Major cleanup of the Library and reorganization of the examples

master
Steve Lascos 6 years ago
parent 86e764eba3
commit 492659ddb2
  1. 124
      examples/BA0_TGA_Pro_TRY_FIRST/BA0_TGA_Pro_TRY_FIRST.ino
  2. 51
      examples/BA1_TGA_Pro_demo/SerialMonitorResults.txt
  3. 19
      examples/BAExpansionCalibrate/BAExpansionCalibrate.ino
  4. 69
      examples/Basic/BA1_TGA_Pro_NOMEM_demo/BA1_TGA_Pro_NOMEM_demo.ino
  5. 2
      examples/Basic/BA2_TGA_Pro_1MEM/BA2_TGA_Pro_1MEM.ino
  6. 3
      examples/Basic/BA3_TGA_Pro_2MEM/BA3_TGA_Pro_2MEM.ino
  7. 1
      examples/Basic/BA4_TGA_Pro_delay_reverb/BA4_TGA_Pro_delay_reverb.ino
  8. 27
      examples/Delay/AnalogDelayDemo/AnalogDelayDemo.ino
  9. 26
      examples/Delay/AnalogDelayDemoExpansion/AnalogDelayDemoExpansion.ino
  10. 9
      examples/Delay/ExternalDelayDemo/ExternalDelayDemo.ino
  11. 10
      examples/Delay/SoundOnSoundDemo/SoundOnSoundDemo.ino
  12. 7
      examples/Delay/SoundOnSoundExpansionDemo/SoundOnSoundExpansionDemo.ino
  13. 6
      examples/README.TXT
  14. 79
      examples/Tests/TGA_PRO_MEM2/PhysicalControls.cpp
  15. 71
      examples/Tests/TGA_PRO_MEM2/TGA_PRO_MEM2.ino
  16. 86
      examples/Tests/TGA_PRO_MEM2/UartTest.cpp
  17. 125
      examples/Tests/TGA_PRO_MEM2/spiTest.cpp
  18. 75
      examples/Tests/TGA_PRO_MEM2_EXP/TGA_PRO_MEM2_EXP.ino
  19. 10
      examples/Tests/TGA_PRO_MEM2_EXP/UartTest.cpp
  20. 29
      src/BAEffects.h
  21. 5
      src/BALibrary.h

@ -1,124 +0,0 @@
/*************************************************************************
* This demo uses only the built-in libraries provided with the Arudino
* Teensy libraries.
*
* IT IS STRONGLY RECOMMENDED to use the BALibrary Library located at
* https://github.com/Blackaddr/BALibrary
* The BALibrary library will made it easier to use the features of your
* GTA Pro board, as well and configure it correctly to eliminate
* unneccesary noise.
*
* The built-in support for the WM8731 codec in the Teensy Library is very
* limited. Without proper configuration, the codec will produce a noisy
* output. This is caused by the default configuration the WM8731 powers
* up in. This can easily be corrected by installing the BALibrary library
*
* For instructions on installing additional libraries follow the
* instructions at https://www.arduino.cc/en/Guide/Libraries after downloading
* the BALibrary repo from github as a zip file.
*
*/
#include <Wire.h>
#include <Audio.h>
#include <MIDI.h>
MIDI_CREATE_DEFAULT_INSTANCE();
using namespace midi;
AudioInputI2S i2sIn;
AudioOutputI2S i2sOut;
// Audio connections, just connect the I2S input directly to the I2S output.
AudioConnection patch0(i2sIn,0, i2sOut, 0);
AudioConnection patch1(i2sIn,1, i2sOut, 1);
AudioControlWM8731 codecControl; // needed to enable the codec
unsigned long t=0;
const int usrLED = 16; // the location of the GTA Pro user LED (not the LED on the Teensy itself)
int usrLEDState = 0;
void setup() {
// Configure the user LED pin as output
pinMode(usrLED, OUTPUT);
digitalWrite(usrLED, usrLEDState);
// Enable the MIDI to listen on all channels
MIDI.begin(MIDI_CHANNEL_OMNI);
Serial.begin(57600); // Enable the serial monitor
Wire.begin(); // Enable the I2C bus for controlling the codec
delay(5);
delay(100);
codecControl.disable(); // Turn off the codec first (in case it was in an unknown state)
delay(100);
AudioMemory(24);
Serial.println("Enabling codec...\n");
codecControl.enable(); // Enable the codec
delay(100);
}
void loop() {
///////////////////////////////////////////////////////////////////////
// MIDI TESTING
// Connect a loopback cable between the MIDI IN and MIDI OUT on the
// GTA Pro. This test code will periodically send MIDI events which
// will loop back and get printed in the Serial Monitor.
///////////////////////////////////////////////////////////////////////
DataByte note, velocity, channel, d1, d2;
// Send MIDI OUT
int cc, val=0xA, channelSend = 1;
for (cc=32; cc<40; cc++) {
MIDI.sendControlChange(cc, val, channelSend); val++; channelSend++;
delay(100);
MIDI.sendNoteOn(10, 100, channelSend);
delay(100);
}
if (MIDI.read()) { // Is there a MIDI message incoming ?
MidiType type = MIDI.getType();
Serial.println(String("MIDI IS WORKING!!!"));
switch (type) {
case NoteOn:
note = MIDI.getData1();
velocity = MIDI.getData2();
channel = MIDI.getChannel();
if (velocity > 0) {
Serial.println(String("Note On: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
} else {
Serial.println(String("Note Off: ch=") + channel + ", note=" + note);
}
break;
case NoteOff:
note = MIDI.getData1();
velocity = MIDI.getData2();
channel = MIDI.getChannel();
Serial.println(String("Note Off: ch=") + channel + ", note=" + note + ", velocity=" + velocity);
break;
default:
d1 = MIDI.getData1();
d2 = MIDI.getData2();
Serial.println(String("Message, type=") + type + ", data = " + d1 + " " + d2);
}
t = millis();
}
// If no MIDI IN activity, print a message every 10 seconds
if (millis() - t > 10000) {
t += 10000;
Serial.println("(no MIDI activity, check cables)");
}
// Toggle the USR LED state
usrLEDState = ~usrLEDState;
digitalWrite(usrLED, usrLEDState);
}

