Fixed a bug in the SPI memory library for accessing MEM1. Also added some more demos, including support for BAAudioEffectExternalDelay

7 years ago · 80bb07abdf
parent ece11f5bea
commit 80bb07abdf
11 changed files with 1009 additions and 9 deletions
--- a/examples/TGA_Pro_1MEM/TGA_Pro_1MEM.ino
+++ b/examples/TGA_Pro_1MEM/TGA_Pro_1MEM.ino
@ -0,0 +1,175 @@
 /*************************************************************************
 * 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 provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
 * It will also perform a sweeo of the SPI MEM0 external RAM.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BAGuitar.h"
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BAGuitar;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 // Audio Thru Connection
 AudioConnection      patch0(i2sIn,0, i2sOut, 0);
 AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codecControl;
 BAGpio                    gpio;  // access to User LED
 BASpiMemory               spiMem0(SpiDeviceId::SPI_DEVICE0);
 BASpiMemory               spiMem1(SpiDeviceId::SPI_DEVICE1);
 unsigned long t=0;
 // SPI stuff
 int spiAddress0 = 0;
 int spiData0 = 0xff;
 int spiErrorCount0 = 0;
 int spiAddress1 = 0;
 int spiData1 = 0xff;
 int spiErrorCount1 = 0;
 void setup() {
  MIDI.begin(MIDI_CHANNEL_OMNI);
  Serial.begin(57600);
  delay(5);
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(24);
  Serial.println("Enabling codec...\n");
  codecControl.enable();
  delay(100);
 }
 void loop() {  
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 0
  //////////////////////////////////////////////////////////////////
  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress0, HEX);
    }
    //mem0Write(spiAddress0, spiData0);
    spiMem0.write(spiAddress0, spiData0);
    spiData0 = (spiData0-1) & 0xff;
  }
  Serial.println("SPI0 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 0
  ///////////////////////////////////////////////////////////////////
  spiErrorCount0 = 0;
  spiAddress0 = 0;
  spiData0 = 0xff;
  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Reading ");
      //Serial.print(spiAddress0, HEX);
    }
    //int data = mem0Read(spiAddress0);
    int data = spiMem0.read(spiAddress0);
    if (data != spiData0) {
      spiErrorCount0++;
      Serial.println("");
      Serial.print("ERROR MEM0: (expected) (actual):");
      Serial.print(spiData0, HEX); Serial.print(":");
      Serial.println(data, HEX);
      delay(100);
    }
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print(", data = ");
      //Serial.println(data, HEX);
    }
    spiData0 = (spiData0-1) & 0xff;
    // Break out of test once the error count reaches 10
    if (spiErrorCount0 > 10) { break; }
  }
  if (spiErrorCount0 == 0) { Serial.println("SPI0 TEST PASSED!!!"); }
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
  // Connect a loopback cable between the MIDI IN and MIDI OUT on the
  // GTA Pro.  This test code will periodically send MIDI events which
  // will loop back and get printed in the Serial Monitor.
  ///////////////////////////////////////////////////////////////////////
  DataByte note, velocity, channel, d1, d2;
  // Send MIDI OUT
  int cc, val=0xA, channelSend = 1;
  for (cc=32; cc<40; cc++) {
    MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
    delay(100);
    MIDI.sendNoteOn(10, 100, channelSend);
    delay(100);
  }
  if (MIDI.read()) {                    // Is there a MIDI message incoming ?
    MidiType type = MIDI.getType();
    Serial.println(String("MIDI IS WORKING!!!"));
    switch (type) {
      case NoteOn:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        if (velocity > 0) {
          Serial.println(String("Note On:  ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        } else {
          Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
        }
        break;
      case NoteOff:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        break;
      default:
        d1 = MIDI.getData1();
        d2 = MIDI.getData2();
        Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
    }
    t = millis();
  }
  if (millis() - t > 10000) {
    t += 10000;
    Serial.println("(no MIDI activity, check cables)");
  }
  // Toggle the USR LED state
  gpio.toggleLed();
 }
--- a/examples/TGA_Pro_2MEM/TGA_Pro_2MEM.ino
+++ b/examples/TGA_Pro_2MEM/TGA_Pro_2MEM.ino
@ -0,0 +1,232 @@
 /*************************************************************************
 * 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 provide an audio passthrough, as well as exercise the
 * MIDI interface.
 * 
 * It will also peform a sweep of SPI MEM0 and MEM1.
