783 assert(object.get() != nullptr);
784 return object.release();
785 }
786
787 ////////////////////////
788 // JSON value storage //
789 ////////////////////////
790
791 /*!
792 @brief a JSON value
793
794 The actual storage for a JSON value of the @ref basic_json class. This
795 union combines the different storage types for the JSON value types
796 defined in @ref value_t.
797
798 JSON type | value_t type | used type
799 --------- | --------------- | ------------------------
800 object | object | pointer to @ref object_t
801 array | array | pointer to @ref array_t
802 string | string | pointer to @ref string_t
803 boolean | boolean | @ref boolean_t
804 number | number_integer | @ref number_integer_t
805 number | number_unsigned | @ref number_unsigned_t
806 number | number_float | @ref number_float_t
807 null | null | *no value is stored*
808
809 @note Variable-length types (objects, arrays, and strings) are stored as
810 pointers. The size of the union should not exceed 64 bits if the default
811 value types are used.
812
813 @since version 1.0.0
814 */
815 union json_value
816 {
817 /// object (stored with pointer to save storage)
818 object_t* object;
819 /// array (stored with pointer to save storage)
820 array_t* array;
821 /// string (stored with pointer to save storage)
822 string_t* string;
823 /// boolean
824 boolean_t boolean;
825 /// number (integer)
826 number_integer_t number_integer;
827 /// number (unsigned integer)
828 number_unsigned_t number_unsigned;
829 /// number (floating-point)
830 number_float_t number_float;
831
832 /// default constructor (for null values)
833 json_value() = default;
834 /// constructor for booleans
835 json_value(boolean_t v) noexcept : boolean(v) {}
836 /// constructor for numbers (integer)
837 json_value(number_integer_t v) noexcept : number_integer(v) {}
838 /// constructor for numbers (unsigned)
839 json_value(number_unsigned_t v) noexcept : number_unsigned(v) {}
840 /// constructor for numbers (floating-point)
841 json_value(number_float_t v) noexcept : number_float(v) {}
842 /// constructor for empty values of a given type
843 json_value(value_t t)
844 {
845 switch (t)
846 {
847 case value_t::object:
848 {
849 object = create<object_t>();
850 break;
851 }
852
853 case value_t::array:
854 {
855 array = create<array_t>();
856 break;
857 }
858
859 case value_t::string:
860 {
861 string = create<string_t>("");
862 break;
863 }
864
865 case value_t::boolean:
866 {
867 boolean = boolean_t(false);
868 break;
869 }
870
871 case value_t::number_integer:
872 {
873 number_integer = number_integer_t(0);
874 break;
875 }
876
877 case value_t::number_unsigned:
878 {
879 number_unsigned = number_unsigned_t(0);
880 break;
881 }
882
883 case value_t::number_float:
884 {
885 number_float = number_float_t(0.0);
886 break;
887 }
888
889 default:
890 {
891 break;
892 }
893 }
894 }
895
896 /// constructor for strings
897 json_value(const string_t& value)
898 {
899 string = create<string_t>(value);
900 }
901
902 /// constructor for objects
903 json_value(const object_t& value)
904 {
905 object = create<object_t>(value);
906 }
907
908 /// constructor for arrays
909 json_value(const array_t& value)
910 {
911 array = create<array_t>(value);
912 }
913 };
914
915 /*!
916 @brief checks the class invariants
917
918 This function asserts the class invariants. It needs to be called at the
919 end of every constructor to make sure that created objects respect the
920 invariant. Furthermore, it has to be called each time the type of a JSON
921 value is changed, because the invariant expresses a relationship between
922 @a m_type and @a m_value.
923 */
924 void assert_invariant() const
925 {
926 assert(m_type != value_t::object or m_value.object != nullptr);
927 assert(m_type != value_t::array or m_value.array != nullptr);
928 assert(m_type != value_t::string or m_value.string != nullptr);
929 }
930
931 public:
932 //////////////////////////
933 // JSON parser callback //
934 //////////////////////////
935
936 /*!
937 @brief JSON callback events
938
939 This enumeration lists the parser events that can trigger calling a
940 callback function of type @ref parser_callback_t during parsing.
941
942 @image html callback_events.png "Example when certain parse events are triggered"
943
944 @since version 1.0.0
945 */
946 enum class parse_event_t : uint8_t
947 {
948 /// the parser read `{` and started to process a JSON object
949 object_start,
950 /// the parser read `}` and finished processing a JSON object
951 object_end,
952 /// the parser read `[` and started to process a JSON array
953 array_start,
954 /// the parser read `]` and finished processing a JSON array
955 array_end,
956 /// the parser read a key of a value in an object
957 key,
958 /// the parser finished reading a JSON value
959 value
960 };
961
962 /*!
963 @brief per-element parser callback type
964
965 With a parser callback function, the result of parsing a JSON text can be
966 influenced. When passed to @ref parse(std::istream&, const
967 parser_callback_t) or @ref parse(const char*, const parser_callback_t),
968 it is called on certain events (passed as @ref parse_event_t via parameter
969 @a event) with a set recursion depth @a depth and context JSON value
970 @a parsed. The return value of the callback function is a boolean
971 indicating whether the element that emitted the callback shall be kept or
972 not.
973
974 We distinguish six scenarios (determined by the event type) in which the
975 callback function can be called. The following table describes the values
976 of the parameters @a depth, @a event, and @a parsed.
977
978 parameter @a event | description | parameter @a depth | parameter @a parsed
979 ------------------ | ----------- | ------------------ | -------------------
980 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
981 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
982 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
983 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
984 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
985 parse_event_t::value | the parser finished reading a JSON value | depth of the value | the parsed JSON value
986
987 @image html callback_events.png "Example when certain parse events are triggered"
988
989 Discarding a value (i.e., returning `false`) has different effects
990 depending on the context in which function was called:
991
992 - Discarded values in structured types are skipped. That is, the parser
993 will behave as if the discarded value was never read.
994 - In case a value outside a structured type is skipped, it is replaced
995 with `null`. This case happens if the top-level element is skipped.
996
997 @param[in] depth the depth of the recursion during parsing
998
999 @param[in] event an event of type parse_event_t indicating the context in
1000 the callback function has been called
1001
1002 @param[in,out] parsed the current intermediate parse result; note that
1003 writing to this value has no effect for parse_event_t::key events
1004
1005 @return Whether the JSON value which called the function during parsing
1006 should be kept (`true`) or not (`false`). In the latter case, it is either
1007 skipped completely or replaced by an empty discarded object.
1008
1009 @sa @ref parse(std::istream&, parser_callback_t) or
1010 @ref parse(const char*, parser_callback_t) for examples
1011
1012 @since version 1.0.0
1013 */
1014 using parser_callback_t = std::function<bool(int depth,
1015 parse_event_t event,
1016 basic_json& parsed)>;
1017
1018
1019 //////////////////
1020 // constructors //
1021 //////////////////
1022
1023 /// @name constructors and destructors
1024 /// Constructors of class @ref basic_json, copy/move constructor, copy
1025 /// assignment, static functions creating objects, and the destructor.
1026 /// @{
1027
1028 /*!
1029 @brief create an empty value with a given type
1030
1031 Create an empty JSON value with a given type. The value will be default
1032 initialized with an empty value which depends on the type:
1033
1034 Value type | initial value
1035 ----------- | -------------
1036 null | `null`
1037 boolean | `false`
1038 string | `""`
1039 number | `0`
1040 object | `{}`
1041 array | `[]`
1042
1043 @param[in] value_type the type of the value to create
1044
1045 @complexity Constant.
1046
1047 @throw std::bad_alloc if allocation for object, array, or string value
1048 fails
1049
1050 @liveexample{The following code shows the constructor for different @ref
1051 value_t values,basic_json__value_t}
1052
1053 @sa @ref basic_json(std::nullptr_t) -- create a `null` value
1054 @sa @ref basic_json(boolean_t value) -- create a boolean value
1055 @sa @ref basic_json(const string_t&) -- create a string value
1056 @sa @ref basic_json(const object_t&) -- create a object value
1057 @sa @ref basic_json(const array_t&) -- create a array value
1058 @sa @ref basic_json(const number_float_t) -- create a number
1059 (floating-point) value
1060 @sa @ref basic_json(const number_integer_t) -- create a number (integer)
1061 value
1062 @sa @ref basic_json(const number_unsigned_t) -- create a number (unsigned)
1063 value
1064
1065 @since version 1.0.0
1066 */
1067 basic_json(const value_t value_type)
1068 : m_type(value_type), m_value(value_type)
1069 {
1070 assert_invariant();
1071 }
1072
1073 /*!
1074 @brief create a null object
1075
1076 Create a `null` JSON value. It either takes a null pointer as parameter
1077 (explicitly creating `null`) or no parameter (implicitly creating `null`).
1078 The passed null pointer itself is not read -- it is only used to choose
1079 the right constructor.
1080
1081 @complexity Constant.
1082
1083 @exceptionsafety No-throw guarantee: this constructor never throws
1084 exceptions.
1085
1086 @liveexample{The following code shows the constructor with and without a
1087 null pointer parameter.,basic_json__nullptr_t}
1088
1089 @since version 1.0.0
1090 */
1091 basic_json(std::nullptr_t = nullptr) noexcept
1092 : basic_json(value_t::null)
1093 {
1094 assert_invariant();
1095 }
1096
1097 /*!
1098 @brief create an object (explicit)
1099
1100 Create an object JSON value with a given content.
1101
1102 @param[in] val a value for the object
1103
1104 @complexity Linear in the size of the passed @a val.
1105
1106 @throw std::bad_alloc if allocation for object value fails
1107
1108 @liveexample{The following code shows the constructor with an @ref
1109 object_t parameter.,basic_json__object_t}
1110
1111 @sa @ref basic_json(const CompatibleObjectType&) -- create an object value
1112 from a compatible STL container
1113
1114 @since version 1.0.0
1115 */
1116 basic_json(const object_t& val)
1117 : m_type(value_t::object), m_value(val)
1118 {
1119 assert_invariant();
1120 }
1121
1122 /*!
1123 @brief create an object (implicit)
1124
1125 Create an object JSON value with a given content. This constructor allows
1126 any type @a CompatibleObjectType that can be used to construct values of
1127 type @ref object_t.
1128
1129 @tparam CompatibleObjectType An object type whose `key_type` and
1130 `value_type` is compatible to @ref object_t. Examples include `std::map`,
1131 `std::unordered_map`, `std::multimap`, and `std::unordered_multimap` with
1132 a `key_type` of `std::string`, and a `value_type` from which a @ref
1133 basic_json value can be constructed.
1134
1135 @param[in] val a value for the object
1136
1137 @complexity Linear in the size of the passed @a val.
1138
1139 @throw std::bad_alloc if allocation for object value fails
1140
1141 @liveexample{The following code shows the constructor with several
1142 compatible object type parameters.,basic_json__CompatibleObjectType}
1143
1144 @sa @ref basic_json(const object_t&) -- create an object value
1145
1146 @since version 1.0.0
1147 */
1148 template<class CompatibleObjectType, typename std::enable_if<
1149 std::is_constructible<typename object_t::key_type, typename CompatibleObjectType::key_type>::value and
1150 std::is_constructible<basic_json, typename CompatibleObjectType::mapped_type>::value, int>::type = 0>
1151 basic_json(const CompatibleObjectType& val)
1152 : m_type(value_t::object)
1153 {
1154 using std::begin;
1155 using std::end;
1156 m_value.object = create<object_t>(begin(val), end(val));
1157 assert_invariant();
1158 }
1159
1160 /*!
1161 @brief create an array (explicit)
1162
1163 Create an array JSON value with a given content.
1164
1165 @param[in] val a value for the array
1166
1167 @complexity Linear in the size of the passed @a val.
1168
1169 @throw std::bad_alloc if allocation for array value fails
1170
1171 @liveexample{The following code shows the constructor with an @ref array_t
1172 parameter.,basic_json__array_t}
1173
1174 @sa @ref basic_json(const CompatibleArrayType&) -- create an array value
1175 from a compatible STL containers
1176
1177 @since version 1.0.0
1178 */
1179 basic_json(const array_t& val)
1180 : m_type(value_t::array), m_value(val)
1181 {
1182 assert_invariant();
1183 }
1184
1185 /*!
1186 @brief create an array (implicit)
1187
1188 Create an array JSON value with a given content. This constructor allows
1189 any type @a CompatibleArrayType that can be used to construct values of
1190 type @ref array_t.
1191
1192 @tparam CompatibleArrayType An object type whose `value_type` is
1193 compatible to @ref array_t. Examples include `std::vector`, `std::deque`,
1194 `std::list`, `std::forward_list`, `std::array`, `std::set`,
1195 `std::unordered_set`, `std::multiset`, and `unordered_multiset` with a
1196 `value_type` from which a @ref basic_json value can be constructed.
1197
1198 @param[in] val a value for the array
1199
1200 @complexity Linear in the size of the passed @a val.
1201
1202 @throw std::bad_alloc if allocation for array value fails
1203
1204 @liveexample{The following code shows the constructor with several
1205 compatible array type parameters.,basic_json__CompatibleArrayType}
1206
1207 @sa @ref basic_json(const array_t&) -- create an array value
1208
1209 @since version 1.0.0
1210 */
1211 template<class CompatibleArrayType, typename std::enable_if<
1212 not std::is_same<CompatibleArrayType, typename basic_json_t::iterator>::value and
1213 not std::is_same<CompatibleArrayType, typename basic_json_t::const_iterator>::value and
1214 not std::is_same<CompatibleArrayType, typename basic_json_t::reverse_iterator>::value and
1215 not std::is_same<CompatibleArrayType, typename basic_json_t::const_reverse_iterator>::value and
1216 not std::is_same<CompatibleArrayType, typename array_t::iterator>::value and
1217 not std::is_same<CompatibleArrayType, typename array_t::const_iterator>::value and
1218 std::is_constructible<basic_json, typename CompatibleArrayType::value_type>::value, int>::type = 0>
1219 basic_json(const CompatibleArrayType& val)
1220 : m_type(value_t::array)
1221 {
1222 using std::begin;
1223 using std::end;
1224 m_value.array = create<array_t>(begin(val), end(val));
1225 assert_invariant();
1226 }
1227
1228 /*!
1229 @brief create a string (explicit)
1230
1231 Create an string JSON value with a given content.
1232
1233 @param[in] val a value for the string
1234
1235 @complexity Linear in the size of the passed @a val.
1236
1237 @throw std::bad_alloc if allocation for string value fails
1238
1239 @liveexample{The following code shows the constructor with an @ref
1240 string_t parameter.,basic_json__string_t}
1241
1242 @sa @ref basic_json(const typename string_t::value_type*) -- create a
1243 string value from a character pointer
1244 @sa @ref basic_json(const CompatibleStringType&) -- create a string value
1245 from a compatible string container
1246
1247 @since version 1.0.0
1248 */
1249 basic_json(const string_t& val)
1250 : m_type(value_t::string), m_value(val)
1251 {
1252 assert_invariant();
1253 }
1254
1255 /*!
1256 @brief create a string (explicit)
1257
1258 Create a string JSON value with a given content.
1259
1260 @param[in] val a literal value for the string
1261
1262 @complexity Linear in the size of the passed @a val.
1263
1264 @throw std::bad_alloc if allocation for string value fails
1265
1266 @liveexample{The following code shows the constructor with string literal
1267 parameter.,basic_json__string_t_value_type}
1268
1269 @sa @ref basic_json(const string_t&) -- create a string value
1270 @sa @ref basic_json(const CompatibleStringType&) -- create a string value
1271 from a compatible string container
1272
1273 @since version 1.0.0
1274 */
1275 basic_json(const typename string_t::value_type* val)
1276 : basic_json(string_t(val))
1277 {
1278 assert_invariant();
1279 }
1280
1281 /*!
1282 @brief create a string (implicit)
1283
1284 Create a string JSON value with a given content.
1285
1286 @param[in] val a value for the string
1287
1288 @tparam CompatibleStringType an string type which is compatible to @ref
1289 string_t, for instance `std::string`.
1290
1291 @complexity Linear in the size of the passed @a val.
1292
1293 @throw std::bad_alloc if allocation for string value fails
1294
1295 @liveexample{The following code shows the construction of a string value
1296 from a compatible type.,basic_json__CompatibleStringType}
1297
1298 @sa @ref basic_json(const string_t&) -- create a string value
1299 @sa @ref basic_json(const typename string_t::value_type*) -- create a
1300 string value from a character pointer
1301
1302 @since version 1.0.0
1303 */
1304 template<class CompatibleStringType, typename std::enable_if<
1305 std::is_constructible<string_t, CompatibleStringType>::value, int>::type = 0>
1306 basic_json(const CompatibleStringType& val)
1307 : basic_json(string_t(val))
1308 {
1309 assert_invariant();
1310 }
1311
1312 /*!
1313 @brief create a boolean (explicit)
1314
1315 Creates a JSON boolean type from a given value.
1316
1317 @param[in] val a boolean value to store
1318
1319 @complexity Constant.
1320
1321 @liveexample{The example below demonstrates boolean
1322 values.,basic_json__boolean_t}
1323
1324 @since version 1.0.0
1325 */
1326 basic_json(boolean_t val) noexcept
1327 : m_type(value_t::boolean), m_value(val)
1328 {
1329 assert_invariant();
1330 }
1331
1332 /*!
1333 @brief create an integer number (explicit)
1334
1335 Create an integer number JSON value with a given content.
1336
1337 @tparam T A helper type to remove this function via SFINAE in case @ref
1338 number_integer_t is the same as `int`. In this case, this constructor
1339 would have the same signature as @ref basic_json(const int value). Note
1340 the helper type @a T is not visible in this constructor's interface.
1341
1342 @param[in] val an integer to create a JSON number from
1343
1344 @complexity Constant.
1345
1346 @liveexample{The example below shows the construction of an integer
1347 number value.,basic_json__number_integer_t}
1348
1349 @sa @ref basic_json(const int) -- create a number value (integer)
1350 @sa @ref basic_json(const CompatibleNumberIntegerType) -- create a number
1351 value (integer) from a compatible number type
1352
1353 @since version 1.0.0
1354 */
1355 template<typename T, typename std::enable_if<
1356 not (std::is_same<T, int>::value) and
1357 std::is_same<T, number_integer_t>::value, int>::type = 0>
1358 basic_json(const number_integer_t val) noexcept
1359 : m_type(value_t::number_integer), m_value(val)
1360 {
1361 assert_invariant();
1362 }
1363
1364 /*!
1365 @brief create an integer number from an enum type (explicit)
1366
1367 Create an integer number JSON value with a given content.
1368
1369 @param[in] val an integer to create a JSON number from
1370
1371 @note This constructor allows to pass enums directly to a constructor. As
1372 C++ has no way of specifying the type of an anonymous enum explicitly, we
1373 can only rely on the fact that such values implicitly convert to int. As
1374 int may already be the same type of number_integer_t, we may need to
1375 switch off the constructor @ref basic_json(const number_integer_t).
1376
1377 @complexity Constant.
1378
1379 @liveexample{The example below shows the construction of an integer
1380 number value from an anonymous enum.,basic_json__const_int}
1381
1382 @sa @ref basic_json(const number_integer_t) -- create a number value
1383 (integer)
1384 @sa @ref basic_json(const CompatibleNumberIntegerType) -- create a number
1385 value (integer) from a compatible number type
1386
1387 @since version 1.0.0
1388 */
1389 basic_json(const int val) noexcept
1390 : m_type(value_t::number_integer),
1391 m_value(static_cast<number_integer_t>(val))
1392 {
1393 assert_invariant();
1394 }
1395
1396 /*!
1397 @brief create an integer number (implicit)
1398
1399 Create an integer number JSON value with a given content. This constructor
1400 allows any type @a CompatibleNumberIntegerType that can be used to
1401 construct values of type @ref number_integer_t.
1402
1403 @tparam CompatibleNumberIntegerType An integer type which is compatible to
1404 @ref number_integer_t. Examples include the types `int`, `int32_t`,
1405 `long`, and `short`.
1406
1407 @param[in] val an integer to create a JSON number from
1408
1409 @complexity Constant.
1410
1411 @liveexample{The example below shows the construction of several integer
1412 number values from compatible
1413 types.,basic_json__CompatibleIntegerNumberType}
1414
1415 @sa @ref basic_json(const number_integer_t) -- create a number value
1416 (integer)
1417 @sa @ref basic_json(const int) -- create a number value (integer)
1418
1419 @since version 1.0.0
1420 */
1421 template<typename CompatibleNumberIntegerType, typename std::enable_if<
1422 std::is_constructible<number_integer_t, CompatibleNumberIntegerType>::value and
1423 std::numeric_limits<CompatibleNumberIntegerType>::is_integer and
1424 std::numeric_limits<CompatibleNumberIntegerType>::is_signed,
1425 CompatibleNumberIntegerType>::type = 0>
1426 basic_json(const CompatibleNumberIntegerType val) noexcept
1427 : m_type(value_t::number_integer),
1428 m_value(static_cast<number_integer_t>(val))
1429 {
1430 assert_invariant();
1431 }
1432
1433 /*!
1434 @brief create an unsigned integer number (explicit)
1435
1436 Create an unsigned integer number JSON value with a given content.
1437
1438 @tparam T helper type to compare number_unsigned_t and unsigned int (not
1439 visible in) the interface.
1440
1441 @param[in] val an integer to create a JSON number from
1442
1443 @complexity Constant.
1444
1445 @sa @ref basic_json(const CompatibleNumberUnsignedType) -- create a number
1446 value (unsigned integer) from a compatible number type
1447
1448 @since version 2.0.0
1449 */
1450 template<typename T, typename std::enable_if<
1451 not (std::is_same<T, int>::value) and
1452 std::is_same<T, number_unsigned_t>::value, int>::type = 0>
1453 basic_json(const number_unsigned_t val) noexcept
1454 : m_type(value_t::number_unsigned), m_value(val)
1455 {
1456 assert_invariant();
1457 }
1458
1459 /*!
1460 @brief create an unsigned number (implicit)
1461
1462 Create an unsigned number JSON value with a given content. This
1463 constructor allows any type @a CompatibleNumberUnsignedType that can be
1464 used to construct values of type @ref number_unsigned_t.
1465
1466 @tparam CompatibleNumberUnsignedType An integer type which is compatible
1467 to @ref number_unsigned_t. Examples may include the types `unsigned int`,
1468 `uint32_t`, or `unsigned short`.
1469
1470 @param[in] val an unsigned integer to create a JSON number from
1471
1472 @complexity Constant.
1473
1474 @sa @ref basic_json(const number_unsigned_t) -- create a number value
1475 (unsigned)
1476
1477 @since version 2.0.0
1478 */
1479 template<typename CompatibleNumberUnsignedType, typename std::enable_if <
1480 std::is_constructible<number_unsigned_t, CompatibleNumberUnsignedType>::value and
1481 std::numeric_limits<CompatibleNumberUnsignedType>::is_integer and
1482 not std::numeric_limits<CompatibleNumberUnsignedType>::is_signed,
1483 CompatibleNumberUnsignedType>::type = 0>
1484 basic_json(const CompatibleNumberUnsignedType val) noexcept
1485 : m_type(value_t::number_unsigned),
1486 m_value(static_cast<number_unsigned_t>(val))
1487 {
1488 assert_invariant();
1489 }
1490
1491 /*!
1492 @brief create a floating-point number (explicit)
1493
1494 Create a floating-point number JSON value with a given content.
1495
1496 @param[in] val a floating-point value to create a JSON number from
1497
1498 @note [RFC 7159](http://www.rfc-editor.org/rfc/rfc7159.txt), section 6
1499 disallows NaN values:
1500 > Numeric values that cannot be represented in the grammar below (such as
1501 > Infinity and NaN) are not permitted.
1502 In case the parameter @a val is not a number, a JSON null value is created
1503 instead.
1504
1505 @complexity Constant.
1506
1507 @liveexample{The following example creates several floating-point
1508 values.,basic_json__number_float_t}
1509
1510 @sa @ref basic_json(const CompatibleNumberFloatType) -- create a number
1511 value (floating-point) from a compatible number type
1512
1513 @since version 1.0.0
1514 */
1515 basic_json(const number_float_t val) noexcept
1516 : m_type(value_t::number_float), m_value(val)
1517 {
1518 // replace infinity and NAN by null
1519 if (not std::isfinite(val))
1520 {
1521 m_type = value_t::null;
1522 m_value = json_value();
1523 }
1524
1525 assert_invariant();
1526 }
1527
1528 /*!
1529 @brief create an floating-point number (implicit)
1530
1531 Create an floating-point number JSON value with a given content. This
1532 constructor allows any type @a CompatibleNumberFloatType that can be used
1533 to construct values of type @ref number_float_t.
1534
1535 @tparam CompatibleNumberFloatType A floating-point type which is
1536 compatible to @ref number_float_t. Examples may include the types `float`
1537 or `double`.
1538
1539 @param[in] val a floating-point to create a JSON number from
1540
1541 @note [RFC 7159](http://www.rfc-editor.org/rfc/rfc7159.txt), section 6
1542 disallows NaN values:
1543 > Numeric values that cannot be represented in the grammar below (such as
1544 > Infinity and NaN) are not permitted.
1545 In case the parameter @a val is not a number, a JSON null value is
1546 created instead.
1547
1548 @complexity Constant.
1549
1550 @liveexample{The example below shows the construction of several
1551 floating-point number values from compatible
1552 types.,basic_json__CompatibleNumberFloatType}
1553
1554 @sa @ref basic_json(const number_float_t) -- create a number value
1555 (floating-point)
1556
1557 @since version 1.0.0
1558 */
1559 template<typename CompatibleNumberFloatType, typename = typename std::enable_if<
1560 std::is_constructible<number_float_t, CompatibleNumberFloatType>::value and
1561 std::is_floating_point<CompatibleNumberFloatType>::value>::type>
1562 basic_json(const CompatibleNumberFloatType val) noexcept
1563 : basic_json(number_float_t(val))
1564 {
1565 assert_invariant();
1566 }
1567
1568 /*!
1569 @brief create a container (array or object) from an initializer list
1570
1571 Creates a JSON value of type array or object from the passed initializer
1572 list @a init. In case @a type_deduction is `true` (default), the type of
1573 the JSON value to be created is deducted from the initializer list @a init
1574 according to the following rules:
1575
1576 1. If the list is empty, an empty JSON object value `{}` is created.
1577 2. If the list consists of pairs whose first element is a string, a JSON
1578 object value is created where the first elements of the pairs are
1579 treated as keys and the second elements are as values.
1580 3. In all other cases, an array is created.
1581
1582 The rules aim to create the best fit between a C++ initializer list and
1583 JSON values. The rationale is as follows:
1584
1585 1. The empty initializer list is written as `{}` which is exactly an empty
1586 JSON object.
1587 2. C++ has now way of describing mapped types other than to list a list of
1588 pairs. As JSON requires that keys must be of type string, rule 2 is the
1589 weakest constraint one can pose on initializer lists to interpret them
1590 as an object.
1591 3. In all other cases, the initializer list could not be interpreted as
1592 JSON object type, so interpreting it as JSON array type is safe.
1593
1594 With the rules described above, the following JSON values cannot be
1595 expressed by an initializer list:
1596
1597 - the empty array (`[]`): use @ref array(std::initializer_list<basic_json>)
1598 with an empty initializer list in this case
1599 - arrays whose elements satisfy rule 2: use @ref
1600 array(std::initializer_list<basic_json>) with the same initializer list
1601 in this case
1602
1603 @note When used without parentheses around an empty initializer list, @ref
1604 basic_json() is called instead of this function, yielding the JSON null
1605 value.
1606
1607 @param[in] init initializer list with JSON values
1608
1609 @param[in] type_deduction internal parameter; when set to `true`, the type
1610 of the JSON value is deducted from the initializer list @a init; when set
1611 to `false`, the type provided via @a manual_type is forced. This mode is
1612 used by the functions @ref array(std::initializer_list<basic_json>) and
1613 @ref object(std::initializer_list<basic_json>).
1614
1615 @param[in] manual_type internal parameter; when @a type_deduction is set
1616 to `false`, the created JSON value will use the provided type (only @ref
1617 value_t::array and @ref value_t::object are valid); when @a type_deduction
1618 is set to `true`, this parameter has no effect
1619
1620 @throw std::domain_error if @a type_deduction is `false`, @a manual_type
1621 is `value_t::object`, but @a init contains an element which is not a pair
1622 whose first element is a string; example: `"cannot create object from
1623 initializer list"`
1624
1625 @complexity Linear in the size of the initializer list @a init.
1626
1627 @liveexample{The example below shows how JSON values are created from
1628 initializer lists.,basic_json__list_init_t}
1629
1630 @sa @ref array(std::initializer_list<basic_json>) -- create a JSON array
1631 value from an initializer list
1632 @sa @ref object(std::initializer_list<basic_json>) -- create a JSON object
1633 value from an initializer list
1634
1635 @since version 1.0.0
1636 */
1637 basic_json(std::initializer_list<basic_json> init,
1638 bool type_deduction = true,
1639 value_t manual_type = value_t::array)
1640 {
1641 // check if each element is an array with two elements whose first
1642 // element is a string
1643 bool is_an_object = std::all_of(init.begin(), init.end(),
1644 [](const basic_json & element)
1645 {
1646 return element.is_array() and element.size() == 2 and element[0].is_string();
1647 });
1648
1649 // adjust type if type deduction is not wanted
1650 if (not type_deduction)
1651 {
1652 // if array is wanted, do not create an object though possible
1653 if (manual_type == value_t::array)
1654 {
1655 is_an_object = false;
1656 }
1657
1658 // if object is wanted but impossible, throw an exception
1659 if (manual_type == value_t::object and not is_an_object)
1660 {
1661 throw std::domain_error("cannot create object from initializer list");
1662 }
1663 }
1664
1665 if (is_an_object)
1666 {
1667 // the initializer list is a list of pairs -> create object
1668 m_type = value_t::object;
1669 m_value = value_t::object;
1670
1671 std::for_each(init.begin(), init.end(), [this](const basic_json & element)
1672 {
1673 m_value.object->emplace(*(element[0].m_value.string), element[1]);
1674 });
1675 }
1676 else
1677 {
1678 // the initializer list describes an array -> create array
1679 m_type = value_t::array;
1680 m_value.array = create<array_t>(init);
1681 }
1682
1683 assert_invariant();
1684 }
1685
1686 /*!
1687 @brief explicitly create an array from an initializer list
1688
1689 Creates a JSON array value from a given initializer list. That is, given a
1690 list of values `a, b, c`, creates the JSON value `[a, b, c]`. If the
1691 initializer list is empty, the empty array `[]` is created.
1692
1693 @note This function is only needed to express two edge cases that cannot
1694 be realized with the initializer list constructor (@ref
1695 basic_json(std::initializer_list<basic_json>, bool, value_t)). These cases
1696 are:
1697 1. creating an array whose elements are all pairs whose first element is a
1698 string -- in this case, the initializer list constructor would create an
1699 object, taking the first elements as keys
1700 2. creating an empty array -- passing the empty initializer list to the
1701 initializer list constructor yields an empty object
1702
1703 @param[in] init initializer list with JSON values to create an array from
1704 (optional)
1705
1706 @return JSON array value
1707
1708 @complexity Linear in the size of @a init.
1709
1710 @liveexample{The following code shows an example for the `array`
1711 function.,array}
1712
1713 @sa @ref basic_json(std::initializer_list<basic_json>, bool, value_t) --
1714 create a JSON value from an initializer list
1715 @sa @ref object(std::initializer_list<basic_json>) -- create a JSON object
1716 value from an initializer list
1717
1718 @since version 1.0.0
1719 */
1720 static basic_json array(std::initializer_list<basic_json> init =
1721 std::initializer_list<basic_json>())
1722 {
1723 return basic_json(init, false, value_t::array);
1724 }
1725
1726 /*!
1727 @brief explicitly create an object from an initializer list
1728
1729 Creates a JSON object value from a given initializer list. The initializer
1730 lists elements must be pairs, and their first elements must be strings. If
1731 the initializer list is empty, the empty object `{}` is created.
1732
1733 @note This function is only added for symmetry reasons. In contrast to the
1734 related function @ref array(std::initializer_list<basic_json>), there are
1735 no cases which can only be expressed by this function. That is, any
1736 initializer list @a init can also be passed to the initializer list
1737 constructor @ref basic_json(std::initializer_list<basic_json>, bool,
1738 value_t).
1739
1740 @param[in] init initializer list to create an object from (optional)
1741
1742 @return JSON object value
1743
1744 @throw std::domain_error if @a init is not a pair whose first elements are
1745 strings; thrown by
1746 @ref basic_json(std::initializer_list<basic_json>, bool, value_t)
1747
1748 @complexity Linear in the size of @a init.
1749
1750 @liveexample{The following code shows an example for the `object`
1751 function.,object}
1752
1753 @sa @ref basic_json(std::initializer_list<basic_json>, bool, value_t) --
1754 create a JSON value from an initializer list
1755 @sa @ref array(std::initializer_list<basic_json>) -- create a JSON array
1756 value from an initializer list
1757
1758 @since version 1.0.0
1759 */
1760 static basic_json object(std::initializer_list<basic_json> init =
1761 std::initializer_list<basic_json>())
1762 {
1763 return basic_json(init, false, value_t::object);
1764 }
1765
1766 /*!
1767 @brief construct an array with count copies of given value
1768
1769 Constructs a JSON array value by creating @a cnt copies of a passed value.
1770 In case @a cnt is `0`, an empty array is created. As postcondition,
1771 `std::distance(begin(),end()) == cnt` holds.
1772
1773 @param[in] cnt the number of JSON copies of @a val to create
1774 @param[in] val the JSON value to copy
1775
1776 @complexity Linear in @a cnt.
1777
1778 @liveexample{The following code shows examples for the @ref
1779 basic_json(size_type\, const basic_json&)
1780 constructor.,basic_json__size_type_basic_json}
1781
1782 @since version 1.0.0
1783 */
1784 basic_json(size_type cnt, const basic_json& val)
1785 : m_type(value_t::array)
1786 {
1787 m_value.array = create<array_t>(cnt, val);
1788 assert_invariant();
1789 }
1790
1791 /*!
1792 @brief construct a JSON container given an iterator range
1793
1794 Constructs the JSON value with the contents of the range `[first, last)`.
1795 The semantics depends on the different types a JSON value can have:
1796 - In case of primitive types (number, boolean, or string), @a first must
1797 be `begin()` and @a last must be `end()`. In this case, the value is
1798 copied. Otherwise, std::out_of_range is thrown.
1799 - In case of structured types (array, object), the constructor behaves as
1800 similar versions for `std::vector`.
1801 - In case of a null type, std::domain_error is thrown.
1802
1803 @tparam InputIT an input iterator type (@ref iterator or @ref
1804 const_iterator)
1805
1806 @param[in] first begin of the range to copy from (included)
1807 @param[in] last end of the range to copy from (excluded)
1808
1809 @pre Iterators @a first and @a last must be initialized. **This
1810 precondition is enforced with an assertion.**
1811
1812 @throw std::domain_error if iterators are not compatible; that is, do not
1813 belong to the same JSON value; example: `"iterators are not compatible"`
1814 @throw std::out_of_range if iterators are for a primitive type (number,
1815 boolean, or string) where an out of range error can be detected easily;
1816 example: `"iterators out of range"`
1817 @throw std::bad_alloc if allocation for object, array, or string fails
1818 @throw std::domain_error if called with a null value; example: `"cannot
1819 use construct with iterators from null"`
1820
1821 @complexity Linear in distance between @a first and @a last.
1822
1823 @liveexample{The example below shows several ways to create JSON values by
1824 specifying a subrange with iterators.,basic_json__InputIt_InputIt}
1825
1826 @since version 1.0.0
1827 */
1828 template<class InputIT, typename std::enable_if<
1829 std::is_same<InputIT, typename basic_json_t::iterator>::value or
1830 std::is_same<InputIT, typename basic_json_t::const_iterator>::value, int>::type = 0>
1831 basic_json(InputIT first, InputIT last)
1832 {
1833 assert(first.m_object != nullptr);
1834 assert(last.m_object != nullptr);
1835
1836 // make sure iterator fits the current value
1837 if (first.m_object != last.m_object)
1838 {
1839 throw std::domain_error("iterators are not compatible");
1840 }
1841
1842 // copy type from first iterator
1843 m_type = first.m_object->m_type;
1844
1845 // check if iterator range is complete for primitive values
1846 switch (m_type)
1847 {
1848 case value_t::boolean:
1849 case value_t::number_float:
1850 case value_t::number_integer:
1851 case value_t::number_unsigned:
1852 case value_t::string:
1853 {
1854 if (not first.m_it.primitive_iterator.is_begin() or not last.m_it.primitive_iterator.is_end())
1855 {
1856 throw std::out_of_range("iterators out of range");
1857 }
1858 break;
1859 }
1860
1861 default:
1862 {
1863 break;
1864 }
1865 }
1866
1867 switch (m_type)
1868 {
1869 case value_t::number_integer:
1870 {
1871 m_value.number_integer = first.m_object->m_value.number_integer;
1872 break;
1873 }
1874
1875 case value_t::number_unsigned:
1876 {
1877 m_value.number_unsigned = first.m_object->m_value.number_unsigned;
1878 break;
1879 }
1880
1881 case value_t::number_float:
1882 {
1883 m_value.number_float = first.m_object->m_value.number_float;
1884 break;
1885 }
1886
1887 case value_t::boolean:
1888 {
1889 m_value.boolean = first.m_object->m_value.boolean;
1890 break;
1891 }
1892
1893 case value_t::string:
1894 {
1895 m_value = *first.m_object->m_value.string;
1896 break;
1897 }
1898
1899 case value_t::object:
1900 {
1901 m_value.object = create<object_t>(first.m_it.object_iterator, last.m_it.object_iterator);
1902 break;
1903 }
1904
1905 case value_t::array:
1906 {
1907 m_value.array = create<array_t>(first.m_it.array_iterator, last.m_it.array_iterator);
1908 break;
1909 }
1910
1911 default:
1912 {
1913 throw std::domain_error("cannot use construct with iterators from " + first.m_object->type_name());
1914 }
1915 }
1916
1917 assert_invariant();
1918 }
1919
1920 /*!
