// automatically generated by the FlatBuffers compiler, do not modify #ifndef FLATBUFFERS_GENERATED_TEST64BIT_H_ #define FLATBUFFERS_GENERATED_TEST64BIT_H_ #include "flatbuffers/flatbuffers.h" // Ensure the included flatbuffers.h is the same version as when this file was // generated, otherwise it may not be compatible. static_assert(FLATBUFFERS_VERSION_MAJOR == 23 && FLATBUFFERS_VERSION_MINOR == 5 && FLATBUFFERS_VERSION_REVISION == 26, "Non-compatible flatbuffers version included"); // For access to the binary schema that produced this file. #include "test_64bit_bfbs_generated.h" struct LeafStruct; struct WrapperTable; struct WrapperTableBuilder; struct WrapperTableT; struct RootTable; struct RootTableBuilder; struct RootTableT; bool operator==(const LeafStruct &lhs, const LeafStruct &rhs); bool operator!=(const LeafStruct &lhs, const LeafStruct &rhs); bool operator==(const WrapperTableT &lhs, const WrapperTableT &rhs); bool operator!=(const WrapperTableT &lhs, const WrapperTableT &rhs); bool operator==(const RootTableT &lhs, const RootTableT &rhs); bool operator!=(const RootTableT &lhs, const RootTableT &rhs); inline const ::flatbuffers::TypeTable *LeafStructTypeTable(); inline const ::flatbuffers::TypeTable *WrapperTableTypeTable(); inline const ::flatbuffers::TypeTable *RootTableTypeTable(); FLATBUFFERS_MANUALLY_ALIGNED_STRUCT(8) LeafStruct FLATBUFFERS_FINAL_CLASS { private: int32_t a_; int32_t padding0__; double b_; public: static const ::flatbuffers::TypeTable *MiniReflectTypeTable() { return LeafStructTypeTable(); } LeafStruct() : a_(0), padding0__(0), b_(0) { (void)padding0__; } LeafStruct(int32_t _a, double _b) : a_(::flatbuffers::EndianScalar(_a)), padding0__(0), b_(::flatbuffers::EndianScalar(_b)) { (void)padding0__; } int32_t a() const { return ::flatbuffers::EndianScalar(a_); } void mutate_a(int32_t _a) { ::flatbuffers::WriteScalar(&a_, _a); } double b() const { return ::flatbuffers::EndianScalar(b_); } void mutate_b(double _b) { ::flatbuffers::WriteScalar(&b_, _b); } }; FLATBUFFERS_STRUCT_END(LeafStruct, 16); inline bool operator==(const LeafStruct &lhs, const LeafStruct &rhs) { return (lhs.a() == rhs.a()) && (lhs.b() == rhs.b()); } inline bool operator!=(const LeafStruct &lhs, const LeafStruct &rhs) { return !(lhs == rhs); } struct WrapperTableT : public ::flatbuffers::NativeTable { typedef WrapperTable TableType; std::vector vector{}; }; struct WrapperTable FLATBUFFERS_FINAL_CLASS : private ::flatbuffers::Table { typedef WrapperTableT NativeTableType; typedef WrapperTableBuilder Builder; typedef RootTableBinarySchema BinarySchema; static const ::flatbuffers::TypeTable *MiniReflectTypeTable() { return WrapperTableTypeTable(); } enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE { VT_VECTOR = 4 }; const ::flatbuffers::Vector *vector() const { return GetPointer64 *>(VT_VECTOR); } ::flatbuffers::Vector *mutable_vector() { return GetPointer64<::flatbuffers::Vector *>(VT_VECTOR); } bool Verify(::flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset64(verifier, VT_VECTOR) && verifier.VerifyVector(vector()) && verifier.EndTable(); } WrapperTableT *UnPack(const ::flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(WrapperTableT *_o, const ::flatbuffers::resolver_function_t *_resolver = nullptr) const; static ::flatbuffers::Offset Pack(::flatbuffers::FlatBufferBuilder64 &_fbb, const WrapperTableT* _o, const ::flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct WrapperTableBuilder { typedef WrapperTable Table; ::flatbuffers::FlatBufferBuilder64 &fbb_; ::flatbuffers::uoffset_t start_; void add_vector(::flatbuffers::Offset64<::flatbuffers::Vector> vector) { fbb_.AddOffset(WrapperTable::VT_VECTOR, vector); } explicit WrapperTableBuilder(::flatbuffers::FlatBufferBuilder64 &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ::flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = ::flatbuffers::Offset(end); return o; } }; inline ::flatbuffers::Offset CreateWrapperTable( ::flatbuffers::FlatBufferBuilder64 &_fbb, ::flatbuffers::Offset64<::flatbuffers::Vector> vector = 0) { WrapperTableBuilder builder_(_fbb); builder_.add_vector(vector); return builder_.Finish(); } inline ::flatbuffers::Offset CreateWrapperTableDirect( ::flatbuffers::FlatBufferBuilder64 &_fbb, const std::vector *vector = nullptr) { auto vector__ = vector ? _fbb.CreateVector64<::flatbuffers::Vector>(*vector) : 0; return CreateWrapperTable( _fbb, vector__); } ::flatbuffers::Offset CreateWrapperTable(::flatbuffers::FlatBufferBuilder64 &_fbb, const WrapperTableT *_o, const ::flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RootTableT : public ::flatbuffers::NativeTable { typedef RootTable TableType; std::vector far_vector{}; int32_t a = 0; std::string far_string{}; std::vector big_vector{}; std::string near_string{}; std::vector nested_root{}; std::vector far_struct_vector{}; std::vector big_struct_vector{}; std::vector> many_vectors{}; RootTableT() = default; RootTableT(const RootTableT &o); RootTableT(RootTableT&&) FLATBUFFERS_NOEXCEPT = default; RootTableT &operator=(RootTableT o) FLATBUFFERS_NOEXCEPT; }; struct RootTable FLATBUFFERS_FINAL_CLASS : private ::flatbuffers::Table { typedef RootTableT NativeTableType; typedef RootTableBuilder Builder; typedef RootTableBinarySchema BinarySchema; static const ::flatbuffers::TypeTable *MiniReflectTypeTable() { return RootTableTypeTable(); } enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE { VT_FAR_VECTOR = 4, VT_A = 6, VT_FAR_STRING = 8, VT_BIG_VECTOR = 10, VT_NEAR_STRING = 12, VT_NESTED_ROOT = 14, VT_FAR_STRUCT_VECTOR = 16, VT_BIG_STRUCT_VECTOR = 18, VT_MANY_VECTORS = 20 }; const ::flatbuffers::Vector *far_vector() const { return GetPointer64 *>(VT_FAR_VECTOR); } ::flatbuffers::Vector *mutable_far_vector() { return GetPointer64<::flatbuffers::Vector *>(VT_FAR_VECTOR); } int32_t a() const { return GetField(VT_A, 0); } bool mutate_a(int32_t _a = 0) { return SetField(VT_A, _a, 0); } const ::flatbuffers::String *far_string() const { return GetPointer64(VT_FAR_STRING); } ::flatbuffers::String *mutable_far_string() { return GetPointer64<::flatbuffers::String *>(VT_FAR_STRING); } const ::flatbuffers::Vector64 *big_vector() const { return GetPointer64 *>(VT_BIG_VECTOR); } ::flatbuffers::Vector64 *mutable_big_vector() { return GetPointer64<::flatbuffers::Vector64 *>(VT_BIG_VECTOR); } const ::flatbuffers::String *near_string() const { return