// Copyright 2013 The Chromium 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 "chrome/common/partial_circular_buffer.h" #include #include "base/logging.h" namespace { inline uint32 Min3(uint32 a, uint32 b, uint32 c) { return std::min(a, std::min(b, c)); } } // namespace PartialCircularBuffer::PartialCircularBuffer(void* buffer, uint32 buffer_size) : buffer_data_(reinterpret_cast(buffer)), memory_buffer_size_(buffer_size), data_size_(0), position_(0), total_read_(0) { uint32 header_size = buffer_data_->data - reinterpret_cast(buffer_data_); data_size_ = memory_buffer_size_ - header_size; DCHECK(buffer_data_); DCHECK_GE(memory_buffer_size_, header_size); DCHECK_LE(buffer_data_->total_written, data_size_); DCHECK_LT(buffer_data_->wrap_position, data_size_); DCHECK_LT(buffer_data_->end_position, data_size_); } PartialCircularBuffer::PartialCircularBuffer(void* buffer, uint32 buffer_size, uint32 wrap_position, bool append) : buffer_data_(reinterpret_cast(buffer)), memory_buffer_size_(buffer_size), data_size_(0), position_(0), total_read_(0) { uint32 header_size = buffer_data_->data - reinterpret_cast(buffer_data_); data_size_ = memory_buffer_size_ - header_size; DCHECK(buffer_data_); DCHECK_GE(memory_buffer_size_, header_size); if (append) { DCHECK_LT(buffer_data_->wrap_position, data_size_); position_ = buffer_data_->end_position; } else { DCHECK_LT(wrap_position, data_size_); buffer_data_->total_written = 0; buffer_data_->wrap_position = wrap_position; buffer_data_->end_position = 0; } } uint32 PartialCircularBuffer::Read(void* buffer, uint32 buffer_size) { DCHECK(buffer_data_); if (total_read_ >= buffer_data_->total_written) return 0; uint8* buffer_uint8 = reinterpret_cast(buffer); uint32 read = 0; // Read from beginning part. if (position_ < buffer_data_->wrap_position) { uint32 to_wrap_pos = buffer_data_->wrap_position - position_; uint32 to_eow = buffer_data_->total_written - total_read_; uint32 to_read = Min3(buffer_size, to_wrap_pos, to_eow); memcpy(buffer_uint8, buffer_data_->data + position_, to_read); position_ += to_read; total_read_ += to_read; read += to_read; if (position_ == buffer_data_->wrap_position && buffer_data_->total_written == data_size_) { // We've read all the beginning part, set the position to the middle part. // (The second condition above checks if the wrapping part is filled, i.e. // writing has wrapped.) position_ = buffer_data_->end_position; } if (read >= buffer_size) { DCHECK_EQ(read, buffer_size); return read; } if (read >= to_eow) { DCHECK_EQ(read, to_eow); DCHECK_EQ(total_read_, buffer_data_->total_written); return read; } } // Read from middle part. DCHECK_GE(position_, buffer_data_->wrap_position); if (position_ >= buffer_data_->end_position) { uint32 remaining_buffer_size = buffer_size - read; uint32 to_eof = data_size_ - position_; uint32 to_eow = buffer_data_->total_written - total_read_; uint32 to_read = Min3(remaining_buffer_size, to_eof, to_eow); memcpy(buffer_uint8 + read, buffer_data_->data + position_, to_read); position_ += to_read; total_read_ += to_read; read += to_read; if (position_ == data_size_) { // We've read all the middle part, set position to the end part. position_ = buffer_data_->wrap_position; } if (read >= buffer_size) { DCHECK_EQ(read, buffer_size); return read; } if (total_read_ >= buffer_data_->total_written) { DCHECK_EQ(total_read_, buffer_data_->total_written); return read; } } // Read from end part. DCHECK_GE(position_, buffer_data_->wrap_position); DCHECK_LT(position_, buffer_data_->end_position); uint32 remaining_buffer_size = buffer_size - read; uint32 to_eob = buffer_data_->end_position - position_; uint32 to_eow = buffer_data_->total_written - total_read_; uint32 to_read = Min3(remaining_buffer_size, to_eob, to_eow); memcpy(buffer_uint8 + read, buffer_data_->data + position_, to_read); position_ += to_read; total_read_ += to_read; read += to_read; DCHECK_LE(read, buffer_size); DCHECK_LE(total_read_, buffer_data_->total_written); return read; } void PartialCircularBuffer::Write(const void* buffer, uint32 buffer_size) { DCHECK(buffer_data_); const uint8* input = static_cast(buffer); uint32 wrap_position = buffer_data_->wrap_position; uint32 cycle_size = data_size_ - wrap_position; // First write the non-wrapping part. if (position_ < wrap_position) { uint32 space_left = wrap_position - position_; uint32 write_size = std::min(buffer_size, space_left); DoWrite(input, write_size); input += write_size; buffer_size -= write_size; } // Skip the part that would overlap. if (buffer_size > cycle_size) { uint32 skip = buffer_size - cycle_size; input += skip; buffer_size -= skip; position_ = wrap_position + (position_ - wrap_position + skip) % cycle_size; } // Finally write the wrapping part. DoWrite(input, buffer_size); } void PartialCircularBuffer::DoWrite(const uint8* input, uint32 input_size) { DCHECK_LT(position_, data_size_); buffer_data_->total_written = std::min(buffer_data_->total_written + input_size, data_size_); // Write() skips any overlapping part, so this loop will run at most twice. while (input_size > 0) { uint32 space_left = data_size_ - position_; uint32 write_size = std::min(input_size, space_left); memcpy(buffer_data_->data + position_, input, write_size); input += write_size; input_size -= write_size; position_ += write_size; if (position_ >= data_size_) { DCHECK_EQ(position_, data_size_); position_ = buffer_data_->wrap_position; } } buffer_data_->end_position = position_; }