1921 @brief construct a JSON value given an input stream
1922
1923 @param[in,out] i stream to read a serialized JSON value from
1924 @param[in] cb a parser callback function of type @ref parser_callback_t
1925 which is used to control the deserialization by filtering unwanted values
1926 (optional)
1927
1928 @complexity Linear in the length of the input. The parser is a predictive
1929 LL(1) parser. The complexity can be higher if the parser callback function
1930 @a cb has a super-linear complexity.
1931
1932 @note A UTF-8 byte order mark is silently ignored.
1933
1934 @deprecated This constructor is deprecated and will be removed in version
1935 3.0.0 to unify the interface of the library. Deserialization will be
1936 done by stream operators or by calling one of the `parse` functions,
1937 e.g. @ref parse(std::istream&, const parser_callback_t). That is, calls
1938 like `json j(i);` for an input stream @a i need to be replaced by
1939 `json j = json::parse(i);`. See the example below.
1940
1941 @liveexample{The example below demonstrates constructing a JSON value from
1942 a `std::stringstream` with and without callback
1943 function.,basic_json__istream}
1944
1945 @since version 2.0.0, deprecated in version 2.0.3, to be removed in
1946 version 3.0.0
1947 */
1948 JSON_DEPRECATED
1949 explicit basic_json(std::istream& i, const parser_callback_t cb = nullptr)
1950 {
1951 *this = parser(i, cb).parse();
1952 assert_invariant();
1953 }
1954
1955 ///////////////////////////////////////
1956 // other constructors and destructor //
1957 ///////////////////////////////////////
1958
1959 /*!
1960 @brief copy constructor
1961
1962 Creates a copy of a given JSON value.
1963
1964 @param[in] other the JSON value to copy
1965
1966 @complexity Linear in the size of @a other.
1967
1968 @requirement This function helps `basic_json` satisfying the
1969 [Container](http://en.cppreference.com/w/cpp/concept/Container)
1970 requirements:
1971 - The complexity is linear.
1972 - As postcondition, it holds: `other == basic_json(other)`.
1973
1974 @throw std::bad_alloc if allocation for object, array, or string fails.
1975
1976 @liveexample{The following code shows an example for the copy
1977 constructor.,basic_json__basic_json}
1978
1979 @since version 1.0.0
1980 */
1981 basic_json(const basic_json& other)
1982 : m_type(other.m_type)
1983 {
1984 // check of passed value is valid
1985 other.assert_invariant();
1986
1987 switch (m_type)
1988 {
1989 case value_t::object:
1990 {
1991 m_value = *other.m_value.object;
1992 break;
1993 }
1994
1995 case value_t::array:
1996 {
1997 m_value = *other.m_value.array;
1998 break;
1999 }
2000
2001 case value_t::string:
2002 {
2003 m_value = *other.m_value.string;
2004 break;
2005 }
2006
2007 case value_t::boolean:
2008 {
2009 m_value = other.m_value.boolean;
2010 break;
2011 }
2012
2013 case value_t::number_integer:
2014 {
2015 m_value = other.m_value.number_integer;
2016 break;
2017 }
2018
2019 case value_t::number_unsigned:
2020 {
2021 m_value = other.m_value.number_unsigned;
2022 break;
2023 }
2024
2025 case value_t::number_float:
2026 {
2027 m_value = other.m_value.number_float;
2028 break;
2029 }
2030
2031 default:
2032 {
2033 break;
2034 }
2035 }
2036
2037 assert_invariant();
2038 }
2039
2040 /*!
2041 @brief move constructor
2042
2043 Move constructor. Constructs a JSON value with the contents of the given
2044 value @a other using move semantics. It "steals" the resources from @a
2045 other and leaves it as JSON null value.
2046
2047 @param[in,out] other value to move to this object
2048
2049 @post @a other is a JSON null value
2050
2051 @complexity Constant.
2052
2053 @liveexample{The code below shows the move constructor explicitly called
2054 via std::move.,basic_json__moveconstructor}
2055
2056 @since version 1.0.0
2057 */
2058 basic_json(basic_json&& other) noexcept
2059 : m_type(std::move(other.m_type)),
2060 m_value(std::move(other.m_value))
2061 {
2062 // check that passed value is valid
2063 other.assert_invariant();
2064
2065 // invalidate payload
2066 other.m_type = value_t::null;
2067 other.m_value = {};
2068
2069 assert_invariant();
2070 }
2071
2072 /*!
2073 @brief copy assignment
2074
2075 Copy assignment operator. Copies a JSON value via the "copy and swap"
2076 strategy: It is expressed in terms of the copy constructor, destructor,
2077 and the swap() member function.
2078
2079 @param[in] other value to copy from
2080
2081 @complexity Linear.
2082
2083 @requirement This function helps `basic_json` satisfying the
2084 [Container](http://en.cppreference.com/w/cpp/concept/Container)
2085 requirements:
2086 - The complexity is linear.
2087
2088 @liveexample{The code below shows and example for the copy assignment. It
2089 creates a copy of value `a` which is then swapped with `b`. Finally\, the
2090 copy of `a` (which is the null value after the swap) is
2091 destroyed.,basic_json__copyassignment}
2092
2093 @since version 1.0.0
2094 */
2095 reference& operator=(basic_json other) noexcept (
2096 std::is_nothrow_move_constructible<value_t>::value and
2097 std::is_nothrow_move_assignable<value_t>::value and
2098 std::is_nothrow_move_constructible<json_value>::value and
2099 std::is_nothrow_move_assignable<json_value>::value
2100 )
2101 {
2102 // check that passed value is valid
2103 other.assert_invariant();
2104
2105 using std::swap;
2106 swap(m_type, other.m_type);
2107 swap(m_value, other.m_value);
2108
2109 assert_invariant();
2110 return *this;
2111 }
2112
2113 /*!
2114 @brief destructor
2115
2116 Destroys the JSON value and frees all allocated memory.
2117
2118 @complexity Linear.
2119
2120 @requirement This function helps `basic_json` satisfying the
2121 [Container](http://en.cppreference.com/w/cpp/concept/Container)
2122 requirements:
2123 - The complexity is linear.
2124 - All stored elements are destroyed and all memory is freed.
2125
2126 @since version 1.0.0
2127 */
2128 ~basic_json()
2129 {
2130 assert_invariant();
2131
2132 switch (m_type)
2133 {
2134 case value_t::object:
2135 {
2136 AllocatorType<object_t> alloc;
2137 alloc.destroy(m_value.object);
2138 alloc.deallocate(m_value.object, 1);
2139 break;
2140 }
2141
2142 case value_t::array:
2143 {
2144 AllocatorType<array_t> alloc;
2145 alloc.destroy(m_value.array);
2146 alloc.deallocate(m_value.array, 1);
2147 break;
2148 }
2149
2150 case value_t::string:
2151 {
2152 AllocatorType<string_t> alloc;
2153 alloc.destroy(m_value.string);
2154 alloc.deallocate(m_value.string, 1);
2155 break;
2156 }
2157
2158 default:
2159 {
2160 // all other types need no specific destructor
2161 break;
2162 }
2163 }
2164 }
2165
2166 /// @}
2167
2168 public:
2169 ///////////////////////
2170 // object inspection //
2171 ///////////////////////
2172
2173 /// @name object inspection
2174 /// Functions to inspect the type of a JSON value.
2175 /// @{
2176
2177 /*!
2178 @brief serialization
2179
2180 Serialization function for JSON values. The function tries to mimic
2181 Python's `json.dumps()` function, and currently supports its @a indent
2182 parameter.
2183
2184 @param[in] indent If indent is nonnegative, then array elements and object
2185 members will be pretty-printed with that indent level. An indent level of
2186 `0` will only insert newlines. `-1` (the default) selects the most compact
2187 representation.
2188
2189 @return string containing the serialization of the JSON value
2190
2191 @complexity Linear.
2192
2193 @liveexample{The following example shows the effect of different @a indent
2194 parameters to the result of the serialization.,dump}
2195
2196 @see https://docs.python.org/2/library/json.html#json.dump
2197
2198 @since version 1.0.0
2199 */
2200 string_t dump(const int indent = -1) const
2201 {
2202 std::stringstream ss;
2203 // fix locale problems
2204 const static std::locale loc(std::locale(), new DecimalSeparator);
2205 ss.imbue(loc);
2206
2207 // 6, 15 or 16 digits of precision allows round-trip IEEE 754
2208 // string->float->string, string->double->string or string->long
2209 // double->string; to be safe, we read this value from
2210 // std::numeric_limits<number_float_t>::digits10
2211 ss.precision(std::numeric_limits<double>::digits10);
2212
2213 if (indent >= 0)
2214 {
2215 dump(ss, true, static_cast<unsigned int>(indent));
2216 }
2217 else
2218 {
2219 dump(ss, false, 0);
2220 }
2221
2222 return ss.str();
2223 }
2224
2225 /*!
2226 @brief return the type of the JSON value (explicit)
2227
2228 Return the type of the JSON value as a value from the @ref value_t
2229 enumeration.
2230
2231 @return the type of the JSON value
2232
2233 @complexity Constant.
2234
2235 @exceptionsafety No-throw guarantee: this member function never throws
2236 exceptions.
2237
2238 @liveexample{The following code exemplifies `type()` for all JSON
2239 types.,type}
2240
2241 @since version 1.0.0
2242 */
2243 constexpr value_t type() const noexcept
2244 {
2245 return m_type;
2246 }
2247
2248 /*!
2249 @brief return whether type is primitive
2250
2251 This function returns true iff the JSON type is primitive (string, number,
2252 boolean, or null).
2253
2254 @return `true` if type is primitive (string, number, boolean, or null),
2255 `false` otherwise.
2256
2257 @complexity Constant.
2258
2259 @exceptionsafety No-throw guarantee: this member function never throws
2260 exceptions.
2261
2262 @liveexample{The following code exemplifies `is_primitive()` for all JSON
2263 types.,is_primitive}
2264
2265 @sa @ref is_structured() -- returns whether JSON value is structured
2266 @sa @ref is_null() -- returns whether JSON value is `null`
2267 @sa @ref is_string() -- returns whether JSON value is a string
2268 @sa @ref is_boolean() -- returns whether JSON value is a boolean
2269 @sa @ref is_number() -- returns whether JSON value is a number
2270
2271 @since version 1.0.0
2272 */
2273 constexpr bool is_primitive() const noexcept
2274 {
2275 return is_null() or is_string() or is_boolean() or is_number();
2276 }
2277
2278 /*!
2279 @brief return whether type is structured
2280
2281 This function returns true iff the JSON type is structured (array or
2282 object).
2283
2284 @return `true` if type is structured (array or object), `false` otherwise.
2285
2286 @complexity Constant.
2287
2288 @exceptionsafety No-throw guarantee: this member function never throws
2289 exceptions.
2290
2291 @liveexample{The following code exemplifies `is_structured()` for all JSON
2292 types.,is_structured}
2293
2294 @sa @ref is_primitive() -- returns whether value is primitive
2295 @sa @ref is_array() -- returns whether value is an array
2296 @sa @ref is_object() -- returns whether value is an object
2297
2298 @since version 1.0.0
2299 */
2300 constexpr bool is_structured() const noexcept
2301 {
2302 return is_array() or is_object();
2303 }
2304
2305 /*!
2306 @brief return whether value is null
2307
2308 This function returns true iff the JSON value is null.
2309
2310 @return `true` if type is null, `false` otherwise.
2311
2312 @complexity Constant.
2313
2314 @exceptionsafety No-throw guarantee: this member function never throws
2315 exceptions.
2316
2317 @liveexample{The following code exemplifies `is_null()` for all JSON
2318 types.,is_null}
2319
2320 @since version 1.0.0
2321 */
2322 constexpr bool is_null() const noexcept
2323 {
2324 return m_type == value_t::null;
2325 }
2326
2327 /*!
2328 @brief return whether value is a boolean
2329
2330 This function returns true iff the JSON value is a boolean.
2331
2332 @return `true` if type is boolean, `false` otherwise.
2333
2334 @complexity Constant.
2335
2336 @exceptionsafety No-throw guarantee: this member function never throws
2337 exceptions.
2338
2339 @liveexample{The following code exemplifies `is_boolean()` for all JSON
2340 types.,is_boolean}
2341
2342 @since version 1.0.0
2343 */
2344 constexpr bool is_boolean() const noexcept
2345 {
2346 return m_type == value_t::boolean;
2347 }
2348
2349 /*!
2350 @brief return whether value is a number
2351
2352 This function returns true iff the JSON value is a number. This includes
2353 both integer and floating-point values.
2354
2355 @return `true` if type is number (regardless whether integer, unsigned
2356 integer or floating-type), `false` otherwise.
2357
2358 @complexity Constant.
2359
2360 @exceptionsafety No-throw guarantee: this member function never throws
2361 exceptions.
2362
2363 @liveexample{The following code exemplifies `is_number()` for all JSON
2364 types.,is_number}
2365
2366 @sa @ref is_number_integer() -- check if value is an integer or unsigned
2367 integer number
2368 @sa @ref is_number_unsigned() -- check if value is an unsigned integer
2369 number
2370 @sa @ref is_number_float() -- check if value is a floating-point number
2371
2372 @since version 1.0.0
2373 */
2374 constexpr bool is_number() const noexcept
2375 {
2376 return is_number_integer() or is_number_float();
2377 }
2378
2379 /*!
2380 @brief return whether value is an integer number
2381
2382 This function returns true iff the JSON value is an integer or unsigned
2383 integer number. This excludes floating-point values.
2384
2385 @return `true` if type is an integer or unsigned integer number, `false`
2386 otherwise.
2387
2388 @complexity Constant.
2389
2390 @exceptionsafety No-throw guarantee: this member function never throws
2391 exceptions.
2392
2393 @liveexample{The following code exemplifies `is_number_integer()` for all
2394 JSON types.,is_number_integer}
2395
2396 @sa @ref is_number() -- check if value is a number
2397 @sa @ref is_number_unsigned() -- check if value is an unsigned integer
2398 number
2399 @sa @ref is_number_float() -- check if value is a floating-point number
2400
2401 @since version 1.0.0
2402 */
2403 constexpr bool is_number_integer() const noexcept
2404 {
2405 return m_type == value_t::number_integer or m_type == value_t::number_unsigned;
2406 }
2407
2408 /*!
2409 @brief return whether value is an unsigned integer number
2410
2411 This function returns true iff the JSON value is an unsigned integer
2412 number. This excludes floating-point and (signed) integer values.
2413
2414 @return `true` if type is an unsigned integer number, `false` otherwise.
2415
2416 @complexity Constant.
2417
2418 @exceptionsafety No-throw guarantee: this member function never throws
2419 exceptions.
2420
2421 @liveexample{The following code exemplifies `is_number_unsigned()` for all
2422 JSON types.,is_number_unsigned}
2423
2424 @sa @ref is_number() -- check if value is a number
2425 @sa @ref is_number_integer() -- check if value is an integer or unsigned
2426 integer number
2427 @sa @ref is_number_float() -- check if value is a floating-point number
2428
2429 @since version 2.0.0
2430 */
2431 constexpr bool is_number_unsigned() const noexcept
2432 {
2433 return m_type == value_t::number_unsigned;
2434 }
2435
2436 /*!
2437 @brief return whether value is a floating-point number
2438
2439 This function returns true iff the JSON value is a floating-point number.
2440 This excludes integer and unsigned integer values.
2441
2442 @return `true` if type is a floating-point number, `false` otherwise.
2443
2444 @complexity Constant.
2445
2446 @exceptionsafety No-throw guarantee: this member function never throws
2447 exceptions.
2448
2449 @liveexample{The following code exemplifies `is_number_float()` for all
2450 JSON types.,is_number_float}
2451
2452 @sa @ref is_number() -- check if value is number
2453 @sa @ref is_number_integer() -- check if value is an integer number
2454 @sa @ref is_number_unsigned() -- check if value is an unsigned integer
2455 number
2456
2457 @since version 1.0.0
2458 */
2459 constexpr bool is_number_float() const noexcept
2460 {
2461 return m_type == value_t::number_float;
2462 }
2463
2464 /*!
2465 @brief return whether value is an object
2466
2467 This function returns true iff the JSON value is an object.
2468
2469 @return `true` if type is object, `false` otherwise.
2470
2471 @complexity Constant.
2472
2473 @exceptionsafety No-throw guarantee: this member function never throws
2474 exceptions.
2475
2476 @liveexample{The following code exemplifies `is_object()` for all JSON
2477 types.,is_object}
2478
2479 @since version 1.0.0
2480 */
2481 constexpr bool is_object() const noexcept
2482 {
2483 return m_type == value_t::object;
2484 }
2485
2486 /*!
2487 @brief return whether value is an array
2488
2489 This function returns true iff the JSON value is an array.
2490
2491 @return `true` if type is array, `false` otherwise.
2492
2493 @complexity Constant.
2494
2495 @exceptionsafety No-throw guarantee: this member function never throws
2496 exceptions.
2497
2498 @liveexample{The following code exemplifies `is_array()` for all JSON
2499 types.,is_array}
2500
2501 @since version 1.0.0
2502 */
2503 constexpr bool is_array() const noexcept
2504 {
2505 return m_type == value_t::array;
2506 }
2507
2508 /*!
2509 @brief return whether value is a string
2510
2511 This function returns true iff the JSON value is a string.
2512
2513 @return `true` if type is string, `false` otherwise.
2514
2515 @complexity Constant.
2516
2517 @exceptionsafety No-throw guarantee: this member function never throws
2518 exceptions.
2519
2520 @liveexample{The following code exemplifies `is_string()` for all JSON
2521 types.,is_string}
2522
2523 @since version 1.0.0
2524 */
2525 constexpr bool is_string() const noexcept
2526 {
2527 return m_type == value_t::string;
2528 }
2529
2530 /*!
2531 @brief return whether value is discarded
2532
2533 This function returns true iff the JSON value was discarded during parsing
2534 with a callback function (see @ref parser_callback_t).
2535
2536 @note This function will always be `false` for JSON values after parsing.
2537 That is, discarded values can only occur during parsing, but will be
2538 removed when inside a structured value or replaced by null in other cases.
2539
2540 @return `true` if type is discarded, `false` otherwise.
2541
2542 @complexity Constant.
2543
2544 @exceptionsafety No-throw guarantee: this member function never throws
2545 exceptions.
2546
2547 @liveexample{The following code exemplifies `is_discarded()` for all JSON
2548 types.,is_discarded}
2549
2550 @since version 1.0.0
2551 */
2552 constexpr bool is_discarded() const noexcept
2553 {
2554 return m_type == value_t::discarded;
2555 }
2556
2557 /*!
2558 @brief return the type of the JSON value (implicit)
2559
2560 Implicitly return the type of the JSON value as a value from the @ref
2561 value_t enumeration.
2562
2563 @return the type of the JSON value
2564
2565 @complexity Constant.
2566
2567 @exceptionsafety No-throw guarantee: this member function never throws
2568 exceptions.
2569
2570 @liveexample{The following code exemplifies the @ref value_t operator for
2571 all JSON types.,operator__value_t}
2572
2573 @since version 1.0.0
2574 */
2575 constexpr operator value_t() const noexcept
2576 {
2577 return m_type;
2578 }
2579
2580 /// @}
2581
2582 private:
2583 //////////////////
2584 // value access //
2585 //////////////////
2586
2587 /// get an object (explicit)
2588 template<class T, typename std::enable_if<
2589 std::is_convertible<typename object_t::key_type, typename T::key_type>::value and
2590 std::is_convertible<basic_json_t, typename T::mapped_type>::value, int>::type = 0>
2591 T get_impl(T*) const
2592 {
2593 if (is_object())
2594 {
2595 return T(m_value.object->begin(), m_value.object->end());
2596 }
2597 else
2598 {
2599 throw std::domain_error("type must be object, but is " + type_name());
2600 }
2601 }
2602
2603 /// get an object (explicit)
2604 object_t get_impl(object_t*) const
2605 {
2606 if (is_object())
2607 {
2608 return *(m_value.object);
2609 }
2610 else
2611 {
2612 throw std::domain_error("type must be object, but is " + type_name());
2613 }
2614 }
2615
2616 /// get an array (explicit)
2617 template<class T, typename std::enable_if<
2618 std::is_convertible<basic_json_t, typename T::value_type>::value and
2619 not std::is_same<basic_json_t, typename T::value_type>::value and
2620 not std::is_arithmetic<T>::value and
2621 not std::is_convertible<std::string, T>::value and
2622 not has_mapped_type<T>::value, int>::type = 0>
2623 T get_impl(T*) const
2624 {
2625 if (is_array())
2626 {
2627 T to_vector;
2628 std::transform(m_value.array->begin(), m_value.array->end(),
2629 std::inserter(to_vector, to_vector.end()), [](basic_json i)
2630 {
2631 return i.get<typename T::value_type>();
2632 });
2633 return to_vector;
2634 }
2635 else
2636 {
2637 throw std::domain_error("type must be array, but is " + type_name());
2638 }
2639 }
2640
2641 /// get an array (explicit)
2642 template<class T, typename std::enable_if<
2643 std::is_convertible<basic_json_t, T>::value and
2644 not std::is_same<basic_json_t, T>::value, int>::type = 0>
2645 std::vector<T> get_impl(std::vector<T>*) const
2646 {
2647 if (is_array())
2648 {
2649 std::vector<T> to_vector;
2650 to_vector.reserve(m_value.array->size());
2651 std::transform(m_value.array->begin(), m_value.array->end(),
2652 std::inserter(to_vector, to_vector.end()), [](basic_json i)
2653 {
2654 return i.get<T>();
2655 });
2656 return to_vector;
2657 }
2658 else
2659 {
2660 throw std::domain_error("type must be array, but is " + type_name());
2661 }
2662 }
2663
2664 /// get an array (explicit)
2665 template<class T, typename std::enable_if<
2666 std::is_same<basic_json, typename T::value_type>::value and
2667 not has_mapped_type<T>::value, int>::type = 0>
2668 T get_impl(T*) const
2669 {
2670 if (is_array())
2671 {
2672 return T(m_value.array->begin(), m_value.array->end());
2673 }
2674 else
2675 {
2676 throw std::domain_error("type must be array, but is " + type_name());
2677 }
2678 }
2679
2680 /// get an array (explicit)
2681 array_t get_impl(array_t*) const
2682 {
2683 if (is_array())
2684 {
2685 return *(m_value.array);
2686 }
2687 else
2688 {
2689 throw std::domain_error("type must be array, but is " + type_name());
2690 }
2691 }
2692
2693 /// get a string (explicit)
2694 template<typename T, typename std::enable_if<
2695 std::is_convertible<string_t, T>::value, int>::type = 0>
2696 T get_impl(T*) const
2697 {
2698 if (is_string())
2699 {
2700 return *m_value.string;
2701 }
2702 else
2703 {
2704 throw std::domain_error("type must be string, but is " + type_name());
2705 }
2706 }
2707
2708 /// get a number (explicit)
2709 template<typename T, typename std::enable_if<
2710 std::is_arithmetic<T>::value, int>::type = 0>
2711 T get_impl(T*) const
2712 {
2713 switch (m_type)
2714 {
2715 case value_t::number_integer:
2716 {
2717 return static_cast<T>(m_value.number_integer);
2718 }
2719
2720 case value_t::number_unsigned:
2721 {
2722 return static_cast<T>(m_value.number_unsigned);
2723 }
2724
2725 case value_t::number_float:
2726 {
2727 return static_cast<T>(m_value.number_float);
2728 }
2729
2730 default:
2731 {
2732 throw std::domain_error("type must be number, but is " + type_name());
2733 }
2734 }
2735 }
2736
2737 /// get a boolean (explicit)
2738 constexpr boolean_t get_impl(boolean_t*) const
2739 {
2740 return is_boolean()
2741 ? m_value.boolean
2742 : throw std::domain_error("type must be boolean, but is " + type_name());
2743 }
2744
2745 /// get a pointer to the value (object)
2746 object_t* get_impl_ptr(object_t*) noexcept
2747 {
2748 return is_object() ? m_value.object : nullptr;
2749 }
2750
2751 /// get a pointer to the value (object)
2752 constexpr const object_t* get_impl_ptr(const object_t*) const noexcept
2753 {
2754 return is_object() ? m_value.object : nullptr;
2755 }
2756
2757 /// get a pointer to the value (array)
2758 array_t* get_impl_ptr(array_t*) noexcept
2759 {
2760 return is_array() ? m_value.array : nullptr;
2761 }
2762
2763 /// get a pointer to the value (array)
2764 constexpr const array_t* get_impl_ptr(const array_t*) const noexcept
2765 {
2766 return is_array() ? m_value.array : nullptr;
2767 }
2768
2769 /// get a pointer to the value (string)
2770 string_t* get_impl_ptr(string_t*) noexcept
2771 {
2772 return is_string() ? m_value.string : nullptr;
2773 }
2774
2775 /// get a pointer to the value (string)
2776 constexpr const string_t* get_impl_ptr(const string_t*) const noexcept
2777 {
2778 return is_string() ? m_value.string : nullptr;
2779 }
2780
2781 /// get a pointer to the value (boolean)
2782 boolean_t* get_impl_ptr(boolean_t*) noexcept
2783 {
2784 return is_boolean() ? &m_value.boolean : nullptr;
2785 }
2786
2787 /// get a pointer to the value (boolean)
2788 constexpr const boolean_t* get_impl_ptr(const boolean_t*) const noexcept
2789 {
2790 return is_boolean() ? &m_value.boolean : nullptr;
2791 }
2792
2793 /// get a pointer to the value (integer number)
2794 number_integer_t* get_impl_ptr(number_integer_t*) noexcept
2795 {
2796 return is_number_integer() ? &m_value.number_integer : nullptr;
2797 }
2798
2799 /// get a pointer to the value (integer number)
2800 constexpr const number_integer_t* get_impl_ptr(const number_integer_t*) const noexcept
2801 {
2802 return is_number_integer() ? &m_value.number_integer : nullptr;
2803 }
2804
2805 /// get a pointer to the value (unsigned number)
2806 number_unsigned_t* get_impl_ptr(number_unsigned_t*) noexcept
2807 {
2808 return is_number_unsigned() ? &m_value.number_unsigned : nullptr;
2809 }
2810
2811 /// get a pointer to the value (unsigned number)
2812 constexpr const number_unsigned_t* get_impl_ptr(const number_unsigned_t*) const noexcept
2813 {
2814 return is_number_unsigned() ? &m_value.number_unsigned : nullptr;
2815 }
2816
2817 /// get a pointer to the value (floating-point number)
2818 number_float_t* get_impl_ptr(number_float_t*) noexcept
2819 {
2820 return is_number_float() ? &m_value.number_float : nullptr;
2821 }
2822
2823 /// get a pointer to the value (floating-point number)
2824 constexpr const number_float_t* get_impl_ptr(const number_float_t*) const noexcept
2825 {
2826 return is_number_float() ? &m_value.number_float : nullptr;
2827 }
2828
2829 /*!
2830 @brief helper function to implement get_ref()
2831
2832 This funcion helps to implement get_ref() without code duplication for
2833 const and non-const overloads
2834
2835 @tparam ThisType will be deduced as `basic_json` or `const basic_json`
2836
2837 @throw std::domain_error if ReferenceType does not match underlying value
2838 type of the current JSON
2839 */
2840 template<typename ReferenceType, typename ThisType>
2841 static ReferenceType get_ref_impl(ThisType& obj)
2842 {
2843 // helper type
2844 using PointerType = typename std::add_pointer<ReferenceType>::type;
2845
2846 // delegate the call to get_ptr<>()
2847 auto ptr = obj.template get_ptr<PointerType>();
2848
2849 if (ptr != nullptr)
2850 {
2851 return *ptr;
2852 }
2853 else
2854 {
2855 throw std::domain_error("incompatible ReferenceType for get_ref, actual type is " +
2856 obj.type_name());
2857 }
2858 }
2859
2860 public:
2861
2862 /// @name value access
2863 /// Direct access to the stored value of a JSON value.
2864 /// @{
2865
2866 /*!
2867 @brief get a value (explicit)
2868
2869 Explicit type conversion between the JSON value and a compatible value.
2870
2871 @tparam ValueType non-pointer type compatible to the JSON value, for
2872 instance `int` for JSON integer numbers, `bool` for JSON booleans, or
2873 `std::vector` types for JSON arrays
2874
2875 @return copy of the JSON value, converted to type @a ValueType
2876
2877 @throw std::domain_error in case passed type @a ValueType is incompatible
2878 to JSON; example: `"type must be object, but is null"`
2879
2880 @complexity Linear in the size of the JSON value.
2881
2882 @liveexample{The example below shows several conversions from JSON values
2883 to other types. There a few things to note: (1) Floating-point numbers can
2884 be converted to integers\, (2) A JSON array can be converted to a standard
2885 `std::vector<short>`\, (3) A JSON object can be converted to C++
2886 associative containers such as `std::unordered_map<std::string\,
2887 json>`.,get__ValueType_const}
2888
2889 @internal
2890 The idea of using a casted null pointer to choose the correct
2891 implementation is from <http://stackoverflow.com/a/8315197/266378>.
2892 @endinternal
2893
2894 @sa @ref operator ValueType() const for implicit conversion
2895 @sa @ref get() for pointer-member access
2896
2897 @since version 1.0.0
2898 */
2899 template<typename ValueType, typename std::enable_if<
2900 not std::is_pointer<ValueType>::value, int>::type = 0>
2901 ValueType get() const
2902 {
2903 return get_impl(static_cast<ValueType*>(nullptr));
2904 }
2905
2906 /*!
2907 @brief get a pointer value (explicit)
2908
2909 Explicit pointer access to the internally stored JSON value. No copies are
2910 made.
2911
2912 @warning The pointer becomes invalid if the underlying JSON object
2913 changes.
2914
2915 @tparam PointerType pointer type; must be a pointer to @ref array_t, @ref
2916 object_t, @ref string_t, @ref boolean_t, @ref number_integer_t,
2917 @ref number_unsigned_t, or @ref number_float_t.
2918
2919 @return pointer to the internally stored JSON value if the requested
2920 pointer type @a PointerType fits to the JSON value; `nullptr` otherwise
2921
2922 @complexity Constant.
2923
2924 @liveexample{The example below shows how pointers to internal values of a
2925 JSON value can be requested. Note that no type conversions are made and a
2926 `nullptr` is returned if the value and the requested pointer type does not
2927 match.,get__PointerType}
2928
2929 @sa @ref get_ptr() for explicit pointer-member access
2930
2931 @since version 1.0.0
2932 */
2933 template<typename PointerType, typename std::enable_if<
2934 std::is_pointer<PointerType>::value, int>::type = 0>
2935 PointerType get() noexcept
2936 {
2937 // delegate the call to get_ptr
2938 return get_ptr<PointerType>();
2939 }
2940
2941 /*!
2942 @brief get a pointer value (explicit)
2943 @copydoc get()
2944 */
2945 template<typename PointerType, typename std::enable_if<
2946 std::is_pointer<PointerType>::value, int>::type = 0>
2947 constexpr const PointerType get() const noexcept
2948 {
2949 // delegate the call to get_ptr
2950 return get_ptr<PointerType>();
2951 }
2952
2953 /*!
2954 @brief get a pointer value (implicit)
2955
2956 Implicit pointer access to the internally stored JSON value. No copies are
2957 made.
2958
2959 @warning Writing data to the pointee of the result yields an undefined
2960 state.
2961
2962 @tparam PointerType pointer type; must be a pointer to @ref array_t, @ref
2963 object_t, @ref string_t, @ref boolean_t, @ref number_integer_t,
2964 @ref number_unsigned_t, or @ref number_float_t. Enforced by a static
2965 assertion.
2966
2967 @return pointer to the internally stored JSON value if the requested
2968 pointer type @a PointerType fits to the JSON value; `nullptr` otherwise
2969
2970 @complexity Constant.
2971
2972 @liveexample{The example below shows how pointers to internal values of a
2973 JSON value can be requested. Note that no type conversions are made and a
2974 `nullptr` is returned if the value and the requested pointer type does not
2975 match.,get_ptr}
2976
2977 @since version 1.0.0
2978 */
2979 template<typename PointerType, typename std::enable_if<
2980 std::is_pointer<PointerType>::value, int>::type = 0>
2981 PointerType get_ptr() noexcept
2982 {
2983 // get the type of the PointerType (remove pointer and const)
2984 using pointee_t = typename std::remove_const<typename
2985 std::remove_pointer<typename
2986 std::remove_const<PointerType>::type>::type>::type;
2987 // make sure the type matches the allowed types
2988 static_assert(
2989 std::is_same<object_t, pointee_t>::value
2990 or std::is_same<array_t, pointee_t>::value
2991 or std::is_same<string_t, pointee_t>::value
2992 or std::is_same<boolean_t, pointee_t>::value
2993 or std::is_same<number_integer_t, pointee_t>::value
2994 or std::is_same<number_unsigned_t, pointee_t>::value
2995 or std::is_same<number_float_t, pointee_t>::value
2996 , "incompatible pointer type");
2997
2998 // delegate the call to get_impl_ptr<>()
2999 return get_impl_ptr(static_cast<PointerType>(nullptr));
3000 }
3001
3002 /*!
3003 @brief get a pointer value (implicit)
3004 @copydoc get_ptr()
3005 */
3006 template<typename PointerType, typename std::enable_if<
3007 std::is_pointer<PointerType>::value and
3008 std::is_const<typename std::remove_pointer<PointerType>::type>::value, int>::type = 0>
3009 constexpr const PointerType get_ptr() const noexcept
3010 {
3011 // get the type of the PointerType (remove pointer and const)
3012 using pointee_t = typename std::remove_const<typename
3013 std::remove_pointer<typename
3014 std::remove_const<PointerType>::type>::type>::type;
3015 // make sure the type matches the allowed types
3016 static_assert(
3017 std::is_same<object_t, pointee_t>::value
3018 or std::is_same<array_t, pointee_t>::value
3019 or std::is_same<string_t, pointee_t>::value
3020 or std::is_same<boolean_t, pointee_t>::value
3021 or std::is_same<number_integer_t, pointee_t>::value
3022 or std::is_same<number_unsigned_t, pointee_t>::value
3023 or std::is_same<number_float_t, pointee_t>::value
3024 , "incompatible pointer type");
3025
3026 // delegate the call to get_impl_ptr<>() const
3027 return get_impl_ptr(static_cast<const PointerType>(nullptr));
3028 }
3029
3030 /*!
3031 @brief get a reference value (implicit)
3032
3033 Implict reference access to the internally stored JSON value. No copies
3034 are made.
3035
3036 @warning Writing data to the referee of the result yields an undefined
3037 state.
3038
3039 @tparam ReferenceType reference type; must be a reference to @ref array_t,
3040 @ref object_t, @ref string_t, @ref boolean_t, @ref number_integer_t, or
3041 @ref number_float_t. Enforced by static assertion.
3042
3043 @return reference to the internally stored JSON value if the requested
3044 reference type @a ReferenceType fits to the JSON value; throws
3045 std::domain_error otherwise
3046
3047 @throw std::domain_error in case passed type @a ReferenceType is
3048 incompatible with the stored JSON value
3049
3050 @complexity Constant.
3051
3052 @liveexample{The example shows several calls to `get_ref()`.,get_ref}
3053
3054 @since version 1.1.0
3055 */
3056 template<typename ReferenceType, typename std::enable_if<
3057 std::is_reference<ReferenceType>::value, int>::type = 0>
3058 ReferenceType get_ref()
3059 {
3060 // delegate call to get_ref_impl
3061 return get_ref_impl<ReferenceType>(*this);
3062 }
3063
3064 /*!
3065 @brief get a reference value (implicit)
3066 @copydoc get_ref()
3067 */
3068 template<typename ReferenceType, typename std::enable_if<
3069 std::is_reference<ReferenceType>::value and
3070 std::is_const<typename std::remove_reference<ReferenceType>::type>::value, int>::type = 0>
3071 ReferenceType get_ref() const
3072 {
3073 // delegate call to get_ref_impl
3074 return get_ref_impl<ReferenceType>(*this);
3075 }
3076
3077 /*!
3078 @brief get a value (implicit)
3079
3080 Implicit type conversion between the JSON value and a compatible value.
3081 The call is realized by calling @ref get() const.
3082
3083 @tparam ValueType non-pointer type compatible to the JSON value, for
3084 instance `int` for JSON integer numbers, `bool` for JSON booleans, or
3085 `std::vector` types for JSON arrays. The character type of @ref string_t
3086 as well as an initializer list of this type is excluded to avoid
3087 ambiguities as these types implicitly convert to `std::string`.
