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ls_settings.ino
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ls_settings.ino
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/****************************** ls_settings: LinnStrument Settings ********************************
Copyright 2023 Roger Linn Design (https://www.rogerlinndesign.com)
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
***************************************************************************************************
These functions handle the changing of any of LinnStrument's panel settings.
**************************************************************************************************/
// These messages correspond to the scrolling texts that will be displayed by default when pressing
// the top-most row in global settings. Only the first 30 characters will be used.
const char* defaultAudienceMessages[16] = {
"LINNSTRUMENT",
"APPLAUSE",
"HA HA HA",
"SINGER SUCKS",
"WRONG NOTE",
"SMELLY NIGHTCLUB",
"HELLO",
"HELLO NEW YORK",
"HELLO LOS ANGELES",
"HELLO SAN FRANCISCO",
"HELLO LONDON",
"HELLO MUNICH",
"HELLO BRUSSELS",
"HELLO PARIS",
"HELLO TOKYO",
"HELLO BARCELONA"
};
// These arrays use the setLed encoding scheme where the color is bitshifted << 3 and ORed with the CellDisplay value
const byte CUSTOM_LEDS_PATTERN1[LED_LAYER_SIZE] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 25, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 25, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 25,
0, 25, 0, 0, 25, 0, 25, 0, 25, 0, 25, 0, 0, 25, 0, 0, 25, 0, 25, 0, 25, 0, 25, 0, 0, 25,
0, 25, 0, 0, 25, 0, 25, 0, 25, 0, 25, 0, 0, 25, 0, 0, 25, 0, 25, 0, 25, 0, 25, 0, 0, 25,
0, 25, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 25, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 25,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0
};
const byte CUSTOM_LEDS_PATTERN2[LED_LAYER_SIZE] = {
0, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0,
0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17,
0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73,
0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9,
0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49,
0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41,
0, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33,
0, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25, 0, 41, 0, 9, 0, 17, 33, 0, 49, 0, 73, 25
};
unsigned long tempoChangeTime = 0; // time of last touch for tempo change
void GlobalSettings::setSwitchAssignment(byte whichSwitch, byte assignment, boolean disableSame) {
if (Global.switchAssignment[whichSwitch] == assignment) {
if (disableSame) {
Global.switchAssignment[whichSwitch] = ASSIGNED_DISABLED;
}
}
else {
resetSwitchStates(whichSwitch);
Global.switchAssignment[whichSwitch] = assignment;
}
}
void switchSerialMode(boolean flag) {
if (controlModeActive) {
controlModeActive = false;
clearDisplay();
updateDisplay();
}
if (Device.operatingLowPower) {
Device.operatingLowPower = false;
applyLedInterval();
applyMidiInterval();
}
Device.serialMode = flag;
applySerialMode();
}
void applySerialMode() {
if (Device.serialMode) {
digitalWrite(35, HIGH);
digitalWrite(36, HIGH);
Serial.begin(115200);
Serial.flush();
}
else {
digitalWrite(35, LOW);
applyMidiIo();
}
}
void initializeStorage() {
byte bootblock = dueFlashStorage.read(0);
if (bootblock != 0) { // See if we need to boot from scratch
if (bootblock == 255) { // When a new firmware is uploaded, the first flash byte will be 255
switchSerialMode(true); // Start in serial mode after OS upgrade to be able to receive the settings
Device.serialMode = true;
firstTimeBoot = true;
}
else {
switchSerialMode(false); // Start in MIDI mode for all other bootblock values
Device.serialMode = false;
}
writeInitialProjectSettings();
writeSettingsToFlash(); // Store the initial default settings
dueFlashStorage.write(0, 0); // Zero out the firstTime location.
setDisplayMode(displayCalibration); // Automatically start calibration after firmware update.
