refactor continued, at least it compiles

2026-04-11 16:39:59 +02:00
parent d1b96e932c
commit fdba6d5ad5
7 changed files with 162 additions and 259 deletions
--- a/RotaxMonitor/lib/led/led.h
+++ b/RotaxMonitor/lib/led/led.h
@@ -47,7 +47,7 @@ public:
    };
 public:
-    RGBled(const uint8_t pin = LED);
+    RGBled(const uint8_t pin = 48);
    ~RGBled();
    void setStatus(const LedStatus s);
--- a/RotaxMonitor/src/datasave.h
+++ b/RotaxMonitor/src/datasave.h
@@ -48,7 +48,3 @@ private:
    void filter(int32_t &old, const int32_t value, const uint32_t k);
    void filter(float &old, const float value, const uint32_t k);
 };
 // Task and function declarations
 void saveHistoryTask(void *pvParameters);
 void save_history(const PSRAMVector<ignitionBoxStatus> &history, const std::filesystem::path &file_path);
--- a/RotaxMonitor/src/devices.h
+++ b/RotaxMonitor/src/devices.h
@@ -3,33 +3,53 @@
 // Library defines
 #define ADS1256_SPI_ALREADY_STARTED
 // System Includes
 #include <memory>
 // Device Libraries
 #include <ADS1256.h>
 #include <AD5292.h>
 #include <PCA95x5.h>
 // ADC Channel mapping
-#define ADC_CH_PEAK_12P_IN      SING_0
+#define ADC_CH_PEAK_12P_IN SING_0
-#define ADC_CH_PEAK_12N_IN      SING_1
+#define ADC_CH_PEAK_12N_IN SING_1
-#define ADC_CH_PEAK_34P_IN      SING_2
+#define ADC_CH_PEAK_34P_IN SING_2
-#define ADC_CH_PEAK_34N_IN      SING_3
+#define ADC_CH_PEAK_34N_IN SING_3
-#define ADC_CH_PEAK_12P_OUT     SING_4
+#define ADC_CH_PEAK_12P_OUT SING_4
-#define ADC_CH_PEAK_12N_OUT     SING_5
+#define ADC_CH_PEAK_12N_OUT SING_5
-#define ADC_CH_PEAK_34P_OUT     SING_6
+#define ADC_CH_PEAK_34P_OUT SING_6
-#define ADC_CH_PEAK_34N_OUT     SING_7
+#define ADC_CH_PEAK_34N_OUT SING_7
 // Device Pointer structs for tasks
-struct Devices {
+struct Devices
-  AD5292 *pot_a = NULL, *pot_b = NULL;
+{
-  ADS1256 *adc_a = NULL, *adc_b = NULL; 
+    std::unique_ptr<SPIClass> m_spi_a = nullptr;
-  PCA9555* io = NULL;
+    std::unique_ptr<SPIClass> m_spi_b = nullptr;
    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<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){
+inline float adcReadChannel(ADS1256 *adc, const uint8_t ch)
 {
    adc->setMUX(ch);
    // scarta 3 conversioni
-    for (int i = 0; i < 3; i++) {
+    for (int i = 0; i < 3; i++)
    {
        adc->readSingle();
    }
    // ora lettura valida a 30kSPS → ~100 µs di settling
--- a/RotaxMonitor/src/main.cpp
+++ b/RotaxMonitor/src/main.cpp
@@ -18,7 +18,7 @@
 // Defines to enable channel B
 #define CH_B_ENABLE
-//#define TEST
+// #define TEST
 // Debug Defines
 #define WIFI_SSID "AstroRotaxMonitor"
@@ -81,71 +81,9 @@ void loop()
    RGBled led;
    led.setStatus(RGBled::LedStatus::INIT);
    bool running = true;
-    const uint32_t max_queue = 128;
+    std::mutex fs_mutex;
    const uint32_t filter_k = 10;
-    PSRAMVector<ignitionBoxStatus> ignA_history_0(max_history);
+    //////// INIT SPI PORTS ////////
    PSRAMVector<ignitionBoxStatus> ignA_history_1(max_history);
    auto *active_history_A = &ignA_history_0;
    auto *writable_history_A = &ignA_history_1;
 #ifdef CH_B_ENABLE
    PSRAMVector<ignitionBoxStatus> ignB_history_0(max_history);
    PSRAMVector<ignitionBoxStatus> ignB_history_1(max_history);
    auto *active_history_B = &ignB_history_0;
    auto *writable_history_B = &ignB_history_1;
 #endif
    // Resources Initialization
    Devices dev;
    // Task handle
    TaskHandle_t trigA_TaskHandle = NULL;
    TaskHandle_t trigB_TaskHandle = NULL;