@ -1,51 +0,0 @@
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Message, type=176, data = 32 10
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Note On: ch=2, note=10, velocity=100
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Message, type=176, data = 33 11
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Note On: ch=3, note=10, velocity=100
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Message, type=176, data = 34 12
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
SPI writing DONE!
SPI TEST PASSED!!!
MIDI IS WORKING!!!
Note On: ch=4, note=10, velocity=100
SPI writing DONE!
SPI TEST PASSED!!!

@ -1,5 +1,20 @@
#define TGA_PRO_REVB /*************************************************************************
#define TGA_PRO_EXPAND_REV2 * This demo uses the BALibrary library to provide enhanced control of
* the TGA Pro board.
*
* The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary
*
* This program can be used to find out the calibration values for each of your POTs
* on the Blackaddr Audio Expansion Control Board.
*
* USE THE ARDUINO SERIAL MONITOR TO PERFORM THE CALIBRATION
*
* When prompted turn the appropriate POT in the specified direction and
* enter any character on the terminal input line and press enter to send the character.
*/
#define TGA_PRO_REVB // Specify our hardware revision
#define TGA_PRO_EXPAND_REV2 // Specify we are using the EXPANSION CONTROL BOARD REV2
#include "BALibrary.h" #include "BALibrary.h"

@ -18,11 +18,7 @@
MIDI_CREATE_DEFAULT_INSTANCE(); MIDI_CREATE_DEFAULT_INSTANCE();
using namespace midi; using namespace midi;
//#define ENABLE_MEM_TEST // uncomment this line and 'Save As' to a new location to test the SPI memory
using namespace BALibrary; using namespace BALibrary;
using namespace BAEffects;
AudioInputI2S i2sIn; AudioInputI2S i2sIn;
AudioOutputI2S i2sOut; AudioOutputI2S i2sOut;
@ -33,16 +29,9 @@ AudioConnection patch1(i2sIn,1, i2sOut, 1);
BAAudioControlWM8731 codecControl; BAAudioControlWM8731 codecControl;
BAGpio gpio; // access to User LED BAGpio gpio; // access to User LED
BASpiMemory spiMem0(SpiDeviceId::SPI_DEVICE0);
unsigned long t=0; unsigned long t=0;
// SPI stuff
int spiAddress = 0;
int spiData = 0xff;
int spiErrorCount = 0;
void setup() { void setup() {
MIDI.begin(MIDI_CHANNEL_OMNI); MIDI.begin(MIDI_CHANNEL_OMNI);
@ -62,64 +51,6 @@ void setup() {
void loop() { void loop() {
#ifdef ENABLE_MEM_TEST
//////////////////////////////////////////////////////////////////
// Write test data to the SPI Memory
//////////////////////////////////////////////////////////////////
for (spiAddress=0; spiAddress <= SPI_MAX_ADDR; spiAddress++) {
if ((spiAddress % 32768) == 0) {
//Serial.print("Writing to ");
//Serial.println(spiAddress, HEX);
}
//mem0Write(spiAddress, spiData);
spiMem0.write(spiAddress, spiData);
spiData = (spiData-1) & 0xff;
}
Serial.println("SPI writing DONE!");
///////////////////////////////////////////////////////////////////
// Read back from the SPI memory
///////////////////////////////////////////////////////////////////
spiErrorCount = 0;
spiAddress = 0;
spiData = 0xff;
for (spiAddress=0; spiAddress <= SPI_MAX_ADDR; spiAddress++) {
if ((spiAddress % 32768) == 0) {
//Serial.print("Reading ");
//Serial.print(spiAddress, HEX);
}
//int data = mem0Read(spiAddress);
int data = spiMem0.read(spiAddress);
if (data != spiData) {
spiErrorCount++;
Serial.println("");
Serial.print("ERROR MEM0: (expected) (actual):");
Serial.print(spiData, HEX); Serial.print(":");
Serial.println(data, HEX);
delay(100);
}
if ((spiAddress % 32768) == 0) {
//Serial.print(", data = ");
//Serial.println(data, HEX);
}
spiData = (spiData-1) & 0xff;
// Break out of test once the error count reaches 10
if (spiErrorCount > 10) { break; }
}
if (spiErrorCount == 0) { Serial.println("SPI TEST PASSED!!!"); }
#endif
/////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////
// MIDI TESTING // MIDI TESTING
// Connect a loopback cable between the MIDI IN and MIDI OUT on the // Connect a loopback cable between the MIDI IN and MIDI OUT on the

