ADC ok with interrupt or drdy

RotaxMonitor/lib/ADS1256/ADS1256.h

@@ -1,4 +1,4 @@
-//ADS1256 header file
+// ADS1256 header file
 /*
  Name:		ADS1256.h
  Created:	2022/07/14
@@ -14,51 +14,55 @@
 #define _ADS1256_h
 
 #include <SPI.h>
+#include <Arduino.h>
 
-//Differential inputs
+// SPI Frequency
-#define DIFF_0_1 0b00000001 //A0 + A1 as differential input
+#define SPI_FREQ 1920000
-#define DIFF_2_3 0b00100011 //A2 + A3 as differential input
-#define DIFF_4_5 0b01000101 //A4 + A5 as differential input
-#define DIFF_6_7 0b01100111 //A6 + A7 as differential input
 
-//Single-ended inputs
+// Differential inputs
-#define SING_0 0b00001111 //A0 + GND (common) as single-ended input
+#define DIFF_0_1 0b00000001 // A0 + A1 as differential input
-#define SING_1 0b00011111 //A1 + GND (common) as single-ended input
+#define DIFF_2_3 0b00100011 // A2 + A3 as differential input
-#define SING_2 0b00101111 //A2 + GND (common) as single-ended input
+#define DIFF_4_5 0b01000101 // A4 + A5 as differential input
-#define SING_3 0b00111111 //A3 + GND (common) as single-ended input
+#define DIFF_6_7 0b01100111 // A6 + A7 as differential input
-#define SING_4 0b01001111 //A4 + GND (common) as single-ended input
-#define SING_5 0b01011111 //A5 + GND (common) as single-ended input
-#define SING_6 0b01101111 //A6 + GND (common) as single-ended input
-#define SING_7 0b01111111 //A7 + GND (common) as single-ended input
 
-//PGA settings			  //Input voltage range
+// Single-ended inputs
-#define PGA_1 0b00000000  //± 5 V
+#define SING_0 0b00001111 // A0 + GND (common) as single-ended input
-#define PGA_2 0b00000001  //± 2.5 V
+#define SING_1 0b00011111 // A1 + GND (common) as single-ended input
-#define PGA_4 0b00000010  //± 1.25 V
+#define SING_2 0b00101111 // A2 + GND (common) as single-ended input
-#define PGA_8 0b00000011  //± 625 mV
+#define SING_3 0b00111111 // A3 + GND (common) as single-ended input
-#define PGA_16 0b00000100 //± 312.5 mV
+#define SING_4 0b01001111 // A4 + GND (common) as single-ended input
+#define SING_5 0b01011111 // A5 + GND (common) as single-ended input
+#define SING_6 0b01101111 // A6 + GND (common) as single-ended input
+#define SING_7 0b01111111 // A7 + GND (common) as single-ended input
+
+// PGA settings			  //Input voltage range
+#define PGA_1 0b00000000  // ± 5 V
+#define PGA_2 0b00000001  // ± 2.5 V
+#define PGA_4 0b00000010  // ± 1.25 V
+#define PGA_8 0b00000011  // ± 625 mV
+#define PGA_16 0b00000100 // ± 312.5 mV
 #define PGA_32 0b00000101 //+ 156.25 mV
-#define PGA_64 0b00000110 //± 78.125 mV
+#define PGA_64 0b00000110 // ± 78.125 mV
 
-//Datarate						  //DEC
+// Datarate						  //DEC
-#define DRATE_30000SPS 0b11110000 //240
+#define DRATE_30000SPS 0b11110000 // 240
-#define DRATE_15000SPS 0b11100000 //224
+#define DRATE_15000SPS 0b11100000 // 224
-#define DRATE_7500SPS 0b11010000  //208
+#define DRATE_7500SPS 0b11010000  // 208
-#define DRATE_3750SPS 0b11000000  //192
+#define DRATE_3750SPS 0b11000000  // 192
-#define DRATE_2000SPS 0b10110000  //176
+#define DRATE_2000SPS 0b10110000  // 176
-#define DRATE_1000SPS 0b10100001  //161
+#define DRATE_1000SPS 0b10100001  // 161
-#define DRATE_500SPS 0b10010010   //146
+#define DRATE_500SPS 0b10010010	  // 146
-#define DRATE_100SPS 0b10000010   //130
+#define DRATE_100SPS 0b10000010	  // 130
-#define DRATE_60SPS 0b01110010    //114
+#define DRATE_60SPS 0b01110010	  // 114
-#define DRATE_50SPS 0b01100011    //99
+#define DRATE_50SPS 0b01100011	  // 99
-#define DRATE_30SPS 0b01010011    //83
+#define DRATE_30SPS 0b01010011	  // 83
-#define DRATE_25SPS 0b01000011    //67
+#define DRATE_25SPS 0b01000011	  // 67
-#define DRATE_15SPS 0b00110011    //51
+#define DRATE_15SPS 0b00110011	  // 51
-#define DRATE_10SPS 0b00100011    //35
+#define DRATE_10SPS 0b00100011	  // 35
-#define DRATE_5SPS 0b00010011     //19
+#define DRATE_5SPS 0b00010011	  // 19
-#define DRATE_2SPS 0b00000011     //3
+#define DRATE_2SPS 0b00000011	  // 3
 
-//Status register
+// Status register
 #define BITORDER_MSB 0
 #define BITORDER_LSB 1
 #define ACAL_DISABLED 0
@@ -66,7 +70,7 @@
 #define BUFFER_DISABLED 0
 #define BUFFER_ENABLED 1
 
-//Register addresses
+// Register addresses
 #define STATUS_REG 0x00
 #define MUX_REG 0x01
 #define ADCON_REG 0x02
@@ -79,7 +83,7 @@
 #define FSC1_REG 0x09
 #define FSC2_REG 0x0A
 
-//Command definitions
+// Command definitions
 #define WAKEUP 0b00000000
 #define RDATA 0b00000001
 #define RDATAC 0b00000011
@@ -96,26 +100,30 @@
 #define RESET 0b11111110
 //----------------------------------------------------------------
 
-
 class ADS1256
 {
 public:
-static constexpr int8_t PIN_UNUSED = -1;
+	static constexpr int8_t PIN_UNUSED = -1;
 
-	//Constructor
+	// Constructor
-	ADS1256(const int8_t DRDY_pin, const int8_t RESET_pin, const int8_t SYNC_pin, const int8_t CS_pin, float VREF, SPIClass* spi = &SPI);
+	ADS1256(const int8_t DRDY_pin, const int8_t RESET_pin, const int8_t SYNC_pin, const int8_t CS_pin, float VREF, SPIClass *spi = &SPI);
+	~ADS1256()
+	{
+		vSemaphoreDelete(m_drdyHigh);
+		vSemaphoreDelete(m_drdyLow);
+	}
 
-	//Initializing function
+	// Initializing function
 	void InitializeADC();
-	//ADS1256(int drate, int pga, int byteOrder, bool bufen);
+	// ADS1256(int drate, int pga, int byteOrder, bool bufen);
 
-	//Read a register
+	// Read a register
 	long readRegister(uint8_t registerAddress);
 
-	//Write a register
+	// Write a register
 	void writeRegister(uint8_t registerAddress, uint8_t registerValueToWrite);
 
-	//Individual methods
+	// Individual methods
 	void setDRATE(uint8_t drate);
 	void setPGA(uint8_t pga);
 	uint8_t getPGA();
@@ -133,57 +141,75 @@ static constexpr int8_t PIN_UNUSED = -1;
 	void setSDCS(uint8_t sdcs);
 	void sendDirectCommand(uint8_t directCommand);
 
