Merge pull request #1 from Blackaddr/dma_spi

Dma spi
7 years ago · d7fdb462d3
parent b8041d00cf a274d6506a
commit d7fdb462d3
26 changed files with 3347 additions and 212 deletions
--- a/README.md
+++ b/README.md
@ -5,9 +5,12 @@ Tested with:
 Arduino IDE: 1.8.4
 Teensyduinio: 1.39
 *** This library requires a forked version of DmaSpi. You must download the version from here: ***
 *** https://github.com/Blackaddr/DmaSpi ***
 *** If this library fails to compile, please ensure you have updated your Arduino IDE/Teensyduino at least to the versions listed above. ***
-This library contains convience C++ classes to allow full and easy access to the features of the Teensy Guitar Audio Series of boards.
+This library contains convienence C++ classes to allow full and easy access to the features of the Teensy Guitar Audio Series of boards.
 "Teensy" is an Arduino compatible series of boards from www.pjrc.com
--- a/examples/BA2_TGA_Pro_1MEM/BA2_TGA_Pro_1MEM.ino
+++ b/examples/BA2_TGA_Pro_1MEM/BA2_TGA_Pro_1MEM.ino
@ -8,9 +8,13 @@
 * This demo will provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
- * It will also perform a sweeo of the SPI MEM0 external RAM.
+ * 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 <i2c_t3.h>
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
@ -19,7 +23,6 @@
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BAGuitar;
 AudioInputI2S            i2sIn;
@ -32,23 +35,25 @@ 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;
-int spiData0 = 0xff;
+uint16_t spiData0 = 0xABCD;
 int spiErrorCount0 = 0;
 int spiAddress1 = 0;
 int spiData1 = 0xff;
 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) {}
  delay(5);
  // If the codec was already powered up (due to reboot) power itd own first
@ -56,10 +61,36 @@ void setup() {
  delay(100);
  AudioMemory(24);
-  Serial.println("Enabling codec...\n");
+  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() {
@ -67,15 +98,16 @@ void loop() {
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 0
  //////////////////////////////////////////////////////////////////
-  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
+  maskPhase = 0;
  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress0, HEX);
    }
-    //mem0Write(spiAddress0, spiData0);
+    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
-    spiMem0.write(spiAddress0, spiData0);
+    spiMem0.write16(spiAddress0, spiData0);
-    spiData0 = (spiData0-1) & 0xff;
+    maskPhase = (maskPhase+1) % 2;
  }
  Serial.println("SPI0 writing DONE!");
@ -84,32 +116,33 @@ void loop() {
  ///////////////////////////////////////////////////////////////////
  spiErrorCount0 = 0;
  spiAddress0 = 0;
-  spiData0 = 0xff;
+  maskPhase = 0;
-  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
+  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0=spiAddress0+2) {
    if ((spiAddress0 % 32768) == 0) {
-      //Serial.print("Reading ");
+//      Serial.print("Reading ");
-      //Serial.print(spiAddress0, HEX);
+//      Serial.print(spiAddress0, HEX);
    }
-    //int data = mem0Read(spiAddress0);
+    spiData0 = calcData(spiAddress0, loopPhase, maskPhase);
-    int data = spiMem0.read(spiAddress0);
+    int data = spiMem0.read16(spiAddress0);
    if (data != spiData0) {
      spiErrorCount0++;
      Serial.println("");
      Serial.print("ERROR MEM0: (expected) (actual):");
      Serial.print(spiData0, HEX); Serial.print(":");
-      Serial.println(data, HEX);
+      Serial.print(data, HEX);
      delay(100);
    }
    maskPhase = (maskPhase+1) % 2;
    if ((spiAddress0 % 32768) == 0) {
-      //Serial.print(", data = ");
+//      Serial.print(", data = ");
-      //Serial.println(data, HEX);
+//      Serial.println(data, HEX);
 //      Serial.println(String(" loopPhase: ") + loopPhase + String(" maskPhase: ") + maskPhase);
    }
    spiData0 = (spiData0-1) & 0xff;
    // Break out of test once the error count reaches 10
    if (spiErrorCount0 > 10) { break; }
@ -117,6 +150,7 @@ void loop() {
  if (spiErrorCount0 == 0) { Serial.println("SPI0 TEST PASSED!!!"); }
  loopPhase = (loopPhase+1) % 2;
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
--- a/examples/Delay/AnalogDelayDemo/AnalogDelayDemo.ino
+++ b/examples/Delay/AnalogDelayDemo/AnalogDelayDemo.ino
@ -0,0 +1,142 @@
 #include <MIDI.h>
 #include "BAGuitar.h"
 using namespace BAGuitar;
 AudioInputI2S i2sIn;
 AudioOutputI2S i2sOut;
 BAAudioControlWM8731 codec;
 /// IMPORTANT /////
 // YOU MUST COMPILE THIS DEMO USING Serial + Midi
 //#define USE_EXT // uncomment this line to use External MEM0
 #define MIDI_DEBUG // uncomment to see raw MIDI info in terminal
 #ifdef USE_EXT
 // If using external SPI memory, we will instantiance an SRAM
 // manager and create an external memory slot to use as the memory
 // for our audio delay
 ExternalSramManager externalSram;
 ExtMemSlot delaySlot; // Declare an external memory slot.
 // Instantiate the AudioEffectAnalogDelay to use external memory by
 /// passing it the delay slot.
 AudioEffectAnalogDelay analogDelay(&delaySlot);
 #else
 // If using internal memory, we will instantiate the AudioEffectAnalogDelay
 // by passing it the maximum amount of delay we will use in millseconds. Note that
 // audio delay lengths are very limited when using internal memory due to limited
 // internal RAM size.
 AudioEffectAnalogDelay analogDelay(200.0f); // max delay of 200 ms.
 #endif
 AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 // Record the audio to the PC
 //AudioOutputUSB usb;
 // Simply connect the input to the delay, and the output
 // to both i2s channels
 AudioConnection input(i2sIn,0, analogDelay,0);
 AudioConnection delayOut(analogDelay, 0, cabFilter, 0);
 AudioConnection leftOut(cabFilter,0, i2sOut, 0);
 AudioConnection rightOut(cabFilter,0, i2sOut, 1);
 //AudioConnection leftOutUSB(cabFilter,0, usb, 0);
 //AudioConnection rightOutUSB(cabFilter,0, usb, 1);
 int loopCount = 0;
 void setup() {
  delay(100);
  Serial.begin(57600); // Start the serial port
  // Disable the codec first
  codec.disable();
  delay(100);
  AudioMemory(128);
  delay(5);
  // Enable the codec
  Serial.println("Enabling codec...\n");
  codec.enable();
  delay(100);
  // If using external memory request request memory from the manager
  // for the slot
  #ifdef USE_EXT
  Serial.println("Using EXTERNAL memory");
  // We have to request memory be allocated to our slot.
  externalSram.requestMemory(&delaySlot, 500.0f, MemSelect::MEM0, true);
  #else
  Serial.println("Using INTERNAL memory");
  #endif
  // Configure which MIDI CC's will control the effect parameters
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::BYPASS,16);
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::DELAY,20);
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::FEEDBACK,21);
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::MIX,22);
  analogDelay.mapMidiControl(AudioEffectAnalogDelay::VOLUME,23);
  // Besure to enable the delay. When disabled, audio is is completely blocked
  // to minimize resources to nearly zero.
  analogDelay.enable(); 
  // Set some default values.
  // These can be changed by sending MIDI CC messages over the USB using
  // the BAMidiTester application.
  analogDelay.delay(200.0f); // initial delay of 200 ms
  analogDelay.bypass(false);
  analogDelay.mix(0.5f);
  analogDelay.feedback(0.0f);
  // 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);
 }
 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
  // each MIDI messages arrives, it return true.  The message must
  // be fully processed before usbMIDI.read() is called again.
  if (loopCount % 524288 == 0) {
    Serial.print("Processor Usage, Total: "); Serial.print(AudioProcessorUsage());
    Serial.print("% ");
    Serial.print(" analogDelay: "); Serial.print(analogDelay.processorUsage());
    Serial.println("%");
  }
  loopCount++;
  // 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
    if (type == 3) {
      // 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/AnalogDelayDemo/name.c
+++ b/examples/Delay/AnalogDelayDemo/name.c
@ -0,0 +1,19 @@
 // To give your project a unique name, this code must be
 // placed into a .c file (its own tab).  It can not be in
 // a .cpp file or your main sketch (the .ino file).
 #include "usb_names.h"
 // Edit these lines to create your own name.  The length must
 // match the number of characters in your custom name.
 #define MIDI_NAME   {'B','l','a','c','k','a','d','d','r',' ','A','u','d','i','o',' ','T','G','A',' ','P','r','o'}
 #define MIDI_NAME_LEN  23
 // Do not change this part.  This exact format is required by USB.
 struct usb_string_descriptor_struct usb_string_product_name = {
        2 + MIDI_NAME_LEN * 2,
        3,
        MIDI_NAME
 };
--- a/examples/Tests/DMA_MEM0_test/DMA_MEM0_test.ino
+++ b/examples/Tests/DMA_MEM0_test/DMA_MEM0_test.ino
@ -0,0 +1,316 @@
 /*************************************************************************
 * This demo uses the BAGuitar 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/BAGuitar
 * 
 * This demo will perform a DMA memory test on MEM0 attached
 * to SPI.
 * 
 * NOTE: SPI MEM0 can be used by a Teensy 3.2/3.5/3.6.
 * pins.
 * 
 */
 #include <Wire.h>
 #include "BAGuitar.h"
 using namespace BAGuitar;
 //#define SANITY
 #define DMA_SIZE 256
 #define SPI_WRITE_CMD 0x2
 #define SPI_READ_CMD 0x3
 #define SPI_ADDR_2_MASK 0xFF0000
 #define SPI_ADDR_2_SHIFT 16
 #define SPI_ADDR_1_MASK 0x00FF00
 #define SPI_ADDR_1_SHIFT 8
 #define SPI_ADDR_0_MASK 0x0000FF
 SPISettings memSettings(20000000, MSBFIRST, SPI_MODE0);
 const int cs0pin = 15;
 BAGpio                    gpio;  // access to User LED
 BASpiMemoryDMA               spiMem0(SpiDeviceId::SPI_DEVICE0);
 bool compareBuffers(uint8_t *a, uint8_t *b, size_t numBytes)
 {
  bool pass=true;
  int errorCount = 0;
  for (size_t i=0; i<numBytes; i++) {
    if (a[i] != b[i]) {
      if (errorCount < 10) {
        Serial.print(i); Serial.print(":: a:"); Serial.print(a[i]); Serial.print(" does not match b:"); Serial.println(b[i]);
        pass=false;
        errorCount++;
      } else { return false; }
    }
  }
  return pass;
 }
 bool compareBuffers16(uint16_t *a, uint16_t *b, size_t numWords)
 {
  return compareBuffers(reinterpret_cast<uint8_t *>(a), reinterpret_cast<uint8_t*>(b), sizeof(uint16_t)*numWords);
 }
 constexpr size_t TEST_END = SPI_MAX_ADDR;
 void setup() {
  Serial.begin(57600);
  while (!Serial) {}
  delay(5);
  Serial.println("Enabling SPI");
  spiMem0.begin();
 }
 bool spi8BitTest(void) {
  size_t spiAddress = 0;
  int spiPhase = 0;
  constexpr uint8_t MASK80 = 0xaa;
  constexpr uint8_t MASK81 = 0x55;
  uint8_t src8[DMA_SIZE];
  uint8_t dest8[DMA_SIZE];
  // Write to the memory using 8-bit transfers
  Serial.println("\nStarting 8-bit test Write/Read");
  while (spiPhase < 4) {
    spiAddress = 0;
    while (spiAddress < TEST_END) {
      // fill the write data buffer
      switch (spiPhase) {
        case 0 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
          }
          break;
        case 1 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
          }
          break;
        case 2 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
          }
          break;
        case 3 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
          }
          break;
      }      
      // Send the DMA transfer
      spiMem0.write(spiAddress, src8, DMA_SIZE);
      // wait until write is done
      while (spiMem0.isWriteBusy()) {}
      spiAddress += DMA_SIZE;    
    }
    // Read back the data using 8-bit transfers
    spiAddress = 0;
    while (spiAddress < TEST_END) {
      // generate the golden data
      switch (spiPhase) {
      case 0 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
        }
        break;
      case 1 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
        }
        break;
      case 2 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
        }
        break;
      case 3 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
        }
        break;
      }
      // Read back the DMA data
      spiMem0.read(spiAddress, dest8, DMA_SIZE);
      // wait until read is done
      while (spiMem0.isReadBusy()) {}
      if (!compareBuffers(src8, dest8, DMA_SIZE)) { 
        Serial.println(String("ERROR @") + spiAddress);
        return false; } // stop the test    
      spiAddress += DMA_SIZE; 
    }
    Serial.println(String("Phase ") + spiPhase + String(": 8-bit Write/Read test passed!"));
    spiPhase++;
  }
 #ifdef SANITY
  for (int i=0; i<DMA_SIZE; i++) {
    Serial.print(src8[i], HEX); Serial.print("="); Serial.println(dest8[i],HEX);
  }
 #endif
  Serial.println("\nStarting 8-bit test Zero/Read");
  // Clear the memory
  spiAddress = 0;
  memset(src8, 0, DMA_SIZE);
  while (spiAddress < SPI_MAX_ADDR) {
      // Send the DMA transfer
      spiMem0.zero(spiAddress, DMA_SIZE);
      // wait until write is done
      while (spiMem0.isWriteBusy()) {}
      spiAddress += DMA_SIZE;     
  }
  // Check the memory is clear
  spiAddress = 0;
  while (spiAddress < SPI_MAX_ADDR) {
    // Read back the DMA data
    spiMem0.read(spiAddress, dest8, DMA_SIZE);
    // wait until read is done
    while (spiMem0.isReadBusy()) {}
    if (!compareBuffers(src8, dest8, DMA_SIZE)) { return false; } // stop the test    
    spiAddress += DMA_SIZE; 
  }
  Serial.println(String(": 8-bit Zero/Read test passed!"));
  return true;
 }
 bool spi16BitTest(void) {
  size_t spiAddress = 0;
  int spiPhase = 0;
  constexpr uint16_t MASK160 = 0xaaaa;
  constexpr uint16_t MASK161 = 0x5555;
  constexpr int NUM_DATA = DMA_SIZE / sizeof(uint16_t);
  uint16_t src16[NUM_DATA];
  uint16_t dest16[NUM_DATA];
  // Write to the memory using 16-bit transfers
  Serial.println("\nStarting 16-bit test");
  while (spiPhase < 4) {
    spiAddress = 0;
    while (spiAddress < SPI_MAX_ADDR) {
      // fill the write data buffer
      switch (spiPhase) {
        case 0 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
          }
          break;
        case 1 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
          }
          break;
        case 2 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
          }
          break;
        case 3 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
          }
          break;
      }
      // Send the DMA transfer
      spiMem0.write16(spiAddress, src16, NUM_DATA);
      // wait until write is done
      while (spiMem0.isWriteBusy()) {}
      spiAddress += DMA_SIZE;    
    }
    // Read back the data using 8-bit transfers
    spiAddress = 0;
    while (spiAddress < SPI_MAX_ADDR) {
      // generate the golden data
      switch (spiPhase) {
      case 0 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
        }
        break;
      case 1 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
        }
        break;
      case 2 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
        }
        break;
      case 3 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
        }
        break;
      }
      // Read back the DMA data
      spiMem0.read16(spiAddress, dest16, NUM_DATA);
      // wait until read is done
      while (spiMem0.isReadBusy()) {}
      if (!compareBuffers16(src16, dest16, NUM_DATA)) { 
        Serial.print("ERROR @"); Serial.println(spiAddress, HEX);
        return false; } // stop the test    
      spiAddress += DMA_SIZE; 
    }
    Serial.println(String("Phase ") + spiPhase + String(": 16-bit test passed!"));
    spiPhase++;
  }
 #ifdef SANITY
  for (int i=0; i<NUM_DATA; i++) {
   Serial.print(src16[i], HEX); Serial.print("="); Serial.println(dest16[i],HEX);
  }
 #endif
  Serial.println("\nStarting 16-bit test Zero/Read");
  // Clear the memory
  spiAddress = 0;
  memset(src16, 0, DMA_SIZE);
  while (spiAddress < SPI_MAX_ADDR) {
      // Send the DMA transfer
      spiMem0.zero16(spiAddress, NUM_DATA);
      // wait until write is done
      while (spiMem0.isWriteBusy()) {}
      spiAddress += DMA_SIZE;     
  }
  // Check the memory is clear
  spiAddress = 0;
  while (spiAddress < SPI_MAX_ADDR) {
    // Read back the DMA data
    spiMem0.read16(spiAddress, dest16, NUM_DATA);
    // wait until read is done
    while (spiMem0.isReadBusy()) {}
    if (!compareBuffers16(src16, dest16, NUM_DATA)) { return false; } // stop the test    
    spiAddress += DMA_SIZE; 
  }
  Serial.println(String(": 16-bit Zero/Read test passed!"));
  return true;
 }
 void loop() {
  spi8BitTest();
  spi16BitTest();
  while(true) {}
 }
--- a/examples/Tests/DMA_MEM1_test/DMA_MEM1_test.ino
+++ b/examples/Tests/DMA_MEM1_test/DMA_MEM1_test.ino
@ -0,0 +1,316 @@
 /*************************************************************************
 * This demo uses the BAGuitar 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/BAGuitar
 * 
 * This demo will perform a DMA memory test on MEM1 attached
 * to SPI1.