@ -14,7 +14,6 @@
* pins. * pins.
* *
*/ */
//#include <i2c_t3.h>
#include <Wire.h> #include <Wire.h>
#include <Audio.h> #include <Audio.h>
#include <MIDI.h> #include <MIDI.h>
@ -24,7 +23,6 @@ MIDI_CREATE_DEFAULT_INSTANCE();
using namespace midi; using namespace midi;
using namespace BALibrary; using namespace BALibrary;
using namespace BAEffects;
AudioInputI2S i2sIn; AudioInputI2S i2sIn;
AudioOutputI2S i2sOut; AudioOutputI2S i2sOut;

@ -15,7 +15,6 @@
* pins. * pins.
* *
*/ */
//#include <i2c_t3.h>
#include <Wire.h> #include <Wire.h>
#include <Audio.h> #include <Audio.h>
#include <MIDI.h> #include <MIDI.h>
@ -23,8 +22,6 @@
MIDI_CREATE_DEFAULT_INSTANCE(); MIDI_CREATE_DEFAULT_INSTANCE();
using namespace midi; using namespace midi;
using namespace BAEffects;
using namespace BALibrary; using namespace BALibrary;
AudioInputI2S i2sIn; AudioInputI2S i2sIn;

@ -14,7 +14,6 @@
#include <MIDI.h> #include <MIDI.h>
#include "BALibrary.h" #include "BALibrary.h"
using namespace BAEffects;
using namespace BALibrary; using namespace BALibrary;
BAAudioControlWM8731 codecControl; BAAudioControlWM8731 codecControl;

@ -1,5 +1,23 @@
/*************************************************************************
* This demo uses the BALibrary library to provide enhanced control of
* the TGA Pro board.
*
* The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary
*
* This example demonstrates teh BAAudioEffectsAnalogDelay effect. It can
* be controlled using USB MIDI. You can get a free USB MIDI Controller
* appliation at
* http://www.blackaddr.com/downloads/BAMidiTester/
* or the source code at
* https://github.com/Blackaddr/BAMidiTester
*
* Even if you don't control the guitar effect with USB MIDI, you must set
* the Arduino IDE USB-Type under Tools to "Serial + MIDI"
*/
#include <MIDI.h> #include <MIDI.h>
#include "BALibrary.h" #include "BALibrary.h"
#include "BAEffects.h"
using namespace midi; using namespace midi;
using namespace BAEffects; using namespace BAEffects;
@ -14,7 +32,6 @@ BAAudioControlWM8731 codec;
// YOU MUST COMPILE THIS DEMO USING Serial + Midi // YOU MUST COMPILE THIS DEMO USING Serial + Midi
//#define USE_EXT // uncomment this line to use External MEM0 //#define USE_EXT // uncomment this line to use External MEM0
#define MIDI_DEBUG // uncomment to see raw MIDI info in terminal #define MIDI_DEBUG // uncomment to see raw MIDI info in terminal
#ifdef USE_EXT #ifdef USE_EXT
@ -32,22 +49,18 @@ AudioEffectAnalogDelay analogDelay(&delaySlot);
// by passing it the maximum amount of delay we will use in millseconds. Note that // 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 // audio delay lengths are very limited when using internal memory due to limited
// internal RAM size. // internal RAM size.
AudioEffectAnalogDelay analogDelay(200.0f); // max delay of 200 ms. AudioEffectAnalogDelay analogDelay(200.0f); // max delay of 200 ms or internal.
// If you use external SPI memory you can get up to 1485.0f ms of delay!
#endif #endif
AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab. 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 // Simply connect the input to the delay, and the output
// to both i2s channels // to both i2s channels
AudioConnection input(i2sIn,0, analogDelay,0); AudioConnection input(i2sIn,0, analogDelay,0);
AudioConnection delayOut(analogDelay, 0, cabFilter, 0); AudioConnection delayOut(analogDelay, 0, cabFilter, 0);
AudioConnection leftOut(cabFilter,0, i2sOut, 0); AudioConnection leftOut(cabFilter,0, i2sOut, 0);
AudioConnection rightOut(cabFilter,0, i2sOut, 1); AudioConnection rightOut(cabFilter,0, i2sOut, 1);
//AudioConnection leftOutUSB(cabFilter,0, usb, 0);
//AudioConnection rightOutUSB(cabFilter,0, usb, 1);
int loopCount = 0; int loopCount = 0;

