Mercurial > hg > touchkeys
view Source/MainApplicationController.cpp @ 56:b4a2d2ae43cf tip
merge
| author | Andrew McPherson <andrewm@eecs.qmul.ac.uk> |
|---|---|
| date | Fri, 23 Nov 2018 15:48:14 +0000 |
| parents | 19650b4076ee e468cb91794a |
| children |
line wrap: on
line source
/* TouchKeys: multi-touch musical keyboard control software Copyright (c) 2013 Andrew McPherson 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 3 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, see <http://www.gnu.org/licenses/>. ===================================================================== MainApplicationController.cpp: contains the overall glue that holds together the various parts of the TouchKeys code. It works together with the user interface to let the user configure the hardware and manage the mappings, but it is kept separate from any particular user interface configuration. */ #include "MainApplicationController.h" #ifndef TOUCHKEYS_NO_GUI #include "Display/KeyboardTesterDisplay.h" #endif #include <cstdlib> #include <sstream> // Strings for pitch classes (two forms for sharps), for static methods const char* kNoteNames[12] = {"C", "C#", "D", "D#", "E", "F", "F#", "G", "G#", "A", "A#", "B"}; const char* kNoteNamesAlternate[12] = {"C", "Db", "D ", "Eb", "E", "F", "Gb", "G", "Ab", "A", "Bb", "B"}; MainApplicationController::MainApplicationController() : midiInputController_(keyboardController_), oscReceiver_(0, "/touchkeys"), touchkeyController_(keyboardController_), touchkeyEmulator_(keyboardController_, oscReceiver_), logPlayback_(0), #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE touchkeyEntropyGenerator_(keyboardController_), entropyGeneratorSelected_(false), #endif touchkeyErrorOccurred_(false), touchkeyErrorMessage_(""), touchkeyAutodetecting_(false), touchkeyStandaloneModeEnabled_(false), deviceUpdateCounter_(0), oscReceiveEnabled_(false), oscReceivePort_(kDefaultOscReceivePort), experimentalMappingsEnabled_(false), #ifndef TOUCHKEYS_NO_GUI keyboardDisplayWindow_(0), keyboardTesterDisplay_(0), keyboardTesterWindow_(0), preferencesWindow_(0), #endif segmentCounter_(0), loggingActive_(false), isPlayingLog_(false) { // Set our OSC controller setOscController(&keyboardController_); oscTransmitter_.setEnabled(false); //oscTransmitter_.setDebugMessages(true); // Initialize the links between objects keyboardController_.setOscTransmitter(&oscTransmitter_); keyboardController_.setMidiOutputController(&midiOutputController_); keyboardController_.setGUI(&keyboardDisplay_); midiInputController_.setMidiOutputController(&midiOutputController_); // Set up default logging directory loggingDirectory_ = (File::getSpecialLocation(File::userHomeDirectory).getFullPathName() + "/Desktop").toUTF8(); // Configure application properties PropertiesFile::Options options; options.applicationName = "TouchKeys"; options.folderName = "TouchKeys"; options.filenameSuffix = ".properties"; options.osxLibrarySubFolder = "Application Support"; applicationProperties_.setStorageParameters(options); // Defaults for display, until we get other information keyboardDisplay_.setKeyboardRange(36, 72); // Add one keyboard segment at the beginning midiSegmentAdd(); // Load the current preferences loadApplicationPreferences(); // Set up an initial OSC transmit host/port if none has been loaded if(oscTransmitter_.addresses().size() == 0) oscTransmitter_.addAddress(kDefaultOscTransmitHost, kDefaultOscTransmitPort); // Listen for control messages by OSC mainOscController_ = new MainApplicationOSCController(*this, oscReceiver_); } MainApplicationController::~MainApplicationController() { #ifdef ENABLE_TOUCHKEYS_SENSOR_TEST if(touchkeySensorTestIsRunning()) touchkeySensorTestStop(); #endif if(logPlayback_ != 0) delete logPlayback_; removeAllOscListeners(); midiInputController_.removeAllSegments(); // Remove segments now to avoid deletion-order problems delete mainOscController_; } // Actions here run in the JUCE initialise() method once the application is loaded void MainApplicationController::initialise() { // Load a preset if enabled if(getPrefsStartupPresetLastSaved()) { if(applicationProperties_.getUserSettings()->containsKey("LastSavedPreset")) { String presetFile = applicationProperties_.getUserSettings()->getValue("LastSavedPreset"); if(presetFile != "") { loadPresetFromFile(presetFile.toUTF8()); } } } else if(getPrefsStartupPresetVibratoPitchBend()) { if(midiInputController_.numSegments() > 0) { MidiKeyboardSegment *segment = midiInputController_.segment(0); MappingFactory *factory = new TouchkeyVibratoMappingFactory(keyboardController_, *segment); if(factory != 0) segment->addMappingFactory(factory, true); factory = new TouchkeyPitchBendMappingFactory(keyboardController_, *segment); if(factory != 0) segment->addMappingFactory(factory, true); } } else if(!getPrefsStartupPresetNone()) { String presetFile = getPrefsStartupPreset(); if(presetFile != "") { loadPresetFromFile(presetFile.toUTF8()); } } // Automatically start the TouchKeys if the preferences are enabled if(getPrefsAutoStartTouchKeys() && applicationProperties_.getUserSettings()->containsKey("TouchKeysDevice")) { String tkDevicePath = applicationProperties_.getUserSettings()->getValue("TouchKeysDevice"); if(touchkeyDeviceExists(tkDevicePath.toUTF8())) { // Exists: try to open and run touchkeyDeviceStartupSequence(tkDevicePath.toUTF8()); } } } bool MainApplicationController::touchkeyDeviceStartupSequence(const char * path) { #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE if(!strcmp(path, "/dev/Entropy Generator") || !strcmp(path, "\\\\.\\Entropy Generator")) { entropyGeneratorSelected_ = true; touchkeyEntropyGenerator_.start(); } else { entropyGeneratorSelected_ = false; #endif // Step 1: attempt to open device if(!openTouchkeyDevice(path)) { touchkeyErrorMessage_ = "Failed to open"; touchkeyErrorOccurred_ = true; return false; } // Step 2: see if a real TouchKeys device is present at the other end if(!touchkeyDeviceCheckForPresence()) { touchkeyErrorMessage_ = "Device not recognized"; touchkeyErrorOccurred_ = true; return false; } // Step 3: update the display keyboardDisplay_.setKeyboardRange(touchkeyController_.lowestKeyPresentMidiNote(), touchkeyController_.highestMidiNote()); #ifndef TOUCHKEYS_NO_GUI if(keyboardDisplayWindow_ != 0) { keyboardDisplayWindow_->getConstrainer()->setFixedAspectRatio(keyboardDisplay_.keyboardAspectRatio()); juce::Rectangle<int> bounds = keyboardDisplayWindow_->getBounds(); if(bounds.getY() < 44) bounds.setY(44); keyboardDisplayWindow_->setBoundsConstrained(bounds); } #endif // Step 4: start data collection from the device if(!startTouchkeyDevice()) { touchkeyErrorMessage_ = "Failed to start"; touchkeyErrorOccurred_ = true; } #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE } #endif // Success! touchkeyErrorMessage_ = ""; touchkeyErrorOccurred_ = false; #ifndef TOUCHKEYS_NO_GUI showKeyboardDisplayWindow(); #endif // Automatically detect the lowest octave if set if(getPrefsAutodetectOctave()) touchkeyDeviceAutodetectLowestMidiNote(); return true; } std::string MainApplicationController::touchkeyDevicePrefix() { #ifdef _MSC_VER return "\\\\.