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flatbuffers-bigfoot/include/flatbuffers/flatbuffers.h
Vladimir Glavnyy 82836a62be [idl_parser] Improve stack overflow protection (#6364) 
* [idl_parser] Improve stack overflow protection

Add stack overflow protection for Flexbuffer and nested Flatbuffer parsers.
Replaces the `Recurse()` method by the new ParseDepthGuard RAII class.

* Remove move operator from Parser.

It was wrong decision to add move ctor and assignment into Parser class.
These operators will make it extremely difficult to add constant or reference fields in the future.

* Remove ';' from definition of FLATBUFFERS_DELETE_FUNC

* Format code

* Make this PR compatible with MSVC2010 (it doesn't support inherited ctor)
2021-01-04 12:39:12 -08:00

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/*
* Copyright 2014 Google Inc. All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef FLATBUFFERS_H_
#define FLATBUFFERS_H_
#include "flatbuffers/base.h"
#include "flatbuffers/stl_emulation.h"
#ifndef FLATBUFFERS_CPP98_STL
#include <functional>
#endif
#if defined(FLATBUFFERS_NAN_DEFAULTS)
# include <cmath>
#endif
namespace flatbuffers {
// Generic 'operator==' with conditional specialisations.
// T e - new value of a scalar field.
// T def - default of scalar (is known at compile-time).
template<typename T> inline bool IsTheSameAs(T e, T def) { return e == def; }
#if defined(FLATBUFFERS_NAN_DEFAULTS) && \
defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0)
// Like `operator==(e, def)` with weak NaN if T=(float|double).
template<typename T> inline bool IsFloatTheSameAs(T e, T def) {
return (e == def) || ((def != def) && (e != e));
}
template<> inline bool IsTheSameAs<float>(float e, float def) {
return IsFloatTheSameAs(e, def);
}
template<> inline bool IsTheSameAs<double>(double e, double def) {
return IsFloatTheSameAs(e, def);
}
#endif
// Check 'v' is out of closed range [low; high].
// Workaround for GCC warning [-Werror=type-limits]:
// comparison is always true due to limited range of data type.
template<typename T>
inline bool IsOutRange(const T &v, const T &low, const T &high) {
return (v < low) || (high < v);
}
// Check 'v' is in closed range [low; high].
template<typename T>
inline bool IsInRange(const T &v, const T &low, const T &high) {
return !IsOutRange(v, low, high);
}
// Wrapper for uoffset_t to allow safe template specialization.
// Value is allowed to be 0 to indicate a null object (see e.g. AddOffset).
template<typename T> struct Offset {
uoffset_t o;
Offset() : o(0) {}
Offset(uoffset_t _o) : o(_o) {}
Offset<void> Union() const { return Offset<void>(o); }
bool IsNull() const { return !o; }
};
inline void EndianCheck() {
int endiantest = 1;
// If this fails, see FLATBUFFERS_LITTLEENDIAN above.
FLATBUFFERS_ASSERT(*reinterpret_cast<char *>(&endiantest) ==
FLATBUFFERS_LITTLEENDIAN);
(void)endiantest;
}
template<typename T> FLATBUFFERS_CONSTEXPR size_t AlignOf() {
// clang-format off
#ifdef _MSC_VER
return __alignof(T);
#else
#ifndef alignof
return __alignof__(T);
#else
return alignof(T);
#endif
#endif
// clang-format on
}
// When we read serialized data from memory, in the case of most scalars,
// we want to just read T, but in the case of Offset, we want to actually
// perform the indirection and return a pointer.
// The template specialization below does just that.
// It is wrapped in a struct since function templates can't overload on the
// return type like this.
// The typedef is for the convenience of callers of this function
// (avoiding the need for a trailing return decltype)
template<typename T> struct IndirectHelper {
typedef T return_type;
typedef T mutable_return_type;
static const size_t element_stride = sizeof(T);
static return_type Read(const uint8_t *p, uoffset_t i) {
return EndianScalar((reinterpret_cast<const T *>(p))[i]);
}
};
template<typename T> struct IndirectHelper<Offset<T>> {
typedef const T *return_type;
typedef T *mutable_return_type;
static const size_t element_stride = sizeof(uoffset_t);
static return_type Read(const uint8_t *p, uoffset_t i) {
p += i * sizeof(uoffset_t);
return reinterpret_cast<return_type>(p + ReadScalar<uoffset_t>(p));
}
};
template<typename T> struct IndirectHelper<const T *> {
typedef const T *return_type;
typedef T *mutable_return_type;
static const size_t element_stride = sizeof(T);
static return_type Read(const uint8_t *p, uoffset_t i) {
return reinterpret_cast<const T *>(p + i * sizeof(T));
}
};
// An STL compatible iterator implementation for Vector below, effectively
// calling Get() for every element.
template<typename T, typename IT> struct VectorIterator {
typedef std::random_access_iterator_tag iterator_category;
typedef IT value_type;
typedef ptrdiff_t difference_type;
typedef IT *pointer;
typedef IT &reference;
VectorIterator(const uint8_t *data, uoffset_t i)
: data_(data + IndirectHelper<T>::element_stride * i) {}
VectorIterator(const VectorIterator &other) : data_(other.data_) {}
VectorIterator() : data_(nullptr) {}
VectorIterator &operator=(const VectorIterator &other) {
data_ = other.data_;
return *this;
}
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
VectorIterator &operator=(VectorIterator &&other) {
data_ = other.data_;
return *this;
}
#endif // !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
bool operator==(const VectorIterator &other) const {
return data_ == other.data_;
}
bool operator<(const VectorIterator &other) const {
return data_ < other.data_;
}
bool operator!=(const VectorIterator &other) const {
return data_ != other.data_;
}
difference_type operator-(const VectorIterator &other) const {
return (data_ - other.data_) / IndirectHelper<T>::element_stride;
}
IT operator*() const { return IndirectHelper<T>::Read(data_, 0); }
IT operator->() const { return IndirectHelper<T>::Read(data_, 0); }
VectorIterator &operator++() {
data_ += IndirectHelper<T>::element_stride;
return *this;
}
VectorIterator operator++(int) {
VectorIterator temp(data_, 0);
data_ += IndirectHelper<T>::element_stride;
return temp;
}
VectorIterator operator+(const uoffset_t &offset) const {
return VectorIterator(data_ + offset * IndirectHelper<T>::element_stride,
0);
}
VectorIterator &operator+=(const uoffset_t &offset) {
data_ += offset * IndirectHelper<T>::element_stride;
return *this;
}
VectorIterator &operator--() {
data_ -= IndirectHelper<T>::element_stride;
return *this;
}
VectorIterator operator--(int) {
VectorIterator temp(data_, 0);
data_ -= IndirectHelper<T>::element_stride;
return temp;
}
VectorIterator operator-(const uoffset_t &offset) const {
return VectorIterator(data_ - offset * IndirectHelper<T>::element_stride,
0);
}
VectorIterator &operator-=(const uoffset_t &offset) {
data_ -= offset * IndirectHelper<T>::element_stride;
return *this;
}
private:
const uint8_t *data_;
};
template<typename Iterator>
struct VectorReverseIterator : public std::reverse_iterator<Iterator> {
explicit VectorReverseIterator(Iterator iter)
: std::reverse_iterator<Iterator>(iter) {}
typename Iterator::value_type operator*() const {
return *(std::reverse_iterator<Iterator>::current);
}
typename Iterator::value_type operator->() const {
return *(std::reverse_iterator<Iterator>::current);
}
};
struct String;
// This is used as a helper type for accessing vectors.
// Vector::data() assumes the vector elements start after the length field.
template<typename T> class Vector {
public:
typedef VectorIterator<T, typename IndirectHelper<T>::mutable_return_type>
iterator;
typedef VectorIterator<T, typename IndirectHelper<T>::return_type>
const_iterator;
typedef VectorReverseIterator<iterator> reverse_iterator;
typedef VectorReverseIterator<const_iterator> const_reverse_iterator;
uoffset_t size() const { return EndianScalar(length_); }
// Deprecated: use size(). Here for backwards compatibility.
FLATBUFFERS_ATTRIBUTE(deprecated("use size() instead"))
uoffset_t Length() const { return size(); }
typedef typename IndirectHelper<T>::return_type return_type;
typedef typename IndirectHelper<T>::mutable_return_type mutable_return_type;
return_type Get(uoffset_t i) const {
FLATBUFFERS_ASSERT(i < size());
return IndirectHelper<T>::Read(Data(), i);
}
return_type operator[](uoffset_t i) const { return Get(i); }
// If this is a Vector of enums, T will be its storage type, not the enum
// type. This function makes it convenient to retrieve value with enum
// type E.
template<typename E> E GetEnum(uoffset_t i) const {
return static_cast<E>(Get(i));
}
// If this a vector of unions, this does the cast for you. There's no check
// to make sure this is the right type!
template<typename U> const U *GetAs(uoffset_t i) const {
return reinterpret_cast<const U *>(Get(i));
}
// If this a vector of unions, this does the cast for you. There's no check
// to make sure this is actually a string!
const String *GetAsString(uoffset_t i) const {
return reinterpret_cast<const String *>(Get(i));
}
const void *GetStructFromOffset(size_t o) const {
return reinterpret_cast<const void *>(Data() + o);
}
iterator begin() { return iterator(Data(), 0); }
const_iterator begin() const { return const_iterator(Data(), 0); }
iterator end() { return iterator(Data(), size()); }
const_iterator end() const { return const_iterator(Data(), size()); }
reverse_iterator rbegin() { return reverse_iterator(end() - 1); }
const_reverse_iterator rbegin() const {
return const_reverse_iterator(end() - 1);
}
reverse_iterator rend() { return reverse_iterator(begin() - 1); }
const_reverse_iterator rend() const {
return const_reverse_iterator(begin() - 1);
}
const_iterator cbegin() const { return begin(); }
const_iterator cend() const { return end(); }
const_reverse_iterator crbegin() const { return rbegin(); }
const_reverse_iterator crend() const { return rend(); }
// Change elements if you have a non-const pointer to this object.
// Scalars only. See reflection.h, and the documentation.
void Mutate(uoffset_t i, const T &val) {
FLATBUFFERS_ASSERT(i < size());
WriteScalar(data() + i, val);
}
// Change an element of a vector of tables (or strings).
// "val" points to the new table/string, as you can obtain from
// e.g. reflection::AddFlatBuffer().
void MutateOffset(uoffset_t i, const uint8_t *val) {
FLATBUFFERS_ASSERT(i < size());
static_assert(sizeof(T) == sizeof(uoffset_t), "Unrelated types");
WriteScalar(data() + i,
static_cast<uoffset_t>(val - (Data() + i * sizeof(uoffset_t))));
}
// Get a mutable pointer to tables/strings inside this vector.
mutable_return_type GetMutableObject(uoffset_t i) const {
FLATBUFFERS_ASSERT(i < size());
return const_cast<mutable_return_type>(IndirectHelper<T>::Read(Data(), i));
}
// The raw data in little endian format. Use with care.
const uint8_t *Data() const {
return reinterpret_cast<const uint8_t *>(&length_ + 1);
}
uint8_t *Data() { return reinterpret_cast<uint8_t *>(&length_ + 1); }
// Similarly, but typed, much like std::vector::data
const T *data() const { return reinterpret_cast<const T *>(Data()); }
T *data() { return reinterpret_cast<T *>(Data()); }
template<typename K> return_type LookupByKey(K key) const {
void *search_result = std::bsearch(
&key, Data(), size(), IndirectHelper<T>::element_stride, KeyCompare<K>);
if (!search_result) {
return nullptr; // Key not found.
}
const uint8_t *element = reinterpret_cast<const uint8_t *>(search_result);
return IndirectHelper<T>::Read(element, 0);
}
protected:
// This class is only used to access pre-existing data. Don't ever
// try to construct these manually.
Vector();
uoffset_t length_;
private:
// This class is a pointer. Copying will therefore create an invalid object.
// Private and unimplemented copy constructor.