@ -5,17 +5,28 @@
* The latest copy of the BA Guitar library can be obtained from * The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary * https://github.com/Blackaddr/BALibrary
* *
* This demo combines the Blackaddr Audio Expansion board to add physical controls * This example demonstrates teh BAAudioEffectsAnalogDelay effect. It can
* to the BAAudioEffectAnalogDelay. * be controlled using the Blackaddr Audio "Expansion Control Board".
* *
* You can control the amount of delay, feedback and mix in realtime, as well as cycle * POT1 (left) controls amount of delay
* through the various analog filters built into the effect. * POT2 (right) controls amount of feedback
* POT3 (center) controls the wet/dry mix
* SW1 will enable/bypass the audio effect. LED1 will be on when effect is enabled.
* SW2 will cycle through the 3 pre-programmed analog filters. LED2 will be on when SW2 is pressed.
* *
* !!! SET POTS TO REASONABLE VALUES BEFORE STARTING TO AVOID SCREECHING FEEDBACK!!!!
* - set POT1 (delay) fully counter-clockwise then increase it slowly.
* - set POT2 (feedback) fully counter-clockwise, then increase it slowly
* - set POT3 (wet/dry mix) to half-way at the detent.
*
* Using the Serial Montitor, send 'u' and 'd' characters to increase or decrease
* the headphone volume between values of 0 and 9.
*/ */
#define TGA_PRO_REVB // Set which hardware revision of the TGA Pro we're using #define TGA_PRO_REVB // Set which hardware revision of the TGA Pro we're using
#define TGA_PRO_EXPAND_REV2 // pull in the pin definitions for the Blackaddr Audio Expansion Board. #define TGA_PRO_EXPAND_REV2 // pull in the pin definitions for the Blackaddr Audio Expansion Board.
#include "BALibrary.h" #include "BALibrary.h"
#include "BAEffects.h"
using namespace BAEffects; using namespace BAEffects;
using namespace BALibrary; using namespace BALibrary;
@ -41,7 +52,8 @@ AudioEffectAnalogDelay analogDelay(&delaySlot);
// by passing it the maximum amount of delay we will use in millseconds. Note that // 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 // audio delay lengths are very limited when using internal memory due to limited
// internal RAM size. // internal RAM size.
AudioEffectAnalogDelay analogDelay(200.0f); // max delay of 200 ms. AudioEffectAnalogDelay analogDelay(200.0f); // set the max delay of 200 ms.
// If you use external SPI memory you can get up to 1485.0f ms of delay!
#endif #endif
AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab. AudioFilterBiquad cabFilter; // We'll want something to cut out the highs and smooth the tone, just like a guitar cab.
@ -77,7 +89,7 @@ BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_E
int loopCount = 0; int loopCount = 0;
unsigned filterIndex = 0; // variable for storing which analog filter we're currently using. unsigned filterIndex = 0; // variable for storing which analog filter we're currently using.
constexpr unsigned MAX_HEADPHONE_VOL = 10; constexpr unsigned MAX_HEADPHONE_VOL = 10;
unsigned headphoneVolume = MAX_HEADPHONE_VOL; // control headphone volume from 0 to 10. unsigned headphoneVolume = 8; // control headphone volume from 0 to 10.
// BAPhysicalControls returns a handle when you register a new control. We'll uses these handles when working with the controls. // BAPhysicalControls returns a handle when you register a new control. We'll uses these handles when working with the controls.
int bypassHandle, filterHandle, delayHandle, feedbackHandle, mixHandle, led1Handle, led2Handle; // Handles for the various controls int bypassHandle, filterHandle, delayHandle, feedbackHandle, mixHandle, led1Handle, led2Handle; // Handles for the various controls
@ -154,7 +166,7 @@ void loop() {
} }
// Use SW2 to cycle through the filters // Use SW2 to cycle through the filters
controls.setOutput(led2Handle, !controls.getSwitchValue(led2Handle)); controls.setOutput(led2Handle, controls.getSwitchValue(led2Handle));
if (controls.isSwitchToggled(filterHandle)) { if (controls.isSwitchToggled(filterHandle)) {
filterIndex = (filterIndex + 1) % 3; // update and potentionall roll the counter 0, 1, 2, 0, 1, 2, ... filterIndex = (filterIndex + 1) % 3; // update and potentionall roll the counter 0, 1, 2, 0, 1, 2, ...
// cast the index between 0 to 2 to the enum class AudioEffectAnalogDelay::Filter // cast the index between 0 to 2 to the enum class AudioEffectAnalogDelay::Filter

@ -11,8 +11,9 @@
* Eight delay taps are configured from a single SRAM device. * Eight delay taps are configured from a single SRAM device.
* *
*/ */
#include <Audio.h>
#include "BALibrary.h" #include "BALibrary.h"
#include "BAEffects.h"
using namespace BAEffects; using namespace BAEffects;
using namespace BALibrary; using namespace BALibrary;
@ -50,13 +51,13 @@ void setup() {
Serial.begin(57600); Serial.begin(57600);
AudioMemory(128); AudioMemory(128);
delay(3000); delay(100);
Serial.println(String("Starting...\n")); Serial.println(String("Starting...\n"));
delay(1000); delay(100);
Serial.println("Enabling codec...\n"); Serial.println("Enabling codec...\n");
codecControl.enable(); codecControl.enable();
delay(1000); delay(100);
// Set up 8 delay taps, each with evenly spaced, longer delays // Set up 8 delay taps, each with evenly spaced, longer delays
longDelay.delay(0, 150.0f); longDelay.delay(0, 150.0f);

@ -5,10 +5,13 @@
* The latest copy of the BA Guitar library can be obtained from * The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary * https://github.com/Blackaddr/BALibrary
* *
* This demo will provide an audio passthrough, as well as exercise the * THIS DEMO REQUIRES THE EXTERNAL SRAM MEM0
* MIDI interface.
* *
* It can optionally exercise the SPI MEM0 if installed on the TGA Pro board. * This demo combines MIDI control with the BAAudioEffectSoundOnSound. You can use
* the BAMidiTester to control the effect but it's best to use external MIDI footswitch
* or the Blackaddr Audio Expansion Control Board.
*
* Use must set the Arduino IDE USB-Type to "Serial + MIDI" in the Tools menu.
* *
*/ */
#include <Wire.h> #include <Wire.h>
@ -16,6 +19,7 @@
#include <MIDI.h> #include <MIDI.h>
#include <SPI.h> #include <SPI.h>
#include "BALibrary.h" #include "BALibrary.h"
#include "BAEffects.h"
#include <midi_UsbTransport.h> #include <midi_UsbTransport.h>
static const unsigned sUsbTransportBufferSize = 16; static const unsigned sUsbTransportBufferSize = 16;