initializeCalibrationSamples();
setLed(0, GLOBAL_SETTINGS_ROW, globalColor, cellOn);
controlButton = GLOBAL_SETTINGS_ROW;
}
else {
loadSettings(); // On subsequent startups, load settings from Flash
if (Device.calibrated) {
// if calibration data is not a plausible series of values, clear out
// all the calibration data and reset everything to defaults
// the validation is needed together with the CRC to weed out bad calibration
// data that could have been lingering from previous firmware versions
if (!validateAndHealCalibrationData()) {
initializeCalibrationData();
}
else if (!Device.calibrationHealed) {
uint32_t crc = calculateCalibrationCRC();
if (Device.calCrcCalculated) {
// if the calculated CRC doesn't match the stored one, clear out
// all the calibration data and reset everything to defaults
if (Device.calCrc != crc) {
initializeCalibrationData();
}
}
// calculate the CRC the first time the device starts up from a firmware
// that didn't calculate the CRC
else {
Device.calCrc = crc;
}
}
}
}
}
void storeSettings() {
if (!sequencerIsRunning()) {
Project.tempo = FXD4_TO_INT(fxd4CurrentTempo);
writeSettingsToFlash();
}
}
void writeAdaptivelyToFlash(uint32_t offset, byte* source, int length) {
// batch and slow down the flash storage in low power mode
if (Device.operatingLowPower) {
unsigned long now = millis();
// ensure that there's at least 50 milliseconds between refreshing the display lights and writing to flash
unsigned long displayModeDelta = calcTimeDelta(now, displayModeStart);
if (displayModeDelta < 50) {
delayUsec((50 - displayModeDelta) * 1000);
}
// write the configuration data
byte batchsize = 128;
int total = length;
int i = 0;
while (i+batchsize < total) {
dueFlashStorage.write(offset+i, source+i, batchsize);
i += batchsize;
delayUsec(100);
}
int remaining = total - i;
if (remaining > 0) {
dueFlashStorage.write(offset+i, source+i, remaining);
}
delayUsec(100);
}
// do the faster possible flash storage in regular power mode
else {
dueFlashStorage.write(offset, source, length);
}
}
void writeSettingsToFlash() {
DEBUGPRINT((2,"writeSettingsToFlash size="));
DEBUGPRINT((2,sizeof(Configuration)));
DEBUGPRINT((2," bytes"));
DEBUGPRINT((2,"\n"));
disableLedDisplay();
// read the marker to know which configuration version was last written successfully
byte marker = dueFlashStorage.read(SETTINGS_OFFSET);
// update the marker and the flash memory offset to now write to the other configuration version
// ensuring that the previous one remains coherent
uint32_t configOffset;
if (marker == 0) {
marker = 1;
configOffset = sizeof(Configuration);
}
else {
marker = 0;
configOffset = 0;
}
// write to flash, taking low power mode into account
writeAdaptivelyToFlash(SETTINGS_OFFSET+sizeof(unsigned long)+configOffset, (byte*)&config, sizeof(Configuration));
// write the marker after the configuration data so that this version becomes to latest coherent one
dueFlashStorage.write(SETTINGS_OFFSET, marker);
clearFullDisplay();
completelyRefreshLeds();
updateDisplay();
enableLedDisplay();
}
void loadSettings() {
// read the marker to know which configuration version was last written successfully
byte marker = dueFlashStorage.read(SETTINGS_OFFSET);
uint32_t configOffset = 0;
if (marker != 0) {
configOffset = sizeof(Configuration);
}
memcpy(&config, dueFlashStorage.readAddress(SETTINGS_OFFSET+sizeof(unsigned long)+configOffset), sizeof(Configuration));
}
void writeInitialProjectSettings() {
dueFlashStorage.write(PROJECTS_OFFSET, 0);
for (byte i = 0; i < PROJECT_INDEXES_COUNT; ++i) {
dueFlashStorage.write(PROJECT_INDEX_OFFSET(0, i), i);
dueFlashStorage.write(PROJECT_INDEX_OFFSET(1, i), i);
}
for (byte p = 0; p <= MAX_PROJECTS; ++p) {
writeProjectToFlashRaw(p);
}
}
void writeProjectToFlashRaw(byte project) {
// write to flash, taking low power mode into account
uint32_t projectOffset = PROJECTS_OFFSET + PROJECTS_MARKERS_SIZE + project * SINGLE_PROJECT_SIZE;
Project.tempo = FXD4_TO_INT(fxd4CurrentTempo);
writeAdaptivelyToFlash(projectOffset, (byte*)&Project, sizeof(SequencerProject));