 * 
 * NOTE: SPI MEM1 can be used by a Teensy 3.5/3.6.
 * pins.
 * 
 */
 #include <Wire.h>
 #include "BAGuitar.h"
 using namespace BAGuitar;
 //#define SANITY
 #define DMA_SIZE 256
 #define SPI_WRITE_CMD 0x2
 #define SPI_READ_CMD 0x3
 #define SPI_ADDR_2_MASK 0xFF0000
 #define SPI_ADDR_2_SHIFT 16
 #define SPI_ADDR_1_MASK 0x00FF00
 #define SPI_ADDR_1_SHIFT 8
 #define SPI_ADDR_0_MASK 0x0000FF
 SPISettings memSettings(20000000, MSBFIRST, SPI_MODE0);
 const int cs0pin = 15;
 BAGpio                    gpio;  // access to User LED
 BASpiMemoryDMA               spiMem1(SpiDeviceId::SPI_DEVICE1);
 bool compareBuffers(uint8_t *a, uint8_t *b, size_t numBytes)
 {
  bool pass=true;
  int errorCount = 0;
  for (size_t i=0; i<numBytes; i++) {
    if (a[i] != b[i]) {
      if (errorCount < 10) {
        Serial.print(i); Serial.print(":: a:"); Serial.print(a[i]); Serial.print(" does not match b:"); Serial.println(b[i]);
        pass=false;
        errorCount++;
      } else { return false; }
    }
  }
  return pass;
 }
 bool compareBuffers16(uint16_t *a, uint16_t *b, size_t numWords)
 {
  return compareBuffers(reinterpret_cast<uint8_t *>(a), reinterpret_cast<uint8_t*>(b), sizeof(uint16_t)*numWords);
 }
 constexpr size_t TEST_END = SPI_MAX_ADDR;
 void setup() {
  Serial.begin(57600);
  while (!Serial) {}
  delay(5);
  Serial.println("Enabling SPI");
  spiMem1.begin();
 }
 bool spi8BitTest(void) {
  size_t spiAddress = 0;
  int spiPhase = 0;
  constexpr uint8_t MASK80 = 0xaa;
  constexpr uint8_t MASK81 = 0x55;
  uint8_t src8[DMA_SIZE];
  uint8_t dest8[DMA_SIZE];
  // Write to the memory using 8-bit transfers
  Serial.println("\nStarting 8-bit test Write/Read");
  while (spiPhase < 4) {
    spiAddress = 0;
    while (spiAddress < TEST_END) {
      // fill the write data buffer
      switch (spiPhase) {
        case 0 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
          }
          break;
        case 1 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
          }
          break;
        case 2 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
          }
          break;
        case 3 :
          for (int i=0; i<DMA_SIZE; i++) {
            src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
          }
          break;
      }      
      // Send the DMA transfer
      spiMem1.write(spiAddress, src8, DMA_SIZE);
      // wait until write is done
      while (spiMem1.isWriteBusy()) {}
      spiAddress += DMA_SIZE;    
    }
    // Read back the data using 8-bit transfers
    spiAddress = 0;
    while (spiAddress < TEST_END) {
      // generate the golden data
      switch (spiPhase) {
      case 0 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
        }
        break;
      case 1 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
        }
        break;
      case 2 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
        }
        break;
      case 3 :
        for (int i=0; i<DMA_SIZE; i++) {
          src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
        }
        break;
      }
      // Read back the DMA data
      spiMem1.read(spiAddress, dest8, DMA_SIZE);
      // wait until read is done
      while (spiMem1.isReadBusy()) {}
      if (!compareBuffers(src8, dest8, DMA_SIZE)) { 
        Serial.println(String("ERROR @") + spiAddress);
        return false; } // stop the test    
      spiAddress += DMA_SIZE; 
    }
    Serial.println(String("Phase ") + spiPhase + String(": 8-bit Write/Read test passed!"));
    spiPhase++;
  }
 #ifdef SANITY
  for (int i=0; i<DMA_SIZE; i++) {
    Serial.print(src8[i], HEX); Serial.print("="); Serial.println(dest8[i],HEX);
  }
 #endif
  Serial.println("\nStarting 8-bit test Zero/Read");
  // Clear the memory
  spiAddress = 0;
  memset(src8, 0, DMA_SIZE);
  while (spiAddress < SPI_MAX_ADDR) {
      // Send the DMA transfer
      spiMem1.zero(spiAddress, DMA_SIZE);
      // wait until write is done
      while (spiMem1.isWriteBusy()) {}
      spiAddress += DMA_SIZE;     
  }
  // Check the memory is clear
  spiAddress = 0;
  while (spiAddress < SPI_MAX_ADDR) {
    // Read back the DMA data
    spiMem1.read(spiAddress, dest8, DMA_SIZE);
    // wait until read is done
    while (spiMem1.isReadBusy()) {}
    if (!compareBuffers(src8, dest8, DMA_SIZE)) { return false; } // stop the test    
    spiAddress += DMA_SIZE; 
  }
  Serial.println(String(": 8-bit Zero/Read test passed!"));
  return true;
 }
 bool spi16BitTest(void) {
  size_t spiAddress = 0;
  int spiPhase = 0;
  constexpr uint16_t MASK160 = 0xaaaa;
  constexpr uint16_t MASK161 = 0x5555;
  constexpr int NUM_DATA = DMA_SIZE / sizeof(uint16_t);
  uint16_t src16[NUM_DATA];
  uint16_t dest16[NUM_DATA];
  // Write to the memory using 16-bit transfers
  Serial.println("\nStarting 16-bit test");
  while (spiPhase < 4) {
    spiAddress = 0;
    while (spiAddress < SPI_MAX_ADDR) {
      // fill the write data buffer
      switch (spiPhase) {
        case 0 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
          }
          break;
        case 1 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
          }
          break;
        case 2 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
          }
          break;
        case 3 :
          for (int i=0; i<NUM_DATA; i++) {
            src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
          }
          break;
      }
      // Send the DMA transfer
      spiMem1.write16(spiAddress, src16, NUM_DATA);
      // wait until write is done
      while (spiMem1.isWriteBusy()) {}
      spiAddress += DMA_SIZE;    
    }
    // Read back the data using 8-bit transfers
    spiAddress = 0;
    while (spiAddress < SPI_MAX_ADDR) {
      // generate the golden data
      switch (spiPhase) {
      case 0 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
        }
        break;
      case 1 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
        }
        break;
      case 2 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
        }
        break;
      case 3 :
        for (int i=0; i<NUM_DATA; i++) {
          src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
        }
        break;
      }
      // Read back the DMA data
      spiMem1.read16(spiAddress, dest16, NUM_DATA);
      // wait until read is done
      while (spiMem1.isReadBusy()) {}
      if (!compareBuffers16(src16, dest16, NUM_DATA)) { 
        Serial.print("ERROR @"); Serial.println(spiAddress, HEX);
        return false; } // stop the test    
      spiAddress += DMA_SIZE; 
    }
    Serial.println(String("Phase ") + spiPhase + String(": 16-bit test passed!"));
    spiPhase++;
  }
 #ifdef SANITY
  for (int i=0; i<NUM_DATA; i++) {
   Serial.print(src16[i], HEX); Serial.print("="); Serial.println(dest16[i],HEX);
  }
 #endif
  Serial.println("\nStarting 16-bit test Zero/Read");
  // Clear the memory
  spiAddress = 0;
  memset(src16, 0, DMA_SIZE);
  while (spiAddress < SPI_MAX_ADDR) {
      // Send the DMA transfer
      spiMem1.zero16(spiAddress, NUM_DATA);
      // wait until write is done
      while (spiMem1.isWriteBusy()) {}
      spiAddress += DMA_SIZE;     
  }
  // Check the memory is clear
  spiAddress = 0;
  while (spiAddress < SPI_MAX_ADDR) {
    // Read back the DMA data
    spiMem1.read16(spiAddress, dest16, NUM_DATA);
    // wait until read is done
    while (spiMem1.isReadBusy()) {}
    if (!compareBuffers16(src16, dest16, NUM_DATA)) { return false; } // stop the test    
    spiAddress += DMA_SIZE; 
  }
  Serial.println(String(": 16-bit Zero/Read test passed!"));
  return true;
 }
 void loop() {
  spi8BitTest();
  spi16BitTest();
  while(true) {}
 }
--- a/src/AudioEffectAnalogDelay.h
+++ b/src/AudioEffectAnalogDelay.h
@ -0,0 +1,162 @@
 /**************************************************************************//**
 *  @file
 *  @author Steve Lascos
 *  @company Blackaddr Audio
 *
 *  AudioEffectAnalogDelay is a class for simulating a classic BBD based delay
 *  like the Boss DM-2. This class works with either internal RAM, or external
 *  SPI RAM for longer delays. The exteranl ram uses DMA to minimize load on the
 *  CPU.
 *
 *  @copyright This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
 #ifndef __BAGUITAR_BAAUDIOEFFECTANALOGDELAY_H
 #define __BAGUITAR_BAAUDIOEFFECTANALOGDELAY_H
 #include <Audio.h>
 #include "LibBasicFunctions.h"
 namespace BAGuitar {
 /**************************************************************************//**
 * AudioEffectAnalogDelay models BBD based analog delays. It provides controls
 * for delay, feedback (or regen), mix and output level. All parameters can be
 * controlled by MIDI. The class supports internal memory, or external SPI
 * memory by providing an ExtMemSlot. External memory access uses DMA to reduce
 * process load.
 *****************************************************************************/
 class AudioEffectAnalogDelay : public AudioStream {
 public:
 	///< List of AudioEffectAnalogDelay MIDI controllable parameters
 	enum {
 		BYPASS = 0,  ///<  controls effect bypass
 		DELAY,       ///< controls the amount of delay
 		FEEDBACK,    ///< controls the amount of echo feedback (regen)
 		MIX,         ///< controls the the mix of input and echo signals
 		VOLUME,      ///< controls the output volume level
 		NUM_CONTROLS ///< this can be used as an alias for the number of MIDI controls
 	};
 	AudioEffectAnalogDelay() = delete;
 	// *** CONSTRUCTORS ***
 	/// Construct an analog delay using internal memory by specifying the maximum
 	/// delay in milliseconds.
 	/// @param maxDelayMs maximum delay in milliseconds. Larger delays use more memory.
 	AudioEffectAnalogDelay(float maxDelayMs);
 	/// Construct an analog delay using internal memory by specifying the maximum
 	/// delay in audio samples.
 	/// @param numSamples maximum delay in audio samples. Larger delays use more memory.
 	AudioEffectAnalogDelay(size_t numSamples);
 	/// Construct an analog delay using external SPI via an ExtMemSlot. The amount of
 	/// delay will be determined by the amount of memory in the slot.
 	/// @param slot A pointer to the ExtMemSlot to use for the delay.
 	AudioEffectAnalogDelay(ExtMemSlot *slot); // requires sufficiently sized pre-allocated memory
 	virtual ~AudioEffectAnalogDelay(); ///< Destructor
 	// *** PARAMETERS ***
 	/// Set the delay in milliseconds.
 	/// @param milliseconds the request delay in milliseconds. Must be less than max delay.
 	void delay(float milliseconds);
 	/// Set the delay in number of audio samples.
 	/// @param delaySamples the request delay in audio samples. Must be less than max delay.
 	void delay(size_t delaySamples);
 	/// Bypass the effect.
 	/// @param byp when true, bypass wil disable the effect, when false, effect is enabled.
    /// Note that audio still passes through when bypass is enabled.
 	void bypass(bool byp) { m_bypass = byp; }
 	/// Set the amount of echo feedback (a.k.a regeneration).
 	/// @param feedback a floating point number between 0.0 and 1.0.
 	void feedback(float feedback) { m_feedback = feedback; }
 	/// Set the amount of blending between dry and wet (echo) at the output.
 	/// @param mix When 0.0, output is 100% dry, when 1.0, output is 100% wet. When
 	/// 0.5, output is 50% Dry, 50% Wet.
 	void mix(float mix) { m_mix = mix; }
 	/// Set the output volume. This affect both the wet and dry signals.