@ -13,11 +13,18 @@
* *
* The pots control the feedback, as well as the gate opening and close times. * The pots control the feedback, as well as the gate opening and close times.
* *
* POT1 - Gate open time. Middle position (detent) is about 2100 ms.
* POT2 - gate close time. Middle position (detent) is about 2100 ms.
* POT3 - Effect volume. Controls the volume of the SOS effect separate from the normal volume
* SW1 - Strum and hold a chord then push this button. Continue holding the button until the LED1 light goes out.
* SW2 - Push this button to clear out the sound circulating in the delay.
*
*/ */
#define TGA_PRO_REVB // Set which hardware revision of the TGA Pro we're using #define TGA_PRO_REVB // Set which hardware revision of the TGA Pro we're using
#define TGA_PRO_EXPAND_REV2 // pull in the pin definitions for the Blackaddr Audio Expansion Board. #define TGA_PRO_EXPAND_REV2 // pull in the pin definitions for the Blackaddr Audio Expansion Board.
#include "BALibrary.h" #include "BALibrary.h"
#include "BAEffects.h"
using namespace BAEffects; using namespace BAEffects;
using namespace BALibrary; using namespace BALibrary;

@ -0,0 +1,6 @@
If you've never used the the library examples before, start with the "Basic" ones.
Pick the correct one based on how many SPI SRAMs you have. (0, 1 or 2 SRAMs).
Use BAExpansionCalibrate to test our the Blackaddr Audio Expanson Control Board if
you purchased one.

@ -1,79 +0,0 @@
#define TGA_PRO_EXPAND_REV2
#include "BALibrary.h"
using namespace BALibrary;
constexpr int potCalibMin = 1;
constexpr int potCalibMax = 1018;
constexpr bool potSwapDirection = true;
int pot1Handle, pot2Handle, pot3Handle, sw1Handle, sw2Handle, led1Handle, led2Handle;
bool mute = false;
BAAudioControlWM8731 *codecPtr = nullptr;
BAPhysicalControls *controlPtr = nullptr;
void configPhysicalControls(BAPhysicalControls &controls, BAAudioControlWM8731 &codec)
{
// Setup the controls. The return value is the handle to use when checking for control changes, etc.
// pushbuttons
sw1Handle = controls.addSwitch(BA_EXPAND_SW1_PIN);
sw2Handle = controls.addSwitch(BA_EXPAND_SW2_PIN);
// pots
pot1Handle = controls.addPot(BA_EXPAND_POT1_PIN, potCalibMin, potCalibMax, potSwapDirection);
pot2Handle = controls.addPot(BA_EXPAND_POT2_PIN, potCalibMin, potCalibMax, potSwapDirection);
pot3Handle = controls.addPot(BA_EXPAND_POT3_PIN, potCalibMin, potCalibMax, potSwapDirection);
// leds
led1Handle = controls.addOutput(BA_EXPAND_LED1_PIN);
led2Handle = controls.addOutput(BA_EXPAND_LED2_PIN); // will illuminate when pressing SW2
controlPtr = &controls;
codecPtr = &codec;
}
void checkPot(unsigned id)
{
float potValue;
unsigned handle;
switch(id) {
case 0 :
handle = pot1Handle;
break;
case 1 :
handle = pot2Handle;
break;
case 2 :
handle = pot3Handle;
break;
default :
handle = pot1Handle;
}
if (controlPtr->checkPotValue(handle, potValue)) {
// Pot has changed
codecPtr->setHeadphoneVolume(potValue);
}
}
void checkSwitch(unsigned id)
{
unsigned swHandle;
unsigned ledHandle;
switch(id) {
case 0 :
swHandle = sw1Handle;
ledHandle = led1Handle;
break;
case 1 :
swHandle = sw2Handle;
ledHandle = led2Handle;
break;
default :
swHandle = sw1Handle;
ledHandle = led1Handle;
}
bool pressed = controlPtr->isSwitchHeld(swHandle);
controlPtr->setOutput(ledHandle, pressed);
}