}
void writeProjectToFlash(byte project) {
DEBUGPRINT((2,"writeProjectToFlash size="));
DEBUGPRINT((2,sizeof(SequencerProject)));
DEBUGPRINT((2," bytes"));
DEBUGPRINT((2,"\n"));
clearDisplayImmediately();
clearFullDisplay();
completelyRefreshLeds();
// read marker of the current index marker
byte marker = dueFlashStorage.read(PROJECTS_OFFSET);
// read the location of the temporary project storage
byte previousIndexes[PROJECT_INDEXES_COUNT];
memcpy(&previousIndexes, dueFlashStorage.readAddress(PROJECT_INDEX_OFFSET(marker, 0)), PROJECT_INDEXES_COUNT);
byte tmpIndex = previousIndexes[MAX_PROJECTS];
byte prjIndex = previousIndexes[project];
writeProjectToFlashRaw(tmpIndex);
// write the marker after the project data so that this version becomes to latest coherent one
byte newMarker = 1 - marker;
previousIndexes[project] = tmpIndex;
previousIndexes[MAX_PROJECTS] = prjIndex;
dueFlashStorage.write(PROJECT_INDEX_OFFSET(newMarker, 0), previousIndexes, PROJECT_INDEXES_COUNT);
dueFlashStorage.write(PROJECTS_OFFSET, newMarker);
updateDisplay();
}
void loadProject(byte project) {
// read the marker to know which configuration version was last written successfully
byte marker = dueFlashStorage.read(PROJECTS_OFFSET);
byte prjIndex = dueFlashStorage.read(PROJECT_INDEX_OFFSET(marker, project));
uint32_t projectOffset = PROJECTS_OFFSET + PROJECTS_MARKERS_SIZE + prjIndex * SINGLE_PROJECT_SIZE;
memcpy(&Project, dueFlashStorage.readAddress(projectOffset), sizeof(SequencerProject));
fxd4CurrentTempo = FXD4_FROM_INT(Project.tempo);
}
void applyPresetSettings() {
applyPitchCorrectHold();
applyLimitsForY();
applyLimitsForZ();
applyLimitsForVelocity();
applyMidiIo();
updateSplitMidiChannels(LEFT);
updateSplitMidiChannels(RIGHT);
}
void applyConfiguration() {
applyPresetSettings();
applySequencerSettings();
loadCustomLedLayer(getActiveCustomLedPattern());
}
void applySystemState() {
applyConfiguration();
applySerialMode();
}
void loadSettingsFromPreset(byte p) {
Device.lastLoadedPreset = p;
memcpy(&Global, &config.preset[p].global, sizeof(GlobalSettings));
memcpy(&Split[LEFT], &config.preset[p].split[LEFT], sizeof(SplitSettings));
memcpy(&Split[RIGHT], &config.preset[p].split[RIGHT], sizeof(SplitSettings));
applyPresetSettings();
}
void storeSettingsToPreset(byte p) {
memcpy(&config.preset[p].global, &Global, sizeof(GlobalSettings));
memcpy(&config.preset[p].split[LEFT], &Split[LEFT], sizeof(SplitSettings));
memcpy(&config.preset[p].split[RIGHT], &Split[RIGHT], sizeof(SplitSettings));
}
// The first time after new code is loaded into the Linnstrument, this sets the initial defaults of all settings.
// On subsequent startups, these values are overwritten by loading the settings stored in flash.
void initializeDeviceSettings() {
Device.version = 16;
Device.serialMode = false;
Device.sleepAnimationActive = false;
Device.sleepActive = false;
Device.sleepDelay = 0;
Device.sleepAnimationType = animationNone;
Device.operatingLowPower = false;
Device.otherHanded = false;
Device.splitHandedness = reversedBoth;
Device.minUSBMIDIInterval = DEFAULT_MIN_USB_MIDI_INTERVAL;
Device.midiThrough = false;
Device.lastLoadedPreset = -1;
Device.lastLoadedProject = -1;
Global.splitActive = false;
initializeAudienceMessages();
memcpy(&Device.customLeds[0][0], &CUSTOM_LEDS_PATTERN1[0], LED_LAYER_SIZE);
memcpy(&Device.customLeds[1][0], &CUSTOM_LEDS_PATTERN2[0], LED_LAYER_SIZE);
memset(&Device.customLeds[2][0], 0, LED_LAYER_SIZE);
}
void initializeAudienceMessages() {
for (byte msg = 0; msg < 16; ++msg) {
memset(Device.audienceMessages[msg], '\0', sizeof(Device.audienceMessages[msg]));
strncpy(Device.audienceMessages[msg], defaultAudienceMessages[msg], 30);
Device.audienceMessages[msg][30] = '\0';
}
}
void initializeNoteLights(GlobalSettings& g) {
g.activeNotes = 0;
// initialize accentNotes array. Starting with only C within each octave highlighted
for (byte count = 0; count < 12; ++count) {
g.accentNotes[count] = 1;
}
// initialize mainNotes array (all off).
