src/connectivity/bluetooth/core/bt-host/common/byte_buffer.cc - fuchsia - Git at Google

 // Copyright 2017 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "byte_buffer.h"

 namespace bt {

 void ByteBuffer::Copy(MutableByteBuffer* out_buffer) const {
   ZX_ASSERT(out_buffer);
   CopyRaw(out_buffer->mutable_data(), out_buffer->size(), 0, size());
 }

 void ByteBuffer::Copy(MutableByteBuffer* out_buffer, size_t pos, size_t size) const {
   ZX_ASSERT(out_buffer);
   CopyRaw(out_buffer->mutable_data(), out_buffer->size(), pos, size);
 }

 BufferView ByteBuffer::view(size_t pos, size_t size) const {
   ZX_ASSERT_MSG(pos <= this->size(), "offset past buffer (pos: %zu, size: %zu)", pos, this->size());
   return BufferView(data() + pos, std::min(size, this->size() - pos));
 }

 std::string_view ByteBuffer::AsString() const {
   return std::string_view(reinterpret_cast<const char*>(data()), size());
 }

 std::string ByteBuffer::ToString() const { return std::string(AsString()); }

 std::vector<uint8_t> ByteBuffer::ToVector() const {
   std::vector<uint8_t> vec(size());
   MutableBufferView vec_view(vec.data(), vec.size());
   vec_view.Write(*this);
   return vec;
 }

 void ByteBuffer::CopyRaw(void* dst_data, size_t dst_capacity, size_t src_offset,
                          size_t copy_size) const {
   ZX_ASSERT_MSG(copy_size == 0 || dst_data != nullptr, "%zu byte write to pointer %p", copy_size,
                 dst_data);
   ZX_ASSERT_MSG(copy_size <= dst_capacity,
                 "destination not large enough (required: %zu, available: %zu)", copy_size,
                 dst_capacity);
   ZX_ASSERT_MSG(src_offset <= this->size(),
                 "offset exceeds source range (begin: %zu, copy_size: %zu)", src_offset,
                 this->size());
   ZX_ASSERT_MSG(std::numeric_limits<size_t>::max() - copy_size >= src_offset,
                 "end of source range overflows size_t (src_offset: %zu, copy_size: %zu)",
                 src_offset, copy_size);
   ZX_ASSERT_MSG(src_offset + copy_size <= this->size(),
                 "end exceeds source range (end: %zu, copy_size: %zu)", src_offset + copy_size,
                 this->size());

   // Data pointers for zero-length buffers are nullptr, over which memcpy has undefined behavior,
   // even for count = 0. Skip the memcpy invocation in that case.
   if (copy_size == 0) {
     return;
   }
   std::memcpy(dst_data, data() + src_offset, copy_size);
 }

 void MutableByteBuffer::Write(const uint8_t* data, size_t size, size_t pos) {
   BufferView from(data, size);
   MutableBufferView to = mutable_view(pos);
   from.Copy(&to);
 }

 void MutableByteBuffer::FillWithRandomBytes() {
   if (size()) {
     zx_cprng_draw(mutable_data(), size());
   }
 }

 MutableBufferView MutableByteBuffer::mutable_view(size_t pos, size_t size) {
   ZX_ASSERT_MSG(pos <= this->size(), "offset past buffer (pos: %zu, size: %zu)", pos, this->size());
   return MutableBufferView(mutable_data() + pos, std::min(size, this->size() - pos));
 }

 DynamicByteBuffer::DynamicByteBuffer() = default;

 DynamicByteBuffer::DynamicByteBuffer(size_t buffer_size) : buffer_size_(buffer_size) {
   if (buffer_size == 0)
     return;
   buffer_ = std::make_unique<uint8_t[]>(buffer_size);

   // TODO(armansito): For now this is dumb but we should properly handle the
   // case when we're out of memory.
   ZX_ASSERT_MSG(buffer_.get(), "failed to allocate buffer");
 }