 	/// @details The default is 1.0.
 	/// @param vol Sets the output volume between -1.0 and +1.0
 	void volume(float vol) {m_volume = vol; }
 	// ** ENABLE  / DISABLE **
 	/// Enables audio processing. Note: when not enabled, CPU load is nearly zero.
 	void enable() { m_enable = true; }
 	/// Disables audio process. When disabled, CPU load is nearly zero.
 	void disable() { m_enable = false; }
 	// ** MIDI **
 	/// Sets whether MIDI OMNI channel is processig on or off. When on,
 	/// all midi channels are used for matching CCs.
 	/// @param isOmni when true, all channels are processed, when false, channel
 	/// must match configured value.
 	void setMidiOmni(bool isOmni) { m_isOmni = isOmni; }
 	/// Configure an effect parameter to be controlled by a MIDI CC
 	/// number on a particular channel.
 	/// @param parameter one of the parameter names in the class enum
 	/// @param midiCC the CC number from 0 to 127
 	/// @param midiChannel the effect will only response to the CC on this channel
 	/// when OMNI mode is off.
 	void mapMidiControl(int parameter, int midiCC, int midiChannel = 0);
 	/// process a MIDI Continous-Controller (CC) message
 	/// @param channel the MIDI channel from 0 to 15)
 	/// @param midiCC the CC number from 0 to 127
 	/// @param value the CC value from 0 to 127
 	void processMidi(int channel, int midiCC, int value);
 	virtual void update(void); ///< update automatically called by the Teesny Audio Library
 private:
 	audio_block_t *m_inputQueueArray[1];
 	bool m_isOmni = false;
 	bool m_bypass = true;
 	bool m_enable = false;
 	bool m_externalMemory = false;
 	AudioDelay *m_memory = nullptr;
 	size_t m_maxDelaySamples = 0;
 	audio_block_t *m_previousBlock = nullptr;
 	audio_block_t *m_blockToRelease  = nullptr;
 	IirBiQuadFilterHQ *m_iir = nullptr;
 	// Controls
 	int m_midiConfig[NUM_CONTROLS][2]; // stores the midi parameter mapping
 	size_t m_delaySamples = 0;
 	float m_feedback = 0.0f;
 	float m_mix = 0.0f;
 	float m_volume = 1.0f;
 	void m_preProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet);
 	void m_postProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet);
 	size_t m_callCount = 0;
 };
 }
 #endif /* __BAGUITAR_BAAUDIOEFFECTANALOGDELAY_H */
--- a/src/BAAudioControlWM8731.h
+++ b/src/BAAudioControlWM8731.h
@ -22,8 +22,8 @@
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
-#ifndef __INC_BAAUDIOCONTROLWM8731_H
+#ifndef __BAGUITAR__BAAUDIOCONTROLWM8731_H
-#define __INC_BAAUDIOCONTROLWM8731_H
+#define __BAGUITAR__BAAUDIOCONTROLWM8731_H
 namespace BAGuitar {
@ -128,4 +128,4 @@ private:
 } /* namespace BAGuitar */
-#endif /* __INC_BAAUDIOCONTROLWM8731_H */
+#endif /* __BAGUITAR__BAAUDIOCONTROLWM8731_H */
--- a/src/BAGpio.h
+++ b/src/BAGpio.h
@ -20,8 +20,8 @@
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
-#ifndef __SRC_BAGPIO_H
+#ifndef __BAGUITAR_BAGPIO_H
-#define __SRC_BAGPIO_H
+#define __BAGUITAR_BAGPIO_H
 #include "BAHardware.h"
@ -35,6 +35,7 @@ namespace BAGuitar {
 *****************************************************************************/
 class BAGpio {
 public:
 	/// Construct a GPIO object for controlling the various GPIO and user pins
 	BAGpio();
 	virtual ~BAGpio();
@ -72,4 +73,4 @@ private:
 } /* namespace BAGuitar */
-#endif /* __SRC_BAGPIO_H */
+#endif /* __BAGUITAR_BAGPIO_H */
--- a/src/BAGuitar.h
+++ b/src/BAGuitar.h
@ -18,14 +18,18 @@
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#ifndef __SRC_BATGUITAR_H
+#ifndef __BATGUITAR_H
-#define __SRC_BATGUITAR_H
+#define __BATGUITAR_H
 #include "BAHardware.h" // contains the Blackaddr hardware board definitions
 #include "BATypes.h"
 #include "BAAudioControlWM8731.h" // Codec Control
 #include "BASpiMemory.h"
 #include "BAGpio.h"
 #include "BAAudioEffectDelayExternal.h"
 #include "AudioEffectAnalogDelay.h"
 #include "LibBasicFunctions.h"
 #include "LibMemoryManagement.h"
-#endif /* __SRC_BATGUITAR_H */
+#endif /* __BATGUITAR_H */
--- a/src/BAHardware.h
+++ b/src/BAHardware.h
@ -20,8 +20,10 @@
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
-#ifndef SRC_BAHARDWARE_H_
+#ifndef __BAGUTIAR_BAHARDWARE_H
-#define SRC_BAHARDWARE_H_
+#define __BAGUTIAR_BAHARDWARE_H
 #include <cstdint>
 /**************************************************************************//**
 * BAGuitar is a namespace/Library for Guitar processing from Blackaddr Audio.
@ -57,19 +59,24 @@ enum class GPIO : uint8_t {
 /**************************************************************************//**
 * Optionally installed SPI RAM
 *****************************************************************************/
 constexpr unsigned NUM_MEM_SLOTS = 2;
 enum MemSelect : unsigned {
 	MEM0 = 0, ///< SPI RAM MEM0
 	MEM1 = 1  ///< SPI RAM MEM1
 };
-constexpr int MEM0_MAX_ADDR = 131071; ///< Max address size per chip
+
-constexpr int MEM1_MAX_ADDR = 131071; ///< Max address size per chip
+/**************************************************************************//**
 * Set the maximum address (byte-based) in the external SPI memories
 *****************************************************************************/
 constexpr size_t MEM_MAX_ADDR[NUM_MEM_SLOTS] = { 131071, 131071 };
 /**************************************************************************//**
 * General Purpose SPI Interfaces
 *****************************************************************************/
-enum class SpiDeviceId {
+enum SpiDeviceId : unsigned {
-	SPI_DEVICE0, ///< Arduino SPI device
+	SPI_DEVICE0 = 0, ///< Arduino SPI device
-	SPI_DEVICE1  ///< Arduino SPI1 device
+	SPI_DEVICE1 = 1  ///< Arduino SPI1 device
 };
 constexpr int SPI_MAX_ADDR = 131071; ///< Max address size per chip
@ -83,4 +90,4 @@ constexpr int SPI_MAX_ADDR = 131071; ///< Max address size per chip
 } // namespace BAGuitar
-#endif /* SRC_BAHARDWARE_H_ */
+#endif /* __BAGUTIAR_BAHARDWARE_H */
--- a/src/BASpiMemory.cpp
+++ b/src/BASpiMemory.cpp
@ -1,155 +0,0 @@
 /*
 * BASpiMemory.cpp
 *
 *  Created on: May 22, 2017
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include "Arduino.h"
 #include "BASpiMemory.h"
 namespace BAGuitar {
 // MEM0 Settings
 constexpr int SPI_CS_MEM0 = 15;
 constexpr int SPI_MOSI_MEM0 = 7;
 constexpr int SPI_MISO_MEM0 = 8;
 constexpr int SPI_SCK_MEM0 = 14;
 // MEM1 Settings
 constexpr int SPI_CS_MEM1 = 31;
 constexpr int SPI_MOSI_MEM1 = 21;
 constexpr int SPI_MISO_MEM1 = 5;
 constexpr int SPI_SCK_MEM1 = 20;
 // SPI Constants
 constexpr int SPI_WRITE_CMD = 0x2;
 constexpr int SPI_READ_CMD = 0x3;
 constexpr int SPI_ADDR_2_MASK = 0xFF0000;
 constexpr int SPI_ADDR_2_SHIFT = 16;
 constexpr int SPI_ADDR_1_MASK = 0x00FF00;
 constexpr int SPI_ADDR_1_SHIFT = 8;
 constexpr int SPI_ADDR_0_MASK = 0x0000FF;
 BASpiMemory::BASpiMemory(SpiDeviceId memDeviceId)
 {
 	m_memDeviceId = memDeviceId;
 	m_settings = {20000000, MSBFIRST, SPI_MODE0};
 }
 BASpiMemory::BASpiMemory(SpiDeviceId memDeviceId, uint32_t speedHz)
 {
 	m_memDeviceId = memDeviceId;
 	m_settings = {speedHz, MSBFIRST, SPI_MODE0};
 }
 // Intitialize the correct Arduino SPI interface
 void BASpiMemory::begin()
 {
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		m_csPin = SPI_CS_MEM0;
 		m_spi = &SPI;
 		m_spi->setMOSI(SPI_MOSI_MEM0);
 		m_spi->setMISO(SPI_MISO_MEM0);
 		m_spi->setSCK(SPI_SCK_MEM0);
 		m_spi->begin();
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		m_csPin = SPI_CS_MEM1;
 		m_spi = &SPI1;
 		m_spi->setMOSI(SPI_MOSI_MEM1);
 		m_spi->setMISO(SPI_MISO_MEM1);
 		m_spi->setSCK(SPI_SCK_MEM1);
 		m_spi->begin();
 		break;
 #endif
 	default :
 		// unreachable since memDeviceId is an enumerated class
 		return;
 	}
 	pinMode(m_csPin, OUTPUT);
 	digitalWrite(m_csPin, HIGH);
 }
 BASpiMemory::~BASpiMemory() {
 }
 // Single address write
 void BASpiMemory::write(int address, int data)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_WRITE_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	m_spi->transfer(data);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 void BASpiMemory::write16(int address, uint16_t data)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_WRITE_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	m_spi->transfer16(data);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 // single address read
 int BASpiMemory::read(int address)
 {
 	int data;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_READ_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	data = m_spi->transfer(0);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 	return data;
 }
 uint16_t BASpiMemory::read16(int address)
 {
 	uint16_t data;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_READ_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	data = m_spi->transfer16(0);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 	return data;
 }
 } /* namespace BAGuitar */
--- a/src/BASpiMemory.h
+++ b/src/BASpiMemory.h
@ -4,7 +4,8 @@
 *  @company Blackaddr Audio
 *
 *  BASpiMemory is convenience class for accessing the optional SPI RAMs on
- *  the GTA Series boards.
+ *  the GTA Series boards. BASpiMemoryDma works the same but uses DMA to reduce
 *  load on the processor.
 *
 *  @copyright This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
@ -19,11 +20,13 @@
 *  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 __SRC_BASPIMEMORY_H
+#ifndef __BAGUITAR_BASPIMEMORY_H
-#define __SRC_BASPIMEMORY_H
+#define __BAGUITAR_BASPIMEMORY_H
 #include <SPI.h>
 #include <DmaSpi.h>
 #include "BATypes.h"
 #include "BAHardware.h"
 namespace BAGuitar {
@ -39,43 +42,174 @@ public:
 	BASpiMemory() = delete;
 	/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2).
 	/// @details default is 20 Mhz
-	/// @param memDeviceId specify which MEM to controlw with SpiDeviceId.
+	/// @param memDeviceId specify which MEM to control with SpiDeviceId.
 	BASpiMemory(SpiDeviceId memDeviceId);
 	/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2)
-	/// @param memDeviceId specify which MEM to controlw with SpiDeviceId.
+	/// @param memDeviceId specify which MEM to control with SpiDeviceId.
 	/// @param speedHz specify the desired speed in Hz.
 	BASpiMemory(SpiDeviceId memDeviceId, uint32_t speedHz);
 	virtual ~BASpiMemory();
-	void begin(void);
+	/// initialize and configure the SPI peripheral
 	virtual void begin();
-	/// write a single data word to the specified address
+	/// write a single 8-bit word to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param data the value to write
-	void write(int address, int data);
+	void write(size_t address, uint8_t data);
-	void write16(int address, uint16_t data);
+	/// Write a block of 8-bit data to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param src pointer to the source data block
 	/// @param numBytes size of the data block in bytes
 	virtual void write(size_t address, uint8_t *src, size_t numBytes);
 	/// Write a block of zeros to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param numBytes size of the data block in bytes
 	virtual void zero(size_t address, size_t numBytes);
 	/// write a single 16-bit word to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param data the value to write
 	void write16(size_t address, uint16_t data);
 	/// Write a block of 16-bit data to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param src pointer to the source data block
 	/// @param numWords size of the data block in 16-bit words
 	virtual void write16(size_t address, uint16_t *src, size_t numWords);
 	/// Write a block of 16-bit zeros to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param numWords size of the data block in 16-bit words
 	virtual void zero16(size_t address, size_t numWords);
 	/// read a single 8-bit data word from the specified address
 	/// @param address the address in the SPI RAM to read from
 	/// @return the data that was read
-	int  read(int address);
+	uint8_t read(size_t address);
 	/// Read a block of 8-bit data from the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param dest pointer to the destination
 	/// @param numBytes size of the data block in bytes
 	virtual void read(size_t address, uint8_t *dest, size_t numBytes);
 	/// read a single 16-bit data word from the specified address
 	/// @param address the address in the SPI RAM to read from
 	/// @return the data that was read
-	uint16_t  read16(int address);
+	uint16_t read16(size_t address);
-private:
+	/// read a block 16-bit data word from the specified address
 	/// @param address the address in the SPI RAM to read from
 	/// @param dest the pointer to the destination
 	/// @param numWords the number of 16-bit words to transfer
 	virtual void read16(size_t address, uint16_t *dest, size_t numWords);
 	/// Check if the class has been configured by a previous begin() call
 	/// @returns true if initialized, false if not yet initialized
    bool isStarted() const { return m_started; }
 protected:
 	SPIClass *m_spi = nullptr;
 	SpiDeviceId m_memDeviceId; // the MEM device being control with this instance
 	uint8_t m_csPin; // the IO pin number for the CS on the controlled SPI device
 	SPISettings m_settings; // the Wire settings for this SPI port
 	bool m_started = false;
 };
 class BASpiMemoryDMA : public BASpiMemory {
 public:
 	BASpiMemoryDMA() = delete;
 	/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2).
 	/// @details default is 20 Mhz
 	/// @param memDeviceId specify which MEM to control with SpiDeviceId.
 	BASpiMemoryDMA(SpiDeviceId memDeviceId);
 	/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2)
 	/// @param memDeviceId specify which MEM to control with SpiDeviceId.
 	/// @param speedHz specify the desired speed in Hz.
