Updates to the production examples

6 years ago · 86e764eba3
parent a4f9f19f7a
commit 86e764eba3
8 changed files with 410 additions and 19 deletions
--- a/examples/Tests/TGA_PRO_MEM2/PhysicalControls.cpp
+++ b/examples/Tests/TGA_PRO_MEM2/PhysicalControls.cpp
@ -72,15 +72,8 @@ void checkSwitch(unsigned id)
      ledHandle = led1Handle;
  }
-    if (controlPtr->isSwitchToggled(swHandle)) {
+  bool pressed = controlPtr->isSwitchHeld(swHandle);
-      Serial.println(String("SW ") + swHandle + String("Pushed"));
+  controlPtr->setOutput(ledHandle, pressed);
      mute = !mute;
      if (mute) { codecPtr->setHeadphoneVolume(0.0f); }
      else { codecPtr->setHeadphoneVolume(0.8f); }
    }
    bool pressed = controlPtr->isSwitchHeld(swHandle);
    controlPtr->setOutput(ledHandle, pressed);
 }
--- a/examples/Tests/TGA_PRO_MEM2/TGA_PRO_MEM2.ino
+++ b/examples/Tests/TGA_PRO_MEM2/TGA_PRO_MEM2.ino
@ -1,3 +1,12 @@
 /*************************************************************************
 * 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>
@ -38,14 +47,16 @@ void setup() {
  // Disable the audio codec first
  codec.disable();
  delay(100);
  AudioMemory(128);
  codec.enable();
  codec.setHeadphoneVolume(0.8f); // Set headphone volume
  configPhysicalControls(controls, codec);
-//  if (uartTest()) { Serial.println("MIDI Ports testing PASSED!"); }
+  // Run the initial Midi connectivity and SPI memory tests.
-//  if (spiTest(&spiMem0)) { Serial.println("SPI0 testing PASSED!");}
+  if (uartTest()) { Serial.println("MIDI Ports testing PASSED!"); }
-//  if (spiTest(&spiMem1)) { Serial.println("SPI1 testing PASSED!");}
+  if (spiTest(&spiMem0)) { Serial.println("SPI0 testing PASSED!");}
  if (spiTest(&spiMem1)) { Serial.println("SPI1 testing PASSED!");}
 }
 void loop() {
@ -55,5 +66,6 @@ void loop() {
  checkPot(2);
  checkSwitch(0);
  checkSwitch(1);
  delay(10);
 }
--- a/examples/Tests/TGA_PRO_MEM2_EXP/PhysicalControls.cpp
+++ b/examples/Tests/TGA_PRO_MEM2_EXP/PhysicalControls.cpp
@ -0,0 +1,79 @@
 #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);
 }
--- a/examples/Tests/TGA_PRO_MEM2_EXP/TGA_PRO_MEM2_EXP.ino
+++ b/examples/Tests/TGA_PRO_MEM2_EXP/TGA_PRO_MEM2_EXP.ino
@ -0,0 +1,71 @@
 /*************************************************************************
 * 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);
 }
--- a/examples/Tests/TGA_PRO_MEM2_EXP/UartTest.cpp
+++ b/examples/Tests/TGA_PRO_MEM2_EXP/UartTest.cpp
@ -0,0 +1,86 @@
 #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;
 }
--- a/examples/Tests/TGA_PRO_MEM2_EXP/spiTest.cpp
+++ b/examples/Tests/TGA_PRO_MEM2_EXP/spiTest.cpp
@ -0,0 +1,125 @@
 #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;
 }
--- a/src/BAPhysicalControls.h
+++ b/src/BAPhysicalControls.h
@ -24,7 +24,7 @@
 #include <vector>
 #include <Encoder.h>
-#include <Bounce.h>
+#include <Bounce2.h>
 namespace BALibrary {
@ -52,6 +52,27 @@ private:
 	int m_val = 0; ///< store the value to support toggling
 };
 /// Convenience class for handling digital inputs. This wraps Bounce with the abilty
 /// to invert the polarity of the pin.
 class DigitalInput : public Bounce {
 public:
 	/// Create an input where digital low is return true. Most switches ground when pressed.