3088
3089 @return copy of the JSON value, converted to type @a ValueType
3090
3091 @throw std::domain_error in case passed type @a ValueType is incompatible
3092 to JSON, thrown by @ref get() const
3093
3094 @complexity Linear in the size of the JSON value.
3095
3096 @liveexample{The example below shows several conversions from JSON values
3097 to other types. There a few things to note: (1) Floating-point numbers can
3098 be converted to integers\, (2) A JSON array can be converted to a standard
3099 `std::vector<short>`\, (3) A JSON object can be converted to C++
3100 associative containers such as `std::unordered_map<std::string\,
3101 json>`.,operator__ValueType}
3102
3103 @since version 1.0.0
3104 */
3105 template < typename ValueType, typename std::enable_if <
3106 not std::is_pointer<ValueType>::value and
3107 not std::is_same<ValueType, typename string_t::value_type>::value
3108#ifndef _MSC_VER // Fix for issue #167 operator<< abiguity under VS2015
3109 and not std::is_same<ValueType, std::initializer_list<typename string_t::value_type>>::value
3110#endif
3111 , int >::type = 0 >
3112 operator ValueType() const
3113 {
3114 // delegate the call to get<>() const
3115 return get<ValueType>();
3116 }
3117
3118 /// @}
3119
3120
3121 ////////////////////
3122 // element access //
3123 ////////////////////
3124
3125 /// @name element access
3126 /// Access to the JSON value.
3127 /// @{
3128
3129 /*!
3130 @brief access specified array element with bounds checking
3131
3132 Returns a reference to the element at specified location @a idx, with
3133 bounds checking.
3134
3135 @param[in] idx index of the element to access
3136
3137 @return reference to the element at index @a idx
3138
3139 @throw std::domain_error if the JSON value is not an array; example:
3140 `"cannot use at() with string"`
3141 @throw std::out_of_range if the index @a idx is out of range of the array;
3142 that is, `idx >= size()`; example: `"array index 7 is out of range"`
3143
3144 @complexity Constant.
3145
3146 @liveexample{The example below shows how array elements can be read and
3147 written using `at()`.,at__size_type}
3148
3149 @since version 1.0.0
3150 */
3151 reference at(size_type idx)
3152 {
3153 // at only works for arrays
3154 if (is_array())
3155 {
3156 try
3157 {
3158 return m_value.array->at(idx);
3159 }
3160 catch (std::out_of_range&)
3161 {
3162 // create better exception explanation
3163 throw std::out_of_range("array index " + std::to_string(idx) + " is out of range");
3164 }
3165 }
3166 else
3167 {
3168 throw std::domain_error("cannot use at() with " + type_name());
3169 }
3170 }
3171
3172 /*!
3173 @brief access specified array element with bounds checking
3174
3175 Returns a const reference to the element at specified location @a idx,
3176 with bounds checking.
3177
3178 @param[in] idx index of the element to access
3179
3180 @return const reference to the element at index @a idx
3181
3182 @throw std::domain_error if the JSON value is not an array; example:
3183 `"cannot use at() with string"`
3184 @throw std::out_of_range if the index @a idx is out of range of the array;
3185 that is, `idx >= size()`; example: `"array index 7 is out of range"`
3186
3187 @complexity Constant.
3188
3189 @liveexample{The example below shows how array elements can be read using
3190 `at()`.,at__size_type_const}
3191
3192 @since version 1.0.0
3193 */
3194 const_reference at(size_type idx) const
3195 {
3196 // at only works for arrays
3197 if (is_array())
3198 {
3199 try
3200 {
3201 return m_value.array->at(idx);
3202 }
3203 catch (std::out_of_range&)
3204 {
3205 // create better exception explanation
3206 throw std::out_of_range("array index " + std::to_string(idx) + " is out of range");
3207 }
3208 }
3209 else
3210 {
3211 throw std::domain_error("cannot use at() with " + type_name());
3212 }
3213 }
3214
3215 /*!
3216 @brief access specified object element with bounds checking
3217
3218 Returns a reference to the element at with specified key @a key, with
3219 bounds checking.
3220
3221 @param[in] key key of the element to access
3222
3223 @return reference to the element at key @a key
3224
3225 @throw std::domain_error if the JSON value is not an object; example:
3226 `"cannot use at() with boolean"`
3227 @throw std::out_of_range if the key @a key is is not stored in the object;
3228 that is, `find(key) == end()`; example: `"key "the fast" not found"`
3229
3230 @complexity Logarithmic in the size of the container.
3231
3232 @liveexample{The example below shows how object elements can be read and
3233 written using `at()`.,at__object_t_key_type}
3234
3235 @sa @ref operator[](const typename object_t::key_type&) for unchecked
3236 access by reference
3237 @sa @ref value() for access by value with a default value
3238
3239 @since version 1.0.0
3240 */
3241 reference at(const typename object_t::key_type& key)
3242 {
3243 // at only works for objects
3244 if (is_object())
3245 {
3246 try
3247 {
3248 return m_value.object->at(key);
3249 }
3250 catch (std::out_of_range&)
3251 {
3252 // create better exception explanation
3253 throw std::out_of_range("key '" + key + "' not found");
3254 }
3255 }
3256 else
3257 {
3258 throw std::domain_error("cannot use at() with " + type_name());
3259 }
3260 }
3261
3262 /*!
3263 @brief access specified object element with bounds checking
3264
3265 Returns a const reference to the element at with specified key @a key,
3266 with bounds checking.
3267
3268 @param[in] key key of the element to access
3269
3270 @return const reference to the element at key @a key
3271
3272 @throw std::domain_error if the JSON value is not an object; example:
3273 `"cannot use at() with boolean"`
3274 @throw std::out_of_range if the key @a key is is not stored in the object;
3275 that is, `find(key) == end()`; example: `"key "the fast" not found"`
3276
3277 @complexity Logarithmic in the size of the container.
3278
3279 @liveexample{The example below shows how object elements can be read using
3280 `at()`.,at__object_t_key_type_const}
3281
3282 @sa @ref operator[](const typename object_t::key_type&) for unchecked
3283 access by reference
3284 @sa @ref value() for access by value with a default value
3285
3286 @since version 1.0.0
3287 */
3288 const_reference at(const typename object_t::key_type& key) const
3289 {
3290 // at only works for objects
3291 if (is_object())
3292 {
3293 try
3294 {
3295 return m_value.object->at(key);
3296 }
3297 catch (std::out_of_range&)
3298 {
3299 // create better exception explanation
3300 throw std::out_of_range("key '" + key + "' not found");
3301 }
3302 }
3303 else
3304 {
3305 throw std::domain_error("cannot use at() with " + type_name());
3306 }
3307 }
3308
3309 /*!
3310 @brief access specified array element
3311
3312 Returns a reference to the element at specified location @a idx.
3313
3314 @note If @a idx is beyond the range of the array (i.e., `idx >= size()`),
3315 then the array is silently filled up with `null` values to make `idx` a
3316 valid reference to the last stored element.
3317
3318 @param[in] idx index of the element to access
3319
3320 @return reference to the element at index @a idx
3321
3322 @throw std::domain_error if JSON is not an array or null; example:
3323 `"cannot use operator[] with string"`
3324
3325 @complexity Constant if @a idx is in the range of the array. Otherwise
3326 linear in `idx - size()`.
3327
3328 @liveexample{The example below shows how array elements can be read and
3329 written using `[]` operator. Note the addition of `null`
3330 values.,operatorarray__size_type}
3331
3332 @since version 1.0.0
3333 */
3334 reference operator[](size_type idx)
3335 {
3336 // implicitly convert null value to an empty array
3337 if (is_null())
3338 {
3339 m_type = value_t::array;
3340 m_value.array = create<array_t>();
3341 assert_invariant();
3342 }
3343
3344 // operator[] only works for arrays
3345 if (is_array())
3346 {
3347 // fill up array with null values if given idx is outside range
3348 if (idx >= m_value.array->size())
3349 {
3350 m_value.array->insert(m_value.array->end(),
3351 idx - m_value.array->size() + 1,
3352 basic_json());
3353 }
3354
3355 return m_value.array->operator[](idx);
3356 }
3357 else
3358 {
3359 throw std::domain_error("cannot use operator[] with " + type_name());
3360 }
3361 }
3362
3363 /*!
3364 @brief access specified array element
3365
3366 Returns a const reference to the element at specified location @a idx.
3367
3368 @param[in] idx index of the element to access
3369
3370 @return const reference to the element at index @a idx
3371
3372 @throw std::domain_error if JSON is not an array; example: `"cannot use
3373 operator[] with null"`
3374
3375 @complexity Constant.
3376
3377 @liveexample{The example below shows how array elements can be read using
3378 the `[]` operator.,operatorarray__size_type_const}
3379
3380 @since version 1.0.0
3381 */
3382 const_reference operator[](size_type idx) const
3383 {
3384 // const operator[] only works for arrays
3385 if (is_array())
3386 {
3387 return m_value.array->operator[](idx);
3388 }
3389 else
3390 {
3391 throw std::domain_error("cannot use operator[] with " + type_name());
3392 }
3393 }
3394
3395 /*!
3396 @brief access specified object element
3397
3398 Returns a reference to the element at with specified key @a key.
3399
3400 @note If @a key is not found in the object, then it is silently added to
3401 the object and filled with a `null` value to make `key` a valid reference.
3402 In case the value was `null` before, it is converted to an object.
3403
3404 @param[in] key key of the element to access
3405
3406 @return reference to the element at key @a key
3407
3408 @throw std::domain_error if JSON is not an object or null; example:
3409 `"cannot use operator[] with string"`
3410
3411 @complexity Logarithmic in the size of the container.
3412
3413 @liveexample{The example below shows how object elements can be read and
3414 written using the `[]` operator.,operatorarray__key_type}
3415
3416 @sa @ref at(const typename object_t::key_type&) for access by reference
3417 with range checking
3418 @sa @ref value() for access by value with a default value
3419
3420 @since version 1.0.0
3421 */
3422 reference operator[](const typename object_t::key_type& key)
3423 {
3424 // implicitly convert null value to an empty object
3425 if (is_null())
3426 {
3427 m_type = value_t::object;
3428 m_value.object = create<object_t>();
3429 assert_invariant();
3430 }
3431
3432 // operator[] only works for objects
3433 if (is_object())
3434 {
3435 return m_value.object->operator[](key);
3436 }
3437 else
3438 {
3439 throw std::domain_error("cannot use operator[] with " + type_name());
3440 }
3441 }
3442
3443 /*!
3444 @brief read-only access specified object element
3445
3446 Returns a const reference to the element at with specified key @a key. No
3447 bounds checking is performed.
3448
3449 @warning If the element with key @a key does not exist, the behavior is
3450 undefined.
3451
3452 @param[in] key key of the element to access
3453
3454 @return const reference to the element at key @a key
3455
3456 @pre The element with key @a key must exist. **This precondition is
3457 enforced with an assertion.**
3458
3459 @throw std::domain_error if JSON is not an object; example: `"cannot use
3460 operator[] with null"`
3461
3462 @complexity Logarithmic in the size of the container.
3463
3464 @liveexample{The example below shows how object elements can be read using
3465 the `[]` operator.,operatorarray__key_type_const}
3466
3467 @sa @ref at(const typename object_t::key_type&) for access by reference
3468 with range checking
3469 @sa @ref value() for access by value with a default value
3470
3471 @since version 1.0.0
3472 */
3473 const_reference operator[](const typename object_t::key_type& key) const
3474 {
3475 // const operator[] only works for objects
3476 if (is_object())
3477 {
3478 assert(m_value.object->find(key) != m_value.object->end());
3479 return m_value.object->find(key)->second;
3480 }
3481 else
3482 {
3483 throw std::domain_error("cannot use operator[] with " + type_name());
3484 }
3485 }
3486
3487 /*!
3488 @brief access specified object element
3489
3490 Returns a reference to the element at with specified key @a key.
3491
3492 @note If @a key is not found in the object, then it is silently added to
3493 the object and filled with a `null` value to make `key` a valid reference.
3494 In case the value was `null` before, it is converted to an object.
3495
3496 @param[in] key key of the element to access
3497
3498 @return reference to the element at key @a key
3499
3500 @throw std::domain_error if JSON is not an object or null; example:
3501 `"cannot use operator[] with string"`
3502
3503 @complexity Logarithmic in the size of the container.
3504
3505 @liveexample{The example below shows how object elements can be read and
3506 written using the `[]` operator.,operatorarray__key_type}
3507
3508 @sa @ref at(const typename object_t::key_type&) for access by reference
3509 with range checking
3510 @sa @ref value() for access by value with a default value
3511
3512 @since version 1.0.0
3513 */
3514 template<typename T, std::size_t n>
3515 reference operator[](T * (&key)[n])
3516 {
3517 return operator[](static_cast<const T>(key));
3518 }
3519
3520 /*!
3521 @brief read-only access specified object element
3522
3523 Returns a const reference to the element at with specified key @a key. No
3524 bounds checking is performed.
3525
3526 @warning If the element with key @a key does not exist, the behavior is
3527 undefined.
3528
3529 @note This function is required for compatibility reasons with Clang.
3530
3531 @param[in] key key of the element to access
3532
3533 @return const reference to the element at key @a key
3534
3535 @throw std::domain_error if JSON is not an object; example: `"cannot use
3536 operator[] with null"`
3537
3538 @complexity Logarithmic in the size of the container.
3539
3540 @liveexample{The example below shows how object elements can be read using
3541 the `[]` operator.,operatorarray__key_type_const}
3542
3543 @sa @ref at(const typename object_t::key_type&) for access by reference
3544 with range checking
3545 @sa @ref value() for access by value with a default value
3546
3547 @since version 1.0.0
3548 */
3549 template<typename T, std::size_t n>
3550 const_reference operator[](T * (&key)[n]) const
3551 {
3552 return operator[](static_cast<const T>(key));
3553 }
3554
3555 /*!
3556 @brief access specified object element
3557
3558 Returns a reference to the element at with specified key @a key.
3559
3560 @note If @a key is not found in the object, then it is silently added to
3561 the object and filled with a `null` value to make `key` a valid reference.
3562 In case the value was `null` before, it is converted to an object.
3563
3564 @param[in] key key of the element to access
3565
3566 @return reference to the element at key @a key
3567
3568 @throw std::domain_error if JSON is not an object or null; example:
3569 `"cannot use operator[] with string"`
3570
3571 @complexity Logarithmic in the size of the container.
3572
3573 @liveexample{The example below shows how object elements can be read and
3574 written using the `[]` operator.,operatorarray__key_type}
3575
3576 @sa @ref at(const typename object_t::key_type&) for access by reference
3577 with range checking
3578 @sa @ref value() for access by value with a default value
3579
3580 @since version 1.1.0
3581 */
3582 template<typename T>
3583 reference operator[](T* key)
3584 {
3585 // implicitly convert null to object
3586 if (is_null())
3587 {
3588 m_type = value_t::object;
3589 m_value = value_t::object;
3590 assert_invariant();
3591 }
3592
3593 // at only works for objects
3594 if (is_object())
3595 {
3596 return m_value.object->operator[](key);
3597 }
3598 else
3599 {
3600 throw std::domain_error("cannot use operator[] with " + type_name());
3601 }
3602 }
3603
3604 /*!
3605 @brief read-only access specified object element
3606
3607 Returns a const reference to the element at with specified key @a key. No
3608 bounds checking is performed.
3609
3610 @warning If the element with key @a key does not exist, the behavior is
3611 undefined.
3612
3613 @param[in] key key of the element to access
3614
3615 @return const reference to the element at key @a key
3616
3617 @pre The element with key @a key must exist. **This precondition is
3618 enforced with an assertion.**
3619
3620 @throw std::domain_error if JSON is not an object; example: `"cannot use
3621 operator[] with null"`
3622
3623 @complexity Logarithmic in the size of the container.
3624
3625 @liveexample{The example below shows how object elements can be read using
3626 the `[]` operator.,operatorarray__key_type_const}
3627
3628 @sa @ref at(const typename object_t::key_type&) for access by reference
3629 with range checking
3630 @sa @ref value() for access by value with a default value
3631
3632 @since version 1.1.0
3633 */
3634 template<typename T>
3635 const_reference operator[](T* key) const
3636 {
3637 // at only works for objects
3638 if (is_object())
3639 {
3640 assert(m_value.object->find(key) != m_value.object->end());
3641 return m_value.object->find(key)->second;
3642 }
3643 else
3644 {
3645 throw std::domain_error("cannot use operator[] with " + type_name());
3646 }
3647 }
3648
3649 /*!
3650 @brief access specified object element with default value
3651
3652 Returns either a copy of an object's element at the specified key @a key
3653 or a given default value if no element with key @a key exists.
3654
3655 The function is basically equivalent to executing
3656 @code {.cpp}
3657 try {
3658 return at(key);
3659 } catch(std::out_of_range) {
3660 return default_value;
3661 }
3662 @endcode
3663
3664 @note Unlike @ref at(const typename object_t::key_type&), this function
3665 does not throw if the given key @a key was not found.
3666
3667 @note Unlike @ref operator[](const typename object_t::key_type& key), this
3668 function does not implicitly add an element to the position defined by @a
3669 key. This function is furthermore also applicable to const objects.
3670
3671 @param[in] key key of the element to access
3672 @param[in] default_value the value to return if @a key is not found
3673
3674 @tparam ValueType type compatible to JSON values, for instance `int` for
3675 JSON integer numbers, `bool` for JSON booleans, or `std::vector` types for
3676 JSON arrays. Note the type of the expected value at @a key and the default
3677 value @a default_value must be compatible.
3678
3679 @return copy of the element at key @a key or @a default_value if @a key
3680 is not found
3681
3682 @throw std::domain_error if JSON is not an object; example: `"cannot use
3683 value() with null"`
3684
3685 @complexity Logarithmic in the size of the container.
3686
3687 @liveexample{The example below shows how object elements can be queried
3688 with a default value.,basic_json__value}
3689
3690 @sa @ref at(const typename object_t::key_type&) for access by reference
3691 with range checking
3692 @sa @ref operator[](const typename object_t::key_type&) for unchecked
3693 access by reference
3694
3695 @since version 1.0.0
3696 */
3697 template<class ValueType, typename std::enable_if<
3698 std::is_convertible<basic_json_t, ValueType>::value, int>::type = 0>
3699 ValueType value(const typename object_t::key_type& key, ValueType default_value) const
3700 {
3701 // at only works for objects
3702 if (is_object())
3703 {
3704 // if key is found, return value and given default value otherwise
3705 const auto it = find(key);
3706 if (it != end())
3707 {
3708 return *it;
3709 }
3710 else
3711 {
3712 return default_value;
3713 }
3714 }
3715 else
3716 {
3717 throw std::domain_error("cannot use value() with " + type_name());
3718 }
3719 }
3720
3721 /*!
3722 @brief overload for a default value of type const char*
3723 @copydoc basic_json::value(const typename object_t::key_type&, ValueType) const
3724 */
3725 string_t value(const typename object_t::key_type& key, const char* default_value) const
3726 {
3727 return value(key, string_t(default_value));
3728 }
3729
3730 /*!
3731 @brief access specified object element via JSON Pointer with default value
3732
3733 Returns either a copy of an object's element at the specified key @a key
3734 or a given default value if no element with key @a key exists.
3735
3736 The function is basically equivalent to executing
3737 @code {.cpp}
3738 try {
3739 return at(ptr);
3740 } catch(std::out_of_range) {
3741 return default_value;
3742 }
3743 @endcode
3744
3745 @note Unlike @ref at(const json_pointer&), this function does not throw
3746 if the given key @a key was not found.
3747
3748 @param[in] ptr a JSON pointer to the element to access
3749 @param[in] default_value the value to return if @a ptr found no value
3750
3751 @tparam ValueType type compatible to JSON values, for instance `int` for
3752 JSON integer numbers, `bool` for JSON booleans, or `std::vector` types for
3753 JSON arrays. Note the type of the expected value at @a key and the default
3754 value @a default_value must be compatible.
3755
3756 @return copy of the element at key @a key or @a default_value if @a key
3757 is not found
3758
3759 @throw std::domain_error if JSON is not an object; example: `"cannot use
3760 value() with null"`
3761
3762 @complexity Logarithmic in the size of the container.
3763
3764 @liveexample{The example below shows how object elements can be queried
3765 with a default value.,basic_json__value_ptr}
3766
3767 @sa @ref operator[](const json_pointer&) for unchecked access by reference
3768
3769 @since version 2.0.2
3770 */
3771 template<class ValueType, typename std::enable_if<
3772 std::is_convertible<basic_json_t, ValueType>::value, int>::type = 0>
3773 ValueType value(const json_pointer& ptr, ValueType default_value) const
3774 {
3775 // at only works for objects
3776 if (is_object())
3777 {
3778 // if pointer resolves a value, return it or use default value
3779 try
3780 {
3781 return ptr.get_checked(this);
3782 }
3783 catch (std::out_of_range&)
3784 {
3785 return default_value;
3786 }
3787 }
3788 else
3789 {
3790 throw std::domain_error("cannot use value() with " + type_name());
3791 }
3792 }
3793
3794 /*!
3795 @brief overload for a default value of type const char*
3796 @copydoc basic_json::value(const json_pointer&, ValueType) const
3797 */
3798 string_t value(const json_pointer& ptr, const char* default_value) const
3799 {
3800 return value(ptr, string_t(default_value));
3801 }
3802
3803 /*!
3804 @brief access the first element
3805
3806 Returns a reference to the first element in the container. For a JSON
3807 container `c`, the expression `c.front()` is equivalent to `*c.begin()`.
3808
3809 @return In case of a structured type (array or object), a reference to the
3810 first element is returned. In cast of number, string, or boolean values, a
3811 reference to the value is returned.
3812
3813 @complexity Constant.
3814
3815 @pre The JSON value must not be `null` (would throw `std::out_of_range`)
3816 or an empty array or object (undefined behavior, **guarded by
3817 assertions**).
3818 @post The JSON value remains unchanged.
3819
3820 @throw std::out_of_range when called on `null` value
3821
3822 @liveexample{The following code shows an example for `front()`.,front}
3823
3824 @sa @ref back() -- access the last element
3825
3826 @since version 1.0.0
3827 */
3828 reference front()
3829 {
3830 return *begin();
3831 }
3832
3833 /*!
3834 @copydoc basic_json::front()
3835 */
3836 const_reference front() const
3837 {
3838 return *cbegin();
3839 }
3840
3841 /*!
3842 @brief access the last element
3843
3844 Returns a reference to the last element in the container. For a JSON
3845 container `c`, the expression `c.back()` is equivalent to
3846 @code {.cpp}
3847 auto tmp = c.end();
3848 --tmp;
3849 return *tmp;
3850 @endcode
3851
3852 @return In case of a structured type (array or object), a reference to the
3853 last element is returned. In cast of number, string, or boolean values, a
3854 reference to the value is returned.
3855
3856 @complexity Constant.
3857
3858 @pre The JSON value must not be `null` (would throw `std::out_of_range`)
3859 or an empty array or object (undefined behavior, **guarded by
3860 assertions**).
3861 @post The JSON value remains unchanged.
3862
3863 @throw std::out_of_range when called on `null` value.
3864
3865 @liveexample{The following code shows an example for `back()`.,back}
3866
3867 @sa @ref front() -- access the first element
3868
3869 @since version 1.0.0
3870 */
3871 reference back()
3872 {
3873 auto tmp = end();
3874 --tmp;
3875 return *tmp;
3876 }
3877
3878 /*!
3879 @copydoc basic_json::back()
3880 */
3881 const_reference back() const
3882 {
3883 auto tmp = cend();
3884 --tmp;
3885 return *tmp;
3886 }
3887
3888 /*!
3889 @brief remove element given an iterator
3890
3891 Removes the element specified by iterator @a pos. The iterator @a pos must
3892 be valid and dereferenceable. Thus the `end()` iterator (which is valid,
3893 but is not dereferenceable) cannot be used as a value for @a pos.
3894
3895 If called on a primitive type other than `null`, the resulting JSON value
3896 will be `null`.
3897
3898 @param[in] pos iterator to the element to remove
3899 @return Iterator following the last removed element. If the iterator @a
3900 pos refers to the last element, the `end()` iterator is returned.
3901
3902 @tparam IteratorType an @ref iterator or @ref const_iterator
3903
3904 @post Invalidates iterators and references at or after the point of the
3905 erase, including the `end()` iterator.
3906
3907 @throw std::domain_error if called on a `null` value; example: `"cannot
3908 use erase() with null"`
3909 @throw std::domain_error if called on an iterator which does not belong to
3910 the current JSON value; example: `"iterator does not fit current value"`
3911 @throw std::out_of_range if called on a primitive type with invalid
3912 iterator (i.e., any iterator which is not `begin()`); example: `"iterator
3913 out of range"`
3914
3915 @complexity The complexity depends on the type:
3916 - objects: amortized constant
3917 - arrays: linear in distance between pos and the end of the container
3918 - strings: linear in the length of the string
3919 - other types: constant
3920
3921 @liveexample{The example shows the result of `erase()` for different JSON
3922 types.,erase__IteratorType}
3923
3924 @sa @ref erase(IteratorType, IteratorType) -- removes the elements in
3925 the given range
3926 @sa @ref erase(const typename object_t::key_type&) -- removes the element
3927 from an object at the given key
3928 @sa @ref erase(const size_type) -- removes the element from an array at
3929 the given index
3930
3931 @since version 1.0.0
3932 */
3933 template<class IteratorType, typename std::enable_if<
3934 std::is_same<IteratorType, typename basic_json_t::iterator>::value or
3935 std::is_same<IteratorType, typename basic_json_t::const_iterator>::value, int>::type
3936 = 0>
3937 IteratorType erase(IteratorType pos)
3938 {
3939 // make sure iterator fits the current value
3940 if (this != pos.m_object)
3941 {
3942 throw std::domain_error("iterator does not fit current value");
3943 }
3944
3945 IteratorType result = end();
3946
3947 switch (m_type)
3948 {
3949 case value_t::boolean:
3950 case value_t::number_float:
3951 case value_t::number_integer:
3952 case value_t::number_unsigned:
3953 case value_t::string:
3954 {
3955 if (not pos.m_it.primitive_iterator.is_begin())
3956 {
3957 throw std::out_of_range("iterator out of range");
3958 }
3959
3960 if (is_string())
3961 {
3962 AllocatorType<string_t> alloc;
3963 alloc.destroy(m_value.string);
3964 alloc.deallocate(m_value.string, 1);
3965 m_value.string = nullptr;
3966 }
3967
3968 m_type = value_t::null;
3969 assert_invariant();
3970 break;
3971 }
3972
3973 case value_t::object:
3974 {
3975 result.m_it.object_iterator = m_value.object->erase(pos.m_it.object_iterator);
3976 break;
3977 }
3978
3979 case value_t::array:
3980 {
3981 result.m_it.array_iterator = m_value.array->erase(pos.m_it.array_iterator);
3982 break;
3983 }
3984
3985 default:
3986 {
3987 throw std::domain_error("cannot use erase() with " + type_name());
3988 }
3989 }
3990
3991 return result;
3992 }
3993
3994 /*!
3995 @brief remove elements given an iterator range
3996
3997 Removes the element specified by the range `[first; last)`. The iterator
3998 @a first does not need to be dereferenceable if `first == last`: erasing
3999 an empty range is a no-op.
4000
4001 If called on a primitive type other than `null`, the resulting JSON value
4002 will be `null`.
4003
4004 @param[in] first iterator to the beginning of the range to remove
4005 @param[in] last iterator past the end of the range to remove
4006 @return Iterator following the last removed element. If the iterator @a
4007 second refers to the last element, the `end()` iterator is returned.
4008
4009 @tparam IteratorType an @ref iterator or @ref const_iterator
4010
4011 @post Invalidates iterators and references at or after the point of the
4012 erase, including the `end()` iterator.
4013
4014 @throw std::domain_error if called on a `null` value; example: `"cannot
4015 use erase() with null"`
4016 @throw std::domain_error if called on iterators which does not belong to
4017 the current JSON value; example: `"iterators do not fit current value"`
4018 @throw std::out_of_range if called on a primitive type with invalid
4019 iterators (i.e., if `first != begin()` and `last != end()`); example:
4020 `"iterators out of range"`
4021
4022 @complexity The complexity depends on the type:
4023 - objects: `log(size()) + std::distance(first, last)`
4024 - arrays: linear in the distance between @a first and @a last, plus linear
4025 in the distance between @a last and end of the container
4026 - strings: linear in the length of the string
4027 - other types: constant
4028
4029 @liveexample{The example shows the result of `erase()` for different JSON
4030 types.,erase__IteratorType_IteratorType}
4031
4032 @sa @ref erase(IteratorType) -- removes the element at a given position
4033 @sa @ref erase(const typename object_t::key_type&) -- removes the element
4034 from an object at the given key
4035 @sa @ref erase(const size_type) -- removes the element from an array at
4036 the given index
4037
4038 @since version 1.0.0
4039 */
4040 template<class IteratorType, typename std::enable_if<
4041 std::is_same<IteratorType, typename basic_json_t::iterator>::value or
4042 std::is_same<IteratorType, typename basic_json_t::const_iterator>::value, int>::type
4043 = 0>
4044 IteratorType erase(IteratorType first, IteratorType last)
4045 {
4046 // make sure iterator fits the current value
4047 if (this != first.m_object or this != last.m_object)
4048 {
4049 throw std::domain_error("iterators do not fit current value");
4050 }
4051
4052 IteratorType result = end();
4053
4054 switch (m_type)
4055 {
4056 case value_t::boolean:
4057 case value_t::number_float:
4058 case value_t::number_integer:
4059 case value_t::number_unsigned:
4060 case value_t::string:
4061 {
4062 if (not first.m_it.primitive_iterator.is_begin() or not last.m_it.primitive_iterator.is_end())
4063 {
4064 throw std::out_of_range("iterators out of range");
4065 }
4066
4067 if (is_string())
4068 {
4069 AllocatorType<string_t> alloc;
4070 alloc.destroy(m_value.string);
4071 alloc.deallocate(m_value.string, 1);
4072 m_value.string = nullptr;
4073 }
4074
4075 m_type = value_t::null;
4076 assert_invariant();
4077 break;
4078 }
4079
4080 case value_t::object:
4081 {
4082 result.m_it.object_iterator = m_value.object->erase(first.m_it.object_iterator,
4083 last.m_it.object_iterator);
4084 break;
4085 }
4086
4087 case value_t::array:
4088 {
4089 result.m_it.array_iterator = m_value.array->erase(first.m_it.array_iterator,
4090 last.m_it.array_iterator);
4091 break;
4092 }
4093
4094 default:
4095 {
4096 throw std::domain_error("cannot use erase() with " + type_name());
4097 }
4098 }
4099
4100 return result;
4101 }
4102
4103 /*!
4104 @brief remove element from a JSON object given a key
4105
4106 Removes elements from a JSON object with the key value @a key.
4107
4108 @param[in] key value of the elements to remove
4109
4110 @return Number of elements removed. If @a ObjectType is the default
4111 `std::map` type, the return value will always be `0` (@a key was not
4112 found) or `1` (@a key was found).
4113
4114 @post References and iterators to the erased elements are invalidated.
4115 Other references and iterators are not affected.
4116
4117 @throw std::domain_error when called on a type other than JSON object;
4118 example: `"cannot use erase() with null"`
4119
4120 @complexity `log(size()) + count(key)`
4121
4122 @liveexample{The example shows the effect of `erase()`.,erase__key_type}
4123
4124 @sa @ref erase(IteratorType) -- removes the element at a given position
4125 @sa @ref erase(IteratorType, IteratorType) -- removes the elements in
4126 the given range
4127 @sa @ref erase(const size_type) -- removes the element from an array at
4128 the given index
4129
4130 @since version 1.0.0
4131 */
4132 size_type erase(const typename object_t::key_type& key)
4133 {
4134 // this erase only works for objects
4135 if (is_object())
4136 {
4137 return m_value.object->erase(key);
4138 }
4139 else
4140 {
4141 throw std::domain_error("cannot use erase() with " + type_name());
4142 }
4143 }
4144
4145 /*!
4146 @brief remove element from a JSON array given an index
4147
4148 Removes element from a JSON array at the index @a idx.
4149
4150 @param[in] idx index of the element to remove
4151
4152 @throw std::domain_error when called on a type other than JSON array;
4153 example: `"cannot use erase() with null"`
4154 @throw std::out_of_range when `idx >= size()`; example: `"array index 17
4155 is out of range"`
4156
4157 @complexity Linear in distance between @a idx and the end of the container.
4158
4159 @liveexample{The example shows the effect of `erase()`.,erase__size_type}
4160
4161 @sa @ref erase(IteratorType) -- removes the element at a given position
4162 @sa @ref erase(IteratorType, IteratorType) -- removes the elements in
4163 the given range
4164 @sa @ref erase(const typename object_t::key_type&) -- removes the element
4165 from an object at the given key
4166
4167 @since version 1.0.0
4168 */
4169 void erase(const size_type idx)
4170 {
4171 // this erase only works for arrays
4172 if (is_array())
4173 {
4174 if (idx >= size())
4175 {
4176 throw std::out_of_range("array index " + std::to_string(idx) + " is out of range");
4177 }
4178
4179 m_value.array->erase(m_value.array->begin() + static_cast<difference_type>(idx));
4180 }
4181 else
4182 {
4183 throw std::domain_error("cannot use erase() with " + type_name());
4184 }
4185 }
4186
4187 /// @}
4188
4189
4190 ////////////
4191 // lookup //
4192 ////////////
4193
4194 /// @name lookup
4195 /// @{
4196
4197 /*!
4198 @brief find an element in a JSON object
4199
4200 Finds an element in a JSON object with key equivalent to @a key. If the
4201 element is not found or the JSON value is not an object, end() is
4202 returned.
4203
4204 @param[in] key key value of the element to search for
4205
4206 @return Iterator to an element with key equivalent to @a key. If no such
4207 element is found, past-the-end (see end()) iterator is returned.
4208
4209 @complexity Logarithmic in the size of the JSON object.
4210
4211 @liveexample{The example shows how `find()` is used.,find__key_type}
4212
4213 @since version 1.0.0
4214 */
4215 iterator find(typename object_t::key_type key)
4216 {
4217 auto result = end();
4218
4219 if (is_object())
4220 {
4221 result.m_it.object_iterator = m_value.object->find(key);
4222 }
4223
4224 return result;
4225 }
4226
4227 /*!
4228 @brief find an element in a JSON object
4229 @copydoc find(typename object_t::key_type)
4230 */
4231 const_iterator find(typename object_t::key_type key) const
4232 {
4233 auto result = cend();
4234
4235 if (is_object())
4236 {
4237 result.m_it.object_iterator = m_value.object->find(key);
4238 }
4239
4240 return result;
4241 }
4242
4243 /*!
4244 @brief returns the number of occurrences of a key in a JSON object
4245
4246 Returns the number of elements with key @a key. If ObjectType is the
4247 default `std::map` type, the return value will always be `0` (@a key was
4248 not found) or `1` (@a key was found).
4249
4250 @param[in] key key value of the element to count
4251
4252 @return Number of elements with key @a key. If the JSON value is not an
4253 object, the return value will be `0`.
4254
4255 @complexity Logarithmic in the size of the JSON object.
4256
4257 @liveexample{The example shows how `count()` is used.,count}
4258
4259 @since version 1.0.0
4260 */
4261 size_type count(typename object_t::key_type key) const
4262 {
4263 // return 0 for all nonobject types
4264 return is_object() ? m_value.object->count(key) : 0;
4265 }
4266
4267 /// @}
4268
4269
4270 ///////////////
4271 // iterators //
4272 ///////////////
4273
4274 /// @name iterators
4275 /// @{
4276
4277 /*!
4278 @brief returns an iterator to the first element
4279
4280 Returns an iterator to the first element.
4281
4282 @image html range-begin-end.svg "Illustration from cppreference.com"
4283
4284 @return iterator to the first element
4285
4286 @complexity Constant.
4287
4288 @requirement This function helps `basic_json` satisfying the
4289 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4290 requirements:
4291 - The complexity is constant.
4292
4293 @liveexample{The following code shows an example for `begin()`.,begin}
4294
4295 @sa @ref cbegin() -- returns a const iterator to the beginning
4296 @sa @ref end() -- returns an iterator to the end
4297 @sa @ref cend() -- returns a const iterator to the end
4298
4299 @since version 1.0.0
4300 */
4301 iterator begin() noexcept
4302 {
4303 iterator result(this);
4304 result.set_begin();
4305 return result;
4306 }
4307
4308 /*!
4309 @copydoc basic_json::cbegin()
4310 */
4311 const_iterator begin() const noexcept
4312 {
4313 return cbegin();
4314 }
4315
4316 /*!
4317 @brief returns a const iterator to the first element
4318
4319 Returns a const iterator to the first element.
4320
4321 @image html range-begin-end.svg "Illustration from cppreference.com"
4322
4323 @return const iterator to the first element
4324
4325 @complexity Constant.
4326
4327 @requirement This function helps `basic_json` satisfying the
4328 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4329 requirements:
4330 - The complexity is constant.