 DynamicByteBuffer::DynamicByteBuffer(const ByteBuffer& buffer)
     : buffer_size_(buffer.size()),
       buffer_(buffer.size() ? std::make_unique<uint8_t[]>(buffer.size()) : nullptr) {
   ZX_ASSERT_MSG(!buffer_size_ || buffer_.get(),
                 "|buffer| cannot be nullptr when |buffer_size| is non-zero");
   buffer.Copy(this);
 }

 DynamicByteBuffer::DynamicByteBuffer(const DynamicByteBuffer& buffer)
     : DynamicByteBuffer(static_cast<const ByteBuffer&>(buffer)) {}

 DynamicByteBuffer::DynamicByteBuffer(size_t buffer_size, std::unique_ptr<uint8_t[]> buffer)
     : buffer_size_(buffer_size), buffer_(std::move(buffer)) {
   ZX_ASSERT_MSG(!buffer_size_ || buffer_.get(),
                 "|buffer| cannot be nullptr when |buffer_size| is non-zero");
 }

 DynamicByteBuffer::DynamicByteBuffer(DynamicByteBuffer&& other) {
   buffer_size_ = other.buffer_size_;
   other.buffer_size_ = 0u;
   buffer_ = std::move(other.buffer_);
 }

 DynamicByteBuffer& DynamicByteBuffer::operator=(DynamicByteBuffer&& other) {
   buffer_size_ = other.buffer_size_;
   other.buffer_size_ = 0u;
   buffer_ = std::move(other.buffer_);
   return *this;
 }

 const uint8_t* DynamicByteBuffer::data() const { return buffer_.get(); }

 uint8_t* DynamicByteBuffer::mutable_data() { return buffer_.get(); }

 size_t DynamicByteBuffer::size() const { return buffer_size_; }

 void DynamicByteBuffer::Fill(uint8_t value) { memset(buffer_.get(), value, buffer_size_); }

 ByteBuffer::const_iterator DynamicByteBuffer::cbegin() const { return buffer_.get(); }

 ByteBuffer::const_iterator DynamicByteBuffer::cend() const { return buffer_.get() + buffer_size_; }

 BufferView::BufferView(const ByteBuffer& buffer, size_t size) { *this = buffer.view(0u, size); }

 BufferView::BufferView(std::string_view string) {
   size_ = string.size();
   bytes_ = reinterpret_cast<const uint8_t*>(string.data());
 }

 BufferView::BufferView(const std::vector<uint8_t>& vec) : BufferView(vec.data(), vec.size()) {}

 BufferView::BufferView(const void* bytes, size_t size)
     : size_(size), bytes_(static_cast<const uint8_t*>(bytes)) {
   // If |size| non-zero then |bytes| cannot be nullptr.
   ZX_ASSERT_MSG(!size_ || bytes_, "|bytes_| cannot be nullptr if |size_| > 0");
 }

 BufferView::BufferView() = default;

 const uint8_t* BufferView::data() const { return bytes_; }

 size_t BufferView::size() const { return size_; }

 ByteBuffer::const_iterator BufferView::cbegin() const { return bytes_; }

 ByteBuffer::const_iterator BufferView::cend() const { return bytes_ + size_; }

 MutableBufferView::MutableBufferView(MutableByteBuffer* buffer) {
   ZX_ASSERT(buffer);
   size_ = buffer->size();
   bytes_ = buffer->mutable_data();
 }

 MutableBufferView::MutableBufferView(void* bytes, size_t size)
     : size_(size), bytes_(static_cast<uint8_t*>(bytes)) {
   // If |size| non-zero then |bytes| cannot be nullptr.
   ZX_ASSERT_MSG(!size_ || bytes_, "|bytes_| cannot be nullptr if |size_| > 0");
 }