-	//Get a single conversion
+	// Get a single conversion
 	long readSingle();
 
-	//Single input continuous reading
+	// Single input continuous reading
 	long readSingleContinuous();
 
-	//Cycling through the single-ended inputs
+	// Cycling through the single-ended inputs
-	long cycleSingle(); //Ax + COM
+	long cycleSingle(); // Ax + COM
 
-	//Cycling through the differential inputs
+	// Cycling through the differential inputs
-	long cycleDifferential(); //Ax + Ay
+	long cycleDifferential(); // Ax + Ay
 
-	//Converts the reading into a voltage value
+	// Converts the reading into a voltage value
 	float convertToVoltage(int32_t rawData);
 
-	//Stop AD
+	// Stop AD
 	void stopConversion();
 
+	// functions for callback
+	inline uint8_t getDRDYpin()
+	{
+		return m_DRDY_pin;
+	}
+
+	SemaphoreHandle_t getDRDYsemaphoreHigh()
+	{
+		return m_drdyHigh;
+	}
+
+	SemaphoreHandle_t getDRDYsemaphoreLow()
+	{
+		return m_drdyLow;
+	}
+
 private:
+	SPIClass *_spi; // Pointer to an SPIClass object
 
-SPIClass* _spi; //Pointer to an SPIClass object
+	void waitForLowDRDY();	// Block until DRDY is low
+	void waitForHighDRDY(); // Block until DRDY is high
+	void updateMUX(uint8_t muxValue);
+	inline void CS_LOW();
+	inline void CS_HIGH();
 
-void waitForLowDRDY(); // Block until DRDY is low
+	void updateConversionParameter(); // Refresh the conversion parameter based on the PGA
-void waitForHighDRDY(); // Block until DRDY is high
-void updateMUX(uint8_t muxValue);
-inline void CS_LOW();
-inline void CS_HIGH();
 
-void updateConversionParameter(); //Refresh the conversion parameter based on the PGA
+	float m_VREF = 0;				 // Value of the reference voltage
+	float m_conversionParameter = 0; // PGA-dependent multiplier
+	// Pins
+	int8_t m_DRDY_pin;	// Pin assigned for DRDY
+	int8_t m_RESET_pin; // Pin assigned for RESET
+	int8_t m_SYNC_pin;	// Pin assigned for SYNC
+	int8_t m_CS_pin;	// Pin assigned for CS
 
-float _VREF = 0; //Value of the reference voltage
+	// Register values
-float conversionParameter = 0; //PGA-dependent multiplier
+	uint8_t m_DRATE;	 // Value of the DRATE register
-//Pins
+	uint8_t m_ADCON;	 // Value of the ADCON register
-int8_t _DRDY_pin; //Pin assigned for DRDY
+	uint8_t m_MUX;		 // Value of the MUX register
-int8_t _RESET_pin; //Pin assigned for RESET
+	uint8_t m_PGA;		 // Value of the PGA (within ADCON)
-int8_t _SYNC_pin; //Pin assigned for SYNC
+	uint8_t m_GPIO;		 // Value of the GPIO register
-int8_t _CS_pin; //Pin assigned for CS
+	uint8_t m_STATUS;	 // Value of the status register
+	uint8_t m_GPIOvalue; // GPIO value
+	uint8_t m_ByteOrder; // Byte order
 
-//Register values
+	uint8_t m_outputBuffer[3];	 // 3-byte (24-bit) buffer for the fast acquisition - Single-channel, continuous
-byte _DRATE; //Value of the DRATE register
+	int32_t m_outputValue;		 // Combined value of the m_outputBuffer[3]
-byte _ADCON; //Value of the ADCON register
+	bool m_isAcquisitionRunning; // bool that keeps track of the acquisition (running or not)
-byte _MUX; //Value of the MUX register
+	uint8_t m_cycle;			 // Tracks the cycles as the MUX is cycling through the input channels
-byte _PGA; //Value of the PGA (within ADCON)
-byte _GPIO; //Value of the GPIO register
-byte _STATUS; //Value of the status register
-byte _GPIOvalue; //GPIO value
-byte _ByteOrder; //Byte order
 
-byte _outputBuffer[3]; //3-byte (24-bit) buffer for the fast acquisition - Single-channel, continuous
+	SemaphoreHandle_t m_drdyHigh;
-long _outputValue; //Combined value of the _outputBuffer[3]
+	SemaphoreHandle_t m_drdyLow;
-bool _isAcquisitionRunning; //bool that keeps track of the acquisition (running or not)
-uint8_t _cycle; //Tracks the cycles as the MUX is cycling through the input channels
 };
 #endif

RotaxMonitor/lib/led/led.cpp

@@ -4,6 +4,7 @@ RGBled::RGBled(const uint8_t pin) : m_led(pin)
 {
     pinMode(m_led, OUTPUT);
     writeStatus(RGBled::ERROR);
+    m_brightness = 1.0f; 
 }
 
 RGBled::~RGBled()
@@ -11,6 +12,11 @@ RGBled::~RGBled()
     pinMode(m_led, INPUT);
 }
 
+void RGBled::setBrightness(const float b)
+{
+    m_brightness = b;
+}
+
 void RGBled::setStatus(const LedStatus s)
 {
     if (m_status == s)
@@ -27,6 +33,6 @@ const RGBled::LedStatus RGBled::getSatus(void)
 
 void RGBled::writeStatus(const RGBled::LedStatus s)
 {
-    RGBled::color_u u{.status = s};
+    const RGBled::color_u u{.status = s};
-    rgbLedWrite(m_led, u.color.r, u.color.g, u.color.b);
+    rgbLedWrite(m_led, (uint8_t)(m_brightness*u.color.r), (uint8_t)(m_brightness*u.color.g), (uint8_t)(m_brightness*u.color.b));
 }

RotaxMonitor/lib/led/led.h

@@ -50,6 +50,7 @@ public:
     RGBled(const uint8_t pin = 48);
     ~RGBled();
 
+    void setBrightness(const float b);
     void setStatus(const LedStatus s);
     const LedStatus getSatus(void);
 
@@ -59,5 +60,6 @@ private:
 private:
     LedStatus m_status = LedStatus::IDLE;
     std::mutex m_mutex;
+    float m_brightness;
     const uint8_t m_led;
 };

RotaxMonitor/platformio.ini

@@ -28,7 +28,7 @@ monitor_port = /dev/ttyACM0
 monitor_speed = 921600
 build_type = release
 build_flags = 
-	-DCORE_DEBUG_LEVEL=1
+	-DCORE_DEBUG_LEVEL=5
 	-DARDUINO_USB_CDC_ON_BOOT=0
 	-DARDUINO_USB_MODE=0
 	-DCONFIG_ASYNC_TCP_MAX_ACK_TIME=5000
@@ -59,7 +59,7 @@ build_flags =
 	-O0
 	-g3
 	-ggdb3
-	-DCORE_DEBUG_LEVEL=3
+	-DCORE_DEBUG_LEVEL=5
 	-DARDUINO_USB_CDC_ON_BOOT=0
 	-DARDUINO_USB_MODE=0
 	-DCONFIG_ASYNC_TCP_MAX_ACK_TIME=5000

RotaxMonitor/src/datasave.cpp

@@ -1,8 +1,6 @@
 #include "datasave.h"
 #include <math.h>
 
-
-
 LITTLEFSGuard::LITTLEFSGuard()
 {
     if (!LittleFS.begin(true, "/littlefs", 10, "littlefs"))
@@ -12,7 +10,7 @@ LITTLEFSGuard::LITTLEFSGuard()
     else
     {
         LOG_INFO("LittleFS mounted successfully");
-        LOG_INFO("LittleFS Free KBytes:", (LittleFS.totalBytes() - LittleFS.usedBytes()) /1024);
+        LOG_INFO("LittleFS Free KBytes:", (LittleFS.totalBytes() - LittleFS.usedBytes()) / 1024);
     }
 }
 