Vector(const Vector &);
Vector &operator=(const Vector &);
template<typename K> static int KeyCompare(const void *ap, const void *bp) {
const K *key = reinterpret_cast<const K *>(ap);
const uint8_t *data = reinterpret_cast<const uint8_t *>(bp);
auto table = IndirectHelper<T>::Read(data, 0);
// std::bsearch compares with the operands transposed, so we negate the
// result here.
return -table->KeyCompareWithValue(*key);
}
};
// Represent a vector much like the template above, but in this case we
// don't know what the element types are (used with reflection.h).
class VectorOfAny {
public:
uoffset_t size() const { return EndianScalar(length_); }
const uint8_t *Data() const {
return reinterpret_cast<const uint8_t *>(&length_ + 1);
}
uint8_t *Data() { return reinterpret_cast<uint8_t *>(&length_ + 1); }
protected:
VectorOfAny();
uoffset_t length_;
private:
VectorOfAny(const VectorOfAny &);
VectorOfAny &operator=(const VectorOfAny &);
};
#ifndef FLATBUFFERS_CPP98_STL
template<typename T, typename U>
Vector<Offset<T>> *VectorCast(Vector<Offset<U>> *ptr) {
static_assert(std::is_base_of<T, U>::value, "Unrelated types");
return reinterpret_cast<Vector<Offset<T>> *>(ptr);
}
template<typename T, typename U>
const Vector<Offset<T>> *VectorCast(const Vector<Offset<U>> *ptr) {
static_assert(std::is_base_of<T, U>::value, "Unrelated types");
return reinterpret_cast<const Vector<Offset<T>> *>(ptr);
}
#endif
// Convenient helper function to get the length of any vector, regardless
// of whether it is null or not (the field is not set).
template<typename T> static inline size_t VectorLength(const Vector<T> *v) {
return v ? v->size() : 0;
}
// This is used as a helper type for accessing arrays.
template<typename T, uint16_t length> class Array {
typedef
typename flatbuffers::integral_constant<bool,
flatbuffers::is_scalar<T>::value>
scalar_tag;
typedef
typename flatbuffers::conditional<scalar_tag::value, T, const T *>::type
IndirectHelperType;
public:
typedef uint16_t size_type;
typedef typename IndirectHelper<IndirectHelperType>::return_type return_type;
typedef VectorIterator<T, return_type> const_iterator;
typedef VectorReverseIterator<const_iterator> const_reverse_iterator;
FLATBUFFERS_CONSTEXPR uint16_t size() const { return length; }
return_type Get(uoffset_t i) const {
FLATBUFFERS_ASSERT(i < size());
return IndirectHelper<IndirectHelperType>::Read(Data(), i);
}
return_type operator[](uoffset_t i) const { return Get(i); }
// If this is a Vector of enums, T will be its storage type, not the enum
// type. This function makes it convenient to retrieve value with enum
// type E.
template<typename E> E GetEnum(uoffset_t i) const {
return static_cast<E>(Get(i));
}
const_iterator begin() const { return const_iterator(Data(), 0); }
const_iterator end() const { return const_iterator(Data(), size()); }
const_reverse_iterator rbegin() const {
return const_reverse_iterator(end());
}
const_reverse_iterator rend() const { return const_reverse_iterator(end()); }
const_iterator cbegin() const { return begin(); }
const_iterator cend() const { return end(); }
const_reverse_iterator crbegin() const { return rbegin(); }
const_reverse_iterator crend() const { return rend(); }
// Get a mutable pointer to elements inside this array.
// This method used to mutate arrays of structs followed by a @p Mutate
// operation. For primitive types use @p Mutate directly.
// @warning Assignments and reads to/from the dereferenced pointer are not
// automatically converted to the correct endianness.
typename flatbuffers::conditional<scalar_tag::value, void, T *>::type
GetMutablePointer(uoffset_t i) const {
FLATBUFFERS_ASSERT(i < size());
return const_cast<T *>(&data()[i]);
}
// Change elements if you have a non-const pointer to this object.
void Mutate(uoffset_t i, const T &val) { MutateImpl(scalar_tag(), i, val); }
// The raw data in little endian format. Use with care.
const uint8_t *Data() const { return data_; }
uint8_t *Data() { return data_; }
// Similarly, but typed, much like std::vector::data
const T *data() const { return reinterpret_cast<const T *>(Data()); }
T *data() { return reinterpret_cast<T *>(Data()); }
// Copy data from a span with endian conversion.
// If this Array and the span overlap, the behavior is undefined.
void CopyFromSpan(flatbuffers::span<const T, length> src) {
const auto p1 = reinterpret_cast<const uint8_t *>(src.data());
const auto p2 = Data();
FLATBUFFERS_ASSERT(!(p1 >= p2 && p1 < (p2 + length)) &&
!(p2 >= p1 && p2 < (p1 + length)));
(void)p1;
(void)p2;
CopyFromSpanImpl(
flatbuffers::integral_constant<bool,
!scalar_tag::value || sizeof(T) == 1 || FLATBUFFERS_LITTLEENDIAN>(),
src);
}
protected:
void MutateImpl(flatbuffers::integral_constant<bool, true>, uoffset_t i,
const T &val) {
FLATBUFFERS_ASSERT(i < size());
WriteScalar(data() + i, val);
}
void MutateImpl(flatbuffers::integral_constant<bool, false>, uoffset_t i,
const T &val) {
*(GetMutablePointer(i)) = val;
}
void CopyFromSpanImpl(flatbuffers::integral_constant<bool, true>,
flatbuffers::span<const T, length> src) {
// Use std::memcpy() instead of std::copy() to avoid preformance degradation
// due to aliasing if T is char or unsigned char.
// The size is known at compile time, so memcpy would be inlined.
std::memcpy(data(), src.data(), length * sizeof(T));
}
// Copy data from flatbuffers::span with endian conversion.
void CopyFromSpanImpl(flatbuffers::integral_constant<bool, false>,
flatbuffers::span<const T, length> src) {
for (size_type k = 0; k < length; k++) { Mutate(k, src[k]); }
}
// This class is only used to access pre-existing data. Don't ever
// try to construct these manually.
// 'constexpr' allows us to use 'size()' at compile time.
// @note Must not use 'FLATBUFFERS_CONSTEXPR' here, as const is not allowed on
// a constructor.
#if defined(__cpp_constexpr)
constexpr Array();
#else
Array();
#endif
uint8_t data_[length * sizeof(T)];
private:
// This class is a pointer. Copying will therefore create an invalid object.
// Private and unimplemented copy constructor.
Array(const Array &);
Array &operator=(const Array &);
};
// Specialization for Array[struct] with access using Offset<void> pointer.
// This specialization used by idl_gen_text.cpp.
template<typename T, uint16_t length> class Array<Offset<T>, length> {
static_assert(flatbuffers::is_same<T, void>::value, "unexpected type T");
public:
typedef const void *return_type;
const uint8_t *Data() const { return data_; }
// Make idl_gen_text.cpp::PrintContainer happy.
return_type operator[](uoffset_t) const {
FLATBUFFERS_ASSERT(false);
return nullptr;
}
private:
// This class is only used to access pre-existing data.
Array();
Array(const Array &);
Array &operator=(const Array &);
uint8_t data_[1];
};
// Cast a raw T[length] to a raw flatbuffers::Array<T, length>
// without endian conversion. Use with care.
template<typename T, uint16_t length>
Array<T, length>& CastToArray(T (&arr)[length]) {
return *reinterpret_cast<Array<T, length> *>(arr);
}
template<typename T, uint16_t length>
const Array<T, length>& CastToArray(const T (&arr)[length]) {
return *reinterpret_cast<const Array<T, length> *>(arr);
}
template<typename E, typename T, uint16_t length>
Array<E, length> &CastToArrayOfEnum(T (&arr)[length]) {
static_assert(sizeof(E) == sizeof(T), "invalid enum type E");
return *reinterpret_cast<Array<E, length> *>(arr);
}
template<typename E, typename T, uint16_t length>
const Array<E, length> &CastToArrayOfEnum(const T (&arr)[length]) {
static_assert(sizeof(E) == sizeof(T), "invalid enum type E");
return *reinterpret_cast<const Array<E, length> *>(arr);
}
// Lexicographically compare two strings (possibly containing nulls), and
// return true if the first is less than the second.
static inline bool StringLessThan(const char *a_data, uoffset_t a_size,
const char *b_data, uoffset_t b_size) {
const auto cmp = memcmp(a_data, b_data, (std::min)(a_size, b_size));
return cmp == 0 ? a_size < b_size : cmp < 0;
}
struct String : public Vector<char> {
const char *c_str() const { return reinterpret_cast<const char *>(Data()); }
std::string str() const { return std::string(c_str(), size()); }
// clang-format off
#ifdef FLATBUFFERS_HAS_STRING_VIEW
flatbuffers::string_view string_view() const {
return flatbuffers::string_view(c_str(), size());
}
#endif // FLATBUFFERS_HAS_STRING_VIEW
// clang-format on
bool operator<(const String &o) const {
return StringLessThan(this->data(), this->size(), o.data(), o.size());
}
};
// Convenience function to get std::string from a String returning an empty
// string on null pointer.
static inline std::string GetString(const String *str) {
return str ? str->str() : "";
}
// Convenience function to get char* from a String returning an empty string on
// null pointer.
static inline const char *GetCstring(const String *str) {
return str ? str->c_str() : "";
}
#ifdef FLATBUFFERS_HAS_STRING_VIEW
// Convenience function to get string_view from a String returning an empty
// string_view on null pointer.
static inline flatbuffers::string_view GetStringView(const String *str) {
return str ? str->string_view() : flatbuffers::string_view();
}
#endif // FLATBUFFERS_HAS_STRING_VIEW
// Allocator interface. This is flatbuffers-specific and meant only for
// `vector_downward` usage.
class Allocator {
public:
virtual ~Allocator() {}
// Allocate `size` bytes of memory.
virtual uint8_t *allocate(size_t size) = 0;
// Deallocate `size` bytes of memory at `p` allocated by this allocator.
virtual void deallocate(uint8_t *p, size_t size) = 0;
// Reallocate `new_size` bytes of memory, replacing the old region of size
// `old_size` at `p`. In contrast to a normal realloc, this grows downwards,
// and is intended specifcally for `vector_downward` use.
// `in_use_back` and `in_use_front` indicate how much of `old_size` is
// actually in use at each end, and needs to be copied.
virtual uint8_t *reallocate_downward(uint8_t *old_p, size_t old_size,
size_t new_size, size_t in_use_back,
size_t in_use_front) {
FLATBUFFERS_ASSERT(new_size > old_size); // vector_downward only grows
uint8_t *new_p = allocate(new_size);
memcpy_downward(old_p, old_size, new_p, new_size, in_use_back,
in_use_front);
deallocate(old_p, old_size);
return new_p;
}
protected:
// Called by `reallocate_downward` to copy memory from `old_p` of `old_size`
// to `new_p` of `new_size`. Only memory of size `in_use_front` and
// `in_use_back` will be copied from the front and back of the old memory
// allocation.
void memcpy_downward(uint8_t *old_p, size_t old_size, uint8_t *new_p,
size_t new_size, size_t in_use_back,
size_t in_use_front) {
memcpy(new_p + new_size - in_use_back, old_p + old_size - in_use_back,
in_use_back);
memcpy(new_p, old_p, in_use_front);
}
};
// DefaultAllocator uses new/delete to allocate memory regions
class DefaultAllocator : public Allocator {
public:
uint8_t *allocate(size_t size) FLATBUFFERS_OVERRIDE {
return new uint8_t[size];
}
void deallocate(uint8_t *p, size_t) FLATBUFFERS_OVERRIDE { delete[] p; }
static void dealloc(void *p, size_t) { delete[] static_cast<uint8_t *>(p); }
};
// These functions allow for a null allocator to mean use the default allocator,
// as used by DetachedBuffer and vector_downward below.