GetPointer(VT_NEAR_STRING); } ::flatbuffers::String *mutable_near_string() { return GetPointer<::flatbuffers::String *>(VT_NEAR_STRING); } const ::flatbuffers::Vector64 *nested_root() const { return GetPointer64 *>(VT_NESTED_ROOT); } ::flatbuffers::Vector64 *mutable_nested_root() { return GetPointer64<::flatbuffers::Vector64 *>(VT_NESTED_ROOT); } const RootTable *nested_root_nested_root() const { const auto _f = nested_root(); return _f ? ::flatbuffers::GetRoot(_f->Data()) : nullptr; } const ::flatbuffers::Vector *far_struct_vector() const { return GetPointer64 *>(VT_FAR_STRUCT_VECTOR); } ::flatbuffers::Vector *mutable_far_struct_vector() { return GetPointer64<::flatbuffers::Vector *>(VT_FAR_STRUCT_VECTOR); } const ::flatbuffers::Vector64 *big_struct_vector() const { return GetPointer64 *>(VT_BIG_STRUCT_VECTOR); } ::flatbuffers::Vector64 *mutable_big_struct_vector() { return GetPointer64<::flatbuffers::Vector64 *>(VT_BIG_STRUCT_VECTOR); } const ::flatbuffers::Vector<::flatbuffers::Offset> *many_vectors() const { return GetPointer> *>(VT_MANY_VECTORS); } ::flatbuffers::Vector<::flatbuffers::Offset> *mutable_many_vectors() { return GetPointer<::flatbuffers::Vector<::flatbuffers::Offset> *>(VT_MANY_VECTORS); } bool Verify(::flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset64(verifier, VT_FAR_VECTOR) && verifier.VerifyVector(far_vector()) && VerifyField(verifier, VT_A, 4) && VerifyOffset64(verifier, VT_FAR_STRING) && verifier.VerifyString(far_string()) && VerifyOffset64(verifier, VT_BIG_VECTOR) && verifier.VerifyVector(big_vector()) && VerifyOffset(verifier, VT_NEAR_STRING) && verifier.VerifyString(near_string()) && VerifyOffset64(verifier, VT_NESTED_ROOT) && verifier.VerifyVector(nested_root()) && verifier.VerifyNestedFlatBuffer(nested_root(), nullptr) && VerifyOffset64(verifier, VT_FAR_STRUCT_VECTOR) && verifier.VerifyVector(far_struct_vector()) && VerifyOffset64(verifier, VT_BIG_STRUCT_VECTOR) && verifier.VerifyVector(big_struct_vector()) && VerifyOffset(verifier, VT_MANY_VECTORS) && verifier.VerifyVector(many_vectors()) && verifier.VerifyVectorOfTables(many_vectors()) && verifier.EndTable(); } RootTableT *UnPack(const ::flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RootTableT *_o, const ::flatbuffers::resolver_function_t *_resolver = nullptr) const; static ::flatbuffers::Offset Pack(::flatbuffers::FlatBufferBuilder64 &_fbb, const RootTableT* _o, const ::flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RootTableBuilder { typedef RootTable Table; ::flatbuffers::FlatBufferBuilder64 &fbb_; ::flatbuffers::uoffset_t start_; void add_far_vector(::flatbuffers::Offset64<::flatbuffers::Vector> far_vector) { fbb_.AddOffset(RootTable::VT_FAR_VECTOR, far_vector); } void add_a(int32_t a) { fbb_.AddElement(RootTable::VT_A, a, 0); } void add_far_string(::flatbuffers::Offset64<::flatbuffers::String> far_string) { fbb_.AddOffset(RootTable::VT_FAR_STRING, far_string); } void add_big_vector(::flatbuffers::Offset64<::flatbuffers::Vector64> big_vector) { fbb_.AddOffset(RootTable::VT_BIG_VECTOR, big_vector); } void add_near_string(::flatbuffers::Offset<::flatbuffers::String> near_string) { fbb_.AddOffset(RootTable::VT_NEAR_STRING, near_string); } void