for (byte count = 0; count < 12; ++count) {
g.mainNotes[count] = 0;
}
// Major
g.mainNotes[0] |= 1 << 0;
g.mainNotes[0] |= 1 << 2;
g.mainNotes[0] |= 1 << 4;
g.mainNotes[0] |= 1 << 5;
g.mainNotes[0] |= 1 << 7;
g.mainNotes[0] |= 1 << 9;
g.mainNotes[0] |= 1 << 11;
// Natural minor
g.mainNotes[1] |= 1 << 0;
g.mainNotes[1] |= 1 << 2;
g.mainNotes[1] |= 1 << 3;
g.mainNotes[1] |= 1 << 5;
g.mainNotes[1] |= 1 << 7;
g.mainNotes[1] |= 1 << 8;
g.mainNotes[1] |= 1 << 10;
// Harmonic minor
g.mainNotes[2] |= 1 << 0;
g.mainNotes[2] |= 1 << 2;
g.mainNotes[2] |= 1 << 3;
g.mainNotes[2] |= 1 << 5;
g.mainNotes[2] |= 1 << 7;
g.mainNotes[2] |= 1 << 8;
g.mainNotes[2] |= 1 << 11;
// Major Pentatonic
g.mainNotes[3] |= 1 << 0;
g.mainNotes[3] |= 1 << 2;
g.mainNotes[3] |= 1 << 4;
g.mainNotes[3] |= 1 << 7;
g.mainNotes[3] |= 1 << 9;
// Minor Pentatonic
g.mainNotes[4] |= 1 << 0;
g.mainNotes[4] |= 1 << 3;
g.mainNotes[4] |= 1 << 5;
g.mainNotes[4] |= 1 << 7;
g.mainNotes[4] |= 1 << 10;
// Major Blues
g.mainNotes[5] |= 1 << 0;
g.mainNotes[5] |= 1 << 3;
g.mainNotes[5] |= 1 << 4;
g.mainNotes[5] |= 1 << 7;
g.mainNotes[5] |= 1 << 9;
g.mainNotes[5] |= 1 << 10;
// Minor Blues
g.mainNotes[6] |= 1 << 0;
g.mainNotes[6] |= 1 << 3;
g.mainNotes[6] |= 1 << 5;
g.mainNotes[6] |= 1 << 6;
g.mainNotes[6] |= 1 << 7;
g.mainNotes[6] |= 1 << 10;
// Diminished
g.mainNotes[7] |= 1 << 0;
g.mainNotes[7] |= 1 << 2;
g.mainNotes[7] |= 1 << 3;
g.mainNotes[7] |= 1 << 5;
g.mainNotes[7] |= 1 << 6;
g.mainNotes[7] |= 1 << 8;
g.mainNotes[7] |= 1 << 9;
g.mainNotes[7] |= 1 << 11;
// Whole Tone
g.mainNotes[8] |= 1 << 0;
g.mainNotes[8] |= 1 << 2;
g.mainNotes[8] |= 1 << 4;
g.mainNotes[8] |= 1 << 6;
g.mainNotes[8] |= 1 << 8;
g.mainNotes[8] |= 1 << 10;
// Spanish (Phrygian Dominant)
g.mainNotes[9] |= 1 << 0;
g.mainNotes[9] |= 1 << 1;
g.mainNotes[9] |= 1 << 4;
g.mainNotes[9] |= 1 << 5;
g.mainNotes[9] |= 1 << 7;
g.mainNotes[9] |= 1 << 8;
g.mainNotes[9] |= 1 << 10;
// Gypsy (Hungarian Minor)
g.mainNotes[10] |= 1 << 0;
g.mainNotes[10] |= 1 << 2;
g.mainNotes[10] |= 1 << 3;
g.mainNotes[10] |= 1 << 6;
g.mainNotes[10] |= 1 << 7;
g.mainNotes[10] |= 1 << 8;
g.mainNotes[10] |= 1 << 10;
// Arabic (Major Locrian)
g.mainNotes[11] |= 1 << 0;
g.mainNotes[11] |= 1 << 2;
g.mainNotes[11] |= 1 << 4;
g.mainNotes[11] |= 1 << 5;
g.mainNotes[11] |= 1 << 6;
g.mainNotes[11] |= 1 << 8;
g.mainNotes[11] |= 1 << 10;
}
void initializeGuitarTuning(GlobalSettings& g) {
g.guitarTuning[0] = 30;
g.guitarTuning[1] = 35;
g.guitarTuning[2] = 40;
g.guitarTuning[3] = 45;
g.guitarTuning[4] = 50;
g.guitarTuning[5] = 55;
g.guitarTuning[6] = 59;
g.guitarTuning[7] = 64;
}
void initializeMidiSettings(byte split, PresetSettings& p) {
for (byte chan = 0; chan < 16; ++chan) {
focusCell[split][chan].col = 0;
focusCell[split][chan].row = 0;
}
p.split[split].midiMode = oneChannel;
p.split[split].midiChanPerRowReversed = false;
p.split[split].expressionForY = timbreCC74;
p.split[split].customCCForY = 74;
p.split[split].expressionForZ = loudnessPolyPressure;
p.split[split].bendRangeOption = bendRange2;
p.split[split].customBendRange = 24;
p.split[split].mpe = false;
// initialize values that differ between the keyboard splits
if (split == LEFT) {
p.split[LEFT].midiChanMain = 1;
p.split[LEFT].midiChanMainEnabled = true;
p.split[LEFT].midiChanSet[0] = false;
for (byte chan = 1; chan < 8; ++chan) {
p.split[LEFT].midiChanSet[chan] = true;
}
for (byte chan = 8; chan < 16; ++chan) {
p.split[LEFT].midiChanSet[chan] = false;
}
p.split[LEFT].midiChanPerRow = 1;
}