// This is to avoid having a statically or dynamically allocated default
// allocator, or having to move it between the classes that may own it.
inline uint8_t *Allocate(Allocator *allocator, size_t size) {
return allocator ? allocator->allocate(size)
: DefaultAllocator().allocate(size);
}
inline void Deallocate(Allocator *allocator, uint8_t *p, size_t size) {
if (allocator)
allocator->deallocate(p, size);
else
DefaultAllocator().deallocate(p, size);
}
inline uint8_t *ReallocateDownward(Allocator *allocator, uint8_t *old_p,
size_t old_size, size_t new_size,
size_t in_use_back, size_t in_use_front) {
return allocator ? allocator->reallocate_downward(old_p, old_size, new_size,
in_use_back, in_use_front)
: DefaultAllocator().reallocate_downward(
old_p, old_size, new_size, in_use_back, in_use_front);
}
// DetachedBuffer is a finished flatbuffer memory region, detached from its
// builder. The original memory region and allocator are also stored so that
// the DetachedBuffer can manage the memory lifetime.
class DetachedBuffer {
public:
DetachedBuffer()
: allocator_(nullptr),
own_allocator_(false),
buf_(nullptr),
reserved_(0),
cur_(nullptr),
size_(0) {}
DetachedBuffer(Allocator *allocator, bool own_allocator, uint8_t *buf,
size_t reserved, uint8_t *cur, size_t sz)
: allocator_(allocator),
own_allocator_(own_allocator),
buf_(buf),
reserved_(reserved),
cur_(cur),
size_(sz) {}
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
DetachedBuffer(DetachedBuffer &&other)
: allocator_(other.allocator_),
own_allocator_(other.own_allocator_),
buf_(other.buf_),
reserved_(other.reserved_),
cur_(other.cur_),
size_(other.size_) {
other.reset();
}
// clang-format off
#endif // !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
DetachedBuffer &operator=(DetachedBuffer &&other) {
if (this == &other) return *this;
destroy();
allocator_ = other.allocator_;
own_allocator_ = other.own_allocator_;
buf_ = other.buf_;
reserved_ = other.reserved_;
cur_ = other.cur_;
size_ = other.size_;
other.reset();
return *this;
}
// clang-format off
#endif // !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
~DetachedBuffer() { destroy(); }
const uint8_t *data() const { return cur_; }
uint8_t *data() { return cur_; }
size_t size() const { return size_; }
// clang-format off
#if 0 // disabled for now due to the ordering of classes in this header
template <class T>
bool Verify() const {
Verifier verifier(data(), size());
return verifier.Verify<T>(nullptr);
}
template <class T>
const T* GetRoot() const {
return flatbuffers::GetRoot<T>(data());
}
template <class T>
T* GetRoot() {
return flatbuffers::GetRoot<T>(data());
}
#endif
// clang-format on
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
// These may change access mode, leave these at end of public section
FLATBUFFERS_DELETE_FUNC(DetachedBuffer(const DetachedBuffer &other));
FLATBUFFERS_DELETE_FUNC(
DetachedBuffer &operator=(const DetachedBuffer &other));
// clang-format off
#endif // !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
protected:
Allocator *allocator_;
bool own_allocator_;
uint8_t *buf_;
size_t reserved_;
uint8_t *cur_;
size_t size_;
inline void destroy() {
if (buf_) Deallocate(allocator_, buf_, reserved_);
if (own_allocator_ && allocator_) { delete allocator_; }
reset();
}
inline void reset() {
allocator_ = nullptr;
own_allocator_ = false;
buf_ = nullptr;
reserved_ = 0;
cur_ = nullptr;
size_ = 0;
}
};
// This is a minimal replication of std::vector<uint8_t> functionality,
// except growing from higher to lower addresses. i.e push_back() inserts data
// in the lowest address in the vector.
// Since this vector leaves the lower part unused, we support a "scratch-pad"
// that can be stored there for temporary data, to share the allocated space.
// Essentially, this supports 2 std::vectors in a single buffer.
class vector_downward {
public:
explicit vector_downward(size_t initial_size, Allocator *allocator,
bool own_allocator, size_t buffer_minalign)
: allocator_(allocator),
own_allocator_(own_allocator),
initial_size_(initial_size),
buffer_minalign_(buffer_minalign),
reserved_(0),
buf_(nullptr),
cur_(nullptr),
scratch_(nullptr) {}
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
vector_downward(vector_downward &&other)
#else
vector_downward(vector_downward &other)
#endif // defined(FLATBUFFERS_CPP98_STL)
// clang-format on
: allocator_(other.allocator_),
own_allocator_(other.own_allocator_),
initial_size_(other.initial_size_),
buffer_minalign_(other.buffer_minalign_),
reserved_(other.reserved_),
buf_(other.buf_),
cur_(other.cur_),
scratch_(other.scratch_) {
// No change in other.allocator_
// No change in other.initial_size_
// No change in other.buffer_minalign_
other.own_allocator_ = false;
other.reserved_ = 0;
other.buf_ = nullptr;
other.cur_ = nullptr;
other.scratch_ = nullptr;
}
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
vector_downward &operator=(vector_downward &&other) {
// Move construct a temporary and swap idiom
vector_downward temp(std::move(other));
swap(temp);
return *this;
}
// clang-format off
#endif // defined(FLATBUFFERS_CPP98_STL)
// clang-format on
~vector_downward() {
clear_buffer();
clear_allocator();
}
void reset() {
clear_buffer();
clear();
}
void clear() {
if (buf_) {
cur_ = buf_ + reserved_;
} else {
reserved_ = 0;
cur_ = nullptr;
}
clear_scratch();
}
void clear_scratch() { scratch_ = buf_; }
void clear_allocator() {
if (own_allocator_ && allocator_) { delete allocator_; }
allocator_ = nullptr;
own_allocator_ = false;
}
void clear_buffer() {
if (buf_) Deallocate(allocator_, buf_, reserved_);
buf_ = nullptr;
}
// Relinquish the pointer to the caller.
uint8_t *release_raw(size_t &allocated_bytes, size_t &offset) {
auto *buf = buf_;
allocated_bytes = reserved_;
offset = static_cast<size_t>(cur_ - buf_);
// release_raw only relinquishes the buffer ownership.
// Does not deallocate or reset the allocator. Destructor will do that.
buf_ = nullptr;
clear();
return buf;
}
// Relinquish the pointer to the caller.
DetachedBuffer release() {
// allocator ownership (if any) is transferred to DetachedBuffer.
DetachedBuffer fb(allocator_, own_allocator_, buf_, reserved_, cur_,
size());
if (own_allocator_) {
allocator_ = nullptr;
own_allocator_ = false;
}
buf_ = nullptr;
clear();
return fb;
}
size_t ensure_space(size_t len) {
FLATBUFFERS_ASSERT(cur_ >= scratch_ && scratch_ >= buf_);
if (len > static_cast<size_t>(cur_ - scratch_)) { reallocate(len); }
// Beyond this, signed offsets may not have enough range:
// (FlatBuffers > 2GB not supported).
FLATBUFFERS_ASSERT(size() < FLATBUFFERS_MAX_BUFFER_SIZE);
return len;
}
inline uint8_t *make_space(size_t len) {
size_t space = ensure_space(len);
cur_ -= space;
return cur_;
}
// Returns nullptr if using the DefaultAllocator.
Allocator *get_custom_allocator() { return allocator_; }
uoffset_t size() const {
return static_cast<uoffset_t>(reserved_ - static_cast<size_t>(cur_ - buf_));
}
uoffset_t scratch_size() const {
return static_cast<uoffset_t>(scratch_ - buf_);
}
size_t capacity() const { return reserved_; }
uint8_t *data() const {
FLATBUFFERS_ASSERT(cur_);
return cur_;
}
uint8_t *scratch_data() const {
FLATBUFFERS_ASSERT(buf_);
return buf_;
}
uint8_t *scratch_end() const {
FLATBUFFERS_ASSERT(scratch_);
return scratch_;
}
uint8_t *data_at(size_t offset) const { return buf_ + reserved_ - offset; }
void push(const uint8_t *bytes, size_t num) {
if (num > 0) { memcpy(make_space(num), bytes, num); }
}
// Specialized version of push() that avoids memcpy call for small data.
template<typename T> void push_small(const T &little_endian_t) {
make_space(sizeof(T));
*reinterpret_cast<T *>(cur_) = little_endian_t;
}
template<typename T> void scratch_push_small(const T &t) {
ensure_space(sizeof(T));
*reinterpret_cast<T *>(scratch_) = t;
scratch_ += sizeof(T);
}
// fill() is most frequently called with small byte counts (<= 4),
// which is why we're using loops rather than calling memset.
void fill(size_t zero_pad_bytes) {
make_space(zero_pad_bytes);
for (size_t i = 0; i < zero_pad_bytes; i++) cur_[i] = 0;
}
// Version for when we know the size is larger.
// Precondition: zero_pad_bytes > 0
void fill_big(size_t zero_pad_bytes) {
memset(make_space(zero_pad_bytes), 0, zero_pad_bytes);
}
void pop(size_t bytes_to_remove) { cur_ += bytes_to_remove; }
void scratch_pop(size_t bytes_to_remove) { scratch_ -= bytes_to_remove; }
void swap(vector_downward &other) {
using std::swap;
swap(allocator_, other.allocator_);
swap(own_allocator_, other.own_allocator_);
swap(initial_size_, other.initial_size_);
swap(buffer_minalign_, other.buffer_minalign_);
swap(reserved_, other.reserved_);
swap(buf_, other.buf_);
swap(cur_, other.cur_);
swap(scratch_, other.scratch_);
}
void swap_allocator(vector_downward &other) {
using std::swap;
swap(allocator_, other.allocator_);
swap(own_allocator_, other.own_allocator_);
}
private:
// You shouldn't really be copying instances of this class.
FLATBUFFERS_DELETE_FUNC(vector_downward(const vector_downward &));
FLATBUFFERS_DELETE_FUNC(vector_downward &operator=(const vector_downward &));
Allocator *allocator_;
bool own_allocator_;
size_t initial_size_;
size_t buffer_minalign_;
size_t reserved_;
uint8_t *buf_;
uint8_t *cur_; // Points at location between empty (below) and used (above).
uint8_t *scratch_; // Points to the end of the scratchpad in use.
void reallocate(size_t len) {
auto old_reserved = reserved_;
auto old_size = size();
auto old_scratch_size = scratch_size();
reserved_ +=
(std::max)(len, old_reserved ? old_reserved / 2 : initial_size_);
reserved_ = (reserved_ + buffer_minalign_ - 1) & ~(buffer_minalign_ - 1);
if (buf_) {
buf_ = ReallocateDownward(allocator_, buf_, old_reserved, reserved_,
old_size, old_scratch_size);
} else {
buf_ = Allocate(allocator_, reserved_);
}
cur_ = buf_ + reserved_ - old_size;
scratch_ = buf_ + old_scratch_size;
}
};
// Converts a Field ID to a virtual table offset.
inline voffset_t FieldIndexToOffset(voffset_t field_id) {
// Should correspond to what EndTable() below builds up.
const int fixed_fields = 2; // Vtable size and Object Size.
return static_cast<voffset_t>((field_id + fixed_fields) * sizeof(voffset_t));
}
template<typename T, typename Alloc>
const T *data(const std::vector<T, Alloc> &v) {
// Eventually the returned pointer gets passed down to memcpy, so
// we need it to be non-null to avoid undefined behavior.
static uint8_t t;
return v.empty() ? reinterpret_cast<const T *>(&t) : &v.front();
}
template<typename T, typename Alloc> T *data(std::vector<T, Alloc> &v) {
// Eventually the returned pointer gets passed down to memcpy, so
// we need it to be non-null to avoid undefined behavior.
static uint8_t t;
return v.empty() ? reinterpret_cast<T *>(&t) : &v.front();
}
/// @endcond
/// @addtogroup flatbuffers_cpp_api
/// @{
/// @class FlatBufferBuilder
/// @brief Helper class to hold data needed in creation of a FlatBuffer.
/// To serialize data, you typically call one of the `Create*()` functions in
/// the generated code, which in turn call a sequence of `StartTable`/
/// `PushElement`/`AddElement`/`EndTable`, or the builtin `CreateString`/
/// `CreateVector` functions. Do this is depth-first order to build up a tree to
/// the root. `Finish()` wraps up the buffer ready for transport.
class FlatBufferBuilder {
public:
/// @brief Default constructor for FlatBufferBuilder.
/// @param[in] initial_size The initial size of the buffer, in bytes. Defaults
/// to `1024`.
/// @param[in] allocator An `Allocator` to use. If null will use
/// `DefaultAllocator`.
/// @param[in] own_allocator Whether the builder/vector should own the
/// allocator. Defaults to / `false`.
/// @param[in] buffer_minalign Force the buffer to be aligned to the given
/// minimum alignment upon reallocation. Only needed if you intend to store
/// types with custom alignment AND you wish to read the buffer in-place
/// directly after creation.
explicit FlatBufferBuilder(
size_t initial_size = 1024, Allocator *allocator = nullptr,
bool own_allocator = false,
size_t buffer_minalign = AlignOf<largest_scalar_t>())
: buf_(initial_size, allocator, own_allocator, buffer_minalign),
num_field_loc(0),
max_voffset_(0),
nested(false),
finished(false),
minalign_(1),
force_defaults_(false),
dedup_vtables_(true),
string_pool(nullptr) {
EndianCheck();
}
// clang-format off
/// @brief Move constructor for FlatBufferBuilder.
#if !defined(FLATBUFFERS_CPP98_STL)
FlatBufferBuilder(FlatBufferBuilder &&other)
#else
FlatBufferBuilder(FlatBufferBuilder &other)
#endif // #if !defined(FLATBUFFERS_CPP98_STL)
: buf_(1024, nullptr, false, AlignOf<largest_scalar_t>()),
num_field_loc(0),
max_voffset_(0),
nested(false),
finished(false),
minalign_(1),
force_defaults_(false),
dedup_vtables_(true),
string_pool(nullptr) {
EndianCheck();
// Default construct and swap idiom.