 MutableBufferView::MutableBufferView() = default;

 const uint8_t* MutableBufferView::data() const { return bytes_; }

 size_t MutableBufferView::size() const { return size_; }

 ByteBuffer::const_iterator MutableBufferView::cbegin() const { return bytes_; }

 ByteBuffer::const_iterator MutableBufferView::cend() const { return bytes_ + size_; }

 uint8_t* MutableBufferView::mutable_data() { return bytes_; }

 void MutableBufferView::Fill(uint8_t value) { memset(bytes_, value, size_); }

 }  // namespace bt
	// Copyright 2017 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "byte_buffer.h"

	namespace bt {

	void ByteBuffer::Copy(MutableByteBuffer* out_buffer) const {
	ZX_ASSERT(out_buffer);
	CopyRaw(out_buffer->mutable_data(), out_buffer->size(), 0, size());
	}

	void ByteBuffer::Copy(MutableByteBuffer* out_buffer, size_t pos, size_t size) const {
	ZX_ASSERT(out_buffer);
	CopyRaw(out_buffer->mutable_data(), out_buffer->size(), pos, size);
	}

	BufferView ByteBuffer::view(size_t pos, size_t size) const {
	ZX_ASSERT_MSG(pos <= this->size(), "offset past buffer (pos: %zu, size: %zu)", pos, this->size());
	return BufferView(data() + pos, std::min(size, this->size() - pos));
	}

	std::string_view ByteBuffer::AsString() const {
	return std::string_view(reinterpret_cast<const char*>(data()), size());
	}

	std::string ByteBuffer::ToString() const { return std::string(AsString()); }

	std::vector<uint8_t> ByteBuffer::ToVector() const {
	std::vector<uint8_t> vec(size());
	MutableBufferView vec_view(vec.data(), vec.size());
	vec_view.Write(*this);
	return vec;
	}

	void ByteBuffer::CopyRaw(void* dst_data, size_t dst_capacity, size_t src_offset,
	size_t copy_size) const {
	ZX_ASSERT_MSG(copy_size == 0 \|\| dst_data != nullptr, "%zu byte write to pointer %p", copy_size,
	dst_data);
	ZX_ASSERT_MSG(copy_size <= dst_capacity,
	"destination not large enough (required: %zu, available: %zu)", copy_size,
	dst_capacity);
	ZX_ASSERT_MSG(src_offset <= this->size(),
	"offset exceeds source range (begin: %zu, copy_size: %zu)", src_offset,
	this->size());
	ZX_ASSERT_MSG(std::numeric_limits<size_t>::max() - copy_size >= src_offset,
	"end of source range overflows size_t (src_offset: %zu, copy_size: %zu)",
	src_offset, copy_size);
	ZX_ASSERT_MSG(src_offset + copy_size <= this->size(),
	"end exceeds source range (end: %zu, copy_size: %zu)", src_offset + copy_size,
	this->size());

	// Data pointers for zero-length buffers are nullptr, over which memcpy has undefined behavior,
	// even for count = 0. Skip the memcpy invocation in that case.
	if (copy_size == 0) {
	return;
	}
	std::memcpy(dst_data, data() + src_offset, copy_size);
	}

	void MutableByteBuffer::Write(const uint8_t* data, size_t size, size_t pos) {
	BufferView from(data, size);
	MutableBufferView to = mutable_view(pos);
	from.Copy(&to);
	}

	void MutableByteBuffer::FillWithRandomBytes() {
	if (size()) {
	zx_cprng_draw(mutable_data(), size());
	}
	}

	MutableBufferView MutableByteBuffer::mutable_view(size_t pos, size_t size) {
	ZX_ASSERT_MSG(pos <= this->size(), "offset past buffer (pos: %zu, size: %zu)", pos, this->size());
	return MutableBufferView(mutable_data() + pos, std::min(size, this->size() - pos));
	}

	DynamicByteBuffer::DynamicByteBuffer() = default;

	DynamicByteBuffer::DynamicByteBuffer(size_t buffer_size) : buffer_size_(buffer_size) {
	if (buffer_size == 0)
	return;
	buffer_ = std::make_unique<uint8_t[]>(buffer_size);

	// TODO(armansito): For now this is dumb but we should properly handle the
	// case when we're out of memory.
	ZX_ASSERT_MSG(buffer_.get(), "failed to allocate buffer");
	}

	DynamicByteBuffer::DynamicByteBuffer(const ByteBuffer& buffer)
	: buffer_size_(buffer.size()),
	buffer_(buffer.size() ? std::make_unique<uint8_t[]>(buffer.size()) : nullptr) {
	ZX_ASSERT_MSG(!buffer_size_ \|\| buffer_.get(),
	"\|buffer\| cannot be nullptr when \|buffer_size\| is non-zero");
	buffer.Copy(this);
	}

