include/flatbuffers/array.h - third_party/flatbuffers - Git at Google

 /*
  * Copyright 2021 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_ARRAY_H_
 #define FLATBUFFERS_ARRAY_H_

 #include "flatbuffers/base.h"
 #include "flatbuffers/stl_emulation.h"
 #include "flatbuffers/vector.h"

 namespace flatbuffers {

 // This is used as a helper type for accessing arrays.
 template<typename T, uint16_t length> class Array {
   // Array<T> can carry only POD data types (scalars or structs).
   typedef typename flatbuffers::bool_constant<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 VectorConstIterator<T, return_type> const_iterator;
   typedef VectorReverseIterator<const_iterator> const_reverse_iterator;

   // If T is a LE-scalar or a struct (!scalar_tag::value).
   static FLATBUFFERS_CONSTEXPR bool is_span_observable =
       (scalar_tag::value && (FLATBUFFERS_LITTLEENDIAN || sizeof(T) == 1)) ||
       !scalar_tag::value;

   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(begin());
   }

   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::bool_constant<is_span_observable>(), src);
   }

  protected:
   void MutateImpl(flatbuffers::true_type, uoffset_t i, const T &val) {
     FLATBUFFERS_ASSERT(i < size());
     WriteScalar(data() + i, val);
   }

   void MutateImpl(flatbuffers::false_type, uoffset_t i, const T &val) {
     *(GetMutablePointer(i)) = val;
   }

   void CopyFromSpanImpl(flatbuffers::true_type,
                         flatbuffers::span<const T, length> src) {
     // Use std::memcpy() instead of std::copy() to avoid performance 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::false_type,
                         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];
 };

 template<class U, uint16_t N>
 FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<U, N> make_span(Array<U, N> &arr)
     FLATBUFFERS_NOEXCEPT {
   static_assert(
       Array<U, N>::is_span_observable,
       "wrong type U, only plain struct, LE-scalar, or byte types are allowed");
   return span<U, N>(arr.data(), N);
 }

 template<class U, uint16_t N>
 FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<const U, N> make_span(
     const Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
   static_assert(
       Array<U, N>::is_span_observable,
       "wrong type U, only plain struct, LE-scalar, or byte types are allowed");
   return span<const U, N>(arr.data(), N);
 }

 template<class U, uint16_t N>
 FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<uint8_t, sizeof(U) * N>
 make_bytes_span(Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
   static_assert(Array<U, N>::is_span_observable,
                 "internal error, Array<T> might hold only scalars or structs");
   return span<uint8_t, sizeof(U) * N>(arr.Data(), sizeof(U) * N);
 }

 template<class U, uint16_t N>
 FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<const uint8_t, sizeof(U) * N>
 make_bytes_span(const Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
   static_assert(Array<U, N>::is_span_observable,
                 "internal error, Array<T> might hold only scalars or structs");
   return span<const uint8_t, sizeof(U) * N>(arr.Data(), sizeof(U) * N);
 }

 // Cast a raw T[length] to a raw flatbuffers::Array<T, length>
 // without endian conversion. Use with care.
 // TODO: move these Cast-methods to `internal` namespace.
 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);
 }

 }  // namespace flatbuffers

 #endif  // FLATBUFFERS_ARRAY_H_
	/*
	* Copyright 2021 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_ARRAY_H_
	#define FLATBUFFERS_ARRAY_H_

	#include "flatbuffers/base.h"
	#include "flatbuffers/stl_emulation.h"
	#include "flatbuffers/vector.h"

	namespace flatbuffers {

	// This is used as a helper type for accessing arrays.
	template<typename T, uint16_t length> class Array {
	// Array<T> can carry only POD data types (scalars or structs).
	typedef typename flatbuffers::bool_constant<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 VectorConstIterator<T, return_type> const_iterator;
	typedef VectorReverseIterator<const_iterator> const_reverse_iterator;

	// If T is a LE-scalar or a struct (!scalar_tag::value).
	static FLATBUFFERS_CONSTEXPR bool is_span_observable =
	(scalar_tag::value && (FLATBUFFERS_LITTLEENDIAN \|\| sizeof(T) == 1)) \|\|
	!scalar_tag::value;

	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(begin());
	}

	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::bool_constant<is_span_observable>(), src);
	}

	protected:
	void MutateImpl(flatbuffers::true_type, uoffset_t i, const T &val) {
	FLATBUFFERS_ASSERT(i < size());
	WriteScalar(data() + i, val);
	}

	void MutateImpl(flatbuffers::false_type, uoffset_t i, const T &val) {
	*(GetMutablePointer(i)) = val;
	}

	void CopyFromSpanImpl(flatbuffers::true_type,
	flatbuffers::span<const T, length> src) {
	// Use std::memcpy() instead of std::copy() to avoid performance 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::false_type,
	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];
	};

	template<class U, uint16_t N>
	FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<U, N> make_span(Array<U, N> &arr)
	FLATBUFFERS_NOEXCEPT {
	static_assert(
	Array<U, N>::is_span_observable,
	"wrong type U, only plain struct, LE-scalar, or byte types are allowed");
	return span<U, N>(arr.data(), N);
	}

	template<class U, uint16_t N>
	FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<const U, N> make_span(
	const Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
	static_assert(
	Array<U, N>::is_span_observable,
	"wrong type U, only plain struct, LE-scalar, or byte types are allowed");
	return span<const U, N>(arr.data(), N);
	}

	template<class U, uint16_t N>
	FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<uint8_t, sizeof(U) * N>
	make_bytes_span(Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
	static_assert(Array<U, N>::is_span_observable,
	"internal error, Array<T> might hold only scalars or structs");
	return span<uint8_t, sizeof(U) * N>(arr.Data(), sizeof(U) * N);
	}

	template<class U, uint16_t N>
	FLATBUFFERS_CONSTEXPR_CPP11 flatbuffers::span<const uint8_t, sizeof(U) * N>
	make_bytes_span(const Array<U, N> &arr) FLATBUFFERS_NOEXCEPT {
	static_assert(Array<U, N>::is_span_observable,
	"internal error, Array<T> might hold only scalars or structs");
	return span<const uint8_t, sizeof(U) * N>(arr.Data(), sizeof(U) * N);
	}

	// Cast a raw T[length] to a raw flatbuffers::Array<T, length>
	// without endian conversion. Use with care.
	// TODO: move these Cast-methods to `internal` namespace.
	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);
	}

	} // namespace flatbuffers

	#endif // FLATBUFFERS_ARRAY_H_