// Lack of delegating constructors in vs2010 makes it more verbose than needed.
Swap(other);
}
// clang-format on
// clang-format off
#if !defined(FLATBUFFERS_CPP98_STL)
// clang-format on
/// @brief Move assignment operator for FlatBufferBuilder.
FlatBufferBuilder &operator=(FlatBufferBuilder &&other) {
// Move construct a temporary and swap idiom
FlatBufferBuilder temp(std::move(other));
Swap(temp);
return *this;
}
// clang-format off
#endif // defined(FLATBUFFERS_CPP98_STL)
// clang-format on
void Swap(FlatBufferBuilder &other) {
using std::swap;
buf_.swap(other.buf_);
swap(num_field_loc, other.num_field_loc);
swap(max_voffset_, other.max_voffset_);
swap(nested, other.nested);
swap(finished, other.finished);
swap(minalign_, other.minalign_);
swap(force_defaults_, other.force_defaults_);
swap(dedup_vtables_, other.dedup_vtables_);
swap(string_pool, other.string_pool);
}
~FlatBufferBuilder() {
if (string_pool) delete string_pool;
}
void Reset() {
Clear(); // clear builder state
buf_.reset(); // deallocate buffer
}
/// @brief Reset all the state in this FlatBufferBuilder so it can be reused
/// to construct another buffer.
void Clear() {
ClearOffsets();
buf_.clear();
nested = false;
finished = false;
minalign_ = 1;
if (string_pool) string_pool->clear();
}
/// @brief The current size of the serialized buffer, counting from the end.
/// @return Returns an `uoffset_t` with the current size of the buffer.
uoffset_t GetSize() const { return buf_.size(); }
/// @brief Get the serialized buffer (after you call `Finish()`).
/// @return Returns an `uint8_t` pointer to the FlatBuffer data inside the
/// buffer.
uint8_t *GetBufferPointer() const {
Finished();
return buf_.data();
}
/// @brief Get the serialized buffer (after you call `Finish()`) as a span.
/// @return Returns a constructed flatbuffers::span that is a view over the
/// FlatBuffer data inside the buffer.
flatbuffers::span<uint8_t> GetBufferSpan() const {
Finished();
return flatbuffers::span<uint8_t>(buf_.data(), buf_.size());
}
/// @brief Get a pointer to an unfinished buffer.
/// @return Returns a `uint8_t` pointer to the unfinished buffer.
uint8_t *GetCurrentBufferPointer() const { return buf_.data(); }
/// @brief Get the released pointer to the serialized buffer.
/// @warning Do NOT attempt to use this FlatBufferBuilder afterwards!
/// @return A `FlatBuffer` that owns the buffer and its allocator and
/// behaves similar to a `unique_ptr` with a deleter.
FLATBUFFERS_ATTRIBUTE(deprecated("use Release() instead"))
DetachedBuffer ReleaseBufferPointer() {
Finished();
return buf_.release();
}
/// @brief Get the released DetachedBuffer.
/// @return A `DetachedBuffer` that owns the buffer and its allocator.
DetachedBuffer Release() {
Finished();
return buf_.release();
}
/// @brief Get the released pointer to the serialized buffer.
/// @param size The size of the memory block containing
/// the serialized `FlatBuffer`.
/// @param offset The offset from the released pointer where the finished
/// `FlatBuffer` starts.
/// @return A raw pointer to the start of the memory block containing
/// the serialized `FlatBuffer`.
/// @remark If the allocator is owned, it gets deleted when the destructor is
/// called..
uint8_t *ReleaseRaw(size_t &size, size_t &offset) {
Finished();
return buf_.release_raw(size, offset);
}
/// @brief get the minimum alignment this buffer needs to be accessed
/// properly. This is only known once all elements have been written (after
/// you call Finish()). You can use this information if you need to embed
/// a FlatBuffer in some other buffer, such that you can later read it
/// without first having to copy it into its own buffer.
size_t GetBufferMinAlignment() const {
Finished();
return minalign_;
}
/// @cond FLATBUFFERS_INTERNAL
void Finished() const {
// If you get this assert, you're attempting to get access a buffer
// which hasn't been finished yet. Be sure to call
// FlatBufferBuilder::Finish with your root table.
// If you really need to access an unfinished buffer, call
// GetCurrentBufferPointer instead.
FLATBUFFERS_ASSERT(finished);
}
/// @endcond
/// @brief In order to save space, fields that are set to their default value
/// don't get serialized into the buffer.
/// @param[in] fd When set to `true`, always serializes default values that
/// are set. Optional fields which are not set explicitly, will still not be
/// serialized.
void ForceDefaults(bool fd) { force_defaults_ = fd; }
/// @brief By default vtables are deduped in order to save space.
/// @param[in] dedup When set to `true`, dedup vtables.
void DedupVtables(bool dedup) { dedup_vtables_ = dedup; }
/// @cond FLATBUFFERS_INTERNAL
void Pad(size_t num_bytes) { buf_.fill(num_bytes); }
void TrackMinAlign(size_t elem_size) {
if (elem_size > minalign_) minalign_ = elem_size;
}
void Align(size_t elem_size) {
TrackMinAlign(elem_size);
buf_.fill(PaddingBytes(buf_.size(), elem_size));
}
void PushFlatBuffer(const uint8_t *bytes, size_t size) {
PushBytes(bytes, size);
finished = true;
}
void PushBytes(const uint8_t *bytes, size_t size) { buf_.push(bytes, size); }
void PopBytes(size_t amount) { buf_.pop(amount); }
template<typename T> void AssertScalarT() {
// The code assumes power of 2 sizes and endian-swap-ability.
static_assert(flatbuffers::is_scalar<T>::value, "T must be a scalar type");
}
// Write a single aligned scalar to the buffer
template<typename T> uoffset_t PushElement(T element) {
AssertScalarT<T>();
T litle_endian_element = EndianScalar(element);
Align(sizeof(T));
buf_.push_small(litle_endian_element);
return GetSize();
}
template<typename T> uoffset_t PushElement(Offset<T> off) {
// Special case for offsets: see ReferTo below.
return PushElement(ReferTo(off.o));
}
// When writing fields, we track where they are, so we can create correct
// vtables later.
void TrackField(voffset_t field, uoffset_t off) {
FieldLoc fl = { off, field };
buf_.scratch_push_small(fl);
num_field_loc++;
max_voffset_ = (std::max)(max_voffset_, field);
}
// Like PushElement, but additionally tracks the field this represents.
template<typename T> void AddElement(voffset_t field, T e, T def) {
// We don't serialize values equal to the default.
if (IsTheSameAs(e, def) && !force_defaults_) return;
auto off = PushElement(e);
TrackField(field, off);
}
template<typename T> void AddElement(voffset_t field, T e) {
auto off = PushElement(e);
TrackField(field, off);
}
template<typename T> void AddOffset(voffset_t field, Offset<T> off) {
if (off.IsNull()) return; // Don't store.
AddElement(field, ReferTo(off.o), static_cast<uoffset_t>(0));
}
template<typename T> void AddStruct(voffset_t field, const T *structptr) {
if (!structptr) return; // Default, don't store.
Align(AlignOf<T>());
buf_.push_small(*structptr);
TrackField(field, GetSize());
}
void AddStructOffset(voffset_t field, uoffset_t off) {
TrackField(field, off);
}
// Offsets initially are relative to the end of the buffer (downwards).
// This function converts them to be relative to the current location
// in the buffer (when stored here), pointing upwards.
uoffset_t ReferTo(uoffset_t off) {
// Align to ensure GetSize() below is correct.
Align(sizeof(uoffset_t));
// Offset must refer to something already in buffer.
FLATBUFFERS_ASSERT(off && off <= GetSize());
return GetSize() - off + static_cast<uoffset_t>(sizeof(uoffset_t));
}
void NotNested() {
// If you hit this, you're trying to construct a Table/Vector/String
// during the construction of its parent table (between the MyTableBuilder
// and table.Finish().
// Move the creation of these sub-objects to above the MyTableBuilder to
// not get this assert.
// Ignoring this assert may appear to work in simple cases, but the reason
// it is here is that storing objects in-line may cause vtable offsets
// to not fit anymore. It also leads to vtable duplication.
FLATBUFFERS_ASSERT(!nested);
// If you hit this, fields were added outside the scope of a table.
FLATBUFFERS_ASSERT(!num_field_loc);
}
// From generated code (or from the parser), we call StartTable/EndTable
// with a sequence of AddElement calls in between.
uoffset_t StartTable() {
NotNested();
nested = true;
return GetSize();
}
// This finishes one serialized object by generating the vtable if it's a
// table, comparing it against existing vtables, and writing the
// resulting vtable offset.
uoffset_t EndTable(uoffset_t start) {
// If you get this assert, a corresponding StartTable wasn't called.
FLATBUFFERS_ASSERT(nested);
// Write the vtable offset, which is the start of any Table.
// We fill it's value later.
auto vtableoffsetloc = PushElement<soffset_t>(0);
// Write a vtable, which consists entirely of voffset_t elements.
// It starts with the number of offsets, followed by a type id, followed
// by the offsets themselves. In reverse:
// Include space for the last offset and ensure empty tables have a
// minimum size.
max_voffset_ =
(std::max)(static_cast<voffset_t>(max_voffset_ + sizeof(voffset_t)),
FieldIndexToOffset(0));
buf_.fill_big(max_voffset_);
auto table_object_size = vtableoffsetloc - start;
// Vtable use 16bit offsets.
FLATBUFFERS_ASSERT(table_object_size < 0x10000);
WriteScalar<voffset_t>(buf_.data() + sizeof(voffset_t),
static_cast<voffset_t>(table_object_size));
WriteScalar<voffset_t>(buf_.data(), max_voffset_);
// Write the offsets into the table
for (auto it = buf_.scratch_end() - num_field_loc * sizeof(FieldLoc);
it < buf_.scratch_end(); it += sizeof(FieldLoc)) {
auto field_location = reinterpret_cast<FieldLoc *>(it);
auto pos = static_cast<voffset_t>(vtableoffsetloc - field_location->off);
// If this asserts, it means you've set a field twice.
FLATBUFFERS_ASSERT(
!ReadScalar<voffset_t>(buf_.data() + field_location->id));
WriteScalar<voffset_t>(buf_.data() + field_location->id, pos);
}
ClearOffsets();
auto vt1 = reinterpret_cast<voffset_t *>(buf_.data());
auto vt1_size = ReadScalar<voffset_t>(vt1);
auto vt_use = GetSize();
// See if we already have generated a vtable with this exact same
// layout before. If so, make it point to the old one, remove this one.
if (dedup_vtables_) {
for (auto it = buf_.scratch_data(); it < buf_.scratch_end();
it += sizeof(uoffset_t)) {
auto vt_offset_ptr = reinterpret_cast<uoffset_t *>(it);
auto vt2 = reinterpret_cast<voffset_t *>(buf_.data_at(*vt_offset_ptr));
auto vt2_size = ReadScalar<voffset_t>(vt2);
if (vt1_size != vt2_size || 0 != memcmp(vt2, vt1, vt1_size)) continue;
vt_use = *vt_offset_ptr;
buf_.pop(GetSize() - vtableoffsetloc);
break;
}
}
// If this is a new vtable, remember it.
if (vt_use == GetSize()) { buf_.scratch_push_small(vt_use); }
// Fill the vtable offset we created above.
// The offset points from the beginning of the object to where the
// vtable is stored.
// Offsets default direction is downward in memory for future format
// flexibility (storing all vtables at the start of the file).
WriteScalar(buf_.data_at(vtableoffsetloc),
static_cast<soffset_t>(vt_use) -
static_cast<soffset_t>(vtableoffsetloc));
nested = false;
return vtableoffsetloc;
}
FLATBUFFERS_ATTRIBUTE(deprecated("call the version above instead"))
uoffset_t EndTable(uoffset_t start, voffset_t /*numfields*/) {
return EndTable(start);
}
// This checks a required field has been set in a given table that has
// just been constructed.
template<typename T> void Required(Offset<T> table, voffset_t field);
uoffset_t StartStruct(size_t alignment) {
Align(alignment);
return GetSize();
}
uoffset_t EndStruct() { return GetSize(); }
void ClearOffsets() {
buf_.scratch_pop(num_field_loc * sizeof(FieldLoc));
num_field_loc = 0;
max_voffset_ = 0;
}
// Aligns such that when "len" bytes are written, an object can be written
// after it with "alignment" without padding.
void PreAlign(size_t len, size_t alignment) {
TrackMinAlign(alignment);
buf_.fill(PaddingBytes(GetSize() + len, alignment));
}
template<typename T> void PreAlign(size_t len) {
AssertScalarT<T>();
PreAlign(len, sizeof(T));
}
/// @endcond
/// @brief Store a string in the buffer, which can contain any binary data.