\\"; #else if(SystemStats::getOperatingSystemType() == SystemStats::Linux) { return "/dev/serial/by-id/"; } else { return "/dev/"; } #endif } // Return a list of available TouchKey devices std::vector<std::string> MainApplicationController::availableTouchkeyDevices() { std::vector<std::string> devices; #ifdef _MSC_VER for(int i = 1; i <= 128; i++) { String comPortName("COM"); comPortName += i; DWORD dwSize = 0; LPCOMMCONFIG lpCC = (LPCOMMCONFIG) new BYTE[1]; BOOL ret = GetDefaultCommConfig(comPortName.toUTF8(), lpCC, &dwSize); delete [] lpCC; if(ret) devices.push_back(comPortName.toStdString()); else { if(GetLastError() == ERROR_INSUFFICIENT_BUFFER) { //Logger::writeToLog(String::formatted("Found " + comPortName)); lpCC = (LPCOMMCONFIG) new BYTE[dwSize]; ret = GetDefaultCommConfig(comPortName.toUTF8(), lpCC, &dwSize); if(ret) devices.push_back(comPortName.toStdString()); else { int error = GetLastError(); //Logger::writeToLog(String("2Didn't find " + comPortName + "; error " + String(error))); } delete [] lpCC; } else { int error = GetLastError(); //Logger::writeToLog(String("Didn't find " + comPortName + "; error " + String(error))); } } } #else if(SystemStats::getOperatingSystemType() == SystemStats::Linux) { DirectoryIterator devDirectory(File("/dev/serial/by-id"),false,"*"); while(devDirectory.next()) { devices.push_back(string(devDirectory.getFile().getFileName().toUTF8())); } } else { DirectoryIterator devDirectory(File("/dev"),false,"cu.usbmodem*"); while(devDirectory.next()) { devices.push_back(string(devDirectory.getFile().getFileName().toUTF8())); } } #endif #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE devices.push_back("Entropy Generator"); #endif return devices; } void MainApplicationController::touchkeyDeviceClearErrorMessage() { touchkeyErrorMessage_ = ""; touchkeyErrorOccurred_ = false; } // Check whether a given touchkey device exists bool MainApplicationController::touchkeyDeviceExists(const char * path) { String pathString(path); File tkDeviceFile(pathString); return tkDeviceFile.existsAsFile(); } // Select a particular touchkey device bool MainApplicationController::openTouchkeyDevice(const char * path) { bool success = touchkeyController_.openDevice(path); if(success) applicationProperties_.getUserSettings()->setValue("TouchKeysDevice", String(path)); return success; } // Close the currently open TouchKeys device void MainApplicationController::closeTouchkeyDevice() { #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE if(entropyGeneratorSelected_) touchkeyEntropyGenerator_.stop(); else touchkeyController_.closeDevice(); #else touchkeyController_.closeDevice(); #endif } // Check whether a TouchKey device is present. Returns true if device found. bool MainApplicationController::touchkeyDeviceCheckForPresence(int waitMilliseconds, int tries) { int count = 0; while(1) { if(touchkeyController_.checkIfDevicePresent(waitMilliseconds)) break; if(++count >= tries) { return false; } } return true; } // Start/stop the TouchKeys data collection bool MainApplicationController::startTouchkeyDevice() { return touchkeyController_.startAutoGathering(); } void MainApplicationController::stopTouchkeyDevice() { touchkeyController_.stopAutoGathering(); } // Status queries on TouchKeys // Returns true if device has been opened bool MainApplicationController::touchkeyDeviceIsOpen() { return touchkeyController_.isOpen(); } // Return true if device is collecting data bool MainApplicationController::touchkeyDeviceIsRunning() { #ifdef TOUCHKEY_ENTROPY_GENERATOR_ENABLE if(entropyGeneratorSelected_) return touchkeyEntropyGenerator_.isRunning(); else return touchkeyController_.isAutoGathering(); #else return touchkeyController_.isAutoGathering(); #endif } // Returns true if an error has occurred bool MainApplicationController::touchkeyDeviceErrorOccurred() { return touchkeyErrorOccurred_; } // Return the error message if one occurred std::string MainApplicationController::touchkeyDeviceErrorMessage() { return touchkeyErrorMessage_; } // How many octaves on the current device int MainApplicationController::touchkeyDeviceNumberOfOctaves() { return touchkeyController_.numberOfOctaves(); } // Return the lowest MIDI note int MainApplicationController::touchkeyDeviceLowestMidiNote() { return touchkeyController_.lowestMidiNote(); } // Set the lowest MIDI note for the TouchKeys void MainApplicationController::touchkeyDeviceSetLowestMidiNote(int note) { keyboardDisplay_.clearAllTouches(); touchkeyEmulator_.setLowestMidiNote(note); touchkeyController_.setLowestMidiNote(note); applicationProperties_.getUserSettings()->setValue("TouchKeysLowestMIDINote", note); } // Start an autodetection routine to match touch data to MIDI void MainApplicationController::touchkeyDeviceAutodetectLowestMidiNote() { if(touchkeyAutodetecting_) return; touchkeyAutodetecting_ = true; addOscListener("/midi/noteon"); } // Abort an autodetection routine void MainApplicationController::touchkeyDeviceStopAutodetecting() { if(!touchkeyAutodetecting_) return; removeOscListener("/midi/noteon"); touchkeyAutodetecting_ = false; } bool MainApplicationController::touchkeyDeviceIsAutodetecting() { return touchkeyAutodetecting_; } // Start logging TouchKeys/MIDI data to a file. Filename is autogenerated // based on current time. void MainApplicationController::startLogging() { if(loggingActive_) stopLogging(); std::stringstream out; out << time(NULL); std::string fileId = out.str(); string midiLogFileName = "midiLog_" + fileId + ".bin"; string keyTouchLogFileName = "keyTouchLog_" + fileId + ".bin"; string analogLogFileName = "keyAngleLog_" + fileId + ".bin"; // Create log files with these names midiInputController_.createLogFile(midiLogFileName, loggingDirectory_); touchkeyController_.createLogFiles(keyTouchLogFileName, analogLogFileName, loggingDirectory_); // Enable logging from each controller