Update to support TGA Pro MKII (#14)

* Cleanup and fix issue with DMA transfers on T4 (#13) * Fix issue with max delay on external memory in AudioEffectAnalogDelay * Cleanup of tremolo and analog delay effects * Improved potentiometer getValue() function * Updated and tested examples with T4.0
4 years ago · 8bb56adfd3
parent 6f20a52ce7
commit 8bb56adfd3
30 changed files with 910 additions and 1088 deletions
--- a/examples/Basic/BA0_HelloAudioWorld/BA0_HelloAudioWorld.ino
+++ b/examples/Basic/BA0_HelloAudioWorld/BA0_HelloAudioWorld.ino
@ -0,0 +1,54 @@
 /*************************************************************************
 * This demo uses the BALibrary library to provide enhanced control of
 * the TGA Pro board.
 * 
 * The latest copy of the BA Guitar library can be obtained from
 * https://github.com/Blackaddr/BALibrary
 * 
 * This demo provides a very simple pass-through, clean audio example. 
 * This can be used to double checking everything is hooked up and working correctly.
 *
 * This example also demonstrates the bare minimum code necessary to pass audio
 * through the TGA Pro:
 *     - BAAudioControlWM8731 to enable and control the CODEC
 *     - AudioInputI2S to receive input audio from the CODEC (it's ADC)
 *     - AudioOutputI2S to send output audio to the CODEC (it's DAC)
 * 
 */
 #include <Audio.h>
 #include "BALibrary.h"
 using namespace BALibrary; // This prevents us having to put BALibrary:: in front of all the Blackaddr Audio components
 BAAudioControlWM8731 codecControl;
 AudioInputI2S        i2sIn;
 AudioOutputI2S       i2sOut;
 // Audio Connections: name(channel)
 // - Setup a mono signal chain, send the mono signal to both output channels in case you are using headphone
 // i2sIn(0) --> i2sOut(0)
 // i2sIn(1) --> i2sOut(1)
 AudioConnection      patch0(i2sIn, 0, i2sOut, 0);  // connect the cab filter to the output.
 AudioConnection      patch1(i2sIn, 0, i2sOut, 1); // connect the cab filter to the output.
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  delay(5); // wait a few ms to make sure the GTA Pro is fully powered up
  AudioMemory(48); // Provide an arbitrarily large number of audio buffers (48 blocks) for the effects (delays use a lot more than others)
  // If the codec was already powered up (due to reboot) power it down first
  codecControl.disable();
  delay(100);
  codecControl.enable();
  delay(100);
 }
 void loop() {  
  // The audio flows automatically through the Teensy Audio Library
 }
--- a/examples/Basic/BA4_TGA_Pro_delay_reverb/BA4_TGA_Pro_delay_reverb.ino
+++ b/examples/Basic/BA4_TGA_Pro_delay_reverb/BA4_TGA_Pro_delay_reverb.ino
@ -7,7 +7,12 @@
 * 
 * This demo provides an example guitar tone consisting of some slap-back delay,
 * followed by a reverb and a low-pass cabinet filter.
 *
 * This example uses very simple versions of these effects in the PJRC Audio
 * Library to make it a bit easier to learn how all this stuff works. More advanced
 * and better sounding effects are available from the Teensy Audio community.
 * 
 * A mild cab filter is used in case you are using headphones.
 */
 #include <Wire.h>
 #include <Audio.h>
@ -28,28 +33,39 @@ AudioMixer4              mixer; // Used to mix the original dry with the wet (ef
 AudioFilterBiquad        cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
-// Audio Connections
+// Audio Connections: name(channel)
 // - Setup a mono signal chain, send the mono signal to both output channels
 // - The reverb effect doesn't mix the dry signal, so we'll do that ourselves with the mixer effect.
 // - We need to reduce the gain into the reverb to prevent it's filters clipping
 // - mix the wet and the dry together, then send to a cabFilter then to the output.
 // i2sIn(0) --> mixer(0)
 // i2sIn(0) --> delayModule(0) --> gainModule(0) --> reverb(0) --> mixer(1)
 // mixer(0) --> cabFilter(0) --> i2sOut(1)
 AudioConnection      patchIn(i2sIn,0, delayModule, 0); // route the input to the delay
 AudioConnection      patch2(delayModule,0, gainModule, 0); // send the delay to the gain module
-AudioConnection      patch2b(gainModule, 0, reverb, 0); // then to the reverb
+AudioConnection      patch2b(gainModule, 0, reverb, 0);    // then to the reverb
-AudioConnection      patch1(i2sIn,0, mixer,0); // mixer input 0 is our original dry signal
+AudioConnection      patch1(i2sIn,0, mixer,0);  // mixer input 0 is our original dry signal
 AudioConnection      patch3(reverb, 0, mixer, 1); // mixer input 1 is our wet
 AudioConnection      patch4(mixer, 0, cabFilter, 0); // mixer outpt to the cabinet filter
-AudioConnection      patch5(cabFilter, 0, i2sOut, 0); // connect the cab filter to the output.
+AudioConnection      patch5(cabFilter, 0, i2sOut, 0);  // connect the cab filter to the output.
 AudioConnection      patch5b(cabFilter, 0, i2sOut, 1); // connect the cab filter to the output.
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  delay(5); // wait a few ms to make sure the GTA Pro is fully powered up
-  AudioMemory(48);
+  AudioMemory(48); // Provide an arbitrarily large number of audio buffers (48 blocks) for the effects (delays use a lot more than others)
-  // If the codec was already powered up (due to reboot) power itd own first
+  // If the codec was already powered up (due to reboot) power it down first
  codecControl.disable();
  delay(100);
  codecControl.enable();
@ -73,4 +89,3 @@ void loop() {
  // The audio flows automatically through the Teensy Audio Library
 }
--- a/examples/Basic/BA1_TGA_Pro_NOMEM_demo/BA1_TGA_Pro_NOMEM_demo.ino
+++ b/examples/Basic/BA1_TGA_Pro_NOMEM_demo/BA1_TGA_Pro_NOMEM_demo.ino
@ -1,106 +0,0 @@
 /*************************************************************************
 * This demo uses the BALibrary library to provide enhanced control of
 * the TGA Pro board.
 * 
 * The latest copy of the BA Guitar library can be obtained from
 * https://github.com/Blackaddr/BALibrary
 * 
 * This demo will provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BALibrary.h"
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BALibrary;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 // Audio Thru Connection
 AudioConnection      patch0(i2sIn,0, i2sOut, 0);
 AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codecControl;
 BAGpio                    gpio;  // access to User LED
 unsigned long t=0;
 void setup() {
  MIDI.begin(MIDI_CHANNEL_OMNI);
  Serial.begin(57600);
  delay(5);
  while (!Serial) { yield(); }
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(24);
  Serial.println("Enabling codec...\n");
  codecControl.enable();
  delay(100);
 }
 void loop() {  
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
  // Connect a loopback cable between the MIDI IN and MIDI OUT on the
  // GTA Pro.  This test code will periodically send MIDI events which
  // will loop back and get printed in the Serial Monitor.
  ///////////////////////////////////////////////////////////////////////
  DataByte note, velocity, channel, d1, d2;
  // Send MIDI OUT
  int cc, val=0xA, channelSend = 1;
  for (cc=32; cc<40; cc++) {
    MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
    delay(100);
    MIDI.sendNoteOn(10, 100, channelSend);
    delay(100);
  }
  if (MIDI.read()) {                    // Is there a MIDI message incoming ?
    MidiType type = MIDI.getType();
    Serial.println(String("MIDI IS WORKING!!!"));
    switch (type) {
      case NoteOn:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        if (velocity > 0) {
          Serial.println(String("Note On:  ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        } else {
          Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
        }
        break;
      case NoteOff:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        break;
      default:
        d1 = MIDI.getData1();
        d2 = MIDI.getData2();
        Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
    }
    t = millis();
  }
  if (millis() - t > 10000) {
    t += 10000;
    Serial.println("(no MIDI activity, check cables)");
  }
  // Toggle the USR LED state
  gpio.toggleLed();
 }
--- a/examples/Basic/BA2_TGA_Pro_1MEM/BA2_TGA_Pro_1MEM.ino
+++ b/examples/Basic/BA2_TGA_Pro_1MEM/BA2_TGA_Pro_1MEM.ino
@ -1,209 +0,0 @@
 /*************************************************************************
 * This demo uses the BALibrary library to provide enhanced control of
 * the TGA Pro board.
 * 
 * The latest copy of the BA Guitar library can be obtained from
 * https://github.com/Blackaddr/BALibrary
 * 
 * This demo will provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
 * It will also peform a sweep of SPI MEM0.
 * 
 * NOTE: SPI MEM0 can be used by a Teensy 3.1/3.2/3.5/3.6.
 * pins.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BALibrary.h"
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BALibrary;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 // Audio Thru Connection
 AudioConnection      patch0(i2sIn,0, i2sOut, 0);
 AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codecControl;
 BAGpio                    gpio;  // access to User LED
 BASpiMemory               spiMem0(SpiDeviceId::SPI_DEVICE0);
 unsigned long t=0;
 // SPI stuff
 unsigned spiAddress0 = 0;
 uint16_t spiData0 = 0xABCD;
 int spiErrorCount0 = 0;
 constexpr int mask0 = 0x5555;
 constexpr int mask1 = 0xaaaa;
 int maskPhase = 0;
 int loopPhase = 0;
 void setup() {
  MIDI.begin(MIDI_CHANNEL_OMNI);
  Serial.begin(57600);
  while (!Serial) { yield(); }
  delay(5);
  SPI_MEM0_1M(); // Set the Spi memory size to 1Mbit
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(24);
  Serial.println("Sketch: Enabling codec...\n");
  codecControl.enable();
  delay(100);
  Serial.println("Enabling SPI");
  spiMem0.begin();
 }
 int calcData(int spiAddress, int loopPhase, int maskPhase)
 {
  int data;
  int phase = ((loopPhase << 1) + maskPhase) & 0x3;
  switch(phase)
  {
    case 0 :
    data = spiAddress ^ mask0;
    break;
    case 1:
    data = spiAddress ^ mask1;
    break;
    case 2:
    data = ~spiAddress ^ mask0;
    break;
    case 3:
    data = ~spiAddress ^ mask1;
  }
  return (data & 0xffff);
 }
 void loop() {
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 0
  //////////////////////////////////////////////////////////////////
  maskPhase = 0;
  for (spiAddress0=0; spiAddress0 <= BAHardwareConfig.getSpiMemMaxAddr(0); spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress0, HEX);
    }
    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
    spiMem0.write16(spiAddress0, spiData0);
    maskPhase = (maskPhase+1) % 2;
  }
  Serial.println("SPI0 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 0
  ///////////////////////////////////////////////////////////////////
  spiErrorCount0 = 0;
  spiAddress0 = 0;
  maskPhase = 0;
  for (spiAddress0=0; spiAddress0 <= BAHardwareConfig.getSpiMemMaxAddr(0); spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
 //      Serial.print("Reading ");
 //      Serial.print(spiAddress0, HEX);
    }
    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
    int data = spiMem0.read16(spiAddress0);
    if (data != spiData0) {
      spiErrorCount0++;
      Serial.println("");
      Serial.print("ERROR MEM0: (expected) (actual):");
      Serial.print(spiData0, HEX); Serial.print(":");
      Serial.print(data, HEX);
      delay(100);
    }
    maskPhase = (maskPhase+1) % 2;
    if ((spiAddress0 % 32768) == 0) {
 //      Serial.print(", data = ");
 //      Serial.println(data, HEX);
 //      Serial.println(String(" loopPhase: ") + loopPhase + String(" maskPhase: ") + maskPhase);
    }
    // Break out of test once the error count reaches 10
    if (spiErrorCount0 > 10) { break; }
  }
  if (spiErrorCount0 == 0) { Serial.println("SPI0 TEST PASSED!!!"); }
  loopPhase = (loopPhase+1) % 2;
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
  // Connect a loopback cable between the MIDI IN and MIDI OUT on the
  // GTA Pro.  This test code will periodically send MIDI events which
  // will loop back and get printed in the Serial Monitor.
  ///////////////////////////////////////////////////////////////////////
  DataByte note, velocity, channel, d1, d2;
  // Send MIDI OUT
  int cc, val=0xA, channelSend = 1;
  for (cc=32; cc<40; cc++) {
    MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
    delay(100);
    MIDI.sendNoteOn(10, 100, channelSend);
    delay(100);
  }
  if (MIDI.read()) {                    // Is there a MIDI message incoming ?
    MidiType type = MIDI.getType();
    Serial.println(String("MIDI IS WORKING!!!"));
    switch (type) {
      case NoteOn:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        if (velocity > 0) {
          Serial.println(String("Note On:  ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        } else {
          Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
        }
        break;
      case NoteOff:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        break;
      default:
        d1 = MIDI.getData1();
        d2 = MIDI.getData2();
        Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
    }
    t = millis();
  }
  if (millis() - t > 10000) {
    t += 10000;
    Serial.println("(no MIDI activity, check cables)");
  }
  // Toggle the USR LED state
  gpio.toggleLed();
 }
--- a/examples/Basic/BA3_TGA_Pro_2MEM/BA3_TGA_Pro_2MEM.ino
+++ b/examples/Basic/BA3_TGA_Pro_2MEM/BA3_TGA_Pro_2MEM.ino
@ -1,271 +0,0 @@
 /*************************************************************************
 * This demo uses the BALibrary library to provide enhanced control of
 * the TGA Pro board.
 * 
 * The latest copy of the BA Guitar library can be obtained from
 * https://github.com/Blackaddr/BALibrary
 * 
 * This demo will provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
 * It will also peform a sweep of SPI MEM0 and MEM1.