/// @param[in] str A const char pointer to the data to be stored as a string.
/// @param[in] len The number of bytes that should be stored from `str`.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateString(const char *str, size_t len) {
NotNested();
PreAlign<uoffset_t>(len + 1); // Always 0-terminated.
buf_.fill(1);
PushBytes(reinterpret_cast<const uint8_t *>(str), len);
PushElement(static_cast<uoffset_t>(len));
return Offset<String>(GetSize());
}
/// @brief Store a string in the buffer, which is null-terminated.
/// @param[in] str A const char pointer to a C-string to add to the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateString(const char *str) {
return CreateString(str, strlen(str));
}
/// @brief Store a string in the buffer, which is null-terminated.
/// @param[in] str A char pointer to a C-string to add to the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateString(char *str) {
return CreateString(str, strlen(str));
}
/// @brief Store a string in the buffer, which can contain any binary data.
/// @param[in] str A const reference to a std::string to store in the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateString(const std::string &str) {
return CreateString(str.c_str(), str.length());
}
// clang-format off
#ifdef FLATBUFFERS_HAS_STRING_VIEW
/// @brief Store a string in the buffer, which can contain any binary data.
/// @param[in] str A const string_view to copy in to the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateString(flatbuffers::string_view str) {
return CreateString(str.data(), str.size());
}
#endif // FLATBUFFERS_HAS_STRING_VIEW
// clang-format on
/// @brief Store a string in the buffer, which can contain any binary data.
/// @param[in] str A const pointer to a `String` struct to add to the buffer.
/// @return Returns the offset in the buffer where the string starts
Offset<String> CreateString(const String *str) {
return str ? CreateString(str->c_str(), str->size()) : 0;
}
/// @brief Store a string in the buffer, which can contain any binary data.
/// @param[in] str A const reference to a std::string like type with support
/// of T::c_str() and T::length() to store in the buffer.
/// @return Returns the offset in the buffer where the string starts.
template<typename T> Offset<String> CreateString(const T &str) {
return CreateString(str.c_str(), str.length());
}
/// @brief Store a string in the buffer, which can contain any binary data.
/// If a string with this exact contents has already been serialized before,
/// instead simply returns the offset of the existing string.
/// @param[in] str A const char pointer to the data to be stored as a string.
/// @param[in] len The number of bytes that should be stored from `str`.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateSharedString(const char *str, size_t len) {
if (!string_pool)
string_pool = new StringOffsetMap(StringOffsetCompare(buf_));
auto size_before_string = buf_.size();
// Must first serialize the string, since the set is all offsets into
// buffer.
auto off = CreateString(str, len);
auto it = string_pool->find(off);
// If it exists we reuse existing serialized data!
if (it != string_pool->end()) {
// We can remove the string we serialized.
buf_.pop(buf_.size() - size_before_string);
return *it;
}
// Record this string for future use.
string_pool->insert(off);
return off;
}
#ifdef FLATBUFFERS_HAS_STRING_VIEW
/// @brief Store a string in the buffer, which can contain any binary data.
/// If a string with this exact contents has already been serialized before,
/// instead simply returns the offset of the existing string.
/// @param[in] str A const std::string_view to store in the buffer.
/// @return Returns the offset in the buffer where the string starts
Offset<String> CreateSharedString(const flatbuffers::string_view str) {
return CreateSharedString(str.data(), str.size());
}
#else
/// @brief Store a string in the buffer, which null-terminated.
/// If a string with this exact contents has already been serialized before,
/// instead simply returns the offset of the existing string.
/// @param[in] str A const char pointer to a C-string to add to the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateSharedString(const char *str) {
return CreateSharedString(str, strlen(str));
}
/// @brief Store a string in the buffer, which can contain any binary data.
/// If a string with this exact contents has already been serialized before,
/// instead simply returns the offset of the existing string.
/// @param[in] str A const reference to a std::string to store in the buffer.
/// @return Returns the offset in the buffer where the string starts.
Offset<String> CreateSharedString(const std::string &str) {
return CreateSharedString(str.c_str(), str.length());
}
#endif
/// @brief Store a string in the buffer, which can contain any binary data.
/// If a string with this exact contents has already been serialized before,
/// instead simply returns the offset of the existing string.
/// @param[in] str A const pointer to a `String` struct to add to the buffer.
/// @return Returns the offset in the buffer where the string starts
Offset<String> CreateSharedString(const String *str) {
return CreateSharedString(str->c_str(), str->size());
}
/// @cond FLATBUFFERS_INTERNAL
uoffset_t EndVector(size_t len) {
FLATBUFFERS_ASSERT(nested); // Hit if no corresponding StartVector.
nested = false;
return PushElement(static_cast<uoffset_t>(len));
}
void StartVector(size_t len, size_t elemsize) {
NotNested();
nested = true;
PreAlign<uoffset_t>(len * elemsize);
PreAlign(len * elemsize, elemsize); // Just in case elemsize > uoffset_t.
}
// Call this right before StartVector/CreateVector if you want to force the
// alignment to be something different than what the element size would
// normally dictate.
// This is useful when storing a nested_flatbuffer in a vector of bytes,
// or when storing SIMD floats, etc.
void ForceVectorAlignment(size_t len, size_t elemsize, size_t alignment) {
PreAlign(len * elemsize, alignment);
}
// Similar to ForceVectorAlignment but for String fields.
void ForceStringAlignment(size_t len, size_t alignment) {
PreAlign((len + 1) * sizeof(char), alignment);
}
/// @endcond
/// @brief Serialize an array into a FlatBuffer `vector`.
/// @tparam T The data type of the array elements.
/// @param[in] v A pointer to the array of type `T` to serialize into the
/// buffer as a `vector`.
/// @param[in] len The number of elements to serialize.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T> Offset<Vector<T>> CreateVector(const T *v, size_t len) {
// If this assert hits, you're specifying a template argument that is
// causing the wrong overload to be selected, remove it.
AssertScalarT<T>();
StartVector(len, sizeof(T));
if (len == 0) {
return Offset<Vector<T>>(EndVector(len));
}
// clang-format off
#if FLATBUFFERS_LITTLEENDIAN
PushBytes(reinterpret_cast<const uint8_t *>(v), len * sizeof(T));
#else
if (sizeof(T) == 1) {
PushBytes(reinterpret_cast<const uint8_t *>(v), len);
} else {
for (auto i = len; i > 0; ) {
PushElement(v[--i]);
}
}
#endif
// clang-format on
return Offset<Vector<T>>(EndVector(len));
}
template<typename T>
Offset<Vector<Offset<T>>> CreateVector(const Offset<T> *v, size_t len) {
StartVector(len, sizeof(Offset<T>));
for (auto i = len; i > 0;) { PushElement(v[--i]); }
return Offset<Vector<Offset<T>>>(EndVector(len));
}
/// @brief Serialize a `std::vector` into a FlatBuffer `vector`.
/// @tparam T The data type of the `std::vector` elements.
/// @param v A const reference to the `std::vector` to serialize into the
/// buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T> Offset<Vector<T>> CreateVector(const std::vector<T> &v) {
return CreateVector(data(v), v.size());
}
// vector<bool> may be implemented using a bit-set, so we can't access it as
// an array. Instead, read elements manually.
// Background: https://isocpp.org/blog/2012/11/on-vectorbool
Offset<Vector<uint8_t>> CreateVector(const std::vector<bool> &v) {
StartVector(v.size(), sizeof(uint8_t));
for (auto i = v.size(); i > 0;) {
PushElement(static_cast<uint8_t>(v[--i]));
}
return Offset<Vector<uint8_t>>(EndVector(v.size()));
}
// clang-format off
#ifndef FLATBUFFERS_CPP98_STL
/// @brief Serialize values returned by a function into a FlatBuffer `vector`.
/// This is a convenience function that takes care of iteration for you.
/// @tparam T The data type of the `std::vector` elements.
/// @param f A function that takes the current iteration 0..vector_size-1 and
/// returns any type that you can construct a FlatBuffers vector out of.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T> Offset<Vector<T>> CreateVector(size_t vector_size,
const std::function<T (size_t i)> &f) {
std::vector<T> elems(vector_size);
for (size_t i = 0; i < vector_size; i++) elems[i] = f(i);
return CreateVector(elems);
}
#endif
// clang-format on
/// @brief Serialize values returned by a function into a FlatBuffer `vector`.
/// This is a convenience function that takes care of iteration for you.
/// @tparam T The data type of the `std::vector` elements.
/// @param f A function that takes the current iteration 0..vector_size-1,
/// and the state parameter returning any type that you can construct a
/// FlatBuffers vector out of.
/// @param state State passed to f.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename F, typename S>
Offset<Vector<T>> CreateVector(size_t vector_size, F f, S *state) {
std::vector<T> elems(vector_size);
for (size_t i = 0; i < vector_size; i++) elems[i] = f(i, state);
return CreateVector(elems);
}
/// @brief Serialize a `std::vector<std::string>` into a FlatBuffer `vector`.
/// This is a convenience function for a common case.
/// @param v A const reference to the `std::vector` to serialize into the
/// buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
Offset<Vector<Offset<String>>> CreateVectorOfStrings(
const std::vector<std::string> &v) {
std::vector<Offset<String>> offsets(v.size());
for (size_t i = 0; i < v.size(); i++) offsets[i] = CreateString(v[i]);
return CreateVector(offsets);
}
/// @brief Serialize an array of structs into a FlatBuffer `vector`.
/// @tparam T The data type of the struct array elements.
/// @param[in] v A pointer to the array of type `T` to serialize into the
/// buffer as a `vector`.
/// @param[in] len The number of elements to serialize.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T>
Offset<Vector<const T *>> CreateVectorOfStructs(const T *v, size_t len) {
StartVector(len * sizeof(T) / AlignOf<T>(), AlignOf<T>());
PushBytes(reinterpret_cast<const uint8_t *>(v), sizeof(T) * len);
return Offset<Vector<const T *>>(EndVector(len));
}
/// @brief Serialize an array of native structs into a FlatBuffer `vector`.
/// @tparam T The data type of the struct array elements.
/// @tparam S The data type of the native struct array elements.
/// @param[in] v A pointer to the array of type `S` to serialize into the
/// buffer as a `vector`.
/// @param[in] len The number of elements to serialize.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename S>
Offset<Vector<const T *>> CreateVectorOfNativeStructs(const S *v,
size_t len) {
extern T Pack(const S &);
std::vector<T> vv(len);
std::transform(v, v + len, vv.begin(), Pack);
return CreateVectorOfStructs<T>(data(vv), vv.size());
}
// clang-format off
#ifndef FLATBUFFERS_CPP98_STL
/// @brief Serialize an array of structs into a FlatBuffer `vector`.
/// @tparam T The data type of the struct array elements.
/// @param[in] filler A function that takes the current iteration 0..vector_size-1
/// and a pointer to the struct that must be filled.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
/// This is mostly useful when flatbuffers are generated with mutation
/// accessors.
template<typename T> Offset<Vector<const T *>> CreateVectorOfStructs(
size_t vector_size, const std::function<void(size_t i, T *)> &filler) {
T* structs = StartVectorOfStructs<T>(vector_size);
for (size_t i = 0; i < vector_size; i++) {
filler(i, structs);
structs++;
}
return EndVectorOfStructs<T>(vector_size);
}
#endif
// clang-format on
/// @brief Serialize an array of structs into a FlatBuffer `vector`.
/// @tparam T The data type of the struct array elements.
/// @param[in] f A function that takes the current iteration 0..vector_size-1,
/// a pointer to the struct that must be filled and the state argument.
/// @param[in] state Arbitrary state to pass to f.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
/// This is mostly useful when flatbuffers are generated with mutation
/// accessors.
template<typename T, typename F, typename S>
Offset<Vector<const T *>> CreateVectorOfStructs(size_t vector_size, F f,
S *state) {
T *structs = StartVectorOfStructs<T>(vector_size);
for (size_t i = 0; i < vector_size; i++) {
f(i, structs, state);
structs++;
}
return EndVectorOfStructs<T>(vector_size);
}
/// @brief Serialize a `std::vector` of structs into a FlatBuffer `vector`.
/// @tparam T The data type of the `std::vector` struct elements.
/// @param[in] v A const reference to the `std::vector` of structs to
/// serialize into the buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename Alloc>
Offset<Vector<const T *>> CreateVectorOfStructs(
const std::vector<T, Alloc> &v) {
return CreateVectorOfStructs(data(v), v.size());
}
/// @brief Serialize a `std::vector` of native structs into a FlatBuffer
/// `vector`.