 * 
 * NOTE: SPI MEM0 can be used by a Teensy 3.1/3.2/3.5/3.6.  SPI MEM1
 * can only be used by a Teensy 3.5/3.6 since it is mapped to the extended
 * pins.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BAGuitar.h"
 MIDI_CREATE_DEFAULT_INSTANCE();
 using namespace midi;
 using namespace BAGuitar;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 // Audio Thru Connection
 AudioConnection      patch0(i2sIn,0, i2sOut, 0);
 AudioConnection      patch1(i2sIn,1, i2sOut, 1);
 BAAudioControlWM8731      codecControl;
 BAGpio                    gpio;  // access to User LED
 BASpiMemory               spiMem0(SpiDeviceId::SPI_DEVICE0);
 BASpiMemory               spiMem1(SpiDeviceId::SPI_DEVICE1);
 unsigned long t=0;
 // SPI stuff
 int spiAddress0 = 0;
 int spiData0 = 0xff;
 int spiErrorCount0 = 0;
 int spiAddress1 = 0;
 int spiData1 = 0xff;
 int spiErrorCount1 = 0;
 void setup() {
  MIDI.begin(MIDI_CHANNEL_OMNI);
  Serial.begin(57600);
  delay(5);
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(24);
  Serial.println("Enabling codec...\n");
  codecControl.enable();
  delay(100);
 }
 void loop() {  
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 0
  //////////////////////////////////////////////////////////////////
  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress0, HEX);
    }
    //mem0Write(spiAddress0, spiData0);
    spiMem0.write(spiAddress0, spiData0);
    spiData0 = (spiData0-1) & 0xff;
  }
  Serial.println("SPI0 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 0
  ///////////////////////////////////////////////////////////////////
  spiErrorCount0 = 0;
  spiAddress0 = 0;
  spiData0 = 0xff;
  for (spiAddress0=0; spiAddress0 <= SPI_MAX_ADDR; spiAddress0++) {
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print("Reading ");
      //Serial.print(spiAddress0, HEX);
    }
    //int data = mem0Read(spiAddress0);
    int data = spiMem0.read(spiAddress0);
    if (data != spiData0) {
      spiErrorCount0++;
      Serial.println("");
      Serial.print("ERROR MEM0: (expected) (actual):");
      Serial.print(spiData0, HEX); Serial.print(":");
      Serial.println(data, HEX);
      delay(100);
    }
    if ((spiAddress0 % 32768) == 0) {
      //Serial.print(", data = ");
      //Serial.println(data, HEX);
    }
    spiData0 = (spiData0-1) & 0xff;
    // Break out of test once the error count reaches 10
    if (spiErrorCount0 > 10) { break; }
  }
  if (spiErrorCount0 == 0) { Serial.println("SPI0 TEST PASSED!!!"); }
  //////////////////////////////////////////////////////////////////
  // Write test data to the SPI Memory 1
  //////////////////////////////////////////////////////////////////
  for (spiAddress1=0; spiAddress1 <= SPI_MAX_ADDR; spiAddress1++) {
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print("Writing to ");
      //Serial.println(spiAddress1, HEX);
    }
    //mem0Write(spiAddress1, spiData1);
    spiMem1.write(spiAddress1, spiData1);
    spiData1 = (spiData1-1) & 0xff;
  }
  Serial.println("SPI1 writing DONE!");
  ///////////////////////////////////////////////////////////////////
  // Read back from the SPI Memory 1
  ///////////////////////////////////////////////////////////////////
  spiErrorCount1 = 0;
  spiAddress1 = 0;
  spiData1 = 0xff;
  for (spiAddress1=0; spiAddress1 <= SPI_MAX_ADDR; spiAddress1++) {
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print("Reading ");
      //Serial.print(spiAddress1, HEX);
    }
    int data = spiMem1.read(spiAddress1);
    if (data != spiData1) {
      spiErrorCount1++;
      Serial.println("");
      Serial.print("ERROR MEM1: (expected) (actual):");
      Serial.print(spiData1, HEX); Serial.print(":");
      Serial.println(data, HEX);
      delay(100);
    }
    if ((spiAddress1 % 32768) == 0) {
      //Serial.print(", data = ");
      //Serial.println(data, HEX);
    }
    spiData1 = (spiData1-1) & 0xff;
    // Break out of test once the error count reaches 10
    if (spiErrorCount1 > 10) { break; }
  }
  if (spiErrorCount1 == 0) { Serial.println("SPI1 TEST PASSED!!!"); }
  ///////////////////////////////////////////////////////////////////////
  // MIDI TESTING
  // Connect a loopback cable between the MIDI IN and MIDI OUT on the
  // GTA Pro.  This test code will periodically send MIDI events which
  // will loop back and get printed in the Serial Monitor.