 * 
 * NOTE: SPI MEM0 can be used by a Teensy 3.1/3.2/3.5/3.6.  SPI MEM1
 * can only be used by a Teensy 3.5/3.6 since it is mapped to the extended
 * pins.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BALibrary.h"
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BALibrary;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 // Audio Thru Connection
 AudioConnection      patch0(i2sIn,0, i2sOut, 0);
 AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codecControl;
 BAGpio                    gpio;  // access to User LED
 BASpiMemory               spiMem0(SpiDeviceId::SPI_DEVICE0);
 BASpiMemory               spiMem1(SpiDeviceId::SPI_DEVICE1);
 unsigned long t=0;
 // SPI stuff
 int spiAddress0 = 0;
 uint16_t spiData0 = 0xABCD;
 int spiErrorCount0 = 0;
 int spiAddress1 = 0;
 uint16_t spiData1 = 0xDCBA;
 int spiErrorCount1 = 0;
 constexpr int mask0 = 0x5555;
 constexpr int mask1 = 0xaaaa;
 int maskPhase = 0;
 int loopPhase = 0;
 void setup() {
  MIDI.begin(MIDI_CHANNEL_OMNI);
  Serial.begin(57600);
  while (!Serial) { yield(); }
  delay(5);
  // Set the SPI memory sizes
  SPI_MEM0_1M();
  SPI_MEM1_1M();
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(24);
  Serial.println("Sketch: Enabling codec...\n");
  codecControl.enable();
  delay(100);
  Serial.println("Enabling SPI");
  spiMem0.begin();
  spiMem1.begin();
 }
 int calcData(int spiAddress, int loopPhase, int maskPhase)
 {
  int data;
  int phase = ((loopPhase << 1) + maskPhase) & 0x3;
  switch(phase)
  {
    case 0 :
    data = spiAddress ^ mask0;
    break;
    case 1:
    data = spiAddress ^ mask1;
    break;
    case 2:
    data = ~spiAddress ^ mask0;
    break;
    case 3:
    data = ~spiAddress ^ mask1;
  }
  return (data & 0xffff);
 }
 void loop() {
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 0
  //////////////////////////////////////////////////////////////////
  maskPhase = 0;
  for (spiAddress0=0; spiAddress0 <= BAHardwareConfig.getSpiMemMaxAddr(0); spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress0, HEX);
    }
    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
    spiMem0.write16(spiAddress0, spiData0);
    maskPhase = (maskPhase+1) % 2;
  }
  Serial.println("SPI0 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 0
  ///////////////////////////////////////////////////////////////////
  spiErrorCount0 = 0;
  spiAddress0 = 0;
  maskPhase = 0;
  for (spiAddress0=0; spiAddress0 <= BAHardwareConfig.getSpiMemMaxAddr(0); spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
 //      Serial.print("Reading ");
 //      Serial.print(spiAddress0, HEX);
    }
    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
    int data = spiMem0.read16(spiAddress0);
    if (data != spiData0) {
      spiErrorCount0++;
      Serial.println("");
      Serial.print("ERROR MEM0: (expected) (actual):");
      Serial.print(spiData0, HEX); Serial.print(":");
      Serial.print(data, HEX);
      delay(100);
    }
    maskPhase = (maskPhase+1) % 2;
    if ((spiAddress0 % 32768) == 0) {
 //      Serial.print(", data = ");
 //      Serial.println(data, HEX);
 //      Serial.println(String(" loopPhase: ") + loopPhase + String(" maskPhase: ") + maskPhase);
    }
    // Break out of test once the error count reaches 10
    if (spiErrorCount0 > 10) { break; }
  }
  if (spiErrorCount0 == 0) { Serial.println("SPI0 TEST PASSED!!!"); }
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 1
  //////////////////////////////////////////////////////////////////
  maskPhase = 0;
  for (spiAddress1=0; spiAddress1 <= BAHardwareConfig.getSpiMemMaxAddr(1); spiAddress1+=2) {
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress1, HEX);
    }
    spiData1 = calcData(spiAddress1, loopPhase, maskPhase);
    spiMem1.write16(spiAddress1, spiData1);
    maskPhase = (maskPhase+1) % 2;
  }
  Serial.println("SPI1 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 1
  ///////////////////////////////////////////////////////////////////
  spiErrorCount1 = 0;
  spiAddress1 = 0;
  maskPhase = 0;
  for (spiAddress1=0; spiAddress1 <= BAHardwareConfig.getSpiMemMaxAddr(1); spiAddress1+=2) {
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print("Reading ");
      //Serial.print(spiAddress1, HEX);
    }
    spiData1 = calcData(spiAddress1, loopPhase, maskPhase);
    uint16_t data = spiMem1.read16(spiAddress1);
    if (data != spiData1) {
      spiErrorCount1++;
      Serial.println("");
      Serial.print("ERROR MEM1: (expected) (actual):");
      Serial.print(spiData1, HEX); Serial.print(":");
      Serial.println(data, HEX);
      delay(100);
    }
    maskPhase = (maskPhase+1) % 2;
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print(", data = ");
      //Serial.println(data, HEX);
    }
    // Break out of test once the error count reaches 10
    if (spiErrorCount1 > 10) { break; }
  }
  if (spiErrorCount1 == 0) { Serial.println("SPI1 TEST PASSED!!!"); }
  loopPhase = (loopPhase+1) % 2;
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
  // Connect a loopback cable between the MIDI IN and MIDI OUT on the
  // GTA Pro.  This test code will periodically send MIDI events which
  // will loop back and get printed in the Serial Monitor.
  ///////////////////////////////////////////////////////////////////////
  DataByte note, velocity, channel, d1, d2;
  // Send MIDI OUT
  int cc, val=0xA, channelSend = 1;
  for (cc=32; cc<40; cc++) {
    MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
    delay(100);
    MIDI.sendNoteOn(10, 100, channelSend);
    delay(100);
  }
  if (MIDI.read()) {                    // Is there a MIDI message incoming ?
    MidiType type = MIDI.getType();
    Serial.println(String("MIDI IS WORKING!!!"));
    switch (type) {
      case NoteOn:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        if (velocity > 0) {
          Serial.println(String("Note On:  ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        } else {
          Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
        }
        break;
      case NoteOff:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        break;
      default:
        d1 = MIDI.getData1();
        d2 = MIDI.getData2();
        Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
    }
    t = millis();
  }
  if (millis() - t > 10000) {
    t += 10000;
    Serial.println("(no MIDI activity, check cables)");
  }
  // Toggle the USR LED state
  gpio.toggleLed();
 }
--- a/examples/Delay/AnalogDelayDemo/AnalogDelayDemo.ino
+++ b/examples/Delay/AnalogDelayDemo/AnalogDelayDemo.ino
@ -15,11 +15,14 @@
 * Even if you don't control the guitar effect with USB MIDI, you must set
 * the Arduino IDE USB-Type under Tools to "Serial + MIDI"
 */
- #include <MIDI.h>
+#include <Audio.h>
 #include <MIDI.h>
 #include "BALibrary.h"
 #include "BAEffects.h"
 using namespace midi;
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace BAEffects;
 using namespace BALibrary;
@ -31,6 +34,7 @@ BAAudioControlWM8731 codec;
 // YOU MUST USE TEENSYDUINO 1.41 or greater
 // YOU MUST COMPILE THIS DEMO USING Serial + Midi
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 //#define USE_EXT // uncomment this line to use External MEM0
 #define MIDI_DEBUG // uncomment to see raw MIDI info in terminal
@ -53,18 +57,45 @@ AudioEffectAnalogDelay analogDelay(200.0f); // max delay of 200 ms or internal.
 // If you use external SPI memory you can get up to 1485.0f ms of delay!
 #endif
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Simply connect the input to the delay, and the output
 // to both i2s channels
 AudioConnection input(i2sIn,0, analogDelay,0);
 #if defined(USE_CAB_FILTER)
 AudioConnection delayOut(analogDelay, 0, cabFilter, 0);
 AudioConnection leftOut(cabFilter,0, i2sOut, 0);
 AudioConnection rightOut(cabFilter,0, i2sOut, 1);
 #else
 AudioConnection leftOut(analogDelay,0, i2sOut, 0);
 AudioConnection rightOut(analogDelay,0, i2sOut, 1);
 #endif
 elapsedMillis timer;
-int loopCount = 0;
+void OnControlChange(byte channel, byte control, byte value) {
  analogDelay.processMidi(channel-1, control, value);
  #ifdef MIDI_DEBUG
  Serial.print("Control Change, ch=");
  Serial.print(channel, DEC);
  Serial.print(", control=");
  Serial.print(control, DEC);
  Serial.print(", value=");
  Serial.print(value, DEC);
  Serial.println();
  #endif  
 }
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  #ifdef USE_EXT
  SPI_MEM0_4M();
  //SPI_MEM0_1M(); // use this line instead of you have the older 1Mbit memory
  #endif
  delay(100);
  Serial.begin(57600); // Start the serial port
@ -82,7 +113,6 @@ void setup() {
  // If using external memory request request memory from the manager
  // for the slot
  #ifdef USE_EXT
  SPI_MEM0_1M();
  Serial.println("Using EXTERNAL memory");
  // We have to request memory be allocated to our slot.
  externalSram.requestMemory(&delaySlot, 500.0f, MemSelect::MEM0, true);
@ -90,6 +120,12 @@ void setup() {
  Serial.println("Using INTERNAL memory");
  #endif
  // Setup MIDI
  MIDI.begin(MIDI_CHANNEL_OMNI);
  MIDI.setHandleControlChange(OnControlChange);
  usbMIDI.setHandleControlChange(OnControlChange);
  // Configure which MIDI CC's will control the effect parameters
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::BYPASS,16);
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::DELAY,20);
@ -116,53 +152,25 @@ void setup() {
  //analogDelay.setFilter(AudioEffectAnalogDelay::Filter::WARM); // A warm filter with a smooth frequency rolloff above 2Khz
  //analogDelay.setFilter(AudioEffectAnalogDelay::Filter::DARK); // A very dark filter, with a sharp rolloff above 1Khz
-  // Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
+#if defined(USE_CAB_FILTER)
  // Guitar cabinet: Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
-}
+#endif
 void OnControlChange(byte channel, byte control, byte value) {
  analogDelay.processMidi(channel, control, value);
  #ifdef MIDI_DEBUG
  Serial.print("Control Change, ch=");
  Serial.print(channel, DEC);
  Serial.print(", control=");
  Serial.print(control, DEC);
  Serial.print(", value=");
  Serial.print(value, DEC);
  Serial.println();
  #endif  
 }
 void loop() {
-  // usbMIDI.read() needs to be called rapidly from loop().  When
+  // usbMIDI.read() needs to be called rapidly from loop().
-  // each MIDI messages arrives, it return true.  The message must
+  
-  // be fully processed before usbMIDI.read() is called again.
+  if (timer > 1000) {
-
+    timer = 0;
  if (loopCount % 524288 == 0) {
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
    Serial.print(" analogDelay: "); Serial.print(analogDelay.processorUsage());
    Serial.println("%");
  }
-  loopCount++;
+
-
+  MIDI.read();
-  // check for new MIDI from USB
+  usbMIDI.read();
  if (usbMIDI.read()) {
    // this code entered only if new MIDI received
    byte type, channel, data1, data2, cable;
    type = usbMIDI.getType();       // which MIDI message, 128-255
    channel = usbMIDI.getChannel(); // which MIDI channel, 1-16
    data1 = usbMIDI.getData1();     // first data byte of message, 0-127
    data2 = usbMIDI.getData2();     // second data byte of message, 0-127
    Serial.println(String("Received a MIDI message on channel ") + channel);
    if (type == MidiType::ControlChange) {
      // if type is 3, it's a CC MIDI Message
      // Note: the Arduino MIDI library encodes channels as 1-16 instead
      // of 0 to 15 as it should, so we must subtract one.
      OnControlChange(channel-1, data1, data2);
    }
  }
 }
--- a/examples/Delay/AnalogDelayDemoExpansion/AnalogDelayDemoExpansion.ino
+++ b/examples/Delay/AnalogDelayDemoExpansion/AnalogDelayDemoExpansion.ino
@ -28,12 +28,13 @@
 using namespace BAEffects;
 using namespace BALibrary;
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 //#define USE_EXT // uncomment this line to use External MEM0
 AudioInputI2S i2sIn;
 AudioOutputI2S i2sOut;
 BAAudioControlWM8731 codec;
 //#define USE_EXT // uncomment this line to use External MEM0
 #ifdef USE_EXT
 // If using external SPI memory, we will instantiate a SRAM
 // manager and create an external memory slot to use as the memory
@ -53,15 +54,19 @@ AudioEffectAnalogDelay analogDelay(200.0f); // set the max delay of 200 ms.
 // If you use external SPI memory you can get up to 1485.0f ms of delay!
 #endif
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Simply connect the input to the delay, and the output
 // to both i2s channels
 AudioConnection input(i2sIn,0, analogDelay,0);
 #if defined(USE_CAB_FILTER)
 AudioConnection delayOut(analogDelay, 0, cabFilter, 0);
 AudioConnection leftOut(cabFilter,0, i2sOut, 0);
 AudioConnection rightOut(cabFilter,0, i2sOut, 1);
-
+#else
 AudioConnection leftOut(analogDelay,0, i2sOut, 0);
 AudioConnection rightOut(analogDelay,0, i2sOut, 1);
 #endif
 //////////////////////////////////////////
 // SETUP PHYSICAL CONTROLS
@ -83,7 +88,7 @@ constexpr bool potSwapDirection = true;
 // Blackaddr Audio Expansion Board.
 BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED);
-int loopCount = 0;
+elapsedMillis timer;
 unsigned filterIndex = 0; // variable for storing which analog filter we're currently using.
 constexpr unsigned MAX_HEADPHONE_VOL = 10;
 unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
@ -92,13 +97,21 @@ unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
 int bypassHandle, filterHandle, delayHandle, feedbackHandle, mixHandle, led1Handle, led2Handle; // Handles for the various controls
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  #ifdef USE_EXT
    SPI_MEM0_4M();
  //SPI_MEM0_1M(); // use this line instead of you have the older 1Mbit memory
  #endif
  delay(100); // wait a bit for serial to be available
  Serial.begin(57600); // Start the serial port
  delay(100);
  // Configure the hardware
-  SPI_MEM0_1M();
+  
  // Setup the controls. The return value is the handle to use when checking for control changes, etc.
  // pushbuttons
  bypassHandle = controls.addSwitch(BA_EXPAND_SW1_PIN); // will be used for bypass control
@ -137,6 +150,7 @@ void setup() {
  // Set some default values.
  // These can be changed using the controls on the Blackaddr Audio Expansion Board
  analogDelay.bypass(false);
  controls.setOutput(led1Handle, !analogDelay.isBypass()); // Set the LED when NOT bypassed  
  analogDelay.mix(0.5f);
  analogDelay.feedback(0.0f);
@ -147,9 +161,11 @@ void setup() {
  //analogDelay.setFilter(AudioEffectAnalogDelay::Filter::WARM); // A warm filter with a smooth frequency rolloff above 2Khz
  //analogDelay.setFilter(AudioEffectAnalogDelay::Filter::DARK); // A very dark filter, with a sharp rolloff above 1Khz
 #if defined(USE_CAB_FILTER)
  // Guitar cabinet: Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
 #endif
 }
 void loop() {
@ -213,14 +229,14 @@ void loop() {
    }
  }
-  // Use the loopCounter to roughly measure human timescales. Every few seconds, print the CPU usage
+  delay(20); // Without some minimal delay here it will be difficult for the pots/switch changes to be detected.
-  // to the serial port. About 500,000 loops!
+  
-  if (loopCount % 524288 == 0) {
+  if (timer > 1000) {
    timer = 0;
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
    Serial.print(" analogDelay: "); Serial.print(analogDelay.processorUsage());
    Serial.println("%");
  }
  loopCount++;
 }
--- a/examples/Delay/ExternalDelayDemo/ExternalDelayDemo.ino
+++ b/examples/Delay/ExternalDelayDemo/ExternalDelayDemo.ino
@ -49,17 +49,21 @@ AudioConnection  outputRight(delayMixer, 0, i2sOut, 1);
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  SPI_MEM0_4M();
  //SPI_MEM0_1M(); // use this line instead of you have the older 1Mbit memory
  Serial.begin(57600);
-  while(!Serial) { yield(); }
+  delay(200);
  AudioMemory(64);
  delay(500);
  Serial.println(String("Starting...\n"));
  delay(100);
  SPI_MEM0_1M(); // set the SPI MEM0 memory size
  // SPI_MEM1_1M(); // set the MEM1 memory aize
  Serial.println("Enabling codec...\n");
  codecControl.enable();
  delay(100);
--- a/examples/Delay/SoundOnSoundDemo/SoundOnSoundDemo.ino
+++ b/examples/Delay/SoundOnSoundDemo/SoundOnSoundDemo.ino
@ -11,32 +11,29 @@
 * the BAMidiTester to control the effect but it's best to use external MIDI footswitch
 * or the Blackaddr Audio Expansion Control Board.