/// @tparam T The data type of the `std::vector` struct elements.
/// @tparam S The data type of the `std::vector` native struct elements.
/// @param[in] v A const reference to the `std::vector` of structs to
/// serialize into the buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename S>
Offset<Vector<const T *>> CreateVectorOfNativeStructs(
const std::vector<S> &v) {
return CreateVectorOfNativeStructs<T, S>(data(v), v.size());
}
/// @cond FLATBUFFERS_INTERNAL
template<typename T> struct StructKeyComparator {
bool operator()(const T &a, const T &b) const {
return a.KeyCompareLessThan(&b);
}
FLATBUFFERS_DELETE_FUNC(
StructKeyComparator &operator=(const StructKeyComparator &));
};
/// @endcond
/// @brief Serialize a `std::vector` of structs into a FlatBuffer `vector`
/// in sorted order.
/// @tparam T The data type of the `std::vector` struct elements.
/// @param[in] v A const reference to the `std::vector` of structs to
/// serialize into the buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T>
Offset<Vector<const T *>> CreateVectorOfSortedStructs(std::vector<T> *v) {
return CreateVectorOfSortedStructs(data(*v), v->size());
}
/// @brief Serialize a `std::vector` of native structs into a FlatBuffer
/// `vector` in sorted order.
/// @tparam T The data type of the `std::vector` struct elements.
/// @tparam S The data type of the `std::vector` native struct elements.
/// @param[in] v A const reference to the `std::vector` of structs to
/// serialize into the buffer as a `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename S>
Offset<Vector<const T *>> CreateVectorOfSortedNativeStructs(
std::vector<S> *v) {
return CreateVectorOfSortedNativeStructs<T, S>(data(*v), v->size());
}
/// @brief Serialize an array of structs into a FlatBuffer `vector` in sorted
/// order.
/// @tparam T The data type of the struct array elements.
/// @param[in] v A pointer to the array of type `T` to serialize into the
/// buffer as a `vector`.
/// @param[in] len The number of elements to serialize.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T>
Offset<Vector<const T *>> CreateVectorOfSortedStructs(T *v, size_t len) {
std::sort(v, v + len, StructKeyComparator<T>());
return CreateVectorOfStructs(v, len);
}
/// @brief Serialize an array of native structs into a FlatBuffer `vector` in
/// sorted order.
/// @tparam T The data type of the struct array elements.
/// @tparam S The data type of the native struct array elements.
/// @param[in] v A pointer to the array of type `S` to serialize into the
/// buffer as a `vector`.
/// @param[in] len The number of elements to serialize.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T, typename S>
Offset<Vector<const T *>> CreateVectorOfSortedNativeStructs(S *v,
size_t len) {
extern T Pack(const S &);
typedef T (*Pack_t)(const S &);
std::vector<T> vv(len);
std::transform(v, v + len, vv.begin(), static_cast<Pack_t &>(Pack));
return CreateVectorOfSortedStructs<T>(vv, len);
}
/// @cond FLATBUFFERS_INTERNAL
template<typename T> struct TableKeyComparator {
TableKeyComparator(vector_downward &buf) : buf_(buf) {}
TableKeyComparator(const TableKeyComparator &other) : buf_(other.buf_) {}
bool operator()(const Offset<T> &a, const Offset<T> &b) const {
auto table_a = reinterpret_cast<T *>(buf_.data_at(a.o));
auto table_b = reinterpret_cast<T *>(buf_.data_at(b.o));
return table_a->KeyCompareLessThan(table_b);
}
vector_downward &buf_;
private:
FLATBUFFERS_DELETE_FUNC(
TableKeyComparator &operator=(const TableKeyComparator &other));
};
/// @endcond
/// @brief Serialize an array of `table` offsets as a `vector` in the buffer
/// in sorted order.
/// @tparam T The data type that the offset refers to.
/// @param[in] v An array of type `Offset<T>` that contains the `table`
/// offsets to store in the buffer in sorted order.
/// @param[in] len The number of elements to store in the `vector`.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T>
Offset<Vector<Offset<T>>> CreateVectorOfSortedTables(Offset<T> *v,
size_t len) {
std::sort(v, v + len, TableKeyComparator<T>(buf_));
return CreateVector(v, len);
}
/// @brief Serialize an array of `table` offsets as a `vector` in the buffer
/// in sorted order.
/// @tparam T The data type that the offset refers to.
/// @param[in] v An array of type `Offset<T>` that contains the `table`
/// offsets to store in the buffer in sorted order.
/// @return Returns a typed `Offset` into the serialized data indicating
/// where the vector is stored.
template<typename T>
Offset<Vector<Offset<T>>> CreateVectorOfSortedTables(
std::vector<Offset<T>> *v) {
return CreateVectorOfSortedTables(data(*v), v->size());
}
/// @brief Specialized version of `CreateVector` for non-copying use cases.
/// Write the data any time later to the returned buffer pointer `buf`.
/// @param[in] len The number of elements to store in the `vector`.
/// @param[in] elemsize The size of each element in the `vector`.
/// @param[out] buf A pointer to a `uint8_t` pointer that can be
/// written to at a later time to serialize the data into a `vector`
/// in the buffer.
uoffset_t CreateUninitializedVector(size_t len, size_t elemsize,
uint8_t **buf) {
NotNested();
StartVector(len, elemsize);
buf_.make_space(len * elemsize);
auto vec_start = GetSize();
auto vec_end = EndVector(len);
*buf = buf_.data_at(vec_start);
return vec_end;
}
/// @brief Specialized version of `CreateVector` for non-copying use cases.
/// Write the data any time later to the returned buffer pointer `buf`.
/// @tparam T The data type of the data that will be stored in the buffer
/// as a `vector`.
/// @param[in] len The number of elements to store in the `vector`.
/// @param[out] buf A pointer to a pointer of type `T` that can be
/// written to at a later time to serialize the data into a `vector`
/// in the buffer.
template<typename T>
Offset<Vector<T>> CreateUninitializedVector(size_t len, T **buf) {
AssertScalarT<T>();
return CreateUninitializedVector(len, sizeof(T),
reinterpret_cast<uint8_t **>(buf));
}
template<typename T>
Offset<Vector<const T *>> CreateUninitializedVectorOfStructs(size_t len,
T **buf) {
return CreateUninitializedVector(len, sizeof(T),
reinterpret_cast<uint8_t **>(buf));
}
// @brief Create a vector of scalar type T given as input a vector of scalar
// type U, useful with e.g. pre "enum class" enums, or any existing scalar
// data of the wrong type.
template<typename T, typename U>
Offset<Vector<T>> CreateVectorScalarCast(const U *v, size_t len) {
AssertScalarT<T>();
AssertScalarT<U>();
StartVector(len, sizeof(T));
for (auto i = len; i > 0;) { PushElement(static_cast<T>(v[--i])); }
return Offset<Vector<T>>(EndVector(len));
}
/// @brief Write a struct by itself, typically to be part of a union.
template<typename T> Offset<const T *> CreateStruct(const T &structobj) {
NotNested();
Align(AlignOf<T>());
buf_.push_small(structobj);
return Offset<const T *>(GetSize());
}
/// @brief The length of a FlatBuffer file header.
static const size_t kFileIdentifierLength = 4;
/// @brief Finish serializing a buffer by writing the root offset.
/// @param[in] file_identifier If a `file_identifier` is given, the buffer
/// will be prefixed with a standard FlatBuffers file header.
template<typename T>
void Finish(Offset<T> root, const char *file_identifier = nullptr) {
Finish(root.o, file_identifier, false);
}
/// @brief Finish a buffer with a 32 bit size field pre-fixed (size of the
/// buffer following the size field). These buffers are NOT compatible
/// with standard buffers created by Finish, i.e. you can't call GetRoot
/// on them, you have to use GetSizePrefixedRoot instead.
/// All >32 bit quantities in this buffer will be aligned when the whole
/// size pre-fixed buffer is aligned.
/// These kinds of buffers are useful for creating a stream of FlatBuffers.
template<typename T>
void FinishSizePrefixed(Offset<T> root,
const char *file_identifier = nullptr) {
Finish(root.o, file_identifier, true);
}
void SwapBufAllocator(FlatBufferBuilder &other) {
buf_.swap_allocator(other.buf_);
}
protected:
// You shouldn't really be copying instances of this class.
FlatBufferBuilder(const FlatBufferBuilder &);
FlatBufferBuilder &operator=(const FlatBufferBuilder &);
void Finish(uoffset_t root, const char *file_identifier, bool size_prefix) {
NotNested();
buf_.clear_scratch();
// This will cause the whole buffer to be aligned.
PreAlign((size_prefix ? sizeof(uoffset_t) : 0) + sizeof(uoffset_t) +
(file_identifier ? kFileIdentifierLength : 0),
minalign_);
if (file_identifier) {
FLATBUFFERS_ASSERT(strlen(file_identifier) == kFileIdentifierLength);
PushBytes(reinterpret_cast<const uint8_t *>(file_identifier),
kFileIdentifierLength);
}
PushElement(ReferTo(root)); // Location of root.
if (size_prefix) { PushElement(GetSize()); }
finished = true;
}
struct FieldLoc {
uoffset_t off;
voffset_t id;
};
vector_downward buf_;
// Accumulating offsets of table members while it is being built.
// We store these in the scratch pad of buf_, after the vtable offsets.
uoffset_t num_field_loc;
// Track how much of the vtable is in use, so we can output the most compact
// possible vtable.
voffset_t max_voffset_;
// Ensure objects are not nested.
bool nested;
// Ensure the buffer is finished before it is being accessed.
bool finished;
size_t minalign_;
bool force_defaults_; // Serialize values equal to their defaults anyway.
bool dedup_vtables_;
struct StringOffsetCompare {
StringOffsetCompare(const vector_downward &buf) : buf_(&buf) {}
bool operator()(const Offset<String> &a, const Offset<String> &b) const {
auto stra = reinterpret_cast<const String *>(buf_->data_at(a.o));
auto strb = reinterpret_cast<const String *>(buf_->data_at(b.o));
return StringLessThan(stra->data(), stra->size(), strb->data(),
strb->size());
}
const vector_downward *buf_;
};
// For use with CreateSharedString. Instantiated on first use only.
typedef std::set<Offset<String>, StringOffsetCompare> StringOffsetMap;
StringOffsetMap *string_pool;
private:
// Allocates space for a vector of structures.
// Must be completed with EndVectorOfStructs().
template<typename T> T *StartVectorOfStructs(size_t vector_size) {
StartVector(vector_size * sizeof(T) / AlignOf<T>(), AlignOf<T>());
return reinterpret_cast<T *>(buf_.make_space(vector_size * sizeof(T)));
}
// End the vector of structues in the flatbuffers.
// Vector should have previously be started with StartVectorOfStructs().
template<typename T>
Offset<Vector<const T *>> EndVectorOfStructs(size_t vector_size) {
return Offset<Vector<const T *>>(EndVector(vector_size));
}
};
/// @}
/// @cond FLATBUFFERS_INTERNAL
// Helpers to get a typed pointer to the root object contained in the buffer.
template<typename T> T *GetMutableRoot(void *buf) {
EndianCheck();
return reinterpret_cast<T *>(
reinterpret_cast<uint8_t *>(buf) +
EndianScalar(*reinterpret_cast<uoffset_t *>(buf)));
}
template<typename T> const T *GetRoot(const void *buf) {
return GetMutableRoot<T>(const_cast<void *>(buf));
}
template<typename T> const T *GetSizePrefixedRoot(const void *buf) {
return GetRoot<T>(reinterpret_cast<const uint8_t *>(buf) + sizeof(uoffset_t));
}
/// Helpers to get a typed pointer to objects that are currently being built.
/// @warning Creating new objects will lead to reallocations and invalidates
/// the pointer!
template<typename T>
T *GetMutableTemporaryPointer(FlatBufferBuilder &fbb, Offset<T> offset) {
return reinterpret_cast<T *>(fbb.GetCurrentBufferPointer() + fbb.GetSize() -
offset.o);
}
template<typename T>
const T *GetTemporaryPointer(FlatBufferBuilder &fbb, Offset<T> offset) {
return GetMutableTemporaryPointer<T>(fbb, offset);
}
/// @brief Get a pointer to the the file_identifier section of the buffer.
/// @return Returns a const char pointer to the start of the file_identifier
/// characters in the buffer. The returned char * has length
/// 'flatbuffers::FlatBufferBuilder::kFileIdentifierLength'.