4331 - Has the semantics of `const_cast<const basic_json&>(*this).begin()`.
4332
4333 @liveexample{The following code shows an example for `cbegin()`.,cbegin}
4334
4335 @sa @ref begin() -- returns an iterator to the beginning
4336 @sa @ref end() -- returns an iterator to the end
4337 @sa @ref cend() -- returns a const iterator to the end
4338
4339 @since version 1.0.0
4340 */
4341 const_iterator cbegin() const noexcept
4342 {
4343 const_iterator result(this);
4344 result.set_begin();
4345 return result;
4346 }
4347
4348 /*!
4349 @brief returns an iterator to one past the last element
4350
4351 Returns an iterator to one past the last element.
4352
4353 @image html range-begin-end.svg "Illustration from cppreference.com"
4354
4355 @return iterator one past the last element
4356
4357 @complexity Constant.
4358
4359 @requirement This function helps `basic_json` satisfying the
4360 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4361 requirements:
4362 - The complexity is constant.
4363
4364 @liveexample{The following code shows an example for `end()`.,end}
4365
4366 @sa @ref cend() -- returns a const iterator to the end
4367 @sa @ref begin() -- returns an iterator to the beginning
4368 @sa @ref cbegin() -- returns a const iterator to the beginning
4369
4370 @since version 1.0.0
4371 */
4372 iterator end() noexcept
4373 {
4374 iterator result(this);
4375 result.set_end();
4376 return result;
4377 }
4378
4379 /*!
4380 @copydoc basic_json::cend()
4381 */
4382 const_iterator end() const noexcept
4383 {
4384 return cend();
4385 }
4386
4387 /*!
4388 @brief returns a const iterator to one past the last element
4389
4390 Returns a const iterator to one past the last element.
4391
4392 @image html range-begin-end.svg "Illustration from cppreference.com"
4393
4394 @return const iterator one past the last element
4395
4396 @complexity Constant.
4397
4398 @requirement This function helps `basic_json` satisfying the
4399 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4400 requirements:
4401 - The complexity is constant.
4402 - Has the semantics of `const_cast<const basic_json&>(*this).end()`.
4403
4404 @liveexample{The following code shows an example for `cend()`.,cend}
4405
4406 @sa @ref end() -- returns an iterator to the end
4407 @sa @ref begin() -- returns an iterator to the beginning
4408 @sa @ref cbegin() -- returns a const iterator to the beginning
4409
4410 @since version 1.0.0
4411 */
4412 const_iterator cend() const noexcept
4413 {
4414 const_iterator result(this);
4415 result.set_end();
4416 return result;
4417 }
4418
4419 /*!
4420 @brief returns an iterator to the reverse-beginning
4421
4422 Returns an iterator to the reverse-beginning; that is, the last element.
4423
4424 @image html range-rbegin-rend.svg "Illustration from cppreference.com"
4425
4426 @complexity Constant.
4427
4428 @requirement This function helps `basic_json` satisfying the
4429 [ReversibleContainer](http://en.cppreference.com/w/cpp/concept/ReversibleContainer)
4430 requirements:
4431 - The complexity is constant.
4432 - Has the semantics of `reverse_iterator(end())`.
4433
4434 @liveexample{The following code shows an example for `rbegin()`.,rbegin}
4435
4436 @sa @ref crbegin() -- returns a const reverse iterator to the beginning
4437 @sa @ref rend() -- returns a reverse iterator to the end
4438 @sa @ref crend() -- returns a const reverse iterator to the end
4439
4440 @since version 1.0.0
4441 */
4442 reverse_iterator rbegin() noexcept
4443 {
4444 return reverse_iterator(end());
4445 }
4446
4447 /*!
4448 @copydoc basic_json::crbegin()
4449 */
4450 const_reverse_iterator rbegin() const noexcept
4451 {
4452 return crbegin();
4453 }
4454
4455 /*!
4456 @brief returns an iterator to the reverse-end
4457
4458 Returns an iterator to the reverse-end; that is, one before the first
4459 element.
4460
4461 @image html range-rbegin-rend.svg "Illustration from cppreference.com"
4462
4463 @complexity Constant.
4464
4465 @requirement This function helps `basic_json` satisfying the
4466 [ReversibleContainer](http://en.cppreference.com/w/cpp/concept/ReversibleContainer)
4467 requirements:
4468 - The complexity is constant.
4469 - Has the semantics of `reverse_iterator(begin())`.
4470
4471 @liveexample{The following code shows an example for `rend()`.,rend}
4472
4473 @sa @ref crend() -- returns a const reverse iterator to the end
4474 @sa @ref rbegin() -- returns a reverse iterator to the beginning
4475 @sa @ref crbegin() -- returns a const reverse iterator to the beginning
4476
4477 @since version 1.0.0
4478 */
4479 reverse_iterator rend() noexcept
4480 {
4481 return reverse_iterator(begin());
4482 }
4483
4484 /*!
4485 @copydoc basic_json::crend()
4486 */
4487 const_reverse_iterator rend() const noexcept
4488 {
4489 return crend();
4490 }
4491
4492 /*!
4493 @brief returns a const reverse iterator to the last element
4494
4495 Returns a const iterator to the reverse-beginning; that is, the last
4496 element.
4497
4498 @image html range-rbegin-rend.svg "Illustration from cppreference.com"
4499
4500 @complexity Constant.
4501
4502 @requirement This function helps `basic_json` satisfying the
4503 [ReversibleContainer](http://en.cppreference.com/w/cpp/concept/ReversibleContainer)
4504 requirements:
4505 - The complexity is constant.
4506 - Has the semantics of `const_cast<const basic_json&>(*this).rbegin()`.
4507
4508 @liveexample{The following code shows an example for `crbegin()`.,crbegin}
4509
4510 @sa @ref rbegin() -- returns a reverse iterator to the beginning
4511 @sa @ref rend() -- returns a reverse iterator to the end
4512 @sa @ref crend() -- returns a const reverse iterator to the end
4513
4514 @since version 1.0.0
4515 */
4516 const_reverse_iterator crbegin() const noexcept
4517 {
4518 return const_reverse_iterator(cend());
4519 }
4520
4521 /*!
4522 @brief returns a const reverse iterator to one before the first
4523
4524 Returns a const reverse iterator to the reverse-end; that is, one before
4525 the first element.
4526
4527 @image html range-rbegin-rend.svg "Illustration from cppreference.com"
4528
4529 @complexity Constant.
4530
4531 @requirement This function helps `basic_json` satisfying the
4532 [ReversibleContainer](http://en.cppreference.com/w/cpp/concept/ReversibleContainer)
4533 requirements:
4534 - The complexity is constant.
4535 - Has the semantics of `const_cast<const basic_json&>(*this).rend()`.
4536
4537 @liveexample{The following code shows an example for `crend()`.,crend}
4538
4539 @sa @ref rend() -- returns a reverse iterator to the end
4540 @sa @ref rbegin() -- returns a reverse iterator to the beginning
4541 @sa @ref crbegin() -- returns a const reverse iterator to the beginning
4542
4543 @since version 1.0.0
4544 */
4545 const_reverse_iterator crend() const noexcept
4546 {
4547 return const_reverse_iterator(cbegin());
4548 }
4549
4550 private:
4551 // forward declaration
4552 template<typename IteratorType> class iteration_proxy;
4553
4554 public:
4555 /*!
4556 @brief wrapper to access iterator member functions in range-based for
4557
4558 This function allows to access @ref iterator::key() and @ref
4559 iterator::value() during range-based for loops. In these loops, a
4560 reference to the JSON values is returned, so there is no access to the
4561 underlying iterator.
4562
4563 @note The name of this function is not yet final and may change in the
4564 future.
4565 */
4566 static iteration_proxy<iterator> iterator_wrapper(reference cont)
4567 {
4568 return iteration_proxy<iterator>(cont);
4569 }
4570
4571 /*!
4572 @copydoc iterator_wrapper(reference)
4573 */
4574 static iteration_proxy<const_iterator> iterator_wrapper(const_reference cont)
4575 {
4576 return iteration_proxy<const_iterator>(cont);
4577 }
4578
4579 /// @}
4580
4581
4582 //////////////
4583 // capacity //
4584 //////////////
4585
4586 /// @name capacity
4587 /// @{
4588
4589 /*!
4590 @brief checks whether the container is empty
4591
4592 Checks if a JSON value has no elements.
4593
4594 @return The return value depends on the different types and is
4595 defined as follows:
4596 Value type | return value
4597 ----------- | -------------
4598 null | `true`
4599 boolean | `false`
4600 string | `false`
4601 number | `false`
4602 object | result of function `object_t::empty()`
4603 array | result of function `array_t::empty()`
4604
4605 @note This function does not return whether a string stored as JSON value
4606 is empty - it returns whether the JSON container itself is empty which is
4607 false in the case of a string.
4608
4609 @complexity Constant, as long as @ref array_t and @ref object_t satisfy
4610 the Container concept; that is, their `empty()` functions have constant
4611 complexity.
4612
4613 @requirement This function helps `basic_json` satisfying the
4614 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4615 requirements:
4616 - The complexity is constant.
4617 - Has the semantics of `begin() == end()`.
4618
4619 @liveexample{The following code uses `empty()` to check if a JSON
4620 object contains any elements.,empty}
4621
4622 @sa @ref size() -- returns the number of elements
4623
4624 @since version 1.0.0
4625 */
4626 bool empty() const noexcept
4627 {
4628 switch (m_type)
4629 {
4630 case value_t::null:
4631 {
4632 // null values are empty
4633 return true;
4634 }
4635
4636 case value_t::array:
4637 {
4638 // delegate call to array_t::empty()
4639 return m_value.array->empty();
4640 }
4641
4642 case value_t::object:
4643 {
4644 // delegate call to object_t::empty()
4645 return m_value.object->empty();
4646 }
4647
4648 default:
4649 {
4650 // all other types are nonempty
4651 return false;
4652 }
4653 }
4654 }
4655
4656 /*!
4657 @brief returns the number of elements
4658
4659 Returns the number of elements in a JSON value.
4660
4661 @return The return value depends on the different types and is
4662 defined as follows:
4663 Value type | return value
4664 ----------- | -------------
4665 null | `0`
4666 boolean | `1`
4667 string | `1`
4668 number | `1`
4669 object | result of function object_t::size()
4670 array | result of function array_t::size()
4671
4672 @note This function does not return the length of a string stored as JSON
4673 value - it returns the number of elements in the JSON value which is 1 in
4674 the case of a string.
4675
4676 @complexity Constant, as long as @ref array_t and @ref object_t satisfy
4677 the Container concept; that is, their size() functions have constant
4678 complexity.
4679
4680 @requirement This function helps `basic_json` satisfying the
4681 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4682 requirements:
4683 - The complexity is constant.
4684 - Has the semantics of `std::distance(begin(), end())`.
4685
4686 @liveexample{The following code calls `size()` on the different value
4687 types.,size}
4688
4689 @sa @ref empty() -- checks whether the container is empty
4690 @sa @ref max_size() -- returns the maximal number of elements
4691
4692 @since version 1.0.0
4693 */
4694 size_type size() const noexcept
4695 {
4696 switch (m_type)
4697 {
4698 case value_t::null:
4699 {
4700 // null values are empty
4701 return 0;
4702 }
4703
4704 case value_t::array:
4705 {
4706 // delegate call to array_t::size()
4707 return m_value.array->size();
4708 }
4709
4710 case value_t::object:
4711 {
4712 // delegate call to object_t::size()
4713 return m_value.object->size();
4714 }
4715
4716 default:
4717 {
4718 // all other types have size 1
4719 return 1;
4720 }
4721 }
4722 }
4723
4724 /*!
4725 @brief returns the maximum possible number of elements
4726
4727 Returns the maximum number of elements a JSON value is able to hold due to
4728 system or library implementation limitations, i.e. `std::distance(begin(),
4729 end())` for the JSON value.
4730
4731 @return The return value depends on the different types and is
4732 defined as follows:
4733 Value type | return value
4734 ----------- | -------------
4735 null | `0` (same as `size()`)
4736 boolean | `1` (same as `size()`)
4737 string | `1` (same as `size()`)
4738 number | `1` (same as `size()`)
4739 object | result of function `object_t::max_size()`
4740 array | result of function `array_t::max_size()`
4741
4742 @complexity Constant, as long as @ref array_t and @ref object_t satisfy
4743 the Container concept; that is, their `max_size()` functions have constant
4744 complexity.
4745
4746 @requirement This function helps `basic_json` satisfying the
4747 [Container](http://en.cppreference.com/w/cpp/concept/Container)
4748 requirements:
4749 - The complexity is constant.
4750 - Has the semantics of returning `b.size()` where `b` is the largest
4751 possible JSON value.
4752
4753 @liveexample{The following code calls `max_size()` on the different value
4754 types. Note the output is implementation specific.,max_size}
4755
4756 @sa @ref size() -- returns the number of elements
4757
4758 @since version 1.0.0
4759 */
4760 size_type max_size() const noexcept
4761 {
4762 switch (m_type)
4763 {
4764 case value_t::array:
4765 {
4766 // delegate call to array_t::max_size()
4767 return m_value.array->max_size();
4768 }
4769
4770 case value_t::object:
4771 {
4772 // delegate call to object_t::max_size()
4773 return m_value.object->max_size();
4774 }
4775
4776 default:
4777 {
4778 // all other types have max_size() == size()
4779 return size();
4780 }
4781 }
4782 }
4783
4784 /// @}
4785
4786
4787 ///////////////
4788 // modifiers //
4789 ///////////////
4790
4791 /// @name modifiers
4792 /// @{
4793
4794 /*!
4795 @brief clears the contents
4796
4797 Clears the content of a JSON value and resets it to the default value as
4798 if @ref basic_json(value_t) would have been called:
4799
4800 Value type | initial value
4801 ----------- | -------------
4802 null | `null`
4803 boolean | `false`
4804 string | `""`
4805 number | `0`
4806 object | `{}`
4807 array | `[]`
4808
4809 @note Floating-point numbers are set to `0.0` which will be serialized to
4810 `0`. The vale type remains @ref number_float_t.
4811
4812 @complexity Linear in the size of the JSON value.
4813
4814 @liveexample{The example below shows the effect of `clear()` to different
4815 JSON types.,clear}
4816
4817 @since version 1.0.0
4818 */
4819 void clear() noexcept
4820 {
4821 switch (m_type)
4822 {
4823 case value_t::number_integer:
4824 {
4825 m_value.number_integer = 0;
4826 break;
4827 }
4828
4829 case value_t::number_unsigned:
4830 {
4831 m_value.number_unsigned = 0;
4832 break;
4833 }
4834
4835 case value_t::number_float:
4836 {
4837 m_value.number_float = 0.0;
4838 break;
4839 }
4840
4841 case value_t::boolean:
4842 {
4843 m_value.boolean = false;
4844 break;
4845 }
4846
4847 case value_t::string:
4848 {
4849 m_value.string->clear();
4850 break;
4851 }
4852
4853 case value_t::array:
4854 {
4855 m_value.array->clear();
4856 break;
4857 }
4858
4859 case value_t::object:
4860 {
4861 m_value.object->clear();
4862 break;
4863 }
4864
4865 default:
4866 {
4867 break;
4868 }
4869 }
4870 }
4871
4872 /*!
4873 @brief add an object to an array
4874
4875 Appends the given element @a val to the end of the JSON value. If the
4876 function is called on a JSON null value, an empty array is created before
4877 appending @a val.
4878
4879 @param[in] val the value to add to the JSON array
4880
4881 @throw std::domain_error when called on a type other than JSON array or
4882 null; example: `"cannot use push_back() with number"`
4883
4884 @complexity Amortized constant.
4885
4886 @liveexample{The example shows how `push_back()` and `+=` can be used to
4887 add elements to a JSON array. Note how the `null` value was silently
4888 converted to a JSON array.,push_back}
4889
4890 @since version 1.0.0
4891 */
4892 void push_back(basic_json&& val)
4893 {
4894 // push_back only works for null objects or arrays
4895 if (not(is_null() or is_array()))
4896 {
4897 throw std::domain_error("cannot use push_back() with " + type_name());
4898 }
4899
4900 // transform null object into an array
4901 if (is_null())
4902 {
4903 m_type = value_t::array;
4904 m_value = value_t::array;
4905 assert_invariant();
4906 }
4907
4908 // add element to array (move semantics)
4909 m_value.array->push_back(std::move(val));
4910 // invalidate object
4911 val.m_type = value_t::null;
4912 }
4913
4914 /*!
4915 @brief add an object to an array
4916 @copydoc push_back(basic_json&&)
4917 */
4918 reference operator+=(basic_json&& val)
4919 {
4920 push_back(std::move(val));
4921 return *this;
4922 }
4923
4924 /*!
4925 @brief add an object to an array
4926 @copydoc push_back(basic_json&&)
4927 */
4928 void push_back(const basic_json& val)
4929 {
4930 // push_back only works for null objects or arrays
4931 if (not(is_null() or is_array()))
4932 {
4933 throw std::domain_error("cannot use push_back() with " + type_name());
4934 }
4935
4936 // transform null object into an array
4937 if (is_null())
4938 {
4939 m_type = value_t::array;
4940 m_value = value_t::array;
4941 assert_invariant();
4942 }
4943
4944 // add element to array
4945 m_value.array->push_back(val);
4946 }
4947
4948 /*!
4949 @brief add an object to an array
4950 @copydoc push_back(basic_json&&)
4951 */
4952 reference operator+=(const basic_json& val)
4953 {
4954 push_back(val);
4955 return *this;
4956 }
4957
4958 /*!
4959 @brief add an object to an object
4960
4961 Inserts the given element @a val to the JSON object. If the function is
4962 called on a JSON null value, an empty object is created before inserting
4963 @a val.
4964
4965 @param[in] val the value to add to the JSON object
4966
4967 @throw std::domain_error when called on a type other than JSON object or
4968 null; example: `"cannot use push_back() with number"`
4969
4970 @complexity Logarithmic in the size of the container, O(log(`size()`)).
4971
4972 @liveexample{The example shows how `push_back()` and `+=` can be used to
4973 add elements to a JSON object. Note how the `null` value was silently
4974 converted to a JSON object.,push_back__object_t__value}
4975
4976 @since version 1.0.0
4977 */
4978 void push_back(const typename object_t::value_type& val)
4979 {
4980 // push_back only works for null objects or objects
4981 if (not(is_null() or is_object()))
4982 {
4983 throw std::domain_error("cannot use push_back() with " + type_name());
4984 }
4985
4986 // transform null object into an object
4987 if (is_null())
4988 {
4989 m_type = value_t::object;
4990 m_value = value_t::object;
4991 assert_invariant();
4992 }
4993
4994 // add element to array
4995 m_value.object->insert(val);
4996 }
4997
4998 /*!
4999 @brief add an object to an object
5000 @copydoc push_back(const typename object_t::value_type&)
5001 */
5002 reference operator+=(const typename object_t::value_type& val)
5003 {
5004 push_back(val);
5005 return *this;
5006 }
5007
5008 /*!
5009 @brief add an object to an object
5010
5011 This function allows to use `push_back` with an initializer list. In case
5012
5013 1. the current value is an object,
5014 2. the initializer list @a init contains only two elements, and
5015 3. the first element of @a init is a string,
5016
5017 @a init is converted into an object element and added using
5018 @ref push_back(const typename object_t::value_type&). Otherwise, @a init
5019 is converted to a JSON value and added using @ref push_back(basic_json&&).
5020
5021 @param init an initializer list
5022
5023 @complexity Linear in the size of the initializer list @a init.
5024
5025 @note This function is required to resolve an ambiguous overload error,
5026 because pairs like `{"key", "value"}` can be both interpreted as
5027 `object_t::value_type` or `std::initializer_list<basic_json>`, see
5028 https://github.com/nlohmann/json/issues/235 for more information.
5029
5030 @liveexample{The example shows how initializer lists are treated as
5031 objects when possible.,push_back__initializer_list}
5032 */
5033 void push_back(std::initializer_list<basic_json> init)
5034 {
5035 if (is_object() and init.size() == 2 and init.begin()->is_string())
5036 {
5037 const string_t key = *init.begin();
5038 push_back(typename object_t::value_type(key, *(init.begin() + 1)));
5039 }
5040 else
5041 {
5042 push_back(basic_json(init));
5043 }
5044 }
5045
5046 /*!
5047 @brief add an object to an object
5048 @copydoc push_back(std::initializer_list<basic_json>)
5049 */
5050 reference operator+=(std::initializer_list<basic_json> init)
5051 {
5052 push_back(init);
5053 return *this;
5054 }
5055
5056 /*!
5057 @brief inserts element
5058
5059 Inserts element @a val before iterator @a pos.
5060
5061 @param[in] pos iterator before which the content will be inserted; may be
5062 the end() iterator
5063 @param[in] val element to insert
5064 @return iterator pointing to the inserted @a val.
5065
5066 @throw std::domain_error if called on JSON values other than arrays;
5067 example: `"cannot use insert() with string"`
5068 @throw std::domain_error if @a pos is not an iterator of *this; example:
5069 `"iterator does not fit current value"`
5070
5071 @complexity Constant plus linear in the distance between pos and end of the
5072 container.
5073
5074 @liveexample{The example shows how `insert()` is used.,insert}
5075
5076 @since version 1.0.0
5077 */
5078 iterator insert(const_iterator pos, const basic_json& val)
5079 {
5080 // insert only works for arrays
5081 if (is_array())
5082 {
5083 // check if iterator pos fits to this JSON value
5084 if (pos.m_object != this)
5085 {
5086 throw std::domain_error("iterator does not fit current value");
5087 }
5088
5089 // insert to array and return iterator
5090 iterator result(this);
5091 result.m_it.array_iterator = m_value.array->insert(pos.m_it.array_iterator, val);
5092 return result;
5093 }
5094 else
5095 {
5096 throw std::domain_error("cannot use insert() with " + type_name());
5097 }
5098 }
5099
5100 /*!
5101 @brief inserts element
5102 @copydoc insert(const_iterator, const basic_json&)
5103 */
5104 iterator insert(const_iterator pos, basic_json&& val)
5105 {
5106 return insert(pos, val);
5107 }
5108
5109 /*!
5110 @brief inserts elements
5111
5112 Inserts @a cnt copies of @a val before iterator @a pos.
5113
5114 @param[in] pos iterator before which the content will be inserted; may be
5115 the end() iterator
5116 @param[in] cnt number of copies of @a val to insert
5117 @param[in] val element to insert
5118 @return iterator pointing to the first element inserted, or @a pos if
5119 `cnt==0`
5120
5121 @throw std::domain_error if called on JSON values other than arrays;
5122 example: `"cannot use insert() with string"`
5123 @throw std::domain_error if @a pos is not an iterator of *this; example:
5124 `"iterator does not fit current value"`
5125
5126 @complexity Linear in @a cnt plus linear in the distance between @a pos
5127 and end of the container.
5128
5129 @liveexample{The example shows how `insert()` is used.,insert__count}
5130
5131 @since version 1.0.0
5132 */
5133 iterator insert(const_iterator pos, size_type cnt, const basic_json& val)
5134 {
5135 // insert only works for arrays
5136 if (is_array())
5137 {
5138 // check if iterator pos fits to this JSON value
5139 if (pos.m_object != this)
5140 {
5141 throw std::domain_error("iterator does not fit current value");
5142 }
5143
5144 // insert to array and return iterator
5145 iterator result(this);
5146 result.m_it.array_iterator = m_value.array->insert(pos.m_it.array_iterator, cnt, val);
5147 return result;
5148 }
5149 else
5150 {
5151 throw std::domain_error("cannot use insert() with " + type_name());
5152 }
5153 }
5154
5155 /*!
5156 @brief inserts elements
5157
5158 Inserts elements from range `[first, last)` before iterator @a pos.
5159
5160 @param[in] pos iterator before which the content will be inserted; may be
5161 the end() iterator
5162 @param[in] first begin of the range of elements to insert
5163 @param[in] last end of the range of elements to insert
5164
5165 @throw std::domain_error if called on JSON values other than arrays;
5166 example: `"cannot use insert() with string"`
5167 @throw std::domain_error if @a pos is not an iterator of *this; example:
5168 `"iterator does not fit current value"`
5169 @throw std::domain_error if @a first and @a last do not belong to the same
5170 JSON value; example: `"iterators do not fit"`
5171 @throw std::domain_error if @a first or @a last are iterators into
5172 container for which insert is called; example: `"passed iterators may not
5173 belong to container"`
5174
5175 @return iterator pointing to the first element inserted, or @a pos if
5176 `first==last`
5177
5178 @complexity Linear in `std::distance(first, last)` plus linear in the
5179 distance between @a pos and end of the container.
5180
5181 @liveexample{The example shows how `insert()` is used.,insert__range}
5182
5183 @since version 1.0.0
5184 */
5185 iterator insert(const_iterator pos, const_iterator first, const_iterator last)
5186 {
5187 // insert only works for arrays
5188 if (not is_array())
5189 {
5190 throw std::domain_error("cannot use insert() with " + type_name());
5191 }
5192
5193 // check if iterator pos fits to this JSON value
5194 if (pos.m_object != this)
5195 {
5196 throw std::domain_error("iterator does not fit current value");
5197 }
5198
5199 // check if range iterators belong to the same JSON object
5200 if (first.m_object != last.m_object)
5201 {
5202 throw std::domain_error("iterators do not fit");
5203 }
5204
5205 if (first.m_object == this or last.m_object == this)
5206 {
5207 throw std::domain_error("passed iterators may not belong to container");
5208 }
5209
5210 // insert to array and return iterator
5211 iterator result(this);
5212 result.m_it.array_iterator = m_value.array->insert(
5213 pos.m_it.array_iterator,
5214 first.m_it.array_iterator,
5215 last.m_it.array_iterator);
5216 return result;
5217 }
5218
5219 /*!
5220 @brief inserts elements
5221
5222 Inserts elements from initializer list @a ilist before iterator @a pos.
5223
5224 @param[in] pos iterator before which the content will be inserted; may be
5225 the end() iterator
5226 @param[in] ilist initializer list to insert the values from
5227
5228 @throw std::domain_error if called on JSON values other than arrays;
5229 example: `"cannot use insert() with string"`
5230 @throw std::domain_error if @a pos is not an iterator of *this; example:
5231 `"iterator does not fit current value"`
5232
5233 @return iterator pointing to the first element inserted, or @a pos if
5234 `ilist` is empty
5235
5236 @complexity Linear in `ilist.size()` plus linear in the distance between
5237 @a pos and end of the container.
5238
5239 @liveexample{The example shows how `insert()` is used.,insert__ilist}
5240
5241 @since version 1.0.0
5242 */
5243 iterator insert(const_iterator pos, std::initializer_list<basic_json> ilist)
5244 {
5245 // insert only works for arrays
5246 if (not is_array())
5247 {
5248 throw std::domain_error("cannot use insert() with " + type_name());
5249 }
5250
5251 // check if iterator pos fits to this JSON value
5252 if (pos.m_object != this)
5253 {
5254 throw std::domain_error("iterator does not fit current value");
5255 }
5256
5257 // insert to array and return iterator
5258 iterator result(this);
5259 result.m_it.array_iterator = m_value.array->insert(pos.m_it.array_iterator, ilist);
5260 return result;
5261 }
5262
5263 /*!
5264 @brief exchanges the values
5265
5266 Exchanges the contents of the JSON value with those of @a other. Does not
5267 invoke any move, copy, or swap operations on individual elements. All
5268 iterators and references remain valid. The past-the-end iterator is
5269 invalidated.
5270
5271 @param[in,out] other JSON value to exchange the contents with
5272
5273 @complexity Constant.
5274
5275 @liveexample{The example below shows how JSON values can be swapped with
5276 `swap()`.,swap__reference}
5277
5278 @since version 1.0.0
5279 */
5280 void swap(reference other) noexcept (
5281 std::is_nothrow_move_constructible<value_t>::value and
5282 std::is_nothrow_move_assignable<value_t>::value and
5283 std::is_nothrow_move_constructible<json_value>::value and
5284 std::is_nothrow_move_assignable<json_value>::value
5285 )
5286 {
5287 std::swap(m_type, other.m_type);
5288 std::swap(m_value, other.m_value);
5289 assert_invariant();
5290 }
5291
5292 /*!
5293 @brief exchanges the values
5294
5295 Exchanges the contents of a JSON array with those of @a other. Does not
5296 invoke any move, copy, or swap operations on individual elements. All
5297 iterators and references remain valid. The past-the-end iterator is
5298 invalidated.
5299
5300 @param[in,out] other array to exchange the contents with
5301
5302 @throw std::domain_error when JSON value is not an array; example: `"cannot
5303 use swap() with string"`
5304
5305 @complexity Constant.
5306
5307 @liveexample{The example below shows how arrays can be swapped with
5308 `swap()`.,swap__array_t}
5309
5310 @since version 1.0.0
5311 */
5312 void swap(array_t& other)
5313 {
5314 // swap only works for arrays
5315 if (is_array())
5316 {
5317 std::swap(*(m_value.array), other);
5318 }
5319 else
5320 {
5321 throw std::domain_error("cannot use swap() with " + type_name());
5322 }
5323 }
5324
5325 /*!
5326 @brief exchanges the values
5327
5328 Exchanges the contents of a JSON object with those of @a other. Does not
5329 invoke any move, copy, or swap operations on individual elements. All
5330 iterators and references remain valid. The past-the-end iterator is
5331 invalidated.
5332
5333 @param[in,out] other object to exchange the contents with
5334
5335 @throw std::domain_error when JSON value is not an object; example:
5336 `"cannot use swap() with string"`
5337
5338 @complexity Constant.
5339
5340 @liveexample{The example below shows how objects can be swapped with
5341 `swap()`.,swap__object_t}
5342
5343 @since version 1.0.0
5344 */
5345 void swap(object_t& other)
5346 {
5347 // swap only works for objects
5348 if (is_object())
5349 {
5350 std::swap(*(m_value.object), other);
5351 }
5352 else
5353 {
5354 throw std::domain_error("cannot use swap() with " + type_name());
5355 }
5356 }
5357
5358 /*!
5359 @brief exchanges the values
5360
5361 Exchanges the contents of a JSON string with those of @a other. Does not
5362 invoke any move, copy, or swap operations on individual elements. All
5363 iterators and references remain valid. The past-the-end iterator is
5364 invalidated.
5365
5366 @param[in,out] other string to exchange the contents with
5367
5368 @throw std::domain_error when JSON value is not a string; example: `"cannot
5369 use swap() with boolean"`
5370
5371 @complexity Constant.
5372
5373 @liveexample{The example below shows how strings can be swapped with
5374 `swap()`.,swap__string_t}
5375
5376 @since version 1.0.0
5377 */
5378 void swap(string_t& other)
5379 {
5380 // swap only works for strings
5381 if (is_string())
5382 {
5383 std::swap(*(m_value.string), other);
5384 }
5385 else
5386 {
5387 throw std::domain_error("cannot use swap() with " + type_name());
5388 }
5389 }
5390
5391 /// @}
5392
5393
5394 //////////////////////////////////////////
5395 // lexicographical comparison operators //
5396 //////////////////////////////////////////
5397
5398 /// @name lexicographical comparison operators
5399 /// @{
5400
5401 private:
5402 /*!
5403 @brief comparison operator for JSON types
5404
5405 Returns an ordering that is similar to Python:
5406 - order: null < boolean < number < object < array < string
5407 - furthermore, each type is not smaller than itself
5408
5409 @since version 1.0.0
5410 */
5411 friend bool operator<(const value_t lhs, const value_t rhs) noexcept
5412 {
5413 static constexpr std::array<uint8_t, 8> order = {{
5414 0, // null
5415 3, // object
5416 4, // array
5417 5, // string
5418 1, // boolean
5419 2, // integer
5420 2, // unsigned
5421 2, // float
5422 }
5423 };
5424
5425 // discarded values are not comparable
5426 if (lhs == value_t::discarded or rhs == value_t::discarded)
5427 {
5428 return false;
5429 }
5430
5431 return order[static_cast<std::size_t>(lhs)] < order[static_cast<std::size_t>(rhs)];
5432 }
5433
5434 public:
5435 /*!
5436 @brief comparison: equal
5437
5438 Compares two JSON values for equality according to the following rules:
5439 - Two JSON values are equal if (1) they are from the same type and (2)
5440 their stored values are the same.
5441 - Integer and floating-point numbers are automatically converted before
5442 comparison. Floating-point numbers are compared indirectly: two
5443 floating-point numbers `f1` and `f2` are considered equal if neither
5444 `f1 > f2` nor `f2 > f1` holds.
5445 - Two JSON null values are equal.
5446
5447 @param[in] lhs first JSON value to consider
5448 @param[in] rhs second JSON value to consider
5449 @return whether the values @a lhs and @a rhs are equal
5450
5451 @complexity Linear.
5452
5453 @liveexample{The example demonstrates comparing several JSON
5454 types.,operator__equal}
5455
5456 @since version 1.0.0
5457 */
5458 friend bool operator==(const_reference lhs, const_reference rhs) noexcept
5459 {
5460 const auto lhs_type = lhs.type();
5461 const auto rhs_type = rhs.type();
5462
5463 if (lhs_type == rhs_type)
5464 {
5465 switch (lhs_type)
5466 {
5467 case value_t::array:
5468 {
5469 return *lhs.m_value.array == *rhs.m_value.array;
5470 }
5471 case value_t::object:
5472 {
5473 return *lhs.m_value.object == *rhs.m_value.object;
5474 }
5475 case value_t::null:
5476 {
5477 return true;
5478 }
5479 case value_t::string:
5480 {
5481 return *lhs.m_value.string == *rhs.m_value.string;
5482 }
5483 case value_t::boolean:
5484 {
5485 return lhs.m_value.boolean == rhs.m_value.boolean;
5486 }
5487 case value_t::number_integer:
5488 {
5489 return lhs.m_value.number_integer == rhs.m_value.number_integer;
5490 }
5491 case value_t::number_unsigned:
5492 {
5493 return lhs.m_value.number_unsigned == rhs.m_value.number_unsigned;
5494 }
5495 case value_t::number_float:
5496 {
5497 return lhs.m_value.number_float == rhs.m_value.number_float;
5498 }
5499 default:
5500 {
5501 return false;
5502 }
5503 }
5504 }
5505 else if (lhs_type == value_t::number_integer and rhs_type == value_t::number_float)
5506 {
5507 return static_cast<number_float_t>(lhs.m_value.number_integer) == rhs.m_value.number_float;
5508 }
5509 else if (lhs_type == value_t::number_float and rhs_type == value_t::number_integer)
5510 {
5511 return lhs.m_value.number_float == static_cast<number_float_t>(rhs.m_value.number_integer);
5512 }
5513 else if (lhs_type == value_t::number_unsigned and rhs_type == value_t::number_float)
5514 {
5515 return static_cast<number_float_t>(lhs.m_value.number_unsigned) == rhs.m_value.number_float;
5516 }
5517 else if (lhs_type == value_t::number_float and rhs_type == value_t::number_unsigned)
5518 {
5519 return lhs.m_value.number_float == static_cast<number_float_t>(rhs.m_value.number_unsigned);
5520 }
5521 else if (lhs_type == value_t::number_unsigned and rhs_type == value_t::number_integer)
5522 {
5523 return static_cast<number_integer_t>(lhs.m_value.number_unsigned) == rhs.m_value.number_integer;
5524 }
5525 else if (lhs_type == value_t::number_integer and rhs_type == value_t::number_unsigned)
5526 {
5527 return lhs.m_value.number_integer == static_cast<number_integer_t>(rhs.m_value.number_unsigned);
5528 }
5529
5530 return false;
5531 }
5532
5533 /*!
5534 @brief comparison: equal
5535
5536 The functions compares the given JSON value against a null pointer. As the
5537 null pointer can be used to initialize a JSON value to null, a comparison
5538 of JSON value @a v with a null pointer should be equivalent to call
5539 `v.is_null()`.
5540
5541 @param[in] v JSON value to consider
5542 @return whether @a v is null
5543
5544 @complexity Constant.
5545
5546 @liveexample{The example compares several JSON types to the null pointer.
5547 ,operator__equal__nullptr_t}
5548
5549 @since version 1.0.0
5550 */
5551 friend bool operator==(const_reference v, std::nullptr_t) noexcept
5552 {
5553 return v.is_null();
5554 }
5555
5556 /*!
5557 @brief comparison: equal
5558 @copydoc operator==(const_reference, std::nullptr_t)
5559 */
5560 friend bool operator==(std::nullptr_t, const_reference v) noexcept
5561 {
5562 return v.is_null();
5563 }
5564
5565 /*!
5566 @brief comparison: not equal
5567
5568 Compares two JSON values for inequality by calculating `not (lhs == rhs)`.
5569
5570 @param[in] lhs first JSON value to consider
5571 @param[in] rhs second JSON value to consider
5572 @return whether the values @a lhs and @a rhs are not equal
5573
5574 @complexity Linear.
5575
5576 @liveexample{The example demonstrates comparing several JSON
5577 types.,operator__notequal}
5578
5579 @since version 1.0.0
5580 */
5581 friend bool operator!=(const_reference lhs, const_reference rhs) noexcept
5582 {
5583 return not (lhs == rhs);
5584 }
5585
5586 /*!