 * 
- * Use must set the Arduino IDE USB-Type to "Serial + MIDI" in the Tools menu.
+ * User must set the Arduino IDE USB-Type to "Serial + MIDI" in the Tools menu.
 * 
 * Afters startup, the effect will spend about 5 seconds clearing the audio delay buffer to prevent
 * any startup pops or clicks from propagating.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
-#include <SPI.h>
+
 #include "BALibrary.h"
 #include "BAEffects.h"
-#include <midi_UsbTransport.h>
+/// IMPORTANT /////
-static const unsigned sUsbTransportBufferSize = 16;
+// YOU MUST USE TEENSYDUINO 1.41 or greater
-typedef midi::UsbTransport<sUsbTransportBufferSize> UsbTransport;
+// YOU MUST COMPILE THIS DEMO USING Serial + Midi
 UsbTransport sUsbTransport;
 MIDI_CREATE_INSTANCE(UsbTransport, sUsbTransport, uMIDI);
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 #define MIDI_DEBUG
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace BAEffects;
 #define MIDI_DEBUG
 using namespace BALibrary;
 AudioInputI2S i2sIn;
@ -54,9 +51,12 @@ AudioEffectSOS sos(&delaySlot);
 AudioEffectDelay         delayModule; // we'll add a little slapback echo
 AudioMixer4              gainModule; // This will be used simply to reduce the gain before the reverb
 AudioEffectReverb        reverb; // Add a bit of 'verb to our tone
 AudioFilterBiquad        cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 AudioMixer4 mixer;
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Connect the input
 AudioConnection inputToSos(i2sIn, 0, sos, 0);
 AudioConnection inputToSolo(i2sIn, 0, delayModule, 0);
@ -69,13 +69,17 @@ AudioConnection inputToReverb(gainModule, 0, reverb, 0);
 AudioConnection mixer0input(i2sIn, 0, mixer, 0);  // SOLO Dry Channel
 AudioConnection mixer1input(reverb, 0, mixer, 1); // SOLO Wet Channel
 AudioConnection mixer2input(sos, 0, mixer, 2); // SOS Channel
 AudioConnection inputToCab(mixer, 0, cabFilter, 0);
-// CODEC Outputs
+#if defined(USE_CAB_FILTER)
 AudioConnection inputToCab(mixer, 0, cabFilter, 0);
 AudioConnection outputLeft(cabFilter, 0, i2sOut, 0);
 AudioConnection outputRight(cabFilter, 0, i2sOut, 1);
 #else
 AudioConnection outputLeft(mixer, 0, i2sOut, 0);
 AudioConnection outputRight(mixer, 0, i2sOut, 1);
 #endif
-int loopCount = 0;
+elapsedMillis timer;
 void OnControlChange(byte channel, byte control, byte value) {
  sos.processMidi(channel-1, control, value);
@ -92,7 +96,14 @@ void OnControlChange(byte channel, byte control, byte value) {
 void setup() {
-delay(100);
+  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  SPI_MEM0_4M();
  //SPI_MEM0_1M(); // use this line instead of you have the older 1Mbit memory
  delay(100);
  Serial.begin(57600); // Start the serial port
  // Disable the codec first
@ -115,20 +126,19 @@ delay(100);
  // Setup MIDI
  MIDI.begin(MIDI_CHANNEL_OMNI);
  MIDI.setHandleControlChange(OnControlChange);
-  uMIDI.begin(MIDI_CHANNEL_OMNI);
+  usbMIDI.setHandleControlChange(OnControlChange);
  uMIDI.setHandleControlChange(OnControlChange);
  // Configure the LED to indicate the gate status
  sos.setGateLedGpio(USR_LED_ID);
  // Configure which MIDI CC's will control the effect parameters
-  sos.mapMidiControl(AudioEffectSOS::BYPASS,16);
+  //sos.mapMidiControl(AudioEffectSOS::BYPASS,16);
-  sos.mapMidiControl(AudioEffectSOS::CLEAR_FEEDBACK_TRIGGER,22);
+  sos.mapMidiControl(AudioEffectSOS::GATE_TRIGGER,16);
-  sos.mapMidiControl(AudioEffectSOS::GATE_TRIGGER,23);
+  sos.mapMidiControl(AudioEffectSOS::CLEAR_FEEDBACK_TRIGGER,17);
  sos.mapMidiControl(AudioEffectSOS::GATE_OPEN_TIME,20);
  sos.mapMidiControl(AudioEffectSOS::GATE_CLOSE_TIME,21);
-  sos.mapMidiControl(AudioEffectSOS::FEEDBACK,24);
+  sos.mapMidiControl(AudioEffectSOS::VOLUME,22);
-  sos.mapMidiControl(AudioEffectSOS::VOLUME,17);
+  //sos.mapMidiControl(AudioEffectSOS::FEEDBACK,24);
  // Besure to enable the delay. When disabled, audio is is completely blocked
  // to minimize resources to nearly zero.
@ -146,51 +156,34 @@ delay(100);
  gainModule.gain(0, 0.25); // the reverb unit clips easily if the input is too high
  delayModule.delay(0, 50.0f); // 50 ms slapback delay
 #if defined(USE_CAB_FILTER)
  // Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
 #endif
  // Setup the Mixer
  mixer.gain(0, 0.5f); // SOLO Dry gain
  mixer.gain(1, 0.5f); // SOLO Wet gain
  mixer.gain(1, 1.0f); // SOS gain
  delay(1000);
  sos.clear();
 }
 void loop() {
-  // usbMIDI.read() needs to be called rapidly from loop().  When
+  // usbMIDI.read() needs to be called rapidly from loop().
  // each MIDI messages arrives, it return true.  The message must
  // be fully processed before usbMIDI.read() is called again.
-  if (loopCount % 524288 == 0) {
+  if (timer > 1000) {
    timer = 0;
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
-    Serial.print(" sos: "); Serial.print(sos.processorUsage());
+    Serial.print(" SOS: "); Serial.print(sos.processorUsage());
    Serial.println("%");
  }
  loopCount++;
  MIDI.read();
-  uMIDI.read();
+  usbMIDI.read();
 //  // check for new MIDI from USB
 //  if (usbMIDI.read()) {
 //    // this code entered only if new MIDI received
 //    byte type, channel, data1, data2, cable;
 //    type = usbMIDI.getType();       // which MIDI message, 128-255
 //    channel = usbMIDI.getChannel(); // which MIDI channel, 1-16
 //    data1 = usbMIDI.getData1();     // first data byte of message, 0-127
 //    data2 = usbMIDI.getData2();     // second data byte of message, 0-127
 //    Serial.println(String("Received a MIDI message on channel ") + channel);
 //    
 //    if (type == MidiType::ControlChange) {
 //      // if type is 3, it's a CC MIDI Message
 //      // Note: the Arduino MIDI library encodes channels as 1-16 instead
 //      // of 0 to 15 as it should, so we must subtract one.
 //      OnControlChange(channel-1, data1, data2);
 //    }
 //  }
 }
--- a/examples/Delay/SoundOnSoundExpansionDemo/SoundOnSoundExpansionDemo.ino
+++ b/examples/Delay/SoundOnSoundExpansionDemo/SoundOnSoundExpansionDemo.ino
@ -13,6 +13,9 @@
 * 
 * The pots control the feedback, as well as the gate opening and close times.
 * 
 * Afters startup, the effect will spend about 5 seconds clearing the audio delay buffer to prevent
 * any startup pops or clicks from propagating.
 * 
 * POT1 - Gate open time. Middle position (detent) is about 2100 ms.
 * POT2 - gate close time. Middle position (detent) is about 2100 ms.
 * POT3 - Effect volume. Controls the volume of the SOS effect separate from the normal volume
@ -20,12 +23,15 @@
 * SW2 - Push this button to clear out the sound circulating in the delay.
 * 
 */
 #include <Audio.h> 
 #include "BALibrary.h"
 #include "BAEffects.h"
 using namespace BAEffects;
 using namespace BALibrary;
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 AudioInputI2S i2sIn;
 AudioOutputI2S i2sOut;
 BAAudioControlWM8731 codec;
@ -41,9 +47,12 @@ AudioEffectSOS sos(&delaySlot);
 AudioEffectDelay         delayModule; // we'll add a little slapback echo
 AudioMixer4              gainModule; // This will be used simply to reduce the gain before the reverb
 AudioEffectReverb        reverb; // Add a bit of 'verb to our tone
 AudioFilterBiquad        cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 AudioMixer4 mixer;
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Connect the input
 AudioConnection inputToSos(i2sIn, 0, sos, 0);
 AudioConnection inputToSolo(i2sIn, 0, delayModule, 0);
@ -56,11 +65,15 @@ AudioConnection inputToReverb(gainModule, 0, reverb, 0);
 AudioConnection mixer0input(i2sIn, 0, mixer, 0);  // SOLO Dry Channel
 AudioConnection mixer1input(reverb, 0, mixer, 1); // SOLO Wet Channel
 AudioConnection mixer2input(sos, 0, mixer, 2); // SOS Channel
 AudioConnection inputToCab(mixer, 0, cabFilter, 0);
-// CODEC Outputs
+#if defined(USE_CAB_FILTER)
 AudioConnection inputToCab(mixer, 0, cabFilter, 0);
 AudioConnection outputLeft(cabFilter, 0, i2sOut, 0);
 AudioConnection outputRight(cabFilter, 0, i2sOut, 1);
 #else
 AudioConnection outputLeft(mixer, 0, i2sOut, 0);
 AudioConnection outputRight(mixer, 0, i2sOut, 1);
 #endif
 //////////////////////////////////////////
 // SETUP PHYSICAL CONTROLS
@ -82,7 +95,7 @@ constexpr bool potSwapDirection = true;
 // Blackaddr Audio Expansion Board.
 BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED);
-int loopCount = 0;
+elapsedMillis timer;
 constexpr unsigned MAX_HEADPHONE_VOL = 10;
 unsigned headphoneVolume = MAX_HEADPHONE_VOL; // control headphone volume from 0 to 10.
 constexpr float MAX_GATE_TIME_MS = 4000.0f; // set maximum gate time of 4 seconds.
@ -93,11 +106,17 @@ int gateHandle, clearHandle, openHandle, closeHandle, volumeHandle, led1Handle,
 void setup() {
-delay(100);
+  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  SPI_MEM0_4M();
  //SPI_MEM0_1M(); // use this line instead of you have the older 1Mbit memory
  delay(100);
  delay(100); // wait a bit for serial to be available
  Serial.begin(57600); // Start the serial port
  delay(100); // wait a bit for serial to be available
  BAHardwareConfig.set(MemSelect::MEM0, SPI_MEMORY_1M);
  // Setup the controls. The return value is the handle to use when checking for control changes, etc.
  // pushbuttons
@ -115,9 +134,6 @@ delay(100);
  codec.disable();
  AudioMemory(128);
  TGA_PRO_EXPAND_REV2(); // Set the expansion board revision
  SPI_MEM0_1M(); // set the Spi memory size
  // Enable the codec
  Serial.println("Enabling codec...\n");
  codec.enable();
@ -130,7 +146,7 @@ delay(100);
  // by BAPhysicalControls
  sos.setGateLedGpio(BA_EXPAND_LED1_PIN);
-  // Besure to enable the delay. When disabled, audio is is completely blocked
+  // Besure to enable the SOS. When disabled, audio is is completely blocked
  // to minimize resources to nearly zero.
  sos.enable(); 
@ -146,19 +162,22 @@ delay(100);
  gainModule.gain(0, 0.25); // the reverb unit clips easily if the input is too high
  delayModule.delay(0, 50.0f); // 50 ms slapback delay
 #if defined(USE_CAB_FILTER)
  // Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
 #endif
  // Setup the Mixer
  mixer.gain(0, 0.5f); // SOLO Dry gain
  mixer.gain(1, 0.5f); // SOLO Wet gain
  mixer.gain(1, 1.0f); // SOS gain
  delay(1000);
  sos.clear();
 }
 void loop() {
  float potValue;
@ -215,12 +234,14 @@ void loop() {
      }
    }
  }
-  if (loopCount % 524288 == 0) {
+  
  delay(20); // Without some minimal delay here it will be difficult for the pots/switch changes to be detected.
  if (timer > 1000) {
    timer = 0;
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
-    Serial.print(" sos: "); Serial.print(sos.processorUsage());
+    Serial.print(" SOS: "); Serial.print(sos.processorUsage());
    Serial.println("%");
  }
  loopCount++;
 }
--- a/examples/Modulation/TemoloDemo/TemoloDemo.ino
+++ b/examples/Modulation/TemoloDemo/TemoloDemo.ino
@ -20,6 +20,8 @@
 #include "BAEffects.h"
 using namespace midi;
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace BAEffects;
 using namespace BALibrary;
@ -31,22 +33,46 @@ BAAudioControlWM8731 codec;
 // YOU MUST USE TEENSYDUINO 1.41 or greater
 // YOU MUST COMPILE THIS DEMO USING Serial + Midi
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 #define MIDI_DEBUG // uncomment to see raw MIDI info in terminal
 AudioEffectTremolo tremolo;
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Simply connect the input to the tremolo, and the output
 // to both i2s channels
 AudioConnection input(i2sIn,0, tremolo,0);
-AudioConnection tremoloOut(tremolo, 0, cabFilter, 0);
+#if defined(USE_CAB_FILTER)
 AudioConnection tremOut(tremolo, 0, cabFilter, 0);
 AudioConnection leftOut(cabFilter,0, i2sOut, 0);
 AudioConnection rightOut(cabFilter,0, i2sOut, 1);
 #else
 AudioConnection leftOut(tremolo,0, i2sOut, 0);
 AudioConnection rightOut(tremolo,0, i2sOut, 1);
 #endif
 elapsedMillis timer;
-int loopCount = 0;
+void OnControlChange(byte channel, byte control, byte value) {
  tremolo.processMidi(channel-1, control, value);
  #ifdef MIDI_DEBUG
  Serial.print("Control Change, ch=");
  Serial.print(channel, DEC);
  Serial.print(", control=");
  Serial.print(control, DEC);
  Serial.print(", value=");
  Serial.print(value, DEC);
  Serial.println();
  #endif  
 }
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  delay(100);
  Serial.begin(57600); // Start the serial port
@ -61,6 +87,11 @@ void setup() {
  codec.enable();
  delay(100);
  // Setup MIDI
  MIDI.begin(MIDI_CHANNEL_OMNI);
  MIDI.setHandleControlChange(OnControlChange);
  usbMIDI.setHandleControlChange(OnControlChange);
  // Configure which MIDI CC's will control the effect parameters
  tremolo.mapMidiControl(AudioEffectTremolo::BYPASS,16);
  tremolo.mapMidiControl(AudioEffectTremolo::RATE,20);
@ -78,53 +109,25 @@ void setup() {
  tremolo.bypass(false);
  tremolo.depth(0.5f); // 50% depth modulation
-  // Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
+#if defined(USE_CAB_FILTER)
  // Guitar cabinet: Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
-}
+#endif
 void OnControlChange(byte channel, byte control, byte value) {
  tremolo.processMidi(channel, control, value);
  #ifdef MIDI_DEBUG
  Serial.print("Control Change, ch=");
  Serial.print(channel, DEC);
  Serial.print(", control=");
  Serial.print(control, DEC);
  Serial.print(", value=");
  Serial.print(value, DEC);
  Serial.println();
  #endif  
 }
 void loop() {
-  // usbMIDI.read() needs to be called rapidly from loop().  When
+  // usbMIDI.read() needs to be called rapidly from loop().