  ///////////////////////////////////////////////////////////////////////
  DataByte note, velocity, channel, d1, d2;
  // Send MIDI OUT
  int cc, val=0xA, channelSend = 1;
  for (cc=32; cc<40; cc++) {
    MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
    delay(100);
    MIDI.sendNoteOn(10, 100, channelSend);
    delay(100);
  }
  if (MIDI.read()) {                    // Is there a MIDI message incoming ?
    MidiType type = MIDI.getType();
    Serial.println(String("MIDI IS WORKING!!!"));
    switch (type) {
      case NoteOn:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        if (velocity > 0) {
          Serial.println(String("Note On:  ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        } else {
          Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
        }
        break;
      case NoteOff:
        note = MIDI.getData1();
        velocity = MIDI.getData2();
        channel = MIDI.getChannel();
        Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
        break;
      default:
        d1 = MIDI.getData1();
        d2 = MIDI.getData2();
        Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
    }
    t = millis();
  }
  if (millis() - t > 10000) {
    t += 10000;
    Serial.println("(no MIDI activity, check cables)");
  }
  // Toggle the USR LED state
  gpio.toggleLed();
 }
--- a/examples/TGA_Pro_ExternalDelay_demo/TGA_Pro_ExternalDelay_demo.ino
+++ b/examples/TGA_Pro_ExternalDelay_demo/TGA_Pro_ExternalDelay_demo.ino
@ -0,0 +1,68 @@
 /*************************************************************************
 * 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 demonstrates how to override the default AudioEffectDelayExternal
 * in the Teensy Library with the one in the BAGuitar library.  This is necessary
 * because the SPI pins in AudioEffectDelayExternal are hard-coded and not the
 * same at the TGA Pro.
 * 
 * Simply replace AudioEffectDelayExternal with BAAudioEffectDelayExternal
 * and it should work the same as the default Audio library.
 * 
 * This demo mixes the original guitar signal with one delayed by 1.45 ms
 * the the external SRAM MEM0 on the TGA Pro
 * 
 */
 #include <Wire.h>
 //#include <Audio.h>
 #include <MIDI.h>
 #include <SPI.h>
 #include "BAGuitar.h"
 using namespace BAGuitar;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 BAAudioControlWM8731      codecControl;
 BAAudioEffectDelayExternal  longDelay;
 AudioMixer4               delayMixer;
 // Audio Connections
 AudioConnection  fromInput(i2sIn,0, longDelay, 0);
 AudioConnection  fromDelayL(longDelay, 0, delayMixer, 0);
 AudioConnection  dry(i2sIn, 1, delayMixer, 1);
 AudioConnection  outputLeft(delayMixer, 0, i2sOut, 0);
 AudioConnection  outputRight(delayMixer, 0, i2sOut, 1);
 void setup() {
  Serial.begin(57600);
  delay(1000);
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  AudioMemory(128);
  Serial.println("Enabling codec...\n");
  codecControl.enable();
  delay(1000);
  longDelay.delay(0, 1450.0f);
  delayMixer.gain(0, 1.0f);
  delayMixer.gain(1, 1.0f);
 }
 void loop() {
 }
--- a/examples/TGA_Pro_delay_reverb/TGA_Pro_delay_reverb.ino
+++ b/examples/TGA_Pro_delay_reverb/TGA_Pro_delay_reverb.ino
@ -0,0 +1,75 @@
 /*************************************************************************
 * 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 provides an example guitar tone consisting of some slap-back delay,
 * followed by a reverb and a low-pass cabinet filter.
 * 
 */
 #include <Wire.h>
 #include <Audio.h>
 #include <MIDI.h>
 #include "BAGuitar.h"
 using namespace BAGuitar;
 BAAudioControlWM8731      codecControl;
 AudioInputI2S            i2sIn;
 AudioOutputI2S           i2sOut;
 AudioMixer4              gainModule; // This will be used simply to reduce the gain before the reverb
 AudioEffectDelay         delayModule; // we'll add a little slapback echo
 AudioEffectReverb        reverb; // Add a bit of 'verb to our tone
 AudioMixer4              mixer; // Used to mix the original dry with the wet (effects) path.
