linux-x86_64/include/flatbuffers/vector_downward.h - platform/prebuilts/android-emulator - 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_VECTOR_DOWNWARD_H_
 #define FLATBUFFERS_VECTOR_DOWNWARD_H_

 #include "flatbuffers/base.h"
 #include "flatbuffers/default_allocator.h"
 #include "flatbuffers/detached_buffer.h"

 namespace flatbuffers {

 // 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),
         size_(0),
         buf_(nullptr),
         cur_(nullptr),
         scratch_(nullptr) {}

   vector_downward(vector_downward &&other)
       // clang-format on
       : allocator_(other.allocator_),
         own_allocator_(other.own_allocator_),
         initial_size_(other.initial_size_),
         buffer_minalign_(other.buffer_minalign_),
         reserved_(other.reserved_),
         size_(other.size_),
         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;
   }

   vector_downward &operator=(vector_downward &&other) {
     // Move construct a temporary and swap idiom
     vector_downward temp(std::move(other));
     swap(temp);
     return *this;
   }

   ~vector_downward() {
     clear_buffer();
     clear_allocator();
   }

   void reset() {
     clear_buffer();
     clear();
   }

   void clear() {
     if (buf_) {
       cur_ = buf_ + reserved_;
     } else {
       reserved_ = 0;
       cur_ = nullptr;
     }
     size_ = 0;
     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) {
     if (len) {
       ensure_space(len);
       cur_ -= len;
       size_ += static_cast<uoffset_t>(len);
     }
     return cur_;
   }

   // Returns nullptr if using the DefaultAllocator.
   Allocator *get_custom_allocator() { return allocator_; }

   inline uoffset_t size() const { return size_; }

   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;
     size_ -= static_cast<uoffset_t>(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(size_, other.size_);
     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_;
   uoffset_t size_;
   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;
   }
 };

 }  // namespace flatbuffers

 #endif  // FLATBUFFERS_VECTOR_DOWNWARD_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_VECTOR_DOWNWARD_H_
	#define FLATBUFFERS_VECTOR_DOWNWARD_H_

	#include "flatbuffers/base.h"
	#include "flatbuffers/default_allocator.h"
	#include "flatbuffers/detached_buffer.h"

	namespace flatbuffers {

	// 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),
	size_(0),
	buf_(nullptr),
	cur_(nullptr),
	scratch_(nullptr) {}

	vector_downward(vector_downward &&other)
	// clang-format on
	: allocator_(other.allocator_),
	own_allocator_(other.own_allocator_),
	initial_size_(other.initial_size_),
	buffer_minalign_(other.buffer_minalign_),
	reserved_(other.reserved_),
	size_(other.size_),
	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;
	}

	vector_downward &operator=(vector_downward &&other) {
	// Move construct a temporary and swap idiom
	vector_downward temp(std::move(other));
	swap(temp);
	return *this;
	}

	~vector_downward() {
	clear_buffer();
	clear_allocator();
	}

	void reset() {
	clear_buffer();
	clear();
	}

	void clear() {
	if (buf_) {
	cur_ = buf_ + reserved_;
	} else {
	reserved_ = 0;
	cur_ = nullptr;
	}
	size_ = 0;
	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) {
	if (len) {
	ensure_space(len);
	cur_ -= len;
	size_ += static_cast<uoffset_t>(len);
	}
	return cur_;
	}

	// Returns nullptr if using the DefaultAllocator.
	Allocator *get_custom_allocator() { return allocator_; }

	inline uoffset_t size() const { return size_; }

	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;
	size_ -= static_cast<uoffset_t>(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(size_, other.size_);
	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_;
	uoffset_t size_;
	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;
	}
	};

	} // namespace flatbuffers

	#endif // FLATBUFFERS_VECTOR_DOWNWARD_H_