    // Data Queue for real time task to main loop communication
    QueueHandle_t rt_taskA_queue = xQueueCreate(max_queue, sizeof(ignitionBoxStatus));
    QueueHandle_t rt_taskB_queue = xQueueCreate(max_queue, sizeof(ignitionBoxStatus));
    rtTaskParams taskA_params{
        .rt_running = true,
        .dev = std::make_shared<Devices>(dev),
        .rt_queue = rt_taskA_queue,
        .rt_int = rtTaskInterruptParams{
            .isr_ptr = &trig_isr_A,
            .trig_pin_12p = TRIG_PIN_A12P,
            .trig_pin_12n = TRIG_PIN_A12N,
            .trig_pin_34p = TRIG_PIN_A34P,
            .trig_pin_34n = TRIG_PIN_A34N,
            .spark_pin_12 = SPARK_PIN_A12,
            .spark_pin_34 = SPARK_PIN_A34},
        .rt_io = rtTaskIOParams{.rst_io_peak = 0, .rst_io_sh = 0}};
 #ifdef CH_B_ENABLE
    rtTaskParams taskB_params{
        .rt_running = true,
        .dev = &dev,
        .rt_queue = rt_taskB_queue,
        .rt_int = rtTaskInterruptParams{
            .isr_ptr = &trig_isr_B,
            .trig_pin_12p = TRIG_PIN_B12P,
            .trig_pin_12n = TRIG_PIN_B12N,
            .trig_pin_34p = TRIG_PIN_B34P,
            .trig_pin_34n = TRIG_PIN_B34N,
            .spark_pin_12 = SPARK_PIN_B12,
            .spark_pin_34 = SPARK_PIN_B34},
        .rt_io = rtTaskIOParams{.rst_io_peak = SS_FORCE_A, .rst_io_sh = SS_INIBHIT_A12}};
 #endif
    if (!rt_taskA_queue || !rt_taskB_queue)
    {
        LOG_ERROR("Unable To Create task queues");
        LOG_ERROR("5 seconds to restart...");
        vTaskDelay(pdMS_TO_TICKS(5000));
        esp_restart();
    }
    else
        LOG_DEBUG("Task Variables OK");
    // Spi ok flags
    bool spiA_ok = true;
    bool spiB_ok = true;
    // Init 2 SPI interfaces
@@ -153,11 +91,9 @@ void loop()
    spiA_ok = SPI_A.begin(SPI_A_SCK, SPI_A_MISO, SPI_A_MOSI);
    SPI_A.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
 #ifdef CH_B_ENABLE
 #ifndef TEST
    SPIClass SPI_B(HSPI);
    spiB_ok = SPI_B.begin(SPI_B_SCK, SPI_B_MISO, SPI_B_MOSI);
    SPI_B.setDataMode(SPI_MODE1); // ADS1256 requires SPI mode 1
 #endif
 #endif
    if (!spiA_ok || !spiB_ok)
    {
@@ -168,52 +104,91 @@ void loop()
    }
    LOG_DEBUG("Init SPI OK");
-#ifndef TEST
+    // Resources Initialization
-    // Init ADC_A
+    std::shared_ptr<Devices> dev = std::make_shared<Devices>();
-    dev.adc_a = new ADS1256(ADC_A_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_A_CS, 2.5, &SPI_A);
+    dev->m_spi_a = std::make_unique<SPIClass>(SPI_A);
-    dev.adc_a->InitializeADC();
+    dev->m_spi_b = std::make_unique<SPIClass>(SPI_B);
    dev.adc_a->setPGA(PGA_1);
    dev.adc_a->setDRATE(DRATE_7500SPS);
 #endif
 #ifdef CH_B_ENABLE
 #ifndef TEST
    // Init ADC_B
    dev.adc_a = new ADS1256(ADC_B_DRDY, ADS1256::PIN_UNUSED, ADS1256::PIN_UNUSED, ADC_B_CS, 2.5, &SPI_B);
    dev.adc_a->InitializeADC();
    dev.adc_a->setPGA(PGA_1);
    dev.adc_a->setDRATE(DRATE_1000SPS);
 #endif
 #endif
-    LOG_DEBUG("Init ADC OK");
+    // Init ADC_A
    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_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);
    const rtIgnitionTask::rtTaskParams taskA_params{
        .rt_running = true,
        .name = "rtIgnTask_A",
        .rt_stack_size = RT_TASK_STACK,
        .rt_priority = RT_TASK_PRIORITY,
        .rt_int = rtIgnitionTask::rtTaskInterruptParams{
            .isr_ptr = &trig_isr_A,
            .trig_pin_12p = TRIG_PIN_A12P,
            .trig_pin_12n = TRIG_PIN_A12N,
            .trig_pin_34p = TRIG_PIN_A34P,