 	BASpiMemoryDMA(SpiDeviceId memDeviceId, uint32_t speedHz);
 	virtual ~BASpiMemoryDMA();
 	/// initialize and configure the SPI peripheral
 	void begin() override;
 	/// Write a block of 8-bit data to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param src pointer to the source data block
 	/// @param numBytes size of the data block in bytes
 	void write(size_t address, uint8_t *src, size_t numBytes) override;
 	/// Write a block of zeros to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param numBytes size of the data block in bytes
 	void zero(size_t address, size_t numBytes) override;
 	/// Write a block of 16-bit data to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param src pointer to the source data block
 	/// @param numWords size of the data block in 16-bit words
 	void write16(size_t address, uint16_t *src, size_t numWords) override;
 	/// Write a block of 16-bit zeros to the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param numWords size of the data block in 16-bit words
 	void zero16(size_t address, size_t numWords) override;
 	/// Read a block of 8-bit data from the specified address
 	/// @param address the address in the SPI RAM to write to
 	/// @param dest pointer to the destination
 	/// @param numBytes size of the data block in bytes
 	void read(size_t address, uint8_t *dest, size_t numBytes) override;
 	/// read a block 16-bit data word from the specified address
 	/// @param address the address in the SPI RAM to read from
 	/// @param dest the pointer to the destination
 	/// @param numWords the number of 16-bit words to transfer
 	void read16(size_t address, uint16_t *dest, size_t numWords) override;
 	/// Check if a DMA write is in progress
 	/// @returns true if a write DMA is in progress, else false
 	bool isWriteBusy() const;
 	/// Check if a DMA read is in progress
 	/// @returns true if a read DMA is in progress, else false
 	bool isReadBusy() const;
 	/// Readout the 8-bit contents of the DMA storage buffer to the specified destination
 	/// @param dest pointer to the destination
 	/// @param numBytes number of bytes to read out
 	/// @param byteOffset, offset from the start of the DMA buffer in bytes to begin reading
 	void readBufferContents(uint8_t *dest,  size_t numBytes, size_t byteOffset = 0);
 	/// Readout the 8-bit contents of the DMA storage buffer to the specified destination
 	/// @param dest pointer to the destination
 	/// @param numWords number of 16-bit words to read out
 	/// @param wordOffset, offset from the start of the DMA buffer in words to begin reading
 	void readBufferContents(uint16_t *dest, size_t numWords, size_t wordOffset = 0);
 private:
 	DmaSpiGeneric *m_spiDma = nullptr;
 	AbstractChipSelect *m_cs = nullptr;
 	uint8_t *m_txCommandBuffer = nullptr;
 	DmaSpi::Transfer *m_txTransfer;
 	uint8_t *m_rxCommandBuffer = nullptr;
 	DmaSpi::Transfer *m_rxTransfer;
 	uint16_t m_txXferCount;
 	uint16_t m_rxXferCount;
 	void m_setSpiCmdAddr(int command, size_t address, uint8_t *dest);
 };
 class BASpiMemoryException {};
 } /* namespace BAGuitar */
-#endif /* __SRC_BASPIMEMORY_H */
+#endif /* __BAGUITAR_BASPIMEMORY_H */
--- a/src/BATypes.h
+++ b/src/BATypes.h
@ -0,0 +1,158 @@
 /**************************************************************************//**
 *  @file
 *  @author Steve Lascos
 *  @company Blackaddr Audio
 *
 *  This file contains some custom types used by the rest of the BAGuitar library.
 *
 *  @copyright This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
 #ifndef __BAGUITAR_BATYPES_H
 #define __BAGUITAR_BATYPES_H
 namespace BAGuitar {
 #define UNUSED(x) (void)(x)
 /**************************************************************************//**
 * Customer RingBuffer with random access
 *****************************************************************************/
 template <class T>
 class RingBuffer {
 public:
 	RingBuffer() = delete;
 	/// Construct a RingBuffer of specified max size
 	/// @param maxSize number of entries in ring buffer
 	RingBuffer(const size_t maxSize) : m_maxSize(maxSize) {
 		m_buffer = new T[maxSize]();
 	}
 	virtual ~RingBuffer(){
 		if (m_buffer) delete [] m_buffer;
 	}
 	/// Add an element to the back of the queue
 	/// @param element element to add to queue
 	/// returns 0 if success, otherwise error
 	int push_back(T element) {
 		//Serial.println(String("RingBuffer::push_back...") + m_head + String(":") + m_tail + String(":") + m_size);
 		if ( (m_head == m_tail) && (m_size > 0) ) {
 			// overflow
 			Serial.println("RingBuffer::push_back: overflow");
 			return -1;
 		}
 		m_buffer[m_head] = element;
 		if (m_head < (m_maxSize-1) ) {
 			m_head++;
 		} else {
 			m_head = 0;
 		}
 		m_size++;
 		return 0;
 	}
 	/// Remove the element at teh front of the queue
 	/// @returns 0 if success, otherwise error
 	int pop_front() {
 		if (m_size == 0) {
 			// buffer is empty
 			//Serial.println("RingBuffer::pop_front: buffer is empty\n");
 			return -1;
 		}
 		if (m_tail < m_maxSize-1) {
 			m_tail++;
 		} else {
 			m_tail = 0;
 		}
 		m_size--;
 		//Serial.println(String("RingBuffer::pop_front: ") + m_head + String(":") + m_tail + String(":") + m_size);
 		return 0;
 	}
 	/// Get the element at the front of the queue
 	/// @returns element at front of queue
 	T front() const {
 		return m_buffer[m_tail];
 	}
 	/// get the element at the back of the queue
 	/// @returns element at the back of the queue
 	T back() const {
 		return m_buffer[m_head-1];
 	}
 	/// Get a previously pushed elememt
 	/// @param offset zero is last pushed, 1 is second last, etc.
 	/// @returns the absolute index corresponding to the requested offset.
 	size_t get_index_from_back(size_t offset = 0) const {
 		// the target at m_head - 1 - offset or m_maxSize + m_head -1 - offset;
 		size_t idx = (m_maxSize + m_head -1 - offset);
 		if ( idx >= m_maxSize) {
 			idx -= m_maxSize;
 		}
 		return idx;
 	}
 	/// get the current size of the queue
 	/// @returns size of the queue
 	size_t size() const {
 		return m_size;
 	}
 	/// get the maximum size the queue can hold
 	/// @returns maximum size of the queue
 	size_t max_size() const {
 	    return m_maxSize;
 	}
 	/// get the element at the specified absolute index
 	/// @param index element to retrieve from absolute queue position
 	/// @returns the request element
    T& operator[] (size_t index) {
        return m_buffer[index];
    }
 	/// get the element at the specified absolute index
 	/// @param index element to retrieve from absolute queue position
 	/// @returns the request element
    T at(size_t index) const {
    	return m_buffer[index];
    }
    /// DEBUG: Prints the status of the Ringbuffer. NOte using this much printing will usually cause audio glitches
    void print() const {
    	for (int idx=0; idx<m_maxSize; idx++) {
    		Serial.print(idx + String(" address: ")); Serial.print((uint32_t)m_buffer[idx], HEX);
    		Serial.print(" data: "); Serial.println((uint32_t)m_buffer[idx]->data, HEX);
    	}
    }
 private:
    size_t m_head=0;        ///< back of the queue
    size_t m_tail=0;        ///< front of the queue
    size_t m_size=0;        ///< current size of the qeueu
    T *m_buffer = nullptr;  ///< pointer to the allocated buffer array
    const size_t m_maxSize; ///< maximum size of the queue
 };
 } // BAGuitar
 #endif /* __BAGUITAR_BATYPES_H */
--- a/src/LibBasicFunctions.h
+++ b/src/LibBasicFunctions.h
@ -0,0 +1,283 @@
 /**************************************************************************//**
 *  @file
 *  @author Steve Lascos
 *  @company Blackaddr Audio
 *
 *  LibBasicFunctions is a collection of helpful functions and classes that make
 *  it easier to perform common tasks in Audio applications.
 *
 *  @copyright This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
 #include <cstddef>
 #include <new>
 #include <arm_math.h>
 #include "Arduino.h"
 #include "Audio.h"
 #include "BATypes.h"
 #include "LibMemoryManagement.h"
 #ifndef __BAGUITAR_LIBBASICFUNCTIONS_H
 #define __BAGUITAR_LIBBASICFUNCTIONS_H
 namespace BAGuitar {
 /**************************************************************************//**
 * QueuePosition is used for storing the index (in an array of queues) and the
 * offset within an audio_block_t data buffer. Useful for dealing with large
 * windows of audio spread across multiple audio data blocks.
 *****************************************************************************/
 struct QueuePosition {
 	int offset; ///< offset in samples within an audio_block_t data buffer
 	int index;  ///< index in an array of audio data blocks
 };
 /// Calculate the exact sample position in an array of audio blocks that corresponds
 /// to a particular offset given as time.
 /// @param milliseconds length of the interval in milliseconds
 /// @returns a struct containing the index and offset
 QueuePosition calcQueuePosition(float milliseconds);
 /// Calculate the exact sample position in an array of audio blocks that corresponds
 /// to a particular offset given as a number of samples
 /// @param milliseconds length of the interval in milliseconds
 /// @returns a struct containing the index and offset
 QueuePosition calcQueuePosition(size_t numSamples);
 /// Calculate the number of audio samples (rounded up) that correspond to a
 /// given length of time.
 /// @param milliseconds length of the interval in milliseconds
 /// @returns the number of corresonding audio samples.
 size_t calcAudioSamples(float milliseconds);
 /// Calculate a length of time in milliseconds from the number of audio samples.
 /// @param numSamples Number of audio samples to convert to time
 /// @return the equivalent time in milliseconds.
 float calcAudioTimeMs(size_t numSamples);
 /// Calculate the number of audio samples (usually an offset) from
 /// a queue position.
 /// @param position specifies the index and offset within a queue
 /// @returns the number of samples from the start of the queue array to the
 /// specified position.
 size_t calcOffset(QueuePosition position);
 /// Clear the contents of an audio block to zero
 /// @param block pointer to the audio block to clear
 void clearAudioBlock(audio_block_t *block);
 /// Perform an alpha blend between to audio blocks. Performs <br>
 /// out = dry*(1-mix) + wet*(mix)
 /// @param out pointer to the destination audio block
 /// @param dry pointer to the dry audio
 /// @param wet pointer to the wet audio
 /// @param mix float between 0.0 and 1.0.
 void alphaBlend(audio_block_t *out, audio_block_t *dry, audio_block_t* wet, float mix);
 /// Applies a gain to the audio via fixed-point scaling accoring to <br>
 /// out = int * (vol * 2^coeffShift)
 /// @param out pointer to output audio block
 /// @param in  pointer to input audio block
 /// @param vol volume cofficient between -1.0 and +1.0
 /// @param coeffShift number of bits to shiftt the coefficient
 void gainAdjust(audio_block_t *out, audio_block_t *in, float vol, int coeffShift = 0);
 template <class T>
 class RingBuffer; // forward declare so AudioDelay can use it.
 /**************************************************************************//**
 * Audio delays are a very common function in audio processing. In addition to
 * being used for simply create a delay effect, it can also be used for buffering
 * a sliding window in time of audio samples. This is useful when combining
 * several audio_block_t data buffers together to form one large buffer for
 * FFTs, etc.
 * @details The buffer works like a queue. You add new audio_block_t when available,
 * and the class will return an old buffer when it is to be discarded from the queue.<br>
 * Note that using INTERNAL memory means the class will only store a queue
 * of pointers to audio_block_t buffers, since the Teensy Audio uses a shared memory
 * approach. When using EXTERNAL memory, data is actually copyied to/from an external
 * SRAM device.
 *****************************************************************************/
 constexpr size_t AUDIO_BLOCK_SIZE = sizeof(int16_t)*AUDIO_BLOCK_SAMPLES;
 class AudioDelay {
 public:
    AudioDelay() = delete;
    /// Construct an audio buffer using INTERNAL memory by specifying the max number
    /// of audio samples you will want.
    /// @param maxSamples equal or greater than your longest delay requirement
    AudioDelay(size_t maxSamples);
    /// Construct an audio buffer using INTERNAL memory by specifying the max amount of
    /// time you will want available in the buffer.
    /// @param maxDelayTimeMs max length of time you want in the buffer specified in milliseconds
    AudioDelay(float maxDelayTimeMs);
    /// Construct an audio buffer using a slot configured with the BAGuitar::ExternalSramManager
    /// @param slot a pointer to the slot representing the memory you wish to use for the buffer.
    AudioDelay(ExtMemSlot *slot);
    ~AudioDelay();
    /// Add a new audio block into the buffer. When the buffer is filled,
    /// adding a new block will push out the oldest once which is returned.
    /// @param blockIn pointer to the most recent block of audio
    /// @returns the buffer to be discarded, or nullptr if not filled (INTERNAL), or
    /// not applicable (EXTERNAL).
    audio_block_t *addBlock(audio_block_t *blockIn);
    /// When using INTERNAL memory, returns the pointer for the specified index into buffer.
    /// @details, the most recent block is 0, 2nd most recent is 1, ..., etc.
    /// @param index the specifies how many buffers older than the current to retrieve
    /// @returns a pointer to the requested audio_block_t
    audio_block_t *getBlock(size_t index);
    /// Retrieve an audio block (or samples) from the buffer.
    /// @details when using INTERNAL memory, only supported size is AUDIO_BLOCK_SAMPLES. When using
    /// EXTERNAL, a size smaller than AUDIO_BLOCK_SAMPLES can be requested.
    /// @param dest pointer to the target audio block to write the samples to.
    /// @param offsetSamples data will start being transferred offset samples from the start of the audio buffer
    /// @param numSamples default value is AUDIO_BLOCK_SAMPLES, so typically you don't have to specify this parameter.
    /// @returns true on success, false on error.
    bool getSamples(audio_block_t *dest, size_t offsetSamples, size_t numSamples = AUDIO_BLOCK_SAMPLES);
    /// When using EXTERNAL memory, this function can return a pointer to the underlying ExtMemSlot object associated
    /// with the buffer.
    /// @returns pointer to the underlying ExtMemSlot.
    ExtMemSlot *getSlot() const { return m_slot; }
    /// Ween using INTERNAL memory, thsi function can return a pointer to the underlying RingBuffer that contains
    /// audio_block_t * pointers.
    /// @returns pointer to the underlying RingBuffer
    RingBuffer<audio_block_t*> *getRingBuffer() const { return m_ringBuffer; }
 private:
    /// enumerates whether the underlying memory buffer uses INTERNAL or EXTERNAL memory
    enum class MemType : unsigned {
        MEM_INTERNAL = 0, ///< internal audio_block_t from the Teensy Audio Library is used
        MEM_EXTERNAL      ///< external SPI based ram is used
    };
    MemType m_type;                                      ///< when 0, INTERNAL memory, when 1, external MEMORY.
    RingBuffer<audio_block_t *> *m_ringBuffer = nullptr; ///< When using INTERNAL memory, a RingBuffer will be created.