@@ -49,8 +47,7 @@ void ignitionBoxStatusFiltered::update(const ignitionBoxStatus &new_status)
     }
     m_count++;
     // simple moving average calculation
-    m_last.timestamp = new_status.timestamp; // keep timestamp of latest status
+    m_last.timestamp = new_status.timestamp;                                         // keep timestamp of latest status
-
     m_last.coils12.n_events = new_status.coils12.n_events;                           // sum events instead of averaging
     m_last.coils12.n_missed_firing = new_status.coils12.n_missed_firing;             // sum missed firings instead of averaging
     m_last.coils12.spark_status = new_status.coils12.spark_status;                   // take latest spark status
@@ -72,7 +69,7 @@ void ignitionBoxStatusFiltered::update(const ignitionBoxStatus &new_status)
     filter(m_last.coils34.peak_n_out, new_status.coils34.peak_n_out, m_max_count);   // incremental average calculation
     filter(m_last.eng_rpm, new_status.eng_rpm, m_max_count);                         // incremental average calculation                   // incremental average calculation
     filter(m_last.adc_read_time, m_last.adc_read_time, m_max_count);                 // incremental average calculation
-    m_last.n_queue_errors = new_status.n_queue_errors;                               // take last of queue errors since it's a cumulative count of errors in the queue, not an average value
+    m_last.n_queue_errors = new_status.n_queue_errors;
 
     if (m_count >= m_max_count)
     {
@@ -124,4 +121,3 @@ const ArduinoJson::JsonDocument ignitionBoxStatusFiltered::toJson() const
     }
     return doc;
 }
-

RotaxMonitor/src/devices.h

@@ -9,7 +9,8 @@
 // Device Libraries
 #include <ADS1256.h>
 #include <AD5292.h>
-#include <PCA95x5.h>
+#include <extio.h>
+#include <Wire.h>
 
 // ADC Channel mapping
 #define ADC_CH_PEAK_12P_IN SING_0
@@ -24,34 +25,31 @@
 // Device Pointer structs for tasks
 struct Devices
 {
+    // Busses
+    std::unique_ptr<TwoWire> m_i2c = nullptr;
     std::unique_ptr<SPIClass> m_spi_a = nullptr;
     std::unique_ptr<SPIClass> m_spi_b = nullptr;
 
+    // Bus Mutextes
+    std::mutex m_spi_a_mutex;
+    std::mutex m_spi_b_mutex;
+    std::mutex m_i2c_mutex;
+
+    // Device Pointers
     std::unique_ptr<AD5292> m_pot_a = nullptr;
     std::unique_ptr<AD5292> m_pot_b = nullptr;
 
     std::unique_ptr<ADS1256> m_adc_a = nullptr;
     std::unique_ptr<ADS1256> m_adc_b = nullptr;
 
-    std::unique_ptr<PCA9555> m_expander_a = nullptr;
+    std::unique_ptr<ExternalIO> m_ext_io = nullptr;
-    std::unique_ptr<PCA9555> m_expander_b = nullptr;
-    std::unique_ptr<PCA9555> m_expander_inputs_ab = nullptr;
-
-    std::mutex m_spi_a_mutex;
-    std::mutex m_spi_b_mutex;
-
-    std::mutex m_i2c_mutex;
 };
 
 // Adc read channel wrapper to selet mux before reading
 inline float adcReadChannel(ADS1256 *adc, const uint8_t ch)
 {
     adc->setMUX(ch);
-    // scarta 3 conversioni
+    adc->readSingle();
-    for (int i = 0; i < 3; i++)
-    {
-        adc->readSingle();
-    }
     // ora lettura valida a 30kSPS → ~100 µs di settling
     return adc->convertToVoltage(adc->readSingle());
 }

RotaxMonitor/src/extio.cpp

@@ -0,0 +1,129 @@
+#include <extio.h>
+
+// Static interrupt callback
+static void onExpanderInterrupt(void *arg)
+{
+    auto cls = (ExternalIO *)(arg);
+    if (!cls) // invalid args
+        return;
+    cls->extReadInterrupt();
+}
+
+ExternalIO::ExternalIO(TwoWire &i2c, std::mutex &i2c_mutex, const uint8_t int_pin) : m_i2cMutex(i2c_mutex), m_i2c(i2c), m_intPin(int_pin)
+{
+    std::lock_guard<std::mutex> lock(m_i2cMutex);
+    // Attach OUT expanders on BUS
+    m_outMap[EXPANDER_A_OUT_ADDR] = std::make_unique<PCA9555>();
+    m_outMap[EXPANDER_A_OUT_ADDR]->attach(m_i2c, EXPANDER_A_OUT_ADDR);
+    m_outMap[EXPANDER_B_OUT_ADDR] = std::make_unique<PCA9555>();
+    m_outMap[EXPANDER_B_OUT_ADDR]->attach(m_i2c, EXPANDER_B_OUT_ADDR);
+
+    for (auto &[a, e] : m_outMap)
+    {
+        e->direction(PCA95x5::Direction::OUT_ALL);
+        e->polarity(PCA95x5::Polarity::ORIGINAL_ALL);
+    };
+
+    // Attach IN Expanders on Bus
+    m_inMap[EXPANDER_A_IN_ADDR] = std::make_unique<PCA9555>();
+    m_inMap[EXPANDER_A_IN_ADDR]->attach(m_i2c, EXPANDER_A_IN_ADDR);
+    m_inMap[EXPANDER_B_IN_ADDR] = std::make_unique<PCA9555>();
+    m_inMap[EXPANDER_B_IN_ADDR]->attach(m_i2c, EXPANDER_B_IN_ADDR);
+
+    for (auto &[a, e] : m_inMap)
+    {
+        e->direction(PCA95x5::Direction::IN_ALL);
+        e->polarity(PCA95x5::Polarity::ORIGINAL_ALL);
+        m_lastInputState[a] = e->read(); /// initialize input state to collect interrupts
+    };
+}
+ExternalIO::~ExternalIO() {
+
+}
+
+void ExternalIO::extDigitalWrite(const uint32_t mappedPin, const bool val)
+{
+    std::lock_guard<std::mutex> lock(m_i2cMutex);
+    const io_t pa = map2pin(mappedPin);
+    if (!m_outMap.contains(pa.addr))
+    {
+        LOG_ERROR("Undefined IO Expander addr: [", pa.addr, "]");
+        return;
+    }
+    auto &io = m_outMap.at(pa.addr);
+    if (!io->write(static_cast<PCA95x5::Port::Port>(pa.pin), val ? PCA95x5::Level::H : PCA95x5::Level::L))
+    {
+        LOG_ERROR("IO Expander [", pa.addr, "] Unable to WRITE Port [", pa.pin, "] to [", val ? "HIGH" : "LOW");
+        LOG_ERROR("IO Expander Error [", io->i2c_error(), "]");
+    }
+}
+
+const bool ExternalIO::extDigitalRead(const uint32_t mappedPin)
+{
+    std::lock_guard<std::mutex> lock(m_i2cMutex);
+    const io_t pa = map2pin(mappedPin);
+    if (!m_inMap.contains(pa.addr))
+    {
+        LOG_ERROR("Undefined IO Expander addr: [", pa.addr, "]");
+        return false;
+    }
+    auto &io = m_inMap.at(pa.addr);
+    const bool rv = io->read(static_cast<PCA95x5::Port::Port>(pa.pin)) == PCA95x5::Level::H ? true : false; // read value
+    const uint8_t err = io->i2c_error();
+    if (err)
+    {
+        LOG_ERROR("IO Expander [", pa.addr, "] Unable to READ Port [", pa.pin, "]");
+        LOG_ERROR("IO Expander Error [", err, "]");
+    }
+    return rv;
+}
+
+void ExternalIO::extAttachInterrupt(ExtInterruptCb cb)
+{
+    attachInterruptArg(EXPANDER_ALL_INTERRUPT, onExpanderInterrupt, (void *)(this), FALLING);
+    m_extInterruptCb = cb;
+}
+
+void ExternalIO::extDetachInterrupt()
+{
+    detachInterrupt(EXPANDER_ALL_INTERRUPT);
+}
+
+void ExternalIO::extReadInterrupt()
+{
+    std::lock_guard<std::mutex> lock(m_i2cMutex);
+    disableInterrupt(EXPANDER_ALL_INTERRUPT);
+    // read all registers and collect
+    IOstate interruptState;
+    for (auto &[a, e] : m_inMap)
+    {
+        interruptState[a] = e->read();
+    }
+    m_lastInputState = interruptState; // restore to current values
+    // compare to last state to see the difference
+    if (m_extInterruptCb)
+    {
+        for (auto &[a, v] : interruptState)
+        {
+            if (v)
+                m_extInterruptCb(stat2map(a, v));
+        }
+    }
+
+    enableInterrupt(EXPANDER_ALL_INTERRUPT);
+}
+
+const ExternalIO::io_t ExternalIO::map2pin(const uint32_t mappedIO)
+{
+    return io_t{
+        .addr = (uint8_t)((mappedIO >> 16) & (uint8_t)0xFF),
+        .pin = (uint8_t)(mappedIO && (uint32_t)0xFF),
+    };
+}
+
+const uint32_t ExternalIO::stat2map(const uint8_t addr, const uint16_t stat)
+{
+    if (!stat)
+        return 0;
+    return (uint32_t)(addr << 16) | (1UL << __builtin_ctz(stat));
+}