            .trig_pin_34n = TRIG_PIN_A34N,
            .spark_pin_12 = SPARK_PIN_A12,
            .spark_pin_34 = SPARK_PIN_A34},
        .rt_io = rtIgnitionTask::rtTaskIOParams{
            .pot_cs_12 = POT_CS_A12,
            .pot_cs_34 = POT_CS_A34,
            .ss_force = SS_FORCE_A,
            .ss_inhibit_12 = SS_INIBHIT_A12,
            .ss_inhibit_34 = SS_INHIBIT_A34,
            .sh_disch_12 = SH_DISCH_A12,
            .sh_disch_34 = SH_DISCH_A34,
            .sh_arm_12 = SH_ARM_A12,
            .sh_arm_34 = SH_ARM_A34,
            .relay_in_12 = RELAY_IN_A12,
            .relay_in_34 = RELAY_OUT_A12,
            .relay_out_12 = RELAY_IN_A34,
            .relay_out_34 = RELAY_OUT_A34,
        },
        .rt_queue = nullptr,
        .dev = dev};
    const rtIgnitionTask::rtTaskParams taskB_params{
        .rt_running = true,
        .name = "rtIgnTask_B",
        .rt_stack_size = RT_TASK_STACK,
        .rt_priority = RT_TASK_PRIORITY,
        .rt_int = rtIgnitionTask::rtTaskInterruptParams{
            .isr_ptr = &trig_isr_B,
            .trig_pin_12p = TRIG_PIN_B12P,
            .trig_pin_12n = TRIG_PIN_B12N,
            .trig_pin_34p = TRIG_PIN_B34P,
            .trig_pin_34n = TRIG_PIN_B34N,
            .spark_pin_12 = SPARK_PIN_B12,
            .spark_pin_34 = SPARK_PIN_B34},
        .rt_io = rtIgnitionTask::rtTaskIOParams{
            .pot_cs_12 = POT_CS_B12,
            .pot_cs_34 = POT_CS_B34,
            .ss_force = SS_FORCE_B,
            .ss_inhibit_12 = SS_INIBHIT_B12,
            .ss_inhibit_34 = SS_INHIBIT_B34,
            .sh_disch_12 = SH_DISCH_B12,
            .sh_disch_34 = SH_DISCH_B34,
            .sh_arm_12 = SH_ARM_B12,
            .sh_arm_34 = SH_ARM_B34,
            .relay_in_12 = RELAY_IN_B12,
            .relay_in_34 = RELAY_OUT_B12,
            .relay_out_12 = RELAY_IN_B34,
            .relay_out_34 = RELAY_OUT_B34,
        },
        .rt_queue = nullptr,
        .dev = dev};
    auto task_A = rtIgnitionTask(taskA_params, 1024, 128, CORE_0, fs_mutex);
    auto task_B = rtIgnitionTask(taskA_params, 1024, 128, CORE_1, fs_mutex);
    // Ignition A on Core 0
-    auto ignA_task_success = pdPASS;
+    auto ignA_task_success = task_A.getStatus() == rtIgnitionTask::OK ? pdPASS : pdFAIL;
-    ignA_task_success = xTaskCreatePinnedToCore(
+    auto ignB_task_success = task_B.getStatus() == rtIgnitionTask::OK ? pdPASS : pdFAIL;
        rtIgnitionTask_realtime,
        "rtTask_A",
        RT_TASK_STACK,
        (void *)&taskA_params,
        RT_TASK_PRIORITY,
        &trigA_TaskHandle,
        CORE_0);
    delay(100); // give some time to the thread to start
    // Ignition B on Core 1
    auto ignB_task_success = pdPASS;
 #ifdef CH_B_ENABLE
    ignB_task_success = xTaskCreatePinnedToCore(
        rtIgnitionTask_realtime,
        "rtTask_B",
        RT_TASK_STACK,
        (void *)&taskB_params,
        RT_TASK_PRIORITY, // priorità leggermente più alta
        &trigB_TaskHandle,
        CORE_1);
    delay(100); // give some time to the thread to start
 #endif
    if (ignA_task_success != pdPASS || ignB_task_success != pdPASS)
    {
        LOG_ERROR("Unable to initialize ISR task");
@@ -225,123 +200,23 @@ void loop()
    LOG_DEBUG("Real Time Tasks A & B initialized");
    led.setStatus(RGBled::LedStatus::OK);
    bool partial_save = false; // flag to indicate if a partial save has been done after a timeout
    auto last_data = millis();
    auto last_info = millis();
    uint32_t counter_a = 0;
    uint32_t counter_b = 0;
