/* This file is part of Evoral. * Copyright (C) 2008 Dave Robillard * * Evoral is free software; you can redistribute it and/or modify it under the * terms of the GNU General Public License as published by the Free Software * Foundation; either version 2 of the License, or (at your option) any later * version. * * Evoral is distributed in the hope that it will be useful, but WITHOUT ANY * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS * FOR A PARTICULAR PURPOSE. See the GNU General Public License for details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #ifndef EVORAL_RING_BUFFER_HPP #define EVORAL_RING_BUFFER_HPP #include #include #include namespace Evoral { /** A lock-free RingBuffer. * Read/Write realtime safe. * Single-reader Single-writer thread safe. */ template class RingBuffer { public: /** @param size Size in bytes. */ RingBuffer(size_t size) : _size(size) , _buf(new T[size]) { reset(); assert(read_space() == 0); assert(write_space() == size - 1); } virtual ~RingBuffer() { delete[] _buf; } /** Reset(empty) the ringbuffer. * NOT thread safe. */ void reset() { g_atomic_int_set(&_write_ptr, 0); g_atomic_int_set(&_read_ptr, 0); } /** Calculate remaining space for writing */ size_t write_space() const { const size_t w = g_atomic_int_get(&_write_ptr); const size_t r = g_atomic_int_get(&_read_ptr); if (w > r) { return ((r - w + _size) % _size) - 1; } else if (w < r) { return (r - w) - 1; } else { return _size - 1; } } /** Calculate how much still can be read */ size_t read_space() const { const size_t w = g_atomic_int_get(&_write_ptr); const size_t r = g_atomic_int_get(&_read_ptr); if (w > r) { return w - r; } else { return (w - r + _size) % _size; } } /** Report the buffers size */ size_t capacity() const { return _size; } /** Peek at the ringbuffer (read w/o advancing read pointer). * @return how much has been peeked (read cannot exceed the end * of the buffer): * 
	 * |-------------------------R=============================|
	 *            read-pointer---^
	 *
*/ size_t peek(size_t size, T* dst); /** Peek at the ringbuffer (read w/o advancing read pointer). * @return how much has been peeked (wraps around if read exceeds * the end of the buffer): * 
	 * |===========--------------R=============================|
	 *            read-pointer---^
	 *
*/ bool full_peek(size_t size, T* dst); /** Read from the ringbuffer. (advances read pointer) * @return how much has been read (read cannot exceed the end * of the buffer): */ size_t read(size_t size, T* dst); /** Read from the ringbuffer. (advances read pointer) * @return how much has been peeked (wraps around if read exceeds * the end of the buffer): */ bool full_read(size_t size, T* dst); /** Advance read pointer by size */ bool skip(size_t size); void write(size_t size, const T* src); protected: mutable int _write_ptr; mutable int _read_ptr; size_t _size; ///< Size (capacity) in bytes T* _buf; ///< size, event, size, event... }; /** Peek at the ringbuffer (read w/o advancing read pointer). * * Note that a full read may not be done if the data wraps around. * Caller must check return value and call again if necessary, or use the * full_peek method which does this automatically. */ template size_t RingBuffer::peek(size_t size, T* dst) { const size_t priv_read_ptr = g_atomic_int_get(&_read_ptr); const size_t read_size = (priv_read_ptr + size < _size) ? size : _size - priv_read_ptr; memcpy(dst, &_buf[priv_read_ptr], read_size); return read_size; } template bool RingBuffer::full_peek(size_t size, T* dst) { if (read_space() < size) { return false; } const size_t read_size = peek(size, dst); if (read_size < size) { peek(size - read_size, dst + read_size); } return true; } /** Read from the ringbuffer. * * Note that a full read may not be done if the data wraps around. * Caller must check return value and call again if necessary, or use the * full_read method which does this automatically. */ template size_t RingBuffer::read(size_t size, T* dst) { const size_t priv_read_ptr = g_atomic_int_get(&_read_ptr); const size_t read_size = (priv_read_ptr + size < _size) ? size : _size - priv_read_ptr; memcpy(dst, &_buf[priv_read_ptr], read_size); g_atomic_int_set(&_read_ptr, (priv_read_ptr + read_size) % _size); return read_size; } template bool RingBuffer::full_read(size_t size, T* dst) { if (read_space() < size) { return false; } const size_t read_size = read(size, dst); if (read_size < size) { read(size - read_size, dst + read_size); } return true; } template bool RingBuffer::skip(size_t size) { if (read_space() < size) { std::cerr << "WARNING: Attempt to skip past end of MIDI ring buffer" << std::endl; return false; } const size_t priv_read_ptr = g_atomic_int_get(&_read_ptr); g_atomic_int_set(&_read_ptr, (priv_read_ptr + size) % _size); return true; } template inline void RingBuffer::write(size_t size, const T* src) { const size_t priv_write_ptr = g_atomic_int_get(&_write_ptr); if (priv_write_ptr + size <= _size) { memcpy(&_buf[priv_write_ptr], src, size); g_atomic_int_set(&_write_ptr, (priv_write_ptr + size) % _size); } else { const size_t this_size = _size - priv_write_ptr; assert(this_size < size); assert(priv_write_ptr + this_size <= _size); memcpy(&_buf[priv_write_ptr], src, this_size); memcpy(&_buf[0], src+this_size, size - this_size); g_atomic_int_set(&_write_ptr, size - this_size); } } } // namespace Evoral #endif // EVORAL_RING_BUFFER_HPP