    ExtMemSlot *m_slot = nullptr;                        ///< When using EXTERNAL memory, an ExtMemSlot must be provided.
 };
 /**************************************************************************//**
 * IIR BiQuad Filter - Direct Form I <br>
 * y[n] = b0 * x[n] + b1 * x[n-1] + b2 * x[n-2] + a1 * y[n-1] + a2 * y[n-2]<br>
 * Some design tools (like Matlab assume the feedback coefficients 'a' are negated. You
 * may have to negate your 'a' coefficients.
 * @details Note that the ARM CMSIS-DSP library requires an extra zero between first
 * and second 'b' coefficients. E.g. <br>
 * {b10, 0, b11, b12, a11, a12, b20, 0, b21, b22, a21, a22, ...}
 *****************************************************************************/
 class IirBiQuadFilter {
 public:
 	IirBiQuadFilter() = delete;
 	/// Construct a Biquad filter with specified number of stages, coefficients and scaling.
 	/// @details See CMSIS-DSP documentation for more details
 	/// @param numStages number of biquad stages. Each stage has 5 coefficients.
 	/// @param coeffs pointer to an array of Q31 fixed-point coefficients (range -1 to +0.999...)
 	/// @param coeffShift coeffs are multiplied by 2^coeffShift to support coefficient range scaling
 	IirBiQuadFilter(unsigned numStages, const int32_t *coeffs, int coeffShift = 0);
 	virtual ~IirBiQuadFilter();
 	/// Process the data using the configured IIR filter
 	/// @details output and input can be the same pointer if in-place modification is desired
 	/// @param output pointer to where the output results will be written
 	/// @param input pointer to where the input data will be read from
    /// @param numSampmles number of samples to process
 	bool process(int16_t *output, int16_t *input, size_t numSamples);
 private:
 	const unsigned NUM_STAGES;
 	int32_t *m_coeffs = nullptr;
 	// ARM DSP Math library filter instance
 	arm_biquad_casd_df1_inst_q31 m_iirCfg;
 	int32_t *m_state = nullptr;
 };
 /**************************************************************************//**
 * A High-precision version of IirBiQuadFilter often necessary for complex, multistage
 * filters. This class uses CMSIS-DSP biquads with 64-bit internal precision instead
 * of 32-bit.
 *****************************************************************************/
 class IirBiQuadFilterHQ {
 public:
 	IirBiQuadFilterHQ() = delete;
    /// Construct a Biquad filter with specified number of stages, coefficients and scaling.
    /// @details See CMSIS-DSP documentation for more details
    /// @param numStages number of biquad stages. Each stage has 5 coefficients.
    /// @param coeffs pointer to an array of Q31 fixed-point coefficients (range -1 to +0.999...)
    /// @param coeffShift coeffs are multiplied by 2^coeffShift to support coefficient range scaling
 	IirBiQuadFilterHQ(unsigned numStages, const int32_t *coeffs, int coeffShift = 0);
 	virtual ~IirBiQuadFilterHQ();
    /// Process the data using the configured IIR filter
    /// @details output and input can be the same pointer if in-place modification is desired
    /// @param output pointer to where the output results will be written
    /// @param input pointer to where the input data will be read from
    /// @param numSampmles number of samples to process
 	bool process(int16_t *output, int16_t *input, size_t numSamples);
 private:
 	const unsigned NUM_STAGES;
 	int32_t *m_coeffs = nullptr;
 	// ARM DSP Math library filter instance
 	arm_biquad_cas_df1_32x64_ins_q31 m_iirCfg;
 	int64_t *m_state = nullptr;
 };
 /**************************************************************************//**
 * A single-precision floating-point biquad using CMSIS-DSP hardware instructions.
 * @details Use this when IirBiQuadFilterHQ is insufficient, since that version
 * is still faster with 64-bit fixed-point arithmetic.
 *****************************************************************************/
 class IirBiQuadFilterFloat {
 public:
 	IirBiQuadFilterFloat() = delete;
    /// Construct a Biquad filter with specified number of stages and coefficients
    /// @details See CMSIS-DSP documentation for more details
    /// @param numStages number of biquad stages. Each stage has 5 coefficients.
    /// @param coeffs pointer to an array of Q31 fixed-point coefficients (range -1 to +0.999...)
 	IirBiQuadFilterFloat(unsigned numStages, const float *coeffs);
 	virtual ~IirBiQuadFilterFloat();
    /// Process the data using the configured IIR filter
    /// @details output and input can be the same pointer if in-place modification is desired
    /// @param output pointer to where the output results will be written
    /// @param input pointer to where the input data will be read from
 	/// @param numberSampmles number of samples to process
 	bool process(float *output, float *input, size_t numSamples);
 private:
 	const unsigned NUM_STAGES;
 	float *m_coeffs = nullptr;
 	// ARM DSP Math library filter instance
 	arm_biquad_cascade_df2T_instance_f32 m_iirCfg;
 	float *m_state = nullptr;
 };
 }
 #endif /* __BAGUITAR_LIBBASICFUNCTIONS_H */
--- a/src/LibMemoryManagement.h
+++ b/src/LibMemoryManagement.h
@ -0,0 +1,212 @@
 /**************************************************************************//**
 *  @file
 *  @author Steve Lascos
 *  @company Blackaddr Audio
 *
 *  LibMemoryManagment is a class for providing access to external SPI based
 *  SRAM with the optional convience of breaking it up into 'slots' which are smaller
 *  memory entities.
 *  @details This class treats an external memory as a pool from which the user requests
 *  a block. When using that block, the user need not be concerned with where the pool
 *  it came from, they only deal with offsets from the start of their memory block. Ie.
 *  Your particular slot of memory appears to you to start at 0 and end at whatever size
 *  was requested.
 *
 *  @copyright This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *****************************************************************************/
 #ifndef __BAGUITAR_LIBMEMORYMANAGEMENT_H
 #define __BAGUITAR_LIBMEMORYMANAGEMENT_H
 #include <cstddef>
 #include "BAHardware.h"
 #include "BASpiMemory.h"
 namespace BAGuitar {
 /**************************************************************************//**
 * MemConfig contains the configuration information associated with a particular
 * SPI interface.
 *****************************************************************************/
 struct MemConfig {
 	size_t size;                  ///< the total size of the external SPI memory
 	size_t totalAvailable;        ///< the number of bytes available (remaining)
 	size_t nextAvailable;         ///< the starting point for the next available slot
 	BASpiMemory *m_spi = nullptr; ///< handle to the SPI interface
 };
 class ExternalSramManager; // forward declare so ExtMemSlot can declared friendship with it
 /**************************************************************************//**
 * ExtMemSlot provides a convenient interface to a particular slot of an
 * external memory.
 * @details the memory can be access randomly, as a single word, as a block of
 * data, or as circular queue.
 *****************************************************************************/
 class ExtMemSlot {
 public:
 	/// clear the entire contents of the slot by writing zeros
 	/// @returns true on success
 	bool clear();
 	/// set a new write position (in bytes) for circular operation
 	/// @param offsetBytes moves the write pointer to the specified offset from the slot start
 	/// @returns true on success, else false if offset is beyond slot boundaries.
 	bool setWritePosition(size_t offsetBytes);
 	/// returns the currently set write pointer pointer
 	/// @returns the write position value
 	size_t getWritePosition() const { return m_currentWrPosition-m_start; }
 	/// set a new read position (in bytes) for circular operation
 	/// @param offsetBytes moves the read pointer to the specified offset from the slot start
 	/// @returns true on success, else false if offset is beyond slot boundaries.
 	bool setReadPosition(size_t offsetBytes);
 	/// returns the currently set read pointer pointer
 	/// @returns the read position value
 	size_t getReadPosition() const { return m_currentRdPosition-m_start; }
 	/// Write a block of 16-bit data to the memory at the specified offset
 	/// @param offsetWords offset in 16-bit words from start of slot
 	/// @param src pointer to start of block of 16-bit data
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool write16(size_t offsetWords, int16_t *src, size_t numWords);
 	/// Write a block of zeros (16-bit) to the memory at the specified offset
 	/// @param offsetWords offset in 16-bit words from start of slot
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool zero16(size_t offsetWords, size_t numWords);
 	/// Read a block of 16-bit data from the memory at the specified location
 	/// @param offsetWords offset in 16-bit words from start of slot
 	/// @param dest pointer to destination for the read data
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool read16(size_t offsetWords, int16_t *dest, size_t numWords);
 	/// Read the next in memory during circular operation
 	/// @returns the next 16-bit data word in memory
 	uint16_t readAdvance16();
 	/// Read the next block of numWords during circular operation
 	/// @details, dest is ignored when using DMA
 	/// @param dest pointer to the destination of the read.
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool readAdvance16(int16_t *dest, size_t numWords);
 	/// Write a block of 16-bit data from the specified location in circular operation
 	/// @param src pointer to the start of the block of data to write to memory
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool writeAdvance16(int16_t *src, size_t numWords);
 	/// Write a single 16-bit data to the next location in circular operation
 	/// @param data the 16-bit word to transfer
 	/// @returns true on success, else false on error
 	bool writeAdvance16(int16_t data); // write just one data
 	/// Write a block of 16-bit data zeros in circular operation
 	/// @param numWords number of 16-bit words to transfer
 	/// @returns true on success, else false on error
 	bool zeroAdvance16(size_t numWords);
 	/// Get the size of the memory slot
 	/// @returns size of the slot in bytes
 	size_t size() const { return m_size; }
 	/// Ensures the underlying SPI interface is enabled
 	/// @returns true on success, false on error
 	bool enable() const;
 	/// Checks whether underlying SPI interface is enabled
 	/// @returns true if enabled, false if not enabled
 	bool isEnabled() const;
 	bool isUseDma() const { return m_useDma; }
 	bool isWriteBusy() const;
 	bool isReadBusy() const;
 	/// DEBUG USE: prints out the slot member variables
 	void printStatus(void) const;
 private:
 	friend ExternalSramManager;     ///< gives the manager access to the private variables
 	bool   m_valid = false;         ///< After a slot is successfully configured by the manager it becomes valid
 	size_t m_start = 0;             ///< the external memory address in bytes where this slot starts
 	size_t m_end = 0;               ///< the external memory address in bytes where this slot ends (inclusive)
 	size_t m_currentWrPosition = 0; ///< current write pointer for circular operation
 	size_t m_currentRdPosition = 0; ///< current read pointer for circular operation
 	size_t m_size = 0;              ///< size of this slot in bytes
 	bool   m_useDma = false;        ///< when TRUE, BASpiMemoryDMA will be used.
 	SpiDeviceId m_spiId;            ///< the SPI Device ID
 	BASpiMemory *m_spi = nullptr;   ///< pointer to an instance of the BASpiMemory interface class
 };
 /**************************************************************************//**
 * ExternalSramManager provides a class to handle dividing an external SPI RAM
 * into independent slots for general use.
 * @details the class does not support deallocated memory because this would cause
 * fragmentation.
 *****************************************************************************/
 class ExternalSramManager final {
 public:
 	ExternalSramManager();
 	/// The manager is constructed by specifying how many external memories to handle allocations for
 	/// @param numMemories the number of external memories
 	ExternalSramManager(unsigned numMemories);
 	virtual ~ExternalSramManager();
 	/// Query the amount of available (unallocated) memory
 	/// @details note that currently, memory cannot be allocated.
 	/// @param mem specifies which memory to query, default is memory 0
 	/// @returns the available memory in bytes
 	size_t availableMemory(BAGuitar::MemSelect mem = BAGuitar::MemSelect::MEM0);
 	/// Request memory be allocated for the provided slot
 	/// @param slot a pointer to the global slot object to which memory will be allocated
 	/// @param delayMilliseconds request the amount of memory based on required time for audio samples, rather than number of bytes.
 	/// @param mem specify which external memory to allocate from
 	/// @param useDma when true, DMA is used for SPI port, else transfers block until complete
 	/// @returns true on success, otherwise false on error
 	bool requestMemory(ExtMemSlot *slot, float delayMilliseconds, BAGuitar::MemSelect mem = BAGuitar::MemSelect::MEM0, bool useDma = false);
 	/// Request memory be allocated for the provided slot
 	/// @param slot a pointer to the global slot object to which memory will be allocated
 	/// @param sizeBytes request the amount of memory in bytes to request
 	/// @param mem specify which external memory to allocate from
    /// @param useDma when true, DMA is used for SPI port, else transfers block until complete
 	/// @returns true on success, otherwise false on error
 	bool requestMemory(ExtMemSlot *slot, size_t sizeBytes, BAGuitar::MemSelect mem = BAGuitar::MemSelect::MEM0, bool useDma = false);
 private:
 	static bool m_configured; ///< there should only be one instance of ExternalSramManager in the whole project
 	static MemConfig m_memConfig[BAGuitar::NUM_MEM_SLOTS]; ///< store the configuration information for each external memory
 };
 }
 #endif /* __LIBMEMORYMANAGEMENT_H */
--- a/src/common/AudioDelay.cpp
+++ b/src/common/AudioDelay.cpp
@ -0,0 +1,171 @@
 /*
 * AudioDelay.cpp
 *
 *  Created on: January 1, 2018
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include "Audio.h"
 #include "LibBasicFunctions.h"
 namespace BAGuitar {
 ////////////////////////////////////////////////////
 // AudioDelay
 ////////////////////////////////////////////////////
 AudioDelay::AudioDelay(size_t maxSamples)
 : m_slot(nullptr)
 {
    m_type = (MemType::MEM_INTERNAL);
 	// INTERNAL memory consisting of audio_block_t data structures.
 	QueuePosition pos = calcQueuePosition(maxSamples);
 	m_ringBuffer = new RingBuffer<audio_block_t *>(pos.index+2); // If the delay is in queue x, we need to overflow into x+1, thus x+2 total buffers.