else if (split == RIGHT) {
p.split[RIGHT].midiChanMain = 16;
p.split[RIGHT].midiChanMainEnabled = true;
for (byte chan = 0; chan < 8; ++chan) {
p.split[RIGHT].midiChanSet[chan] = false;
}
for (byte chan = 8; chan < 15; ++chan) {
p.split[RIGHT].midiChanSet[chan] = true;
}
p.split[RIGHT].midiChanSet[15] = false;
p.split[RIGHT].midiChanPerRow = 9;
}
}
void initializePresetSettings() {
Global.splitActive = false;
for (byte n = 0; n < NUMPRESETS; ++n) {
presetBlinkStart[n] = 0;
PresetSettings& p = config.preset[n];
GlobalSettings& g = p.global;
if (LINNMODEL == 200) {
g.splitPoint = 12;
}
else if (LINNMODEL == 128) {
g.splitPoint = 9;
}
g.currentPerSplit = LEFT;
g.rowOffset = 5;
g.customRowOffset = 12;
g.velocitySensitivity = velocityMedium;
g.minForVelocity = DEFAULT_MIN_VELOCITY;
g.maxForVelocity = DEFAULT_MAX_VELOCITY;
g.valueForFixedVelocity = DEFAULT_FIXED_VELOCITY;
g.pressureSensitivity = pressureMedium;
g.pressureAftertouch = false;
g.midiIO = 1; // set to 1 for USB jacks (not MIDI jacks)
// initialize switch settings
g.switchAssignment[SWITCH_FOOT_L] = ASSIGNED_ARPEGGIATOR;
g.switchAssignment[SWITCH_FOOT_R] = ASSIGNED_SUSTAIN;
g.switchAssignment[SWITCH_SWITCH_1] = ASSIGNED_SUSTAIN;
g.switchAssignment[SWITCH_SWITCH_2] = ASSIGNED_ARPEGGIATOR;
g.switchAssignment[SWITCH_FOOT_B] = ASSIGNED_DISABLED;
g.switchBothSplits[SWITCH_FOOT_L] = false;
g.switchBothSplits[SWITCH_FOOT_R] = false;
g.switchBothSplits[SWITCH_SWITCH_1] = false;
g.switchBothSplits[SWITCH_SWITCH_2] = false;
g.switchBothSplits[SWITCH_FOOT_B] = false;
g.ccForSwitchCC65[SWITCH_FOOT_L] = 65;
g.ccForSwitchCC65[SWITCH_FOOT_R] = 65;
g.ccForSwitchCC65[SWITCH_SWITCH_1] = 65;
g.ccForSwitchCC65[SWITCH_SWITCH_2] = 65;
g.ccForSwitchCC65[SWITCH_FOOT_B] = 65;
g.ccForSwitchSustain[SWITCH_FOOT_L] = 64;
g.ccForSwitchSustain[SWITCH_FOOT_R] = 64;
g.ccForSwitchSustain[SWITCH_SWITCH_1] = 64;
g.ccForSwitchSustain[SWITCH_SWITCH_2] = 64;
g.ccForSwitchSustain[SWITCH_FOOT_B] = 64;
g.customSwitchAssignment[SWITCH_FOOT_L] = ASSIGNED_TAP_TEMPO;
g.customSwitchAssignment[SWITCH_FOOT_R] = ASSIGNED_TAP_TEMPO;
g.customSwitchAssignment[SWITCH_SWITCH_1] = ASSIGNED_TAP_TEMPO;
g.customSwitchAssignment[SWITCH_SWITCH_2] = ASSIGNED_TAP_TEMPO;
g.customSwitchAssignment[SWITCH_FOOT_B] = ASSIGNED_SEQUENCER_PLAY;
initializeNoteLights(g);
initializeGuitarTuning(g);
g.arpDirection = ArpReplayAll;
g.arpTempo = ArpSixteenthSwing;
g.arpOctave = 0;
g.sustainBehavior = sustainHold;
// initialize all identical values in the keyboard split data
for (byte s = 0; s < NUMSPLITS; ++s) {
p.split[s].sendX = true;
p.split[s].sendY = true;
p.split[s].sendZ = true;
p.split[s].pitchCorrectQuantize = true;
p.split[s].pitchCorrectHold = true;
p.split[s].pitchResetOnRelease = false;
p.split[s].minForY = 0;
p.split[s].maxForY = 127;
p.split[s].relativeY = false;
p.split[s].initialRelativeY = 64;
p.split[s].minForZ = 0;
p.split[s].maxForZ = 127;
p.split[s].customCCForZ = 11;
p.split[s].ccForZ14Bit = false;
memcpy(&p.split[s].ccForFader, ccFaderDefaults, sizeof(unsigned short)*8);
p.split[s].colorAccent = COLOR_CYAN;
p.split[s].colorLowRow = COLOR_YELLOW;
p.split[s].colorSequencerEmpty = COLOR_YELLOW;
p.split[s].colorSequencerEvent = COLOR_ORANGE;
p.split[s].colorSequencerDisabled = COLOR_LIME;
p.split[s].playedTouchMode = playedCell;
p.split[s].lowRowCCXBehavior = lowRowCCHold;
p.split[s].ccForLowRow = 1;
p.split[s].lowRowCCXYZBehavior = lowRowCCHold;
p.split[s].ccForLowRowX = 16;
p.split[s].ccForLowRowY = 17;
p.split[s].ccForLowRowZ = 18;