midiInputController_.startLogging(); touchkeyController_.startLogging(); loggingActive_ = true; } // Stop a currently running log. void MainApplicationController::stopLogging() { if(!loggingActive_) return; // stop logging data midiInputController_.stopLogging(); touchkeyController_.stopLogging(); // close the log files midiInputController_.closeLogFile(); touchkeyController_.closeLogFile(); loggingActive_ = false; } void MainApplicationController::setLoggingDirectory(const char *directory) { loggingDirectory_ = directory; } void MainApplicationController::playLogWithDialog() { if(isPlayingLog_) return; FileChooser tkChooser ("Select TouchKeys log...", File::nonexistent, // File::getSpecialLocation (File::userHomeDirectory), "*.bin"); if(tkChooser.browseForFileToOpen()) { FileChooser midiChooser ("Select MIDI log...", File::nonexistent, // File::getSpecialLocation (File::userHomeDirectory), "*.bin"); if(midiChooser.browseForFileToOpen()) { logPlayback_ = new LogPlayback(keyboardController_, midiInputController_); if(logPlayback_ == 0) return; if(logPlayback_->openLogFiles(tkChooser.getResult().getFullPathName().toRawUTF8(), midiChooser.getResult().getFullPathName().toRawUTF8())) { logPlayback_->startPlayback(); isPlayingLog_ = true; #ifndef TOUCHKEYS_NO_GUI // Always show 88 keys for log playback since we won't know which keys were actually recorded keyboardDisplay_.setKeyboardRange(21, 108); if(keyboardDisplayWindow_ != 0) { keyboardDisplayWindow_->getConstrainer()->setFixedAspectRatio(keyboardDisplay_.keyboardAspectRatio()); juce::Rectangle<int> bounds = keyboardDisplayWindow_->getBounds(); if(bounds.getY() < 44) bounds.setY(44); keyboardDisplayWindow_->setBoundsConstrained(bounds); } showKeyboardDisplayWindow(); #endif } } } } void MainApplicationController::stopPlayingLog() { if(!isPlayingLog_) return; if(logPlayback_ != 0) { logPlayback_->stopPlayback(); logPlayback_->closeLogFiles(); delete logPlayback_; logPlayback_ = 0; } #ifndef TOUCHKEYS_NO_GUI keyboardDisplay_.clearAllTouches(); #endif midiInputController_.allNotesOff(); isPlayingLog_ = false; } // Add a new MIDI keyboard segment. This method also handles numbering of the segments MidiKeyboardSegment* MainApplicationController::midiSegmentAdd() { // For now, the segment counter increments with each new segment. Eventually, we could // consider renumbering every time a segment is removed so that we always have an index // 0-N which corresponds to the indexes within MidiInputController (and also the layout // of the tabs). MidiKeyboardSegment *newSegment = midiInputController_.addSegment(segmentCounter_, 12, 127); // Set up defaults newSegment->setModePassThrough(); newSegment->setPolyphony(8); newSegment->setVoiceStealingEnabled(false); newSegment->enableAllChannels(); newSegment->setOutputTransposition(0); newSegment->setUsesKeyboardPitchWheel(true); // Enable the MIDI output for this segment if it exists in the preferences loadMIDIOutputFromApplicationPreferences(segmentCounter_); // Enable standalone mode on the new segment if generally enabled if(touchkeyStandaloneModeEnabled_) newSegment->enableTouchkeyStandaloneMode(); segmentCounter_++; return newSegment; } // Remove a MIDI keyboard segment. void MainApplicationController::midiSegmentRemove(MidiKeyboardSegment *segment) { if(segment == 0) return; // Check if this segment uses a virtual output port. Right now, we have a unique // output per segment. If it does, then disable the virtual output port. int identifier = segment->outputPort(); if(midiOutputController_.enabledPort(identifier) == MidiOutputController::kMidiVirtualOutputPortNumber) midiOutputController_.disablePort(identifier); midiInputController_.removeSegment(segment); } // Enable one MIDI input port either as primary or auxiliary void MainApplicationController::enableMIDIInputPort(int portNumber, bool isPrimary) { midiInputController_.enablePort(portNumber, isPrimary); if(isPrimary) applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", midiInputController_.deviceName(portNumber)); else applicationProperties_.getUserSettings()->setValue("MIDIInputAuxiliary", midiInputController_.deviceName(portNumber)); } // Enable all available MIDI input ports, with one in particular selected as primary void MainApplicationController::enableAllMIDIInputPorts(int primaryPortNumber) { midiInputController_.enableAllPorts(primaryPortNumber); applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", midiInputController_.deviceName(primaryPortNumber)); applicationProperties_.getUserSettings()->setValue("MIDIInputAuxiliary", "__all__"); } // Disable a particular MIDI input port number // For now, the preferences for auxiliary ports don't update; could add a complete list of enabled aux ports void MainApplicationController::disableMIDIInputPort(int portNumber) { if(portNumber == selectedMIDIPrimaryInputPort()) applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", ""); midiInputController_.disablePort(portNumber); } // Disable the current primary MIDI input port void MainApplicationController::disablePrimaryMIDIInputPort() { applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", ""); midiInputController_.disablePrimaryPort(); } // Disable either all MIDI input ports or all auxiliary inputs void MainApplicationController::disableAllMIDIInputPorts(bool auxiliaryOnly) { applicationProperties_.getUserSettings()->setValue("MIDIInputAuxiliary", ""); if(!auxiliaryOnly) applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", ""); midiInputController_.disableAllPorts(auxiliaryOnly); } // Enable a particular MIDI output port, associating it with a segment void MainApplicationController::enableMIDIOutputPort(int identifier, int deviceNumber) { midiOutputController_.enablePort(identifier, deviceNumber); String zoneName = "MIDIOutputZone"; zoneName += identifier; applicationProperties_.getUserSettings()->setValue(zoneName, midiOutputController_.deviceName(deviceNumber)); } #ifndef JUCE_WINDOWS // Create a virtual (inter-application) MIDI output port void MainApplicationController::enableMIDIOutputVirtualPort(int identifier, const char *name) { midiOutputController_.enableVirtualPort(identifier, name); String zoneName = "MIDIOutputZone"; zoneName += identifier; String zoneValue = "__virtual__"; zoneValue += String(name); applicationProperties_.getUserSettings()->setValue(zoneName, zoneValue); } #endif // Disable a particular MIDI output port void MainApplicationController::disableMIDIOutputPort(int identifier) { String zoneName = "MIDIOutputZone"; zoneName += identifier; applicationProperties_.getUserSettings()->setValue(zoneName, ""); midiOutputController_.disablePort(identifier); } // Disable all MIDI output ports void MainApplicationController::disableAllMIDIOutputPorts() { std::vector<std::pair<int, int> > enabledPorts = midiOutputController_.enabledPorts(); for(int i = 0; i < enabledPorts.size(); i++) { // For each active zone, set output port to disabled in preferences String zoneName = "MIDIOutputZone"; zoneName += enabledPorts[i].first; applicationProperties_.getUserSettings()->setValue(zoneName, ""); } midiOutputController_.disableAllPorts(); } // Enable TouchKeys standalone mode void MainApplicationController::midiTouchkeysStandaloneModeEnable() { touchkeyStandaloneModeEnabled_ = true; // Go through all segments and enable standalone mode for(int i = 0; i < midiInputController_.numSegments(); i++) { midiInputController_.segment(i)->enableTouchkeyStandaloneMode(); } applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", "__standalone__"); } void MainApplicationController::midiTouchkeysStandaloneModeDisable() { touchkeyStandaloneModeEnabled_ = false; // Go through all segments and disable standalone mode for(int i = 0; i < midiInputController_.numSegments(); i++) { midiInputController_.segment(i)->disableTouchkeyStandaloneMode(); } if(applicationProperties_.getUserSettings()->getValue("MIDIInputPrimary") == "__standalone__") applicationProperties_.getUserSettings()->setValue("MIDIInputPrimary", ""); } // *** OSC device methods *** // Return whether OSC transmission is enabled bool MainApplicationController::oscTransmitEnabled() { return oscTransmitter_.enabled(); } // Set whether OSC transmission is enabled void MainApplicationController::oscTransmitSetEnabled(bool enable) { oscTransmitter_.setEnabled(enable); applicationProperties_.getUserSettings()->setValue("OSCTransmitEnabled", enable); } // Return whether raw frame transmission is enabled bool MainApplicationController::oscTransmitRawDataEnabled() { return touchkeyController_.transmitRawDataEnabled(); } // Set whether raw frame transmission is enabled void MainApplicationController::oscTransmitSetRawDataEnabled(bool enable) { touchkeyController_.setTransmitRawData(enable); applicationProperties_.getUserSettings()->setValue("OSCTransmitRawDataEnabled", enable); } // Return the addresses to which OSC messages are sent std::vector<lo_address> MainApplicationController::oscTransmitAddresses() { return oscTransmitter_.addresses(); } // Add a new address for sending OSC messages to int MainApplicationController::oscTransmitAddAddress(const char * host, const char * port, int proto) { int indexOfNewAddress = oscTransmitter_.addAddress(host, port, proto); if(indexOfNewAddress >= 0) { // Successfully added; update preferences String keyName = "OSCTransmitHost"; keyName += indexOfNewAddress; applicationProperties_.getUserSettings()->setValue(keyName, String(host)); keyName = "OSCTransmitPort"; keyName += indexOfNewAddress; applicationProperties_.getUserSettings()->setValue(keyName, String(port)); keyName = "OSCTransmitProtocol"; keyName += indexOfNewAddress; applicationProperties_.getUserSettings()->setValue(keyName, proto); } return indexOfNewAddress; } // Remove a particular OSC address from the send list void MainApplicationController::oscTransmitRemoveAddress(int index) { oscTransmitter_.removeAddress(index); // Remove this destination from the preferences, if it exists String keyName = "OSCTransmitHost"; keyName += index; if(applicationProperties_.getUserSettings()->containsKey(keyName)) { applicationProperties_.getUserSettings()->setValue(keyName, ""); keyName = "OSCTransmitPort"; keyName += index; applicationProperties_.getUserSettings()->setValue(keyName, ""); keyName = "OSCTransmitProtocol"; keyName += index; applicationProperties_.getUserSettings()->setValue(keyName, (int)0); } } // Remove all OSC addresses from the send list void MainApplicationController::oscTransmitClearAddresses() { oscTransmitter_.clearAddresses(); for(int index = 0; index < 16; index++) { // Go through and clear preferences for recent OSC hosts; // 16 hosts is a sanity check String keyName = "OSCTransmitHost"; keyName += index; if(applicationProperties_.getUserSettings()->containsKey(keyName)) { applicationProperties_.getUserSettings()->setValue(keyName, ""); keyName = "OSCTransmitPort"; keyName += index; applicationProperties_.getUserSettings()->setValue(keyName, ""); keyName = "OSCTransmitProtocol"; keyName += index; applicationProperties_.getUserSettings()->setValue(keyName, (int)0); } } } // OSC Input (receiver) methods // Enable or disable on the OSC receive, and report is status bool MainApplicationController::oscReceiveEnabled() { return oscReceiveEnabled_; } // Enable method returns true on success (false only if it was // unable to set the port) bool MainApplicationController::oscReceiveSetEnabled(bool enable) { applicationProperties_.getUserSettings()->setValue("OSCReceiveEnabled", enable); if(enable && !oscReceiveEnabled_) { oscReceiveEnabled_ = true; return oscReceiver_.setPort(oscReceivePort_); } else if(!enable && oscReceiveEnabled_) { oscReceiveEnabled_ = false; return oscReceiver_.setPort(0); } return true; } // Whether the OSC server is running (false means couldn't open port) bool MainApplicationController::oscReceiveRunning() { return oscReceiver_.running(); } // Get the current OSC receive port int MainApplicationController::oscReceivePort() { return oscReceivePort_; } // Set the current OSC receive port (returns true on success) bool MainApplicationController::oscReceiveSetPort(int port) { applicationProperties_.getUserSettings()->setValue("OSCReceivePort", port); oscReceivePort_ = port; return oscReceiver_.setPort(port); } // OSC handler method bool MainApplicationController::oscHandlerMethod(const char *path, const char *types, int numValues, lo_arg **values, void *data) { std::cout << path << endl; if(!strcmp(path, "/midi/noteon")) { if(touchkeyAutodetecting_ && numValues > 0) { // std::cout << "/midi/noteon\n"; // Found a MIDI note. Look for a unique touch on this pitch class to // determine which octave the keyboard is set to if(types[0] != 'i') return false; // Ill-formed message int midiNote = values[0]->i; if(midiNote < 0 || midiNote > 127) return false; // Go through each octave and see if a touch is present int midiTestNote = midiNote % 12; int count = 0; int lastFoundTouchNote = 0; while(midiTestNote <= 127) { if(keyboardController_.key(midiTestNote) != 