/* * Copyright (C) 2015 Tim Mayberry * * This program 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. * * This program 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 more 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "winmmemidi_input_device.h" #include #include #include "pbd/compose.h" #include "win_utils.h" #include "midi_util.h" #include "debug.h" static const uint32_t MIDI_BUFFER_SIZE = 32768; static const uint32_t SYSEX_BUFFER_SIZE = 32768; namespace ARDOUR { WinMMEMidiInputDevice::WinMMEMidiInputDevice (int index) : m_handle(0) , m_midi_buffer(new RingBuffer(MIDI_BUFFER_SIZE)) , m_sysex_buffer(new uint8_t[SYSEX_BUFFER_SIZE]) { DEBUG_MIDI (string_compose ("Creating midi input device index: %1\n", index)); std::string error_msg; if (!open (index, error_msg)) { DEBUG_MIDI (error_msg); throw std::runtime_error (error_msg); } // perhaps this should be called in open if (!add_sysex_buffer (error_msg)) { DEBUG_MIDI (error_msg); std::string close_error; if (!close (close_error)) { DEBUG_MIDI (close_error); } throw std::runtime_error (error_msg); } set_device_name (index); } WinMMEMidiInputDevice::~WinMMEMidiInputDevice () { std::string error_msg; if (!close (error_msg)) { DEBUG_MIDI (error_msg); } } bool WinMMEMidiInputDevice::open (UINT index, std::string& error_msg) { MMRESULT result = midiInOpen (&m_handle, index, (DWORD_PTR) winmm_input_callback, (DWORD_PTR) this, CALLBACK_FUNCTION | MIDI_IO_STATUS); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); return false; } DEBUG_MIDI (string_compose ("Opened MIDI device index %1\n", index)); return true; } bool WinMMEMidiInputDevice::close (std::string& error_msg) { // return error message for first error encountered? bool success = true; MMRESULT result = midiInReset (m_handle); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); DEBUG_MIDI (error_msg); success = false; } result = midiInUnprepareHeader (m_handle, &m_sysex_header, sizeof(MIDIHDR)); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); DEBUG_MIDI (error_msg); success = false; } result = midiInClose (m_handle); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); DEBUG_MIDI (error_msg); success = false; } m_handle = 0; if (success) { DEBUG_MIDI (string_compose ("Closed MIDI device: %1\n", name ())); } else { DEBUG_MIDI (string_compose ("Unable to Close MIDI device: %1\n", name ())); } return success; } bool WinMMEMidiInputDevice::add_sysex_buffer (std::string& error_msg) { m_sysex_header.dwBufferLength = SYSEX_BUFFER_SIZE; m_sysex_header.dwFlags = 0; m_sysex_header.lpData = (LPSTR)m_sysex_buffer.get (); MMRESULT result = midiInPrepareHeader (m_handle, &m_sysex_header, sizeof(MIDIHDR)); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); DEBUG_MIDI (error_msg); return false; } result = midiInAddBuffer (m_handle, &m_sysex_header, sizeof(MIDIHDR)); if (result != MMSYSERR_NOERROR) { error_msg = get_error_string (result); DEBUG_MIDI (error_msg); return false; } return true; } bool WinMMEMidiInputDevice::set_device_name (UINT index) { MIDIINCAPS capabilities; MMRESULT result = midiInGetDevCaps (index, &capabilities, sizeof(capabilities)); if (result != MMSYSERR_NOERROR) { DEBUG_MIDI (get_error_string (result)); m_name = "Unknown Midi Input Device"; return false; } else { m_name = capabilities.szPname; } return true; } std::string WinMMEMidiInputDevice::get_error_string (MMRESULT error_code) { char error_msg[MAXERRORLENGTH]; MMRESULT result = midiInGetErrorText (error_code, error_msg, MAXERRORLENGTH); if (result != MMSYSERR_NOERROR) { return error_msg; } return "WinMMEMidiInput: Unknown Error code"; } void CALLBACK WinMMEMidiInputDevice::winmm_input_callback(HMIDIIN handle, UINT msg, DWORD_PTR instance, DWORD_PTR midi_msg, DWORD timestamp) { WinMMEMidiInputDevice* midi_input = (WinMMEMidiInputDevice*)instance; switch (msg) { case MIM_OPEN: case MIM_CLOSE: // devices_changed_callback break; case MIM_MOREDATA: // passing MIDI_IO_STATUS to midiInOpen means that MIM_MOREDATA // will be sent when the callback isn't processing MIM_DATA messages // fast enough to keep up with messages arriving at input device // driver. I'm not sure what could be done differently if that occurs // so just handle MIM_DATA as per normal case MIM_DATA: midi_input->handle_short_msg ((const