RotaxMonitor/src/extio.h

@@ -0,0 +1,49 @@
+#pragma once
+#define DEBUGLOG_DEFAULT_LOG_LEVEL_DEBUG
+
+#include <Arduino.h>
+#include <DebugLog.h>
+#include <PCA95x5.h>
+
+#include <pins.h>
+
+#include <memory>
+#include <map>
+
+class ExternalIO
+{
+    using IOptr = std::unique_ptr<PCA9555>;
+    using IOmap = std::map<const uint8_t, IOptr>;
+    using IOstate = std::map<const uint8_t, uint16_t>;
+    using ExtInterruptCb = std::function<void(const uint32_t)>;
+
+    struct io_t
+    {
+        uint8_t addr;
+        uint8_t pin;
+    };
+
+public:
+    ExternalIO(TwoWire &i2c, std::mutex &i2c_mutex, const uint8_t int_pin);
+    ~ExternalIO();
+
+    void extDigitalWrite(const uint32_t mappedPin, const bool val);
+    const bool extDigitalRead(const uint32_t mappedPin);
+    void extAttachInterrupt(ExtInterruptCb cb = nullptr);
+    void extDetachInterrupt();
+    void extReadInterrupt();
+
+private:
+    const io_t map2pin(const uint32_t mappedIO);
+    const uint32_t stat2map(const uint8_t addr, const uint16_t stat);
+
+private:
+    const uint8_t m_intPin;
+    IOmap m_inMap;
+    IOmap m_outMap;
+    uint8_t m_intPinChanged;
+    IOstate m_lastInputState;
+    ExtInterruptCb m_extInterruptCb = nullptr;
+    std::mutex &m_i2cMutex;
+    TwoWire &m_i2c;
+};

RotaxMonitor/src/main.cpp

@@ -17,12 +17,13 @@
 #include <led.h>
 
 // Defines to enable channel B
-#define CH_B_ENABLE
+// #define CH_B_ENABLE
-// #define TEST
 
 // Debug Defines
 #define WIFI_SSID "AstroRotaxMonitor"
 #define WIFI_PASSWORD "maledettirotax"
+#define PSRAM_MAX 4096
+#define QUEUE_MAX 256
 
 void setup()
 {
@@ -31,7 +32,7 @@ void setup()
 
     // Setup Logger
     LOG_ATTACH_SERIAL(Serial);
-    LOG_SET_LEVEL(DebugLogLevel::LVL_DEBUG);
+    LOG_SET_LEVEL(DebugLogLevel::LVL_INFO);
 
     // Print Processor Info
     LOG_DEBUG("ESP32 Chip:", ESP.getChipModel());
@@ -52,7 +53,7 @@ void setup()
     IPAddress gateway(10, 11, 12, 1);
     IPAddress subnet(255, 255, 255, 0);
     WiFi.softAPConfig(local_IP, gateway, subnet);
-    WiFi.setTxPower(WIFI_POWER_13dBm); // reduce wifi power
+    WiFi.setTxPower(WIFI_POWER_5dBm); // reduce wifi power
     if (WiFi.softAP(WIFI_SSID, WIFI_PASSWORD))
     {
         LOG_INFO("WiFi AP Mode Started");
@@ -79,23 +80,30 @@ void loop()
 {
     // global variables
     RGBled led;
+    led.setBrightness(0.025f);
     led.setStatus(RGBled::LedStatus::INIT);
+
+    std::shared_ptr<Devices> dev = std::make_shared<Devices>();
     bool running = true;
     std::mutex fs_mutex;
     LITTLEFSGuard fsGuard;
 
-    //////// INIT SPI PORTS ////////
+    //////// INIT SPI INTERFACES ////////
     bool spiA_ok = true;
     bool spiB_ok = true;
-    // Init 2 SPI interfaces
+    LOG_DEBUG("Init SPI Interfaces");
-//     SPIClass SPI_A(FSPI);
+    SPIClass SPI_A(FSPI);
-//     spiA_ok = SPI_A.begin(SPI_A_SCK, SPI_A_MISO, SPI_A_MOSI);
+    spiA_ok = SPI_A.begin(SPI_A_SCK, SPI_A_MISO, SPI_A_MOSI);
-//     SPI_A.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
+    SPI_A.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
-// #ifdef CH_B_ENABLE
+    LOG_DEBUG("Init SPI A ok");
-//     SPIClass SPI_B(HSPI);
+#ifdef CH_B_ENABLE
-//     spiB_ok = SPI_B.begin(SPI_B_SCK, SPI_B_MISO, SPI_B_MOSI);
+    delay(50);
-//     SPI_B.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
+    SPIClass SPI_B(HSPI);
-// #endif
+    spiB_ok = SPI_B.begin(SPI_B_SCK, SPI_B_MISO, SPI_B_MOSI);
+    SPI_B.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
+    LOG_DEBUG("Init SPI B ok");
+#endif
+
     if (!spiA_ok || !spiB_ok)
     {
         LOG_ERROR("Unable to Initialize SPI Busses");
@@ -103,25 +111,42 @@ void loop()
         vTaskDelay(pdMS_TO_TICKS(5000));
         esp_restart();
     }
+    dev->m_spi_a.reset(&SPI_A);
+#ifdef CH_B_ENABLE
+    dev->m_spi_b.reset(&SPI_B);
+#endif
+    // Init ADCs
+    dev->m_adc_a = std::make_unique<ADS1256>(ADC_A_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_A_CS, 2.5, &SPI_A);
+#ifdef CH_B_ENABLE
+    dev->m_adc_b = std::make_unique<ADS1256>(ADC_B_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_B_CS, 2.5, &SPI_B);
+#endif
+    // Configure ADCs
+    dev->m_adc_a->InitializeADC();
+    dev->m_adc_a->setPGA(PGA_1);
+    dev->m_adc_a->setDRATE(DRATE_7500SPS);
+#ifdef CH_B_ENABLE
+    dev->m_adc_b->InitializeADC();
+    dev->m_adc_b->setPGA(PGA_1);
+    dev->m_adc_b->setDRATE(DRATE_30000SPS);
+#endif
     LOG_DEBUG("Init SPI OK");
 