0) { if(keyboardController_.key(midiTestNote)->touchIsActive()) { count++; lastFoundTouchNote = midiTestNote; } } midiTestNote += 12; } // We return success if exactly one note had a touch on this pitch class if(count == 1) { int noteDifference = lastFoundTouchNote - midiNote; int currentMinNote = touchkeyController_.lowestMidiNote(); // std::cout << "Found difference of " << noteDifference << std::endl; currentMinNote -= noteDifference; if(currentMinNote >= 0 && currentMinNote <= 127) { touchkeyController_.setLowestMidiNote(currentMinNote); applicationProperties_.getUserSettings()->setValue("TouchKeysLowestMIDINote", currentMinNote); } touchkeyDeviceStopAutodetecting(); } return false; // Others may still want to handle this message } } return false; } // Save the current settings to an XML file // Returns true on success bool MainApplicationController::savePresetToFile(const char *filename) { File outputFile(filename); return savePresetHelper(outputFile); } // Load settings from a saved XML file // Returns true on success bool MainApplicationController::loadPresetFromFile(const char *filename) { File inputFile(filename); return loadPresetHelper(inputFile); } #ifndef TOUCHKEYS_NO_GUI // Present the user with a Save dialog and then save the preset bool MainApplicationController::savePresetWithDialog() { FileChooser myChooser ("Save preset...", File::nonexistent, // File::getSpecialLocation (File::userHomeDirectory), "*.tkpreset"); if(myChooser.browseForFileToSave(true)) { File outputFile(myChooser.getResult()); return savePresetHelper(outputFile); } // User clicked cancel... return true; } // Present the user with a Load dialog and then save the preset bool MainApplicationController::loadPresetWithDialog() { FileChooser myChooser ("Select a preset...", File::nonexistent, // File::getSpecialLocation (File::userHomeDirectory), "*.tkpreset"); if(myChooser.browseForFileToOpen()) { return loadPresetHelper(myChooser.getResult()); } // User clicked cancel... return true; } #endif bool MainApplicationController::loadPresetHelper(File const& inputFile) { if(!inputFile.existsAsFile()) return false; // Load the XML element from the file and check that it is valid XmlDocument document(inputFile); ScopedPointer<XmlElement> mainElement(document.getDocumentElement()); if(mainElement == 0) return false; if(mainElement->getTagName() != "TouchKeysPreset") return false; XmlElement *segmentsElement = mainElement->getChildByName("KeyboardSegments"); if(segmentsElement == 0) return false; // Load the preset from this element bool result = midiInputController_.loadSegmentPreset(segmentsElement); // Enable any necessary MIDI outputs for(int i = 0; i < midiInputController_.numSegments(); i++) loadMIDIOutputFromApplicationPreferences(i); // Loading a preset won't set standalone mode; so re-enable it when finished // if needed if(touchkeyStandaloneModeEnabled_) { midiTouchkeysStandaloneModeEnable(); } return result; } bool MainApplicationController::savePresetHelper(File& outputFile) { XmlElement mainElement("TouchKeysPreset"); mainElement.setAttribute("format", "0.1"); XmlElement* segmentsElement = midiInputController_.getSegmentPreset(); mainElement.addChildElement(segmentsElement); bool result = mainElement.writeToFile(outputFile, ""); if(result) { applicationProperties_.getUserSettings()->setValue("LastSavedPreset", outputFile.getFullPathName()); } return result; } // Clear the current preset and restore default settings void MainApplicationController::clearPreset() { midiInputController_.removeAllSegments(); //midiOutputController_.disableAllPorts(); segmentCounter_ = 0; // Re-add a new segment, starting at 0 midiSegmentAdd(); } // Whether to automatically start the TouchKeys on startup bool MainApplicationController::getPrefsAutoStartTouchKeys() { if(!applicationProperties_.getUserSettings()->containsKey("StartupStartTouchKeys")) return false; return applicationProperties_.getUserSettings()->getBoolValue("StartupStartTouchKeys"); } void MainApplicationController::setPrefsAutoStartTouchKeys(bool autoStart) { applicationProperties_.getUserSettings()->setValue("StartupStartTouchKeys", autoStart); } // Whether to automatically detect the TouchKeys octave when they start bool MainApplicationController::getPrefsAutodetectOctave() { if(!applicationProperties_.getUserSettings()->containsKey("StartupAutodetectTouchKeysOctave")) return false; return applicationProperties_.getUserSettings()->getBoolValue("StartupAutodetectTouchKeysOctave"); } void MainApplicationController::setPrefsAutodetectOctave(bool autoDetect) { applicationProperties_.getUserSettings()->setValue("StartupAutodetectTouchKeysOctave", autoDetect); } // Which preset (if any) to load at startup void MainApplicationController::setPrefsStartupPresetNone() { applicationProperties_.getUserSettings()->setValue("StartupPreset", "__none__"); } bool MainApplicationController::getPrefsStartupPresetNone() { // By default, no prefs means no preset if(!applicationProperties_.getUserSettings()->containsKey("StartupPreset")) return true; if(applicationProperties_.getUserSettings()->getValue("StartupPreset") == "__none__") return true; return false; } void MainApplicationController::setPrefsStartupPresetVibratoPitchBend() { applicationProperties_.getUserSettings()->setValue("StartupPreset", "__vib_pb__"); } bool MainApplicationController::getPrefsStartupPresetVibratoPitchBend() { if(!applicationProperties_.getUserSettings()->containsKey("StartupPreset")) return false; if(applicationProperties_.getUserSettings()->getValue("StartupPreset") == "__vib_pb__") return true; return false; } void MainApplicationController::setPrefsStartupPresetLastSaved() { applicationProperties_.getUserSettings()->setValue("StartupPreset", "__last__"); } bool MainApplicationController::getPrefsStartupPresetLastSaved() { if(!applicationProperties_.getUserSettings()->containsKey("StartupPreset")) return false; if(applicationProperties_.getUserSettings()->getValue("StartupPreset") == "__last__") return true; return false; } void MainApplicationController::setPrefsStartupPreset(String const& path) { applicationProperties_.getUserSettings()->setValue("StartupPreset", path); } String MainApplicationController::getPrefsStartupPreset() { if(!applicationProperties_.getUserSettings()->containsKey("StartupPreset")) return ""; return applicationProperties_.getUserSettings()->getValue("StartupPreset"); } // Reset application preferences to defaults void MainApplicationController::resetPreferences() { // TODO: reset