  // each MIDI messages arrives, it return true.  The message must
  // be fully processed before usbMIDI.read() is called again.
-  if (loopCount % 524288 == 0) {
+  if (timer > 1000) {
    timer = 0;
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
    Serial.print(" tremolo: "); Serial.print(tremolo.processorUsage());
    Serial.println("%");
  }
-  loopCount++;
+
-
+  MIDI.read();
-  // check for new MIDI from USB
+  usbMIDI.read();
  if (usbMIDI.read()) {
    // this code entered only if new MIDI received
    byte type, channel, data1, data2, cable;
    type = usbMIDI.getType();       // which MIDI message, 128-255
    channel = usbMIDI.getChannel(); // which MIDI channel, 1-16
    data1 = usbMIDI.getData1();     // first data byte of message, 0-127
    data2 = usbMIDI.getData2();     // second data byte of message, 0-127
    Serial.println(String("Received a MIDI message on channel ") + channel);
    if (type == MidiType::ControlChange) {
      // if type is 3, it's a CC MIDI Message
      // Note: the Arduino MIDI library encodes channels as 1-16 instead
      // of 0 to 15 as it should, so we must subtract one.
      OnControlChange(channel-1, data1, data2);
    }
  }
 }
--- a/examples/Modulation/TremoloDemoExpansion/TremoloDemoExpansion.ino
+++ b/examples/Modulation/TremoloDemoExpansion/TremoloDemoExpansion.ino
@ -8,11 +8,12 @@
 * This example demonstrates teh BAAudioEffectsTremolo effect. It can
 * be controlled using the Blackaddr Audio "Expansion Control Board".
 * 
- * POT1 (left) controls amount of delay
+ * POT1 (left) controls the tremolo RATE
- * POT2 (right) controls amount of feedback
+ * POT2 (right) controls the tremolo DEPTH
- * POT3 (center) controls the wet/dry mix
+ * POT3 (center) controls the output VOLUME
 * SW1 will enable/bypass the audio effect. LED1 will be on when effect is enabled.
- * SW2 will cycle through the 3 pre-programmed analog filters. LED2 will be on when SW2 is pressed.
+ * SW2 will cycle through the 3 pre-programmed waveforms. NOTE: any waveform other than Sine will cause
 *     pops/clicks since the waveforms are not bandlimited.
 * 
 * 
 * Using the Serial Montitor, send 'u' and 'd' characters to increase or decrease
@ -25,20 +26,27 @@
 using namespace BAEffects;
 using namespace BALibrary;
 //#define USE_CAB_FILTER // uncomment this line to add a simple low-pass filter to simulate a cabinet if you are going straight to headphones
 AudioInputI2S i2sIn;
 AudioOutputI2S i2sOut;
 BAAudioControlWM8731 codec;
 AudioEffectTremolo tremolo;
 #if defined(USE_CAB_FILTER)
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 #endif
 // Simply connect the input to the delay, and the output
 // to both i2s channels
 AudioConnection input(i2sIn,0, tremolo,0);
-AudioConnection delayOut(tremolo, 0, cabFilter, 0);
+#if defined(USE_CAB_FILTER)
 AudioConnection tremOut(tremolo, 0, cabFilter, 0);
 AudioConnection leftOut(cabFilter,0, i2sOut, 0);
 AudioConnection rightOut(cabFilter,0, i2sOut, 1);
 #else
 AudioConnection leftOut(tremolo,0, i2sOut, 0);
 AudioConnection rightOut(tremolo,0, i2sOut, 1);
 #endif
 //////////////////////////////////////////
@ -61,7 +69,8 @@ constexpr bool potSwapDirection = true;
 // Blackaddr Audio Expansion Board.
 BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED);
-int loopCount = 0;
+elapsedMillis timer;
 unsigned waveformIndex = 0; // variable for storing which analog filter we're currently using.
 constexpr unsigned MAX_HEADPHONE_VOL = 10;
 unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
@ -70,12 +79,14 @@ unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
 int bypassHandle, waveformHandle, rateHandle, depthHandle, volumeHandle, led1Handle, led2Handle; // Handles for the various controls
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  delay(100); // wait a bit for serial to be available
  Serial.begin(57600); // Start the serial port
  delay(100);
  TGA_PRO_EXPAND_REV2(); // Configure the expansion board revision
  // Setup the controls. The return value is the handle to use when checking for control changes, etc.
  // pushbuttons
  bypassHandle = controls.addSwitch(BA_EXPAND_SW1_PIN); // will be used for bypass control
@ -104,6 +115,7 @@ void setup() {
  // Set some default values.
  // These can be changed using the controls on the Blackaddr Audio Expansion Board
  tremolo.bypass(false);
  controls.setOutput(led1Handle, !tremolo.isBypass()); // Set the LED when NOT bypassed  
  tremolo.rate(0.0f);
  tremolo.depth(1.0f);
@ -112,9 +124,11 @@ void setup() {
  // These are commented out, in this example we'll use SW2 to cycle through the different filters
  //tremolo.setWaveform(Waveform::SINE); // The default waveform
 #if defined(USE_CAB_FILTER)
  // Guitar cabinet: Setup 2-stages of LPF, cutoff 4500 Hz, Q-factor 0.7071 (a 'normal' Q-factor)
  cabFilter.setLowpass(0, 4500, .7071);
  cabFilter.setLowpass(1, 4500, .7071);
 #endif
 }
 void loop() {
@ -178,15 +192,14 @@ void loop() {
    }
  }
-  // Use the loopCounter to roughly measure human timescales. Every few seconds, print the CPU usage
+  delay(20); // Without some minimal delay here it will be difficult for the pots/switch changes to be detected.
-  // to the serial port. About 500,000 loops!
+  
-  //if (loopCount % 524288 == 0) {
+  if (timer > 1000) {
-  if (loopCount % 25000 == 0) {
+    timer = 0;
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
    Serial.print(" tremolo: "); Serial.print(tremolo.processorUsage());
    Serial.println("%");
  }
  loopCount++;
 }
--- a/examples/Tests/BAExpansionCalibrate/BAExpansionCalibrate.ino
+++ b/examples/Tests/BAExpansionCalibrate/BAExpansionCalibrate.ino
@ -8,6 +8,10 @@
 * This program can be used to find out the calibration values for each of your POTs
 * on the Blackaddr Audio Expansion Control Board.
 * 
 * Normally the default values used in the BALibrary are appropriate for the Expansion
 * Control Board, however you an use this program as a reference for calibrating pots
 * in a custom design.
 * 
 * USE THE ARDUINO SERIAL MONITOR TO PERFORM THE CALIBRATION
 * 
 * When prompted turn the appropriate POT in the specified direction and
@ -24,8 +28,11 @@ void setup() {
  delay(100);
  Serial.begin(57600);
  delay(500); // long delay to wait for Serial to init
  Serial.flush();
-  TGA_PRO_EXPAND_REV2(); // Set the expansion board revision
+  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  // put your setup code here, to run once:
  Serial.println("Calibrating POT1");
--- a/examples/Tests/MeasureNoise/MeasureNoise.ino
+++ b/examples/Tests/MeasureNoise/MeasureNoise.ino
@ -15,6 +15,8 @@
 * be useful for frequency detection but is not appropriate for when sound quality is desired as
 * the modulation of the filter will result in audible artifacts.
 * 
 * ALLOW THE TEST TO RUN THROUGH SEVERAL CYCLE of toggling the HPF so the CODEC can calibrate correctly.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
@ -39,6 +41,9 @@ AudioConnection      patchOutL(rmsModule, 0, i2sOut, 0); // connect the cab filt
 AudioConnection      patchOutR(rmsModule, 0, i2sOut, 1); // connect the cab filter to the output.
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  delay(5); // wait a few ms to make sure the GTA Pro is fully powered up
  AudioMemory(48);
--- a/examples/Tests/TGA_PRO_Basic_Test/PhysicalControls.cpp
+++ b/examples/Tests/TGA_PRO_Basic_Test/PhysicalControls.cpp
--- a/examples/Tests/TGA_PRO_Basic_Test/TGA_PRO_Basic_Test.ino
+++ b/examples/Tests/TGA_PRO_Basic_Test/TGA_PRO_Basic_Test.ino
@ -7,7 +7,6 @@
 * - Audio INPUT and OUTPUT JACKS
 * - Midi INPUT and Midi OUTPUT jacks
 * - MEM0 (if installed)
 * - MEM1 (if installed)
 * - User LED
 * 
 * This will also test the Expansion Control Board (if installed):
@ -42,9 +41,9 @@
 * 
 */
-//#define RUN_MIDI_TEST // Uncomment this line to run the MIDI test.
+//#define RUN_MIDI_TEST // Uncomment this line to run a MIDI test. You must connect a MIDI cable as a loopback between the MIDI input and output jacks.
-//#define RUN_MEMO_TEST // Uncomment this line to run the MEM0 test.
+//#define RUN_MEMO_TEST // Uncomment this line if you purchased the option SPI RAM.
-//#define RUN_MEM1_TEST // (Teensy 3.5/3/6 only!) Uncomment this line to run the MEM1 test.
+//#define RUN_EXP_TEST  // Uncomment if you purchased the Expansion Control Board
 #include <Audio.h>
 #include "BALibrary.h"
@ -61,6 +60,8 @@ AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codec;
 BAGpio                    gpio;  // access to User LED
 elapsedMillis timer;
 #if defined(RUN_MEMO_TEST)
 BASpiMemoryDMA spiMem0(SpiDeviceId::SPI_DEVICE0);
 #endif
@ -71,30 +72,38 @@ BASpiMemoryDMA spiMem1(SpiDeviceId::SPI_DEVICE1);
 // Create a control object using the number of switches, pots, encoders and outputs on the
 // Blackaddr Audio Expansion Board.
 #ifdef RUN_EXP_TEST
 BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED);
 void configPhysicalControls(BAPhysicalControls &controls, BAAudioControlWM8731 &codec);
 void checkPot(unsigned id);
 void checkSwitch(unsigned id);
 #endif
 bool spiTest(BASpiMemory *mem, int id); // returns true if passed
 bool uartTest();                   // returns true if passed
 unsigned loopCounter = 0;
 void setup() {
  TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
  //TGA_PRO_REVB(x);
  //TGA_PRO_REVA(x);
  Serial.begin(57600);
-  while (!Serial) { yield(); }
+  //while (!Serial) { yield(); }
  delay(500);
  // Disable the audio codec first
  codec.disable();
  delay(100);
-  AudioMemory(128);
+  AudioMemory(64);
  codec.enable();
  codec.setHeadphoneVolume(0.8f); // Set headphone volume
 #if defined(RUN_EXP_TEST)
  configPhysicalControls(controls, codec);
-
+  Serial.println("Now monitoring for input from Expansion Control Board");
-  TGA_PRO_EXPAND_REV2(); // Macro to declare expansion board revision
+#endif
  // Run the initial Midi connectivity and SPI memory tests.
 #if defined(RUN_MIDI_TEST)
@ -102,33 +111,28 @@ void setup() {
 #endif
 #if defined(RUN_MEMO_TEST)
-  SPI_MEM0_1M();
+  SPI_MEM0_4M(); // Declare the correct memory size
-  //SPI_MEM0_4M();
+  // SPI_MEM0_1M(); // older boards only had 1M memories 
  spiMem0.begin(); delay(10);
  if (spiTest(&spiMem0, 0)) { Serial.println("SPI0 testing PASSED!");}
 #endif
 #if defined(RUN_MEM1_TEST) && !defined(__IMXRT1062__)
  SPI_MEM1_1M();
  //SPI_MEM1_4M();
  spiMem1.begin(); delay(10);
  if (spiTest(&spiMem1, 1)) { Serial.println("SPI1 testing PASSED!");}
 #endif
  Serial.println("Now monitoring for input from Expansion Control Board");
 }
 void loop() {
  checkPot(0);
  checkPot(1);
  checkPot(2);
  checkSwitch(0);
  checkSwitch(1);
-  delay(20);
+  #if defined(RUN_EXP_TEST)
    checkPot(0);
    checkPot(1);
    checkPot(2);
    checkSwitch(0);
    checkSwitch(1);
  #endif
  delay(20); // Without some minimal delay here it will be difficult for the pots/switch changes to be detected.
  loopCounter++;
-  if ((loopCounter % 100) == 0) {
+  if (timer > 1000) {
-    gpio.toggleLed();
+    timer = 0;
    gpio.toggleLed(); // toggle the user LED every 1 second
  }
 }
--- a/examples/Tests/TGA_PRO_Basic_Test/UartTest.cpp
+++ b/examples/Tests/TGA_PRO_Basic_Test/UartTest.cpp
--- a/examples/Tests/TGA_PRO_Basic_Test/spiTest.cpp
+++ b/examples/Tests/TGA_PRO_Basic_Test/spiTest.cpp
--- a/src/BAGpio.h
+++ b/src/BAGpio.h
@ -67,6 +67,11 @@ public:
 	/// @returns the new stage of the user LED.