@ -1,71 +0,0 @@
/*************************************************************************
* This demo is used for manufacturing tests on the TGA Pro Expansion
* Control Board. Pushing the buttons turns on the LEDs. Adjusting
* any know will adjust the volume.
*
* The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary
*
*/
#include <Wire.h>
#include <Audio.h>
#include <SPI.h>
#define TGA_PRO_EXPAND_REV2
#include "BALibrary.h"
using namespace BALibrary;
AudioInputI2S i2sIn;
AudioOutputI2S i2sOut;
// Audio Thru Connection
AudioConnection patch0(i2sIn,0, i2sOut, 0);
AudioConnection patch1(i2sIn,1, i2sOut, 1);
BAAudioControlWM8731 codec;
BAGpio gpio; // access to User LED
BASpiMemoryDMA spiMem0(SpiDeviceId::SPI_DEVICE0);
BASpiMemoryDMA spiMem1(SpiDeviceId::SPI_DEVICE1);
// Create a control object using the number of switches, pots, encoders and outputs on the
// Blackaddr Audio Expansion Board.
BAPhysicalControls controls(BA_EXPAND_NUM_SW, BA_EXPAND_NUM_POT, BA_EXPAND_NUM_ENC, BA_EXPAND_NUM_LED);
void configPhysicalControls(BAPhysicalControls &controls, BAAudioControlWM8731 &codec);
void checkPot(unsigned id);
void checkSwitch(unsigned id);
bool spiTest(BASpiMemoryDMA *mem); // returns true if passed
bool uartTest(); // returns true if passed
void setup() {
Serial.begin(57600);
spiMem0.begin();
spiMem1.begin();
// Disable the audio codec first
codec.disable();
delay(100);
AudioMemory(128);
codec.enable();
codec.setHeadphoneVolume(0.8f); // Set headphone volume
configPhysicalControls(controls, codec);
// Run the initial Midi connectivity and SPI memory tests.
if (uartTest()) { Serial.println("MIDI Ports testing PASSED!"); }
if (spiTest(&spiMem0)) { Serial.println("SPI0 testing PASSED!");}
if (spiTest(&spiMem1)) { Serial.println("SPI1 testing PASSED!");}
}
void loop() {
// put your main code here, to run repeatedly:
checkPot(0);
checkPot(1);
checkPot(2);
checkSwitch(0);
checkSwitch(1);
delay(10);
}

@ -1,86 +0,0 @@
#include "BAHardware.h"
#include "BASpiMemory.h"
using namespace BALibrary;
constexpr unsigned LOW_RATE = 2400;
constexpr unsigned MIDI_RATE = 31250;
constexpr unsigned HIGH_RATE = 250000;
constexpr unsigned TEST_TIME = 5; // 5 second test each
static unsigned baudRate = LOW_RATE; // start with low speed
static uint8_t writeData = 0;
static unsigned loopCounter = 0;
static unsigned errorCount = 0;
static bool testFailed = false;
static bool testDone = false;
static unsigned testPhase = 0; // 0 for low speed, 1 for MIDI speed, 2 for high speed.
bool uartTest(void)
{
Serial1.begin(baudRate, SERIAL_8N1);
delay(100);
while(!Serial) {}
Serial.println(String("\nRunning MIDI Port speed test at ") + baudRate);
// write the first data
Serial1.write(writeData);
while(!testFailed && !testDone) {
if (loopCounter >= (baudRate/4)) { // the divisor determines how long the test runs for
// next test
switch (testPhase) {
case 0 :
baudRate = MIDI_RATE;
break;
case 1 :
baudRate = HIGH_RATE;
break;
case 2 :
testDone = true;
}
if (errorCount == 0) { Serial.println("TEST PASSED!"); }
else {
Serial.println("MIDI PORT TEST FAILED!");
}
errorCount = 0;
testPhase++;
loopCounter = 0;
if (!testDone) {
Serial.println(String("\nRunning MIDI Port speed test at ") + baudRate);
Serial1.begin(baudRate, SERIAL_8N1);
while (!Serial1) {} // wait for serial to be ready
} else {
Serial.println("MIDI PORT TEST DONE!\n");
}
}
// Wait for read data
if (Serial1.available()) {
uint8_t readData= Serial1.read();
if (readData != writeData) {
Serial.println(String("ERROR: readData = ") + readData + String(" writeData = ") + writeData);
errorCount++;
}
if ((loopCounter % (baudRate/64)) == 0) { // the divisor determines how often the period is printed
Serial.print("."); Serial.flush();
}
if (errorCount > 16) {
Serial.println("Halting test");
testFailed = true;
}
loopCounter++;
writeData++;
Serial1.write(writeData);
}
}
return testFailed;
}