 AudioFilterBiquad        cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
 // Audio Connections
 AudioConnection      patchIn(i2sIn,0, delayModule, 0); // route the input to the delay
 AudioConnection      patch2(delayModule,0, gainModule, 0); // send the delay to the gain module
 AudioConnection      patch2b(gainModule, 0, reverb, 0); // then to the reverb
 AudioConnection      patch1(i2sIn,1, mixer,0); // mixer input 0 is our original dry signal
 AudioConnection      patch3(reverb, 0, mixer, 1); // mixer input 1 is our wet
 AudioConnection      patch4(mixer, 0, cabFilter, 0); // mixer outpt to the cabinet filter
 AudioConnection      patch5(cabFilter, 0, i2sOut, 0); // connect the cab filter to the output.
 void setup() {
  delay(5); // wait a few ms to make sure the GTA Pro is fully powered up
  AudioMemory(48);
  // If the codec was already powered up (due to reboot) power itd own first
  codecControl.disable();
  delay(100);
  codecControl.enable();
  delay(100);
  // Configure our effects
  delayModule.delay(0, 50.0f); // 50 ms slapback delay
  gainModule.gain(0, 0.25); // the reverb unit clips easily if the input is too high
  mixer.gain(0, 1.0f); // unity gain on the dry
  mixer.gain(1, 1.0f); // unity gain on the wet
  // 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 loop() {  
  // The audio flows automatically through the Teensy Audio Library
 }
--- a/keywords.txt
+++ b/keywords.txt
@ -8,6 +8,8 @@
 BAAudioControlWM8731	KEYWORD1
 BASpiMemory             KEYWORD1
 BAGpio                  KEYWORD1
 BAAudioEffectDelayExternal	KEYWORD1
 #######################################
 # Methods and Functions (KEYWORD2)
--- a/src/BAAudioControlWM8731.cpp
+++ b/src/BAAudioControlWM8731.cpp
@ -74,6 +74,10 @@ constexpr int WM8731_DAC_MUTE_SHIFT = 3;
 constexpr int WM8731_HPF_DISABLE_ADDR = 5;
 constexpr int WM8731_HPF_DISABLE_MASK = 0x1;
 constexpr int WM8731_HPF_DISABLE_SHIFT = 0;
 // Register 7
 constexpr int WM8731_LRSWAP_ADDR = 5;
 constexpr int WM8731_LRSWAP_MASK = 0x20;
 constexpr int WM8731_LRSWAPE_SHIFT = 5;
 // Register 9
 constexpr int WM8731_ACTIVATE_ADDR = 9;
@ -228,6 +232,17 @@ void BAAudioControlWM8731::setRightInMute(bool val)
 	write(WM8731_RIGHT_INPUT_MUTE_ADDR, regArray[WM8731_RIGHT_INPUT_MUTE_ADDR]);
 }
 // Left/right swap control
 void BAAudioControlWM8731::setLeftRightSwap(bool val)
 {
 	if (val) {
 		regArray[WM8731_LRSWAP_ADDR] |= WM8731_LRSWAP_MASK;
 	} else {
 		regArray[WM8731_LRSWAP_ADDR] &= ~WM8731_LRSWAP_MASK;
 	}
 	write(WM8731_LRSWAP_ADDR, regArray[WM8731_LRSWAP_ADDR]);
 }
 // Dac output mute control
 void BAAudioControlWM8731::setDacMute(bool val)
 {
--- a/src/BAAudioControlWM8731.h
+++ b/src/BAAudioControlWM8731.h
@ -69,6 +69,9 @@ public:
 	/// affect both channels.
 	/// @param val when true, channels are linked, when false, they are controlled separately
 	void setLinkLeftRightIn(bool val);
 	/// Swaps the left and right channels in the codec.
 	///param val when true, channels are swapped, else normal.
 	void setLeftRightSwap(bool val);
 	/// Mute/unmute the output DAC, affects both Left and Right output channels.
 	/// @param when true, output DAC is muted, when false, unmuted.
--- a/src/BAAudioEffectDelayExternal.cpp
+++ b/src/BAAudioEffectDelayExternal.cpp
@ -0,0 +1,322 @@
 /*
 * BAAudioControlWM8731.h
 *
 *  Created on: November 1, 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 "BAAudioEffectDelayExternal.h"
 namespace BAGuitar {
 /* Audio Library for Teensy 3.X
 * Copyright (c) 2014, Paul Stoffregen, paul@pjrc.com
 *
 * Development of this audio library was funded by PJRC.COM, LLC by sales of
 * Teensy and Audio Adaptor boards.  Please support PJRC's efforts to develop
 * open source software by purchasing Teensy or other PJRC products.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice, development funding notice, and this permission
 * notice shall be included in all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */
 //#include "effect_delay_ext.h"
 //#define INTERNAL_TEST
 // While 20 MHz (Teensy actually uses 16 MHz in most cases) and even 24 MHz
 // have worked well in testing at room temperature with 3.3V power, to fully
 // meet all the worst case timing specs, the SPI clock low time would need
 // to be 40ns (12.5 MHz clock) for the single chip case and 51ns (9.8 MHz
 // clock) for the 6-chip memoryboard with 74LCX126 buffers.