settings now, not after restart applicationProperties_.getUserSettings()->clear(); setPrefsStartupPresetVibratoPitchBend(); setPrefsAutodetectOctave(true); } // Load the current devices from a global preferences file void MainApplicationController::loadApplicationPreferences(){ PropertiesFile *props = applicationProperties_.getUserSettings(); if(props == 0) return; // A few first-time defaults if the properties file is missing if(props->getAllProperties().size() == 0) { resetPreferences(); } // Load TouchKeys settings if(props->containsKey("TouchKeysDevice")) { // TODO } if(props->containsKey("TouchKeysLowestMIDINote")) { int note = props->getIntValue("TouchKeysLowestMIDINote"); if(note >= 0 && note <= 127) touchkeyDeviceSetLowestMidiNote(note); } // Load MIDI input settings if(props->containsKey("MIDIInputPrimary")) { String deviceName = props->getValue("MIDIInputPrimary"); if(deviceName == "__standalone__") { midiTouchkeysStandaloneModeEnable(); } else { int index = midiInputController_.indexOfDeviceNamed(deviceName); // cout << "primary input id " << index << " name " << deviceName << endl; if(index >= 0) enableMIDIInputPort(index, true); } } if(props->containsKey("MIDIInputAuxiliary")) { String deviceName = props->getValue("MIDIInputAuxiliary"); int index = midiInputController_.indexOfDeviceNamed(deviceName); // cout << "aux input id " << index << " name " << deviceName << endl; if(index >= 0) enableMIDIInputPort(index, false); } // MIDI output settings are loaded when segments are created // OSC settings if(props->containsKey("OSCTransmitEnabled")) { bool enable = props->getBoolValue("OSCTransmitEnabled"); oscTransmitSetEnabled(enable); } if(props->containsKey("OSCTransmitRawDataEnabled")) { bool enable = props->getBoolValue("OSCTransmitRawDataEnabled"); oscTransmitSetRawDataEnabled(enable); } for(int i = 0; i < 16; i++) { String keyName = "OSCTransmitHost"; String host, port; int protocol = LO_UDP; keyName += i; if(props->containsKey(keyName)) { host = props->getValue(keyName); } else continue; keyName = "OSCTransmitPort"; keyName += i; if(props->containsKey(keyName)) { port = props->getValue(keyName); } else continue; keyName = "OSCTransmitProtocol"; keyName += i; if(props->containsKey(keyName)) { protocol = props->getIntValue(keyName); } // okay to go ahead without protocol; use default // Check for validity if(host != "" && port != "" && (protocol == LO_UDP || protocol == LO_TCP)) { oscTransmitter_.addAddress(host.toUTF8(), port.toUTF8(), protocol); } } if(props->containsKey("OSCReceiveEnabled")) { bool enable = props->getBoolValue("OSCReceiveEnabled"); oscReceiveSetEnabled(enable); } if(props->containsKey("OSCReceivePort")) { int port = props->getIntValue("OSCReceivePort"); if(port >= 1 && port <= 65535) oscReceiveSetPort(port); } } // Load the MIDI output device for a given zone void MainApplicationController::loadMIDIOutputFromApplicationPreferences(int zone) { PropertiesFile *props = applicationProperties_.getUserSettings(); String keyName = "MIDIOutputZone"; keyName += zone; if(props->containsKey(keyName)) { String output = props->getValue(keyName); if(output.startsWith("__virtual__")) { #ifndef JUCE_WINDOWS // Open virtual port with the name that follows String virtualPortName = output.substring(11); // length of "__virtual__" midiOutputController_.enableVirtualPort(zone, virtualPortName.toUTF8()); #endif } else { String deviceName = props->getValue(keyName); int index = midiOutputController_.indexOfDeviceNamed(deviceName); // cout << "zone " << zone << " id " << index << " name " << deviceName << endl; if(index >= 0) enableMIDIOutputPort(zone, index); } } } #ifdef ENABLE_TOUCHKEYS_SENSOR_TEST // Start testing the TouchKeys sensors. Returns true on success. bool MainApplicationController::touchkeySensorTestStart(const char *path, int firstKey) { #ifndef TOUCHKEYS_NO_GUI if(path == 0 || firstKey < touchkeyController_.lowestMidiNote()) return false; if(keyboardTesterDisplay_ != 0) return true; // First, close the existing device which stops the data autogathering closeTouchkeyDevice(); // Now reopen the TouchKeys device if(!touchkeyController_.openDevice(path)) { touchkeyErrorMessage_ = "Failed to open"; touchkeyErrorOccurred_ = true; return false; } // Next, see if a real TouchKeys device is present at the other end if(!touchkeyDeviceCheckForPresence()) { touchkeyErrorMessage_ = "Device not recognized"; touchkeyErrorOccurred_ = true; return false; } // Now, create the KeyboardTesterDisplay object which will handle processing // raw data and displaying the results. Also a new window to hold it. keyboardTesterDisplay_ = new KeyboardTesterDisplay(*this, keyboardController_); keyboardTesterDisplay_->setKeyboardRange(touchkeyController_.lowestKeyPresentMidiNote(), touchkeyController_.highestMidiNote()); keyboardTesterWindow_ = new GraphicsDisplayWindow("TouchKeys Sensor Test", *keyboardTesterDisplay_); // Start raw data gathering from the indicated key (converted to octave/key notation) int keyOffset = firstKey - touchkeyController_.lowestMidiNote(); if(keyOffset < 0) // Shouldn't happen... keyOffset = 0; if(!touchkeyController_.startRawDataCollection(keyOffset / 12, keyOffset % 12, 3, 2)) { touchkeyErrorMessage_ = "Failed to start"; touchkeyErrorOccurred_ = true; return false; } keyboardTesterWindow_->addToDesktop(keyboardTesterWindow_->getDesktopWindowStyleFlags() | ComponentPeer::windowHasCloseButton); keyboardTesterWindow_->setVisible(true); keyboardTesterWindow_->toFront(true); touchkeyErrorMessage_ = ""; touchkeyErrorOccurred_ = false; return true; #endif } // Stop testing the TouchKeys sensors void MainApplicationController::touchkeySensorTestStop() { #ifndef TOUCHKEYS_NO_GUI if(keyboardTesterDisplay_ == 0) return; // Stop raw data gathering first and close device touchkeyController_.stopAutoGathering(); touchkeyController_.closeDevice(); // Delete the testing objects delete keyboardTesterWindow_; delete keyboardTesterDisplay_; keyboardTesterWindow_ = 0; keyboardTesterDisplay_ = 0; touchkeyErrorMessage_ = ""; touchkeyErrorOccurred_ = false; #endif } // Is the sensor test running? bool MainApplicationController::touchkeySensorTestIsRunning() { #ifdef TOUCHKEYS_NO_GUI return false; #else return (keyboardTesterDisplay_ != 0); #endif } // Set the current key that is begin tested void MainApplicationController::touchkeySensorTestSetKey(int key) { #ifndef TOUCHKEYS_NO_GUI if(keyboardTesterDisplay_ == 0 || key < touchkeyController_.lowestMidiNote()) return; int keyOffset = key - touchkeyController_.lowestMidiNote(); if(keyOffset < 0) // Shouldn't happen... keyOffset = 0; touchkeyController_.rawDataChangeKeyAndMode(keyOffset / 12, keyOffset % 12, 3, 2); #endif } // Reset the testing state to all sensors off void MainApplicationController::touchkeySensorTestResetState() { #ifndef TOUCHKEYS_NO_GUI if(keyboardTesterDisplay_ == 0) return; for(int key = 0; key < 128; key++) keyboardTesterDisplay_->resetSensorState(key); #endif } #endif // ENABLE_TOUCHKEYS_SENSOR_TEST #ifdef ENABLE_TOUCHKEYS_FIRMWARE_UPDATE // Put TouchKeys controller board into bootloader mode, for receiving firmware updates // (supplied by a different utility) bool MainApplicationController::touchkeyJumpToBootloader(const char *path) { // First, close the existing device which stops the data autogathering closeTouchkeyDevice(); // Now reopen the TouchKeys device if(!touchkeyController_.openDevice(path)) { touchkeyErrorMessage_ = "Failed to open"; touchkeyErrorOccurred_ = true; return false; } touchkeyController_.jumpToBootloader(); // Set an "error" condition to display this message, and because // after jumping to bootloader mode, the device will not open properly // until it has been reset. touchkeyErrorMessage_ = "Firmware update mode"; touchkeyErrorOccurred_ = true; return true; } #endif // ENABLE_TOUCHKEYS_FIRMWARE_UPDATE // Return the name of a MIDI note given its number std::string MainApplicationController::midiNoteName(int noteNumber) { if(noteNumber < 0 || noteNumber > 127) return ""; char name[6]; #ifdef _MSC_VER _snprintf_s(name, 6, _TRUNCATE, "%s%d", kNoteNames[noteNumber % 12], (noteNumber / 12) - 1); #else snprintf(name, 6, "%s%d", kNoteNames[noteNumber % 12], (noteNumber / 12) - 1); #endif return name; } // Get the number of a MIDI note given its name int MainApplicationController::midiNoteNumberForName(std::string const& name) { // Any valid note name will have at least two characters if(name.length() < 2) return -1; // Find the pitch class first, then the octave int pitchClass = -1; int startIndex = 1; if(!name.compare(0, 2, "C#") || !name.compare(0, 2, "c#") || !name.compare(0, 2, "Db") || !name.compare(0, 2, "db")) { pitchClass = 1; startIndex = 2; } else if(!name.compare(0, 2, "D#") || !name.compare(0, 2, "d#") || !name.compare(0, 2, "Eb") || !name.compare(0, 2, "eb")) { pitchClass = 3; startIndex = 2; } else if(!name.compare(0, 2, "F#") || !name.compare(0, 2, "f#") || !name.compare(0, 2, "Gb") || !name.compare(0, 2, "gb")){ pitchClass = 6; startIndex = 2; } else if(!name.compare(0, 2, "G#") || !name.compare(0, 2, "g#") || !name.compare(0, 2, "Ab") || !name.compare(0, 2, "ab")){ pitchClass = 8; startIndex = 2; } else if(!name.compare(0, 2, "A#") || !name.compare(0, 2, "a#") || !name.compare(0, 2, "Bb") || !name.compare(0, 2, "bb")){ pitchClass = 10; startIndex = 2; } else if(!name.compare(0, 1, "C") || !name.compare(0, 1, "c")) pitchClass = 0; else if(!name.compare(0, 1, "D") || !name.compare(0, 1, "d")) pitchClass = 2; else if(!name.compare(0, 1, "E") || !name.compare(0, 1, "e")) pitchClass = 4; else if(!name.compare(0, 1, "F") || !name.compare(0, 1, "f")) pitchClass = 5; else if(!name.compare(0, 1, "G") || !name.compare(0, 1, "g")) pitchClass = 7; else if(!name.compare(0, 1, "A") || !name.compare(0, 1, "a")) pitchClass = 9; else if(!name.compare(0, 1, "B") || !name.compare(0, 1, "b")) pitchClass = 11; if(pitchClass < 0) // No valid note found return -1; int octave = atoi(name.substr(startIndex).c_str()); int noteNumber = (octave + 1) * 12 + pitchClass; if(noteNumber < 0 || noteNumber > 127) return -1; return noteNumber; } // ***** External OSC Control ***** bool MainApplicationOSCController::oscHandlerMethod(const char *path, const char *types, int numValues, lo_arg **values, void *data) { if(!strncmp(path, "/control", 8)) { // OSC messages that start with /touchkeys/control are used to control the operation of the // software and mappings // First check if the message belongs to one of the segments if(!strncmp(path, "/control/segment", 16) && strlen(path) > 16) { // Pick out which segment based on the following number: e.g. /control/segment0/... std::string subpath(&path[16]); int separatorLoc = subpath.find_first_of('/'); if(separatorLoc == std::string::npos || separatorLoc == subpath.length() - 1) { // Malformed input (no slash or it's the last character): ignore return false; } std::stringstream segmentNumberSStream(subpath.substr(0, separatorLoc)); int segmentNumber = 0; segmentNumberSStream >> segmentNumber; if(segmentNumber < 0) // Unknown segment number return false; // Pass this message onto the corresponding segment in MidiInputController // If the segment doesn't exist, it will return false. All further handling is // done within MidiInputController with its corresponding mutex locked so // the segments can't change while this message is processed. subpath = subpath.substr(separatorLoc); // Start at the '/' if(subpath == "/set-midi-out") { // Special case for setting the MIDI output, which is done in the main controller // rather than in the segment itself if(numValues >= 1) { if(types[0] == 'i') { MidiKeyboardSegment* segment = controller_.midiInputController_.segment(segmentNumber); if(segment == 0) oscControlTransmitResult(1); // Failure response else { if(values[0]->i < 0) { // Negative value means disable controller_.disableMIDIOutputPort(segment->outputPort()); } else { controller_.enableMIDIOutputPort(segment->outputPort(), values[0]->i); } oscControlTransmitResult(0); } } #ifndef JUCE_WINDOWS else if(types[0] == 's') { MidiKeyboardSegment* segment = controller_.midiInputController_.segment(segmentNumber); if(segment == 0) oscControlTransmitResult(1); // Failure response else { if(!strcmp(&values[0]->s, "virtual")) { char st[20]; snprintf(st, 20, "TouchKeys %d", segment->outputPort()); controller_.enableMIDIOutputVirtualPort(segment->outputPort(), st); oscControlTransmitResult(0); } } } #endif } } else { // All other segment messages are handled within MidiKeyboardSegment OscMessage* response = controller_.midiInputController_.oscControlMessageForSegment(segmentNumber, subpath.c_str(), types, numValues, values, data); if(response != 0) { // Add the right prefix to the response. If it is a simple result status, // then give it the generic prefix. Otherwise add the zone beforehand if(!strcmp(response->path(), "/result")) response->prependPath("/touchkeys/control"); else { char prefix[28]; #ifdef _MSC_VER _snprintf_s(prefix, 28, _TRUNCATE, "/touchkeys/control/segment%d", segmentNumber); #else snprintf(prefix, 28, "/touchkeys/control/segment%d", segmentNumber); #endif response->prependPath(prefix); } // Send the message and free it controller_.oscTransmitter_.sendMessage(response->path(), response->type(), response->message()); delete response; } } } else if(!strcmp(path, "/control/preset-load")) { // Load preset from file // Argument 0 is the path to the file if(numValues > 0) { if(types[0] == 's') { bool result = controller_.loadPresetFromFile(&values[0]->s); // Send back a message on success/failure oscControlTransmitResult(result == true ? 