-    // Resources Initialization
+    //////// INIT I2C INTERFACES ////////
-    std::shared_ptr<Devices> dev = std::make_shared<Devices>();
+    LOG_DEBUG("Init I2C Interfaces");
-    // dev->m_spi_a = std::make_unique<SPIClass>(SPI_A);
+    bool i2c_ok = true;
-    // dev->m_spi_b = std::make_unique<SPIClass>(SPI_B);
+    i2c_ok = Wire.begin(SDA, SCL, 100000);
+    if (!i2c_ok)
+    {
+        LOG_ERROR("Unable to Initialize I2C Bus");
+        LOG_ERROR("5 seconds to restart...");
+        vTaskDelay(pdMS_TO_TICKS(5000));
+        esp_restart();
+    }
 
-    // // Init ADC_A
+    // Init IO Expanders
-    // dev->m_adc_a = std::make_unique<ADS1256>(ADC_A_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_A_CS, 2.5, &SPI_A);
+    // dev->m_ext_io = std::make_unique<ExternalIO>(Wire, dev->m_i2c_mutex, EXPANDER_ALL_INTERRUPT);
-    // dev->m_adc_b = std::make_unique<ADS1256>(ADC_B_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_B_CS, 2.5, &SPI_B);
-
-    // dev->m_adc_a->InitializeADC();
-    // dev->m_adc_a->setPGA(PGA_1);
-    // dev->m_adc_a->setDRATE(DRATE_7500SPS);
-
-    // dev->m_adc_b->InitializeADC();
-    // dev->m_adc_b->setPGA(PGA_1);
-    // dev->m_adc_b->setDRATE(DRATE_7500SPS);
 
+    //////// INIT REALTIME TASKS PARAMETERS ////////
     const rtIgnitionTask::rtTaskParams taskA_params{
         .rt_running = true,
         .name = "rtIgnTask_A",
@@ -184,9 +209,10 @@ void loop()
         .rt_queue = nullptr,
         .dev = dev};
 
-    auto task_A = rtIgnitionTask(taskA_params, 4096, 256, CORE_0, fs_mutex);
+    //////// SPAWN REALTIME TASKS ////////
+    auto task_A = rtIgnitionTask(taskA_params, PSRAM_MAX, QUEUE_MAX, CORE_0, fs_mutex);
     delay(50);
-    auto task_B = rtIgnitionTask(taskB_params, 4096, 256, CORE_1, fs_mutex);
+    auto task_B = rtIgnitionTask(taskB_params, PSRAM_MAX, QUEUE_MAX, CORE_1, fs_mutex);
 
     // Ignition A on Core 0
     auto ignA_task_success = task_A.getStatus() == rtIgnitionTask::OK ? pdPASS : pdFAIL;
@@ -206,22 +232,26 @@ void loop()
     {
         led.setStatus(RGBled::LedStatus::ERROR);
         LOG_ERROR("Unable to start realtime tasks");
-    } else 
+    }
-    LOG_DEBUG("Real Time Tasks A & B initialized");
+    else
-    led.setStatus(RGBled::LedStatus::OK);
+    {
+        LOG_DEBUG("Real Time Tasks A & B initialized");
+        led.setStatus(RGBled::LedStatus::OK);
+    }
 
-    AstroWebServer webPage(80, LittleFS); // Initialize webserver and Websocket
+    //////// SPAWN WEBSERVER and WEBSOCKET ////////
+    AstroWebServer webPage(80, LittleFS);
     ArduinoJson::JsonDocument json_data;
     bool data_a, data_b;
-    task_A.onMessage([&webPage, &json_data, &data_a](ignitionBoxStatusFiltered sts){
+    task_A.onMessage([&webPage, &json_data, &data_a](ignitionBoxStatusFiltered sts)
+                     {
         json_data["box_a"] = sts.toJson();
-        data_a = true;
+        data_a = true; });
-    });
 
-    task_B.onMessage([&webPage, &json_data, &data_b](ignitionBoxStatusFiltered sts){
+    task_B.onMessage([&webPage, &json_data, &data_b](ignitionBoxStatusFiltered sts)
+                     {
         json_data["box_b"] = sts.toJson();
-        data_b = true;
+        data_b = true; });
-    });
 
     // task_A.enableSave(true, "ignitionA_test.csv");
     // task_B.enableSave(true, "ignitionB_test.csv");
@@ -238,7 +268,8 @@ void loop()
             printRunningTasksMod(Serial);
             monitor_loop = millis();
         }
-        if ((data_a && data_b) || (this_loop - data_loop > 500)) {
+        if ((data_a && data_b) || (this_loop - data_loop > 500))
+        {
             webPage.sendWsData(json_data.as<String>());
             json_data.clear();
             data_a = data_b = false;

RotaxMonitor/src/pins.h

@@ -53,12 +53,6 @@
 #define ADC_B_CS 21
 #define ADC_B_DRDY 47
 
-// =====================
-// DIGITAL POT
-// =====================
-#define POT_A_CS 18
-#define POT_B_CS 35
-
 // =====================
 // TRIGGER INPUT INTERRUPTS
 // =====================
@@ -79,86 +73,87 @@
 #define SPARK_PIN_B12 1
 #define SPARK_PIN_B34 2
 
-// =====================
+// +++++++++++++++++++++
-// PCA9555 I/O EXPANDER BOX_A
+// MACRO TO COMBINE PIN NUMBER AND ADDRESS
-// =====================
+#define PIN2ADDR(p, a) ((1UL << p) | ((uint32_t)(a) << 16))
+// +++++++++++++++++++++
 
-#define EXPANDER_A_ADDR 0x010101
+// =====================
+// PCA9555 I/O EXPANDER INTERRUPT (Common)
+// =====================
+#define EXPANDER_ALL_INTERRUPT 17
+
+// =====================
+// PCA9555 I/O EXPANDER BOX_A (OUT)
+// =====================
+#define EXPANDER_A_OUT_ADDR 0xFF
 
 // --- DIGITAL POT CHIP SELECT LINES ---
-#define POT_CS_A12 0
+#define POT_CS_A12 PIN2ADDR(0, EXPANDER_A_OUT_ADDR)
-#define POT_CS_A34 1
+#define POT_CS_A34 PIN2ADDR(1, EXPANDER_A_OUT_ADDR)
 
 // --- SOFT START FORCE LINES ---
-#define SS_FORCE_A 2
+#define SS_FORCE_A PIN2ADDR(2, EXPANDER_A_OUT_ADDR)
-#define SS_INIBHIT_A12 3
+#define SS_INIBHIT_A12 PIN2ADDR(3, EXPANDER_A_OUT_ADDR)
-#define SS_INHIBIT_A34 4
+#define SS_INHIBIT_A34 PIN2ADDR(4, EXPANDER_A_OUT_ADDR)
 