 	int toggleLed();
 	/// Convert the GPIO enum to the underlying logical pin number
 	/// @param gpio the enum value to convert
 	/// @returns the logical pin number for the GPIO
 	uint8_t enumToPinNumber(GPIO gpio);
 private:
 	uint8_t m_ledState;
 };
--- a/src/BAHardware.h
+++ b/src/BAHardware.h
@ -20,8 +20,8 @@
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
-#ifndef __BALIBRARY_BAHARDWARE_H
+#ifndef BALIBRARY_BAHARDWARE_H_
-#define __BALIBRARY_BAHARDWARE_H
+#define BALIBRARY_BAHARDWARE_H_
 #include <Arduino.h>
 #include <cstdint>
@ -32,30 +32,29 @@
 *****************************************************************************/
 namespace BALibrary {
 // In your Arudino .ino file, use #defines for your TGA Pro revision and options
 // to correctly configure your hardware
 #define TGA_PRO_REVA(x)        BALibrary::BAHardwareConfig.m_tgaBoard = TgaBoard::REV_A ///< Macro for specifying REV A of the TGA Pro
 #define TGA_PRO_REVB(x)        BALibrary::BAHardwareConfig.m_tgaBoard = TgaBoard::REV_B ///< Macro for specifying REV B of the TGA Pro
 #define TGA_PRO_EXPAND_REV2(x) BALibrary::BAHardwareConfig.m_expansionBoard = ExpansionBoard::REV_2 ///< Macro for specifying REV 2 of the Expansion Board
 #define SPI_MEM0_1M(x)         BALibrary::BAHardwareConfig.m_spiMem0 = SPI_MEMORY_1M ///< Macro for specifying MEM0 is 1Mbit
 #define SPI_MEM0_4M(x)         BALibrary::BAHardwareConfig.m_spiMem0 = SPI_MEMORY_4M ///< Macro for specifying MEM1 is 4Mbit
 #define SPI_MEM1_1M(x)         BALibrary::BAHardwareConfig.m_spiMem1 = SPI_MEMORY_1M ///< Macro for specifying MEM0 is 1Mbit
 #define SPI_MEM1_4M(x)         BALibrary::BAHardwareConfig.m_spiMem1 = SPI_MEMORY_4M ///< Macro for specifying MEM1 is 1Mbit
 /******************************************************************************
 * Hardware Configuration
 *****************************************************************************/
 /// enum to specify the TGA Board revision
 enum class TgaBoard : unsigned {
    REV_A = 0, ///< indicates using REV A of the TGA Pro
-    REV_B      ///< indicates using REV B of the TGA Pro
+    REV_B,     ///< indicates using REV B of the TGA Pro
    MKII_REV1, ///< indicates using MKII, Rev 1 of the TGA Pro
    AVALON
 };
 /// enum to specify the TGA Board revision
 enum class TeensyProcessor : unsigned {
    TEENSY3 = 0, ///< indicates using REV A of the TGA Pro
    TEENSY4,     ///< indicates using REV B of the TGA Pro
 };
 /// enum to specify the TGA Pro Expansion Board revision
 enum class ExpansionBoard : unsigned {
    NO_EXPANSION = 0, ///< default, indicates no expansion board is present
    REV_1,            ///< indicates using REV 1 of the Expansion Board
-    REV_2             ///< indicates using REV 2 of the Expansion Board
+    REV_2,            ///< indicates using REV 2 of the Expansion Board
    REV_3             ///< indicates using REV 3 of the Expansion Board (MKII Series)
 };
 /// enum to specify SPI memory dize
@ -66,6 +65,7 @@ enum class SpiMemorySize : unsigned {
 };
 constexpr unsigned NUM_MEM_SLOTS = 2; ///< The TGA Pro has two SPI ports for memory
 /// enum to specify MEM0 or MEM1
 enum MemSelect : unsigned {
    MEM0 = 0, ///< SPI RAM MEM0
@ -108,6 +108,22 @@ enum class SpiDeviceId : unsigned {
    SPI_DEVICE1 = 1  ///< Arduino SPI1 device
 };
 // GPIOs and Testpoints are accessed via enumerated class constants.
 enum class GPIO {
    GPIO0 = 0,
    GPIO1 = 1,
    GPIO2 = 2,
    GPIO3 = 3,
    GPIO4 = 4,
    GPIO5 = 5,
    GPIO6 = 6,
    GPIO7 = 7,
    TP1 = 8,
    TP2 = 9
 };
 /**************************************************************************//**
 * BAHardware is a global object that holds hardware configuration options for
 * board revisions and ordering options. It is created automatically, and only
@ -116,7 +132,7 @@ enum class SpiDeviceId : unsigned {
 *****************************************************************************/
 class BAHardware {
 public:
-    BAHardware() = default; ///< default constructor
+    BAHardware(); ///< default constructor
    /// sets the TGA Pro board revision
    /// @param tgaBoard enum to specify board revision
@ -126,6 +142,10 @@ public:
    /// @returns enum for the board revision
    TgaBoard getTgaBoard(void);
    /// get the configured Teensy Processor
    /// @returns enum for the processor
    TeensyProcessor getTeensyProcessor();
    /// sets the Expansion board revision
    /// @param expansionBoard enum to specify the expansion board revision
    void set(ExpansionBoard expansionBoard);
@ -163,75 +183,75 @@ public:
    /// @returns the last valid address location in the memory
    size_t getSpiMemMaxAddr  (unsigned memIndex);
-    TgaBoard       m_tgaBoard       = TgaBoard::REV_B; ///< stores the configured TGA Pro revision
+    TgaBoard            m_tgaBoard        = TgaBoard::MKII_REV1;              ///< stores the configured TGA Pro revision
-    ExpansionBoard m_expansionBoard = ExpansionBoard::NO_EXPANSION; ///< stores the configured Expansion Board revision
+    TeensyProcessor     m_teensyProcessor = TeensyProcessor::TEENSY4;   ///< store the processor in use
-    SpiMemoryDefinition m_spiMem0   = SPI_MEMORY_NONE; ///< stores the definition for MEM0
+    ExpansionBoard      m_expansionBoard  = ExpansionBoard::NO_EXPANSION; ///< stores the configured Expansion Board revision
-    SpiMemoryDefinition m_spiMem1   = SPI_MEMORY_NONE; ///< stores the definition for MEM1
+    SpiMemoryDefinition m_spiMem0         = SPI_MEMORY_NONE;              ///< stores the definition for MEM0
    SpiMemoryDefinition m_spiMem1         = SPI_MEMORY_NONE;              ///< stores the definition for MEM1
 };
 extern BAHardware BAHardwareConfig; ///< external definition of global configuration class object
-/**************************************************************************//**
+// In your Arudino .ino file, use #defines for your TGA Pro revision and options
- * Teensy 3.6/3.5 Hardware Pinout
+// to correctly configure your hardware
- *****************************************************************************/
+#define TGA_PRO_REVA(x)        BALibrary::BAHardwareConfig.set(TgaBoard::REV_A)     ///< Macro for specifying REV A of the TGA Pro
-#if defined(__MK66FX1M0__) || defined(__MK64FX512__) // T3.6 or T3.5
+#define TGA_PRO_REVB(x)        BALibrary::BAHardwareConfig.set(TgaBoard::REV_B)     ///< Macro for specifying REV B of the TGA Pro
-constexpr uint8_t USR_LED_ID = 16; ///< Teensy IO number for the user LED.
+#define TGA_PRO_MKII_REV1(x)   BALibrary::BAHardwareConfig.set(TgaBoard::MKII_REV1) ///< Macro for specifying REV B of the TGA Pro
 #define TGA_PRO_EXPAND_REV2(x) BALibrary::BAHardwareConfig.setExpansionBoard(ExpansionBoard::REV_2) ///< Macro for specifying REV 2 of the Expansion Board
 #define TGA_PRO_EXPAND_REV3(x) BALibrary::BAHardwareConfig.setExpansionBoard(ExpansionBoard::REV_3) ///< Macro for specifying REV 2 of the Expansion Board
 #define SPI_MEM0_1M(x)         BALibrary::BAHardwareConfig.set(MEM0, SPI_MEMORY_1M) ///< Macro for specifying MEM0 is 1Mbit
 #define SPI_MEM0_4M(x)         BALibrary::BAHardwareConfig.set(MEM0, SPI_MEMORY_4M) ///< Macro for specifying MEM1 is 4Mbit
 #define SPI_MEM1_1M(x)         BALibrary::BAHardwareConfig.set(MEM1, SPI_MEMORY_1M) ///< Macro for specifying MEM0 is 1Mbit
 #define SPI_MEM1_4M(x)         BALibrary::BAHardwareConfig.set(MEM1, SPI_MEMORY_4M) ///< Macro for specifying MEM1 is 1Mbit
 extern uint8_t USR_LED_ID; ///< Teensy IO number for the user LED.
 extern unsigned BA_EXPAND_NUM_POT;
 extern unsigned BA_EXPAND_NUM_SW;
 extern unsigned BA_EXPAND_NUM_LED;
 extern unsigned BA_EXPAND_NUM_ENC;
 extern uint8_t BA_EXPAND_POT1_PIN; // 14_A0_TX3_SPDIFOUT
 extern uint8_t BA_EXPAND_POT2_PIN; // 15_A1_RX3_SPDIFIN
 extern uint8_t BA_EXPAND_POT3_PIN; // 16_A2_RX4_SCL1
 extern uint8_t BA_EXPAND_SW1_PIN;  // 2_OUT2
 extern uint8_t BA_EXPAND_SW2_PIN;  // 3_LRCLK2
 extern uint8_t BA_EXPAND_LED1_PIN;  // 4_BLCK2
 extern uint8_t BA_EXPAND_LED2_PIN;  // 5_IN2
 extern uint8_t GPIO0;
 extern uint8_t GPIO1;
 extern uint8_t GPIO2;
 extern uint8_t GPIO3;
 extern uint8_t GPIO4;
 extern uint8_t GPIO5;
 extern uint8_t GPIO6;
 extern uint8_t GPIO7;
 extern uint8_t TP1;
 extern uint8_t TP2;
 // SPI0 and SPI1 pinouts
-constexpr uint8_t SPI0_SCK_PIN = 14;
+extern uint8_t SPI0_SCK_PIN;
-constexpr uint8_t SPI0_CS_PIN = 15;
+extern uint8_t SPI0_CS_PIN;
-constexpr uint8_t SPI0_MISO_PIN = 8;
+extern uint8_t SPI0_MISO_PIN;
-constexpr uint8_t SPI0_MOSI_PIN = 7;
+extern uint8_t SPI0_MOSI_PIN;
-#define SPI1_AVAILABLE
+extern uint8_t SPI1_SCK_PIN;
-constexpr uint8_t SPI1_SCK_PIN = 20;
+extern uint8_t SPI1_CS_PIN;
-constexpr uint8_t SPI1_CS_PIN = 31;
+extern uint8_t SPI1_MISO_PIN;
-constexpr uint8_t SPI1_MISO_PIN = 5;
+extern uint8_t SPI1_MOSI_PIN;
 constexpr uint8_t SPI1_MOSI_PIN = 21;
-// GPIOs and Testpoints are accessed via enumerated class constants.
+#if defined(ARDUINO_TEENSY41) || defined(__MK66FX1M0__) || defined(__MK64FX512__)
-enum class GPIO : uint8_t {
+#define SPI1_AVAILABLE
-	GPIO0 = 2,
+#endif
 	GPIO1 = 3,
 	GPIO2 = 4,
 	GPIO3 = 6,
 	GPIO4 = 12,
 	GPIO5 = 32,
 	GPIO6 = 27,
 	GPIO7 = 28,
 	TP1 = 34,
 	TP2 = 33
 };
 /**************************************************************************//**
 * Teensy 4.0 Hardware Settings
 *****************************************************************************/
-#elif defined(__IMXRT1062__) // T4.0
+#if defined(__IMXRT1062__) // T4.0
 constexpr uint8_t USR_LED_ID = 2; ///< Teensy IO number for the user LED.
 // SPI0 pinouts
 constexpr uint8_t SPI0_SCK_PIN = 13;
 constexpr uint8_t SPI0_CS_PIN = 10;
 constexpr uint8_t SPI0_MISO_PIN = 12;
 constexpr uint8_t SPI0_MOSI_PIN = 11;
 // GPIOs and Testpoints are accessed via enumerated class constants.
 enum class GPIO : uint8_t {
    GPIO0 = 3,
    GPIO1 = 4,
    GPIO2 = 5,
    GPIO3 = 6,
    GPIO4 = 17,
    GPIO5 = 16,
    GPIO6 = 15,
    GPIO7 = 14,
    TP1 = 9,
    TP2 = 22
 };
 #define SCL_PAD_CTRL IOMUXC_SW_PAD_CTL_PAD_GPIO_AD_B1_00
 #define SDA_PAD_CTRL IOMUXC_SW_PAD_CTL_PAD_GPIO_AD_B1_01
@ -242,75 +262,10 @@ constexpr uint32_t SCL_SDA_PAD_CFG = 0xF808;
 #define LRCLK_PAD_CTRL IOMUXC_SW_PAD_CTL_PAD_GPIO_AD_B1_11
 #define DAC_PAD_CTRL   IOMUXC_SW_PAD_CTL_PAD_GPIO_B1_01
 constexpr uint32_t I2S_PAD_CFG = 0x0008;
 /**************************************************************************//**
 * DEFAULT Teensy 3.2 Hardware Settings
 *****************************************************************************/
 #else
 constexpr uint8_t USR_LED_ID = 16; ///< Teensy IO number for the user LED.
 // SPI0 and SPI1 pinouts
 constexpr uint8_t SPI0_SCK_PIN = 14;
 constexpr uint8_t SPI0_CS_PIN = 15;
 constexpr uint8_t SPI0_MISO_PIN = 8;
 constexpr uint8_t SPI0_MOSI_PIN = 7;
 // GPIOs and Testpoints are accessed via enumerated class constants.