 }
 AudioDelay::AudioDelay(float maxDelayTimeMs)
 : AudioDelay(calcAudioSamples(maxDelayTimeMs))
 {
 }
 AudioDelay::AudioDelay(ExtMemSlot *slot)
 {
 	m_type = (MemType::MEM_EXTERNAL);
 	m_slot = slot;
 }
 AudioDelay::~AudioDelay()
 {
    if (m_ringBuffer) delete m_ringBuffer;
 }
 audio_block_t* AudioDelay::addBlock(audio_block_t *block)
 {
 	audio_block_t *blockToRelease = nullptr;
 	if (m_type == (MemType::MEM_INTERNAL)) {
 		// INTERNAL memory
 		// purposefully don't check if block is valid, the ringBuffer can support nullptrs
 		if ( m_ringBuffer->size() >= m_ringBuffer->max_size() ) {
 			// pop before adding
 			blockToRelease = m_ringBuffer->front();
 			m_ringBuffer->pop_front();
 		}
 		// add the new buffer
 		m_ringBuffer->push_back(block);
 		return blockToRelease;
 	} else {
 		// EXTERNAL memory
 		if (!m_slot) { Serial.println("addBlock(): m_slot is not valid"); }
 		if (block) {
 			// this causes pops
 		    m_slot->writeAdvance16(block->data, AUDIO_BLOCK_SAMPLES);
 		}
 		blockToRelease =  block;
 	}
 	return blockToRelease;
 }
 audio_block_t* AudioDelay::getBlock(size_t index)
 {
 	audio_block_t *ret = nullptr;
 	if (m_type == (MemType::MEM_INTERNAL)) {
 		ret =  m_ringBuffer->at(m_ringBuffer->get_index_from_back(index));
 	}
 	return ret;
 }
 bool AudioDelay::getSamples(audio_block_t *dest, size_t offsetSamples, size_t numSamples)
 {
 	if (!dest) {
 		Serial.println("getSamples(): dest is invalid");
 		return false;
 	}
 	if (m_type == (MemType::MEM_INTERNAL)) {
 		QueuePosition position = calcQueuePosition(offsetSamples);
 		size_t index = position.index;
 		audio_block_t *currentQueue0 = m_ringBuffer->at(m_ringBuffer->get_index_from_back(index));
 		// The latest buffer is at the back. We need index+1 counting from the back.
 		audio_block_t *currentQueue1 = m_ringBuffer->at(m_ringBuffer->get_index_from_back(index+1));
 		// check if either queue is invalid, if so just zero the destination buffer
 		if ( (!currentQueue0) || (!currentQueue0) ) {
 			// a valid entry is not in all queue positions while it is filling, use zeros
 			memset(static_cast<void*>(dest->data), 0, numSamples * sizeof(int16_t));
 			return true;
 		}
 		if (position.offset == 0) {
 			// single transfer
 			memcpy(static_cast<void*>(dest->data), static_cast<void*>(currentQueue0->data), numSamples * sizeof(int16_t));
 			return true;
 		}
 		// Otherwise we need to break the transfer into two memcpy because it will go across two source queues.
 		// Audio is stored in reverse order. That means the first sample (in time) goes in the last location in the audio block.
 		int16_t *destStart = dest->data;
 		int16_t *srcStart;
 		// Break the transfer into two. Copy the 'older' data first then the 'newer' data with respect to current time.
 		//currentQueue = m_ringBuffer->at(m_ringBuffer->get_index_from_back(index+1)); // The latest buffer is at the back. We need index+1 counting from the back.
 		srcStart  = (currentQueue1->data + AUDIO_BLOCK_SAMPLES - position.offset);
 		size_t numData = position.offset;
 		memcpy(static_cast<void*>(destStart), static_cast<void*>(srcStart), numData * sizeof(int16_t));
 		//currentQueue = m_ringBuffer->at(m_ringBuffer->get_index_from_back(index)); // now grab the queue where the 'first' data sample was
 		destStart += numData; // we already wrote numData so advance by this much.
 		srcStart  = (currentQueue0->data);
 		numData = AUDIO_BLOCK_SAMPLES - numData;
 		memcpy(static_cast<void*>(destStart), static_cast<void*>(srcStart), numData * sizeof(int16_t));
 		return true;
 	} else {
 		// EXTERNAL Memory
 		if (numSamples*sizeof(int16_t) <= m_slot->size() ) {
 			int currentPositionBytes = (int)m_slot->getWritePosition() - (int)(AUDIO_BLOCK_SAMPLES*sizeof(int16_t));
 			size_t offsetBytes = offsetSamples * sizeof(int16_t);
 			if ((int)offsetBytes <= currentPositionBytes) {
 				m_slot->setReadPosition(currentPositionBytes - offsetBytes);
 			} else {
 				// It's going to wrap around to the end of the slot
 				int readPosition = (int)m_slot->size() + currentPositionBytes - offsetBytes;
 				m_slot->setReadPosition((size_t)readPosition);
 			}
 			// This causes pops
 			m_slot->readAdvance16(dest->data, AUDIO_BLOCK_SAMPLES);
 			return true;
 		} else {
 			// numSampmles is > than total slot size
 			Serial.println("getSamples(): ERROR numSamples > total slot size");
 			return false;
 		}
 	}
 }
 }
--- a/src/common/AudioHelpers.cpp
+++ b/src/common/AudioHelpers.cpp
@ -0,0 +1,78 @@
 /*
 * AudioHelpers.cpp
 *
 *  Created on: January 1, 2018
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include "Audio.h"
 #include "LibBasicFunctions.h"
 namespace BAGuitar {
 size_t calcAudioSamples(float milliseconds)
 {
 	return (size_t)((milliseconds*(AUDIO_SAMPLE_RATE_EXACT/1000.0f))+0.5f);
 }
 float calcAudioTimeMs(size_t numSamples)
 {
 	return ((float)(numSamples) / AUDIO_SAMPLE_RATE_EXACT) * 1000.0f;
 }
 QueuePosition calcQueuePosition(size_t numSamples)
 {
 	QueuePosition queuePosition;
 	queuePosition.index = (int)(numSamples / AUDIO_BLOCK_SAMPLES);
 	queuePosition.offset = numSamples % AUDIO_BLOCK_SAMPLES;
 	return queuePosition;
 }
 QueuePosition calcQueuePosition(float milliseconds) {
 	size_t numSamples = (int)((milliseconds*(AUDIO_SAMPLE_RATE_EXACT/1000.0f))+0.5f);
 	return calcQueuePosition(numSamples);
 }
 size_t calcOffset(QueuePosition position)
 {
 	return (position.index*AUDIO_BLOCK_SAMPLES) + position.offset;
 }
 void alphaBlend(audio_block_t *out, audio_block_t *dry, audio_block_t* wet, float mix)
 {
 	// ARM DSP optimized
 	int16_t wetBuffer[AUDIO_BLOCK_SAMPLES];
 	int16_t dryBuffer[AUDIO_BLOCK_SAMPLES];
 	int16_t scaleFractWet = (int16_t)(mix * 32767.0f);
 	int16_t scaleFractDry = 32767-scaleFractWet;
 	arm_scale_q15(dry->data, scaleFractDry, 0, dryBuffer, AUDIO_BLOCK_SAMPLES);
 	arm_scale_q15(wet->data, scaleFractWet, 0, wetBuffer, AUDIO_BLOCK_SAMPLES);
 	arm_add_q15(wetBuffer, dryBuffer, out->data, AUDIO_BLOCK_SAMPLES);
 }
 void gainAdjust(audio_block_t *out, audio_block_t *in, float vol, int coeffShift)
 {
 	int16_t scale = (int16_t)(vol * 32767.0f);
 	arm_scale_q15(in->data, scale, coeffShift, out->data, AUDIO_BLOCK_SAMPLES);
 }
 void clearAudioBlock(audio_block_t *block)
 {
 	memset(block->data, 0, sizeof(int16_t)*AUDIO_BLOCK_SAMPLES);
 }
 }
--- a/src/common/ExtMemSlot.cpp
+++ b/src/common/ExtMemSlot.cpp
@ -0,0 +1,235 @@
 /*
 * ExtMemSlot.cpp
 *
 *  Created on: Jan 19, 2018
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <cstring>
 #include <new>
 #include "Audio.h"
 #include "LibMemoryManagement.h"
 namespace BAGuitar {
 /////////////////////////////////////////////////////////////////////////////
 // MEM SLOT
 /////////////////////////////////////////////////////////////////////////////
 bool ExtMemSlot::clear()
 {
 	if (!m_valid) { return false; }
 	m_spi->zero16(m_start, m_size);
 	return true;
 }
 bool ExtMemSlot::setWritePosition(size_t offsetBytes)
 {
 	if (m_start + offsetBytes <= m_end) {
 		m_currentWrPosition = m_start + offsetBytes;
 		return true;
 	} else { return false; }
 }
 bool ExtMemSlot::write16(size_t offsetWords, int16_t *src, size_t numWords)
 {
 	if (!m_valid) { return false; }
 	size_t writeStart = m_start + sizeof(int16_t)*offsetWords; // 2x because int16 is two bytes per data
 	size_t numBytes = sizeof(int16_t)*numWords;
 	if ((writeStart + numBytes-1) <= m_end) {
 		m_spi->write16(writeStart, reinterpret_cast<uint16_t*>(src), numWords); // cast audio data to uint
 		return true;
 	} else {
 		// this would go past the end of the memory slot, do not perform the write
 		return false;
 	}
 }
 bool ExtMemSlot::setReadPosition(size_t offsetBytes)
 {
 	if (m_start + offsetBytes <= m_end) {
 		m_currentRdPosition = m_start + offsetBytes;
 		return true;
 	} else {
 		return false;
 	}
 }
 bool ExtMemSlot::zero16(size_t offsetWords, size_t numWords)
 {
 	if (!m_valid) { return false; }
 	size_t writeStart = m_start + sizeof(int16_t)*offsetWords;
 	size_t numBytes = sizeof(int16_t)*numWords;
 	if ((writeStart + numBytes-1) <= m_end) {
 		m_spi->zero16(writeStart, numWords); // cast audio data to uint
 		return true;
 	} else {
 		// this would go past the end of the memory slot, do not perform the write
 		return false;
 	}
 }
 bool ExtMemSlot::read16(size_t offsetWords, int16_t *dest, size_t numWords)
 {
 	if (!dest) return false; // invalid destination
 	size_t readOffset = m_start + sizeof(int16_t)*offsetWords;
 	size_t numBytes = sizeof(int16_t)*numWords;
 	if ((readOffset + numBytes-1) <= m_end) {
 		m_spi->read16(readOffset, reinterpret_cast<uint16_t*>(dest), numWords);
 		return true;
 	} else {
 		// this would go past the end of the memory slot, do not perform the read
 		return false;
 	}
 }
 uint16_t ExtMemSlot::readAdvance16()
 {
 	uint16_t val = m_spi->read16(m_currentRdPosition);
 	if (m_currentRdPosition < m_end-1) {
 		m_currentRdPosition +=2; // position is in bytes and we read two
 	} else {
 		m_currentRdPosition = m_start;
 	}
 	return val;
 }
 bool ExtMemSlot::readAdvance16(int16_t *dest, size_t numWords)
 {
    if (!m_valid) { return false; }
    size_t numBytes = sizeof(int16_t)*numWords;
    if (m_currentRdPosition + numBytes-1 <= m_end) {
        // entire block fits in memory slot without wrapping
        m_spi->read16(m_currentRdPosition, reinterpret_cast<uint16_t*>(dest), numWords); // cast audio data to uint.
        m_currentRdPosition += numBytes;
    } else {
        // this read will wrap the memory slot
        size_t rdBytes = m_end - m_currentRdPosition + 1;
        size_t rdDataNum = rdBytes >> 1; // divide by two to get the number of data
        m_spi->read16(m_currentRdPosition, reinterpret_cast<uint16_t*>(dest), rdDataNum);
        size_t remainingData = numWords - rdDataNum;
        m_spi->read16(m_start, reinterpret_cast<uint16_t*>(dest + rdDataNum), remainingData); // write remaining bytes are start
        m_currentRdPosition = m_start + (remainingData*sizeof(int16_t));
    }
    return true;
 }
 bool ExtMemSlot::writeAdvance16(int16_t *src, size_t numWords)
 {
 	if (!m_valid) { return false; }
 	size_t numBytes = sizeof(int16_t)*numWords;
 	if (m_currentWrPosition + numBytes-1 <= m_end) {
 		// entire block fits in memory slot without wrapping
 		m_spi->write16(m_currentWrPosition, reinterpret_cast<uint16_t*>(src), numWords); // cast audio data to uint.
 		m_currentWrPosition += numBytes;
 	} else {
 		// 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));
 	}
 	return true;
 }
 bool ExtMemSlot::zeroAdvance16(size_t numWords)
 {
 	if (!m_valid) { return false; }
 	size_t numBytes = 2*numWords;
 	if (m_currentWrPosition + numBytes-1 <= m_end) {
 		// entire block fits in memory slot without wrapping
 		m_spi->zero16(m_currentWrPosition, numWords); // cast audio data to uint.