    uint32_t wait_count = 0;
    ignitionBoxStatus ign_info_A;
    ignitionBoxStatus ign_info_B;
    ignitionBoxStatusFiltered ign_info_avg_A(filter_k);
    ignitionBoxStatusFiltered ign_info_avg_B(filter_k);
    LITTLEFSGuard fsGuard;
    WebPage webPage(80, LittleFS); // Initialize webserver and Websocket
    uint32_t last_loop = millis();
    //////////////// INNER LOOP /////////////////////
    while (running)
    {
-        auto dataA = pdFALSE;
+        led.setStatus(RGBled::LedStatus::IDLE);
-        auto dataB = pdFALSE;
+        delay(100);
-        dataA = xQueueReceive(rt_taskA_queue, &ign_info_A, 0);
+        if ((millis() - last_loop) > 1000)
        if (counter_a >= active_history_A->size()) // not concurrent with write task
        {
            counter_a = 0;
            partial_save = false; // reset partial save flag on new data cycle
            swapHistory(active_history_A, writable_history_A);
            save_history(*writable_history_A, "ignition_historyA.csv"); // directly call the save task function to save without delay
        }
 #ifdef CH_B_ENABLE
        dataB = xQueueReceive(rt_taskB_queue, &ign_info_B, 0);
        if (counter_b >= active_history_B->size()) // not concurrent with write task
        {
            counter_b = 0;
            partial_save = false; // reset partial save flag on new data cycle
            swapHistory(active_history_B, writable_history_B);
            save_history(*writable_history_B, "ignition_historyB.csv"); // directly call the save task function to save without delay
        }
 #endif
        // Update last data
        if (dataA == pdTRUE || dataB == pdTRUE)
            last_data = millis();
        // Update Led color
        if (dataA == pdTRUE && dataB == pdFALSE)
            led.setStatus(RGBled::DATA_A);
        else if (dataB == pdTRUE && dataA == pdFALSE)
            led.setStatus(RGBled::DATA_B);
        else
            led.setStatus(RGBled::DATA_ALL);
        if (dataA == pdTRUE)
        {
            (*active_history_A)[counter_a++ % active_history_A->size()] = ign_info_A;
            ign_info_avg_A.update(ign_info_A); // update moving average with latest ignition status
            // Serial.printf("Data Received A: %d/%d\n\r", counter_a, (*active_history_A).size());
            if (counter_a % filter_k == 0) // send data every 10 samples
            {
                ArduinoJson::JsonDocument wsData;
                wsData["box_a"] = ign_info_avg_A.toJson();
                wsData["box_b"] = JsonObject();
                webPage.sendWsData(wsData.as<String>());
            }
        }
 #ifdef CH_B_ENABLE
        if (dataB == pdTRUE)
        {
            (*active_history_B)[counter_b++ % active_history_B->size()] = ign_info_B;
            ign_info_avg_B.update(ign_info_B); // update moving average with latest ignition status
            // Serial.printf("Data Received B: %d/%d\n\r", counter_b, (*active_history_B).size());
            if (counter_b % filter_k == 0) // send data every 10 samples
            {
                ArduinoJson::JsonDocument wsData;
                wsData["box_a"] = JsonObject();
                wsData["box_b"] = ign_info_avg_B.toJson();
                webPage.sendWsData(wsData.as<String>());
            }
        }
 #endif
        if (dataA == pdFALSE && dataB == pdFALSE && (millis() - last_data) > 2000)
        {
            if (!partial_save && counter_a > 0) // if timeout occurs but we have unsaved data, save it before next timeout
            {