 enum class GPIO : uint8_t {
    GPIO0 = 2,
    GPIO1 = 3,
    GPIO2 = 4,
    GPIO3 = 6,
    GPIO4 = 12,
    GPIO5 = 32,
    GPIO6 = 27,
    GPIO7 = 28,
    TP1 = 34,
    TP2 = 33
 };
 #endif
 /**************************************************************************//**
 * Blackaddr Audio Expansion Board Pin Configuration
 *****************************************************************************/
 #if defined(__MK66FX1M0__) || defined(__MK64FX512__) // T3.6 or T3.5
 // Teensy 3.6 Pinout
 constexpr unsigned BA_EXPAND_NUM_POT  = 3;
 constexpr unsigned BA_EXPAND_NUM_SW   = 2;
 constexpr unsigned BA_EXPAND_NUM_LED  = 2;
 constexpr unsigned BA_EXPAND_NUM_ENC  = 0;
 constexpr uint8_t BA_EXPAND_POT1_PIN = A16; // 35_A16_PWM
 constexpr uint8_t BA_EXPAND_POT2_PIN = A17; // 36_A17_PWM
 constexpr uint8_t BA_EXPAND_POT3_PIN = A18; // 37_SCL1_A18_PWM
 constexpr uint8_t BA_EXPAND_SW1_PIN  = 2;  // 2)PWM
 constexpr uint8_t BA_EXPAND_SW2_PIN  = 3;  // 3_SCL2_PWM
 constexpr uint8_t BA_EXPAND_LED1_PIN = 4;  // 4_SDA2_PWM
 constexpr uint8_t BA_EXPAND_LED2_PIN = 6;  // 6_PWM
 #elif defined(__IMXRT1062__)
 // Teensy 4.0 pinout
 constexpr unsigned BA_EXPAND_NUM_POT  = 3;
 constexpr unsigned BA_EXPAND_NUM_SW   = 2;
 constexpr unsigned BA_EXPAND_NUM_LED  = 2;
 constexpr unsigned BA_EXPAND_NUM_ENC  = 0;
 constexpr uint8_t BA_EXPAND_POT1_PIN = A0; // 14_A0_TX3_SPDIFOUT
 constexpr uint8_t BA_EXPAND_POT2_PIN = A1; // 15_A1_RX3_SPDIFIN
 constexpr uint8_t BA_EXPAND_POT3_PIN = A2; // 16_A2_RX4_SCL1
 constexpr uint8_t BA_EXPAND_SW1_PIN  = 3;  // 3_LRCLK2
 constexpr uint8_t BA_EXPAND_SW2_PIN  = 4;  // 4_BCLK2
 constexpr uint8_t BA_EXPAND_LED1_PIN = 5;  // 5_IN2
 constexpr uint8_t BA_EXPAND_LED2_PIN = 6;  // 6_OUT1D
 #else
 #warning Your processor is not yet supported in BALibrary
 #endif
 } // namespace BALibrary
-#endif /* __BALIBRARY_BAHARDWARE_H */
+#endif /* BALIBRARY_BAHARDWARE_H_ */
--- a/src/BALibrary.h
+++ b/src/BALibrary.h
@ -17,8 +17,8 @@
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#ifndef __BALIBRARY_H
+#ifndef BALIBRARY_H_
-#define __BALIBRARY_H
+#define BALIBRARY_H_
 #include "BAHardware.h" // contains the Blackaddr hardware board definitions
@ -31,4 +31,4 @@
 #include "BAGpio.h"
 #include "BAPhysicalControls.h"
-#endif /* __BALIBRARY_H */
+#endif /* BALIBRARY_H_ */
--- a/src/common/AudioDelay.cpp
+++ b/src/common/AudioDelay.cpp
@ -87,7 +87,6 @@ audio_block_t* AudioDelay::addBlock(audio_block_t *block)
            setSpiDmaCopyBuffer();
 #endif
 			// this causes pops
 		    m_slot->writeAdvance16(block->data, AUDIO_BLOCK_SAMPLES);
 		}
 		blockToRelease =  block;
@ -115,7 +114,10 @@ size_t AudioDelay::getMaxDelaySamples()
 bool AudioDelay::getSamples(audio_block_t *dest, size_t offsetSamples, size_t numSamples)
 {
-	return m_getSamples(dest->data, offsetSamples, numSamples);
+    if (!dest) { return false; }
    else {
 	    return m_getSamples(dest->data, offsetSamples, numSamples);
    }
 }
 bool AudioDelay::getSamples(int16_t *dest, size_t offsetSamples, size_t numSamples)
@ -221,6 +223,7 @@ bool AudioDelay::interpolateDelay(int16_t *extendedSourceBuffer, int16_t *destBu
 bool AudioDelay::setSpiDmaCopyBuffer(void)
 {
    bool returnValue = false;
    if (m_slot->isUseDma()) {
        // For DMA use on T4.0 we need this kluge
        BASpiMemoryDMA * spiDma = static_cast<BASpiMemoryDMA*>(m_slot->getSpiMemoryHandle());
--- a/src/common/BAHardware.cpp
+++ b/src/common/BAHardware.cpp
@ -23,15 +23,277 @@ namespace BALibrary {
 BAHardware BAHardwareConfig; // create the global configuration struct
 ////////////////////////////////////////////////////////////////////////////////
 // DEFAULT SETTINGS - modified appropriate when user calls BAHardware:set()
 // Default settings are currently for TGA PRO MKII & Teensy 4
 ////////////////////////////////////////////////////////////////////////////////
 uint8_t USR_LED_ID = 6; ///< Teensy IO number for the user LED.
 unsigned BA_EXPAND_NUM_POT  = 3;
 unsigned BA_EXPAND_NUM_SW   = 2;
 unsigned BA_EXPAND_NUM_LED  = 2;
 unsigned BA_EXPAND_NUM_ENC  = 0;
 uint8_t BA_EXPAND_POT1_PIN = A0; // 14_A0_TX3_SPDIFOUT
 uint8_t BA_EXPAND_POT2_PIN = A1; // 15_A1_RX3_SPDIFIN
 uint8_t BA_EXPAND_POT3_PIN = A2; // 16_A2_RX4_SCL1
 uint8_t BA_EXPAND_SW1_PIN  = 2;  // 2_OUT2
 uint8_t BA_EXPAND_SW2_PIN  = 3;  // 3_LRCLK2
 uint8_t BA_EXPAND_LED1_PIN = 4;  // 4_BLCK2
 uint8_t BA_EXPAND_LED2_PIN = 5;  // 5_IN2
 uint8_t GPIO0 = 2;
 uint8_t GPIO1 = 3;
 uint8_t GPIO2 = 4;
 uint8_t GPIO3 = 5;
 uint8_t GPIO4 = 255; // Not available on MKII
 uint8_t GPIO5 = 16;
 uint8_t GPIO6 = 15;
 uint8_t GPIO7 = 14;
 uint8_t TP1 = 9;
 uint8_t TP2 = 22;
 // SPI0
 uint8_t SPI0_SCK_PIN  = 13;
 uint8_t SPI0_CS_PIN   = 10;
 uint8_t SPI0_MISO_PIN = 12;
 uint8_t SPI0_MOSI_PIN = 11;
 // SPI1 is only available on user breakout board for MKII/T4
 uint8_t SPI1_SCK_PIN  = 27;
 uint8_t SPI1_CS_PIN   = 38;
 uint8_t SPI1_MISO_PIN = 39;
 uint8_t SPI1_MOSI_PIN = 26;
 BAHardware::BAHardware()
 {
 #if defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY40) // T4.X
    m_teensyProcessor = TeensyProcessor::TEENSY4;
 #elif defined(__MK66FX1M0__) || defined(__MK64FX512__) || defined(__MK20DX256__)
    m_teensyProcessor = TeensyProcessor::TEENSY3;
 #else
 #error "Only Teensy 4.1, 4.0, 3.6, 3.5, 3.2 are supported"
 #endif
 }
 void BAHardware::set(TgaBoard tgaBoard)
 {
-    m_tgaBoard = tgaBoard;
+    m_tgaBoard        = tgaBoard;
    ////////////////////////////////////////////////////////////////////////////
    // MKII                                                                   //
    ////////////////////////////////////////////////////////////////////////////
 #if defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY40) // T4.X
    if (tgaBoard == TgaBoard::MKII_REV1) {
        // No change from defaults
    }
 #endif
 #if defined(__MK66FX1M0__) || defined(__MK64FX512__) || defined(__MK20DX256__) // T3.6 or T3.5 or T3.2
    if (tgaBoard == TgaBoard::MKII_REV1) {
        // Uses TEENSY_ADAPTER_T3
        USR_LED_ID = 16;
        BA_EXPAND_POT1_PIN = A16; // 14_A0_TX3_SPDIFOUT
        BA_EXPAND_POT2_PIN = A17; // 15_A1_RX3_SPDIFIN
        BA_EXPAND_POT3_PIN = A18; // 16_A2_RX4_SCL1
        BA_EXPAND_SW1_PIN  = 2;  // 2_OUT2
        BA_EXPAND_SW2_PIN  = 3;  // 3_LRCLK2
        BA_EXPAND_LED1_PIN = 4;  // 4_BLCK2
        BA_EXPAND_LED2_PIN = 6;  // 5_IN2
        GPIO0 = 2;
        GPIO1 = 3;
        GPIO2 = 4;
        GPIO3 = 6;
        GPIO4 = 255; // Not available on MKII
        GPIO5 = 37;
        GPIO6 = 36;
        GPIO7 = 35;
        TP1   = 34;
        TP2   = 33;
        SPI0_SCK_PIN  = 14;
        SPI0_CS_PIN   = 15;
        SPI0_MISO_PIN = 8;
        SPI0_MOSI_PIN = 7;
        SPI1_SCK_PIN  = 20;
        SPI1_CS_PIN   = 31;
        SPI1_MISO_PIN = 5;
        SPI1_MOSI_PIN = 21;
    }
 #endif
    ////////////////////////////////////////////////////////////////////////////
    // REVB (Original TGA Pro)                                                //
    ////////////////////////////////////////////////////////////////////////////
 #if defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY40) // T4.X
    if (tgaBoard == TgaBoard::REV_B) {
        // Uses TGA_T4_ADAPTER board
        USR_LED_ID = 2;
        BA_EXPAND_POT1_PIN = A0; // 14_A0_TX3_SPDIFOUT
        BA_EXPAND_POT2_PIN = A1; // 15_A1_RX3_SPDIFIN
        BA_EXPAND_POT3_PIN = A2; // 16_A2_RX4_SCL1
        BA_EXPAND_SW1_PIN  = 3;  // 2_OUT2
        BA_EXPAND_SW2_PIN  = 4;  // 3_LRCLK2
        BA_EXPAND_LED1_PIN = 5;  // 4_BLCK2
        BA_EXPAND_LED2_PIN = 6;  // 5_IN2
        GPIO0 = 3;
        GPIO1 = 4;
        GPIO2 = 5;
        GPIO3 = 6;
        GPIO4 = 17;
        GPIO5 = 16;
        GPIO6 = 15;
        GPIO7 = 14;
        TP1   = 9;
        TP2   = 255; // Not available
        SPI0_SCK_PIN  = 13;
        SPI0_CS_PIN   = 10;
        SPI0_MISO_PIN = 12;
        SPI0_MOSI_PIN = 11;
    }
 #endif
 #if defined(__MK66FX1M0__) || defined(__MK64FX512__) || defined(__MK20DX256__) // T3.6 or T3.5 or T3.2
    if (tgaBoard == TgaBoard::REV_B) {
        USR_LED_ID = 16;
        BA_EXPAND_POT1_PIN = A16; // 14_A0_TX3_SPDIFOUT
        BA_EXPAND_POT2_PIN = A17; // 15_A1_RX3_SPDIFIN
        BA_EXPAND_POT3_PIN = A18; // 16_A2_RX4_SCL1
        BA_EXPAND_SW1_PIN  = 2;  // 2_OUT2
        BA_EXPAND_SW2_PIN  = 3;  // 3_LRCLK2
        BA_EXPAND_LED1_PIN = 4;  // 4_BLCK2
        BA_EXPAND_LED2_PIN = 6;  // 5_IN2
        GPIO0 = 2;
        GPIO1 = 3;
        GPIO2 = 4;
        GPIO3 = 6;
        GPIO4 = 38;
        GPIO5 = 37;
        GPIO6 = 36;
        GPIO7 = 35;
        TP1   = 34;
        TP2   = 33;
        SPI0_SCK_PIN  = 14;
        SPI0_CS_PIN   = 15;
        SPI0_MISO_PIN = 8;
        SPI0_MOSI_PIN = 7;
        SPI1_SCK_PIN  = 20;
        SPI1_CS_PIN   = 31;
        SPI1_MISO_PIN = 5;
        SPI1_MOSI_PIN = 21;
    }
 #endif
    ////////////////////////////////////////////////////////////////////////////
    // REVA (Original TGA Pro)                                                //
    ////////////////////////////////////////////////////////////////////////////
 #if defined(ARDUINO_TEENSY41) || defined(ARDUINO_TEENSY40) // T4.X
    if (tgaBoard == TgaBoard::REV_A) {
        // Uses TGA_T4_ADAPTER board
        USR_LED_ID = 2;
        GPIO0 = 3;
        GPIO1 = 4;
        GPIO2 = 5;
        GPIO3 = 6;
        GPIO4 = 17;
        GPIO5 = 16;
        GPIO6 = 15;
        GPIO7 = 14;
        TP1   = 9;
        TP2   = 255; // Not available
        SPI0_SCK_PIN  = 13;
        SPI0_CS_PIN   = 10;
        SPI0_MISO_PIN = 12;
        SPI0_MOSI_PIN = 11;
    }
 #endif
 #if defined(__MK66FX1M0__) || defined(__MK64FX512__) || defined(__MK20DX256__) // T3.6 or T3.5 or T3.2
    if (tgaBoard == TgaBoard::REV_A) {
        // REVA did not support Expansion board
        USR_LED_ID = 16;
        GPIO0 = 2;
        GPIO1 = 3;
        GPIO2 = 4;
        GPIO3 = 6;
        GPIO4 = 12;
        GPIO5 = 32;
        GPIO6 = 27;
        GPIO7 = 29;
        TP1   = 34;
        TP2   = 33;
        SPI0_SCK_PIN  = 14;
        SPI0_CS_PIN   = 15;
        SPI0_MISO_PIN = 8;
        SPI0_MOSI_PIN = 7;
        SPI1_SCK_PIN  = 20;
        SPI1_CS_PIN   = 31;
        SPI1_MISO_PIN = 5;
        SPI1_MOSI_PIN = 21;
    }
 #endif
    ////////////////////////////////////////////////////////////////////////////
    // Avalon                                                                 //
    ////////////////////////////////////////////////////////////////////////////
 #if defined(ARDUINO_TEENSY41) // T4.X
    if (tgaBoard == TgaBoard::AVALON) {
        BA_EXPAND_NUM_POT  = 2;
        BA_EXPAND_NUM_SW   = 6;
        BA_EXPAND_NUM_LED  = 2;
        BA_EXPAND_NUM_ENC  = 4;
        BA_EXPAND_POT1_PIN = A0;
        BA_EXPAND_POT2_PIN = A1;
        BA_EXPAND_POT3_PIN = A13;
        BA_EXPAND_SW1_PIN  = 17;
        BA_EXPAND_SW2_PIN  = 16;
        BA_EXPAND_LED1_PIN = 22;
        BA_EXPAND_LED2_PIN = 32;
        SPI0_SCK_PIN  = 13;
        SPI0_CS_PIN   = 10;
        SPI0_MISO_PIN = 12;
        SPI0_MOSI_PIN = 11;
    }
 #endif
 }
 TgaBoard BAHardware::getTgaBoard(void)
 {
    return m_tgaBoard;
 }
 TeensyProcessor BAHardware::getTeensyProcessor(void)
 {
    return m_teensyProcessor;
 }
 void BAHardware::set(ExpansionBoard expansionBoard)
 {
    m_expansionBoard = expansionBoard;
--- a/src/common/ExtMemSlot.cpp
+++ b/src/common/ExtMemSlot.cpp
@ -144,11 +144,17 @@ bool ExtMemSlot::writeAdvance16(int16_t *src, size_t numWords)
 		// this write will wrap the memory slot
 		size_t wrBytes = m_end - m_currentWrPosition + 1;
 		size_t wrDataNum = wrBytes >> 1; // divide by two to get the number of data
 		m_spi->write16(m_currentWrPosition, reinterpret_cast<uint16_t*>(src), wrDataNum);
 		size_t remainingData = numWords - wrDataNum;
 		m_spi->write16(m_start, reinterpret_cast<uint16_t*>(src + wrDataNum), remainingData); // write remaining bytes are start
 		m_currentWrPosition = m_start + (remainingData*sizeof(int16_t));
 	}
 	// If a write transaction landed exactly on the end of the memory, the next position must be
 	// manually put back to the start
 	if (m_currentWrPosition > m_end) { m_currentWrPosition = m_start; }
 	return true;
 }
--- a/src/effects/AudioEffectAnalogDelay.cpp
+++ b/src/effects/AudioEffectAnalogDelay.cpp
@ -36,7 +36,9 @@ AudioEffectAnalogDelay::AudioEffectAnalogDelay(ExtMemSlot *slot)
 : AudioStream(1, m_inputQueueArray)
 {
 	m_memory = new AudioDelay(slot);
-	m_maxDelaySamples = (slot->size() / sizeof(int16_t));
+
 	// the delay cannot be exactly equal to the slot size, you need at least one sample so the wr/rd are not on top of each other.