0 : 1); return true; } else if(types[0] == 'i') { // TODO: take a second form of the message which has a numerical // input for selecting presets } } return false; } else if(!strcmp(path, "/control/preset-save")) { // Save preset to file if(numValues > 0) { if(types[0] == 's') { bool result = controller_.savePresetToFile(&values[0]->s); // Send back a message on success/failure oscControlTransmitResult(result == true ? 0 : 1); return true; } else if(types[0] == 'i') { // TODO: take a second form of the message which has a numerical // input for selecting presets } } return false; } else if(!strcmp(path, "/control/preset-clear")) { // Clear everything in preset controller_.clearPreset(); oscControlTransmitResult(0); return true; } else if(!strcmp(path, "/control/tk-list-devices")) { // Return a list of TouchKeys devices OscMessage *response = OscTransmitter::createMessage("/touchkeys/control/tk-list-devices/result", "i", controller_.availableTouchkeyDevices().size(), LO_ARGS_END); vector<std::string> devices = controller_.availableTouchkeyDevices(); vector<string>::iterator it; for(it = devices.begin(); it != devices.end(); ++it) { lo_message_add_string(response->message(), it->c_str()); } controller_.oscTransmitter_.sendMessage(response->path(), response->type(), response->message()); delete response; return true; } else if(!strcmp(path, "/control/tk-start")) { // Start the TouchKeys device with the given path if(numValues > 0) { if(types[0] == 's') { char *device = &values[0]->s; bool result = controller_.touchkeyDeviceStartupSequence(device); oscControlTransmitResult(result == true ? 0 : 1); return true; } } } else if(!strcmp(path, "/control/tk-stop")) { // Stop TouchKeys if(controller_.touchkeyDeviceIsOpen()) { controller_.closeTouchkeyDevice(); oscControlTransmitResult(0); } else { // Not running, can't close oscControlTransmitResult(1); } return true; } else if(!strcmp(path, "/control/tk-set-lowest-midi-note")) { // Set TouchKeys octave such that the lowest key is at the // given note. Only 'C' notes are valid. if(numValues > 0) { if(types[0] == 'i') { int note = values[0]->i; if(note % 12 == 0 && note >= 12 && note < 127) { controller_.touchkeyDeviceSetLowestMidiNote(note); oscControlTransmitResult(0); } else { // Invalid note oscControlTransmitResult(1); } return true; } } } else if(!strcmp(path, "/control/tk-autodetect")) { // Autodetect lowest TouchKeys octave controller_.touchkeyDeviceAutodetectLowestMidiNote(); oscControlTransmitResult(0); return true; } else if(!strcmp(path, "/control/tk-autodetect-stop")) { // Stop autodetecting TouchKeys octave controller_.touchkeyDeviceStopAutodetecting(); oscControlTransmitResult(0); return true; } else if(!strcmp(path, "/control/list-midi-in")) { // List available MIDI input devices std::vector<std::pair<int, std::string> > midiInputs = controller_.availableMIDIInputDevices(); OscMessage *response = OscTransmitter::createMessage("/list-midi-in/result", "i", midiInputs.size(), LO_ARGS_END); std::vector<std::pair<int, std::string> >::iterator it; for(it = midiInputs.begin(); it != midiInputs.end(); ++it) { lo_message_add_int32(response->message(), it->first); lo_message_add_string(response->message(), it->second.c_str()); } controller_.oscTransmitter_.sendMessage(response->path(), response->type(), response->message()); delete response; return true; } else if(!strcmp(path, "/control/list-midi-out")) { // List available MIDI output devices std::vector<std::pair<int, std::string> > midiOutputs = controller_.availableMIDIOutputDevices(); OscMessage *response = OscTransmitter::createMessage("/list-midi-out/result", "i", midiOutputs.size(), LO_ARGS_END); std::vector<std::pair<int, std::string> >::iterator it; for(it = midiOutputs.begin(); it != midiOutputs.end(); ++it) { lo_message_add_int32(response->message(), it->first); lo_message_add_string(response->message(), it->second.c_str()); } controller_.oscTransmitter_.sendMessage(response->path(), response->type(), response->message()); delete response; return true; } else if(!strcmp(path, "/control/set-midi-in-keyboard")) { // Set MIDI input device for keyboard if(numValues > 0) { if(types[0] == 'i') { if(controller_.midiTouchkeysStandaloneModeIsEnabled()) controller_.midiTouchkeysStandaloneModeDisable(); if(values[0]->i < 0) { // Negative means disable controller_.disablePrimaryMIDIInputPort(); } else { controller_.enableMIDIInputPort(values[0]->i, true); } oscControlTransmitResult(0); return true; } else if(types[0] == 's') { if(!strncmp(&values[0]->s, "stand", 5)) { // Enable TouchKeys standalone mode in place of MIDI input controller_.disablePrimaryMIDIInputPort(); controller_.midiTouchkeysStandaloneModeEnable(); oscControlTransmitResult(0); return true; } } } } else if(!strcmp(path, "/control/set-midi-in-aux")) { // Set MIDI auxiliary input device if(numValues > 0) { if(types[0] == 'i') { controller_.disableAllMIDIInputPorts(true); if(values[0]->i >= 0) { // Negative values mean leave the port disabled controller_.enableMIDIInputPort(values[0]->i, false); } oscControlTransmitResult(0); return true; } } } else if(!strcmp(path, "/control/add-segment")) { // Add a new keyboard segment if(controller_.midiSegmentsCount() >= 8) { // Max of 8 segments possible oscControlTransmitResult(1); } else { controller_.midiSegmentAdd(); oscControlTransmitResult(0); } return true; } else if(!strcmp(path, "/control/delete-segment")) { // Remove a keyboard segment by number if(numValues > 0) { if(types[0] == 'i') { int segmentNumber = values[0]->i; bool result = controller_.midiInputController_.removeSegment(segmentNumber); oscControlTransmitResult(result == true ? 0 : 1); return true; } } } } return false; } // Send back an OSC message to indicate the result of a control command void MainApplicationOSCController::oscControlTransmitResult(int result) { controller_.oscTransmitter_.sendMessage("/touchkeys/control/result", "i", result, LO_ARGS_END); }