5587 @brief comparison: not equal
5588
5589 The functions compares the given JSON value against a null pointer. As the
5590 null pointer can be used to initialize a JSON value to null, a comparison
5591 of JSON value @a v with a null pointer should be equivalent to call
5592 `not v.is_null()`.
5593
5594 @param[in] v JSON value to consider
5595 @return whether @a v is not null
5596
5597 @complexity Constant.
5598
5599 @liveexample{The example compares several JSON types to the null pointer.
5600 ,operator__notequal__nullptr_t}
5601
5602 @since version 1.0.0
5603 */
5604 friend bool operator!=(const_reference v, std::nullptr_t) noexcept
5605 {
5606 return not v.is_null();
5607 }
5608
5609 /*!
5610 @brief comparison: not equal
5611 @copydoc operator!=(const_reference, std::nullptr_t)
5612 */
5613 friend bool operator!=(std::nullptr_t, const_reference v) noexcept
5614 {
5615 return not v.is_null();
5616 }
5617
5618 /*!
5619 @brief comparison: less than
5620
5621 Compares whether one JSON value @a lhs is less than another JSON value @a
5622 rhs according to the following rules:
5623 - If @a lhs and @a rhs have the same type, the values are compared using
5624 the default `<` operator.
5625 - Integer and floating-point numbers are automatically converted before
5626 comparison
5627 - In case @a lhs and @a rhs have different types, the values are ignored
5628 and the order of the types is considered, see
5629 @ref operator<(const value_t, const value_t).
5630
5631 @param[in] lhs first JSON value to consider
5632 @param[in] rhs second JSON value to consider
5633 @return whether @a lhs is less than @a rhs
5634
5635 @complexity Linear.
5636
5637 @liveexample{The example demonstrates comparing several JSON
5638 types.,operator__less}
5639
5640 @since version 1.0.0
5641 */
5642 friend bool operator<(const_reference lhs, const_reference rhs) noexcept
5643 {
5644 const auto lhs_type = lhs.type();
5645 const auto rhs_type = rhs.type();
5646
5647 if (lhs_type == rhs_type)
5648 {
5649 switch (lhs_type)
5650 {
5651 case value_t::array:
5652 {
5653 return *lhs.m_value.array < *rhs.m_value.array;
5654 }
5655 case value_t::object:
5656 {
5657 return *lhs.m_value.object < *rhs.m_value.object;
5658 }
5659 case value_t::null:
5660 {
5661 return false;
5662 }
5663 case value_t::string:
5664 {
5665 return *lhs.m_value.string < *rhs.m_value.string;
5666 }
5667 case value_t::boolean:
5668 {
5669 return lhs.m_value.boolean < rhs.m_value.boolean;
5670 }
5671 case value_t::number_integer:
5672 {
5673 return lhs.m_value.number_integer < rhs.m_value.number_integer;
5674 }
5675 case value_t::number_unsigned:
5676 {
5677 return lhs.m_value.number_unsigned < rhs.m_value.number_unsigned;
5678 }
5679 case value_t::number_float:
5680 {
5681 return lhs.m_value.number_float < rhs.m_value.number_float;
5682 }
5683 default:
5684 {
5685 return false;
5686 }
5687 }
5688 }
5689 else if (lhs_type == value_t::number_integer and rhs_type == value_t::number_float)
5690 {
5691 return static_cast<number_float_t>(lhs.m_value.number_integer) < rhs.m_value.number_float;
5692 }
5693 else if (lhs_type == value_t::number_float and rhs_type == value_t::number_integer)
5694 {
5695 return lhs.m_value.number_float < static_cast<number_float_t>(rhs.m_value.number_integer);
5696 }
5697 else if (lhs_type == value_t::number_unsigned and rhs_type == value_t::number_float)
5698 {
5699 return static_cast<number_float_t>(lhs.m_value.number_unsigned) < rhs.m_value.number_float;
5700 }
5701 else if (lhs_type == value_t::number_float and rhs_type == value_t::number_unsigned)
5702 {
5703 return lhs.m_value.number_float < static_cast<number_float_t>(rhs.m_value.number_unsigned);
5704 }
5705 else if (lhs_type == value_t::number_integer and rhs_type == value_t::number_unsigned)
5706 {
5707 return lhs.m_value.number_integer < static_cast<number_integer_t>(rhs.m_value.number_unsigned);
5708 }
5709 else if (lhs_type == value_t::number_unsigned and rhs_type == value_t::number_integer)
5710 {
5711 return static_cast<number_integer_t>(lhs.m_value.number_unsigned) < rhs.m_value.number_integer;
5712 }
5713
5714 // We only reach this line if we cannot compare values. In that case,
5715 // we compare types. Note we have to call the operator explicitly,
5716 // because MSVC has problems otherwise.
5717 return operator<(lhs_type, rhs_type);
5718 }
5719
5720 /*!
5721 @brief comparison: less than or equal
5722
5723 Compares whether one JSON value @a lhs is less than or equal to another
5724 JSON value by calculating `not (rhs < lhs)`.
5725
5726 @param[in] lhs first JSON value to consider
5727 @param[in] rhs second JSON value to consider
5728 @return whether @a lhs is less than or equal to @a rhs
5729
5730 @complexity Linear.
5731
5732 @liveexample{The example demonstrates comparing several JSON
5733 types.,operator__greater}
5734
5735 @since version 1.0.0
5736 */
5737 friend bool operator<=(const_reference lhs, const_reference rhs) noexcept
5738 {
5739 return not (rhs < lhs);
5740 }
5741
5742 /*!
5743 @brief comparison: greater than
5744
5745 Compares whether one JSON value @a lhs is greater than another
5746 JSON value by calculating `not (lhs <= rhs)`.
5747
5748 @param[in] lhs first JSON value to consider
5749 @param[in] rhs second JSON value to consider
5750 @return whether @a lhs is greater than to @a rhs
5751
5752 @complexity Linear.
5753
5754 @liveexample{The example demonstrates comparing several JSON
5755 types.,operator__lessequal}
5756
5757 @since version 1.0.0
5758 */
5759 friend bool operator>(const_reference lhs, const_reference rhs) noexcept
5760 {
5761 return not (lhs <= rhs);
5762 }
5763
5764 /*!
5765 @brief comparison: greater than or equal
5766
5767 Compares whether one JSON value @a lhs is greater than or equal to another
5768 JSON value by calculating `not (lhs < rhs)`.
5769
5770 @param[in] lhs first JSON value to consider
5771 @param[in] rhs second JSON value to consider
5772 @return whether @a lhs is greater than or equal to @a rhs
5773
5774 @complexity Linear.
5775
5776 @liveexample{The example demonstrates comparing several JSON
5777 types.,operator__greaterequal}
5778
5779 @since version 1.0.0
5780 */
5781 friend bool operator>=(const_reference lhs, const_reference rhs) noexcept
5782 {
5783 return not (lhs < rhs);
5784 }
5785
5786 /// @}
5787
5788
5789 ///////////////////
5790 // serialization //
5791 ///////////////////
5792
5793 /// @name serialization
5794 /// @{
5795
5796 /*!
5797 @brief serialize to stream
5798
5799 Serialize the given JSON value @a j to the output stream @a o. The JSON
5800 value will be serialized using the @ref dump member function. The
5801 indentation of the output can be controlled with the member variable
5802 `width` of the output stream @a o. For instance, using the manipulator
5803 `std::setw(4)` on @a o sets the indentation level to `4` and the
5804 serialization result is the same as calling `dump(4)`.
5805
5806 @note During serializaion, the locale and the precision of the output
5807 stream @a o are changed. The original values are restored when the
5808 function returns.
5809
5810 @param[in,out] o stream to serialize to
5811 @param[in] j JSON value to serialize
5812
5813 @return the stream @a o
5814
5815 @complexity Linear.
5816
5817 @liveexample{The example below shows the serialization with different
5818 parameters to `width` to adjust the indentation level.,operator_serialize}
5819
5820 @since version 1.0.0
5821 */
5822 friend std::ostream& operator<<(std::ostream& o, const basic_json& j)
5823 {
5824 // read width member and use it as indentation parameter if nonzero
5825 const bool pretty_print = (o.width() > 0);
5826 const auto indentation = (pretty_print ? o.width() : 0);
5827
5828 // reset width to 0 for subsequent calls to this stream
5829 o.width(0);
5830
5831 // fix locale problems
5832 const auto old_locale = o.imbue(std::locale(std::locale(), new DecimalSeparator));
5833 // set precision
5834
5835 // 6, 15 or 16 digits of precision allows round-trip IEEE 754
5836 // string->float->string, string->double->string or string->long
5837 // double->string; to be safe, we read this value from
5838 // std::numeric_limits<number_float_t>::digits10
5839 const auto old_precision = o.precision(std::numeric_limits<double>::digits10);
5840
5841 // do the actual serialization
5842 j.dump(o, pretty_print, static_cast<unsigned int>(indentation));
5843
5844 // reset locale and precision
5845 o.imbue(old_locale);
5846 o.precision(old_precision);
5847 return o;
5848 }
5849
5850 /*!
5851 @brief serialize to stream
5852 @copydoc operator<<(std::ostream&, const basic_json&)
5853 */
5854 friend std::ostream& operator>>(const basic_json& j, std::ostream& o)
5855 {
5856 return o << j;
5857 }
5858
5859 /// @}
5860
5861
5862 /////////////////////
5863 // deserialization //
5864 /////////////////////
5865
5866 /// @name deserialization
5867 /// @{
5868
5869 /*!
5870 @brief deserialize from an array
5871
5872 This function reads from an array of 1-byte values.
5873
5874 @pre Each element of the container has a size of 1 byte. Violating this
5875 precondition yields undefined behavior. **This precondition is enforced
5876 with a static assertion.**
5877
5878 @param[in] array array to read from
5879 @param[in] cb a parser callback function of type @ref parser_callback_t
5880 which is used to control the deserialization by filtering unwanted values
5881 (optional)
5882
5883 @return result of the deserialization
5884
5885 @complexity Linear in the length of the input. The parser is a predictive
5886 LL(1) parser. The complexity can be higher if the parser callback function
5887 @a cb has a super-linear complexity.
5888
5889 @note A UTF-8 byte order mark is silently ignored.
5890
5891 @liveexample{The example below demonstrates the `parse()` function reading
5892 from an array.,parse__array__parser_callback_t}
5893
5894 @since version 2.0.3
5895 */
5896 template<class T, std::size_t N>
5897 static basic_json parse(T (&array)[N],
5898 const parser_callback_t cb = nullptr)
5899 {
5900 // delegate the call to the iterator-range parse overload
5901 return parse(std::begin(array), std::end(array), cb);
5902 }
5903
5904 /*!
5905 @brief deserialize from string literal
5906
5907 @tparam CharT character/literal type with size of 1 byte
5908 @param[in] s string literal to read a serialized JSON value from
5909 @param[in] cb a parser callback function of type @ref parser_callback_t
5910 which is used to control the deserialization by filtering unwanted values
5911 (optional)
5912
5913 @return result of the deserialization
5914
5915 @complexity Linear in the length of the input. The parser is a predictive
5916 LL(1) parser. The complexity can be higher if the parser callback function
5917 @a cb has a super-linear complexity.
5918
5919 @note A UTF-8 byte order mark is silently ignored.
5920 @note String containers like `std::string` or @ref string_t can be parsed
5921 with @ref parse(const ContiguousContainer&, const parser_callback_t)
5922
5923 @liveexample{The example below demonstrates the `parse()` function with
5924 and without callback function.,parse__string__parser_callback_t}
5925
5926 @sa @ref parse(std::istream&, const parser_callback_t) for a version that
5927 reads from an input stream
5928
5929 @since version 1.0.0 (originally for @ref string_t)
5930 */
5931 template<typename CharPT, typename std::enable_if<
5932 std::is_pointer<CharPT>::value and
5933 std::is_integral<typename std::remove_pointer<CharPT>::type>::value and
5934 sizeof(typename std::remove_pointer<CharPT>::type) == 1, int>::type = 0>
5935 static basic_json parse(const CharPT s,
5936 const parser_callback_t cb = nullptr)
5937 {
5938 return parser(reinterpret_cast<const char*>(s), cb).parse();
5939 }
5940
5941 /*!
5942 @brief deserialize from stream
5943
5944 @param[in,out] i stream to read a serialized JSON value from
5945 @param[in] cb a parser callback function of type @ref parser_callback_t
5946 which is used to control the deserialization by filtering unwanted values
5947 (optional)
5948
5949 @return result of the deserialization
5950
5951 @complexity Linear in the length of the input. The parser is a predictive
5952 LL(1) parser. The complexity can be higher if the parser callback function
5953 @a cb has a super-linear complexity.
5954
5955 @note A UTF-8 byte order mark is silently ignored.
5956
5957 @liveexample{The example below demonstrates the `parse()` function with
5958 and without callback function.,parse__istream__parser_callback_t}
5959
5960 @sa @ref parse(const char*, const parser_callback_t) for a version
5961 that reads from a string
5962
5963 @since version 1.0.0
5964 */
5965 static basic_json parse(std::istream& i,
5966 const parser_callback_t cb = nullptr)
5967 {
5968 return parser(i, cb).parse();
5969 }
5970
5971 /*!
5972 @copydoc parse(std::istream&, const parser_callback_t)
5973 */
5974 static basic_json parse(std::istream&& i,
5975 const parser_callback_t cb = nullptr)
5976 {
5977 return parser(i, cb).parse();
5978 }
5979
5980 /*!
5981 @brief deserialize from an iterator range with contiguous storage
5982
5983 This function reads from an iterator range of a container with contiguous
5984 storage of 1-byte values. Compatible container types include
5985 `std::vector`, `std::string`, `std::array`, `std::valarray`, and
5986 `std::initializer_list`. Furthermore, C-style arrays can be used with
5987 `std::begin()`/`std::end()`. User-defined containers can be used as long
5988 as they implement random-access iterators and a contiguous storage.
5989
5990 @pre The iterator range is contiguous. Violating this precondition yields
5991 undefined behavior. **This precondition is enforced with an assertion.**
5992 @pre Each element in the range has a size of 1 byte. Violating this
5993 precondition yields undefined behavior. **This precondition is enforced
5994 with a static assertion.**
5995
5996 @warning There is no way to enforce all preconditions at compile-time. If
5997 the function is called with noncompliant iterators and with
5998 assertions switched off, the behavior is undefined and will most
5999 likely yield segmentation violation.
6000
6001 @tparam IteratorType iterator of container with contiguous storage
6002 @param[in] first begin of the range to parse (included)
6003 @param[in] last end of the range to parse (excluded)
6004 @param[in] cb a parser callback function of type @ref parser_callback_t
6005 which is used to control the deserialization by filtering unwanted values
6006 (optional)
6007
6008 @return result of the deserialization
6009
6010 @complexity Linear in the length of the input. The parser is a predictive
6011 LL(1) parser. The complexity can be higher if the parser callback function
6012 @a cb has a super-linear complexity.
6013
6014 @note A UTF-8 byte order mark is silently ignored.
6015
6016 @liveexample{The example below demonstrates the `parse()` function reading
6017 from an iterator range.,parse__iteratortype__parser_callback_t}
6018
6019 @since version 2.0.3
6020 */
6021 template<class IteratorType, typename std::enable_if<
6022 std::is_base_of<
6023 std::random_access_iterator_tag,
6024 typename std::iterator_traits<IteratorType>::iterator_category>::value, int>::type = 0>
6025 static basic_json parse(IteratorType first, IteratorType last,
6026 const parser_callback_t cb = nullptr)
6027 {
6028 // assertion to check that the iterator range is indeed contiguous,
6029 // see http://stackoverflow.com/a/35008842/266378 for more discussion
6030 assert(std::accumulate(first, last, std::make_pair<bool, int>(true, 0),
6031 [&first](std::pair<bool, int> res, decltype(*first) val)
6032 {
6033 res.first &= (val == *(std::next(std::addressof(*first), res.second++)));
6034 return res;
6035 }).first);
6036
6037 // assertion to check that each element is 1 byte long
6038 static_assert(sizeof(typename std::iterator_traits<IteratorType>::value_type) == 1,
6039 "each element in the iterator range must have the size of 1 byte");
6040
6041 // if iterator range is empty, create a parser with an empty string
6042 // to generate "unexpected EOF" error message
6043 if (std::distance(first, last) <= 0)
6044 {
6045 return parser("").parse();
6046 }
6047
6048 return parser(first, last, cb).parse();
6049 }
6050
6051 /*!
6052 @brief deserialize from a container with contiguous storage
6053
6054 This function reads from a container with contiguous storage of 1-byte
6055 values. Compatible container types include `std::vector`, `std::string`,
6056 `std::array`, and `std::initializer_list`. User-defined containers can be
6057 used as long as they implement random-access iterators and a contiguous
6058 storage.
6059
6060 @pre The container storage is contiguous. Violating this precondition
6061 yields undefined behavior. **This precondition is enforced with an
6062 assertion.**
6063 @pre Each element of the container has a size of 1 byte. Violating this
6064 precondition yields undefined behavior. **This precondition is enforced
6065 with a static assertion.**
6066
6067 @warning There is no way to enforce all preconditions at compile-time. If
6068 the function is called with a noncompliant container and with
6069 assertions switched off, the behavior is undefined and will most
6070 likely yield segmentation violation.
6071
6072 @tparam ContiguousContainer container type with contiguous storage
6073 @param[in] c container to read from
6074 @param[in] cb a parser callback function of type @ref parser_callback_t
6075 which is used to control the deserialization by filtering unwanted values
6076 (optional)
6077
6078 @return result of the deserialization
6079
6080 @complexity Linear in the length of the input. The parser is a predictive
6081 LL(1) parser. The complexity can be higher if the parser callback function
6082 @a cb has a super-linear complexity.
6083
6084 @note A UTF-8 byte order mark is silently ignored.
6085
6086 @liveexample{The example below demonstrates the `parse()` function reading
6087 from a contiguous container.,parse__contiguouscontainer__parser_callback_t}
6088
6089 @since version 2.0.3
6090 */
6091 template<class ContiguousContainer, typename std::enable_if<
6092 not std::is_pointer<ContiguousContainer>::value and
6093 std::is_base_of<
6094 std::random_access_iterator_tag,
6095 typename std::iterator_traits<decltype(std::begin(std::declval<ContiguousContainer const>()))>::iterator_category>::value
6096 , int>::type = 0>
6097 static basic_json parse(const ContiguousContainer& c,
6098 const parser_callback_t cb = nullptr)
6099 {
6100 // delegate the call to the iterator-range parse overload
6101 return parse(std::begin(c), std::end(c), cb);
6102 }
6103
6104 /*!
6105 @brief deserialize from stream
6106
6107 Deserializes an input stream to a JSON value.
6108
6109 @param[in,out] i input stream to read a serialized JSON value from
6110 @param[in,out] j JSON value to write the deserialized input to
6111
6112 @throw std::invalid_argument in case of parse errors
6113
6114 @complexity Linear in the length of the input. The parser is a predictive
6115 LL(1) parser.
6116
6117 @note A UTF-8 byte order mark is silently ignored.
6118
6119 @liveexample{The example below shows how a JSON value is constructed by
6120 reading a serialization from a stream.,operator_deserialize}
6121
6122 @sa parse(std::istream&, const parser_callback_t) for a variant with a
6123 parser callback function to filter values while parsing
6124
6125 @since version 1.0.0
6126 */
6127 friend std::istream& operator<<(basic_json& j, std::istream& i)
6128 {
6129 j = parser(i).parse();
6130 return i;
6131 }
6132
6133 /*!
6134 @brief deserialize from stream
6135 @copydoc operator<<(basic_json&, std::istream&)
6136 */
6137 friend std::istream& operator>>(std::istream& i, basic_json& j)
6138 {
6139 j = parser(i).parse();
6140 return i;
6141 }
6142
6143 /// @}
6144
6145
6146 private:
6147 ///////////////////////////
6148 // convenience functions //
6149 ///////////////////////////
6150
6151 /*!
6152 @brief return the type as string
6153
6154 Returns the type name as string to be used in error messages - usually to
6155 indicate that a function was called on a wrong JSON type.
6156
6157 @return basically a string representation of a the @a m_type member
6158
6159 @complexity Constant.
6160
6161 @since version 1.0.0
6162 */
6163 std::string type_name() const
6164 {
6165 switch (m_type)
6166 {
6167 case value_t::null:
6168 return "null";
6169 case value_t::object:
6170 return "object";
6171 case value_t::array:
6172 return "array";
6173 case value_t::string:
6174 return "string";
6175 case value_t::boolean:
6176 return "boolean";
6177 case value_t::discarded:
6178 return "discarded";
6179 default:
6180 return "number";
6181 }
6182 }
6183
6184 /*!
6185 @brief calculates the extra space to escape a JSON string
6186
6187 @param[in] s the string to escape
6188 @return the number of characters required to escape string @a s
6189
6190 @complexity Linear in the length of string @a s.
6191 */
6192 static std::size_t extra_space(const string_t& s) noexcept
6193 {
6194 return std::accumulate(s.begin(), s.end(), size_t{},
6195 [](size_t res, typename string_t::value_type c)
6196 {
6197 switch (c)
6198 {
6199 case '"':
6200 case '\\':
6201 case '\b':
6202 case '\f':
6203 case '\n':
6204 case '\r':
6205 case '\t':
6206 {
6207 // from c (1 byte) to \x (2 bytes)
6208 return res + 1;
6209 }
6210
6211 default:
6212 {
6213 if (c >= 0x00 and c <= 0x1f)
6214 {
6215 // from c (1 byte) to \uxxxx (6 bytes)
6216 return res + 5;
6217 }
6218 else
6219 {
6220 return res;
6221 }
6222 }
6223 }
6224 });
6225 }
6226
6227 /*!
6228 @brief escape a string
6229
6230 Escape a string by replacing certain special characters by a sequence of
6231 an escape character (backslash) and another character and other control
6232 characters by a sequence of "\u" followed by a four-digit hex
6233 representation.
6234
6235 @param[in] s the string to escape
6236 @return the escaped string
6237
6238 @complexity Linear in the length of string @a s.
6239 */
6240 static string_t escape_string(const string_t& s)
6241 {
6242 const auto space = extra_space(s);
6243 if (space == 0)
6244 {
6245 return s;
6246 }
6247
6248 // create a result string of necessary size
6249 string_t result(s.size() + space, '\\');
6250 std::size_t pos = 0;
6251
6252 for (const auto& c : s)
6253 {
6254 switch (c)
6255 {
6256 // quotation mark (0x22)
6257 case '"':
6258 {
6259 result[pos + 1] = '"';
6260 pos += 2;
6261 break;
6262 }
6263
6264 // reverse solidus (0x5c)
6265 case '\\':
6266 {
6267 // nothing to change
6268 pos += 2;
6269 break;
6270 }
6271
6272 // backspace (0x08)
6273 case '\b':
6274 {
6275 result[pos + 1] = 'b';
6276 pos += 2;
6277 break;
6278 }
6279
6280 // formfeed (0x0c)
6281 case '\f':
6282 {
6283 result[pos + 1] = 'f';
6284 pos += 2;
6285 break;
6286 }
6287
6288 // newline (0x0a)
6289 case '\n':
6290 {
6291 result[pos + 1] = 'n';
6292 pos += 2;
6293 break;
6294 }
6295
6296 // carriage return (0x0d)
6297 case '\r':
6298 {
6299 result[pos + 1] = 'r';
6300 pos += 2;
6301 break;
6302 }
6303
6304 // horizontal tab (0x09)
6305 case '\t':
6306 {
6307 result[pos + 1] = 't';
6308 pos += 2;
6309 break;
6310 }
6311
6312 default:
6313 {
6314 if (c >= 0x00 and c <= 0x1f)
6315 {
6316 // convert a number 0..15 to its hex representation
6317 // (0..f)
6318 static const char hexify[16] =
6319 {
6320 '0', '1', '2', '3', '4', '5', '6', '7',
6321 '8', '9', 'a', 'b', 'c', 'd', 'e', 'f'
6322 };
6323
6324 // print character c as \uxxxx
6325 for (const char m :
6326 { 'u', '0', '0', hexify[c >> 4], hexify[c & 0x0f]
6327 })
6328 {
6329 result[++pos] = m;
6330 }
6331
6332 ++pos;
6333 }
6334 else
6335 {
6336 // all other characters are added as-is
6337 result[pos++] = c;
6338 }
6339 break;
6340 }
6341 }
6342 }
6343
6344 return result;
6345 }
6346
6347 /*!
6348 @brief internal implementation of the serialization function
6349
6350 This function is called by the public member function dump and organizes
6351 the serialization internally. The indentation level is propagated as
6352 additional parameter. In case of arrays and objects, the function is
6353 called recursively. Note that
6354
6355 - strings and object keys are escaped using `escape_string()`
6356 - integer numbers are converted implicitly via `operator<<`
6357 - floating-point numbers are converted to a string using `"%g"` format
6358
6359 @param[out] o stream to write to
6360 @param[in] pretty_print whether the output shall be pretty-printed
6361 @param[in] indent_step the indent level
6362 @param[in] current_indent the current indent level (only used internally)
6363 */
6364 void dump(std::ostream& o,
6365 const bool pretty_print,
6366 const unsigned int indent_step,
6367 const unsigned int current_indent = 0) const
6368 {
6369 // variable to hold indentation for recursive calls
6370 unsigned int new_indent = current_indent;
6371
6372 switch (m_type)
6373 {
6374 case value_t::object:
6375 {
6376 if (m_value.object->empty())
6377 {
6378 o << "{}";
6379 return;
6380 }
6381
6382 o << "{";
6383
6384 // increase indentation
6385 if (pretty_print)
6386 {
6387 new_indent += indent_step;
6388 o << "\n";
6389 }
6390
6391 for (auto i = m_value.object->cbegin(); i != m_value.object->cend(); ++i)
6392 {
6393 if (i != m_value.object->cbegin())
6394 {
6395 o << (pretty_print ? ",\n" : ",");
6396 }
6397 o << string_t(new_indent, ' ') << "\""
6398 << escape_string(i->first) << "\":"
6399 << (pretty_print ? " " : "");
6400 i->second.dump(o, pretty_print, indent_step, new_indent);
6401 }
6402
6403 // decrease indentation
6404 if (pretty_print)
6405 {
6406 new_indent -= indent_step;
6407 o << "\n";
6408 }
6409
6410 o << string_t(new_indent, ' ') + "}";
6411 return;
6412 }
6413
6414 case value_t::array:
6415 {
6416 if (m_value.array->empty())
6417 {
6418 o << "[]";
6419 return;
6420 }
6421
6422 o << "[";
6423
6424 // increase indentation
6425 if (pretty_print)
6426 {
6427 new_indent += indent_step;
6428 o << "\n";
6429 }
6430
6431 for (auto i = m_value.array->cbegin(); i != m_value.array->cend(); ++i)
6432 {
6433 if (i != m_value.array->cbegin())
6434 {
6435 o << (pretty_print ? ",\n" : ",");
6436 }
6437 o << string_t(new_indent, ' ');
6438 i->dump(o, pretty_print, indent_step, new_indent);
6439 }
6440
6441 // decrease indentation
6442 if (pretty_print)
6443 {
6444 new_indent -= indent_step;
6445 o << "\n";
6446 }
6447
6448 o << string_t(new_indent, ' ') << "]";
6449 return;
6450 }
6451
6452 case value_t::string:
6453 {
6454 o << string_t("\"") << escape_string(*m_value.string) << "\"";
6455 return;
6456 }
6457
6458 case value_t::boolean:
6459 {
6460 o << (m_value.boolean ? "true" : "false");
6461 return;
6462 }
6463
6464 case value_t::number_integer:
6465 {
6466 o << m_value.number_integer;
6467 return;
6468 }
6469
6470 case value_t::number_unsigned:
6471 {
6472 o << m_value.number_unsigned;
6473 return;
6474 }
6475
6476 case value_t::number_float:
6477 {
6478 if (m_value.number_float == 0)
6479 {
6480 // special case for zero to get "0.0"/"-0.0"
6481 o << (std::signbit(m_value.number_float) ? "-0.0" : "0.0");
6482 }
6483 else
6484 {
6485 o << m_value.number_float;
6486 }
6487 return;
6488 }
6489
6490 case value_t::discarded:
6491 {
6492 o << "<discarded>";
6493 return;
6494 }
6495
6496 case value_t::null:
6497 {
6498 o << "null";
6499 return;
6500 }
6501 }
6502 }
6503
6504 private:
6505 //////////////////////
6506 // member variables //
6507 //////////////////////
6508
6509 /// the type of the current element
6510 value_t m_type = value_t::null;
6511
6512 /// the value of the current element
6513 json_value m_value = {};
6514
6515
6516 private:
6517 ///////////////
6518 // iterators //
6519 ///////////////
6520
6521 /*!
6522 @brief an iterator for primitive JSON types
6523
6524 This class models an iterator for primitive JSON types (boolean, number,
6525 string). It's only purpose is to allow the iterator/const_iterator classes
6526 to "iterate" over primitive values. Internally, the iterator is modeled by
6527 a `difference_type` variable. Value begin_value (`0`) models the begin,
6528 end_value (`1`) models past the end.
6529 */
6530 class primitive_iterator_t
6531 {
6532 public:
6533 /// set iterator to a defined beginning
6534 void set_begin() noexcept
6535 {
6536 m_it = begin_value;
6537 }
6538
6539 /// set iterator to a defined past the end
6540 void set_end() noexcept
6541 {
6542 m_it = end_value;
6543 }
6544
6545 /// return whether the iterator can be dereferenced
6546 constexpr bool is_begin() const noexcept
6547 {
6548 return (m_it == begin_value);
6549 }
6550
6551 /// return whether the iterator is at end
6552 constexpr bool is_end() const noexcept
6553 {
6554 return (m_it == end_value);
6555 }
6556
6557 /// return reference to the value to change and compare
6558 operator difference_type& () noexcept
6559 {
6560 return m_it;
6561 }
6562
6563 /// return value to compare
6564 constexpr operator difference_type () const noexcept
6565 {
6566 return m_it;
6567 }
6568
6569 private:
6570 static constexpr difference_type begin_value = 0;
6571 static constexpr difference_type end_value = begin_value + 1;
6572
6573 /// iterator as signed integer type
6574 difference_type m_it = std::numeric_limits<std::ptrdiff_t>::denorm_min();
6575 };
6576
6577 /*!
6578 @brief an iterator value
6579
6580 @note This structure could easily be a union, but MSVC currently does not
6581 allow unions members with complex constructors, see
6582 https://github.com/nlohmann/json/pull/105.
6583 */
6584 struct internal_iterator
6585 {
6586 /// iterator for JSON objects
6587 typename object_t::iterator object_iterator;
6588 /// iterator for JSON arrays
6589 typename array_t::iterator array_iterator;
6590 /// generic iterator for all other types
6591 primitive_iterator_t primitive_iterator;
6592
6593 /// create an uninitialized internal_iterator
6594 internal_iterator() noexcept
6595 : object_iterator(), array_iterator(), primitive_iterator()
6596 {}
6597 };
6598
6599 /// proxy class for the iterator_wrapper functions
6600 template<typename IteratorType>
6601 class iteration_proxy
6602 {
6603 private:
6604 /// helper class for iteration
6605 class iteration_proxy_internal
6606 {
6607 private:
6608 /// the iterator
6609 IteratorType anchor;
6610 /// an index for arrays (used to create key names)
6611 size_t array_index = 0;
6612
6613 public:
6614 explicit iteration_proxy_internal(IteratorType it) noexcept
6615 : anchor(it)
6616 {}
6617
6618 /// dereference operator (needed for range-based for)
6619 iteration_proxy_internal& operator*()
6620 {
6621 return *this;
6622 }
6623
6624 /// increment operator (needed for range-based for)
6625 iteration_proxy_internal& operator++()
6626 {
6627 ++anchor;
6628 ++array_index;
6629
6630 return *this;
6631 }
6632
6633 /// inequality operator (needed for range-based for)
6634 bool operator!= (const iteration_proxy_internal& o) const
6635 {
6636 return anchor != o.anchor;
6637 }
6638
6639 /// return key of the iterator
6640 typename basic_json::string_t key() const
6641 {
6642 assert(anchor.m_object != nullptr);
6643
6644 switch (anchor.m_object->type())
6645 {
6646 // use integer array index as key
6647 case value_t::array:
6648 {
6649 return std::to_string(array_index);
6650 }
6651
6652 // use key from the object
6653 case value_t::object:
6654 {
6655 return anchor.key();
6656 }
6657
6658 // use an empty key for all primitive types
6659 default:
6660 {
6661 return "";
6662 }
6663 }
6664 }
6665
6666 /// return value of the iterator
6667 typename IteratorType::reference value() const
6668 {
6669 return anchor.value();
6670 }
6671 };
6672
6673 /// the container to iterate
6674 typename IteratorType::reference container;
6675
6676 public:
6677 /// construct iteration proxy from a container
6678 explicit iteration_proxy(typename IteratorType::reference cont)
6679 : container(cont)
6680 {}
6681
6682 /// return iterator begin (needed for range-based for)
6683 iteration_proxy_internal begin() noexcept
6684 {
6685 return iteration_proxy_internal(container.begin());
6686 }
6687
6688 /// return iterator end (needed for range-based for)
6689 iteration_proxy_internal end() noexcept
6690 {
6691 return iteration_proxy_internal(container.end());
6692 }
6693 };
6694
6695 public:
6696 /*!
6697 @brief a const random access iterator for the @ref basic_json class
6698
6699 This class implements a const iterator for the @ref basic_json class. From
6700 this class, the @ref iterator class is derived.
6701
6702 @note An iterator is called *initialized* when a pointer to a JSON value
6703 has been set (e.g., by a constructor or a copy assignment). If the
6704 iterator is default-constructed, it is *uninitialized* and most
6705 methods are undefined. **The library uses assertions to detect calls
6706 on uninitialized iterators.**
6707
6708 @requirement The class satisfies the following concept requirements:
6709 - [RandomAccessIterator](http://en.cppreference.com/w/cpp/concept/RandomAccessIterator):
6710 The iterator that can be moved to point (forward and backward) to any
6711 element in constant time.
6712
6713 @since version 1.0.0
6714 */
6715 class const_iterator : public std::iterator<std::random_access_iterator_tag, const basic_json>
6716 {
6717 /// allow basic_json to access private members
6718 friend class basic_json;
6719
6720 public:
6721 /// the type of the values when the iterator is dereferenced
6722 using value_type = typename basic_json::value_type;
6723 /// a type to represent differences between iterators
6724 using difference_type = typename basic_json::difference_type;
6725 /// defines a pointer to the type iterated over (value_type)
6726 using pointer = typename basic_json::const_pointer;
6727 /// defines a reference to the type iterated over (value_type)
6728 using reference = typename basic_json::const_reference;
6729 /// the category of the iterator
6730 using iterator_category = std::bidirectional_iterator_tag;
6731
6732 /// default constructor
6733 const_iterator() = default;
6734
6735 /*!
6736 @brief constructor for a given JSON instance
6737 @param[in] object pointer to a JSON object for this iterator
6738 @pre object != nullptr
6739 @post The iterator is initialized; i.e. `m_object != nullptr`.
6740 */
6741 explicit const_iterator(pointer object) noexcept
6742 : m_object(object)
6743 {
6744 assert(m_object != nullptr);
6745
6746 switch (m_object->m_type)
6747 {
6748 case basic_json::value_t::object:
6749 {
6750 m_it.object_iterator = typename object_t::iterator();
6751 break;
6752 }
6753
6754 case basic_json::value_t::array:
6755 {
6756 m_it.array_iterator = typename array_t::iterator();
6757 break;
6758 }
6759
6760 default:
6761 {
6762 m_it.primitive_iterator = primitive_iterator_t();
6763 break;
6764 }
6765 }
6766 }
6767
6768 /*!
6769 @brief copy constructor given a non-const iterator
6770 @param[in] other iterator to copy from
6771 @note It is not checked whether @a other is initialized.
6772 */
6773 explicit const_iterator(const iterator& other) noexcept
6774 : m_object(other.m_object)
6775 {
6776 if (m_object != nullptr)
6777 {
6778 switch (m_object->m_type)
6779 {
6780 case basic_json::value_t::object:
6781 {
6782 m_it.object_iterator = other.m_it.object_iterator;
6783 break;
6784 }
6785
6786 case basic_json::value_t::array:
6787 {
6788 m_it.array_iterator = other.m_it.array_iterator;
6789 break;
6790 }
6791
6792 default:
6793 {
6794 m_it.primitive_iterator = other.m_it.primitive_iterator;
6795 break;
6796 }
6797 }
6798 }
6799 }
6800
6801 /*!
6802 @brief copy constructor
6803 @param[in] other iterator to copy from
6804 @note It is not checked whether @a other is initialized.
6805 */
6806 const_iterator(const const_iterator& other) noexcept
6807 : m_object(other.m_object), m_it(other.m_it)
6808 {}
6809
6810 /*!
6811 @brief copy assignment
6812 @param[in,out] other iterator to copy from
6813 @note It is not checked whether @a other is initialized.
6814 */
6815 const_iterator& operator=(const_iterator other) noexcept(
6816 std::is_nothrow_move_constructible<pointer>::value and
6817 std::is_nothrow_move_assignable<pointer>::value and
6818 std::is_nothrow_move_constructible<internal_iterator>::value and
6819 std::is_nothrow_move_assignable<internal_iterator>::value
6820 )
6821 {
6822 std::swap(m_object, other.m_object);
6823 std::swap(m_it, other.m_it);
6824 return *this;
6825 }
6826
6827 private:
6828 /*!