p.split[s].transposeOctave = 0;
p.split[s].transposePitch = 0;
p.split[s].transposeLights = 0;
p.split[s].arpeggiator = false;
p.split[s].ccFaders = false;
p.split[s].strum = false;
p.split[s].sequencer = false;
}
// initialize values that differ between the keyboard splits
initializeMidiSettings(LEFT, p);
p.split[LEFT].colorMain = COLOR_GREEN;
p.split[LEFT].colorPlayed = COLOR_RED;
p.split[LEFT].lowRowMode = lowRowNormal;
p.split[LEFT].sequencerView = sequencerScales;
initializeMidiSettings(RIGHT, p);
p.split[RIGHT].colorMain = COLOR_BLUE;
p.split[RIGHT].colorPlayed = COLOR_MAGENTA;
p.split[RIGHT].lowRowMode = lowRowNormal;
p.split[RIGHT].sequencerView = sequencerScales;
}
// we're initializing the current settings with preset 0
memcpy(&config.settings, &config.preset[0], sizeof(PresetSettings));
// preset 0 is pre-programmed for one channel sounds from our Logic example file
config.preset[0].split[LEFT].midiMode = oneChannel;
config.preset[0].split[RIGHT].midiMode = oneChannel;
config.preset[0].split[LEFT].bendRangeOption = bendRange12;
config.preset[0].split[RIGHT].bendRangeOption = bendRange12;
config.preset[0].split[LEFT].expressionForZ = loudnessPolyPressure;
config.preset[0].split[RIGHT].expressionForZ = loudnessPolyPressure;
// preset 1 is pre-programmed for channel per note sounds from our Logic example file
config.preset[1].split[LEFT].midiMode = channelPerNote;
config.preset[1].split[RIGHT].midiMode = channelPerNote;
config.preset[1].split[LEFT].bendRangeOption = bendRange24;
config.preset[1].split[RIGHT].bendRangeOption = bendRange24;
config.preset[1].split[LEFT].customBendRange = 48;
config.preset[1].split[RIGHT].customBendRange = 48;
config.preset[1].split[LEFT].expressionForZ = loudnessChannelPressure;
config.preset[1].split[RIGHT].expressionForZ = loudnessChannelPressure;
config.preset[1].split[LEFT].midiChanMain = 1;
config.preset[1].split[LEFT].midiChanSet[0] = false;
config.preset[1].split[RIGHT].midiChanMain = 16;
config.preset[1].split[RIGHT].midiChanSet[15] = false;
// preset 3 is pre-programmed for making drumbeats
config.preset[3].split[LEFT].midiMode = channelPerNote;
config.preset[3].split[RIGHT].midiMode = oneChannel;
config.preset[3].split[LEFT].bendRangeOption = bendRange2;
config.preset[3].split[RIGHT].bendRangeOption = bendRange24;
config.preset[3].split[LEFT].pitchCorrectHold = pitchCorrectHoldOff;
config.preset[3].split[RIGHT].pitchCorrectHold = pitchCorrectHoldOff;
config.preset[3].split[LEFT].expressionForZ = loudnessChannelPressure;
config.preset[3].split[RIGHT].expressionForZ = loudnessChannelPressure;
config.preset[3].split[LEFT].lowRowMode = lowRowArpeggiator;
config.preset[3].split[RIGHT].lowRowMode = lowRowArpeggiator;
config.preset[3].split[LEFT].arpeggiator = true;
config.preset[3].split[RIGHT].arpeggiator = true;
config.preset[3].global.arpDirection = ArpReplayAll;
config.preset[3].global.arpTempo = ArpSixteenthSwing;
config.preset[3].global.splitActive = true;
// initialize runtime data
applyPitchCorrectHold();
applyLimitsForY();
applyLimitsForZ();
applyLimitsForVelocity();
for (byte s = 0; s < NUMSPLITS; ++s) {
for (byte c = 0; c < 129; ++c) {
ccFaderValues[s][c] = 0;
}
ccFaderValues[s][7] = 63;
currentEditedCCFader[s] = 0;
midiPreset[0] = 0;
arpTempoDelta[s] = 0;
splitChannels[s].clear();
}
}
void applyPitchCorrectHold() {
for (byte sp = 0; sp < NUMSPLITS; ++sp) {
switch (Split[sp].pitchCorrectHold) {
case pitchCorrectHoldOff:
{
fxdPitchHoldSamples[sp] = FXD_MAKE(PITCH_CORRECT_HOLD_SAMPLES_DEFAULT);