 	m_maxDelaySamples = (slot->size() / sizeof(int16_t))-AUDIO_BLOCK_SAMPLES;
 	m_externalMemory = true;
 	m_constructFilter();
 }
@ -77,50 +79,52 @@ void AudioEffectAnalogDelay::setFilter(Filter filter)
 void AudioEffectAnalogDelay::update(void)
 {
 	audio_block_t *inputAudioBlock = receiveReadOnly(); // get the next block of input samples
 	// Check is block is disabled
 	if (m_enable == false) {
 		// do not transmit or process any audio, return as quickly as possible.
 		if (inputAudioBlock) release(inputAudioBlock);
 		// release all held memory resources
 		if (m_previousBlock) {
 			release(m_previousBlock); m_previousBlock = nullptr;
 		}
 		if (!m_externalMemory) {
 			// when using internal memory we have to release all references in the ring buffer
 			while (m_memory->getRingBuffer()->size() > 0) {
 				audio_block_t *releaseBlock = m_memory->getRingBuffer()->front();
 				m_memory->getRingBuffer()->pop_front();
 				if (releaseBlock) release(releaseBlock);
 			}
 		}
 		return;
 	}
-	// Check is block is bypassed, if so either transmit input directly or create silence
+    // Check is block is disabled
-	if (m_bypass == true) {
+    if (m_enable == false) {
-		// transmit the input directly
+        // release all held memory resources
-		if (!inputAudioBlock) {
+        if (m_previousBlock) {
-			// create silence
+            release(m_previousBlock); m_previousBlock = nullptr;
-			inputAudioBlock = allocate();
+        }
-			if (!inputAudioBlock) { return; } // failed to allocate
+        if (!m_externalMemory) {
-			else {
+            // when using internal memory we have to release all references in the ring buffer
-				clearAudioBlock(inputAudioBlock);
+            while (m_memory->getRingBuffer()->size() > 0) {
-			}
+                audio_block_t *releaseBlock = m_memory->getRingBuffer()->front();
-		}
+                m_memory->getRingBuffer()->pop_front();
-		transmit(inputAudioBlock, 0);
+                if (releaseBlock) release(releaseBlock);
-		release(inputAudioBlock);
+            }
-		return;
+        }
-	}
+        return;
    }
    audio_block_t *inputAudioBlock = receiveReadOnly(); // get the next block of input samples
    // Check is block is bypassed, if so either transmit input directly or create silence
    if ((m_bypass == true) || (!inputAudioBlock)) {
        // transmit the input directly
        if (!inputAudioBlock) {
            // create silence
            inputAudioBlock = allocate();
            if (!inputAudioBlock) { return; } // failed to allocate
            else {
                clearAudioBlock(inputAudioBlock);
            }
        }
        transmit(inputAudioBlock, 0);
        release(inputAudioBlock);
        return;
    }
 	// Otherwise perform normal processing
 	// In order to make use of the SPI DMA, we need to request the read from memory first,
 	// then do other processing while it fills in the back.
 	audio_block_t *blockToOutput = nullptr; // this will hold the output audio
    blockToOutput = allocate();
-    if (!blockToOutput) return; // skip this update cycle due to failure
+    if (!blockToOutput) {
        transmit(inputAudioBlock, 0);
        release(inputAudioBlock);
        return; // skip this update cycle due to failure
    }
    // get the data. If using external memory with DMA, this won't be filled until
    // later.
@ -162,21 +166,17 @@ void AudioEffectAnalogDelay::delay(float milliseconds)
 {
 	size_t delaySamples = calcAudioSamples(milliseconds);
-	if (delaySamples > m_memory->getMaxDelaySamples()) {
+	if (!m_memory) { Serial.println("delay(): m_memory is not valid"); return; }
 	    // this exceeds max delay value, limit it.
 	    delaySamples = m_memory->getMaxDelaySamples();
 	}
 	if (!m_memory) { Serial.println("delay(): m_memory is not valid"); }
 	if (!m_externalMemory) {
 		// internal memory
 	    m_maxDelaySamples = m_memory->getMaxDelaySamples();
 		//QueuePosition queuePosition = calcQueuePosition(milliseconds);
 		//Serial.println(String("CONFIG: delay:") + delaySamples + String(" queue position ") + queuePosition.index + String(":") + queuePosition.offset);
 	} else {
 		// external memory
 		//Serial.println(String("CONFIG: delay:") + delaySamples);
 		ExtMemSlot *slot = m_memory->getSlot();
 		m_maxDelaySamples = (slot->size() / sizeof(int16_t))-AUDIO_BLOCK_SAMPLES;
 		if (!slot) { Serial.println("ERROR: slot ptr is not valid"); }
 		if (!slot->isEnabled()) {
@ -185,6 +185,10 @@ void AudioEffectAnalogDelay::delay(float milliseconds)
 		}
 	}
    if (delaySamples > m_maxDelaySamples) {
        // this exceeds max delay value, limit it.
        delaySamples = m_maxDelaySamples;
    }
 	m_delaySamples = delaySamples;
 }
@ -194,43 +198,52 @@ void AudioEffectAnalogDelay::delay(size_t delaySamples)
 	if (!m_externalMemory) {
 		// internal memory
 	    m_maxDelaySamples = m_memory->getMaxDelaySamples();
 		//QueuePosition queuePosition = calcQueuePosition(delaySamples);
 		//Serial.println(String("CONFIG: delay:") + delaySamples + String(" queue position ") + queuePosition.index + String(":") + queuePosition.offset);
 	} else {
 		// external memory
 		//Serial.println(String("CONFIG: delay:") + delaySamples);
 		ExtMemSlot *slot = m_memory->getSlot();
 		m_maxDelaySamples = (slot->size() / sizeof(int16_t))-AUDIO_BLOCK_SAMPLES;
 		if (!slot->isEnabled()) {
 			slot->enable();
 		}
 	}
-	m_delaySamples = delaySamples;
+
 	if (delaySamples > m_maxDelaySamples) {
        // this exceeds max delay value, limit it.
        delaySamples = m_maxDelaySamples;
    }
    m_delaySamples = delaySamples;
 }
 void AudioEffectAnalogDelay::delayFractionMax(float delayFraction)
 {
 	size_t delaySamples = static_cast<size_t>(static_cast<float>(m_memory->getMaxDelaySamples()) * delayFraction);
 	if (delaySamples > m_memory->getMaxDelaySamples()) {
 	    // this exceeds max delay value, limit it.
 	    delaySamples = m_memory->getMaxDelaySamples();
 	}
 	if (!m_memory) { Serial.println("delay(): m_memory is not valid"); }
 	if (!m_externalMemory) {
 		// internal memory
 	    m_maxDelaySamples = m_memory->getMaxDelaySamples();
 		//QueuePosition queuePosition = calcQueuePosition(delaySamples);
 		//Serial.println(String("CONFIG: delay:") + delaySamples + String(" queue position ") + queuePosition.index + String(":") + queuePosition.offset);
 	} else {
 		// external memory
 		//Serial.println(String("CONFIG: delay:") + delaySamples);
 		ExtMemSlot *slot = m_memory->getSlot();
 		m_maxDelaySamples = (slot->size() / sizeof(int16_t))-AUDIO_BLOCK_SAMPLES;
 		if (!slot->isEnabled()) {
 			slot->enable();
 		}
 	}
-	m_delaySamples = delaySamples;
+
 	if (delaySamples > m_maxDelaySamples) {
        // this exceeds max delay value, limit it.
        delaySamples = m_maxDelaySamples;
    }
    m_delaySamples = delaySamples;
 }
 void AudioEffectAnalogDelay::m_preProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet)
@ -268,8 +281,8 @@ void AudioEffectAnalogDelay::processMidi(int channel, int control, int value)
 	if ((m_midiConfig[DELAY][MIDI_CHANNEL] == channel) &&
        (m_midiConfig[DELAY][MIDI_CONTROL] == control)) {
 		// Delay
-		if (m_externalMemory) { m_maxDelaySamples = m_memory->getSlot()->size() / sizeof(int16_t); }
+		if (m_externalMemory) { m_maxDelaySamples = (m_memory->getSlot()->size() / sizeof(int16_t))-AUDIO_BLOCK_SAMPLES; }
-		size_t delayVal = (size_t)(val * (float)m_maxDelaySamples);
+		size_t delayVal = (size_t)(val * (float)(m_maxDelaySamples));
 		delay(delayVal);
 		Serial.println(String("AudioEffectAnalogDelay::delay (ms): ") + calcAudioTimeMs(delayVal)
 				+ String(" (samples): ") + delayVal + String(" out of ") + m_maxDelaySamples);
--- a/src/effects/AudioEffectSOS.cpp
+++ b/src/effects/AudioEffectSOS.cpp
@ -62,28 +62,25 @@ void AudioEffectSOS::enable(void)
    if (m_externalMemory) {
        // Because we hold the previous output buffer for an update cycle, the maximum delay is actually
        // 1 audio block mess then the max delay returnable from the memory.
-        m_maxDelaySamples = m_memory->getMaxDelaySamples();
+        m_maxDelaySamples = m_memory->getMaxDelaySamples() - AUDIO_BLOCK_SAMPLES;
        Serial.println(String("SOS Enabled with delay length ") + m_maxDelaySamples + String(" samples"));
    }
    m_delaySamples = m_maxDelaySamples;
    m_inputGateAuto.setupParameter(GATE_OPEN_STAGE, 0.0f, 1.0f, 1000.0f, ParameterAutomation<float>::Function::EXPONENTIAL);
-    m_inputGateAuto.setupParameter(GATE_HOLD_STAGE, 1.0f, 1.0f, m_maxDelaySamples, ParameterAutomation<float>::Function::HOLD);
+    m_inputGateAuto.setupParameter(GATE_HOLD_STAGE, 1.0f, 1.0f, m_delaySamples, ParameterAutomation<float>::Function::HOLD);
    m_inputGateAuto.setupParameter(GATE_CLOSE_STAGE, 1.0f, 0.0f, 1000.0f, ParameterAutomation<float>::Function::EXPONENTIAL);
    m_clearFeedbackAuto.setupParameter(GATE_OPEN_STAGE, 1.0f, 0.0f, 1000.0f, ParameterAutomation<float>::Function::EXPONENTIAL);
-    m_clearFeedbackAuto.setupParameter(GATE_HOLD_STAGE, 0.0f, 0.0f, m_maxDelaySamples, ParameterAutomation<float>::Function::HOLD);
+    m_clearFeedbackAuto.setupParameter(GATE_HOLD_STAGE, 0.0f, 0.0f, m_delaySamples, ParameterAutomation<float>::Function::HOLD);
    m_clearFeedbackAuto.setupParameter(GATE_CLOSE_STAGE, 0.0f, 1.0f, 1000.0f, ParameterAutomation<float>::Function::EXPONENTIAL);
 }
 void AudioEffectSOS::update(void)
 {
    audio_block_t *inputAudioBlock = receiveReadOnly(); // get the next block of input samples
    // Check is block is disabled
    if (m_enable == false) {
        // do not transmit or process any audio, return as quickly as possible.
        if (inputAudioBlock) release(inputAudioBlock);
        // release all held memory resources
        if (m_previousBlock) {
            release(m_previousBlock); m_previousBlock = nullptr;
@ -99,6 +96,8 @@ void AudioEffectSOS::update(void)
        return;
    }
    audio_block_t *inputAudioBlock = receiveReadOnly(); // get the next block of input samples
    // Check is block is bypassed, if so either transmit input directly or create silence
    if ( (m_bypass == true) || (!inputAudioBlock) ) {
        // transmit the input directly
@ -138,11 +137,7 @@ void AudioEffectSOS::update(void)
    // mix the input with the feedback path in the pre-processing stage
    m_preProcessing(preProcessed, inputAudioBlock, m_previousBlock);
    // consider doing the BBD post processing here to use up more time while waiting
    // for the read data to come back
    audio_block_t *blockToRelease = m_memory->addBlock(preProcessed);
    //audio_block_t *blockToRelease = m_memory->addBlock(inputAudioBlock);
    //Serial.println("Done adding new block");
    // BACK TO OUTPUT PROCESSING
@ -158,15 +153,14 @@ void AudioEffectSOS::update(void)
    release(inputAudioBlock);
-    if (m_previousBlock)
+    if (m_previousBlock) { release(m_previousBlock); }
        release(m_previousBlock);
    m_previousBlock = blockToOutput;
    if (m_blockToRelease == m_previousBlock) {
        Serial.println("ERROR: POINTER COLLISION");
    }
-    if (m_blockToRelease) release(m_blockToRelease);
+    if (m_blockToRelease) { release(m_blockToRelease); }
    m_blockToRelease = blockToRelease;
 }
@ -176,14 +170,12 @@ void AudioEffectSOS::gateOpenTime(float milliseconds)
    // TODO - change the paramter automation to an automation sequence
    m_openTimeMs = milliseconds;
    m_inputGateAuto.setupParameter(GATE_OPEN_STAGE, 0.0f, 1.0f, m_openTimeMs, ParameterAutomation<float>::Function::EXPONENTIAL);
    //m_clearFeedbackAuto.setupParameter(GATE_OPEN_STAGE, 1.0f, 0.0f, m_openTimeMs, ParameterAutomation<float>::Function::EXPONENTIAL);
 }
 void AudioEffectSOS::gateCloseTime(float milliseconds)
 {
    m_closeTimeMs = milliseconds;
    m_inputGateAuto.setupParameter(GATE_CLOSE_STAGE, 1.0f, 0.0f, m_closeTimeMs, ParameterAutomation<float>::Function::EXPONENTIAL);
    //m_clearFeedbackAuto.setupParameter(GATE_CLOSE_STAGE, 0.0f, 1.0f, m_closeTimeMs, ParameterAutomation<float>::Function::EXPONENTIAL);
 }
 ////////////////////////////////////////////////////////////////////////
--- a/src/effects/AudioEffectTremolo.cpp
+++ b/src/effects/AudioEffectTremolo.cpp
@ -28,17 +28,16 @@ AudioEffectTremolo::~AudioEffectTremolo()
 void AudioEffectTremolo::update(void)
 {
-	audio_block_t *inputAudioBlock = receiveWritable(); // get the next block of input samples
+    // Check is block is disabled
    if (m_enable == false) {
        // do not transmit or process any audio, return as quickly as possible.
        return;
    }
-	// Check is block is disabled
+	audio_block_t *inputAudioBlock = receiveWritable(); // get the next block of input samples
 	if (m_enable == false) {
 		// do not transmit or process any audio, return as quickly as possible.