uint8_t*)&midi_msg, (uint32_t)timestamp); break; case MIM_LONGDATA: midi_input->handle_sysex_msg ((MIDIHDR*)&midi_msg, (uint32_t)timestamp); break; case MIM_ERROR: DEBUG_MIDI ("WinMME: Driver sent an invalid MIDI message\n"); break; case MIM_LONGERROR: DEBUG_MIDI ("WinMME: Driver sent an invalid or incomplete SYSEX message\n"); break; } } void WinMMEMidiInputDevice::handle_short_msg (const uint8_t* midi_data, uint32_t timestamp) { int length = get_midi_msg_length (midi_data[0]); if (length == 0 || length == -1) { DEBUG_MIDI ("ERROR: midi input driver sent an invalid midi message\n"); return; } enqueue_midi_msg (midi_data, length, timestamp); } void WinMMEMidiInputDevice::handle_sysex_msg (MIDIHDR* const midi_header, uint32_t timestamp) { #ifdef ENABLE_SYSEX LPMIDIHDR header = (LPMIDIHDR)midi_header; size_t byte_count = header->dwBytesRecorded; if (!byte_count) { DEBUG_MIDI ( "ERROR: WinMME driver has returned sysex header to us with no bytes\n"); return; } uint8_t* data = (uint8_t*)header->lpData; if ((data[0] != 0xf0) || (data[byte_count - 1] != 0xf7)) { DEBUG_MIDI (string_compose ("Discarding %1 byte sysex chunk\n", byte_count)); } else { enqueue_midi_msg (data, byte_count, timestamp); } MMRESULT result = midiInAddBuffer (m_handle, &m_sysex_header, sizeof(MIDIHDR)); if (result != MMSYSERR_NOERROR) { DEBUG_MIDI (get_error_string (result)); } #endif } // fix param order bool WinMMEMidiInputDevice::dequeue_midi_event (uint64_t timestamp_start, uint64_t timestamp_end, uint64_t& timestamp, uint8_t* midi_data, size_t& data_size) { const uint32_t read_space = m_midi_buffer->read_space(); struct MidiEventHeader h(0,0); if (read_space <= sizeof(MidiEventHeader)) { return false; } RingBuffer::rw_vector vector; m_midi_buffer->get_read_vector (&vector); if (vector.len[0] >= sizeof(MidiEventHeader)) { memcpy ((uint8_t*)&h, vector.buf[0], sizeof(MidiEventHeader)); } else { if (vector.len[0] > 0) { memcpy ((uint8_t*)&h, vector.buf[0], vector.len[0]); } assert (vector.buf[1] || vector.len[0] == sizeof(MidiEventHeader)); memcpy (((uint8_t*)&h) + vector.len[0], vector.buf[1], sizeof(MidiEventHeader) - vector.len[0]); } if (h.time >= timestamp_end) { DEBUG_TIMING (string_compose ("WinMMEMidiInput EVENT %1(ms) early\n", (h.time - timestamp_end) * 1e-3)); return false; } else if (h.time < timestamp_start) { DEBUG_TIMING (string_compose ("WinMMEMidiInput EVENT %1(ms) late\n", (timestamp_start - h.time) * 1e-3)); } m_midi_buffer->increment_read_idx (sizeof(MidiEventHeader)); assert (h.size > 0); if (h.size > data_size) { DEBUG_MIDI ("WinMMEMidiInput::dequeue_event MIDI event too large!\n"); m_midi_buffer->increment_read_idx (h.size); return false; } if (m_midi_buffer->read (&midi_data[0], h.size) != h.size) { DEBUG_MIDI ("WinMMEMidiInput::dequeue_event Garbled MIDI EVENT DATA!!\n"); return false; } timestamp = h.time; data_size = h.size; return true; } bool WinMMEMidiInputDevice::enqueue_midi_msg (const uint8_t* midi_data, size_t data_size, uint32_t timestamp) { const uint32_t total_size = sizeof(MidiEventHeader) + data_size; if (data_size == 0) { DEBUG_MIDI ("ERROR: zero length midi data\n"); return false; } if (m_midi_buffer->write_space () < total_size) { DEBUG_MIDI ("WinMMEMidiInput: ring buffer overflow\n"); return false; } // don't use winmme timestamps for now uint64_t ts = utils::get_microseconds (); DEBUG_TIMING (string_compose ( "Enqueing MIDI data device: %1 with timestamp: %2 and size %3\n", name (), ts, data_size)); struct MidiEventHeader h (ts, data_size); m_midi_buffer->write ((uint8_t*)&h, sizeof(MidiEventHeader)); m_midi_buffer->write (midi_data, data_size); return true; } bool WinMMEMidiInputDevice::start () { if (!m_started) { MMRESULT result = midiInStart (m_handle); m_started = (result == MMSYSERR_NOERROR); if (!m_started) { DEBUG_MIDI (get_error_string (result)); } else { DEBUG_MIDI ( string_compose ("WinMMEMidiInput: device %1 started\n", name ())); } } return m_started; } bool WinMMEMidiInputDevice::stop () { if (m_started) { MMRESULT result = midiInStop (m_handle); m_started = (result != MMSYSERR_NOERROR); if (m_started) { DEBUG_MIDI (get_error_string (result)); } else { DEBUG_MIDI ( string_compose ("WinMMEMidiInput: device %1 stopped\n", name ())); } } return !m_started; } } // namespace ARDOUR