 	DigitalInput() : m_isPolarityInverted(true) {}
 	/// Create an input and specify if input polarity is inverted.
 	/// @param isPolarityInverted when false, a high voltage on the pin returns true, 0V returns false.
 	DigitalInput(bool isPolarityInverted) : m_isPolarityInverted(isPolarityInverted) {}
 	/// Read the state of the pin according to the polarity
 	/// @returns true when the input should be interpreted as the switch is closed, else false.
 	bool read() { return Bounce::read() != m_isPolarityInverted; } // logical XOR to conditionally invert polarity
 	/// Set whether the input pin polarity
 	/// @param polarity when true, a low voltage on the pin is considered true by read(), else false.
 	void setPolarityInverted(bool polarity) { m_isPolarityInverted = polarity; }
 private:
 	bool m_isPolarityInverted;
 };
 /// Convenience class for handling an analog pot as a control. When calibrated,
 /// returns a float between 0.0 and 1.0.
 class Potentiometer {
@ -238,7 +259,7 @@ public:
 private:
  std::vector<Potentiometer> m_pots;     ///< a vector of all added pots
  std::vector<RotaryEncoder> m_encoders; ///< a vector of all added encoders
-  std::vector<Bounce>  m_switches;       ///< a vector of all added switches
+  std::vector<DigitalInput>  m_switches;       ///< a vector of all added switches
  std::vector<DigitalOutput> m_outputs;  ///< a vector of all added outputs
 };
--- a/src/peripherals/BAPhysicalControls.cpp
+++ b/src/peripherals/BAPhysicalControls.cpp
@ -57,7 +57,10 @@ unsigned BAPhysicalControls::addRotary(uint8_t pin1, uint8_t pin2, bool swapDire
 }
 unsigned BAPhysicalControls::addSwitch(uint8_t pin, unsigned long intervalMilliseconds) {
-	m_switches.emplace_back(pin, intervalMilliseconds);
+	//m_switches.emplace_back(pin, intervalMilliseconds);'
 	m_switches.emplace_back();
 	m_switches.back().attach(pin);
 	m_switches.back().interval(10);
 	pinMode(pin, INPUT);
 	return m_switches.size()-1;
 }
@ -87,7 +90,7 @@ void BAPhysicalControls::setOutput(unsigned handle, int val) {
 void BAPhysicalControls::setOutput(unsigned handle, bool val) {
 	if (handle >= m_outputs.size()) { return; }
-	unsigned value = val ? true : false;
+	unsigned value = val ? 1 : 0;
 	m_outputs[handle].set(value);
 }
@ -116,7 +119,7 @@ bool BAPhysicalControls::checkPotValue(unsigned handle, float &value) {
 bool BAPhysicalControls::isSwitchToggled(unsigned handle) {
 	if (handle >= m_switches.size()) { return 0; } // handle is greater than number of switches
-	Bounce &sw = m_switches[handle];
+	DigitalInput &sw = m_switches[handle];
 	if (sw.update() && sw.fallingEdge()) {
 	  return true;
@ -128,8 +131,9 @@ bool BAPhysicalControls::isSwitchToggled(unsigned handle) {
 bool BAPhysicalControls::isSwitchHeld(unsigned handle)
 {
 	if (handle >= m_switches.size()) { return 0; } // handle is greater than number of switches
-	Bounce &sw = m_switches[handle];
+	DigitalInput &sw = m_switches[handle];
 	sw.update();
 	if (sw.read()) {
 		return true;
 	} else {
@ -140,7 +144,7 @@ bool BAPhysicalControls::isSwitchHeld(unsigned handle)
 int BAPhysicalControls::getSwitchValue(unsigned handle)
 {
 	if (handle >= m_switches.size()) { return 0; } // handle is greater than number of switches
-	Bounce &sw = m_switches[handle];
+	DigitalInput &sw = m_switches[handle];
 	return sw.read();
 }