// Copyright 2014 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 "media/midi/usb_midi_output_stream.h" #include "base/logging.h" #include "media/midi/midi_message_util.h" #include "media/midi/usb_midi_device.h" namespace media { namespace midi { UsbMidiOutputStream::UsbMidiOutputStream(const UsbMidiJack& jack) : jack_(jack), pending_size_(0), is_sending_sysex_(false) {} void UsbMidiOutputStream::Send(const std::vector& data) { // To prevent link errors caused by DCHECK_*. const size_t kPacketContentSize = UsbMidiOutputStream::kPacketContentSize; DCHECK_LT(jack_.cable_number, 16u); std::vector data_to_send; size_t current = 0; size_t size = GetSize(data); while (current < size) { uint8 first_byte = Get(data, current); if (first_byte == kSysExByte || is_sending_sysex_) { // System Exclusive messages if (!PushSysExMessage(data, ¤t, &data_to_send)) break; } else if ((first_byte & kSysMessageBitMask) == kSysMessageBitPattern) { if (first_byte & 0x08) { // System Real-Time messages PushSysRTMessage(data, ¤t, &data_to_send); } else { // System Common messages if (!PushSysCommonMessage(data, ¤t, &data_to_send)) break; } } else if (first_byte & 0x80) { if (!PushChannelMessage(data, ¤t, &data_to_send)) break; } else { // Unknown messages DVLOG(1) << "Unknown byte: " << static_cast(first_byte); ++current; } } if (data_to_send.size() > 0) jack_.device->Send(jack_.endpoint_number(), data_to_send); DCHECK_LE(current, size); DCHECK_LE(size - current, kPacketContentSize); // Note that this can be a self-copying and the iteration order is important. for (size_t i = current; i < size; ++i) pending_data_[i - current] = Get(data, i); pending_size_ = size - current; } size_t UsbMidiOutputStream::GetSize(const std::vector& data) const { return data.size() + pending_size_; } uint8_t UsbMidiOutputStream::Get(const std::vector& data, size_t index) const { DCHECK_LT(index, GetSize(data)); if (index < pending_size_) return pending_data_[index]; return data[index - pending_size_]; } bool UsbMidiOutputStream::PushSysExMessage(const std::vector& data, size_t* current, std::vector* data_to_send) { size_t index = *current; size_t message_size = 0; const size_t kMessageSizeMax = 3; uint8 message[kMessageSizeMax] = {}; while (index < GetSize(data)) { if (message_size == kMessageSizeMax) { // We can't find the end-of-message mark in the three bytes. *current = index; data_to_send->push_back((jack_.cable_number << 4) | 0x4); data_to_send->insert(data_to_send->end(), message, message + arraysize(message)); is_sending_sysex_ = true; return true; } uint8 byte = Get(data, index); if ((byte & kSysRTMessageBitMask) == kSysRTMessageBitPattern) { // System Real-Time messages interleaved in a SysEx message PushSysRTMessage(data, &index, data_to_send); continue; } message[message_size] = byte; ++message_size; if (byte == kEndOfSysExByte) { uint8 code_index = static_cast(message_size) + 0x4; DCHECK(code_index == 0x5 || code_index == 0x6 || code_index == 0x7); data_to_send->push_back((jack_.cable_number << 4) | code_index); data_to_send->insert(data_to_send->end(), message, message + arraysize(message)); *current = index + 1; is_sending_sysex_ = false; return true; } ++index; } return false; } bool UsbMidiOutputStream::PushSysCommonMessage( const std::vector& data, size_t* current, std::vector* data_to_send) { size_t index = *current; uint8 first_byte = Get(data, index); DCHECK_LE(0xf1, first_byte); DCHECK_LE(first_byte, 0xf7); DCHECK_EQ(0xf0, first_byte & 0xf8); // There are only 6 message types (0xf1 - 0xf7), so the table size is 8. const size_t message_size_table[8] = { 0, 2, 3, 2, 1, 1, 1, 0, }; size_t message_size = message_size_table[first_byte & 0x07]; DCHECK_NE(0u, message_size); DCHECK_LE(message_size, 3u); if (GetSize(data) < index + message_size) { // The message is incomplete. return false; } uint8 code_index = message_size == 1 ? 0x5 : static_cast(message_size); data_to_send->push_back((jack_.cable_number << 4) | code_index); for (size_t i = index; i < index + 3; ++i) data_to_send->push_back(i < index + message_size ? Get(data, i) : 0); *current += message_size; return true; } void UsbMidiOutputStream::PushSysRTMessage(const std::vector& data, size_t* current, std::vector* data_to_send) { size_t index = *current; uint8 first_byte = Get(data, index); DCHECK_LE(0xf8, first_byte); DCHECK_LE(first_byte, 0xff); data_to_send->push_back((jack_.cable_number << 4) | 0x5); data_to_send->push_back(first_byte); data_to_send->push_back(0); data_to_send->push_back(0); *current += 1; } bool UsbMidiOutputStream::PushChannelMessage(const std::vector& data, size_t* current, std::vector* data_to_send) { size_t index = *current; uint8 first_byte = Get(data, index); DCHECK_LE(0x80, (first_byte & 0xf0)); DCHECK_LE((first_byte & 0xf0), 0xe0); // There are only 7 message types (0x8-0xe in the higher four bits), so the // table size is 8. const size_t message_size_table[8] = { 3, 3, 3, 3, 2, 3, 3, 0, }; uint8 code_index = first_byte >> 4; DCHECK_LE(0x08, code_index); DCHECK_LE(code_index, 0x0e); size_t message_size = message_size_table[code_index & 0x7]; DCHECK_NE(0u, message_size); DCHECK_LE(message_size, 3u); if (GetSize(data) < index + message_size) { // The message is incomplete. return false; } data_to_send->push_back((jack_.cable_number << 4) | code_index); for (size_t i = index; i < index + 3; ++i) data_to_send->push_back(i < index + message_size ? Get(data, i) : 0); *current += message_size; return true; } } // namespace midi } // namespace media