fxdRateXThreshold[sp] = FXD_MAKE(RATEX_THRESHOLD_DEFAULT);
break;
}
case pitchCorrectHoldFast:
{
fxdPitchHoldSamples[sp] = FXD_MAKE(PITCH_CORRECT_HOLD_SAMPLES_FAST);
fxdRateXThreshold[sp] = FXD_MAKE(RATEX_THRESHOLD_FAST);
break;
}
case pitchCorrectHoldMedium:
{
fxdPitchHoldSamples[sp] = FXD_MAKE(PITCH_CORRECT_HOLD_SAMPLES_MEDIUM);
fxdRateXThreshold[sp] = FXD_MAKE(RATEX_THRESHOLD_MEDIUM);
break;
}
case pitchCorrectHoldSlow:
{
fxdPitchHoldSamples[sp] = FXD_MAKE(PITCH_CORRECT_HOLD_SAMPLES_SLOW);
fxdRateXThreshold[sp] = FXD_MAKE(RATEX_THRESHOLD_SLOW);
break;
}
}
}
}
void setBendRange(byte split, byte bendRange) {
applyBendRange(Split[split], bendRange);
midiSendMpePitchBendRange(split);
}
void applyBendRange(SplitSettings& target, byte bendRange) {
switch (bendRange) {
case 2:
target.bendRangeOption = bendRange2;
break;
case 3:
target.bendRangeOption = bendRange3;
break;
case 12:
target.bendRangeOption = bendRange12;
break;
default:
target.bendRangeOption = bendRange24;
target.customBendRange = bendRange;
break;
}
}
void applyLimitsForY() {
for (byte sp = 0; sp < NUMSPLITS; ++sp) {
int32_t fxd_range = FXD_FROM_INT(Split[sp].maxForY - Split[sp].minForY);
fxdLimitsForYRatio[sp] = FXD_DIV(fxd_range, FXD_CONST_127);
}
}
void applyLimitsForZ() {
for (byte sp = 0; sp < NUMSPLITS; ++sp) {
int32_t fxd_range = FXD_FROM_INT(Split[sp].maxForZ - Split[sp].minForZ);
fxdLimitsForZRatio[sp] = FXD_DIV(fxd_range, FXD_CONST_127);
}
}
void applyLimitsForVelocity() {
fxdMinVelOffset = FXD_FROM_INT(Global.minForVelocity * 8);
int32_t fxd_maxVelOffset = FXD_CONST_1016 - FXD_FROM_INT(Global.maxForVelocity * 8);
fxdVelRatio = FXD_DIV(FXD_CONST_1016 - fxdMinVelOffset - fxd_maxVelOffset, FXD_CONST_1016);
}
// Called to handle press events of the 8 control buttons
void handleControlButtonNewTouch() {
// if we're in the startup phase after a global reset
// a new press on a control button terminates the global reset state
// and makes sure that startup control button combination is reset
if (globalReset) {
globalReset = false;
cellTouched(0, 0, untouchedCell);
cellTouched(0, 2, untouchedCell);
}
// allow the sequencer to short-circuit the control button new touch
if (handleSequencerControlButtonNewTouch()) {
lastControlPress[sensorRow] = millis();
return;
}
// only allow one control button to be pressed at the same time
// this prevents phantom presses to occur for the control buttons
// this is not detectable with the regular phantom press algorithm
if ((rowsInColsTouched[0] & ~(1 << sensorRow)) != 0) {
return;
}
if (sensorRow != SWITCH_1_ROW &&
sensorRow != SWITCH_2_ROW) { // handle non-switch control buttons
if (sensorRow == SPLIT_ROW) { // the split control has custom toggle / hold behavior
if (controlButton != -1) {
return;
}
}
else if (controlButton == sensorRow) { // detect whether this is the toggle off of a previous control press
lastControlPress[sensorRow] = 0;
handleControlButtonRelease(); // in that case act as if it was a button release
return;
}
else if (controlButton != -1) { // automatically turn off the led of another previously pressed control button
clearLed(0, controlButton);
}
controlButton = sensorRow; // keep track of which control button we're handling
}
// determine whether a double-tap happened on the switch (ie. second tap within 500 ms)
boolean doubleTap = (calcTimeDelta(millis(), lastControlPress[sensorRow]) < 500);
lastControlPress[sensorRow] = millis(); // keep track of the last press
switch (sensorRow) { // which control button is it?