add_nested_root(::flatbuffers::Offset64<::flatbuffers::Vector64> nested_root) { fbb_.AddOffset(RootTable::VT_NESTED_ROOT, nested_root); } void add_far_struct_vector(::flatbuffers::Offset64<::flatbuffers::Vector> far_struct_vector) { fbb_.AddOffset(RootTable::VT_FAR_STRUCT_VECTOR, far_struct_vector); } void add_big_struct_vector(::flatbuffers::Offset64<::flatbuffers::Vector64> big_struct_vector) { fbb_.AddOffset(RootTable::VT_BIG_STRUCT_VECTOR, big_struct_vector); } void add_many_vectors(::flatbuffers::Offset<::flatbuffers::Vector<::flatbuffers::Offset>> many_vectors) { fbb_.AddOffset(RootTable::VT_MANY_VECTORS, many_vectors); } explicit RootTableBuilder(::flatbuffers::FlatBufferBuilder64 &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ::flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = ::flatbuffers::Offset(end); return o; } }; inline ::flatbuffers::Offset CreateRootTable( ::flatbuffers::FlatBufferBuilder64 &_fbb, ::flatbuffers::Offset64<::flatbuffers::Vector> far_vector = 0, int32_t a = 0, ::flatbuffers::Offset64<::flatbuffers::String> far_string = 0, ::flatbuffers::Offset64<::flatbuffers::Vector64> big_vector = 0, ::flatbuffers::Offset<::flatbuffers::String> near_string = 0, ::flatbuffers::Offset64<::flatbuffers::Vector64> nested_root = 0, ::flatbuffers::Offset64<::flatbuffers::Vector> far_struct_vector = 0, ::flatbuffers::Offset64<::flatbuffers::Vector64> big_struct_vector = 0, ::flatbuffers::Offset<::flatbuffers::Vector<::flatbuffers::Offset>> many_vectors = 0) { RootTableBuilder builder_(_fbb); builder_.add_big_struct_vector(big_struct_vector); builder_.add_nested_root(nested_root); builder_.add_big_vector(big_vector); builder_.add_many_vectors(many_vectors); builder_.add_far_struct_vector(far_struct_vector); builder_.add_near_string(near_string); builder_.add_far_string(far_string); builder_.add_a(a); builder_.add_far_vector(far_vector); return builder_.Finish(); } inline ::flatbuffers::Offset CreateRootTableDirect( ::flatbuffers::FlatBufferBuilder64 &_fbb, const std::vector *far_vector = nullptr, int32_t a = 0, const char *far_string = nullptr, const std::vector *big_vector = nullptr, const char *near_string = nullptr, const std::vector *nested_root = nullptr, const std::vector *far_struct_vector = nullptr, const std::vector *big_struct_vector = nullptr, const std::vector<::flatbuffers::Offset> *many_vectors = nullptr) { auto far_vector__ = far_vector ? _fbb.CreateVector64<::flatbuffers::Vector>(*far_vector) : 0; auto far_string__ = far_string ? _fbb.CreateString<::flatbuffers::Offset64>(far_string) : 0; auto big_vector__ = big_vector ? _fbb.CreateVector64(*big_vector) : 0; auto nested_root__ = nested_root ? _fbb.CreateVector64(*nested_root) : 0; auto far_struct_vector__ = far_struct_vector ? _fbb.CreateVectorOfStructs64<::flatbuffers::Vector>(*far_struct_vector) : 0; auto big_struct_vector__ = big_struct_vector ? _fbb.CreateVectorOfStructs64(*big_struct_vector) : 0; auto near_string__ = near_string ? _fbb.CreateString(near_string) : 0; auto many_vectors__ = many_vectors ? _fbb.CreateVector<::flatbuffers::Offset>(*many_vectors) : 0; return CreateRootTable( _fbb, far_vector__, a, far_string__, big_vector__, near_string__, nested_root__, far_struct_vector__, big_struct_vector__, many_vectors__); } ::flatbuffers::Offset CreateRootTable(::flatbuffers::FlatBufferBuilder64 &_fbb, const RootTableT *_o, const ::flatbuffers::rehasher_function_t *_rehasher = nullptr); inline bool operator==(const WrapperTableT &lhs, const WrapperTableT &rhs) { return (lhs.vector == rhs.vector); } inline bool operator!