 // --- SAMPLE AND HOLD ARM AND DISCHARGE ---
-#define SH_DISCH_A12 5
+#define SH_DISCH_A12 PIN2ADDR(5, EXPANDER_A_OUT_ADDR)
-#define SH_DISCH_A34 6
+#define SH_DISCH_A34 PIN2ADDR(6, EXPANDER_A_OUT_ADDR)
-#define SH_ARM_A12 7
+#define SH_ARM_A12 PIN2ADDR(7, EXPANDER_A_OUT_ADDR)
-#define SH_ARM_A34 8
+#define SH_ARM_A34 PIN2ADDR(8, EXPANDER_A_OUT_ADDR)
 
 // --- RELAY ---
-#define RELAY_IN_A12 9
+#define RELAY_IN_A12 PIN2ADDR(9, EXPANDER_A_OUT_ADDR)
-#define RELAY_OUT_A12 10
+#define RELAY_OUT_A12 PIN2ADDR(10, EXPANDER_A_OUT_ADDR)
-#define RELAY_IN_A34 11
+#define RELAY_IN_A34 PIN2ADDR(11, EXPANDER_A_OUT_ADDR)
-#define RELAY_OUT_A34 12
+#define RELAY_OUT_A34 PIN2ADDR(12, EXPANDER_A_OUT_ADDR)
-
-// --- STATUS / BUTTON ---
-#define STA_2 13
-#define STA_3 14
-#define STA_4 15
 
 // =====================
-// PCA9555 I/O EXPANDER BOX_B
+// PCA9555 I/O EXPANDER BOX_A (IN)
 // =====================
+#define EXPANDER_A_IN_ADDR 0xFF
 
-#define EXPANDER_B_ADDR 0x101010
+#define SS_A12_ON PIN2ADDR(0, EXPANDER_A_IN_ADDR)
+#define SS_A12_OFF PIN2ADDR(1, EXPANDER_A_IN_ADDR)
+#define SS_A34_ON PIN2ADDR(2, EXPANDER_A_IN_ADDR)
+#define SS_A34_OFF PIN2ADDR(3, EXPANDER_A_IN_ADDR)
+
+// =====================
+// PCA9555 I/O EXPANDER BOX_B (OUT)
+// =====================
+#define EXPANDER_B_OUT_ADDR 0xFF
 
 // --- DIGITAL POT CHIP SELECT LINES ---
-#define POT_CS_B12 0
+#define POT_CS_B12 PIN2ADDR(0, EXPANDER_B_OUT_ADDR)
-#define POT_CS_B34 1
+#define POT_CS_B34 PIN2ADDR(1, EXPANDER_B_OUT_ADDR)
 
 // --- SOFT START FORCE LINES ---
-#define SS_FORCE_B 2
+#define SS_FORCE_B PIN2ADDR(2, EXPANDER_B_OUT_ADDR)
-#define SS_INIBHIT_B12 3
+#define SS_INIBHIT_B12 PIN2ADDR(3, EXPANDER_B_OUT_ADDR)
-#define SS_INHIBIT_B34 4
+#define SS_INHIBIT_B34 PIN2ADDR(4, EXPANDER_B_OUT_ADDR)
 
 // --- SAMPLE AND HOLD ARM AND DISCHARGE ---
-#define SH_DISCH_B12 5
+#define SH_DISCH_B12 PIN2ADDR(5, EXPANDER_B_OUT_ADDR)
-#define SH_DISCH_B34 6
+#define SH_DISCH_B34 PIN2ADDR(6, EXPANDER_B_OUT_ADDR)
-#define SH_ARM_B12 7
+#define SH_ARM_B12 PIN2ADDR(7, EXPANDER_B_OUT_ADDR)
-#define SH_ARM_B34 8
+#define SH_ARM_B34 PIN2ADDR(8, EXPANDER_B_OUT_ADDR)
 
 // --- RELAY ---
-#define RELAY_IN_B12 9
+#define RELAY_IN_B12 PIN2ADDR(9, EXPANDER_B_OUT_ADDR)
-#define RELAY_OUT_B12 10
+#define RELAY_OUT_B12 PIN2ADDR(10, EXPANDER_B_OUT_ADDR)
-#define RELAY_IN_B34 11
+#define RELAY_IN_B34 PIN2ADDR(11, EXPANDER_B_OUT_ADDR)
-#define RELAY_OUT_B34 12
+#define RELAY_OUT_B34 PIN2ADDR(12, EXPANDER_B_OUT_ADDR)
-
-// --- STATUS / BUTTON ---
-#define STA_2 13
-#define STA_3 14
-#define STA_4 15
 
 // =====================
-// PCA9555 I/O EXPANDER INPUTS A+B
+// PCA9555 I/O EXPANDER BOX_B (IN)
 // =====================
+#define EXPANDER_B_IN_ADDR 0xFF
 
-#define EXPANDER_IN_ADDR 0x0a0a0a
+#define SS_B12_ON PIN2ADDR(0, EXPANDER_B_IN_ADDR)
-
+#define SS_B12_OFF PIN2ADDR(1, EXPANDER_B_IN_ADDR)
-#define SS_A12_ON
+#define SS_B34_ON PIN2ADDR(2, EXPANDER_B_IN_ADDR)
-#define SS_A12_OFF
+#define SS_B34_OFF PIN2ADDR(3, EXPANDER_B_IN_ADDR)
-#define SS_A34_ON
-#define SS_A34_OFF
-
-#define SS_B12_ON
-#define SS_B12_OFF
-#define SS_B34_ON
-#define SS_B34_OFF
-
 
 // Init Pin Functions
 inline void initTriggerPinsInputs()

RotaxMonitor/src/tasks.cpp

@@ -1,6 +1,7 @@
 #include "tasks.h"
 #include <esp_timer.h>
 #include <datasave.h>
+#include <mutex>
 
 //// GLOBAL STATIC FUNCTIONS
 
@@ -38,14 +39,14 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
     const rtTaskIOParams rt_rst = params->rt_io;         // copy to avoid external override
     QueueHandle_t rt_queue = params->rt_queue;
     Devices *dev = params->dev.get();
-    ADS1256 *adc = dev->m_adc_a.get();
+    ADS1256 *adc = params->name == "rtIgnTask_A" ? dev->m_adc_a.get() : dev->m_adc_b.get();
-    PCA9555 *io = dev->m_expander_a.get();
+    std::mutex &spi_mutex = params->name == "rtIgnTask_A" ? dev->m_spi_a_mutex : dev->m_spi_b_mutex;
+    ExternalIO *io = dev->m_ext_io.get();
 
     TaskStatus_t rt_task_info;
     vTaskGetInfo(NULL, &rt_task_info, pdFALSE, eInvalid);
 
-    const auto rt_task_name = pcTaskGetName(rt_task_info.xHandle);
+    LOG_INFO("rtTask Params OK [", params->name.c_str(), "]");
-    LOG_INFO("rtTask Params OK [", rt_task_name, "]");
 
     ignitionBoxStatus ign_box_sts;
 
@@ -96,7 +97,7 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
     attachInterruptArg(digitalPinToInterrupt(rt_int.spark_pin_12), rt_int.isr_ptr, (void *)&isr_params_sp12, RISING);
     attachInterruptArg(digitalPinToInterrupt(rt_int.spark_pin_34), rt_int.isr_ptr, (void *)&isr_params_sp34, RISING);
 
-    LOG_INFO("rtTask ISR Attach OK [", rt_task_name, "]");
+    LOG_INFO("rtTask ISR Attach OK [", params->name.c_str(), "]");
 