 //
 // Timing analysis and info is here:
 // https://forum.pjrc.com/threads/29276-Limits-of-delay-effect-in-audio-library?p=97506&viewfull=1#post97506
 #define SPISETTING SPISettings(20000000, MSBFIRST, SPI_MODE0)
 // Use these with the audio adaptor board  (should be adjustable by the user...)
 //#define SPIRAM_MOSI_PIN  7
 //#define SPIRAM_MISO_PIN  12
 //#define SPIRAM_SCK_PIN   14
 //
 //#define SPIRAM_CS_PIN    6
 // Use with TGA Pro
 #define SPIRAM_MOSI_PIN  7
 #define SPIRAM_MISO_PIN  8
 #define SPIRAM_SCK_PIN   14
 #define SPIRAM_CS_PIN    15
 #define MEMBOARD_CS0_PIN 2
 #define MEMBOARD_CS1_PIN 3
 #define MEMBOARD_CS2_PIN 4
 void BAAudioEffectDelayExternal::update(void)
 {
 	audio_block_t *block;
 	uint32_t n, channel, read_offset;
 	// grab incoming data and put it into the memory
 	block = receiveReadOnly();
 	if (memory_type >= BA_AUDIO_MEMORY_UNDEFINED) {
 		// ignore input and do nothing if undefined memory type
 		release(block);
 		return;
 	}
 	if (block) {
 		if (head_offset + AUDIO_BLOCK_SAMPLES <= memory_length) {
 			// a single write is enough
 			write(head_offset, AUDIO_BLOCK_SAMPLES, block->data);
 			head_offset += AUDIO_BLOCK_SAMPLES;
 		} else {
 			// write wraps across end-of-memory
 			n = memory_length - head_offset;
 			write(head_offset, n, block->data);
 			head_offset = AUDIO_BLOCK_SAMPLES - n;
 			write(0, head_offset, block->data + n);
 		}
 		release(block);
 	} else {
 		// if no input, store zeros, so later playback will
 		// not be random garbage previously stored in memory
 		if (head_offset + AUDIO_BLOCK_SAMPLES <= memory_length) {
 			zero(head_offset, AUDIO_BLOCK_SAMPLES);
 			head_offset += AUDIO_BLOCK_SAMPLES;
 		} else {
 			n = memory_length - head_offset;
 			zero(head_offset, n);
 			head_offset = AUDIO_BLOCK_SAMPLES - n;
 			zero(0, head_offset);
 		}
 	}
 	// transmit the delayed outputs
 	for (channel = 0; channel < 8; channel++) {
 		if (!(activemask & (1<<channel))) continue;
 		block = allocate();
 		if (!block) continue;
 		// compute the delayed location where we read
 		if (delay_length[channel] <= head_offset) {
 			read_offset = head_offset - delay_length[channel];
 		} else {
 			read_offset = memory_length + head_offset - delay_length[channel];
 		}
 		if (read_offset + AUDIO_BLOCK_SAMPLES <= memory_length) {
 			// a single read will do it
 			read(read_offset, AUDIO_BLOCK_SAMPLES, block->data);
 		} else {
 			// read wraps across end-of-memory
 			n = memory_length - read_offset;
 			read(read_offset, n, block->data);
 			read(0, AUDIO_BLOCK_SAMPLES - n, block->data + n);
 		}
 		transmit(block, channel);
 		release(block);
 	}
 }
 uint32_t BAAudioEffectDelayExternal::allocated[2] = {0, 0};
 void BAAudioEffectDelayExternal::initialize(BAAudioEffectDelayMemoryType_t type, uint32_t samples)
 {
 	uint32_t memsize, avail;
 	activemask = 0;
 	head_offset = 0;
 	memory_type = type;
 	SPI.setMOSI(SPIRAM_MOSI_PIN);
 	SPI.setMISO(SPIRAM_MISO_PIN);
 	SPI.setSCK(SPIRAM_SCK_PIN);
 	SPI.begin();	
 	if (type == BA_AUDIO_MEMORY_23LC1024) {
 #ifdef INTERNAL_TEST
 		memsize = 8000;
 #else
 		memsize = 65536;
 #endif
 		pinMode(SPIRAM_CS_PIN, OUTPUT);
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 	} else if (type == BA_AUDIO_MEMORY_MEMORYBOARD) {
 		memsize = 393216;
 		pinMode(MEMBOARD_CS0_PIN, OUTPUT);
 		pinMode(MEMBOARD_CS1_PIN, OUTPUT);
 		pinMode(MEMBOARD_CS2_PIN, OUTPUT);