=(const WrapperTableT &lhs, const WrapperTableT &rhs) { return !(lhs == rhs); } inline WrapperTableT *WrapperTable::UnPack(const ::flatbuffers::resolver_function_t *_resolver) const { auto _o = std::unique_ptr(new WrapperTableT()); UnPackTo(_o.get(), _resolver); return _o.release(); } inline void WrapperTable::UnPackTo(WrapperTableT *_o, const ::flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = vector(); if (_e) { _o->vector.resize(_e->size()); std::copy(_e->begin(), _e->end(), _o->vector.begin()); } } } inline ::flatbuffers::Offset WrapperTable::Pack(::flatbuffers::FlatBufferBuilder64 &_fbb, const WrapperTableT* _o, const ::flatbuffers::rehasher_function_t *_rehasher) { return CreateWrapperTable(_fbb, _o, _rehasher); } inline ::flatbuffers::Offset CreateWrapperTable(::flatbuffers::FlatBufferBuilder64 &_fbb, const WrapperTableT *_o, const ::flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { ::flatbuffers::FlatBufferBuilder64 *__fbb; const WrapperTableT* __o; const ::flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _vector = _o->vector.size() ? _fbb.CreateVector64<::flatbuffers::Vector>(_o->vector) : 0; return CreateWrapperTable( _fbb, _vector); } inline bool operator==(const RootTableT &lhs, const RootTableT &rhs) { return (lhs.far_vector == rhs.far_vector) && (lhs.a == rhs.a) && (lhs.far_string == rhs.far_string) && (lhs.big_vector == rhs.big_vector) && (lhs.near_string == rhs.near_string) && (lhs.nested_root == rhs.nested_root) && (lhs.far_struct_vector == rhs.far_struct_vector) && (lhs.big_struct_vector == rhs.big_struct_vector) && (lhs.many_vectors.size() == rhs.many_vectors.size() && std::equal(lhs.many_vectors.cbegin(), lhs.many_vectors.cend(), rhs.many_vectors.cbegin(), [](std::unique_ptr const &a, std::unique_ptr const &b) { return (a == b) || (a && b && *a == *b); })); } inline bool operator!=(const RootTableT &lhs, const RootTableT &rhs) { return !(lhs == rhs); } inline RootTableT::RootTableT(const RootTableT &o) : far_vector(o.far_vector), a(o.a), far_string(o.far_string), big_vector(o.big_vector), near_string(o.near_string), nested_root(o.nested_root), far_struct_vector(o.far_struct_vector), big_struct_vector(o.big_struct_vector) { many_vectors.reserve(o.many_vectors.size()); for (const auto &many_vectors_ : o.many_vectors) { many_vectors.emplace_back((many_vectors_) ? new WrapperTableT(*many_vectors_) : nullptr); } } inline RootTableT &RootTableT::operator=(RootTableT o) FLATBUFFERS_NOEXCEPT { std::swap(far_vector, o.far_vector); std::swap(a, o.a); std::swap(far_string, o.far_string); std::swap(big_vector, o.big_vector); std::swap(near_string, o.near_string); std::swap(nested_root, o.nested_root); std::swap(far_struct_vector, o.far_struct_vector); std::swap(big_struct_vector, o.big_struct_vector); std::swap(many_vectors, o.many_vectors); return *this; } inline RootTableT *RootTable::UnPack(const ::flatbuffers::resolver_function_t *_resolver) const { auto _o = std::unique_ptr(new RootTableT()); UnPackTo(_o.get(), _resolver); return _o.release(); } inline void RootTable::UnPackTo(RootTableT *_o, const ::flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = far_vector(); if (_e) { _o->far_vector.resize(_e->size()); std::copy(_e->begin(), _e->end(), _o->far_vector.begin()); } } { auto _e = a(); _o->a = _e; } { auto _e = far_string(); if (_e) _o->far_string = _e->str(); } { auto _e = big_vector(); if (_e) { _o->big_vector.resize(_e->size()); std::copy(_e->begin(), _e->end(), _o->big_vector.begin()); } } { auto _e = near_string(); if (_e) _o->near_string = _e->str(); } { auto _e = nested_root(); if (_e) { _o->nested_root.resize(_e->size()); std::copy(_e->begin(), _e->end(), _o->nested_root.begin()); } } { auto _e = far_struct_vector(); if (_e) { _o->far_struct_vector.resize(_e->size()); for (::flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->far_struct_vector[_i] = *_e->Get(_i); } } else { _o->far_struct_vector.resize(0); } } { auto _e = big_struct_vector(); if (_e) { _o->big_struct_vector.resize(_e->size()); for (::flatbuffers::uoffset64_t _i = 0; _i < _e->size(); _i++) { _o->big_struct_vector[_i] = *_e->Get(_i); } } else { _o->big_struct_vector.resize(0); } } { auto _e = many_vectors(); if (_e) { _o->many_vectors.resize(_e->size()); for (::flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { if(_o->many_vectors[_i]) { _e->Get(_i)->UnPackTo(_o->many_vectors[_i].get(), _resolver); } else { _o->many_vectors[_i] = std::unique_ptr(_e->Get(_i)->UnPack(_resolver)); }; } } else { _o->many_vectors.resize(0); } } } inline ::flatbuffers::Offset RootTable::Pack(::flatbuffers::FlatBufferBuilder64 &_fbb, const RootTableT* _o, const ::flatbuffers::rehasher_function_t *_rehasher) { return CreateRootTable(_fbb, _o, _rehasher); } inline ::flatbuffers::Offset CreateRootTable(::flatbuffers::FlatBufferBuilder64 &_fbb, const RootTableT *_o, const ::flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { ::flatbuffers::FlatBufferBuilder64 *__fbb; const RootTableT* __o; const ::flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _far_vector = _o->far_vector.size() ? _fbb.CreateVector64<::flatbuffers::Vector>(_o->far_vector) : 0; auto _a = _o->a; auto _far_string = _o->far_string.empty() ? 0 : _fbb.CreateString<::flatbuffers::Offset64>(_o->far_string); auto _big_vector = _o->big_vector.size() ? _fbb.CreateVector64(_o->big_vector) : 0; auto _near_string = _o->near_string.empty() ? 0 : _fbb.CreateString(_o->near_string); auto _nested_root = _o->nested_root.size() ? _fbb.CreateVector64(_o->nested_root) : 0; auto _far_struct_vector = _o->far_struct_vector.size() ? _fbb.CreateVectorOfStructs64<::flatbuffers::Vector>(_o->far_struct_vector) : 0; auto _big_struct_vector = _o->big_struct_vector.size() ? _fbb.CreateVectorOfStructs64(_o->big_struct_vector) : 0; auto _many_vectors = _o->many_vectors.size() ? _fbb.CreateVector<::flatbuffers::Offset> (_o->many_vectors.size(), [](size_t i, _VectorArgs *__va) { return CreateWrapperTable(*__va->__fbb, __va->__o->many_vectors[i].get(), __va->__rehasher); }, &_va ) : 0; return CreateRootTable( _fbb, _far_vector, _a, _far_string, _big_vector, _near_string, _nested_root, _far_struct_vector, _big_struct_vector, _many_vectors); } inline const ::flatbuffers::TypeTable *LeafStructTypeTable() { static const ::flatbuffers::TypeCode type_codes[] = { { ::flatbuffers::ET_INT, 0, -1 }, { ::flatbuffers::ET_DOUBLE, 0, -1 } }; static const int64_t values[] = { 0, 8, 16 }; static const char * const names[] = { "a", "b" }; static const ::flatbuffers::TypeTable tt = { ::flatbuffers::ST_STRUCT, 2, type_codes, nullptr, nullptr, values, names }; return &tt; } inline const ::flatbuffers::TypeTable *WrapperTableTypeTable() { static const ::flatbuffers::TypeCode type_codes[] = { { ::flatbuffers::ET_CHAR, 1, -1 } }; static const char * const names[] = { "vector" }; static const ::flatbuffers::TypeTable tt = { ::flatbuffers::ST_TABLE, 1, type_codes, nullptr, nullptr, nullptr, names }; return &tt; } inline const ::flatbuffers::TypeTable *RootTableTypeTable() { static const ::flatbuffers::TypeCode type_codes[] = { { ::flatbuffers::ET_UCHAR, 1, -1 }, { ::flatbuffers::ET_INT, 0, -1 }, { ::flatbuffers::ET_STRING, 0, -1 }, { ::flatbuffers::ET_UCHAR, 1, -1 }, { ::flatbuffers::ET_STRING, 0, -1 }, { ::flatbuffers::ET_UCHAR, 1, -1 }, { ::flatbuffers::ET_SEQUENCE, 1, 0 }, { ::flatbuffers::ET_SEQUENCE, 1, 0 }, { ::flatbuffers::ET_SEQUENCE, 1, 1 } }; static const ::flatbuffers::TypeFunction type_refs[] = { LeafStructTypeTable, WrapperTableTypeTable }; static const char * const names[] = { "far_vector", "a", "far_string", "big_vector", "near_string", "nested_root", "far_struct_vector", "big_struct_vector", "many_vectors" }; static const ::flatbuffers::TypeTable tt = { ::flatbuffers::ST_TABLE, 9, type_codes, type_refs, nullptr, nullptr, names }; return &tt; } inline const RootTable *GetRootTable(const void *buf) { return ::flatbuffers::GetRoot(buf); } inline const RootTable *GetSizePrefixedRootTable(const void *buf) { return ::flatbuffers::GetSizePrefixedRoot(buf); } inline RootTable *GetMutableRootTable(void *buf) { return ::flatbuffers::GetMutableRoot(buf); } inline RootTable *GetMutableSizePrefixedRootTable(void *buf) { return ::flatbuffers::GetMutableSizePrefixedRoot(buf); } inline bool VerifyRootTableBuffer( ::flatbuffers::Verifier &verifier) { return verifier.VerifyBuffer(nullptr); } inline bool VerifySizePrefixedRootTableBuffer( ::flatbuffers::Verifier &verifier) { return verifier.VerifySizePrefixedBuffer(nullptr); } inline void FinishRootTableBuffer( ::flatbuffers::FlatBufferBuilder64 &fbb, ::flatbuffers::Offset root) { fbb.Finish(root); } inline void FinishSizePrefixedRootTableBuffer( ::flatbuffers::FlatBufferBuilder64 &fbb, ::flatbuffers::Offset root) { fbb.FinishSizePrefixed(root); } inline std::unique_ptr UnPackRootTable( const void *buf, const ::flatbuffers::resolver_function_t *res = nullptr) { return std::unique_ptr(GetRootTable(buf)->UnPack(res)); } inline std::unique_ptr UnPackSizePrefixedRootTable( const void *buf, const ::flatbuffers::resolver_function_t *res = nullptr) { return std::unique_ptr(GetSizePrefixedRootTable(buf)->UnPack(res)); } #endif // FLATBUFFERS_GENERATED_TEST64BIT_H_