     // Global rt_task_ptr variables
     bool first_cycle = true;
@@ -234,17 +235,19 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
             //  read adc channels: pickup12, out12 [ pos + neg ]
             if (adc) // read only if adc initialized
             {
+                std::lock_guard<std::mutex> lock(spi_mutex);
                 uint32_t start_adc_read = esp_timer_get_time();
                 // from peak detector circuits
-                ign_box_sts.coils12.peak_p_in = adcReadChannel(adc, ADC_CH_PEAK_12P_IN);
+                ign_box_sts.coils12.peak_p_in = adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils12.peak_n_in = adcReadChannel(adc, ADC_CH_PEAK_12N_IN);
+                ign_box_sts.coils12.peak_n_in = adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils34.peak_p_in = adcReadChannel(adc, ADC_CH_PEAK_34P_IN);
+                ign_box_sts.coils34.peak_p_in = adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils34.peak_n_in = adcReadChannel(adc, ADC_CH_PEAK_34N_IN);
+                ign_box_sts.coils34.peak_n_in = adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils12.peak_p_out = adcReadChannel(adc, ADC_CH_PEAK_12P_OUT);
+                ign_box_sts.coils12.peak_p_out =adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils12.peak_n_out = adcReadChannel(adc, ADC_CH_PEAK_12N_OUT);
+                ign_box_sts.coils12.peak_n_out =adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils34.peak_p_out = adcReadChannel(adc, ADC_CH_PEAK_34P_OUT);
+                ign_box_sts.coils34.peak_p_out =adc->convertToVoltage(adc->cycleSingle());
-                ign_box_sts.coils34.peak_n_out = adcReadChannel(adc, ADC_CH_PEAK_34N_OUT);
+                ign_box_sts.coils34.peak_n_out =adc->convertToVoltage(adc->cycleSingle());
                 ign_box_sts.adc_read_time = (int32_t)(esp_timer_get_time() - start_adc_read);
+                adc->stopConversion();
             }
             else // simulate adc read timig
                 vTaskDelay(pdMS_TO_TICKS(c_adc_time));
@@ -253,10 +256,23 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
             // outputs on io expander
             if (io)
             {
-                // [TODO] code to reset sample and hold and arm trigger level detectors
+                // Discharge Pulse
+                io->extDigitalWrite(rt_rst.sh_disch_12, true);
+                io->extDigitalWrite(rt_rst.sh_disch_34, true);
+                delayMicroseconds(250);
+                io->extDigitalWrite(rt_rst.sh_disch_12, false);
+                io->extDigitalWrite(rt_rst.sh_disch_34, false);
+                // Safety delay
+                delayMicroseconds(500);
+                // Re-Arm Pulse
+                io->extDigitalWrite(rt_rst.sh_arm_12, true);
+                io->extDigitalWrite(rt_rst.sh_arm_34, true);
+                delayMicroseconds(250);
+                io->extDigitalWrite(rt_rst.sh_arm_12, false);
+                io->extDigitalWrite(rt_rst.sh_arm_34, false);
             }
             else
-                vTaskDelay(pdMS_TO_TICKS(1));
+                vTaskDelay(pdMS_TO_TICKS(c_io_time));
 
             // send essage to main loop with ignition info, by copy so local static variable is ok
             if (rt_queue)
@@ -269,7 +285,7 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
     }
     // Delete the timeout timer
     esp_timer_delete(timeout_timer);
-    LOG_WARN("rtTask Ending [", rt_task_name, "]");
+    LOG_WARN("rtTask Ending [", params->name.c_str(), "]");
     // Ignition A Interrupts DETACH
     detachInterrupt(rt_int.trig_pin_12p);
     detachInterrupt(rt_int.trig_pin_12n);

RotaxMonitor/src/tasks.h

@@ -59,19 +59,19 @@ public:
     struct rtTaskIOParams
     {
         const uint32_t expander_addr;
-        const uint8_t pot_cs_12;
+        const uint32_t pot_cs_12;
-        const uint8_t pot_cs_34;
+        const uint32_t pot_cs_34;
-        const uint8_t ss_force;
+        const uint32_t ss_force;
-        const uint8_t ss_inhibit_12;
+        const uint32_t ss_inhibit_12;
-        const uint8_t ss_inhibit_34;
+        const uint32_t ss_inhibit_34;
-        const uint8_t sh_disch_12;
+        const uint32_t sh_disch_12;
-        const uint8_t sh_disch_34;
+        const uint32_t sh_disch_34;
-        const uint8_t sh_arm_12;
+        const uint32_t sh_arm_12;
-        const uint8_t sh_arm_34;
+        const uint32_t sh_arm_34;
-        const uint8_t relay_in_12;
+        const uint32_t relay_in_12;
-        const uint8_t relay_in_34;
+        const uint32_t relay_in_34;
-        const uint8_t relay_out_12;
+        const uint32_t relay_out_12;
-        const uint8_t relay_out_34;
+        const uint32_t relay_out_34;
     };
 
     // RT task parameters

RotaxMonitorTester/platformio.ini

@@ -22,7 +22,7 @@ build_type = release
 [env:esp32-devtest-debug]
 board = esp32dev
 platform = https://github.com/pioarduino/platform-espressif32/releases/download/stable/platform-espressif32.zip
-
+framework = arduino
 lib_deps = 
 	hideakitai/DebugLog@^0.8.4
 board_build.flash_size = 4MB

RotaxMonitorTester/src/colors.h

@@ -0,0 +1,12 @@
+#pragma once
+
+// ANSI colors
+#define COLOR_RESET "\033[0m"
+#define COLOR_RED "\033[31m"
+#define COLOR_GREEN "\033[32m"
+#define COLOR_BLUE "\033[34m"
+#define COLOR_MAGENTA "\033[35m"
+#define COLOR_CYAN "\033[36m"
+#define COLOR_YELLOW "\033[33m"
+#define COLOR_WHITE "\033[37m"
+#define COLOR_LBLUE "\033[94m"

RotaxMonitorTester/src/main.cpp

@@ -4,6 +4,8 @@
 #include <DebugLog.h>
 
 #include "timer.h"
+#include "colors.h"
+
 #include <map>
 
 static hw_timer_t *timerA = NULL;
@@ -17,6 +19,12 @@ static uint32_t count = 0;
 #define SPARK_DLY_MIN 10
 #define SPARK_DLY_MAX 490
 
+#define COIL_PULSE_MIN 100
+#define COIL_PULSE_MAX 1000
+
+#define SPARK_PULSE_MIN 10
+#define SPARK_PULSE_MAX 500
+
 #define PAUSE_LONG_MIN 5000
 #define PAUSE_LONG_MAX PAUSE_LONG_MIN * 100
 
@@ -30,7 +38,8 @@ void clearScreen()
   Serial.flush();
 }
 
-static double filtered_rpm = 0;
+static uint32_t set_rpm = 500;
+static uint32_t set_delay = 100;
 
 static const std::map<const uint32_t, const char *> pin2Name = {
     {PIN_TRIG_A12P, "HIGH_PIN_TRIG_A12P"},
@@ -68,7 +77,7 @@ static timerStatus stsB = {
     .clock_period_us = (uint32_t)PERIOD_US,
     .pause_long_us = 10000,
     .pause_short_us = 1000,
-    .coil_pulse_us = 1000,
+    .coil_pulse_us = 500,
     .spark_pulse_us = 100,
     .spark_delay_us = 50,
     .pins = {
@@ -83,11 +92,14 @@ static timerStatus stsB = {
 static bool isEnabled_A = false;
 static bool isEnabled_B = false;
 