 		digitalWriteFast(MEMBOARD_CS0_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS1_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS2_PIN, LOW);		
 	} else if (type == BA_AUDIO_MEMORY_CY15B104) {
 #ifdef INTERNAL_TEST
 		memsize = 8000;
 #else		
 		memsize = 262144;
 #endif	
 		pinMode(SPIRAM_CS_PIN, OUTPUT);
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 	} else {
 		return;
 	}
 	avail = memsize - allocated[type];
 	if (avail < AUDIO_BLOCK_SAMPLES*2+1) {
 		memory_type = BA_AUDIO_MEMORY_UNDEFINED;
 		return;
 	}
 	if (samples > avail) samples = avail;
 	memory_begin = allocated[type];
 	allocated[type] += samples;
 	memory_length = samples;
 	zero(0, memory_length);
 }
 #ifdef INTERNAL_TEST
 static int16_t testmem[8000]; // testing only
 #endif
 void BAAudioEffectDelayExternal::read(uint32_t offset, uint32_t count, int16_t *data)
 {
 	uint32_t addr = memory_begin + offset;
 #ifdef INTERNAL_TEST
 	while (count) { *data++ = testmem[addr++]; count--; } // testing only
 #else
 	if (memory_type == BA_AUDIO_MEMORY_23LC1024 ||
 		memory_type == BA_AUDIO_MEMORY_CY15B104) {
 		addr *= 2;
 		SPI.beginTransaction(SPISETTING);
 		digitalWriteFast(SPIRAM_CS_PIN, LOW);
 		SPI.transfer16((0x03 << 8) | (addr >> 16));
 		SPI.transfer16(addr & 0xFFFF);
 		while (count) {
 			*data++ = (int16_t)(SPI.transfer16(0));
 			count--;
 		}
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 		SPI.endTransaction();
 	} else if (memory_type == BA_AUDIO_MEMORY_MEMORYBOARD) {
 		SPI.beginTransaction(SPISETTING);
 		while (count) {
 			uint32_t chip = (addr >> 16) + 1;
 			digitalWriteFast(MEMBOARD_CS0_PIN, chip & 1);
 			digitalWriteFast(MEMBOARD_CS1_PIN, chip & 2);
 			digitalWriteFast(MEMBOARD_CS2_PIN, chip & 4);
 			uint32_t chipaddr = (addr & 0xFFFF) << 1;
 			SPI.transfer16((0x03 << 8) | (chipaddr >> 16));
 			SPI.transfer16(chipaddr & 0xFFFF);
 			uint32_t num = 0x10000 - (addr & 0xFFFF);
 			if (num > count) num = count;
 			count -= num;
 			addr += num;
 			do {
 				*data++ = (int16_t)(SPI.transfer16(0));
 			} while (--num > 0);
 		}
 		digitalWriteFast(MEMBOARD_CS0_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS1_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS2_PIN, LOW);
 		SPI.endTransaction();
 	}
 #endif
 }
 void BAAudioEffectDelayExternal::write(uint32_t offset, uint32_t count, const int16_t *data)
 {
 	uint32_t addr = memory_begin + offset;
 #ifdef INTERNAL_TEST
 	while (count) { testmem[addr++] = *data++; count--; } // testing only
 #else
 	if (memory_type == BA_AUDIO_MEMORY_23LC1024) {
 		addr *= 2;
 		SPI.beginTransaction(SPISETTING);
 		digitalWriteFast(SPIRAM_CS_PIN, LOW);
 		SPI.transfer16((0x02 << 8) | (addr >> 16));
 		SPI.transfer16(addr & 0xFFFF);
 		while (count) {
 			int16_t w = 0;
 			if (data) w = *data++;
 			SPI.transfer16(w);
 			count--;
 		}
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 		SPI.endTransaction();
 	} else if (memory_type == BA_AUDIO_MEMORY_CY15B104) {
 		addr *= 2;
 		SPI.beginTransaction(SPISETTING);
 		digitalWriteFast(SPIRAM_CS_PIN, LOW);
 		SPI.transfer(0x06); //write-enable before every write
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 		asm volatile ("NOP\n NOP\n NOP\n NOP\n NOP\n NOP\n");
 		digitalWriteFast(SPIRAM_CS_PIN, LOW);
 		SPI.transfer16((0x02 << 8) | (addr >> 16));
 		SPI.transfer16(addr & 0xFFFF);
 		while (count) {
 			int16_t w = 0;
 			if (data) w = *data++;
 			SPI.transfer16(w);
 			count--;