6829 @brief set the iterator to the first value
6830 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6831 */
6832 void set_begin() noexcept
6833 {
6834 assert(m_object != nullptr);
6835
6836 switch (m_object->m_type)
6837 {
6838 case basic_json::value_t::object:
6839 {
6840 m_it.object_iterator = m_object->m_value.object->begin();
6841 break;
6842 }
6843
6844 case basic_json::value_t::array:
6845 {
6846 m_it.array_iterator = m_object->m_value.array->begin();
6847 break;
6848 }
6849
6850 case basic_json::value_t::null:
6851 {
6852 // set to end so begin()==end() is true: null is empty
6853 m_it.primitive_iterator.set_end();
6854 break;
6855 }
6856
6857 default:
6858 {
6859 m_it.primitive_iterator.set_begin();
6860 break;
6861 }
6862 }
6863 }
6864
6865 /*!
6866 @brief set the iterator past the last value
6867 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6868 */
6869 void set_end() noexcept
6870 {
6871 assert(m_object != nullptr);
6872
6873 switch (m_object->m_type)
6874 {
6875 case basic_json::value_t::object:
6876 {
6877 m_it.object_iterator = m_object->m_value.object->end();
6878 break;
6879 }
6880
6881 case basic_json::value_t::array:
6882 {
6883 m_it.array_iterator = m_object->m_value.array->end();
6884 break;
6885 }
6886
6887 default:
6888 {
6889 m_it.primitive_iterator.set_end();
6890 break;
6891 }
6892 }
6893 }
6894
6895 public:
6896 /*!
6897 @brief return a reference to the value pointed to by the iterator
6898 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6899 */
6900 reference operator*() const
6901 {
6902 assert(m_object != nullptr);
6903
6904 switch (m_object->m_type)
6905 {
6906 case basic_json::value_t::object:
6907 {
6908 assert(m_it.object_iterator != m_object->m_value.object->end());
6909 return m_it.object_iterator->second;
6910 }
6911
6912 case basic_json::value_t::array:
6913 {
6914 assert(m_it.array_iterator != m_object->m_value.array->end());
6915 return *m_it.array_iterator;
6916 }
6917
6918 case basic_json::value_t::null:
6919 {
6920 throw std::out_of_range("cannot get value");
6921 }
6922
6923 default:
6924 {
6925 if (m_it.primitive_iterator.is_begin())
6926 {
6927 return *m_object;
6928 }
6929 else
6930 {
6931 throw std::out_of_range("cannot get value");
6932 }
6933 }
6934 }
6935 }
6936
6937 /*!
6938 @brief dereference the iterator
6939 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6940 */
6941 pointer operator->() const
6942 {
6943 assert(m_object != nullptr);
6944
6945 switch (m_object->m_type)
6946 {
6947 case basic_json::value_t::object:
6948 {
6949 assert(m_it.object_iterator != m_object->m_value.object->end());
6950 return &(m_it.object_iterator->second);
6951 }
6952
6953 case basic_json::value_t::array:
6954 {
6955 assert(m_it.array_iterator != m_object->m_value.array->end());
6956 return &*m_it.array_iterator;
6957 }
6958
6959 default:
6960 {
6961 if (m_it.primitive_iterator.is_begin())
6962 {
6963 return m_object;
6964 }
6965 else
6966 {
6967 throw std::out_of_range("cannot get value");
6968 }
6969 }
6970 }
6971 }
6972
6973 /*!
6974 @brief post-increment (it++)
6975 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6976 */
6977 const_iterator operator++(int)
6978 {
6979 auto result = *this;
6980 ++(*this);
6981 return result;
6982 }
6983
6984 /*!
6985 @brief pre-increment (++it)
6986 @pre The iterator is initialized; i.e. `m_object != nullptr`.
6987 */
6988 const_iterator& operator++()
6989 {
6990 assert(m_object != nullptr);
6991
6992 switch (m_object->m_type)
6993 {
6994 case basic_json::value_t::object:
6995 {
6996 std::advance(m_it.object_iterator, 1);
6997 break;
6998 }
6999
7000 case basic_json::value_t::array:
7001 {
7002 std::advance(m_it.array_iterator, 1);
7003 break;
7004 }
7005
7006 default:
7007 {
7008 ++m_it.primitive_iterator;
7009 break;
7010 }
7011 }
7012
7013 return *this;
7014 }
7015
7016 /*!
7017 @brief post-decrement (it--)
7018 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7019 */
7020 const_iterator operator--(int)
7021 {
7022 auto result = *this;
7023 --(*this);
7024 return result;
7025 }
7026
7027 /*!
7028 @brief pre-decrement (--it)
7029 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7030 */
7031 const_iterator& operator--()
7032 {
7033 assert(m_object != nullptr);
7034
7035 switch (m_object->m_type)
7036 {
7037 case basic_json::value_t::object:
7038 {
7039 std::advance(m_it.object_iterator, -1);
7040 break;
7041 }
7042
7043 case basic_json::value_t::array:
7044 {
7045 std::advance(m_it.array_iterator, -1);
7046 break;
7047 }
7048
7049 default:
7050 {
7051 --m_it.primitive_iterator;
7052 break;
7053 }
7054 }
7055
7056 return *this;
7057 }
7058
7059 /*!
7060 @brief comparison: equal
7061 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7062 */
7063 bool operator==(const const_iterator& other) const
7064 {
7065 // if objects are not the same, the comparison is undefined
7066 if (m_object != other.m_object)
7067 {
7068 throw std::domain_error("cannot compare iterators of different containers");
7069 }
7070
7071 assert(m_object != nullptr);
7072
7073 switch (m_object->m_type)
7074 {
7075 case basic_json::value_t::object:
7076 {
7077 return (m_it.object_iterator == other.m_it.object_iterator);
7078 }
7079
7080 case basic_json::value_t::array:
7081 {
7082 return (m_it.array_iterator == other.m_it.array_iterator);
7083 }
7084
7085 default:
7086 {
7087 return (m_it.primitive_iterator == other.m_it.primitive_iterator);
7088 }
7089 }
7090 }
7091
7092 /*!
7093 @brief comparison: not equal
7094 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7095 */
7096 bool operator!=(const const_iterator& other) const
7097 {
7098 return not operator==(other);
7099 }
7100
7101 /*!
7102 @brief comparison: smaller
7103 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7104 */
7105 bool operator<(const const_iterator& other) const
7106 {
7107 // if objects are not the same, the comparison is undefined
7108 if (m_object != other.m_object)
7109 {
7110 throw std::domain_error("cannot compare iterators of different containers");
7111 }
7112
7113 assert(m_object != nullptr);
7114
7115 switch (m_object->m_type)
7116 {
7117 case basic_json::value_t::object:
7118 {
7119 throw std::domain_error("cannot compare order of object iterators");
7120 }
7121
7122 case basic_json::value_t::array:
7123 {
7124 return (m_it.array_iterator < other.m_it.array_iterator);
7125 }
7126
7127 default:
7128 {
7129 return (m_it.primitive_iterator < other.m_it.primitive_iterator);
7130 }
7131 }
7132 }
7133
7134 /*!
7135 @brief comparison: less than or equal
7136 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7137 */
7138 bool operator<=(const const_iterator& other) const
7139 {
7140 return not other.operator < (*this);
7141 }
7142
7143 /*!
7144 @brief comparison: greater than
7145 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7146 */
7147 bool operator>(const const_iterator& other) const
7148 {
7149 return not operator<=(other);
7150 }
7151
7152 /*!
7153 @brief comparison: greater than or equal
7154 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7155 */
7156 bool operator>=(const const_iterator& other) const
7157 {
7158 return not operator<(other);
7159 }
7160
7161 /*!
7162 @brief add to iterator
7163 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7164 */
7165 const_iterator& operator+=(difference_type i)
7166 {
7167 assert(m_object != nullptr);
7168
7169 switch (m_object->m_type)
7170 {
7171 case basic_json::value_t::object:
7172 {
7173 throw std::domain_error("cannot use offsets with object iterators");
7174 }
7175
7176 case basic_json::value_t::array:
7177 {
7178 std::advance(m_it.array_iterator, i);
7179 break;
7180 }
7181
7182 default:
7183 {
7184 m_it.primitive_iterator += i;
7185 break;
7186 }
7187 }
7188
7189 return *this;
7190 }
7191
7192 /*!
7193 @brief subtract from iterator
7194 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7195 */
7196 const_iterator& operator-=(difference_type i)
7197 {
7198 return operator+=(-i);
7199 }
7200
7201 /*!
7202 @brief add to iterator
7203 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7204 */
7205 const_iterator operator+(difference_type i)
7206 {
7207 auto result = *this;
7208 result += i;
7209 return result;
7210 }
7211
7212 /*!
7213 @brief subtract from iterator
7214 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7215 */
7216 const_iterator operator-(difference_type i)
7217 {
7218 auto result = *this;
7219 result -= i;
7220 return result;
7221 }
7222
7223 /*!
7224 @brief return difference
7225 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7226 */
7227 difference_type operator-(const const_iterator& other) const
7228 {
7229 assert(m_object != nullptr);
7230
7231 switch (m_object->m_type)
7232 {
7233 case basic_json::value_t::object:
7234 {
7235 throw std::domain_error("cannot use offsets with object iterators");
7236 }
7237
7238 case basic_json::value_t::array:
7239 {
7240 return m_it.array_iterator - other.m_it.array_iterator;
7241 }
7242
7243 default:
7244 {
7245 return m_it.primitive_iterator - other.m_it.primitive_iterator;
7246 }
7247 }
7248 }
7249
7250 /*!
7251 @brief access to successor
7252 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7253 */
7254 reference operator[](difference_type n) const
7255 {
7256 assert(m_object != nullptr);
7257
7258 switch (m_object->m_type)
7259 {
7260 case basic_json::value_t::object:
7261 {
7262 throw std::domain_error("cannot use operator[] for object iterators");
7263 }
7264
7265 case basic_json::value_t::array:
7266 {
7267 return *std::next(m_it.array_iterator, n);
7268 }
7269
7270 case basic_json::value_t::null:
7271 {
7272 throw std::out_of_range("cannot get value");
7273 }
7274
7275 default:
7276 {
7277 if (m_it.primitive_iterator == -n)
7278 {
7279 return *m_object;
7280 }
7281 else
7282 {
7283 throw std::out_of_range("cannot get value");
7284 }
7285 }
7286 }
7287 }
7288
7289 /*!
7290 @brief return the key of an object iterator
7291 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7292 */
7293 typename object_t::key_type key() const
7294 {
7295 assert(m_object != nullptr);
7296
7297 if (m_object->is_object())
7298 {
7299 return m_it.object_iterator->first;
7300 }
7301 else
7302 {
7303 throw std::domain_error("cannot use key() for non-object iterators");
7304 }
7305 }
7306
7307 /*!
7308 @brief return the value of an iterator
7309 @pre The iterator is initialized; i.e. `m_object != nullptr`.
7310 */
7311 reference value() const
7312 {
7313 return operator*();
7314 }
7315
7316 private:
7317 /// associated JSON instance
7318 pointer m_object = nullptr;
7319 /// the actual iterator of the associated instance
7320 internal_iterator m_it = internal_iterator();
7321 };
7322
7323 /*!
7324 @brief a mutable random access iterator for the @ref basic_json class
7325
7326 @requirement The class satisfies the following concept requirements:
7327 - [RandomAccessIterator](http://en.cppreference.com/w/cpp/concept/RandomAccessIterator):
7328 The iterator that can be moved to point (forward and backward) to any
7329 element in constant time.
7330 - [OutputIterator](http://en.cppreference.com/w/cpp/concept/OutputIterator):
7331 It is possible to write to the pointed-to element.
7332
7333 @since version 1.0.0
7334 */
7335 class iterator : public const_iterator
7336 {
7337 public:
7338 using base_iterator = const_iterator;
7339 using pointer = typename basic_json::pointer;
7340 using reference = typename basic_json::reference;
7341
7342 /// default constructor
7343 iterator() = default;
7344
7345 /// constructor for a given JSON instance
7346 explicit iterator(pointer object) noexcept
7347 : base_iterator(object)
7348 {}
7349
7350 /// copy constructor
7351 iterator(const iterator& other) noexcept
7352 : base_iterator(other)
7353 {}
7354
7355 /// copy assignment
7356 iterator& operator=(iterator other) noexcept(
7357 std::is_nothrow_move_constructible<pointer>::value and
7358 std::is_nothrow_move_assignable<pointer>::value and
7359 std::is_nothrow_move_constructible<internal_iterator>::value and
7360 std::is_nothrow_move_assignable<internal_iterator>::value
7361 )
7362 {
7363 base_iterator::operator=(other);
7364 return *this;
7365 }
7366
7367 /// return a reference to the value pointed to by the iterator
7368 reference operator*() const
7369 {
7370 return const_cast<reference>(base_iterator::operator*());
7371 }
7372
7373 /// dereference the iterator
7374 pointer operator->() const
7375 {
7376 return const_cast<pointer>(base_iterator::operator->());
7377 }
7378
7379 /// post-increment (it++)
7380 iterator operator++(int)
7381 {
7382 iterator result = *this;
7383 base_iterator::operator++();
7384 return result;
7385 }
7386
7387 /// pre-increment (++it)
7388 iterator& operator++()
7389 {
7390 base_iterator::operator++();
7391 return *this;
7392 }
7393
7394 /// post-decrement (it--)
7395 iterator operator--(int)
7396 {
7397 iterator result = *this;
7398 base_iterator::operator--();
7399 return result;
7400 }
7401
7402 /// pre-decrement (--it)
7403 iterator& operator--()
7404 {
7405 base_iterator::operator--();
7406 return *this;
7407 }
7408
7409 /// add to iterator
7410 iterator& operator+=(difference_type i)
7411 {
7412 base_iterator::operator+=(i);
7413 return *this;
7414 }
7415
7416 /// subtract from iterator
7417 iterator& operator-=(difference_type i)
7418 {
7419 base_iterator::operator-=(i);
7420 return *this;
7421 }
7422
7423 /// add to iterator
7424 iterator operator+(difference_type i)
7425 {
7426 auto result = *this;
7427 result += i;
7428 return result;
7429 }
7430
7431 /// subtract from iterator
7432 iterator operator-(difference_type i)
7433 {
7434 auto result = *this;
7435 result -= i;
7436 return result;
7437 }
7438
7439 /// return difference
7440 difference_type operator-(const iterator& other) const
7441 {
7442 return base_iterator::operator-(other);
7443 }
7444
7445 /// access to successor
7446 reference operator[](difference_type n) const
7447 {
7448 return const_cast<reference>(base_iterator::operator[](n));
7449 }
7450
7451 /// return the value of an iterator
7452 reference value() const
7453 {
7454 return const_cast<reference>(base_iterator::value());
7455 }
7456 };
7457
7458 /*!
7459 @brief a template for a reverse iterator class
7460
7461 @tparam Base the base iterator type to reverse. Valid types are @ref
7462 iterator (to create @ref reverse_iterator) and @ref const_iterator (to
7463 create @ref const_reverse_iterator).
7464
7465 @requirement The class satisfies the following concept requirements:
7466 - [RandomAccessIterator](http://en.cppreference.com/w/cpp/concept/RandomAccessIterator):
7467 The iterator that can be moved to point (forward and backward) to any
7468 element in constant time.
7469 - [OutputIterator](http://en.cppreference.com/w/cpp/concept/OutputIterator):
7470 It is possible to write to the pointed-to element (only if @a Base is
7471 @ref iterator).
7472
7473 @since version 1.0.0
7474 */
7475 template<typename Base>
7476 class json_reverse_iterator : public std::reverse_iterator<Base>
7477 {
7478 public:
7479 /// shortcut to the reverse iterator adaptor
7480 using base_iterator = std::reverse_iterator<Base>;
7481 /// the reference type for the pointed-to element
7482 using reference = typename Base::reference;
7483
7484 /// create reverse iterator from iterator
7485 json_reverse_iterator(const typename base_iterator::iterator_type& it) noexcept
7486 : base_iterator(it)
7487 {}
7488
7489 /// create reverse iterator from base class
7490 json_reverse_iterator(const base_iterator& it) noexcept
7491 : base_iterator(it)
7492 {}
7493
7494 /// post-increment (it++)
7495 json_reverse_iterator operator++(int)
7496 {
7497 return base_iterator::operator++(1);
7498 }
7499
7500 /// pre-increment (++it)
7501 json_reverse_iterator& operator++()
7502 {
7503 base_iterator::operator++();
7504 return *this;
7505 }
7506
7507 /// post-decrement (it--)
7508 json_reverse_iterator operator--(int)
7509 {
7510 return base_iterator::operator--(1);
7511 }
7512
7513 /// pre-decrement (--it)
7514 json_reverse_iterator& operator--()
7515 {
7516 base_iterator::operator--();
7517 return *this;
7518 }
7519
7520 /// add to iterator
7521 json_reverse_iterator& operator+=(difference_type i)
7522 {
7523 base_iterator::operator+=(i);
7524 return *this;
7525 }
7526
7527 /// add to iterator
7528 json_reverse_iterator operator+(difference_type i) const
7529 {
7530 auto result = *this;
7531 result += i;
7532 return result;
7533 }
7534
7535 /// subtract from iterator
7536 json_reverse_iterator operator-(difference_type i) const
7537 {
7538 auto result = *this;
7539 result -= i;
7540 return result;
7541 }
7542
7543 /// return difference
7544 difference_type operator-(const json_reverse_iterator& other) const
7545 {
7546 return this->base() - other.base();
7547 }
7548
7549 /// access to successor
7550 reference operator[](difference_type n) const
7551 {
7552 return *(this->operator+(n));
7553 }
7554
7555 /// return the key of an object iterator
7556 typename object_t::key_type key() const
7557 {
7558 auto it = --this->base();
7559 return it.key();
7560 }
7561
7562 /// return the value of an iterator
7563 reference value() const
7564 {
7565 auto it = --this->base();
7566 return it.operator * ();
7567 }
7568 };
7569
7570
7571 private:
7572 //////////////////////
7573 // lexer and parser //
7574 //////////////////////
7575
7576 /*!
7577 @brief lexical analysis
7578
7579 This class organizes the lexical analysis during JSON deserialization. The
7580 core of it is a scanner generated by [re2c](http://re2c.org) that
7581 processes a buffer and recognizes tokens according to RFC 7159.
7582 */
7583 class lexer
7584 {
7585 public:
7586 /// token types for the parser
7587 enum class token_type
7588 {
7589 uninitialized, ///< indicating the scanner is uninitialized
7590 literal_true, ///< the `true` literal
7591 literal_false, ///< the `false` literal
7592 literal_null, ///< the `null` literal
7593 value_string, ///< a string -- use get_string() for actual value
7594 value_number, ///< a number -- use get_number() for actual value
7595 begin_array, ///< the character for array begin `[`
7596 begin_object, ///< the character for object begin `{`
7597 end_array, ///< the character for array end `]`
7598 end_object, ///< the character for object end `}`
7599 name_separator, ///< the name separator `:`
7600 value_separator, ///< the value separator `,`
7601 parse_error, ///< indicating a parse error
7602 end_of_input ///< indicating the end of the input buffer
7603 };
7604
7605 /// the char type to use in the lexer
7606 using lexer_char_t = unsigned char;
7607
7608 /// a lexer from a buffer with given length
7609 lexer(const lexer_char_t* buff, const size_t len) noexcept
7610 : m_content(buff)
7611 {
7612 assert(m_content != nullptr);
7613 m_start = m_cursor = m_content;
7614 m_limit = m_content + len;
7615 }
7616
7617 /// a lexer from an input stream
7618 explicit lexer(std::istream& s)
7619 : m_stream(&s), m_line_buffer()
7620 {
7621 // fill buffer
7622 fill_line_buffer();
7623
7624 // skip UTF-8 byte-order mark
7625 if (m_line_buffer.size() >= 3 and m_line_buffer.substr(0, 3) == "\xEF\xBB\xBF")
7626 {
7627 m_line_buffer[0] = ' ';
7628 m_line_buffer[1] = ' ';
7629 m_line_buffer[2] = ' ';
7630 }
7631 }
7632
7633 // switch off unwanted functions (due to pointer members)
7634 lexer() = delete;
7635 lexer(const lexer&) = delete;
7636 lexer operator=(const lexer&) = delete;
7637
7638 /*!
7639 @brief create a string from one or two Unicode code points
7640
7641 There are two cases: (1) @a codepoint1 is in the Basic Multilingual
7642 Plane (U+0000 through U+FFFF) and @a codepoint2 is 0, or (2)
7643 @a codepoint1 and @a codepoint2 are a UTF-16 surrogate pair to
7644 represent a code point above U+FFFF.
7645
7646 @param[in] codepoint1 the code point (can be high surrogate)
7647 @param[in] codepoint2 the code point (can be low surrogate or 0)
7648
7649 @return string representation of the code point; the length of the
7650 result string is between 1 and 4 characters.
7651
7652 @throw std::out_of_range if code point is > 0x10ffff; example: `"code
7653 points above 0x10FFFF are invalid"`
7654 @throw std::invalid_argument if the low surrogate is invalid; example:
7655 `""missing or wrong low surrogate""`
7656
7657 @complexity Constant.
7658
7659 @see <http://en.wikipedia.org/wiki/UTF-8#Sample_code>
7660 */
7661 static string_t to_unicode(const std::size_t codepoint1,
7662 const std::size_t codepoint2 = 0)
7663 {
7664 // calculate the code point from the given code points
7665 std::size_t codepoint = codepoint1;
7666
7667 // check if codepoint1 is a high surrogate
7668 if (codepoint1 >= 0xD800 and codepoint1 <= 0xDBFF)
7669 {
7670 // check if codepoint2 is a low surrogate
7671 if (codepoint2 >= 0xDC00 and codepoint2 <= 0xDFFF)
7672 {
7673 codepoint =
7674 // high surrogate occupies the most significant 22 bits
7675 (codepoint1 << 10)
7676 // low surrogate occupies the least significant 15 bits
7677 + codepoint2
7678 // there is still the 0xD800, 0xDC00 and 0x10000 noise
7679 // in the result so we have to subtract with:
7680 // (0xD800 << 10) + DC00 - 0x10000 = 0x35FDC00
7681 - 0x35FDC00;
7682 }
7683 else
7684 {
7685 throw std::invalid_argument("missing or wrong low surrogate");
7686 }
7687 }
7688
7689 string_t result;
7690
7691 if (codepoint < 0x80)
7692 {
7693 // 1-byte characters: 0xxxxxxx (ASCII)
7694 result.append(1, static_cast<typename string_t::value_type>(codepoint));
7695 }
7696 else if (codepoint <= 0x7ff)
7697 {
7698 // 2-byte characters: 110xxxxx 10xxxxxx
7699 result.append(1, static_cast<typename string_t::value_type>(0xC0 | ((codepoint >> 6) & 0x1F)));
7700 result.append(1, static_cast<typename string_t::value_type>(0x80 | (codepoint & 0x3F)));
7701 }
7702 else if (codepoint <= 0xffff)
7703 {
7704 // 3-byte characters: 1110xxxx 10xxxxxx 10xxxxxx
7705 result.append(1, static_cast<typename string_t::value_type>(0xE0 | ((codepoint >> 12) & 0x0F)));
7706 result.append(1, static_cast<typename string_t::value_type>(0x80 | ((codepoint >> 6) & 0x3F)));
7707 result.append(1, static_cast<typename string_t::value_type>(0x80 | (codepoint & 0x3F)));
7708 }
7709 else if (codepoint <= 0x10ffff)
7710 {
7711 // 4-byte characters: 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
7712 result.append(1, static_cast<typename string_t::value_type>(0xF0 | ((codepoint >> 18) & 0x07)));
7713 result.append(1, static_cast<typename string_t::value_type>(0x80 | ((codepoint >> 12) & 0x3F)));
7714 result.append(1, static_cast<typename string_t::value_type>(0x80 | ((codepoint >> 6) & 0x3F)));
7715 result.append(1, static_cast<typename string_t::value_type>(0x80 | (codepoint & 0x3F)));
7716 }
7717 else
7718 {
7719 throw std::out_of_range("code points above 0x10FFFF are invalid");
7720 }
7721
7722 return result;
7723 }
7724
7725 /// return name of values of type token_type (only used for errors)
7726 static std::string token_type_name(const token_type t)
7727 {
7728 switch (t)
7729 {
7730 case token_type::uninitialized:
7731 return "<uninitialized>";
7732 case token_type::literal_true:
7733 return "true literal";
7734 case token_type::literal_false:
7735 return "false literal";
7736 case token_type::literal_null:
7737 return "null literal";
7738 case token_type::value_string:
7739 return "string literal";
7740 case token_type::value_number:
7741 return "number literal";
7742 case token_type::begin_array:
7743 return "'['";
7744 case token_type::begin_object:
7745 return "'{'";
7746 case token_type::end_array:
7747 return "']'";
7748 case token_type::end_object:
7749 return "'}'";
7750 case token_type::name_separator:
7751 return "':'";
7752 case token_type::value_separator:
7753 return "','";
7754 case token_type::parse_error:
7755 return "<parse error>";
7756 case token_type::end_of_input:
7757 return "end of input";
7758 default:
7759 {
7760 // catch non-enum values
7761 return "unknown token"; // LCOV_EXCL_LINE
7762 }
7763 }
7764 }
7765
7766 /*!
7767 This function implements a scanner for JSON. It is specified using
7768 regular expressions that try to follow RFC 7159 as close as possible.
7769 These regular expressions are then translated into a minimized
7770 deterministic finite automaton (DFA) by the tool
7771 [re2c](http://re2c.org). As a result, the translated code for this
7772 function consists of a large block of code with `goto` jumps.
7773
7774 @return the class of the next token read from the buffer
7775
7776 @complexity Linear in the length of the input.\n
7777
7778 Proposition: The loop below will always terminate for finite input.\n
7779
7780 Proof (by contradiction): Assume a finite input. To loop forever, the
7781 loop must never hit code with a `break` statement. The only code
7782 snippets without a `break` statement are the continue statements for
7783 whitespace and byte-order-marks. To loop forever, the input must be an
7784 infinite sequence of whitespace or byte-order-marks. This contradicts
7785 the assumption of finite input, q.e.d.
7786 */
7787 token_type scan()
7788 {
7789 while (true)
7790 {
7791 // pointer for backtracking information
7792 m_marker = nullptr;
7793
7794 // remember the begin of the token
7795 m_start = m_cursor;
7796 assert(m_start != nullptr);
7797
7798
7799 {
7800 lexer_char_t yych;
7801 unsigned int yyaccept = 0;
7802 static const unsigned char yybm[] =
7803 {
7804 0, 0, 0, 0, 0, 0, 0, 0,
7805 0, 32, 32, 0, 0, 32, 0, 0,
7806 0, 0, 0, 0, 0, 0, 0, 0,
7807 0, 0, 0, 0, 0, 0, 0, 0,
7808 160, 128, 0, 128, 128, 128, 128, 128,
7809 128, 128, 128, 128, 128, 128, 128, 128,
7810 192, 192, 192, 192, 192, 192, 192, 192,
7811 192, 192, 128, 128, 128, 128, 128, 128,
7812 128, 128, 128, 128, 128, 128, 128, 128,
7813 128, 128, 128, 128, 128, 128, 128, 128,
7814 128, 128, 128, 128, 128, 128, 128, 128,
7815 128, 128, 128, 128, 0, 128, 128, 128,
7816 128, 128, 128, 128, 128, 128, 128, 128,
7817 128, 128, 128, 128, 128, 128, 128, 128,
7818 128, 128, 128, 128, 128, 128, 128, 128,
7819 128, 128, 128, 128, 128, 128, 128, 128,
7820 0, 0, 0, 0, 0, 0, 0, 0,
7821 0, 0, 0, 0, 0, 0, 0, 0,
7822 0, 0, 0, 0, 0, 0, 0, 0,
7823 0, 0, 0, 0, 0, 0, 0, 0,
7824 0, 0, 0, 0, 0, 0, 0, 0,
7825 0, 0, 0, 0, 0, 0, 0, 0,
7826 0, 0, 0, 0, 0, 0, 0, 0,
7827 0, 0, 0, 0, 0, 0, 0, 0,
7828 0, 0, 0, 0, 0, 0, 0, 0,
7829 0, 0, 0, 0, 0, 0, 0, 0,
7830 0, 0, 0, 0, 0, 0, 0, 0,
7831 0, 0, 0, 0, 0, 0, 0, 0,
7832 0, 0, 0, 0, 0, 0, 0, 0,
7833 0, 0, 0, 0, 0, 0, 0, 0,
7834 0, 0, 0, 0, 0, 0, 0, 0,
7835 0, 0, 0, 0, 0, 0, 0, 0,
7836 };
7837 if ((m_limit - m_cursor) < 5)
7838 {
7839 fill_line_buffer(5); // LCOV_EXCL_LINE
7840 }
7841 yych = *m_cursor;
7842 if (yybm[0 + yych] & 32)
7843 {
7844 goto basic_json_parser_6;
7845 }
7846 if (yych <= '[')
7847 {
7848 if (yych <= '-')
7849 {
7850 if (yych <= '"')
7851 {
7852 if (yych <= 0x00)
7853 {
7854 goto basic_json_parser_2;
7855 }
7856 if (yych <= '!')
7857 {
7858 goto basic_json_parser_4;
7859 }
7860 goto basic_json_parser_9;
7861 }
7862 else
7863 {
7864 if (yych <= '+')
7865 {
7866 goto basic_json_parser_4;
7867 }
7868 if (yych <= ',')
7869 {
7870 goto basic_json_parser_10;
7871 }
7872 goto basic_json_parser_12;
7873 }
7874 }
7875 else
7876 {
7877 if (yych <= '9')
7878 {
7879 if (yych <= '/')
7880 {
7881 goto basic_json_parser_4;
7882 }
7883 if (yych <= '0')
7884 {
7885 goto basic_json_parser_13;
7886 }
7887 goto basic_json_parser_15;
7888 }
7889 else
7890 {
7891 if (yych <= ':')
7892 {
7893 goto basic_json_parser_17;
7894 }
7895 if (yych <= 'Z')
7896 {
7897 goto basic_json_parser_4;
7898 }
7899 goto basic_json_parser_19;
7900 }
7901 }
7902 }
7903 else
7904 {
7905 if (yych <= 'n')
7906 {
7907 if (yych <= 'e')
7908 {
7909 if (yych == ']')
7910 {
7911 goto basic_json_parser_21;
7912 }
7913 goto basic_json_parser_4;
7914 }
7915 else
7916 {
7917 if (yych <= 'f')
7918 {
7919 goto basic_json_parser_23;
7920 }
7921 if (yych <= 'm')
7922 {
7923 goto basic_json_parser_4;
7924 }
7925 goto basic_json_parser_24;
7926 }
7927 }
7928 else
7929 {
7930 if (yych <= 'z')
7931 {
7932 if (yych == 't')
7933 {
7934 goto basic_json_parser_25;
7935 }
7936 goto basic_json_parser_4;
7937 }
7938 else
7939 {
7940 if (yych <= '{')
7941 {
7942 goto basic_json_parser_26;
7943 }
7944 if (yych == '}')
7945 {
7946 goto basic_json_parser_28;
7947 }
7948 goto basic_json_parser_4;
7949 }
7950 }
7951 }
7952basic_json_parser_2:
7953 ++m_cursor;
7954 {
7955 last_token_type = token_type::end_of_input;
7956 break;
7957 }
7958basic_json_parser_4:
7959 ++m_cursor;
7960basic_json_parser_5:
7961 {
7962 last_token_type = token_type::parse_error;
7963 break;
7964 }
7965basic_json_parser_6:
7966 ++m_cursor;
7967 if (m_limit <= m_cursor)
7968 {
7969 fill_line_buffer(1); // LCOV_EXCL_LINE
7970 }
7971 yych = *m_cursor;
7972 if (yybm[0 + yych] & 32)
7973 {
7974 goto basic_json_parser_6;
7975 }
7976 {
7977 continue;
7978 }
7979basic_json_parser_9:
7980 yyaccept = 0;
7981 yych = *(m_marker = ++m_cursor);
7982 if (yych <= 0x1F)
7983 {
7984 goto basic_json_parser_5;
7985 }
7986 if (yych <= 0x7F)
7987 {
7988 goto basic_json_parser_31;
7989 }
7990 if (yych <= 0xC1)
7991 {
7992 goto basic_json_parser_5;
7993 }
7994 if (yych <= 0xF4)
7995 {
7996 goto basic_json_parser_31;
7997 }
7998 goto basic_json_parser_5;
7999basic_json_parser_10:
8000 ++m_cursor;
8001 {
8002 last_token_type = token_type::value_separator;
8003 break;
8004 }
8005basic_json_parser_12:
8006 yych = *++m_cursor;
8007 if (yych <= '/')
8008 {
8009 goto basic_json_parser_5;
8010 }
8011 if (yych <= '0')
8012 {
8013 goto basic_json_parser_13;
8014 }
8015 if (yych <= '9')
8016 {
8017 goto basic_json_parser_15;
8018 }
8019 goto basic_json_parser_5;
8020basic_json_parser_13:
8021 yyaccept = 1;
8022 yych = *(m_marker = ++m_cursor);
8023 if (yych <= 'D')
8024 {
8025 if (yych == '.')
8026 {
8027 goto basic_json_parser_43;
8028 }
8029 }
8030 else
8031 {
8032 if (yych <= 'E')
8033 {
8034 goto basic_json_parser_44;
8035 }
8036 if (yych == 'e')
8037 {
8038 goto basic_json_parser_44;
8039 }
8040 }
8041basic_json_parser_14:
8042 {
8043 last_token_type = token_type::value_number;
8044 break;
8045 }
8046basic_json_parser_15:
8047 yyaccept = 1;
8048 m_marker = ++m_cursor;
8049 if ((m_limit - m_cursor) < 3)
8050 {
8051 fill_line_buffer(3); // LCOV_EXCL_LINE
8052 }
8053 yych = *m_cursor;
8054 if (yybm[0 + yych] & 64)
8055 {
8056 goto basic_json_parser_15;
8057 }
8058 if (yych <= 'D')
8059 {
8060 if (yych == '.')
8061 {
8062 goto basic_json_parser_43;
8063 }
8064 goto basic_json_parser_14;
8065 }
8066 else
8067 {
8068 if (yych <= 'E')
8069 {
8070 goto basic_json_parser_44;
8071 }
8072 if (yych == 'e')
8073 {
8074 goto basic_json_parser_44;
8075 }
8076 goto basic_json_parser_14;
8077 }
8078basic_json_parser_17:
8079 ++m_cursor;
8080 {
8081 last_token_type = token_type::name_separator;
8082 break;
8083 }
8084basic_json_parser_19:
8085 ++m_cursor;
8086 {
8087 last_token_type = token_type::begin_array;
8088 break;
8089 }
8090basic_json_parser_21:
8091 ++m_cursor;
8092 {
8093 last_token_type = token_type::end_array;
8094 break;
8095 }
8096basic_json_parser_23:
8097 yyaccept = 0;
8098 yych = *(m_marker = ++m_cursor);
8099 if (yych == 'a')
8100 {
8101 goto basic_json_parser_45;
8102 }
8103 goto basic_json_parser_5;
8104basic_json_parser_24:
8105 yyaccept = 0;
8106 yych = *(m_marker = ++m_cursor);
8107 if (yych == 'u')
8108 {
8109 goto basic_json_parser_46;
8110 }
8111 goto basic_json_parser_5;
8112basic_json_parser_25:
8113 yyaccept = 0;
8114 yych = *(m_marker = ++m_cursor);
8115 if (yych == 'r')
8116 {
8117 goto basic_json_parser_47;
8118 }
8119 goto basic_json_parser_5;
8120basic_json_parser_26:
8121 ++m_cursor;
8122 {
8123 last_token_type = token_type::begin_object;
8124 break;
8125 }
8126basic_json_parser_28:
8127 ++m_cursor;
8128 {
8129 last_token_type = token_type::end_object;
8130 break;
8131 }
8132basic_json_parser_30:
8133 ++m_cursor;
8134 if (m_limit <= m_cursor)
8135 {
8136 fill_line_buffer(1); // LCOV_EXCL_LINE
8137 }
8138 yych = *m_cursor;
8139basic_json_parser_31:
8140 if (yybm[0 + yych] & 128)
8141 {
8142 goto basic_json_parser_30;
8143 }
8144 if (yych <= 0xE0)
8145 {
8146 if (yych <= '\\')
8147 {
8148 if (yych <= 0x1F)
8149 {
8150 goto basic_json_parser_32;
8151 }
8152 if (yych <= '"')
8153 {
8154 goto basic_json_parser_33;
8155 }
8156 goto basic_json_parser_35;
8157 }
8158 else
8159 {
8160 if (yych <= 0xC1)
8161 {
8162 goto basic_json_parser_32;
8163 }
8164 if (yych <= 0xDF)
8165 {
8166 goto basic_json_parser_36;
8167 }
8168 goto basic_json_parser_37;
8169 }
8170 }
8171 else
8172 {
8173 if (yych <= 0xEF)
8174 {
8175 if (yych == 0xED)
8176 {
8177 goto basic_json_parser_39;
8178 }
8179 goto basic_json_parser_38;
8180 }
8181 else
8182 {
8183 if (yych <= 0xF0)
8184 {
8185 goto basic_json_parser_40;
8186 }
8187 if (yych <= 0xF3)
8188 {
8189 goto basic_json_parser_41;
8190 }
8191 if (yych <= 0xF4)
8192 {
8193 goto basic_json_parser_42;
8194 }
8195 }
8196 }
8197basic_json_parser_32:
8198 m_cursor = m_marker;
8199 if (yyaccept == 0)
8200 {
8201 goto basic_json_parser_5;
8202 }
8203 else
8204 {
8205 goto basic_json_parser_14;
8206 }
8207basic_json_parser_33:
8208 ++m_cursor;
8209 {
8210 last_token_type = token_type::value_string;
8211 break;
8212 }
8213basic_json_parser_35:
8214 ++m_cursor;
8215 if (m_limit <= m_cursor)
8216 {
8217 fill_line_buffer(1); // LCOV_EXCL_LINE
8218 }
8219 yych = *m_cursor;
8220 if (yych <= 'e')
8221 {
8222 if (yych <= '/')
8223 {
8224 if (yych == '"')
8225 {
8226 goto basic_json_parser_30;
8227 }
8228 if (yych <= '.')