+static String last_command;
+
 void setup()
 {
 
   Serial.begin(115200);
   delay(1000);
+  Serial.setTimeout(100);
   LOG_ATTACH_SERIAL(Serial);
 
   pinMode(PIN_TRIG_A12P, OUTPUT);
@@ -133,63 +145,124 @@ void setup()
 
 void loop()
 {
-  LOG_INFO("Loop: ", count++);
+  clearScreen();
-  uint32_t spark_delay = (uint32_t)(map(analogRead(SPARK_DELAY_POT), 0, 4096, SPARK_DLY_MIN, SPARK_DLY_MAX) / PERIOD_US);
-  stsA.spark_delay_us = spark_delay * PERIOD_US;
-  if (stsA.spark_delay_us > (SPARK_DLY_MIN + SPARK_DLY_MAX) / 2)
-  {
-    stsA.soft_start = true;
-    stsA.spark_delay_us -= (SPARK_DLY_MIN + SPARK_DLY_MAX) / 2;
-  }
-  else
-  {
-    stsA.soft_start = false;
-  }
-  stsB.soft_start = stsA.soft_start;
-  stsB.spark_delay_us = stsA.spark_delay_us;
 
-  double new_rpm = (double)(map(analogRead(FREQ_POT), 0, 4096, RPM_MIN, RPM_MAX));
+  Serial.printf("\t++++ Loop: %u ++++\n", count++);
-  filtered_rpm = filtered_rpm + 0.1 * (new_rpm - filtered_rpm);
-  stsA.pause_long_us = (uint32_t)(60000000.0f / filtered_rpm / 2.0f);
-  stsB.pause_long_us = stsA.pause_long_us;
 
   if (isEnabled_A)
-    LOG_INFO("==== System A is ENABLED ====");
+    Serial.println("==== System A is" COLOR_GREEN " ENABLED" COLOR_RESET " ====");
   else
-    LOG_INFO("==== System A is DISABLED ====");
+    Serial.println("==== System A is" COLOR_RED " DISABLED" COLOR_RESET " ====");
 
   if (isEnabled_B)
-    LOG_INFO("==== System B is ENABLED ====");
+    Serial.println("==== System B is" COLOR_GREEN " ENABLED" COLOR_RESET " ====");
   else
-    LOG_INFO("==== System B is DISABLED ====");
+    Serial.println("==== System B is" COLOR_RED " DISABLED" COLOR_RESET " ====");
 
-  LOG_INFO("Spark Delay uS: ", stsA.spark_delay_us, "\tSoft Start: ", stsA.soft_start ? "TRUE" : "FALSE");
+  Serial.printf("Spark Delay uS: %u\n", stsA.spark_delay_us);
-  LOG_INFO("Engine Rpm: ", (uint32_t)(filtered_rpm));
+  Serial.printf("Soft Start: %s\n", stsA.soft_start ? "ENABLED" : "DISABLED");
-  LOG_INFO("Coil Pulse: ", stsA.coil_pulse_us, "us");
+  Serial.printf("Engine Rpm: %u\n", (uint32_t)(set_rpm));
-  LOG_INFO("Spark Pulse: ", stsA.spark_pulse_us, "us");
+  Serial.printf("Coil Pulse: %u uS\n", stsA.coil_pulse_us);
+  Serial.printf("Spark Pulse: %u uS\n", stsA.spark_pulse_us);
+  Serial.println(COLOR_CYAN "-------------------------------------");
+  Serial.println("E[a/b] > Enable Box a/b | D[a/b]  > Disable a/b");
+  Serial.println("S[ddd] > Spark Delay    | R[dddd] > Engine RPM");
+  Serial.println("C[ddd] > Spark Pulse    | P[ddd]  > Coil Pulse");
+  Serial.println("-------------------------------------" COLOR_RESET);
+  Serial.printf("Last Command: %s\n", last_command.c_str());
 
-  if (digitalRead(ENABLE_PIN_A) == LOW && !isEnabled_A)
+  auto str = Serial.readStringUntil('\n');
+  if (!str.isEmpty())
   {
-    timerStart(timerA);
+    last_command = str;
-    isEnabled_A = true;
+    const auto cmd = str.charAt(0);
-  }
+    char c;
-  else if (digitalRead(ENABLE_PIN_A) == HIGH && isEnabled_A)
+    switch (cmd)
-  {
+    {
-    timerStop(timerA);
+    case 'E':
-    isEnabled_A = false;
+    {
+      char box;
+      sscanf(str.c_str(), "%c%c\n", &c, &box);
+      if (box == 'a' && !isEnabled_A)
+      {
+        timerStart(timerA);
+        isEnabled_A = true;
+      }
+      else if (box == 'b' && !isEnabled_B)
+      {
+        timerStart(timerB);
+        isEnabled_B = true;
+      }
+      break;
+    }
+    case 'D':
+    {
+      char c;
+      char box;
+      sscanf(str.c_str(), "%c%c\n", &c, &box);
+      if (box == 'a' && isEnabled_A)
+      {
+        timerStop(timerA);
+        isEnabled_A = false;
+      }
+      else if (box == 'b' && isEnabled_B)
+      {
+        timerStop(timerB);
+        isEnabled_B = false;
+      }
+      break;
+    }
+    case 'R':
+    {
+      int new_rpm;
+      sscanf(str.c_str(), "%c%d\n", &c, &new_rpm);
+      new_rpm = min(RPM_MAX, max(RPM_MIN, new_rpm));
+      stsA.pause_long_us = (uint32_t)(60000000.0f / (float)new_rpm / 2.0f);
+      stsB.pause_long_us = stsA.pause_long_us;
+      set_rpm = (uint32_t)new_rpm;
+      break;
+    }
+    case 'S':
+    {
+      int new_delay;
+      sscanf(str.c_str(), "%c%d\n", &c, &new_delay);
+      new_delay = min(SPARK_DLY_MAX, max(SPARK_DLY_MIN, new_delay));
+      stsA.spark_delay_us = (uint32_t)(new_delay);
+      if (stsA.spark_delay_us > (SPARK_DLY_MIN + SPARK_DLY_MAX) / 2)
+      {
+        stsA.soft_start = true;
+        stsA.spark_delay_us -= (SPARK_DLY_MIN + SPARK_DLY_MAX) / 2;
+      }
+      else
+      {
+        stsA.soft_start = false;
+      }
+      stsB.soft_start = stsA.soft_start;
+      stsB.spark_delay_us = stsA.spark_delay_us;
+      break;
+    }
+    case 'P':
+    {
+      int new_pulse;
+      sscanf(str.c_str(), "%c%d\n", &c, &new_pulse);
+      new_pulse = min(COIL_PULSE_MAX, max(COIL_PULSE_MIN, new_pulse));
+      stsA.coil_pulse_us = stsB.coil_pulse_us = (uint32_t)new_pulse;
+      break;
+    }
+    case 'C':
+    {
+      int new_pulse;
+      sscanf(str.c_str(), "%c%d\n", &c, &new_pulse);
+      new_pulse = min(SPARK_PULSE_MAX, max(SPARK_PULSE_MIN, new_pulse));
+      stsA.spark_pulse_us = stsB.spark_pulse_us = (uint32_t)new_pulse;
+      break;
+    }
+    default:
+      break;
+    }
+    Serial.read();
   }
 
-  if (digitalRead(ENABLE_PIN_B) == LOW && !isEnabled_B)
+  str.clear();
-  {
+  delay(1000);
-    timerStart(timerB);
-    isEnabled_B = true;
-  }
-  else if (digitalRead(ENABLE_PIN_B) == HIGH && isEnabled_B)
-  {
-    timerStop(timerB);
-    isEnabled_B = false;
-  }
-
-  delay(100);
-  clearScreen();
 }