@ -1,125 +0,0 @@
#include <cstddef>
#include <cstdint>
#include "BAHardware.h"
#include "BASpiMemory.h"
constexpr int NUM_TESTS = 12;
constexpr int NUM_BLOCK_WORDS = 128;
constexpr int mask0 = 0x5555;
constexpr int mask1 = 0xaaaa;
//#define SANITY_CHECK
using namespace BALibrary;
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);
}
bool spiTest(BASpiMemoryDMA *mem)
{
int spiAddress = 0;
int spiErrorCount = 0;
int maskPhase = 0;
int loopPhase = 0;
uint16_t memBlock[NUM_BLOCK_WORDS];
uint16_t goldData[NUM_BLOCK_WORDS];
Serial.println("Starting SPI MEM Test");
for (int cnt = 0; cnt < NUM_TESTS; cnt++) {
// Zero check
mem->zero16(0, SPI_MEM0_SIZE_BYTES / sizeof(uint16_t));
while (mem->isWriteBusy()) {}
for (spiAddress = 0; spiAddress <= SPI_MAX_ADDR; spiAddress += NUM_BLOCK_WORDS*sizeof(uint16_t)) {
mem->read16(spiAddress, memBlock, NUM_BLOCK_WORDS);
while (mem->isReadBusy()) {}
for (int i=0; i<NUM_BLOCK_WORDS; i++) {
if (memBlock[i] != 0) {
spiErrorCount++;
if (spiErrorCount >= 10) break;
}
}
if (spiErrorCount >= 10) break;
}
//if (spiErrorCount == 0) { Serial.println(String("SPI MEMORY(") + cnt + String("): Zero test PASSED!")); }
if (spiErrorCount == 0) { Serial.print("."); Serial.flush(); }
if (spiErrorCount > 0) { Serial.println(String("SPI MEMORY(") + cnt + String("): Zero test FAILED, error count = ") + spiErrorCount); return false;}
// Write all test data to the memory
maskPhase = 0;
for (spiAddress = 0; spiAddress <= SPI_MAX_ADDR; spiAddress += NUM_BLOCK_WORDS*sizeof(uint16_t)) {
// Calculate the data for a block
for (int i=0; i<NUM_BLOCK_WORDS; i++) {
memBlock[i] = calcData(spiAddress+i, loopPhase, maskPhase);
maskPhase = (maskPhase+1) % 2;
}
mem->write16(spiAddress, memBlock, NUM_BLOCK_WORDS);
while (mem->isWriteBusy()) {}
}
// Read back the test data
spiErrorCount = 0;
spiAddress = 0;
maskPhase = 0;
for (spiAddress = 0; spiAddress <= SPI_MAX_ADDR; spiAddress += NUM_BLOCK_WORDS*sizeof(uint16_t)) {
mem->read16(spiAddress, memBlock, NUM_BLOCK_WORDS);
// Calculate the golden data for a block
for (int i=0; i<NUM_BLOCK_WORDS; i++) {
goldData[i] = calcData(spiAddress+i, loopPhase, maskPhase);
maskPhase = (maskPhase+1) % 2;
}
while (mem->isReadBusy()) {} // wait for the read to finish
for (int i=0; i<NUM_BLOCK_WORDS; i++) {
if (goldData[i] != memBlock[i]) {
Serial.println(String("ERROR@ ") + i + String(": ") + goldData[i] + String("!=") + memBlock[i]);
spiErrorCount++;
if (spiErrorCount >= 10) break;
}
#ifdef SANITY_CHECK
else {
if ((spiAddress == 0) && (i<10) && (cnt == 0) ){
Serial.println(String("SHOW@ ") + i + String(": ") + goldData[i] + String("==") + memBlock[i]);
}
}
#endif
}
if (spiErrorCount >= 10) break;
}
//if (spiErrorCount == 0) { Serial.println(String("SPI MEMORY(") + cnt + String("): Data test PASSED!")); }
if (spiErrorCount == 0) { Serial.print("."); Serial.flush(); }
if (spiErrorCount > 0) { Serial.println(String("SPI MEMORY(") + cnt + String("): Data test FAILED, error count = ") + spiErrorCount); return false;}
loopPhase = (loopPhase+1) % 2;
}
return true;
}

@ -1,15 +1,52 @@
/************************************************************************* /*************************************************************************
* This demo is used for manufacturing tests on the TGA Pro Expansion * This demo is used for manufacturing testing on the TGA Pro Expansion
* Control Board. Pushing the buttons turns on the LEDs. Adjusting * Control Board.
* any know will adjust the volume. *
* This will test the following on the TGA Pro:
*
* - Audio INPUT and OUTPUT JACKS
* - Midi INPUT and Midi OUTPUT jacks
* - MEM0 (if installed)
* - MEM1 (if installed)
* - User LED
*
* This will also test the Expansion Control Board (if installed):
*
* - three POT knobs
* - two pushbutton SWitches
* - two LEDs
* - headphone output
*
* SETUP INSTRUCTIONS:
*
* 1) Connect an audio source to AUDIO INPUT.
* 2) Connect AUDIO OUTPUT to amp, stereo, headphone amplifier, etc.
* 3) if testing the MIDI ports, connect a MIDI cable between MIDI INPUT and MIDI OUTPUT
* 4) comment out any tests you want to skip
* 5) Compile and run the demo on your Teensy with TGA Pro.
* 6) Launch the Arduino Serial Monitor to see results.
*
* TESTING INSTRUCTIONS:
*
* 1) Check the Serial Monitor for the results of the MIDI testing, and external memory testing.
* 2) Confirm that the audio sent to the INPUT is coming out the OUTPUT.
* 3) Confirm the User LED is blinking every 1 or 2 seconds
*
* If using the Expansion Control Board:
*
* 1) Try pushing the pushbuttons. When pushed, they should turn on their corresponding LED.
* 2) Try turn each of the knobs one at a time. They should adjust the volume.
* *
* The latest copy of the BA Guitar library can be obtained from * The latest copy of the BA Guitar library can be obtained from
* https://github.com/Blackaddr/BALibrary * https://github.com/Blackaddr/BALibrary
* *
*/ */
#include <Wire.h>
#define RUN_MIDI_TEST // Comment out or delete this line to skip the MIDI test.
#define RUN_MEMO_TEST // Comment out or delete this line to skip the MEM0 test.
#define RUN_MEM1_TEST // (Teensy 3.5/3/6 only!) Comment out or delete this line to skip the MEM1 test.
#include <Audio.h> #include <Audio.h>
#include <SPI.h>
#define TGA_PRO_EXPAND_REV2 #define TGA_PRO_EXPAND_REV2
#include "BALibrary.h" #include "BALibrary.h"
@ -26,8 +63,13 @@ AudioConnection patch1(i2sIn,1, i2sOut, 1);
BAAudioControlWM8731 codec; BAAudioControlWM8731 codec;
BAGpio gpio; // access to User LED BAGpio gpio; // access to User LED
#if defined(RUN_MEMO_TEST)
BASpiMemoryDMA spiMem0(SpiDeviceId::SPI_DEVICE0); BASpiMemoryDMA spiMem0(SpiDeviceId::SPI_DEVICE0);
#endif
#if defined(RUN_MEM1_TEST)
BASpiMemoryDMA spiMem1(SpiDeviceId::SPI_DEVICE1); BASpiMemoryDMA spiMem1(SpiDeviceId::SPI_DEVICE1);
#endif
// Create a control object using the number of switches, pots, encoders and outputs on the // Create a control object using the number of switches, pots, encoders and outputs on the
// Blackaddr Audio Expansion Board. // Blackaddr Audio Expansion Board.
@ -39,12 +81,11 @@ void checkSwitch(unsigned id);
bool spiTest(BASpiMemoryDMA *mem); // returns true if passed bool spiTest(BASpiMemoryDMA *mem); // returns true if passed
bool uartTest(); // returns true if passed bool uartTest(); // returns true if passed
unsigned loopCounter = 0;
void setup() { void setup() {
Serial.begin(57600); Serial.begin(57600);
spiMem0.begin();
spiMem1.begin();
// Disable the audio codec first // Disable the audio codec first
codec.disable(); codec.disable();
delay(100); delay(100);
@ -54,13 +95,25 @@ void setup() {
configPhysicalControls(controls, codec); configPhysicalControls(controls, codec);
// Run the initial Midi connectivity and SPI memory tests. // Run the initial Midi connectivity and SPI memory tests.
#if defined(RUN_MIDI_TEST)
if (uartTest()) { Serial.println("MIDI Ports testing PASSED!"); } if (uartTest()) { Serial.println("MIDI Ports testing PASSED!"); }
#endif
#if defined(RUN_MEMO_TEST)
spiMem0.begin(); delay(10);
if (spiTest(&spiMem0)) { Serial.println("SPI0 testing PASSED!");} if (spiTest(&spiMem0)) { Serial.println("SPI0 testing PASSED!");}
#endif
#if defined(RUN_MEM1_TEST)
spiMem1.begin(); delay(10);
if (spiTest(&spiMem1)) { Serial.println("SPI1 testing PASSED!");} if (spiTest(&spiMem1)) { Serial.println("SPI1 testing PASSED!");}
#endif
Serial.println("Now monitoring for input from Expansion Control Board");
} }
void loop() { void loop() {
// put your main code here, to run repeatedly:
checkPot(0); checkPot(0);
checkPot(1); checkPot(1);
checkPot(2); checkPot(2);
@ -68,4 +121,8 @@ void loop() {
checkSwitch(1); checkSwitch(1);
delay(10); delay(10);
loopCounter++;
if ((loopCounter % 100) == 0) {
gpio.toggleLed();
}
} }