/// This function is UNDEFINED for FlatBuffers whose schema does not include
/// a file_identifier (likely points at padding or the start of a the root
/// vtable).
inline const char *GetBufferIdentifier(const void *buf,
bool size_prefixed = false) {
return reinterpret_cast<const char *>(buf) +
((size_prefixed) ? 2 * sizeof(uoffset_t) : sizeof(uoffset_t));
}
// Helper to see if the identifier in a buffer has the expected value.
inline bool BufferHasIdentifier(const void *buf, const char *identifier,
bool size_prefixed = false) {
return strncmp(GetBufferIdentifier(buf, size_prefixed), identifier,
FlatBufferBuilder::kFileIdentifierLength) == 0;
}
// Helper class to verify the integrity of a FlatBuffer
class Verifier FLATBUFFERS_FINAL_CLASS {
public:
Verifier(const uint8_t *buf, size_t buf_len, uoffset_t _max_depth = 64,
uoffset_t _max_tables = 1000000, bool _check_alignment = true)
: buf_(buf),
size_(buf_len),
depth_(0),
max_depth_(_max_depth),
num_tables_(0),
max_tables_(_max_tables),
upper_bound_(0),
check_alignment_(_check_alignment) {
FLATBUFFERS_ASSERT(size_ < FLATBUFFERS_MAX_BUFFER_SIZE);
}
// Central location where any verification failures register.
bool Check(bool ok) const {
// clang-format off
#ifdef FLATBUFFERS_DEBUG_VERIFICATION_FAILURE
FLATBUFFERS_ASSERT(ok);
#endif
#ifdef FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE
if (!ok)
upper_bound_ = 0;
#endif
// clang-format on
return ok;
}
// Verify any range within the buffer.
bool Verify(size_t elem, size_t elem_len) const {
// clang-format off
#ifdef FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE
auto upper_bound = elem + elem_len;
if (upper_bound_ < upper_bound)
upper_bound_ = upper_bound;
#endif
// clang-format on
return Check(elem_len < size_ && elem <= size_ - elem_len);
}
template<typename T> bool VerifyAlignment(size_t elem) const {
return Check((elem & (sizeof(T) - 1)) == 0 || !check_alignment_);
}
// Verify a range indicated by sizeof(T).
template<typename T> bool Verify(size_t elem) const {
return VerifyAlignment<T>(elem) && Verify(elem, sizeof(T));
}
bool VerifyFromPointer(const uint8_t *p, size_t len) {
auto o = static_cast<size_t>(p - buf_);
return Verify(o, len);
}
// Verify relative to a known-good base pointer.
bool Verify(const uint8_t *base, voffset_t elem_off, size_t elem_len) const {
return Verify(static_cast<size_t>(base - buf_) + elem_off, elem_len);
}
template<typename T>
bool Verify(const uint8_t *base, voffset_t elem_off) const {
return Verify(static_cast<size_t>(base - buf_) + elem_off, sizeof(T));
}
// Verify a pointer (may be NULL) of a table type.
template<typename T> bool VerifyTable(const T *table) {
return !table || table->Verify(*this);
}
// Verify a pointer (may be NULL) of any vector type.
template<typename T> bool VerifyVector(const Vector<T> *vec) const {
return !vec || VerifyVectorOrString(reinterpret_cast<const uint8_t *>(vec),
sizeof(T));
}
// Verify a pointer (may be NULL) of a vector to struct.
template<typename T> bool VerifyVector(const Vector<const T *> *vec) const {
return VerifyVector(reinterpret_cast<const Vector<T> *>(vec));
}
// Verify a pointer (may be NULL) to string.
bool VerifyString(const String *str) const {
size_t end;
return !str || (VerifyVectorOrString(reinterpret_cast<const uint8_t *>(str),
1, &end) &&
Verify(end, 1) && // Must have terminator
Check(buf_[end] == '\0')); // Terminating byte must be 0.
}
// Common code between vectors and strings.
bool VerifyVectorOrString(const uint8_t *vec, size_t elem_size,
size_t *end = nullptr) const {
auto veco = static_cast<size_t>(vec - buf_);
// Check we can read the size field.
if (!Verify<uoffset_t>(veco)) return false;
// Check the whole array. If this is a string, the byte past the array
// must be 0.
auto size = ReadScalar<uoffset_t>(vec);
auto max_elems = FLATBUFFERS_MAX_BUFFER_SIZE / elem_size;
if (!Check(size < max_elems))
return false; // Protect against byte_size overflowing.
auto byte_size = sizeof(size) + elem_size * size;
if (end) *end = veco + byte_size;
return Verify(veco, byte_size);
}
// Special case for string contents, after the above has been called.
bool VerifyVectorOfStrings(const Vector<Offset<String>> *vec) const {
if (vec) {
for (uoffset_t i = 0; i < vec->size(); i++) {
if (!VerifyString(vec->Get(i))) return false;
}
}
return true;
}
// Special case for table contents, after the above has been called.
template<typename T> bool VerifyVectorOfTables(const Vector<Offset<T>> *vec) {
if (vec) {
for (uoffset_t i = 0; i < vec->size(); i++) {
if (!vec->Get(i)->Verify(*this)) return false;
}
}
return true;
}
__supress_ubsan__("unsigned-integer-overflow") bool VerifyTableStart(
const uint8_t *table) {
// Check the vtable offset.
auto tableo = static_cast<size_t>(table - buf_);
if (!Verify<soffset_t>(tableo)) return false;
// This offset may be signed, but doing the subtraction unsigned always
// gives the result we want.
auto vtableo = tableo - static_cast<size_t>(ReadScalar<soffset_t>(table));
// Check the vtable size field, then check vtable fits in its entirety.
return VerifyComplexity() && Verify<voffset_t>(vtableo) &&
VerifyAlignment<voffset_t>(ReadScalar<voffset_t>(buf_ + vtableo)) &&
Verify(vtableo, ReadScalar<voffset_t>(buf_ + vtableo));
}
template<typename T>
bool VerifyBufferFromStart(const char *identifier, size_t start) {
if (identifier && !Check((size_ >= 2 * sizeof(flatbuffers::uoffset_t) &&
BufferHasIdentifier(buf_ + start, identifier)))) {
return false;
}
// Call T::Verify, which must be in the generated code for this type.
auto o = VerifyOffset(start);
return o && reinterpret_cast<const T *>(buf_ + start + o)->Verify(*this)
// clang-format off
#ifdef FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE
&& GetComputedSize()
#endif
;
// clang-format on
}
// Verify this whole buffer, starting with root type T.
template<typename T> bool VerifyBuffer() { return VerifyBuffer<T>(nullptr); }
template<typename T> bool VerifyBuffer(const char *identifier) {
return VerifyBufferFromStart<T>(identifier, 0);
}
template<typename T> bool VerifySizePrefixedBuffer(const char *identifier) {
return Verify<uoffset_t>(0U) &&
ReadScalar<uoffset_t>(buf_) == size_ - sizeof(uoffset_t) &&
VerifyBufferFromStart<T>(identifier, sizeof(uoffset_t));
}
uoffset_t VerifyOffset(size_t start) const {
if (!Verify<uoffset_t>(start)) return 0;
auto o = ReadScalar<uoffset_t>(buf_ + start);
// May not point to itself.
if (!Check(o != 0)) return 0;
// Can't wrap around / buffers are max 2GB.
if (!Check(static_cast<soffset_t>(o) >= 0)) return 0;
// Must be inside the buffer to create a pointer from it (pointer outside
// buffer is UB).
if (!Verify(start + o, 1)) return 0;
return o;
}
uoffset_t VerifyOffset(const uint8_t *base, voffset_t start) const {
return VerifyOffset(static_cast<size_t>(base - buf_) + start);
}
// Called at the start of a table to increase counters measuring data
// structure depth and amount, and possibly bails out with false if
// limits set by the constructor have been hit. Needs to be balanced
// with EndTable().
bool VerifyComplexity() {
depth_++;
num_tables_++;
return Check(depth_ <= max_depth_ && num_tables_ <= max_tables_);
}
// Called at the end of a table to pop the depth count.
bool EndTable() {
depth_--;
return true;
}
// Returns the message size in bytes
size_t GetComputedSize() const {
// clang-format off
#ifdef FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE
uintptr_t size = upper_bound_;
// Align the size to uoffset_t
size = (size - 1 + sizeof(uoffset_t)) & ~(sizeof(uoffset_t) - 1);
return (size > size_) ? 0 : size;
#else
// Must turn on FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE for this to work.
(void)upper_bound_;
FLATBUFFERS_ASSERT(false);
return 0;
#endif
// clang-format on
}
private:
const uint8_t *buf_;
size_t size_;
uoffset_t depth_;
uoffset_t max_depth_;
uoffset_t num_tables_;
uoffset_t max_tables_;
mutable size_t upper_bound_;
bool check_alignment_;
};
// Convenient way to bundle a buffer and its length, to pass it around
// typed by its root.
// A BufferRef does not own its buffer.
struct BufferRefBase {}; // for std::is_base_of
template<typename T> struct BufferRef : BufferRefBase {
BufferRef() : buf(nullptr), len(0), must_free(false) {}
BufferRef(uint8_t *_buf, uoffset_t _len)
: buf(_buf), len(_len), must_free(false) {}
~BufferRef() {
if (must_free) free(buf);
}
const T *GetRoot() const { return flatbuffers::GetRoot<T>(buf); }
bool Verify() {
Verifier verifier(buf, len);
return verifier.VerifyBuffer<T>(nullptr);
}
uint8_t *buf;
uoffset_t len;
bool must_free;
};
// "structs" are flat structures that do not have an offset table, thus
// always have all members present and do not support forwards/backwards
// compatible extensions.
class Struct FLATBUFFERS_FINAL_CLASS {
public:
template<typename T> T GetField(uoffset_t o) const {
return ReadScalar<T>(&data_[o]);
}
template<typename T> T GetStruct(uoffset_t o) const {
return reinterpret_cast<T>(&data_[o]);
}
const uint8_t *GetAddressOf(uoffset_t o) const { return &data_[o]; }
uint8_t *GetAddressOf(uoffset_t o) { return &data_[o]; }
private:
// private constructor & copy constructor: you obtain instances of this
// class by pointing to existing data only
Struct();
Struct(const Struct &);
Struct &operator=(const Struct &);
uint8_t data_[1];
};
// "tables" use an offset table (possibly shared) that allows fields to be
// omitted and added at will, but uses an extra indirection to read.
class Table {
public:
const uint8_t *GetVTable() const {
return data_ - ReadScalar<soffset_t>(data_);
}
// This gets the field offset for any of the functions below it, or 0
// if the field was not present.
voffset_t GetOptionalFieldOffset(voffset_t field) const {
// The vtable offset is always at the start.
auto vtable = GetVTable();
// The first element is the size of the vtable (fields + type id + itself).
auto vtsize = ReadScalar<voffset_t>(vtable);
// If the field we're accessing is outside the vtable, we're reading older
// data, so it's the same as if the offset was 0 (not present).
return field < vtsize ? ReadScalar<voffset_t>(vtable + field) : 0;
}
template<typename T> T GetField(voffset_t field, T defaultval) const {
auto field_offset = GetOptionalFieldOffset(field);
return field_offset ? ReadScalar<T>(data_ + field_offset) : defaultval;
}
template<typename P> P GetPointer(voffset_t field) {
auto field_offset = GetOptionalFieldOffset(field);
auto p = data_ + field_offset;
return field_offset ? reinterpret_cast<P>(p + ReadScalar<uoffset_t>(p))
: nullptr;
}
template<typename P> P GetPointer(voffset_t field) const {
return const_cast<Table *>(this)->GetPointer<P>(field);
}
template<typename P> P GetStruct(voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
auto p = const_cast<uint8_t *>(data_ + field_offset);
return field_offset ? reinterpret_cast<P>(p) : nullptr;
}
template<typename Raw, typename Face>
flatbuffers::Optional<Face> GetOptional(voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
auto p = data_ + field_offset;
return field_offset ? Optional<Face>(static_cast<Face>(ReadScalar<Raw>(p)))
: Optional<Face>();
}
template<typename T> bool SetField(voffset_t field, T val, T def) {
auto field_offset = GetOptionalFieldOffset(field);
if (!field_offset) return IsTheSameAs(val, def);
WriteScalar(data_ + field_offset, val);
return true;
}
template<typename T> bool SetField(voffset_t field, T val) {
auto field_offset = GetOptionalFieldOffset(field);
if (!field_offset) return false;
WriteScalar(data_ + field_offset, val);
return true;
}
bool SetPointer(voffset_t field, const uint8_t *val) {
auto field_offset = GetOptionalFieldOffset(field);
if (!field_offset) return false;
WriteScalar(data_ + field_offset,
static_cast<uoffset_t>(val - (data_ + field_offset)));
return true;
}
uint8_t *GetAddressOf(voffset_t field) {
auto field_offset = GetOptionalFieldOffset(field);
return field_offset ? data_ + field_offset : nullptr;
}
const uint8_t *GetAddressOf(voffset_t field) const {
return const_cast<Table *>(this)->GetAddressOf(field);
}
bool CheckField(voffset_t field) const {
return GetOptionalFieldOffset(field) != 0;
}
// Verify the vtable of this table.