 		}
 		digitalWriteFast(SPIRAM_CS_PIN, HIGH);
 		SPI.endTransaction();	
 	} else if (memory_type == BA_AUDIO_MEMORY_MEMORYBOARD) {
 		SPI.beginTransaction(SPISETTING);
 		while (count) {
 			uint32_t chip = (addr >> 16) + 1;
 			digitalWriteFast(MEMBOARD_CS0_PIN, chip & 1);
 			digitalWriteFast(MEMBOARD_CS1_PIN, chip & 2);
 			digitalWriteFast(MEMBOARD_CS2_PIN, chip & 4);
 			uint32_t chipaddr = (addr & 0xFFFF) << 1;
 			SPI.transfer16((0x02 << 8) | (chipaddr >> 16));
 			SPI.transfer16(chipaddr & 0xFFFF);
 			uint32_t num = 0x10000 - (addr & 0xFFFF);
 			if (num > count) num = count;
 			count -= num;
 			addr += num;
 			do {
 				int16_t w = 0;
 				if (data) w = *data++;
 				SPI.transfer16(w);
 			} while (--num > 0);
 		}
 		digitalWriteFast(MEMBOARD_CS0_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS1_PIN, LOW);
 		digitalWriteFast(MEMBOARD_CS2_PIN, LOW);
 		SPI.endTransaction();
 	}
 #endif
 }
 } /* namespace BAGuitar */
--- a/src/BAAudioEffectDelayExternal.h
+++ b/src/BAAudioEffectDelayExternal.h
@ -0,0 +1,104 @@
 /*
 * BAAudioEffectDelayExternal.h
 *
 *  Created on: Nov 5, 2017
 *      Author: slascos
 */
 #ifndef __BAGUITAR_BAAUDIOEFFECTDELAYEXTERNAL_H
 #define __BAGUITAR_BAAUDIOEFFECTDELAYEXTERNAL_H
 #include <Audio.h>
 namespace BAGuitar {
 /* Audio Library for Teensy 3.X
 * Copyright (c) 2014, Paul Stoffregen, paul@pjrc.com
 *
 * Development of this audio library was funded by PJRC.COM, LLC by sales of
 * Teensy and Audio Adaptor boards.  Please support PJRC's efforts to develop
 * open source software by purchasing Teensy or other PJRC products.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice, development funding notice, and this permission
 * notice shall be included in all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */
 #include "Arduino.h"
 #include "AudioStream.h"
 #include "spi_interrupt.h"
 enum BAAudioEffectDelayMemoryType_t {
 	BA_AUDIO_MEMORY_23LC1024 = 0,	// 128k x 8 S-RAM
 	BA_AUDIO_MEMORY_MEMORYBOARD = 1,
 	BA_AUDIO_MEMORY_CY15B104 = 2,	// 512k x 8 F-RAM
 	BA_AUDIO_MEMORY_UNDEFINED = 3
 };
 class BAAudioEffectDelayExternal : public AudioStream
 {
 public:
 	BAAudioEffectDelayExternal() : AudioStream(1, inputQueueArray) {
 		initialize(BA_AUDIO_MEMORY_23LC1024, 65536);
 	}
 	BAAudioEffectDelayExternal(BAAudioEffectDelayMemoryType_t type, float milliseconds=1e6)
 	  : AudioStream(1, inputQueueArray) {
 		uint32_t n = (milliseconds*(AUDIO_SAMPLE_RATE_EXACT/1000.0f))+0.5f;
 		initialize(type, n);
 	}
 	void delay(uint8_t channel, float milliseconds) {
 		if (channel >= 8 || memory_type >= BA_AUDIO_MEMORY_UNDEFINED) return;
 		if (milliseconds < 0.0) milliseconds = 0.0;
 		uint32_t n = (milliseconds*(AUDIO_SAMPLE_RATE_EXACT/1000.0f))+0.5f;
 		n += AUDIO_BLOCK_SAMPLES;
 		if (n > memory_length - AUDIO_BLOCK_SAMPLES)
 			n = memory_length - AUDIO_BLOCK_SAMPLES;
 		delay_length[channel] = n;
 		uint8_t mask = activemask;
 		if (activemask == 0) AudioStartUsingSPI();
 		activemask = mask | (1<<channel);
 	}
 	void disable(uint8_t channel) {
 		if (channel >= 8) return;
 		uint8_t mask = activemask & ~(1<<channel);
 		activemask = mask;
 		if (mask == 0) AudioStopUsingSPI();
 	}
 	virtual void update(void);
 private:
 	void initialize(BAAudioEffectDelayMemoryType_t type, uint32_t samples);
 	void read(uint32_t address, uint32_t count, int16_t *data);
 	void write(uint32_t address, uint32_t count, const int16_t *data);