@ -3,18 +3,17 @@
using namespace BALibrary; using namespace BALibrary;
constexpr unsigned LOW_RATE = 2400;
constexpr unsigned MIDI_RATE = 31250; constexpr unsigned MIDI_RATE = 31250;
constexpr unsigned HIGH_RATE = 250000; constexpr unsigned HIGH_RATE = 250000;
constexpr unsigned TEST_TIME = 5; // 5 second test each constexpr unsigned TEST_TIME = 5; // 5 second test each
static unsigned baudRate = LOW_RATE; // start with low speed static unsigned baudRate = MIDI_RATE; // start with low speed
static uint8_t writeData = 0; static uint8_t writeData = 0;
static unsigned loopCounter = 0; static unsigned loopCounter = 0;
static unsigned errorCount = 0; static unsigned errorCount = 0;
static bool testFailed = false; static bool testFailed = false;
static bool testDone = false; static bool testDone = false;
static unsigned testPhase = 0; // 0 for low speed, 1 for MIDI speed, 2 for high speed. static unsigned testPhase = 0; // 0 for MIDI speed, 1 for high speed.
bool uartTest(void) bool uartTest(void)
{ {
@ -32,12 +31,9 @@ bool uartTest(void)
// next test // next test
switch (testPhase) { switch (testPhase) {
case 0 : case 0 :
baudRate = MIDI_RATE;
break;
case 1 :
baudRate = HIGH_RATE; baudRate = HIGH_RATE;
break; break;
case 2 : case 1 :
testDone = true; testDone = true;
} }

@ -0,0 +1,29 @@
/*
* BAEffects.h
*
* 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/>.
*/
#ifndef __BAEFFECTS_H
#define __BAEFFECTS_H
#include "BALibrary.h" // contains the Blackaddr hardware board definitions
#include "BAAudioEffectDelayExternal.h"
#include "AudioEffectAnalogDelay.h"
#include "AudioEffectSOS.h"
#endif /* __BAEFFECTS_H */

@ -23,11 +23,12 @@
#include "BAHardware.h" // contains the Blackaddr hardware board definitions #include "BAHardware.h" // contains the Blackaddr hardware board definitions
#include "BATypes.h" #include "BATypes.h"
#include "LibBasicFunctions.h"
#include "LibMemoryManagement.h"
#include "BAAudioControlWM8731.h" // Codec Control #include "BAAudioControlWM8731.h" // Codec Control
#include "BASpiMemory.h" #include "BASpiMemory.h"
#include "BAGpio.h" #include "BAGpio.h"
#include "LibBasicFunctions.h"
#include "LibMemoryManagement.h"
#include "BAPhysicalControls.h" #include "BAPhysicalControls.h"
#endif /* __BALIBRARY_H */ #endif /* __BALIBRARY_H */

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