 		m_currentWrPosition += numBytes;
 	} else {
 		// this write will wrap the memory slot
 		size_t wrBytes = m_end - m_currentWrPosition + 1;
 		size_t wrDataNum = wrBytes >> 1;
 		m_spi->zero16(m_currentWrPosition, wrDataNum);
 		size_t remainingWords = numWords - wrDataNum; // calculate the remaining bytes
 		m_spi->zero16(m_start, remainingWords); // write remaining bytes are start
 		m_currentWrPosition = m_start + remainingWords*sizeof(int16_t);
 	}
 	return true;
 }
 bool ExtMemSlot::writeAdvance16(int16_t data)
 {
 	if (!m_valid) { return false; }
 	m_spi->write16(m_currentWrPosition, static_cast<uint16_t>(data));
 	if (m_currentWrPosition < m_end-1) {
 		m_currentWrPosition+=2; // wrote two bytes
 	} else {
 		m_currentWrPosition = m_start;
 	}
 	return true;
 }
 bool ExtMemSlot::enable() const
 {
 	if (m_spi) {
 		Serial.println("ExtMemSlot::enable()");
 		m_spi->begin();
 		return true;
 	}
 	else {
 		Serial.println("ExtMemSlot m_spi is nullptr");
 		return false;
 	}
 }
 bool ExtMemSlot::isEnabled() const
 {
 	if (m_spi) { return m_spi->isStarted(); }
 	else return false;
 }
 bool ExtMemSlot::isWriteBusy() const
 {
 	if (m_useDma) {
 		return (static_cast<BASpiMemoryDMA*>(m_spi))->isWriteBusy();
 	} else { return false; }
 }
 bool ExtMemSlot::isReadBusy() const
 {
 	if (m_useDma) {
 		return (static_cast<BASpiMemoryDMA*>(m_spi))->isReadBusy();
 	} else { return false; }
 }
 void ExtMemSlot::printStatus(void) const
 {
 	Serial.println(String("valid:") + m_valid + String(" m_start:") + m_start + \
 			       String(" m_end:") + m_end + String(" m_currentWrPosition: ") + m_currentWrPosition + \
 				   String(" m_currentRdPosition: ") + m_currentRdPosition + \
 				   String(" m_size:") + m_size);
 }
 }
--- a/src/common/ExternalSramManager.cpp
+++ b/src/common/ExternalSramManager.cpp
@ -0,0 +1,120 @@
 /*
 * LibMemoryManagement.cpp
 *
 *  Created on: Jan 19, 2018
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <cstring>
 #include <new>
 #include "Audio.h"
 #include "LibMemoryManagement.h"
 namespace BAGuitar {
 /////////////////////////////////////////////////////////////////////////////
 // EXTERNAL SRAM MANAGER
 /////////////////////////////////////////////////////////////////////////////
 bool ExternalSramManager::m_configured = false;
 MemConfig ExternalSramManager::m_memConfig[BAGuitar::NUM_MEM_SLOTS];
 ExternalSramManager::ExternalSramManager(unsigned numMemories)
 {
 	// Initialize the static memory configuration structs
 	if (!m_configured) {
 		for (unsigned i=0; i < NUM_MEM_SLOTS; i++) {
 			m_memConfig[i].size           = MEM_MAX_ADDR[i];
 			m_memConfig[i].totalAvailable = MEM_MAX_ADDR[i];
 			m_memConfig[i].nextAvailable  = 0;
 			m_memConfig[i].m_spi = nullptr;
 		}
 		m_configured = true;
 	}
 }
 ExternalSramManager::ExternalSramManager()
 : ExternalSramManager(1)
 {
 }
 ExternalSramManager::~ExternalSramManager()
 {
 	for (unsigned i=0; i < NUM_MEM_SLOTS; i++) {
 		if (m_memConfig[i].m_spi) { delete m_memConfig[i].m_spi; }
 	}
 }
 size_t ExternalSramManager::availableMemory(BAGuitar::MemSelect mem)
 {
 	return m_memConfig[mem].totalAvailable;
 }
 bool ExternalSramManager::requestMemory(ExtMemSlot *slot, float delayMilliseconds, BAGuitar::MemSelect mem, bool useDma)
 {
 	// convert the time to numer of samples
 	size_t delayLengthInt = (size_t)((delayMilliseconds*(AUDIO_SAMPLE_RATE_EXACT/1000.0f))+0.5f);
 	return requestMemory(slot, delayLengthInt * sizeof(int16_t), mem, useDma);
 }
 bool ExternalSramManager::requestMemory(ExtMemSlot *slot, size_t sizeBytes, BAGuitar::MemSelect mem, bool useDma)
 {
 	if (m_memConfig[mem].totalAvailable >= sizeBytes) {
 		Serial.println(String("Configuring a slot for mem ") + mem);
 		// there is enough available memory for this request
 		slot->m_start = m_memConfig[mem].nextAvailable;
 		slot->m_end   = slot->m_start + sizeBytes -1;
 		slot->m_currentWrPosition = slot->m_start; // init to start of slot
 		slot->m_currentRdPosition = slot->m_start; // init to start of slot
 		slot->m_size = sizeBytes;
 		if (!m_memConfig[mem].m_spi) {
 		    if (useDma) {
 		        m_memConfig[mem].m_spi = new BAGuitar::BASpiMemoryDMA(static_cast<BAGuitar::SpiDeviceId>(mem));
 		        slot->m_useDma = true;
 		    } else {
 		        m_memConfig[mem].m_spi = new BAGuitar::BASpiMemory(static_cast<BAGuitar::SpiDeviceId>(mem));
 		        slot->m_useDma = false;
 		    }
 			if (!m_memConfig[mem].m_spi) {
 			} else {
 				Serial.println("Calling spi begin()");
 				m_memConfig[mem].m_spi->begin();
 			}
 		}
 		slot->m_spi = m_memConfig[mem].m_spi;
 		// Update the mem config
 		m_memConfig[mem].nextAvailable   = slot->m_end+1;
 		m_memConfig[mem].totalAvailable -= sizeBytes;
 		slot->m_valid = true;
 		if (!slot->isEnabled()) { slot->enable(); }
 		Serial.println("Clear the memory\n"); Serial.flush();
 		slot->clear();
 		Serial.println("Done Request memory\n"); Serial.flush();
 		return true;
 	} else {
 		// there is not enough memory available for the request
 		return false;
 	}
 }
 }
--- a/src/common/IirBiquadFilter.cpp
+++ b/src/common/IirBiquadFilter.cpp
@ -0,0 +1,145 @@
 /*
 * IirBiquadFilter.cpp
 *
 *  Created on: January 1, 2018
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include "Audio.h"
 #include "LibBasicFunctions.h"
 namespace BAGuitar {
 ////////////////////////////////////////////////////
 // IirBiQuadFilter
 ////////////////////////////////////////////////////
 IirBiQuadFilter::IirBiQuadFilter(unsigned numStages, const int32_t *coeffs, int coeffShift)
 : NUM_STAGES(numStages)
 {
 	m_coeffs = new int32_t[5*numStages];
 	memcpy(m_coeffs, coeffs, 5*numStages * sizeof(int32_t));
 	m_state  = new int32_t[4*numStages];
 	arm_biquad_cascade_df1_init_q31(&m_iirCfg, numStages, m_coeffs, m_state, coeffShift);
 }
 IirBiQuadFilter::~IirBiQuadFilter()
 {
 	if (m_coeffs) delete [] m_coeffs;
 	if (m_state)  delete [] m_state;
 }
 bool IirBiQuadFilter::process(int16_t *output, int16_t *input, size_t numSamples)
 {
 	if (!output) return false;
 	if (!input) {
 		// send zeros
 		memset(output, 0, numSamples * sizeof(int16_t));
 	} else {
 		// create convertion buffers on teh stack
 		int32_t input32[numSamples];
 		int32_t output32[numSamples];
 		for (size_t i=0; i<numSamples; i++) {
 			input32[i] = (int32_t)(input[i]);
 		}
 		arm_biquad_cascade_df1_fast_q31(&m_iirCfg, input32, output32, numSamples);
 		for (size_t i=0; i<numSamples; i++) {
 			output[i] = (int16_t)(output32[i] & 0xffff);
 		}
 	}
 	return true;
 }
 // HIGH QUALITY
 IirBiQuadFilterHQ::IirBiQuadFilterHQ(unsigned numStages, const int32_t *coeffs, int coeffShift)
 : NUM_STAGES(numStages)
 {
 	m_coeffs = new int32_t[5*numStages];
 	memcpy(m_coeffs, coeffs, 5*numStages * sizeof(int32_t));
 	m_state = new int64_t[4*numStages];;
 	arm_biquad_cas_df1_32x64_init_q31(&m_iirCfg, numStages, m_coeffs, m_state, coeffShift);
 }
 IirBiQuadFilterHQ::~IirBiQuadFilterHQ()
 {
 	if (m_coeffs) delete [] m_coeffs;
 	if (m_state)  delete [] m_state;
 }
 bool IirBiQuadFilterHQ::process(int16_t *output, int16_t *input, size_t numSamples)
 {
 	if (!output) return false;
 	if (!input) {
 		// send zeros
 		memset(output, 0, numSamples * sizeof(int16_t));
 	} else {
 		// create convertion buffers on teh stack
 		int32_t input32[numSamples];
 		int32_t output32[numSamples];
 		for (size_t i=0; i<numSamples; i++) {
 			input32[i] = (int32_t)(input[i]);
 		}
 		arm_biquad_cas_df1_32x64_q31(&m_iirCfg, input32, output32, numSamples);
 		for (size_t i=0; i<numSamples; i++) {
 			output[i] = (int16_t)(output32[i] & 0xffff);
 		}
 	}
 	return true;
 }
 // FLOAT
 IirBiQuadFilterFloat::IirBiQuadFilterFloat(unsigned numStages, const float *coeffs)
 : NUM_STAGES(numStages)
 {
 	m_coeffs = new float[5*numStages];
 	memcpy(m_coeffs, coeffs, 5*numStages * sizeof(float));
 	m_state = new float[4*numStages];;
 	arm_biquad_cascade_df2T_init_f32(&m_iirCfg, numStages, m_coeffs, m_state);
 }
 IirBiQuadFilterFloat::~IirBiQuadFilterFloat()
 {
 	if (m_coeffs) delete [] m_coeffs;
 	if (m_state)  delete [] m_state;
 }
 bool IirBiQuadFilterFloat::process(float *output, float *input, size_t numSamples)
 {
 	if (!output) return false;
 	if (!input) {
 		// send zeros
 		memset(output, 0, numSamples * sizeof(float));
 	} else {
 		arm_biquad_cascade_df2T_f32(&m_iirCfg, input, output, numSamples);
 	}
 	return true;
 }
 }
--- a/src/effects/AudioEffectAnalogDelay.cpp
+++ b/src/effects/AudioEffectAnalogDelay.cpp
@ -0,0 +1,279 @@
 /*
 * AudioEffectAnalogDelay.cpp
 *
 *  Created on: Jan 7, 2018
 *      Author: slascos
 */
 #include <new>
 #include "AudioEffectAnalogDelay.h"
 namespace BAGuitar {
 constexpr int MIDI_CHANNEL = 0;
 constexpr int MIDI_CONTROL = 1;
 // BOSS DM-3 Filters
 constexpr unsigned NUM_IIR_STAGES = 4;
 constexpr unsigned IIR_COEFF_SHIFT = 2;
 constexpr int32_t DEFAULT_COEFFS[5*NUM_IIR_STAGES] = {
    536870912,            988616936,            455608573,            834606945,           -482959709,
    536870912,           1031466345,            498793368,            965834205,           -467402235,
    536870912,           1105821939,            573646688,            928470657,           -448083489,
    2339,                      5093,                 2776,            302068995,              4412722
 };
 AudioEffectAnalogDelay::AudioEffectAnalogDelay(float maxDelayMs)
 : AudioStream(1, m_inputQueueArray)
 {
 	m_memory = new AudioDelay(maxDelayMs);
 	m_maxDelaySamples = calcAudioSamples(maxDelayMs);
 	m_iir  = new IirBiQuadFilterHQ(NUM_IIR_STAGES, reinterpret_cast<const int32_t *>(&DEFAULT_COEFFS), IIR_COEFF_SHIFT);
 }
 AudioEffectAnalogDelay::AudioEffectAnalogDelay(size_t numSamples)
 : AudioStream(1, m_inputQueueArray)
 {
 	m_memory = new AudioDelay(numSamples);
 	m_maxDelaySamples = numSamples;
 	m_iir = new IirBiQuadFilterHQ(NUM_IIR_STAGES, reinterpret_cast<const int32_t *>(&DEFAULT_COEFFS), IIR_COEFF_SHIFT);
 }
 // requires preallocated memory large enough
 AudioEffectAnalogDelay::AudioEffectAnalogDelay(ExtMemSlot *slot)
 : AudioStream(1, m_inputQueueArray)
 {
 	m_memory = new AudioDelay(slot);
 	m_maxDelaySamples = (slot->size() / sizeof(int16_t));
 	m_externalMemory = true;
 	m_iir = new IirBiQuadFilterHQ(NUM_IIR_STAGES, reinterpret_cast<const int32_t *>(&DEFAULT_COEFFS), IIR_COEFF_SHIFT);
 }
 AudioEffectAnalogDelay::~AudioEffectAnalogDelay()
 {
 	if (m_memory) delete m_memory;
 	if (m_iir) delete m_iir;
 }
 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
 	if (m_bypass == true) {
 		// 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
    // get the data. If using external memory with DMA, this won't be filled until
    // later.