// Call this once per table, followed by VerifyField once per field.
bool VerifyTableStart(Verifier &verifier) const {
return verifier.VerifyTableStart(data_);
}
// Verify a particular field.
template<typename T>
bool VerifyField(const Verifier &verifier, voffset_t field) const {
// Calling GetOptionalFieldOffset should be safe now thanks to
// VerifyTable().
auto field_offset = GetOptionalFieldOffset(field);
// Check the actual field.
return !field_offset || verifier.Verify<T>(data_, field_offset);
}
// VerifyField for required fields.
template<typename T>
bool VerifyFieldRequired(const Verifier &verifier, voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
return verifier.Check(field_offset != 0) &&
verifier.Verify<T>(data_, field_offset);
}
// Versions for offsets.
bool VerifyOffset(const Verifier &verifier, voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
return !field_offset || verifier.VerifyOffset(data_, field_offset);
}
bool VerifyOffsetRequired(const Verifier &verifier, voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
return verifier.Check(field_offset != 0) &&
verifier.VerifyOffset(data_, field_offset);
}
private:
// private constructor & copy constructor: you obtain instances of this
// class by pointing to existing data only
Table();
Table(const Table &other);
Table &operator=(const Table &);
uint8_t data_[1];
};
// This specialization allows avoiding warnings like:
// MSVC C4800: type: forcing value to bool 'true' or 'false'.
template<>
inline flatbuffers::Optional<bool> Table::GetOptional<uint8_t, bool>(
voffset_t field) const {
auto field_offset = GetOptionalFieldOffset(field);
auto p = data_ + field_offset;
return field_offset ? Optional<bool>(ReadScalar<uint8_t>(p) != 0)
: Optional<bool>();
}
template<typename T>
void FlatBufferBuilder::Required(Offset<T> table, voffset_t field) {
auto table_ptr = reinterpret_cast<const Table *>(buf_.data_at(table.o));
bool ok = table_ptr->GetOptionalFieldOffset(field) != 0;
// If this fails, the caller will show what field needs to be set.
FLATBUFFERS_ASSERT(ok);
(void)ok;
}
/// @brief This can compute the start of a FlatBuffer from a root pointer, i.e.
/// it is the opposite transformation of GetRoot().
/// This may be useful if you want to pass on a root and have the recipient
/// delete the buffer afterwards.
inline const uint8_t *GetBufferStartFromRootPointer(const void *root) {
auto table = reinterpret_cast<const Table *>(root);
auto vtable = table->GetVTable();
// Either the vtable is before the root or after the root.
auto start = (std::min)(vtable, reinterpret_cast<const uint8_t *>(root));
// Align to at least sizeof(uoffset_t).
start = reinterpret_cast<const uint8_t *>(reinterpret_cast<uintptr_t>(start) &
~(sizeof(uoffset_t) - 1));
// Additionally, there may be a file_identifier in the buffer, and the root
// offset. The buffer may have been aligned to any size between
// sizeof(uoffset_t) and FLATBUFFERS_MAX_ALIGNMENT (see "force_align").
// Sadly, the exact alignment is only known when constructing the buffer,
// since it depends on the presence of values with said alignment properties.
// So instead, we simply look at the next uoffset_t values (root,
// file_identifier, and alignment padding) to see which points to the root.
// None of the other values can "impersonate" the root since they will either
// be 0 or four ASCII characters.
static_assert(FlatBufferBuilder::kFileIdentifierLength == sizeof(uoffset_t),
"file_identifier is assumed to be the same size as uoffset_t");
for (auto possible_roots = FLATBUFFERS_MAX_ALIGNMENT / sizeof(uoffset_t) + 1;
possible_roots; possible_roots--) {
start -= sizeof(uoffset_t);
if (ReadScalar<uoffset_t>(start) + start ==
reinterpret_cast<const uint8_t *>(root))
return start;
}
// We didn't find the root, either the "root" passed isn't really a root,
// or the buffer is corrupt.
// Assert, because calling this function with bad data may cause reads
// outside of buffer boundaries.
FLATBUFFERS_ASSERT(false);
return nullptr;
}
/// @brief This return the prefixed size of a FlatBuffer.
inline uoffset_t GetPrefixedSize(const uint8_t *buf) {
return ReadScalar<uoffset_t>(buf);
}
// Base class for native objects (FlatBuffer data de-serialized into native
// C++ data structures).
// Contains no functionality, purely documentative.
struct NativeTable {};
/// @brief Function types to be used with resolving hashes into objects and
/// back again. The resolver gets a pointer to a field inside an object API
/// object that is of the type specified in the schema using the attribute
/// `cpp_type` (it is thus important whatever you write to this address
/// matches that type). The value of this field is initially null, so you
/// may choose to implement a delayed binding lookup using this function
/// if you wish. The resolver does the opposite lookup, for when the object
/// is being serialized again.
typedef uint64_t hash_value_t;
// clang-format off
#ifdef FLATBUFFERS_CPP98_STL
typedef void (*resolver_function_t)(void **pointer_adr, hash_value_t hash);
typedef hash_value_t (*rehasher_function_t)(void *pointer);
#else
typedef std::function<void (void **pointer_adr, hash_value_t hash)>
resolver_function_t;
typedef std::function<hash_value_t (void *pointer)> rehasher_function_t;
#endif
// clang-format on
// Helper function to test if a field is present, using any of the field
// enums in the generated code.
// `table` must be a generated table type. Since this is a template parameter,
// this is not typechecked to be a subclass of Table, so beware!
// Note: this function will return false for fields equal to the default
// value, since they're not stored in the buffer (unless force_defaults was
// used).
template<typename T>
bool IsFieldPresent(const T *table, typename T::FlatBuffersVTableOffset field) {
// Cast, since Table is a private baseclass of any table types.
return reinterpret_cast<const Table *>(table)->CheckField(
static_cast<voffset_t>(field));
}
// Utility function for reverse lookups on the EnumNames*() functions
// (in the generated C++ code)
// names must be NULL terminated.
inline int LookupEnum(const char **names, const char *name) {
for (const char **p = names; *p; p++)
if (!strcmp(*p, name)) return static_cast<int>(p - names);
return -1;
}
// These macros allow us to layout a struct with a guarantee that they'll end
// up looking the same on different compilers and platforms.
// It does this by disallowing the compiler to do any padding, and then
// does padding itself by inserting extra padding fields that make every
// element aligned to its own size.
// Additionally, it manually sets the alignment of the struct as a whole,
// which is typically its largest element, or a custom size set in the schema
// by the force_align attribute.
// These are used in the generated code only.
// clang-format off
#if defined(_MSC_VER)
#define FLATBUFFERS_MANUALLY_ALIGNED_STRUCT(alignment) \
__pragma(pack(1)) \
struct __declspec(align(alignment))
#define FLATBUFFERS_STRUCT_END(name, size) \
__pragma(pack()) \
static_assert(sizeof(name) == size, "compiler breaks packing rules")
#elif defined(__GNUC__) || defined(__clang__) || defined(__ICCARM__)
#define FLATBUFFERS_MANUALLY_ALIGNED_STRUCT(alignment) \
_Pragma("pack(1)") \
struct __attribute__((aligned(alignment)))
#define FLATBUFFERS_STRUCT_END(name, size) \
_Pragma("pack()") \
static_assert(sizeof(name) == size, "compiler breaks packing rules")
#else
#error Unknown compiler, please define structure alignment macros
#endif
// clang-format on
// Minimal reflection via code generation.
// Besides full-fat reflection (see reflection.h) and parsing/printing by
// loading schemas (see idl.h), we can also have code generation for mimimal
// reflection data which allows pretty-printing and other uses without needing
// a schema or a parser.
// Generate code with --reflect-types (types only) or --reflect-names (names
// also) to enable.
// See minireflect.h for utilities using this functionality.
// These types are organized slightly differently as the ones in idl.h.
enum SequenceType { ST_TABLE, ST_STRUCT, ST_UNION, ST_ENUM };
// Scalars have the same order as in idl.h
// clang-format off
#define FLATBUFFERS_GEN_ELEMENTARY_TYPES(ET) \
ET(ET_UTYPE) \
ET(ET_BOOL) \
ET(ET_CHAR) \
ET(ET_UCHAR) \
ET(ET_SHORT) \
ET(ET_USHORT) \
ET(ET_INT) \
ET(ET_UINT) \
ET(ET_LONG) \
ET(ET_ULONG) \
ET(ET_FLOAT) \
ET(ET_DOUBLE) \
ET(ET_STRING) \
ET(ET_SEQUENCE) // See SequenceType.
enum ElementaryType {
#define FLATBUFFERS_ET(E) E,
FLATBUFFERS_GEN_ELEMENTARY_TYPES(FLATBUFFERS_ET)
#undef FLATBUFFERS_ET
};
inline const char * const *ElementaryTypeNames() {
static const char * const names[] = {
#define FLATBUFFERS_ET(E) #E,
FLATBUFFERS_GEN_ELEMENTARY_TYPES(FLATBUFFERS_ET)
#undef FLATBUFFERS_ET
};
return names;
}
// clang-format on
// Basic type info cost just 16bits per field!
// We're explicitly defining the signedness since the signedness of integer
// bitfields is otherwise implementation-defined and causes warnings on older
// GCC compilers.
struct TypeCode {
unsigned short base_type : 4; // ElementaryType
unsigned short is_repeating : 1; // Either vector (in table) or array (in struct)
signed short sequence_ref : 11; // Index into type_refs below, or -1 for none.
};
static_assert(sizeof(TypeCode) == 2, "TypeCode");
struct TypeTable;
// Signature of the static method present in each type.
typedef const TypeTable *(*TypeFunction)();
struct TypeTable {
SequenceType st;
size_t num_elems; // of type_codes, values, names (but not type_refs).
const TypeCode *type_codes; // num_elems count
const TypeFunction *type_refs; // less than num_elems entries (see TypeCode).
const int16_t *array_sizes; // less than num_elems entries (see TypeCode).
const int64_t *values; // Only set for non-consecutive enum/union or structs.
const char *const *names; // Only set if compiled with --reflect-names.
};
// String which identifies the current version of FlatBuffers.
// flatbuffer_version_string is used by Google developers to identify which
// applications uploaded to Google Play are using this library. This allows
// the development team at Google to determine the popularity of the library.
// How it works: Applications that are uploaded to the Google Play Store are
// scanned for this version string. We track which applications are using it
// to measure popularity. You are free to remove it (of course) but we would
// appreciate if you left it in.
// Weak linkage is culled by VS & doesn't work on cygwin.
// clang-format off
#if !defined(_WIN32) && !defined(__CYGWIN__)
extern volatile __attribute__((weak)) const char *flatbuffer_version_string;
volatile __attribute__((weak)) const char *flatbuffer_version_string =
"FlatBuffers "
FLATBUFFERS_STRING(FLATBUFFERS_VERSION_MAJOR) "."
FLATBUFFERS_STRING(FLATBUFFERS_VERSION_MINOR) "."
FLATBUFFERS_STRING(FLATBUFFERS_VERSION_REVISION);
#endif // !defined(_WIN32) && !defined(__CYGWIN__)
#define FLATBUFFERS_DEFINE_BITMASK_OPERATORS(E, T)\
inline E operator | (E lhs, E rhs){\
return E(T(lhs) | T(rhs));\
}\
inline E operator & (E lhs, E rhs){\
return E(T(lhs) & T(rhs));\
}\
inline E operator ^ (E lhs, E rhs){\
return E(T(lhs) ^ T(rhs));\
}\
inline E operator ~ (E lhs){\
return E(~T(lhs));\
}\
inline E operator |= (E &lhs, E rhs){\
lhs = lhs | rhs;\
return lhs;\
}\
inline E operator &= (E &lhs, E rhs){\
lhs = lhs & rhs;\
return lhs;\
}\
inline E operator ^= (E &lhs, E rhs){\
lhs = lhs ^ rhs;\
return lhs;\
}\
inline bool operator !(E rhs) \
{\
return !bool(T(rhs)); \
}
/// @endcond
} // namespace flatbuffers
// clang-format on
#endif // FLATBUFFERS_H_
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