 	void zero(uint32_t address, uint32_t count) {
 		write(address, count, NULL);
 	}
 	uint32_t memory_begin;    // the first address in the memory we're using
 	uint32_t memory_length;   // the amount of memory we're using
 	uint32_t head_offset;     // head index (incoming) data into external memory
 	uint32_t delay_length[8]; // # of sample delay for each channel (128 = no delay)
 	uint8_t  activemask;      // which output channels are active
 	uint8_t  memory_type;     // 0=23LC1024, 1=Frank's Memoryboard
 	static uint32_t allocated[2];
 	audio_block_t *inputQueueArray[1];
 };
 } /* namespace BAGuitar */
 #endif /* __BAGUITAR_BAAUDIOEFFECTDELAYEXTERNAL_H */
--- a/src/BAGuitar.h
+++ b/src/BAGuitar.h
@ -24,6 +24,7 @@
 #include "BAAudioControlWM8731.h" // Codec Control
 #include "BASpiMemory.h"
 #include "BAGpio.h"
 #include "BAAudioEffectDelayExternal.h"
 /**************************************************************************//**
 * BAGuitar is a namespace/Library for Guitar processing from Blackaddr Audio.
--- a/src/BASpiMemory.cpp
+++ b/src/BASpiMemory.cpp
@ -71,6 +71,7 @@ void BASpiMemory::m_Init()
 		SPI.setMOSI(SPI_MOSI_MEM0);
 		SPI.setMISO(SPI_MISO_MEM0);
 		SPI.setSCK(SPI_SCK_MEM0);
 		SPI.begin();
 		break;
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
@ -79,6 +80,7 @@ void BASpiMemory::m_Init()
 		SPI1.setMOSI(SPI_MOSI_MEM1);
 		SPI1.setMISO(SPI_MISO_MEM1);
 		SPI1.setSCK(SPI_SCK_MEM1);
 		SPI1.begin();
 		break;
 #endif
@ -87,7 +89,6 @@ void BASpiMemory::m_Init()
 		return;
 	}
 	SPI.begin();
 	pinMode(m_csPin, OUTPUT);
 	digitalWrite(m_csPin, HIGH);
@ -99,12 +100,10 @@ BASpiMemory::~BASpiMemory() {
 // Single address write
 void BASpiMemory::write(int address, int data)
 {
 	SPI.beginTransaction(m_settings);
 	digitalWrite(m_csPin, LOW);
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		SPI.beginTransaction(m_settings);
 		digitalWrite(m_csPin, LOW);
 		SPI.transfer(SPI_WRITE_CMD);
 		SPI.transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 		SPI.transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
@ -115,7 +114,8 @@ void BASpiMemory::write(int address, int data)
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
-		digitalWrite(m_csPin, HIGH);
+		SPI1.beginTransaction(m_settings);
 		digitalWrite(m_csPin, LOW);
 		SPI1.transfer(SPI_WRITE_CMD);
 		SPI1.transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 		SPI1.transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
@ -137,10 +137,11 @@ int BASpiMemory::read(int address)
 {
 	int data = -1;
-	SPI.beginTransaction(m_settings);
+
 	digitalWrite(m_csPin, LOW);
 	switch (m_memDeviceId) {
 	case SpiDeviceId::SPI_DEVICE0 :
 		SPI.beginTransaction(m_settings);
 		digitalWrite(m_csPin, LOW);
 		SPI.transfer(SPI_READ_CMD);
 		SPI.transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 		SPI.transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
@ -151,11 +152,13 @@ int BASpiMemory::read(int address)
 #if defined(__MK64FX512__) || defined(__MK66FX1M0__)
 	case SpiDeviceId::SPI_DEVICE1 :
 		SPI1.beginTransaction(m_settings);
 		digitalWrite(m_csPin, LOW);
 		SPI1.transfer(SPI_READ_CMD);
 		SPI1.transfer((address & SPI_ADDR_2_MASK) >> SPI_ADDR_2_SHIFT);
 		SPI1.transfer((address & SPI_ADDR_1_MASK) >> SPI_ADDR_1_SHIFT);
 		SPI1.transfer((address & SPI_ADDR_0_MASK));
-		data = SPI.transfer(0);
+		data = SPI1.transfer(0);
 		SPI1.endTransaction();
 		break;
 #endif