case GLOBAL_SETTINGS_ROW: // global settings button presssed
resetAllTouches();
lightLed(0, 0); // light the button
setDisplayMode(displayGlobal); // change to global settings display mode
resetNumericDataChange();
updateDisplay();
break;
case SPLIT_ROW: // SPLIT button pressed
resetAllTouches();
splitButtonDown = true;
changedSplitPoint = false;
setDisplayMode(displaySplitPoint);
// handle double-tap
if (doubleTap) {
Global.currentPerSplit = otherSplit(Global.currentPerSplit);
}
updateDisplay();
break;
case SWITCH_2_ROW: // SWITCH 2 pressed
doSwitchPressed(SWITCH_SWITCH_2);
updateSwitchLeds();
break;
case SWITCH_1_ROW: // SWITCH 1 pressed
if (isSequencerSettingsDisplayMode()) {
setDisplayMode(displayNormal);
cellTouched(ignoredCell);
updateDisplay();
updateSwitchLeds();
}
else if (displayMode == displayCustomLedsEditor) {
customLedColor = colorCycle(customLedColor, false);
updateDisplay();
}
else {
doSwitchPressed(SWITCH_SWITCH_1);
updateSwitchLeds();
}
break;
case OCTAVE_ROW: // OCTAVE button pressed
resetAllTouches();
setLed(0, OCTAVE_ROW, globalColor, cellOn);
setDisplayMode(displayOctaveTranspose);
updateDisplay();
break;
case VOLUME_ROW: // displayVolume button pressed
resetAllTouches();
setLed(0, VOLUME_ROW, globalColor, cellOn);
setDisplayMode(displayVolume);
updateDisplay();
break;
case PRESET_ROW: // displayPreset button pressed
resetAllTouches();
setLed(0, PRESET_ROW, globalColor, cellOn);
for (byte p = 0; p < NUMPRESETS; ++p) {
presetBlinkStart[p] = 0;
}
setDisplayMode(displayPreset);
resetNumericDataChange();
updateDisplay();
break;
case PER_SPLIT_ROW: // PER SPLIT SETTINGs buttons pressed
resetAllTouches();
setLed(0, PER_SPLIT_ROW, globalColor, cellOn);
setDisplayMode(displayPerSplit);
resetNumericDataChange();
updateDisplay();
break;
}
}
// Called to handle release events of the 8 control buttons
void handleControlButtonRelease() {
// unless we pressed a new control button, no control button releases in global reset
// phase will be taken into account, this is needed to allow users to release the
// control button startup combination without leaving calibration mode
if (globalReset) {
return;
}
// allow the sequencer to short-circuit the control button touch release
if (handleSequencerControlButtonRelease()) {
return;
}
if (sensorRow != SWITCH_1_ROW &&
sensorRow != SWITCH_2_ROW) { // don't allow simultaneous control buttons except for the switches
if (controlButton != sensorRow || // only handle the release of the control button that's currently pressed
(calcTimeDelta(millis(), lastControlPress[sensorRow]) <= SWITCH_HOLD_DELAY && // however if this was not a hold press, don't process the release either
controlButton != SPLIT_ROW)) { // except for the split row, who has its own hold behavior
return;
}
controlButton = -1; // keep track of which control button we're handling
}
switch (sensorRow) {
// Most of the buttons, when released, revert the display to normal
// and save the global settings which may have been changed.
case GLOBAL_SETTINGS_ROW: // global settings button released
if (displayMode == displayReset) {
// ensure that MPE is actively disabled before resetting
disableMpe(LEFT);
disableMpe(RIGHT);
// reset all values to default
reset();
}
// fallthrough is on purpose
case PER_SPLIT_ROW:
case OCTAVE_ROW: // octave button released
case VOLUME_ROW: // volume button released
case PRESET_ROW: // preset button released
clearLed(0, sensorRow);
setDisplayMode(displayNormal);
storeSettings();
updateDisplay();
break;
case SPLIT_ROW: // SPLIT button released
if (Split[otherSplit(Global.currentPerSplit)].sequencer) {
Global.currentPerSplit = otherSplit(Global.currentPerSplit);
setLed(0, SPLIT_ROW, globalColor, Global.splitActive ? cellOn : cellOff);
updateDisplay();
}
else if (splitButtonDown) {
splitButtonDown = false;
if (changedSplitPoint) {
storeSettings();
}
else {
Global.splitActive = !Global.splitActive;
}
setLed(0, SPLIT_ROW, globalColor, Global.splitActive ? cellOn : cellOff);
setDisplayMode(displayNormal);
updateDisplay();
}