    m_memory->getSamples(blockToOutput, m_delaySamples);
    // If using DMA, we need something else to do while that read executes, so
    // move on to input preprocessing
 	// Preprocessing
 	audio_block_t *preProcessed = allocate();
 	// 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);
 	// BACK TO OUTPUT PROCESSING
 	// Check if external DMA, if so, we need to be sure the read is completed
 	if (m_externalMemory && m_memory->getSlot()->isUseDma()) {
 	    // Using DMA
 		while (m_memory->getSlot()->isReadBusy()) {}
 	}
 	// perform the wet/dry mix mix
 	m_postProcessing(blockToOutput, inputAudioBlock, blockToOutput);
 	transmit(blockToOutput);
 	release(inputAudioBlock);
 	release(m_previousBlock);
 	m_previousBlock = blockToOutput;
 //	if (m_externalMemory && m_memory->getSlot()->isUseDma()) {
 //	    // Using DMA
 //		if (m_blockToRelease) release(m_blockToRelease);
 //		m_blockToRelease = blockToRelease;
 //	}
 	if (m_blockToRelease) release(m_blockToRelease);
 	m_blockToRelease = blockToRelease;
 }
 void AudioEffectAnalogDelay::delay(float milliseconds)
 {
 	size_t delaySamples = calcAudioSamples(milliseconds);
 	if (!m_memory) { Serial.println("delay(): m_memory is not valid"); }
 	if (!m_externalMemory) {
 		// internal memory
 		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();
 		if (!slot) { Serial.println("ERROR: slot ptr is not valid"); }
 		if (!slot->isEnabled()) {
 			slot->enable();
 			Serial.println("WEIRD: slot was not enabled");
 		}
 	}
 	m_delaySamples = delaySamples;
 }
 void AudioEffectAnalogDelay::delay(size_t delaySamples)
 {
 	if (!m_memory) { Serial.println("delay(): m_memory is not valid"); }
 	if (!m_externalMemory) {
 		// internal memory
 		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();
 		if (!slot->isEnabled()) {
 			slot->enable();
 		}
 	}
 	m_delaySamples= delaySamples;
 }
 void AudioEffectAnalogDelay::m_preProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet)
 {
 	if ( out && dry && wet) {
 		alphaBlend(out, dry, wet, m_feedback);
 		m_iir->process(out->data, out->data, AUDIO_BLOCK_SAMPLES);
 	} else if (dry) {
 		memcpy(out->data, dry->data, sizeof(int16_t) * AUDIO_BLOCK_SAMPLES);
 	}
 }
 void AudioEffectAnalogDelay::m_postProcessing(audio_block_t *out, audio_block_t *dry, audio_block_t *wet)
 {
 	if (!out) return; // no valid output buffer
 	if ( out && dry && wet) {
 		// Simulate the LPF IIR nature of the analog systems
 		//m_iir->process(wet->data, wet->data, AUDIO_BLOCK_SAMPLES);
 		alphaBlend(out, dry, wet, m_mix);
 	} else if (dry) {
 		memcpy(out->data, dry->data, sizeof(int16_t) * AUDIO_BLOCK_SAMPLES);
 	}
 	// Set the output volume
 	gainAdjust(out, out, m_volume, 1);
 }
 void AudioEffectAnalogDelay::processMidi(int channel, int control, int value)
 {
 	float val = (float)value / 127.0f;
 	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); }
 		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);
 		return;
 	}
 	if ((m_midiConfig[BYPASS][MIDI_CHANNEL] == channel) &&
        (m_midiConfig[BYPASS][MIDI_CONTROL] == control)) {
 		// Bypass
 		if (value >= 65) { bypass(false); Serial.println(String("AudioEffectAnalogDelay::not bypassed -> ON") + value); }
 		else { bypass(true); Serial.println(String("AudioEffectAnalogDelay::bypassed -> OFF") + value); }
 		return;
 	}
 	if ((m_midiConfig[FEEDBACK][MIDI_CHANNEL] == channel) &&
        (m_midiConfig[FEEDBACK][MIDI_CONTROL] == control)) {
 		// Feedback
 		Serial.println(String("AudioEffectAnalogDelay::feedback: ") + 100*val + String("%"));
 		feedback(val);
 		return;
 	}
 	if ((m_midiConfig[MIX][MIDI_CHANNEL] == channel) &&
        (m_midiConfig[MIX][MIDI_CONTROL] == control)) {
 		// Mix
 		Serial.println(String("AudioEffectAnalogDelay::mix: Dry: ") + 100*(1-val) + String("% Wet: ") + 100*val );
 		mix(val);
 		return;
 	}
 	if ((m_midiConfig[VOLUME][MIDI_CHANNEL] == channel) &&
        (m_midiConfig[VOLUME][MIDI_CONTROL] == control)) {
 		// Volume
 		Serial.println(String("AudioEffectAnalogDelay::volume: ") + 100*val + String("%"));
 		volume(val);
 		return;
 	}
 }
 void AudioEffectAnalogDelay::mapMidiControl(int parameter, int midiCC, int midiChannel)
 {
 	if (parameter >= NUM_CONTROLS) {
 		return ; // Invalid midi parameter
 	}
 	m_midiConfig[parameter][MIDI_CHANNEL] = midiChannel;
 	m_midiConfig[parameter][MIDI_CONTROL] = midiCC;
 }
 }
--- a/src/effects/BAAudioEffectDelayExternal.cpp
+++ b/src/effects/BAAudioEffectDelayExternal.cpp
--- a/src/peripherals/BAAudioControlWM8731.cpp
+++ b/src/peripherals/BAAudioControlWM8731.cpp
--- a/src/peripherals/BAGpio.cpp
+++ b/src/peripherals/BAGpio.cpp
--- a/src/peripherals/BASpiMemory.cpp
+++ b/src/peripherals/BASpiMemory.cpp
@ -0,0 +1,471 @@
 /*
 * BASpiMemory.cpp
 *
 *  Created on: May 22, 2017
 *      Author: slascos
 *
 *  This program is free software: you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation, either version 3 of the License, or
 *  (at your option) any later version.*
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include "Arduino.h"
 #include "BASpiMemory.h"
 namespace BAGuitar {
 // MEM0 Settings
 constexpr int SPI_CS_MEM0 = 15;
 constexpr int SPI_MOSI_MEM0 = 7;
 constexpr int SPI_MISO_MEM0 = 8;
 constexpr int SPI_SCK_MEM0 = 14;
 // MEM1 Settings
 constexpr int SPI_CS_MEM1 = 31;
 constexpr int SPI_MOSI_MEM1 = 21;
 constexpr int SPI_MISO_MEM1 = 5;
 constexpr int SPI_SCK_MEM1 = 20;
 // SPI Constants
 constexpr int SPI_WRITE_MODE_REG = 0x1;
 constexpr int SPI_WRITE_CMD = 0x2;
 constexpr int SPI_READ_CMD = 0x3;
 constexpr int SPI_ADDR_2_MASK = 0xFF0000;
 constexpr int SPI_ADDR_2_SHIFT = 16;
 constexpr int SPI_ADDR_1_MASK = 0x00FF00;
 constexpr int SPI_ADDR_1_SHIFT = 8;
 constexpr int SPI_ADDR_0_MASK = 0x0000FF;
 constexpr int CMD_ADDRESS_SIZE = 4;
 constexpr int MAX_DMA_XFER_SIZE = 0x4000;
 BASpiMemory::BASpiMemory(SpiDeviceId memDeviceId)
 {
 	m_memDeviceId = memDeviceId;
 	m_settings = {20000000, MSBFIRST, SPI_MODE0};
 }
 BASpiMemory::BASpiMemory(SpiDeviceId memDeviceId, uint32_t speedHz)
 {
 	m_memDeviceId = memDeviceId;
 	m_settings = {speedHz, MSBFIRST, SPI_MODE0};
 }
 // Intitialize the correct Arduino SPI interface
 void BASpiMemory::begin()
 {
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		m_csPin = SPI_CS_MEM0;
 		m_spi = &SPI;
 		m_spi->setMOSI(SPI_MOSI_MEM0);
 		m_spi->setMISO(SPI_MISO_MEM0);
 		m_spi->setSCK(SPI_SCK_MEM0);
 		m_spi->begin();
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		m_csPin = SPI_CS_MEM1;
 		m_spi = &SPI1;
 		m_spi->setMOSI(SPI_MOSI_MEM1);
 		m_spi->setMISO(SPI_MISO_MEM1);
 		m_spi->setSCK(SPI_SCK_MEM1);
 		m_spi->begin();
 		break;
 #endif
 	default :
 		// unreachable since memDeviceId is an enumerated class
 		return;
 	}
 	pinMode(m_csPin, OUTPUT);
 	digitalWrite(m_csPin, HIGH);
 	m_started = true;
 }
 BASpiMemory::~BASpiMemory() {
 }
 // Single address write
 void BASpiMemory::write(size_t address, uint8_t data)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_WRITE_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	m_spi->transfer(data);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 // Single address write
 void BASpiMemory::write(size_t address, uint8_t *src, size_t numBytes)
 {
 	uint8_t *dataPtr = src;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_WRITE_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	for (size_t i=0; i < numBytes; i++) {
 		m_spi->transfer(*dataPtr++);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 void BASpiMemory::zero(size_t address, size_t numBytes)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_WRITE_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	for (size_t i=0; i < numBytes; i++) {
 		m_spi->transfer(0);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 void BASpiMemory::write16(size_t address, uint16_t data)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_WRITE_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	m_spi->transfer16(data);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 void BASpiMemory::write16(size_t address, uint16_t *src, size_t numWords)
 {
 	uint16_t *dataPtr = src;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_WRITE_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	for (size_t i=0; i<numWords; i++) {
 		m_spi->transfer16(*dataPtr++);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 void BASpiMemory::zero16(size_t address, size_t numWords)
 {
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_WRITE_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	for (size_t i=0; i<numWords; i++) {
 		m_spi->transfer16(0);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 	Serial.println("DONE!");
 }
 // single address read
 uint8_t BASpiMemory::read(size_t address)
 {
 	int data;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_READ_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	data = m_spi->transfer(0);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 	return data;
 }
 void BASpiMemory::read(size_t address, uint8_t *dest, size_t numBytes)
 {
 	uint8_t *dataPtr = dest;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer(SPI_READ_CMD);
 	m_spi->transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	m_spi->transfer((address & SPI_ADDR_0_MASK));
 	for (size_t i=0; i<numBytes; i++) {
 		*dataPtr++ = m_spi->transfer(0);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 uint16_t BASpiMemory::read16(size_t address)
 {
 	uint16_t data;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_READ_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	data = m_spi->transfer16(0);
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 	return data;
 }
 void BASpiMemory::read16(size_t address, uint16_t *dest, size_t numWords)
 {
 	uint16_t *dataPtr = dest;
 	m_spi->beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	m_spi->transfer16((SPI_READ_CMD << 8) | (address >> 16) );
 	m_spi->transfer16(address & 0xFFFF);
 	for (size_t i=0; i<numWords; i++) {
 		*dataPtr++ = m_spi->transfer16(0);
 	}
 	m_spi->endTransaction();
 	digitalWrite(m_csPin, HIGH);
 }
 /////////////////////////////////////////////////////////////////////////////
 // BASpiMemoryDMA
 /////////////////////////////////////////////////////////////////////////////
 BASpiMemoryDMA::BASpiMemoryDMA(SpiDeviceId memDeviceId)
 : BASpiMemory(memDeviceId)
 {
 	int cs;
 	switch (memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		cs = SPI_CS_MEM0;
 		m_cs = new ActiveLowChipSelect(cs, m_settings);
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		cs = SPI_CS_MEM1;
 		m_cs = new ActiveLowChipSelect1(cs, m_settings);
 		break;
 #endif
 	default :
 		cs = SPI_CS_MEM0;
 	}
 	// add 4 bytes to buffer for SPI CMD and 3 bytes of address
 	m_txCommandBuffer = new uint8_t[CMD_ADDRESS_SIZE];
 	m_rxCommandBuffer = new uint8_t[CMD_ADDRESS_SIZE];
 	m_txTransfer = new DmaSpi::Transfer[2];
 	m_rxTransfer = new DmaSpi::Transfer[2];
 }
 BASpiMemoryDMA::BASpiMemoryDMA(SpiDeviceId memDeviceId, uint32_t speedHz)
 : BASpiMemory(memDeviceId, speedHz)
 {
 	int cs;
 	switch (memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		cs = SPI_CS_MEM0;
 		m_cs = new ActiveLowChipSelect(cs, m_settings);
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		cs = SPI_CS_MEM1;
 		m_cs = new ActiveLowChipSelect1(cs, m_settings);
 		break;
 #endif
 	default :
 		cs = SPI_CS_MEM0;
 	}
 	m_txCommandBuffer = new uint8_t[CMD_ADDRESS_SIZE];
 	m_rxCommandBuffer = new uint8_t[CMD_ADDRESS_SIZE];
 	m_txTransfer = new DmaSpi::Transfer[2];
 	m_rxTransfer = new DmaSpi::Transfer[2];
 }
 BASpiMemoryDMA::~BASpiMemoryDMA()
 {
 	delete m_cs;
 	if (m_txTransfer) delete [] m_txTransfer;
 	if (m_rxTransfer) delete [] m_rxTransfer;
 	if (m_txCommandBuffer) delete [] m_txCommandBuffer;
 	if (m_rxCommandBuffer) delete [] m_txCommandBuffer;
 }
 void BASpiMemoryDMA::m_setSpiCmdAddr(int command, size_t address, uint8_t *dest)
 {
 	dest[0] = command;
 	dest[1] = ((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 	dest[2] = ((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 	dest[3] = ((address & SPI_ADDR_0_MASK));
 }
 void BASpiMemoryDMA::begin(void)
 {
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		m_csPin = SPI_CS_MEM0;
 		m_spi = &SPI;
 		m_spi->setMOSI(SPI_MOSI_MEM0);
 		m_spi->setMISO(SPI_MISO_MEM0);
 		m_spi->setSCK(SPI_SCK_MEM0);
 		m_spi->begin();
 		//m_spiDma = &DMASPI0;
 		m_spiDma = new DmaSpiGeneric();
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		m_csPin = SPI_CS_MEM1;
 		m_spi = &SPI1;
 		m_spi->setMOSI(SPI_MOSI_MEM1);
 		m_spi->setMISO(SPI_MISO_MEM1);
 		m_spi->setSCK(SPI_SCK_MEM1);
 		m_spi->begin();
 		m_spiDma = new DmaSpiGeneric(1);
 		//m_spiDma = &DMASPI1;
 		break;
 #endif
 	default :
 		// unreachable since memDeviceId is an enumerated class
 		return;
 	}
    m_spiDma->begin();
    m_spiDma->start();
    m_started = true;
 }
 // SPI must build up a payload that starts the teh CMD/Address first. It will cycle
 // through the payloads in a circular buffer and use the transfer objects to check if they
 // are done before continuing.
 void BASpiMemoryDMA::write(size_t address, uint8_t *src, size_t numBytes)
 {
 	size_t bytesRemaining = numBytes;
 	uint8_t *srcPtr = src;
 	size_t nextAddress = address;
 	while (bytesRemaining > 0) {
 		m_txXferCount = min(bytesRemaining, MAX_DMA_XFER_SIZE);
 		while ( m_txTransfer[1].busy()) {} // 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]);
 		while ( m_txTransfer[0].busy()) {} // wait until not busy
 		m_txTransfer[0] = DmaSpi::Transfer(srcPtr, m_txXferCount, nullptr, 0, m_cs, TransferType::NO_START_CS);
 		m_spiDma->registerTransfer(m_txTransfer[0]);
 		bytesRemaining -= m_txXferCount;
 		srcPtr += m_txXferCount;
 		nextAddress += m_txXferCount;
 	}
 }
 void BASpiMemoryDMA::zero(size_t address, size_t numBytes)
 {
 	size_t bytesRemaining = numBytes;
 	size_t nextAddress = address;
 	while (bytesRemaining > 0) {
 		m_txXferCount = min(bytesRemaining, MAX_DMA_XFER_SIZE);
 		while ( m_txTransfer[1].busy()) {} // 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]);
 		while ( m_txTransfer[0].busy()) {} // wait until not busy
 		m_txTransfer[0] = DmaSpi::Transfer(nullptr, m_txXferCount, nullptr, 0, m_cs, TransferType::NO_START_CS);
 		m_spiDma->registerTransfer(m_txTransfer[0]);
 		bytesRemaining -= m_txXferCount;
 		nextAddress += m_txXferCount;
 	}
 }
 void BASpiMemoryDMA::write16(size_t address, uint16_t *src, size_t numWords)
 {
 	write(address, reinterpret_cast<uint8_t*>(src), sizeof(uint16_t)*numWords);
 }
 void BASpiMemoryDMA::zero16(size_t address, size_t numWords)
 {
 	zero(address, sizeof(uint16_t)*numWords);
 }
 void BASpiMemoryDMA::read(size_t address, uint8_t *dest, size_t numBytes)
 {
 	size_t bytesRemaining = numBytes;
 	uint8_t *destPtr = dest;
 	size_t nextAddress = address;
 	while (bytesRemaining > 0) {
 		m_setSpiCmdAddr(SPI_READ_CMD, nextAddress, m_rxCommandBuffer);
 		while ( m_rxTransfer[1].busy()) {}
 		m_rxTransfer[1] = DmaSpi::Transfer(m_rxCommandBuffer, CMD_ADDRESS_SIZE, nullptr, 0, m_cs, TransferType::NO_END_CS);
 		m_spiDma->registerTransfer(m_rxTransfer[1]);
 		m_rxXferCount = min(bytesRemaining, MAX_DMA_XFER_SIZE);
 		while ( m_rxTransfer[0].busy()) {}
 		m_rxTransfer[0] = DmaSpi::Transfer(nullptr, m_rxXferCount, destPtr, 0, m_cs, TransferType::NO_START_CS);
 		m_spiDma->registerTransfer(m_rxTransfer[0]);
 		bytesRemaining -= m_rxXferCount;
 		destPtr += m_rxXferCount;
 		nextAddress += m_rxXferCount;
 	}
 }
 void BASpiMemoryDMA::read16(size_t address, uint16_t *dest, size_t numWords)
 {
 	read(address, reinterpret_cast<uint8_t*>(dest), sizeof(uint16_t)*numWords);
 }
 bool BASpiMemoryDMA::isWriteBusy(void) const
 {
 	return (m_txTransfer[0].busy() or m_txTransfer[1].busy());
 }
 bool BASpiMemoryDMA::isReadBusy(void) const
 {
 	return (m_rxTransfer[0].busy() or m_rxTransfer[1].busy());
 }
 } /* namespace BAGuitar */