8229 {
8230 goto basic_json_parser_32;
8231 }
8232 goto basic_json_parser_30;
8233 }
8234 else
8235 {
8236 if (yych <= '\\')
8237 {
8238 if (yych <= '[')
8239 {
8240 goto basic_json_parser_32;
8241 }
8242 goto basic_json_parser_30;
8243 }
8244 else
8245 {
8246 if (yych == 'b')
8247 {
8248 goto basic_json_parser_30;
8249 }
8250 goto basic_json_parser_32;
8251 }
8252 }
8253 }
8254 else
8255 {
8256 if (yych <= 'q')
8257 {
8258 if (yych <= 'f')
8259 {
8260 goto basic_json_parser_30;
8261 }
8262 if (yych == 'n')
8263 {
8264 goto basic_json_parser_30;
8265 }
8266 goto basic_json_parser_32;
8267 }
8268 else
8269 {
8270 if (yych <= 's')
8271 {
8272 if (yych <= 'r')
8273 {
8274 goto basic_json_parser_30;
8275 }
8276 goto basic_json_parser_32;
8277 }
8278 else
8279 {
8280 if (yych <= 't')
8281 {
8282 goto basic_json_parser_30;
8283 }
8284 if (yych <= 'u')
8285 {
8286 goto basic_json_parser_48;
8287 }
8288 goto basic_json_parser_32;
8289 }
8290 }
8291 }
8292basic_json_parser_36:
8293 ++m_cursor;
8294 if (m_limit <= m_cursor)
8295 {
8296 fill_line_buffer(1); // LCOV_EXCL_LINE
8297 }
8298 yych = *m_cursor;
8299 if (yych <= 0x7F)
8300 {
8301 goto basic_json_parser_32;
8302 }
8303 if (yych <= 0xBF)
8304 {
8305 goto basic_json_parser_30;
8306 }
8307 goto basic_json_parser_32;
8308basic_json_parser_37:
8309 ++m_cursor;
8310 if (m_limit <= m_cursor)
8311 {
8312 fill_line_buffer(1); // LCOV_EXCL_LINE
8313 }
8314 yych = *m_cursor;
8315 if (yych <= 0x9F)
8316 {
8317 goto basic_json_parser_32;
8318 }
8319 if (yych <= 0xBF)
8320 {
8321 goto basic_json_parser_36;
8322 }
8323 goto basic_json_parser_32;
8324basic_json_parser_38:
8325 ++m_cursor;
8326 if (m_limit <= m_cursor)
8327 {
8328 fill_line_buffer(1); // LCOV_EXCL_LINE
8329 }
8330 yych = *m_cursor;
8331 if (yych <= 0x7F)
8332 {
8333 goto basic_json_parser_32;
8334 }
8335 if (yych <= 0xBF)
8336 {
8337 goto basic_json_parser_36;
8338 }
8339 goto basic_json_parser_32;
8340basic_json_parser_39:
8341 ++m_cursor;
8342 if (m_limit <= m_cursor)
8343 {
8344 fill_line_buffer(1); // LCOV_EXCL_LINE
8345 }
8346 yych = *m_cursor;
8347 if (yych <= 0x7F)
8348 {
8349 goto basic_json_parser_32;
8350 }
8351 if (yych <= 0x9F)
8352 {
8353 goto basic_json_parser_36;
8354 }
8355 goto basic_json_parser_32;
8356basic_json_parser_40:
8357 ++m_cursor;
8358 if (m_limit <= m_cursor)
8359 {
8360 fill_line_buffer(1); // LCOV_EXCL_LINE
8361 }
8362 yych = *m_cursor;
8363 if (yych <= 0x8F)
8364 {
8365 goto basic_json_parser_32;
8366 }
8367 if (yych <= 0xBF)
8368 {
8369 goto basic_json_parser_38;
8370 }
8371 goto basic_json_parser_32;
8372basic_json_parser_41:
8373 ++m_cursor;
8374 if (m_limit <= m_cursor)
8375 {
8376 fill_line_buffer(1); // LCOV_EXCL_LINE
8377 }
8378 yych = *m_cursor;
8379 if (yych <= 0x7F)
8380 {
8381 goto basic_json_parser_32;
8382 }
8383 if (yych <= 0xBF)
8384 {
8385 goto basic_json_parser_38;
8386 }
8387 goto basic_json_parser_32;
8388basic_json_parser_42:
8389 ++m_cursor;
8390 if (m_limit <= m_cursor)
8391 {
8392 fill_line_buffer(1); // LCOV_EXCL_LINE
8393 }
8394 yych = *m_cursor;
8395 if (yych <= 0x7F)
8396 {
8397 goto basic_json_parser_32;
8398 }
8399 if (yych <= 0x8F)
8400 {
8401 goto basic_json_parser_38;
8402 }
8403 goto basic_json_parser_32;
8404basic_json_parser_43:
8405 yych = *++m_cursor;
8406 if (yych <= '/')
8407 {
8408 goto basic_json_parser_32;
8409 }
8410 if (yych <= '9')
8411 {
8412 goto basic_json_parser_49;
8413 }
8414 goto basic_json_parser_32;
8415basic_json_parser_44:
8416 yych = *++m_cursor;
8417 if (yych <= ',')
8418 {
8419 if (yych == '+')
8420 {
8421 goto basic_json_parser_51;
8422 }
8423 goto basic_json_parser_32;
8424 }
8425 else
8426 {
8427 if (yych <= '-')
8428 {
8429 goto basic_json_parser_51;
8430 }
8431 if (yych <= '/')
8432 {
8433 goto basic_json_parser_32;
8434 }
8435 if (yych <= '9')
8436 {
8437 goto basic_json_parser_52;
8438 }
8439 goto basic_json_parser_32;
8440 }
8441basic_json_parser_45:
8442 yych = *++m_cursor;
8443 if (yych == 'l')
8444 {
8445 goto basic_json_parser_54;
8446 }
8447 goto basic_json_parser_32;
8448basic_json_parser_46:
8449 yych = *++m_cursor;
8450 if (yych == 'l')
8451 {
8452 goto basic_json_parser_55;
8453 }
8454 goto basic_json_parser_32;
8455basic_json_parser_47:
8456 yych = *++m_cursor;
8457 if (yych == 'u')
8458 {
8459 goto basic_json_parser_56;
8460 }
8461 goto basic_json_parser_32;
8462basic_json_parser_48:
8463 ++m_cursor;
8464 if (m_limit <= m_cursor)
8465 {
8466 fill_line_buffer(1); // LCOV_EXCL_LINE
8467 }
8468 yych = *m_cursor;
8469 if (yych <= '@')
8470 {
8471 if (yych <= '/')
8472 {
8473 goto basic_json_parser_32;
8474 }
8475 if (yych <= '9')
8476 {
8477 goto basic_json_parser_57;
8478 }
8479 goto basic_json_parser_32;
8480 }
8481 else
8482 {
8483 if (yych <= 'F')
8484 {
8485 goto basic_json_parser_57;
8486 }
8487 if (yych <= '`')
8488 {
8489 goto basic_json_parser_32;
8490 }
8491 if (yych <= 'f')
8492 {
8493 goto basic_json_parser_57;
8494 }
8495 goto basic_json_parser_32;
8496 }
8497basic_json_parser_49:
8498 yyaccept = 1;
8499 m_marker = ++m_cursor;
8500 if ((m_limit - m_cursor) < 3)
8501 {
8502 fill_line_buffer(3); // LCOV_EXCL_LINE
8503 }
8504 yych = *m_cursor;
8505 if (yych <= 'D')
8506 {
8507 if (yych <= '/')
8508 {
8509 goto basic_json_parser_14;
8510 }
8511 if (yych <= '9')
8512 {
8513 goto basic_json_parser_49;
8514 }
8515 goto basic_json_parser_14;
8516 }
8517 else
8518 {
8519 if (yych <= 'E')
8520 {
8521 goto basic_json_parser_44;
8522 }
8523 if (yych == 'e')
8524 {
8525 goto basic_json_parser_44;
8526 }
8527 goto basic_json_parser_14;
8528 }
8529basic_json_parser_51:
8530 yych = *++m_cursor;
8531 if (yych <= '/')
8532 {
8533 goto basic_json_parser_32;
8534 }
8535 if (yych >= ':')
8536 {
8537 goto basic_json_parser_32;
8538 }
8539basic_json_parser_52:
8540 ++m_cursor;
8541 if (m_limit <= m_cursor)
8542 {
8543 fill_line_buffer(1); // LCOV_EXCL_LINE
8544 }
8545 yych = *m_cursor;
8546 if (yych <= '/')
8547 {
8548 goto basic_json_parser_14;
8549 }
8550 if (yych <= '9')
8551 {
8552 goto basic_json_parser_52;
8553 }
8554 goto basic_json_parser_14;
8555basic_json_parser_54:
8556 yych = *++m_cursor;
8557 if (yych == 's')
8558 {
8559 goto basic_json_parser_58;
8560 }
8561 goto basic_json_parser_32;
8562basic_json_parser_55:
8563 yych = *++m_cursor;
8564 if (yych == 'l')
8565 {
8566 goto basic_json_parser_59;
8567 }
8568 goto basic_json_parser_32;
8569basic_json_parser_56:
8570 yych = *++m_cursor;
8571 if (yych == 'e')
8572 {
8573 goto basic_json_parser_61;
8574 }
8575 goto basic_json_parser_32;
8576basic_json_parser_57:
8577 ++m_cursor;
8578 if (m_limit <= m_cursor)
8579 {
8580 fill_line_buffer(1); // LCOV_EXCL_LINE
8581 }
8582 yych = *m_cursor;
8583 if (yych <= '@')
8584 {
8585 if (yych <= '/')
8586 {
8587 goto basic_json_parser_32;
8588 }
8589 if (yych <= '9')
8590 {
8591 goto basic_json_parser_63;
8592 }
8593 goto basic_json_parser_32;
8594 }
8595 else
8596 {
8597 if (yych <= 'F')
8598 {
8599 goto basic_json_parser_63;
8600 }
8601 if (yych <= '`')
8602 {
8603 goto basic_json_parser_32;
8604 }
8605 if (yych <= 'f')
8606 {
8607 goto basic_json_parser_63;
8608 }
8609 goto basic_json_parser_32;
8610 }
8611basic_json_parser_58:
8612 yych = *++m_cursor;
8613 if (yych == 'e')
8614 {
8615 goto basic_json_parser_64;
8616 }
8617 goto basic_json_parser_32;
8618basic_json_parser_59:
8619 ++m_cursor;
8620 {
8621 last_token_type = token_type::literal_null;
8622 break;
8623 }
8624basic_json_parser_61:
8625 ++m_cursor;
8626 {
8627 last_token_type = token_type::literal_true;
8628 break;
8629 }
8630basic_json_parser_63:
8631 ++m_cursor;
8632 if (m_limit <= m_cursor)
8633 {
8634 fill_line_buffer(1); // LCOV_EXCL_LINE
8635 }
8636 yych = *m_cursor;
8637 if (yych <= '@')
8638 {
8639 if (yych <= '/')
8640 {
8641 goto basic_json_parser_32;
8642 }
8643 if (yych <= '9')
8644 {
8645 goto basic_json_parser_66;
8646 }
8647 goto basic_json_parser_32;
8648 }
8649 else
8650 {
8651 if (yych <= 'F')
8652 {
8653 goto basic_json_parser_66;
8654 }
8655 if (yych <= '`')
8656 {
8657 goto basic_json_parser_32;
8658 }
8659 if (yych <= 'f')
8660 {
8661 goto basic_json_parser_66;
8662 }
8663 goto basic_json_parser_32;
8664 }
8665basic_json_parser_64:
8666 ++m_cursor;
8667 {
8668 last_token_type = token_type::literal_false;
8669 break;
8670 }
8671basic_json_parser_66:
8672 ++m_cursor;
8673 if (m_limit <= m_cursor)
8674 {
8675 fill_line_buffer(1); // LCOV_EXCL_LINE
8676 }
8677 yych = *m_cursor;
8678 if (yych <= '@')
8679 {
8680 if (yych <= '/')
8681 {
8682 goto basic_json_parser_32;
8683 }
8684 if (yych <= '9')
8685 {
8686 goto basic_json_parser_30;
8687 }
8688 goto basic_json_parser_32;
8689 }
8690 else
8691 {
8692 if (yych <= 'F')
8693 {
8694 goto basic_json_parser_30;
8695 }
8696 if (yych <= '`')
8697 {
8698 goto basic_json_parser_32;
8699 }
8700 if (yych <= 'f')
8701 {
8702 goto basic_json_parser_30;
8703 }
8704 goto basic_json_parser_32;
8705 }
8706 }
8707
8708 }
8709
8710 return last_token_type;
8711 }
8712
8713 /*!
8714 @brief append data from the stream to the line buffer
8715
8716 This function is called by the scan() function when the end of the
8717 buffer (`m_limit`) is reached and the `m_cursor` pointer cannot be
8718 incremented without leaving the limits of the line buffer. Note re2c
8719 decides when to call this function.
8720
8721 If the lexer reads from contiguous storage, there is no trailing null
8722 byte. Therefore, this function must make sure to add these padding
8723 null bytes.
8724
8725 If the lexer reads from an input stream, this function reads the next
8726 line of the input.
8727
8728 @pre
8729 p p p p p p u u u u u x . . . . . .
8730 ^ ^ ^ ^
8731 m_content m_start | m_limit
8732 m_cursor
8733
8734 @post
8735 u u u u u x x x x x x x . . . . . .
8736 ^ ^ ^
8737 | m_cursor m_limit
8738 m_start
8739 m_content
8740 */
8741 void fill_line_buffer(size_t n = 0)
8742 {
8743 // number of processed characters (p)
8744 const auto offset_start = m_start - m_content;
8745 // offset for m_marker wrt. to m_start
8746 const auto offset_marker = (m_marker == nullptr) ? 0 : m_marker - m_start;
8747 // number of unprocessed characters (u)
8748 const auto offset_cursor = m_cursor - m_start;
8749
8750 // no stream is used or end of file is reached
8751 if (m_stream == nullptr or m_stream->eof())
8752 {
8753 // skip this part if we are already using the line buffer
8754 if (m_start != reinterpret_cast<const lexer_char_t*>(m_line_buffer.data()))
8755 {
8756 // copy unprocessed characters to line buffer
8757 m_line_buffer.clear();
8758 for (m_cursor = m_start; m_cursor != m_limit; ++m_cursor)
8759 {
8760 m_line_buffer.append(1, static_cast<const char>(*m_cursor));
8761 }
8762 }
8763
8764 // append n characters to make sure that there is sufficient
8765 // space between m_cursor and m_limit
8766 m_line_buffer.append(1, '\x00');
8767 m_line_buffer.append(n - 1, '\x01');
8768 }
8769 else
8770 {
8771 // delete processed characters from line buffer
8772 m_line_buffer.erase(0, static_cast<size_t>(offset_start));
8773 // read next line from input stream
8774 std::string line;
8775 std::getline(*m_stream, line, '\n');
8776 // add line with newline symbol to the line buffer
8777 m_line_buffer += line + "\n";
8778 }
8779
8780 // set pointers
8781 m_content = reinterpret_cast<const lexer_char_t*>(m_line_buffer.c_str());
8782 assert(m_content != nullptr);
8783 m_start = m_content;
8784 m_marker = m_start + offset_marker;
8785 m_cursor = m_start + offset_cursor;
8786 m_limit = m_start + m_line_buffer.size();
8787 }
8788
8789 /// return string representation of last read token
8790 string_t get_token_string() const
8791 {
8792 assert(m_start != nullptr);
8793 return string_t(reinterpret_cast<typename string_t::const_pointer>(m_start),
8794 static_cast<size_t>(m_cursor - m_start));
8795 }
8796
8797 /*!
8798 @brief return string value for string tokens
8799
8800 The function iterates the characters between the opening and closing
8801 quotes of the string value. The complete string is the range
8802 [m_start,m_cursor). Consequently, we iterate from m_start+1 to
8803 m_cursor-1.
8804
8805 We differentiate two cases:
8806
8807 1. Escaped characters. In this case, a new character is constructed
8808 according to the nature of the escape. Some escapes create new
8809 characters (e.g., `"\\n"` is replaced by `"\n"`), some are copied
8810 as is (e.g., `"\\\\"`). Furthermore, Unicode escapes of the shape
8811 `"\\uxxxx"` need special care. In this case, to_unicode takes care
8812 of the construction of the values.
8813 2. Unescaped characters are copied as is.
8814
8815 @pre `m_cursor - m_start >= 2`, meaning the length of the last token
8816 is at least 2 bytes which is trivially true for any string (which
8817 consists of at least two quotes).
8818
8819 " c1 c2 c3 ... "
8820 ^ ^
8821 m_start m_cursor
8822
8823 @complexity Linear in the length of the string.\n
8824
8825 Lemma: The loop body will always terminate.\n
8826
8827 Proof (by contradiction): Assume the loop body does not terminate. As
8828 the loop body does not contain another loop, one of the called
8829 functions must never return. The called functions are `std::strtoul`
8830 and to_unicode. Neither function can loop forever, so the loop body
8831 will never loop forever which contradicts the assumption that the loop
8832 body does not terminate, q.e.d.\n
8833
8834 Lemma: The loop condition for the for loop is eventually false.\n
8835
8836 Proof (by contradiction): Assume the loop does not terminate. Due to
8837 the above lemma, this can only be due to a tautological loop
8838 condition; that is, the loop condition i < m_cursor - 1 must always be
8839 true. Let x be the change of i for any loop iteration. Then
8840 m_start + 1 + x < m_cursor - 1 must hold to loop indefinitely. This
8841 can be rephrased to m_cursor - m_start - 2 > x. With the
8842 precondition, we x <= 0, meaning that the loop condition holds
8843 indefinitly if i is always decreased. However, observe that the value
8844 of i is strictly increasing with each iteration, as it is incremented
8845 by 1 in the iteration expression and never decremented inside the loop
8846 body. Hence, the loop condition will eventually be false which
8847 contradicts the assumption that the loop condition is a tautology,
8848 q.e.d.
8849
8850 @return string value of current token without opening and closing
8851 quotes
8852 @throw std::out_of_range if to_unicode fails
8853 */
8854 string_t get_string() const
8855 {
8856 assert(m_cursor - m_start >= 2);
8857
8858 string_t result;
8859 result.reserve(static_cast<size_t>(m_cursor - m_start - 2));
8860
8861 // iterate the result between the quotes
8862 for (const lexer_char_t* i = m_start + 1; i < m_cursor - 1; ++i)
8863 {
8864 // process escaped characters
8865 if (*i == '\\')
8866 {
8867 // read next character
8868 ++i;
8869
8870 switch (*i)
8871 {
8872 // the default escapes
8873 case 't':
8874 {
8875 result += "\t";
8876 break;
8877 }
8878 case 'b':
8879 {
8880 result += "\b";
8881 break;
8882 }
8883 case 'f':
8884 {
8885 result += "\f";
8886 break;
8887 }
8888 case 'n':
8889 {
8890 result += "\n";
8891 break;
8892 }
8893 case 'r':
8894 {
8895 result += "\r";
8896 break;
8897 }
8898 case '\\':
8899 {
8900 result += "\\";
8901 break;
8902 }
8903 case '/':
8904 {
8905 result += "/";
8906 break;
8907 }
8908 case '"':
8909 {
8910 result += "\"";
8911 break;
8912 }
8913
8914 // unicode
8915 case 'u':
8916 {
8917 // get code xxxx from uxxxx
8918 auto codepoint = std::strtoul(std::string(reinterpret_cast<typename string_t::const_pointer>(i + 1),
8919 4).c_str(), nullptr, 16);
8920
8921 // check if codepoint is a high surrogate
8922 if (codepoint >= 0xD800 and codepoint <= 0xDBFF)
8923 {
8924 // make sure there is a subsequent unicode
8925 if ((i + 6 >= m_limit) or * (i + 5) != '\\' or * (i + 6) != 'u')
8926 {
8927 throw std::invalid_argument("missing low surrogate");
8928 }
8929
8930 // get code yyyy from uxxxx\uyyyy
8931 auto codepoint2 = std::strtoul(std::string(reinterpret_cast<typename string_t::const_pointer>
8932 (i + 7), 4).c_str(), nullptr, 16);
8933 result += to_unicode(codepoint, codepoint2);
8934 // skip the next 10 characters (xxxx\uyyyy)
8935 i += 10;
8936 }
8937 else if (codepoint >= 0xDC00 and codepoint <= 0xDFFF)
8938 {
8939 // we found a lone low surrogate
8940 throw std::invalid_argument("missing high surrogate");
8941 }
8942 else
8943 {
8944 // add unicode character(s)
8945 result += to_unicode(codepoint);
8946 // skip the next four characters (xxxx)
8947 i += 4;
8948 }
8949 break;
8950 }
8951 }
8952 }
8953 else
8954 {
8955 // all other characters are just copied to the end of the
8956 // string
8957 result.append(1, static_cast<typename string_t::value_type>(*i));
8958 }
8959 }
8960
8961 return result;
8962 }
8963
8964 /*!
8965 @brief parse floating point number
8966
8967 This function (and its overloads) serves to select the most approprate
8968 standard floating point number parsing function based on the type
8969 supplied via the first parameter. Set this to @a
8970 static_cast<number_float_t*>(nullptr).
8971
8972 @param[in] type the @ref number_float_t in use
8973
8974 @param[in,out] endptr recieves a pointer to the first character after
8975 the number
8976
8977 @return the floating point number
8978 */
8979 long double str_to_float_t(long double* /* type */, char** endptr) const
8980 {
8981 return std::strtold(reinterpret_cast<typename string_t::const_pointer>(m_start), endptr);
8982 }
8983
8984 /*!
8985 @brief parse floating point number
8986
8987 This function (and its overloads) serves to select the most approprate
8988 standard floating point number parsing function based on the type
8989 supplied via the first parameter. Set this to @a
8990 static_cast<number_float_t*>(nullptr).
8991
8992 @param[in] type the @ref number_float_t in use
8993
8994 @param[in,out] endptr recieves a pointer to the first character after
8995 the number
8996
8997 @return the floating point number
8998 */
8999 double str_to_float_t(double* /* type */, char** endptr) const
9000 {
9001 return std::strtod(reinterpret_cast<typename string_t::const_pointer>(m_start), endptr);
9002 }
9003
9004 /*!
9005 @brief parse floating point number
9006
9007 This function (and its overloads) serves to select the most approprate
9008 standard floating point number parsing function based on the type
9009 supplied via the first parameter. Set this to @a
9010 static_cast<number_float_t*>(nullptr).
9011
9012 @param[in] type the @ref number_float_t in use
9013
9014 @param[in,out] endptr recieves a pointer to the first character after
9015 the number
9016
9017 @return the floating point number
9018 */
9019 float str_to_float_t(float* /* type */, char** endptr) const
9020 {
9021 return std::strtof(reinterpret_cast<typename string_t::const_pointer>(m_start), endptr);
9022 }
9023
9024 /*!
9025 @brief return number value for number tokens
9026
9027 This function translates the last token into the most appropriate
9028 number type (either integer, unsigned integer or floating point),
9029 which is passed back to the caller via the result parameter.
9030
9031 This function parses the integer component up to the radix point or
9032 exponent while collecting information about the 'floating point
9033 representation', which it stores in the result parameter. If there is
9034 no radix point or exponent, and the number can fit into a @ref
9035 number_integer_t or @ref number_unsigned_t then it sets the result
9036 parameter accordingly.
9037
9038 If the number is a floating point number the number is then parsed
9039 using @a std:strtod (or @a std:strtof or @a std::strtold).
9040
9041 @param[out] result @ref basic_json object to receive the number, or
9042 NAN if the conversion read past the current token. The latter case
9043 needs to be treated by the caller function.
9044 */
9045 void get_number(basic_json& result) const
9046 {
9047 assert(m_start != nullptr);
9048
9049 const lexer::lexer_char_t* curptr = m_start;
9050
9051 // accumulate the integer conversion result (unsigned for now)
9052 number_unsigned_t value = 0;
9053
9054 // maximum absolute value of the relevant integer type
9055 number_unsigned_t max;
9056
9057 // temporarily store the type to avoid unecessary bitfield access
9058 value_t type;
9059
9060 // look for sign
9061 if (*curptr == '-')
9062 {
9063 type = value_t::number_integer;
9064 max = static_cast<uint64_t>((std::numeric_limits<number_integer_t>::max)()) + 1;
9065 curptr++;
9066 }
9067 else
9068 {
9069 type = value_t::number_unsigned;
9070 max = static_cast<uint64_t>((std::numeric_limits<number_unsigned_t>::max)());
9071 }
9072
9073 // count the significant figures
9074 for (; curptr < m_cursor; curptr++)
9075 {
9076 // quickly skip tests if a digit
9077 if (*curptr < '0' || *curptr > '9')
9078 {
9079 if (*curptr == '.')
9080 {
9081 // don't count '.' but change to float
9082 type = value_t::number_float;
9083 continue;
9084 }
9085 // assume exponent (if not then will fail parse): change to
9086 // float, stop counting and record exponent details
9087 type = value_t::number_float;
9088 break;
9089 }
9090
9091 // skip if definitely not an integer
9092 if (type != value_t::number_float)
9093 {
9094 // multiply last value by ten and add the new digit
9095 auto temp = value * 10 + *curptr - '0';
9096
9097 // test for overflow
9098 if (temp < value || temp > max)
9099 {
9100 // overflow
9101 type = value_t::number_float;
9102 }
9103 else
9104 {
9105 // no overflow - save it
9106 value = temp;
9107 }
9108 }
9109 }
9110
9111 // save the value (if not a float)
9112 if (type == value_t::number_unsigned)
9113 {
9114 result.m_value.number_unsigned = value;
9115 }
9116 else if (type == value_t::number_integer)
9117 {
9118 result.m_value.number_integer = -static_cast<number_integer_t>(value);
9119 }
9120 else
9121 {
9122 // parse with strtod
9123 result.m_value.number_float = str_to_float_t(static_cast<number_float_t*>(nullptr), NULL);
9124
9125 // replace infinity and NAN by null
9126 if (not std::isfinite(result.m_value.number_float))
9127 {
9128 type = value_t::null;
9129 result.m_value = basic_json::json_value();
9130 }
9131 }
9132
9133 // save the type
9134 result.m_type = type;
9135 }
9136
9137 private:
9138 /// optional input stream
9139 std::istream* m_stream = nullptr;
9140 /// line buffer buffer for m_stream
9141 string_t m_line_buffer {};
9142 /// the buffer pointer
9143 const lexer_char_t* m_content = nullptr;
9144 /// pointer to the beginning of the current symbol
9145 const lexer_char_t* m_start = nullptr;
9146 /// pointer for backtracking information
9147 const lexer_char_t* m_marker = nullptr;
9148 /// pointer to the current symbol
9149 const lexer_char_t* m_cursor = nullptr;
9150 /// pointer to the end of the buffer
9151 const lexer_char_t* m_limit = nullptr;
9152 /// the last token type
9153 token_type last_token_type = token_type::end_of_input;
9154 };
9155
9156 /*!
9157 @brief syntax analysis
9158
9159 This class implements a recursive decent parser.
9160 */
9161 class parser
9162 {
9163 public:
9164 /// a parser reading from a string literal
9165 parser(const char* buff, const parser_callback_t cb = nullptr)
9166 : callback(cb),
9167 m_lexer(reinterpret_cast<const typename lexer::lexer_char_t*>(buff), strlen(buff))
9168 {}
9169
9170 /// a parser reading from an input stream
9171 parser(std::istream& is, const parser_callback_t cb = nullptr)
9172 : callback(cb), m_lexer(is)
9173 {}
9174
9175 /// a parser reading from an iterator range with contiguous storage
9176 template<class IteratorType, typename std::enable_if<
9177 std::is_same<typename std::iterator_traits<IteratorType>::iterator_category, std::random_access_iterator_tag>::value
9178 , int>::type
9179 = 0>
9180 parser(IteratorType first, IteratorType last, const parser_callback_t cb = nullptr)
9181 : callback(cb),
9182 m_lexer(reinterpret_cast<const typename lexer::lexer_char_t*>(&(*first)),
9183 static_cast<size_t>(std::distance(first, last)))
9184 {}
9185
9186 /// public parser interface
9187 basic_json parse()
9188 {
9189 // read first token
9190 get_token();
9191
9192 basic_json result = parse_internal(true);
9193 result.assert_invariant();
9194
9195 expect(lexer::token_type::end_of_input);
9196
9197 // return parser result and replace it with null in case the
9198 // top-level value was discarded by the callback function
9199 return result.is_discarded() ? basic_json() : std::move(result);
9200 }
9201
9202 private:
9203 /// the actual parser
9204 basic_json parse_internal(bool keep)
9205 {
9206 auto result = basic_json(value_t::discarded);
9207
9208 switch (last_token)
9209 {
9210 case lexer::token_type::begin_object:
9211 {
9212 if (keep and (not callback
9213 or ((keep = callback(depth++, parse_event_t::object_start, result)) != 0)))
9214 {
9215 // explicitly set result to object to cope with {}
9216 result.m_type = value_t::object;
9217 result.m_value = value_t::object;
9218 }
9219
9220 // read next token
9221 get_token();
9222
9223 // closing } -> we are done
9224 if (last_token == lexer::token_type::end_object)
9225 {
9226 get_token();
9227 if (keep and callback and not callback(--depth, parse_event_t::object_end, result))
9228 {
9229 result = basic_json(value_t::discarded);
9230 }
9231 return result;
9232 }
9233
9234 // no comma is expected here
9235 unexpect(lexer::token_type::value_separator);
9236
9237 // otherwise: parse key-value pairs
9238 do
9239 {
9240 // ugly, but could be fixed with loop reorganization
9241 if (last_token == lexer::token_type::value_separator)
9242 {
9243 get_token();
9244 }
9245
9246 // store key
9247 expect(lexer::token_type::value_string);
9248 const auto key = m_lexer.get_string();
9249
9250 bool keep_tag = false;
9251 if (keep)
9252 {
9253 if (callback)
9254 {
9255 basic_json k(key);
9256 keep_tag = callback(depth, parse_event_t::key, k);
9257 }
9258 else
9259 {
9260 keep_tag = true;
9261 }
9262 }
9263
9264 // parse separator (:)
9265 get_token();
9266 expect(lexer::token_type::name_separator);
9267
9268 // parse and add value
9269 get_token();
9270 auto value = parse_internal(keep);
9271 if (keep and keep_tag and not value.is_discarded())
9272 {
9273 result[key] = std::move(value);
9274 }
9275 }
9276 while (last_token == lexer::token_type::value_separator);
9277
9278 // closing }
9279 expect(lexer::token_type::end_object);
9280 get_token();
9281 if (keep and callback and not callback(--depth, parse_event_t::object_end, result))
9282 {
9283 result = basic_json(value_t::discarded);
9284 }
9285
9286 return result;
9287 }
9288
9289 case lexer::token_type::begin_array:
9290 {
9291 if (keep and (not callback
9292 or ((keep = callback(depth++, parse_event_t::array_start, result)) != 0)))
9293 {
9294 // explicitly set result to object to cope with []
9295 result.m_type = value_t::array;
9296 result.m_value = value_t::array;
9297 }
9298
9299 // read next token
9300 get_token();
9301
9302 // closing ] -> we are done
9303 if (last_token == lexer::token_type::end_array)
9304 {
9305 get_token();
9306 if (callback and not callback(--depth, parse_event_t::array_end, result))
9307 {
9308 result = basic_json(value_t::discarded);
9309 }
9310 return result;
9311 }
9312
9313 // no comma is expected here
9314 unexpect(lexer::token_type::value_separator);
9315
9316 // otherwise: parse values
9317 do
9318 {
9319 // ugly, but could be fixed with loop reorganization
9320 if (last_token == lexer::token_type::value_separator)
9321 {
9322 get_token();
9323 }
9324
9325 // parse value
9326 auto value = parse_internal(keep);
9327 if (keep and not value.is_discarded())
9328 {
9329 result.push_back(std::move(value));
9330 }
9331 }
9332 while (last_token == lexer::token_type::value_separator);
9333
9334 // closing ]
9335 expect(lexer::token_type::end_array);
9336 get_token();
9337 if (keep and callback and not callback(--depth, parse_event_t::array_end, result))
9338 {
9339 result = basic_json(value_t::discarded);
9340 }
9341
9342 return result;
9343 }
9344
9345 case lexer::token_type::literal_null:
9346 {
9347 get_token();
9348 result.m_type = value_t::null;
9349 break;
9350 }
9351
9352 case lexer::token_type::value_string:
9353 {
9354 const auto s = m_lexer.get_string();
9355 get_token();
9356 result = basic_json(s);
9357 break;
9358 }
9359
9360 case lexer::token_type::literal_true:
9361 {
9362 get_token();
9363 result.m_type = value_t::boolean;
9364 result.m_value = true;
9365 break;
9366 }
9367
9368 case lexer::token_type::literal_false:
9369 {
9370 get_token();
9371 result.m_type = value_t::boolean;
9372 result.m_value = false;
9373 break;
9374 }
9375
9376 case lexer::token_type::value_number:
9377 {
9378 m_lexer.get_number(result);
9379 get_token();
9380 break;
9381 }
9382
9383 default:
9384 {
9385 // the last token was unexpected
9386 unexpect(last_token);
9387 }
9388 }
9389
9390 if (keep and callback and not callback(depth, parse_event_t::value, result))
9391 {
9392 result = basic_json(value_t::discarded);
9393 }
9394 return result;
9395 }
9396
9397 /// get next token from lexer
9398 typename lexer::token_type get_token()
9399 {
9400 last_token = m_lexer.scan();
9401 return last_token;
9402 }
9403
9404 void expect(typename lexer::token_type t) const
9405 {
9406 if (t != last_token)
9407 {
9408 std::string error_msg = "parse error - unexpected ";
9409 error_msg += (last_token == lexer::token_type::parse_error ? ("'" + m_lexer.get_token_string() +
9410 "'") :
9411 lexer::token_type_name(last_token));
9412 error_msg += "; expected " + lexer::token_type_name(t);
9413 throw std::invalid_argument(error_msg);
9414 }
9415 }
9416
9417 void unexpect(typename lexer::token_type t) const
9418 {
9419 if (t == last_token)
9420 {
9421 std::string error_msg = "parse error - unexpected ";
9422 error_msg += (last_token == lexer::token_type::parse_error ? ("'" + m_lexer.get_token_string() +
9423 "'") :
9424 lexer::token_type_name(last_token));
9425 throw std::invalid_argument(error_msg);
9426 }
9427 }
9428
9429 private:
9430 /// current level of recursion
9431 int depth = 0;
9432 /// callback function
9433 const parser_callback_t callback = nullptr;
9434 /// the type of the last read token
9435 typename lexer::token_type last_token = lexer::token_type::uninitialized;
9436 /// the lexer
9437 lexer m_lexer;
9438 };
9439
9440 public:
9441 /*!
9442 @brief JSON Pointer
9443
9444 A JSON pointer defines a string syntax for identifying a specific value
9445 within a JSON document. It can be used with functions `at` and
9446 `operator[]`. Furthermore, JSON pointers are the base for JSON patches.
9447
9448 @sa [RFC 6901](https://tools.ietf.org/html/rfc6901)
9449
9450 @since version 2.0.0
9451 */
9452 class json_pointer
9453 {
9454 /// allow basic_json to access private members
9455 friend class basic_json;
9456
9457 public:
9458 /*!
9459 @brief create JSON pointer
9460
9461 Create a JSON pointer according to the syntax described in
9462 [Section 3 of RFC6901](https://tools.ietf.org/html/rfc6901#section-3).
9463
9464 @param[in] s string representing the JSON pointer; if omitted, the
9465 empty string is assumed which references the whole JSON
9466 value
9467
9468 @throw std::domain_error if reference token is nonempty and does not
9469 begin with a slash (`/`); example: `"JSON pointer must be empty or
9470 begin with /"`
9471 @throw std::domain_error if a tilde (`~`) is not followed by `0`
9472 (representing `~`) or `1` (representing `/`); example: `"escape error:
9473 ~ must be followed with 0 or 1"`
9474
9475 @liveexample{The example shows the construction several valid JSON
9476 pointers as well as the exceptional behavior.,json_pointer}
9477
9478 @since version 2.0.0
9479 */
9480 explicit json_pointer(const std::string& s = "")
9481 : reference_tokens(split(s))
9482 {}
9483
9484 /*!