	DynamicByteBuffer::DynamicByteBuffer(const DynamicByteBuffer& buffer)
	: DynamicByteBuffer(static_cast<const ByteBuffer&>(buffer)) {}

	DynamicByteBuffer::DynamicByteBuffer(size_t buffer_size, std::unique_ptr<uint8_t[]> buffer)
	: buffer_size_(buffer_size), buffer_(std::move(buffer)) {
	ZX_ASSERT_MSG(!buffer_size_ \|\| buffer_.get(),
	"\|buffer\| cannot be nullptr when \|buffer_size\| is non-zero");
	}

	DynamicByteBuffer::DynamicByteBuffer(DynamicByteBuffer&& other) {
	buffer_size_ = other.buffer_size_;
	other.buffer_size_ = 0u;
	buffer_ = std::move(other.buffer_);
	}

	DynamicByteBuffer& DynamicByteBuffer::operator=(DynamicByteBuffer&& other) {
	buffer_size_ = other.buffer_size_;
	other.buffer_size_ = 0u;
	buffer_ = std::move(other.buffer_);
	return *this;
	}

	const uint8_t* DynamicByteBuffer::data() const { return buffer_.get(); }

	uint8_t* DynamicByteBuffer::mutable_data() { return buffer_.get(); }

	size_t DynamicByteBuffer::size() const { return buffer_size_; }

	void DynamicByteBuffer::Fill(uint8_t value) { memset(buffer_.get(), value, buffer_size_); }

	ByteBuffer::const_iterator DynamicByteBuffer::cbegin() const { return buffer_.get(); }

	ByteBuffer::const_iterator DynamicByteBuffer::cend() const { return buffer_.get() + buffer_size_; }

	BufferView::BufferView(const ByteBuffer& buffer, size_t size) { *this = buffer.view(0u, size); }

	BufferView::BufferView(std::string_view string) {
	size_ = string.size();
	bytes_ = reinterpret_cast<const uint8_t*>(string.data());
	}

	BufferView::BufferView(const std::vector<uint8_t>& vec) : BufferView(vec.data(), vec.size()) {}

	BufferView::BufferView(const void* bytes, size_t size)
	: size_(size), bytes_(static_cast<const uint8_t*>(bytes)) {
	// If \|size\| non-zero then \|bytes\| cannot be nullptr.
	ZX_ASSERT_MSG(!size_ \|\| bytes_, "\|bytes_\| cannot be nullptr if \|size_\| > 0");
	}

	BufferView::BufferView() = default;

	const uint8_t* BufferView::data() const { return bytes_; }

	size_t BufferView::size() const { return size_; }

	ByteBuffer::const_iterator BufferView::cbegin() const { return bytes_; }

	ByteBuffer::const_iterator BufferView::cend() const { return bytes_ + size_; }

	MutableBufferView::MutableBufferView(MutableByteBuffer* buffer) {
	ZX_ASSERT(buffer);
	size_ = buffer->size();
	bytes_ = buffer->mutable_data();
	}

	MutableBufferView::MutableBufferView(void* bytes, size_t size)
	: size_(size), bytes_(static_cast<uint8_t*>(bytes)) {
	// If \|size\| non-zero then \|bytes\| cannot be nullptr.
	ZX_ASSERT_MSG(!size_ \|\| bytes_, "\|bytes_\| cannot be nullptr if \|size_\| > 0");
	}

	MutableBufferView::MutableBufferView() = default;

	const uint8_t* MutableBufferView::data() const { return bytes_; }

	size_t MutableBufferView::size() const { return size_; }

	ByteBuffer::const_iterator MutableBufferView::cbegin() const { return bytes_; }

	ByteBuffer::const_iterator MutableBufferView::cend() const { return bytes_ + size_; }

	uint8_t* MutableBufferView::mutable_data() { return bytes_; }

	void MutableBufferView::Fill(uint8_t value) { memset(bytes_, value, size_); }

	} // namespace bt