 		if (inputAudioBlock) release(inputAudioBlock);
 		return;
 	}
 	// Check is block is bypassed, if so either transmit input directly or create silence
-	if (m_bypass == true) {
+	if ((m_bypass == true) || (!inputAudioBlock)) {
 		// transmit the input directly
 		if (!inputAudioBlock) {
 			// create silence
--- a/src/peripherals/BAGpio.cpp
+++ b/src/peripherals/BAGpio.cpp
@ -26,18 +26,18 @@ namespace BALibrary {
 BAGpio::BAGpio()
 {
 	// Set all GPIOs to input
-	pinMode(static_cast<uint8_t>(GPIO::GPIO0), INPUT);
+	pinMode(GPIO0, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO1), INPUT);
+	pinMode(GPIO1, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO2), INPUT);
+	pinMode(GPIO2, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO3), INPUT);
+	pinMode(GPIO3, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO4), INPUT);
+	pinMode(GPIO4, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO5), INPUT);
+	pinMode(GPIO5, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO6), INPUT);
+	pinMode(GPIO6, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::GPIO7), INPUT);
+	pinMode(GPIO7, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::TP1),   INPUT);
+	pinMode(TP1, INPUT);
-	pinMode(static_cast<uint8_t>(GPIO::TP2),   INPUT);
+	pinMode(TP2, INPUT);
-	// Set the LED ot ouput
+	// Set the LED to ouput
 	pinMode(USR_LED_ID, OUTPUT);
 	clearLed(); // turn off the LED
@ -49,21 +49,21 @@ BAGpio::~BAGpio()
 void BAGpio::setGPIODirection(GPIO gpioId, int direction)
 {
-	pinMode(static_cast<uint8_t>(gpioId), direction);
+    pinMode(enumToPinNumber(gpioId), direction);
 }
 void BAGpio::setGPIO(GPIO gpioId)
 {
-	digitalWrite(static_cast<uint8_t>(gpioId), 0x1);
+	digitalWrite(enumToPinNumber(gpioId), 0x1);
 }
 void BAGpio::clearGPIO(GPIO gpioId)
 {
-	digitalWrite(static_cast<uint8_t>(gpioId), 0);
+	digitalWrite(enumToPinNumber(gpioId), 0);
 }
 int BAGpio::toggleGPIO(GPIO gpioId)
 {
-	int data = digitalRead(static_cast<uint8_t>(gpioId));
+	int data = digitalRead(enumToPinNumber(gpioId));
-	digitalWrite(static_cast<uint8_t>(gpioId), ~data);
+	digitalWrite(enumToPinNumber(gpioId), ~data);
 	return ~data;
 }
@ -84,5 +84,24 @@ int BAGpio::toggleLed()
 	return m_ledState;
 }
 uint8_t enumToPinNumber(GPIO gpio)
 {
    uint8_t pinNumber;
    switch(gpio) {
    case GPIO::GPIO0 : pinNumber = GPIO0; break;
    case GPIO::GPIO1 : pinNumber = GPIO1; break;
    case GPIO::GPIO2 : pinNumber = GPIO2; break;
    case GPIO::GPIO3 : pinNumber = GPIO3; break;
    case GPIO::GPIO4 : pinNumber = GPIO4; break;
    case GPIO::GPIO5 : pinNumber = GPIO5; break;
    case GPIO::GPIO6 : pinNumber = GPIO6; break;
    case GPIO::GPIO7 : pinNumber = GPIO7; break;
    case GPIO::TP1   : pinNumber = TP1;   break;
    case GPIO::TP2   : pinNumber = TP2;   break;
    default          : pinNumber = 0;     break;
    }
    return pinNumber;
 }
 } /* namespace BALibrary */
--- a/src/peripherals/BAPhysicalControls.cpp
+++ b/src/peripherals/BAPhysicalControls.cpp
@ -265,12 +265,22 @@ bool Potentiometer::getValue(float &value) {
            return false;
        }
    }
    m_lastValidValue = m_lastValue;
    // Convert the integer reading to a float value range 0.0 to 1.0f
-    if      (valFilter < m_minCalibrationThresholded) { value = 0.0f; }
+    if (valFilter < m_minCalibrationThresholded) {
-    else if (valFilter > m_maxCalibrationThresholded) { value = 1.0f; }
+        m_lastValue = m_minCalibrationThresholded;
        if (m_lastValidValue == m_minCalibrationThresholded) { return false; }
        m_lastValidValue = m_lastValue;
        value = 0.0f;
    }
    else if (valFilter > m_maxCalibrationThresholded) {
        m_lastValue = m_maxCalibrationThresholded;
        if (m_lastValidValue == m_maxCalibrationThresholded) { return false; }
        m_lastValidValue = m_lastValue;
        value = 1.0f;
    }
    else {
        m_lastValidValue = m_lastValue;
        value = static_cast<float>(valFilter - m_minCalibrationThresholded) / static_cast<float>(m_rangeThresholded);
    }
@ -319,6 +329,9 @@ void Potentiometer::setChangeThreshold(float changeThreshold)
 Potentiometer::Calib Potentiometer::calibrate(uint8_t pin) {
 	Calib calib;
 	// Flush the serial port input buffer
 	while (Serial.available() > 0) {}
 	Serial.print("Calibration pin "); Serial.println(pin);
 	Serial.println("Move the pot fully counter-clockwise to the minimum setting and press any key then ENTER");
 	while (true) {
--- a/src/peripherals/BASpiMemory.cpp
+++ b/src/peripherals/BASpiMemory.cpp
@ -24,19 +24,19 @@
 namespace BALibrary {
-// MEM0 Settings
+//// MEM0 Settings
-constexpr int SPI_CS_MEM0 = SPI0_CS_PIN;
+//int SPI_CS_MEM0   = SPI0_CS_PIN;
-constexpr int SPI_MOSI_MEM0 = SPI0_MOSI_PIN;
+//int SPI_MOSI_MEM0 = SPI0_MOSI_PIN;
-constexpr int SPI_MISO_MEM0 = SPI0_MISO_PIN;
+//int SPI_MISO_MEM0 = SPI0_MISO_PIN;
-constexpr int SPI_SCK_MEM0 = SPI0_SCK_PIN;
+//int SPI_SCK_MEM0  = SPI0_SCK_PIN;
-
+//
-#if defined(SPI1_AVAILABLE)
+//#if defined(SPI1_AVAILABLE)
-// MEM1 Settings
+//// MEM1 Settings
-constexpr int SPI_CS_MEM1 = SPI1_CS_PIN;
+//int SPI_CS_MEM1   = SPI1_CS_PIN;
-constexpr int SPI_MOSI_MEM1 = SPI1_MOSI_PIN;
+//int SPI_MOSI_MEM1 = SPI1_MOSI_PIN;
-constexpr int SPI_MISO_MEM1 = SPI1_MISO_PIN;
+//int SPI_MISO_MEM1 = SPI1_MISO_PIN;
-constexpr int SPI_SCK_MEM1 = SPI1_SCK_PIN;
+//int SPI_SCK_MEM1  = SPI1_SCK_PIN;
-#endif
+//#endif
 // SPI Constants
 constexpr int SPI_WRITE_MODE_REG = 0x1;
@ -73,22 +73,22 @@ void BASpiMemory::begin()
 {
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
-		m_csPin = SPI_CS_MEM0;
+		m_csPin = SPI0_CS_PIN;
 		m_spi = &SPI;
-		m_spi->setMOSI(SPI_MOSI_MEM0);
+		m_spi->setMOSI(SPI0_MOSI_PIN);
-		m_spi->setMISO(SPI_MISO_MEM0);
+		m_spi->setMISO(SPI0_MISO_PIN);
-		m_spi->setSCK(SPI_SCK_MEM0);
+		m_spi->setSCK(SPI0_SCK_PIN);
 		m_spi->begin();
 		m_dieBoundary = BAHardwareConfig.getSpiMemoryDefinition(MemSelect::MEM0).DIE_BOUNDARY;
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
-		m_csPin = SPI_CS_MEM1;
+		m_csPin = SPI1_CS_PIN;
 		m_spi = &SPI1;
-		m_spi->setMOSI(SPI_MOSI_MEM1);
+		m_spi->setMOSI(SPI1_MOSI_PIN);
-		m_spi->setMISO(SPI_MISO_MEM1);
+		m_spi->setMISO(SPI1_MISO_PIN);
-		m_spi->setSCK(SPI_SCK_MEM1);
+		m_spi->setSCK(SPI1_SCK_PIN);
 		m_spi->begin();
 		m_dieBoundary = BAHardwareConfig.getSpiMemoryDefinition(MemSelect::MEM1).DIE_BOUNDARY;
 		break;
@ -367,17 +367,17 @@ BASpiMemoryDMA::BASpiMemoryDMA(SpiDeviceId memDeviceId)
 	int cs;
 	switch (memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
-		cs = SPI_CS_MEM0;
+		cs = SPI0_CS_PIN;
 		m_cs = new ActiveLowChipSelect(cs, m_settings);
 		break;
 #if defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
-		cs = SPI_CS_MEM1;
+		cs = SPI1_CS_PIN;
 		m_cs = new ActiveLowChipSelect1(cs, m_settings);
 		break;
 #endif
 	default :
-		cs = SPI_CS_MEM0;
+		cs = SPI0_CS_PIN;
 	}
 	// add 4 bytes to buffer for SPI CMD and 3 bytes of address
@ -393,17 +393,17 @@ BASpiMemoryDMA::BASpiMemoryDMA(SpiDeviceId memDeviceId, uint32_t speedHz)
 	int cs;
 	switch (memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
-		cs = SPI_CS_MEM0;
+		cs = SPI0_CS_PIN;
 		m_cs = new ActiveLowChipSelect(cs, m_settings);
 		break;
 #if defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
-		cs = SPI_CS_MEM1;
+		cs = SPI1_CS_PIN;
 		m_cs = new ActiveLowChipSelect1(cs, m_settings);
 		break;
 #endif
 	default :
-		cs = SPI_CS_MEM0;
+		cs = SPI0_CS_PIN;
 	}
 	m_txCommandBuffer = new uint8_t[CMD_ADDRESS_SIZE];
@ -433,11 +433,11 @@ void BASpiMemoryDMA::begin(void)
 {
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
-		m_csPin = SPI_CS_MEM0;
+		m_csPin = SPI0_CS_PIN;
 		m_spi = &SPI;
-		m_spi->setMOSI(SPI_MOSI_MEM0);
+		m_spi->setMOSI(SPI0_MOSI_PIN);
-		m_spi->setMISO(SPI_MISO_MEM0);
+		m_spi->setMISO(SPI0_MISO_PIN);
-		m_spi->setSCK(SPI_SCK_MEM0);
+		m_spi->setSCK(SPI0_SCK_PIN);
 		m_spi->begin();
 		m_spiDma = new DmaSpiGeneric();
 		m_dieBoundary = BAHardwareConfig.getSpiMemoryDefinition(MemSelect::MEM0).DIE_BOUNDARY;
@ -445,11 +445,11 @@ void BASpiMemoryDMA::begin(void)
 #if defined(__MK66FX1M0__) // DMA on SPI1 is only supported on T3.6
 	case SpiDeviceId::SPI_DEVICE1 :
-		m_csPin = SPI_CS_MEM1;
+		m_csPin = SPI1_CS_PIN;
 		m_spi = &SPI1;
-		m_spi->setMOSI(SPI_MOSI_MEM1);
+		m_spi->setMOSI(SPI1_MOSI_PIN);
-		m_spi->setMISO(SPI_MISO_MEM1);
+		m_spi->setMISO(SPI1_MISO_PIN);
-		m_spi->setSCK(SPI_SCK_MEM1);
+		m_spi->setSCK(SPI1_SCK_PIN);
 		m_spi->begin();
 		m_spiDma = new DmaSpiGeneric(1);
 		m_dieBoundary = BAHardwareConfig.getSpiMemoryDefinition(MemSelect::MEM1).DIE_BOUNDARY;
@ -478,6 +478,8 @@ void BASpiMemoryDMA::write(size_t address, uint8_t *src, size_t numBytes)
 	size_t nextAddress = address;
    uint8_t *intermediateBuffer = nullptr;
    while ( m_txTransfer[1].busy() || m_txTransfer[0].busy()) { yield(); } // wait until not busy
    // Check for intermediate buffer use
    if (m_dmaCopyBufferSize) {
        // copy to the intermediate buffer;
@ -487,8 +489,6 @@ void BASpiMemoryDMA::write(size_t address, uint8_t *src, size_t numBytes)
 	while (bytesRemaining > 0) {
 	    m_txXferCount = m_bytesToXfer(nextAddress, min(bytesRemaining, static_cast<size_t>(MAX_DMA_XFER_SIZE))); // check for die boundary
 		while ( m_txTransfer[1].busy() || m_txTransfer[0].busy()) { yield(); } // wait until not busy
 		m_setSpiCmdAddr(SPI_WRITE_CMD, nextAddress, m_txCommandBuffer);
 		m_txTransfer[1] = DmaSpi::Transfer(m_txCommandBuffer, CMD_ADDRESS_SIZE, nullptr, 0, m_cs, TransferType::NO_END_CS);
 		m_spiDma->registerTransfer(m_txTransfer[1]);
@ -559,14 +559,13 @@ void BASpiMemoryDMA::read(size_t address, uint8_t *dest, size_t numBytes)
 	}
 	while (bytesRemaining > 0) {
 	    m_rxXferCount = m_bytesToXfer(nextAddress, min(bytesRemaining, static_cast<size_t>(MAX_DMA_XFER_SIZE))); // check for die boundary
 	    while ( m_rxTransfer[1].busy() || m_rxTransfer[0].busy()) { yield(); }
 	    m_rxXferCount = m_bytesToXfer(nextAddress, min(bytesRemaining, static_cast<size_t>(MAX_DMA_XFER_SIZE))); // check for die boundary
 		m_setSpiCmdAddr(SPI_READ_CMD, nextAddress, m_rxCommandBuffer);
 		while ( m_rxTransfer[1].busy() || m_rxTransfer[0].busy()) { yield(); }
 		m_rxTransfer[1] = DmaSpi::Transfer(m_rxCommandBuffer, CMD_ADDRESS_SIZE, nullptr, 0, m_cs, TransferType::NO_END_CS);
 		m_spiDma->registerTransfer(m_rxTransfer[1]);
 		while ( m_rxTransfer[0].busy() || m_rxTransfer[1].busy()) { yield(); }
 		m_rxTransfer[0] = DmaSpi::Transfer(nullptr, m_rxXferCount, destPtr, 0, m_cs, TransferType::NO_START_CS, nullptr, intermediateBuffer);
 		m_spiDma->registerTransfer(m_rxTransfer[0]);
@ -615,7 +614,6 @@ bool BASpiMemoryDMA::setDmaCopyBufferSize(size_t numBytes)
        m_dmaReadCopyBuffer = (volatile uint8_t*)dma_aligned_malloc(MEM_ALIGNED_ALLOC, numBytes);
        if (!m_dmaReadCopyBuffer) {
            // allocate failed
            m_dmaCopyBufferSize = 0;
            return false;
        }