9485 @brief return a string representation of the JSON pointer
9486
9487 @invariant For each JSON pointer `ptr`, it holds:
9488 @code {.cpp}
9489 ptr == json_pointer(ptr.to_string());
9490 @endcode
9491
9492 @return a string representation of the JSON pointer
9493
9494 @liveexample{The example shows the result of `to_string`.,
9495 json_pointer__to_string}
9496
9497 @since version 2.0.0
9498 */
9499 std::string to_string() const noexcept
9500 {
9501 return std::accumulate(reference_tokens.begin(),
9502 reference_tokens.end(), std::string{},
9503 [](const std::string & a, const std::string & b)
9504 {
9505 return a + "/" + escape(b);
9506 });
9507 }
9508
9509 /// @copydoc to_string()
9510 operator std::string() const
9511 {
9512 return to_string();
9513 }
9514
9515 private:
9516 /// remove and return last reference pointer
9517 std::string pop_back()
9518 {
9519 if (is_root())
9520 {
9521 throw std::domain_error("JSON pointer has no parent");
9522 }
9523
9524 auto last = reference_tokens.back();
9525 reference_tokens.pop_back();
9526 return last;
9527 }
9528
9529 /// return whether pointer points to the root document
9530 bool is_root() const
9531 {
9532 return reference_tokens.empty();
9533 }
9534
9535 json_pointer top() const
9536 {
9537 if (is_root())
9538 {
9539 throw std::domain_error("JSON pointer has no parent");
9540 }
9541
9542 json_pointer result = *this;
9543 result.reference_tokens = {reference_tokens[0]};
9544 return result;
9545 }
9546
9547 /*!
9548 @brief create and return a reference to the pointed to value
9549
9550 @complexity Linear in the number of reference tokens.
9551 */
9552 reference get_and_create(reference j) const
9553 {
9554 pointer result = &j;
9555
9556 // in case no reference tokens exist, return a reference to the
9557 // JSON value j which will be overwritten by a primitive value
9558 for (const auto& reference_token : reference_tokens)
9559 {
9560 switch (result->m_type)
9561 {
9562 case value_t::null:
9563 {
9564 if (reference_token == "0")
9565 {
9566 // start a new array if reference token is 0
9567 result = &result->operator[](0);
9568 }
9569 else
9570 {
9571 // start a new object otherwise
9572 result = &result->operator[](reference_token);
9573 }
9574 break;
9575 }
9576
9577 case value_t::object:
9578 {
9579 // create an entry in the object
9580 result = &result->operator[](reference_token);
9581 break;
9582 }
9583
9584 case value_t::array:
9585 {
9586 // create an entry in the array
9587 result = &result->operator[](static_cast<size_type>(std::stoi(reference_token)));
9588 break;
9589 }
9590
9591 /*
9592 The following code is only reached if there exists a
9593 reference token _and_ the current value is primitive. In
9594 this case, we have an error situation, because primitive
9595 values may only occur as single value; that is, with an
9596 empty list of reference tokens.
9597 */
9598 default:
9599 {
9600 throw std::domain_error("invalid value to unflatten");
9601 }
9602 }
9603 }
9604
9605 return *result;
9606 }
9607
9608 /*!
9609 @brief return a reference to the pointed to value
9610
9611 @note This version does not throw if a value is not present, but tries
9612 to create nested values instead. For instance, calling this function
9613 with pointer `"/this/that"` on a null value is equivalent to calling
9614 `operator[]("this").operator[]("that")` on that value, effectively
9615 changing the null value to an object.
9616
9617 @param[in] ptr a JSON value
9618
9619 @return reference to the JSON value pointed to by the JSON pointer
9620
9621 @complexity Linear in the length of the JSON pointer.
9622
9623 @throw std::out_of_range if the JSON pointer can not be resolved
9624 @throw std::domain_error if an array index begins with '0'
9625 @throw std::invalid_argument if an array index was not a number
9626 */
9627 reference get_unchecked(pointer ptr) const
9628 {
9629 for (const auto& reference_token : reference_tokens)
9630 {
9631 // convert null values to arrays or objects before continuing
9632 if (ptr->m_type == value_t::null)
9633 {
9634 // check if reference token is a number
9635 const bool nums = std::all_of(reference_token.begin(),
9636 reference_token.end(),
9637 [](const char x)
9638 {
9639 return std::isdigit(x);
9640 });
9641
9642 // change value to array for numbers or "-" or to object
9643 // otherwise
9644 if (nums or reference_token == "-")
9645 {
9646 *ptr = value_t::array;
9647 }
9648 else
9649 {
9650 *ptr = value_t::object;
9651 }
9652 }
9653
9654 switch (ptr->m_type)
9655 {
9656 case value_t::object:
9657 {
9658 // use unchecked object access
9659 ptr = &ptr->operator[](reference_token);
9660 break;
9661 }
9662
9663 case value_t::array:
9664 {
9665 // error condition (cf. RFC 6901, Sect. 4)
9666 if (reference_token.size() > 1 and reference_token[0] == '0')
9667 {
9668 throw std::domain_error("array index must not begin with '0'");
9669 }
9670
9671 if (reference_token == "-")
9672 {
9673 // explicityly treat "-" as index beyond the end
9674 ptr = &ptr->operator[](ptr->m_value.array->size());
9675 }
9676 else
9677 {
9678 // convert array index to number; unchecked access
9679 ptr = &ptr->operator[](static_cast<size_type>(std::stoi(reference_token)));
9680 }
9681 break;
9682 }
9683
9684 default:
9685 {
9686 throw std::out_of_range("unresolved reference token '" + reference_token + "'");
9687 }
9688 }
9689 }
9690
9691 return *ptr;
9692 }
9693
9694 reference get_checked(pointer ptr) const
9695 {
9696 for (const auto& reference_token : reference_tokens)
9697 {
9698 switch (ptr->m_type)
9699 {
9700 case value_t::object:
9701 {
9702 // note: at performs range check
9703 ptr = &ptr->at(reference_token);
9704 break;
9705 }
9706
9707 case value_t::array:
9708 {
9709 if (reference_token == "-")
9710 {
9711 // "-" always fails the range check
9712 throw std::out_of_range("array index '-' (" +
9713 std::to_string(ptr->m_value.array->size()) +
9714 ") is out of range");
9715 }
9716
9717 // error condition (cf. RFC 6901, Sect. 4)
9718 if (reference_token.size() > 1 and reference_token[0] == '0')
9719 {
9720 throw std::domain_error("array index must not begin with '0'");
9721 }
9722
9723 // note: at performs range check
9724 ptr = &ptr->at(static_cast<size_type>(std::stoi(reference_token)));
9725 break;
9726 }
9727
9728 default:
9729 {
9730 throw std::out_of_range("unresolved reference token '" + reference_token + "'");
9731 }
9732 }
9733 }
9734
9735 return *ptr;
9736 }
9737
9738 /*!
9739 @brief return a const reference to the pointed to value
9740
9741 @param[in] ptr a JSON value
9742
9743 @return const reference to the JSON value pointed to by the JSON
9744 pointer
9745 */
9746 const_reference get_unchecked(const_pointer ptr) const
9747 {
9748 for (const auto& reference_token : reference_tokens)
9749 {
9750 switch (ptr->m_type)
9751 {
9752 case value_t::object:
9753 {
9754 // use unchecked object access
9755 ptr = &ptr->operator[](reference_token);
9756 break;
9757 }
9758
9759 case value_t::array:
9760 {
9761 if (reference_token == "-")
9762 {
9763 // "-" cannot be used for const access
9764 throw std::out_of_range("array index '-' (" +
9765 std::to_string(ptr->m_value.array->size()) +
9766 ") is out of range");
9767 }
9768
9769 // error condition (cf. RFC 6901, Sect. 4)
9770 if (reference_token.size() > 1 and reference_token[0] == '0')
9771 {
9772 throw std::domain_error("array index must not begin with '0'");
9773 }
9774
9775 // use unchecked array access
9776 ptr = &ptr->operator[](static_cast<size_type>(std::stoi(reference_token)));
9777 break;
9778 }
9779
9780 default:
9781 {
9782 throw std::out_of_range("unresolved reference token '" + reference_token + "'");
9783 }
9784 }
9785 }
9786
9787 return *ptr;
9788 }
9789
9790 const_reference get_checked(const_pointer ptr) const
9791 {
9792 for (const auto& reference_token : reference_tokens)
9793 {
9794 switch (ptr->m_type)
9795 {
9796 case value_t::object:
9797 {
9798 // note: at performs range check
9799 ptr = &ptr->at(reference_token);
9800 break;
9801 }
9802
9803 case value_t::array:
9804 {
9805 if (reference_token == "-")
9806 {
9807 // "-" always fails the range check
9808 throw std::out_of_range("array index '-' (" +
9809 std::to_string(ptr->m_value.array->size()) +
9810 ") is out of range");
9811 }
9812
9813 // error condition (cf. RFC 6901, Sect. 4)
9814 if (reference_token.size() > 1 and reference_token[0] == '0')
9815 {
9816 throw std::domain_error("array index must not begin with '0'");
9817 }
9818
9819 // note: at performs range check
9820 ptr = &ptr->at(static_cast<size_type>(std::stoi(reference_token)));
9821 break;
9822 }
9823
9824 default:
9825 {
9826 throw std::out_of_range("unresolved reference token '" + reference_token + "'");
9827 }
9828 }
9829 }
9830
9831 return *ptr;
9832 }
9833
9834 /// split the string input to reference tokens
9835 static std::vector<std::string> split(const std::string& reference_string)
9836 {
9837 std::vector<std::string> result;
9838
9839 // special case: empty reference string -> no reference tokens
9840 if (reference_string.empty())
9841 {
9842 return result;
9843 }
9844
9845 // check if nonempty reference string begins with slash
9846 if (reference_string[0] != '/')
9847 {
9848 throw std::domain_error("JSON pointer must be empty or begin with '/'");
9849 }
9850
9851 // extract the reference tokens:
9852 // - slash: position of the last read slash (or end of string)
9853 // - start: position after the previous slash
9854 for (
9855 // search for the first slash after the first character
9856 size_t slash = reference_string.find_first_of("/", 1),
9857 // set the beginning of the first reference token
9858 start = 1;
9859 // we can stop if start == string::npos+1 = 0
9860 start != 0;
9861 // set the beginning of the next reference token
9862 // (will eventually be 0 if slash == std::string::npos)
9863 start = slash + 1,
9864 // find next slash
9865 slash = reference_string.find_first_of("/", start))
9866 {
9867 // use the text between the beginning of the reference token
9868 // (start) and the last slash (slash).
9869 auto reference_token = reference_string.substr(start, slash - start);
9870
9871 // check reference tokens are properly escaped
9872 for (size_t pos = reference_token.find_first_of("~");
9873 pos != std::string::npos;
9874 pos = reference_token.find_first_of("~", pos + 1))
9875 {
9876 assert(reference_token[pos] == '~');
9877
9878 // ~ must be followed by 0 or 1
9879 if (pos == reference_token.size() - 1 or
9880 (reference_token[pos + 1] != '0' and
9881 reference_token[pos + 1] != '1'))
9882 {
9883 throw std::domain_error("escape error: '~' must be followed with '0' or '1'");
9884 }
9885 }
9886
9887 // finally, store the reference token
9888 unescape(reference_token);
9889 result.push_back(reference_token);
9890 }
9891
9892 return result;
9893 }
9894
9895 private:
9896 /*!
9897 @brief replace all occurrences of a substring by another string
9898
9899 @param[in,out] s the string to manipulate
9900 @param[in] f the substring to replace with @a t
9901 @param[in] t the string to replace @a f
9902
9903 @return The string @a s where all occurrences of @a f are replaced
9904 with @a t.
9905
9906 @pre The search string @a f must not be empty.
9907
9908 @since version 2.0.0
9909 */
9910 static void replace_substring(std::string& s,
9911 const std::string& f,
9912 const std::string& t)
9913 {
9914 assert(not f.empty());
9915
9916 for (
9917 size_t pos = s.find(f); // find first occurrence of f
9918 pos != std::string::npos; // make sure f was found
9919 s.replace(pos, f.size(), t), // replace with t
9920 pos = s.find(f, pos + t.size()) // find next occurrence of f
9921 );
9922 }
9923
9924 /// escape tilde and slash
9925 static std::string escape(std::string s)
9926 {
9927 // escape "~"" to "~0" and "/" to "~1"
9928 replace_substring(s, "~", "~0");
9929 replace_substring(s, "/", "~1");
9930 return s;
9931 }
9932
9933 /// unescape tilde and slash
9934 static void unescape(std::string& s)
9935 {
9936 // first transform any occurrence of the sequence '~1' to '/'
9937 replace_substring(s, "~1", "/");
9938 // then transform any occurrence of the sequence '~0' to '~'
9939 replace_substring(s, "~0", "~");
9940 }
9941
9942 /*!
9943 @param[in] reference_string the reference string to the current value
9944 @param[in] value the value to consider
9945 @param[in,out] result the result object to insert values to
9946
9947 @note Empty objects or arrays are flattened to `null`.
9948 */
9949 static void flatten(const std::string& reference_string,
9950 const basic_json& value,
9951 basic_json& result)
9952 {
9953 switch (value.m_type)
9954 {
9955 case value_t::array:
9956 {
9957 if (value.m_value.array->empty())
9958 {
9959 // flatten empty array as null
9960 result[reference_string] = nullptr;
9961 }
9962 else
9963 {
9964 // iterate array and use index as reference string
9965 for (size_t i = 0; i < value.m_value.array->size(); ++i)
9966 {
9967 flatten(reference_string + "/" + std::to_string(i),
9968 value.m_value.array->operator[](i), result);
9969 }
9970 }
9971 break;
9972 }
9973
9974 case value_t::object:
9975 {
9976 if (value.m_value.object->empty())
9977 {
9978 // flatten empty object as null
9979 result[reference_string] = nullptr;
9980 }
9981 else
9982 {
9983 // iterate object and use keys as reference string
9984 for (const auto& element : *value.m_value.object)
9985 {
9986 flatten(reference_string + "/" + escape(element.first),
9987 element.second, result);
9988 }
9989 }
9990 break;
9991 }
9992
9993 default:
9994 {
9995 // add primitive value with its reference string
9996 result[reference_string] = value;
9997 break;
9998 }
9999 }
10000 }
10001
10002 /*!
10003 @param[in] value flattened JSON
10004
10005 @return unflattened JSON
10006 */
10007 static basic_json unflatten(const basic_json& value)
10008 {
10009 if (not value.is_object())
10010 {
10011 throw std::domain_error("only objects can be unflattened");
10012 }
10013
10014 basic_json result;
10015
10016 // iterate the JSON object values
10017 for (const auto& element : *value.m_value.object)
10018 {
10019 if (not element.second.is_primitive())
10020 {
10021 throw std::domain_error("values in object must be primitive");
10022 }
10023
10024 // assign value to reference pointed to by JSON pointer; Note
10025 // that if the JSON pointer is "" (i.e., points to the whole
10026 // value), function get_and_create returns a reference to
10027 // result itself. An assignment will then create a primitive
10028 // value.
10029 json_pointer(element.first).get_and_create(result) = element.second;
10030 }
10031
10032 return result;
10033 }
10034
10035 private:
10036 /// the reference tokens
10037 std::vector<std::string> reference_tokens {};
10038 };
10039
10040 //////////////////////////
10041 // JSON Pointer support //
10042 //////////////////////////
10043
10044 /// @name JSON Pointer functions
10045 /// @{
10046
10047 /*!
10048 @brief access specified element via JSON Pointer
10049
10050 Uses a JSON pointer to retrieve a reference to the respective JSON value.
10051 No bound checking is performed. Similar to @ref operator[](const typename
10052 object_t::key_type&), `null` values are created in arrays and objects if
10053 necessary.
10054
10055 In particular:
10056 - If the JSON pointer points to an object key that does not exist, it
10057 is created an filled with a `null` value before a reference to it
10058 is returned.
10059 - If the JSON pointer points to an array index that does not exist, it
10060 is created an filled with a `null` value before a reference to it
10061 is returned. All indices between the current maximum and the given
10062 index are also filled with `null`.
10063 - The special value `-` is treated as a synonym for the index past the
10064 end.
10065
10066 @param[in] ptr a JSON pointer
10067
10068 @return reference to the element pointed to by @a ptr
10069
10070 @complexity Constant.
10071
10072 @throw std::out_of_range if the JSON pointer can not be resolved
10073 @throw std::domain_error if an array index begins with '0'
10074 @throw std::invalid_argument if an array index was not a number
10075
10076 @liveexample{The behavior is shown in the example.,operatorjson_pointer}
10077
10078 @since version 2.0.0
10079 */
10080 reference operator[](const json_pointer& ptr)
10081 {
10082 return ptr.get_unchecked(this);
10083 }
10084
10085 /*!
10086 @brief access specified element via JSON Pointer
10087
10088 Uses a JSON pointer to retrieve a reference to the respective JSON value.
10089 No bound checking is performed. The function does not change the JSON
10090 value; no `null` values are created. In particular, the the special value
10091 `-` yields an exception.
10092
10093 @param[in] ptr JSON pointer to the desired element
10094
10095 @return const reference to the element pointed to by @a ptr
10096
10097 @complexity Constant.
10098
10099 @throw std::out_of_range if the JSON pointer can not be resolved
10100 @throw std::domain_error if an array index begins with '0'
10101 @throw std::invalid_argument if an array index was not a number
10102
10103 @liveexample{The behavior is shown in the example.,operatorjson_pointer_const}
10104
10105 @since version 2.0.0
10106 */
10107 const_reference operator[](const json_pointer& ptr) const
10108 {
10109 return ptr.get_unchecked(this);
10110 }
10111
10112 /*!
10113 @brief access specified element via JSON Pointer
10114
10115 Returns a reference to the element at with specified JSON pointer @a ptr,
10116 with bounds checking.
10117
10118 @param[in] ptr JSON pointer to the desired element
10119
10120 @return reference to the element pointed to by @a ptr
10121
10122 @complexity Constant.
10123
10124 @throw std::out_of_range if the JSON pointer can not be resolved
10125 @throw std::domain_error if an array index begins with '0'
10126 @throw std::invalid_argument if an array index was not a number
10127
10128 @liveexample{The behavior is shown in the example.,at_json_pointer}
10129
10130 @since version 2.0.0
10131 */
10132 reference at(const json_pointer& ptr)
10133 {
10134 return ptr.get_checked(this);
10135 }
10136
10137 /*!
10138 @brief access specified element via JSON Pointer
10139
10140 Returns a const reference to the element at with specified JSON pointer @a
10141 ptr, with bounds checking.
10142
10143 @param[in] ptr JSON pointer to the desired element
10144
10145 @return reference to the element pointed to by @a ptr
10146
10147 @complexity Constant.
10148
10149 @throw std::out_of_range if the JSON pointer can not be resolved
10150 @throw std::domain_error if an array index begins with '0'
10151 @throw std::invalid_argument if an array index was not a number
10152
10153 @liveexample{The behavior is shown in the example.,at_json_pointer_const}
10154
10155 @since version 2.0.0
10156 */
10157 const_reference at(const json_pointer& ptr) const
10158 {
10159 return ptr.get_checked(this);
10160 }
10161
10162 /*!
10163 @brief return flattened JSON value
10164
10165 The function creates a JSON object whose keys are JSON pointers (see [RFC
10166 6901](https://tools.ietf.org/html/rfc6901)) and whose values are all
10167 primitive. The original JSON value can be restored using the @ref
10168 unflatten() function.
10169
10170 @return an object that maps JSON pointers to primitve values
10171
10172 @note Empty objects and arrays are flattened to `null` and will not be
10173 reconstructed correctly by the @ref unflatten() function.
10174
10175 @complexity Linear in the size the JSON value.
10176
10177 @liveexample{The following code shows how a JSON object is flattened to an
10178 object whose keys consist of JSON pointers.,flatten}
10179
10180 @sa @ref unflatten() for the reverse function
10181
10182 @since version 2.0.0
10183 */
10184 basic_json flatten() const
10185 {
10186 basic_json result(value_t::object);
10187 json_pointer::flatten("", *this, result);
10188 return result;
10189 }
10190
10191 /*!
10192 @brief unflatten a previously flattened JSON value
10193
10194 The function restores the arbitrary nesting of a JSON value that has been
10195 flattened before using the @ref flatten() function. The JSON value must
10196 meet certain constraints:
10197 1. The value must be an object.
10198 2. The keys must be JSON pointers (see
10199 [RFC 6901](https://tools.ietf.org/html/rfc6901))
10200 3. The mapped values must be primitive JSON types.
10201
10202 @return the original JSON from a flattened version
10203
10204 @note Empty objects and arrays are flattened by @ref flatten() to `null`
10205 values and can not unflattened to their original type. Apart from
10206 this example, for a JSON value `j`, the following is always true:
10207 `j == j.flatten().unflatten()`.
10208
10209 @complexity Linear in the size the JSON value.
10210
10211 @liveexample{The following code shows how a flattened JSON object is
10212 unflattened into the original nested JSON object.,unflatten}
10213
10214 @sa @ref flatten() for the reverse function
10215
10216 @since version 2.0.0
10217 */
10218 basic_json unflatten() const
10219 {
10220 return json_pointer::unflatten(*this);
10221 }
10222
10223 /// @}
10224
10225 //////////////////////////
10226 // JSON Patch functions //
10227 //////////////////////////
10228
10229 /// @name JSON Patch functions
10230 /// @{
10231
10232 /*!
10233 @brief applies a JSON patch
10234
10235 [JSON Patch](http://jsonpatch.com) defines a JSON document structure for
10236 expressing a sequence of operations to apply to a JSON) document. With
10237 this funcion, a JSON Patch is applied to the current JSON value by
10238 executing all operations from the patch.
10239
10240 @param[in] json_patch JSON patch document
10241 @return patched document
10242
10243 @note The application of a patch is atomic: Either all operations succeed
10244 and the patched document is returned or an exception is thrown. In
10245 any case, the original value is not changed: the patch is applied
10246 to a copy of the value.
10247
10248 @throw std::out_of_range if a JSON pointer inside the patch could not
10249 be resolved successfully in the current JSON value; example: `"key baz
10250 not found"`
10251 @throw invalid_argument if the JSON patch is malformed (e.g., mandatory
10252 attributes are missing); example: `"operation add must have member path"`
10253
10254 @complexity Linear in the size of the JSON value and the length of the
10255 JSON patch. As usually only a fraction of the JSON value is affected by
10256 the patch, the complexity can usually be neglected.
10257
10258 @liveexample{The following code shows how a JSON patch is applied to a
10259 value.,patch}
10260
10261 @sa @ref diff -- create a JSON patch by comparing two JSON values
10262
10263 @sa [RFC 6902 (JSON Patch)](https://tools.ietf.org/html/rfc6902)
10264 @sa [RFC 6901 (JSON Pointer)](https://tools.ietf.org/html/rfc6901)
10265
10266 @since version 2.0.0
10267 */
10268 basic_json patch(const basic_json& json_patch) const
10269 {
10270 // make a working copy to apply the patch to
10271 basic_json result = *this;
10272
10273 // the valid JSON Patch operations
10274 enum class patch_operations {add, remove, replace, move, copy, test, invalid};
10275
10276 const auto get_op = [](const std::string op)
10277 {
10278 if (op == "add")
10279 {
10280 return patch_operations::add;
10281 }
10282 if (op == "remove")
10283 {
10284 return patch_operations::remove;
10285 }
10286 if (op == "replace")
10287 {
10288 return patch_operations::replace;
10289 }
10290 if (op == "move")
10291 {
10292 return patch_operations::move;
10293 }
10294 if (op == "copy")
10295 {
10296 return patch_operations::copy;
10297 }
10298 if (op == "test")
10299 {
10300 return patch_operations::test;
10301 }
10302
10303 return patch_operations::invalid;
10304 };
10305
10306 // wrapper for "add" operation; add value at ptr
10307 const auto operation_add = [&result](json_pointer & ptr, basic_json val)
10308 {
10309 // adding to the root of the target document means replacing it
10310 if (ptr.is_root())
10311 {
10312 result = val;
10313 }
10314 else
10315 {
10316 // make sure the top element of the pointer exists
10317 json_pointer top_pointer = ptr.top();
10318 if (top_pointer != ptr)
10319 {
10320 result.at(top_pointer);
10321 }
10322
10323 // get reference to parent of JSON pointer ptr
10324 const auto last_path = ptr.pop_back();
10325 basic_json& parent = result[ptr];
10326
10327 switch (parent.m_type)
10328 {
10329 case value_t::null:
10330 case value_t::object:
10331 {
10332 // use operator[] to add value
10333 parent[last_path] = val;
10334 break;
10335 }
10336
10337 case value_t::array:
10338 {
10339 if (last_path == "-")
10340 {
10341 // special case: append to back
10342 parent.push_back(val);
10343 }
10344 else
10345 {
10346 const auto idx = std::stoi(last_path);
10347 if (static_cast<size_type>(idx) > parent.size())
10348 {
10349 // avoid undefined behavior
10350 throw std::out_of_range("array index " + std::to_string(idx) + " is out of range");
10351 }
10352 else
10353 {
10354 // default case: insert add offset
10355 parent.insert(parent.begin() + static_cast<difference_type>(idx), val);
10356 }
10357 }
10358 break;
10359 }
10360
10361 default:
10362 {
10363 // if there exists a parent it cannot be primitive
10364 assert(false); // LCOV_EXCL_LINE
10365 }
10366 }
10367 }
10368 };
10369
10370 // wrapper for "remove" operation; remove value at ptr
10371 const auto operation_remove = [&result](json_pointer & ptr)
10372 {
10373 // get reference to parent of JSON pointer ptr
10374 const auto last_path = ptr.pop_back();
10375 basic_json& parent = result.at(ptr);
10376
10377 // remove child
10378 if (parent.is_object())
10379 {
10380 // perform range check
10381 auto it = parent.find(last_path);
10382 if (it != parent.end())
10383 {
10384 parent.erase(it);
10385 }
10386 else
10387 {
10388 throw std::out_of_range("key '" + last_path + "' not found");
10389 }
10390 }
10391 else if (parent.is_array())
10392 {
10393 // note erase performs range check
10394 parent.erase(static_cast<size_type>(std::stoi(last_path)));
10395 }
10396 };
10397
10398 // type check
10399 if (not json_patch.is_array())
10400 {
10401 // a JSON patch must be an array of objects
10402 throw std::invalid_argument("JSON patch must be an array of objects");
10403 }
10404
10405 // iterate and apply th eoperations
10406 for (const auto& val : json_patch)
10407 {
10408 // wrapper to get a value for an operation
10409 const auto get_value = [&val](const std::string & op,
10410 const std::string & member,
10411 bool string_type) -> basic_json&
10412 {
10413 // find value
10414 auto it = val.m_value.object->find(member);
10415
10416 // context-sensitive error message
10417 const auto error_msg = (op == "op") ? "operation" : "operation '" + op + "'";
10418
10419 // check if desired value is present
10420 if (it == val.m_value.object->end())
10421 {
10422 throw std::invalid_argument(error_msg + " must have member '" + member + "'");
10423 }
10424
10425 // check if result is of type string
10426 if (string_type and not it->second.is_string())
10427 {
10428 throw std::invalid_argument(error_msg + " must have string member '" + member + "'");
10429 }
10430
10431 // no error: return value
10432 return it->second;
10433 };
10434
10435 // type check
10436 if (not val.is_object())
10437 {
10438 throw std::invalid_argument("JSON patch must be an array of objects");
10439 }
10440
10441 // collect mandatory members
10442 const std::string op = get_value("op", "op", true);
10443 const std::string path = get_value(op, "path", true);
10444 json_pointer ptr(path);
10445
10446 switch (get_op(op))
10447 {
10448 case patch_operations::add:
10449 {
10450 operation_add(ptr, get_value("add", "value", false));
10451 break;
10452 }
10453
10454 case patch_operations::remove:
10455 {
10456 operation_remove(ptr);
10457 break;
10458 }
10459
10460 case patch_operations::replace:
10461 {
10462 // the "path" location must exist - use at()
10463 result.at(ptr) = get_value("replace", "value", false);
10464 break;
10465 }
10466
10467 case patch_operations::move:
10468 {
10469 const std::string from_path = get_value("move", "from", true);
10470 json_pointer from_ptr(from_path);
10471
10472 // the "from" location must exist - use at()
10473 basic_json v = result.at(from_ptr);
10474
10475 // The move operation is functionally identical to a
10476 // "remove" operation on the "from" location, followed
10477 // immediately by an "add" operation at the target
10478 // location with the value that was just removed.
10479 operation_remove(from_ptr);
10480 operation_add(ptr, v);
10481 break;
10482 }
10483
10484 case patch_operations::copy:
10485 {
10486 const std::string from_path = get_value("copy", "from", true);;
10487 const json_pointer from_ptr(from_path);
10488
10489 // the "from" location must exist - use at()
10490 result[ptr] = result.at(from_ptr);
10491 break;
10492 }
10493
10494 case patch_operations::test:
10495 {
10496 bool success = false;
10497 try
10498 {
10499 // check if "value" matches the one at "path"
10500 // the "path" location must exist - use at()
10501 success = (result.at(ptr) == get_value("test", "value", false));
10502 }
10503 catch (std::out_of_range&)
10504 {
10505 // ignore out of range errors: success remains false
10506 }
10507
10508 // throw an exception if test fails
10509 if (not success)
10510 {
10511 throw std::domain_error("unsuccessful: " + val.dump());
10512 }
10513
10514 break;
10515 }
10516
10517 case patch_operations::invalid:
10518 {
10519 // op must be "add", "remove", "replace", "move", "copy", or
10520 // "test"
10521 throw std::invalid_argument("operation value '" + op + "' is invalid");
10522 }
10523 }
10524 }
10525
10526 return result;
10527 }
10528
10529 /*!
10530 @brief creates a diff as a JSON patch
10531
10532 Creates a [JSON Patch](http://jsonpatch.com) so that value @a source can
10533 be changed into the value @a target by calling @ref patch function.
10534
10535 @invariant For two JSON values @a source and @a target, the following code
10536 yields always `true`:
10537 @code {.cpp}
10538 source.patch(diff(source, target)) == target;
10539 @endcode
10540
10541 @note Currently, only `remove`, `add`, and `replace` operations are
10542 generated.
10543
10544 @param[in] source JSON value to copare from
10545 @param[in] target JSON value to copare against
10546 @param[in] path helper value to create JSON pointers
10547
10548 @return a JSON patch to convert the @a source to @a target
10549
10550 @complexity Linear in the lengths of @a source and @a target.
10551
10552 @liveexample{The following code shows how a JSON patch is created as a
10553 diff for two JSON values.,diff}
10554
10555 @sa @ref patch -- apply a JSON patch
10556
10557 @sa [RFC 6902 (JSON Patch)](https://tools.ietf.org/html/rfc6902)
10558
10559 @since version 2.0.0
10560 */
10561 static basic_json diff(const basic_json& source,
10562 const basic_json& target,
10563 const std::string& path = "")
10564 {
10565 // the patch
10566 basic_json result(value_t::array);
10567
10568 // if the values are the same, return empty patch
10569 if (source == target)
10570 {
10571 return result;
10572 }
10573
10574 if (source.type() != target.type())
10575 {
10576 // different types: replace value
10577 result.push_back(
10578 {
10579 {"op", "replace"},
10580 {"path", path},
10581 {"value", target}
10582 });
10583 }
10584 else
10585 {
10586 switch (source.type())
10587 {
10588 case value_t::array:
10589 {
10590 // first pass: traverse common elements
10591 size_t i = 0;
10592 while (i < source.size() and i < target.size())
10593 {
10594 // recursive call to compare array values at index i
10595 auto temp_diff = diff(source[i], target[i], path + "/" + std::to_string(i));
10596 result.insert(result.end(), temp_diff.begin(), temp_diff.end());
10597 ++i;
10598 }
10599
10600 // i now reached the end of at least one array
10601 // in a second pass, traverse the remaining elements
10602
10603 // remove my remaining elements
10604 const auto end_index = static_cast<difference_type>(result.size());
10605 while (i < source.size())
10606 {
10607 // add operations in reverse order to avoid invalid
10608 // indices
10609 result.insert(result.begin() + end_index, object(
10610 {
10611 {"op", "remove"},
10612 {"path", path + "/" + std::to_string(i)}
10613 }));
10614 ++i;
10615 }
10616
10617 // add other remaining elements
10618 while (i < target.size())
10619 {
10620 result.push_back(
10621 {
10622 {"op", "add"},
10623 {"path", path + "/" + std::to_string(i)},
10624 {"value", target[i]}
10625 });
10626 ++i;
10627 }
10628
10629 break;
10630 }
10631
10632 case value_t::object:
10633 {
10634 // first pass: traverse this object's elements
10635 for (auto it = source.begin(); it != source.end(); ++it)
10636 {
10637 // escape the key name to be used in a JSON patch
10638 const auto key = json_pointer::escape(it.key());
10639
10640 if (target.find(it.key()) != target.end())
10641 {
10642 // recursive call to compare object values at key it
10643 auto temp_diff = diff(it.value(), target[it.key()], path + "/" + key);
10644 result.insert(result.end(), temp_diff.begin(), temp_diff.end());
10645 }
10646 else
10647 {
10648 // found a key that is not in o -> remove it
10649 result.push_back(object(
10650 {
10651 {"op", "remove"},
10652 {"path", path + "/" + key}
10653 }));
10654 }
10655 }
10656
10657 // second pass: traverse other object's elements
10658 for (auto it = target.begin(); it != target.end(); ++it)
10659 {
10660 if (source.find(it.key()) == source.end())
10661 {
10662 // found a key that is not in this -> add it
10663 const auto key = json_pointer::escape(it.key());
10664 result.push_back(
10665 {
10666 {"op", "add"},
10667 {"path", path + "/" + key},
10668 {"value", it.value()}
10669 });
10670 }
10671 }
10672
10673 break;
10674 }
10675
10676 default:
10677 {
10678 // both primitive type: replace value
10679 result.push_back(
10680 {
10681 {"op", "replace"},
10682 {"path", path},
10683 {"value", target}
10684 });
10685 break;
10686 }
10687 }
10688 }
10689
10690 return result;
10691 }
10692
10693 /// @}
10694};
10695
10696
10697/////////////
10698// presets //
10699/////////////
10700
10701/*!
10702@brief default JSON class
10703
10704This type is the default specialization of the @ref basic_json class which
10705uses the standard template types.
10706
10707@since version 1.0.0
10708*/
10709using json = basic_json<>;
10710}
10711
10712
10713///////////////////////
10714// nonmember support //
10715///////////////////////
10716
10717// specialization of std::swap, and std::hash
10718namespace std
10719{
10720/*!
10721@brief exchanges the values of two JSON objects
10722
10723@since version 1.0.0
10724*/
10725template<>
10726inline void swap(nlohmann::json& j1,
10727 nlohmann::json& j2) noexcept(
10728 is_nothrow_move_constructible<nlohmann::json>::value and
10729 is_nothrow_move_assignable<nlohmann::json>::value
10730 )
10731{
10732 j1.swap(j2);
10733}
10734
10735/// hash value for JSON objects
10736template<>
10737struct hash<nlohmann::json>
10738{
10739 /*!
10740 @brief return a hash value for a JSON object
10741
10742 @since version 1.0.0
10743 */
10744 std::size_t operator()(const nlohmann::json& j) const
10745 {
10746 // a naive hashing via the string representation
10747 const auto& h = hash<nlohmann::json::string_t>();
10748 return h(j.dump());
10749 }
10750};
10751}
10752
10753/*!
10754@brief user-defined string literal for JSON values
10755
10756This operator implements a user-defined string literal for JSON objects. It
10757can be used by adding `"_json"` to a string literal and returns a JSON object
10758if no parse error occurred.
10759
10760@param[in] s a string representation of a JSON object
10761@param[in] n the length of string @a s
10762@return a JSON object
10763
10764@since version 1.0.0
10765*/
10766inline nlohmann::json operator "" _json(const char* s, std::size_t n)
10767{
10768 return nlohmann::json::parse(s, s + n);
10769}
10770
10771/*!
10772@brief user-defined string literal for JSON pointer
10773
10774This operator implements a user-defined string literal for JSON Pointers. It
10775can be used by adding `"_json_pointer"` to a string literal and returns a JSON pointer
10776object if no parse error occurred.
10777
10778@param[in] s a string representation of a JSON Pointer
10779@param[in] n the length of string @a s
10780@return a JSON pointer object
10781
10782@since version 2.0.0
10783*/
10784inline nlohmann::json::json_pointer operator "" _json_pointer(const char* s, std::size_t n)
10785{
10786 return nlohmann::json::json_pointer(std::string(s, n));
10787}
10788
10789// restore GCC/clang diagnostic settings
10790#if defined(__clang__) || defined(__GNUC__) || defined(__GNUG__)
10791 #pragma GCC diagnostic pop
10792#endif
10793
10794#endif