                active_history_A->resize(counter_a); // resize active history to actual number of records received to avoid saving empty records
                save_history(*active_history_A, "ignition_history_A.csv");
                active_history_A->resize(max_history); // resize back to max history size for next data cycle
 #ifdef CH_B_ENABLE
                active_history_B->resize(counter_a); // resize active history to actual number of records received to avoid saving empty records
                save_history(*active_history_B, "ignition_history_B.csv");
                active_history_B->resize(max_history); // resize back to max history size for next data cycle
 #endif
                counter_a = 0; // reset counter after saving
                counter_b = 0; // reset counter after saving
                partial_save = true;
                first_save = true;
            }
            // Serial.printf("[%d] Waiting for data...\r", wait_count++);
            led.setStatus(RGBled::LedStatus::IDLE);
            delay(100);
        }
        if ((millis() - last_info) > 1000)
        {
            clearScreen();
            Serial.println();
            printRunningTasksMod(Serial);
-            last_info = millis();
+            last_loop = millis();
        }
    } //////////////// INNER LOOP /////////////////////
    if (trigA_TaskHandle)
        vTaskDelete(trigA_TaskHandle);
    if (trigB_TaskHandle)
        vTaskDelete(trigB_TaskHandle);
 } ////////////////////// MAIN LOOP //////////////////////
--- a/RotaxMonitor/src/pins.h
+++ b/RotaxMonitor/src/pins.h
@@ -122,7 +122,7 @@
 #define POT_CS_B34 1
 // --- SOFT START FORCE LINES ---
-#define SS_FORCE_A 2
+#define SS_FORCE_B 2
 #define SS_INIBHIT_B12 3
 #define SS_INHIBIT_B34 4
--- a/RotaxMonitor/src/tasks.cpp
+++ b/RotaxMonitor/src/tasks.cpp
@@ -38,8 +38,8 @@ 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->adc_a;
+    ADS1256 *adc = dev->m_adc_a.get();
-    PCA9555 *io = dev->io;
+    PCA9555 *io = dev->m_expander_a.get();
    TaskStatus_t rt_task_info;
    vTaskGetInfo(NULL, &rt_task_info, pdFALSE, eInvalid);
@@ -282,7 +282,7 @@ void rtIgnitionTask::rtIgnitionTask_realtime(void *pvParameters)
 }
 ///////////// CLASS MEMBER DEFINITIONS /////////////
-rtIgnitionTask::rtIgnitionTask(const rtTaskParams params, const uint32_t history_size, const uint32_t queue_size, const uint8_t core, std::mutex &fs_mutex, fs::FS &filesystem = LittleFS) : m_params(params), m_filesystem(filesystem), m_fs_mutex(fs_mutex), m_core(core)
+rtIgnitionTask::rtIgnitionTask(const rtTaskParams params, const uint32_t history_size, const uint32_t queue_size, const uint8_t core, std::mutex &fs_mutex, fs::FS &filesystem) : m_params(params), m_filesystem(filesystem), m_fs_mutex(fs_mutex), m_core(core), m_max_history(history_size)
 {
    // create queue buffers
    m_queue = xQueueCreate(queue_size, sizeof(ignitionBoxStatus));
@@ -299,8 +299,8 @@ rtIgnitionTask::rtIgnitionTask(const rtTaskParams params, const uint32_t history
    m_history_0.resize(history_size);
    m_history_1.resize(history_size);
    // assing active and writable history
-    m_active_history = std::make_unique<PSHistory>(m_history_0.data());
+    m_active_history = std::unique_ptr<PSHistory>(&m_history_0);
-    m_save_history = std::make_unique<PSHistory>(m_history_1.data());
+    m_save_history = std::unique_ptr<PSHistory>(&m_history_1);
    LOG_WARN("Starting Manager for [", m_params.name.c_str(), "]");
    auto task_success = xTaskCreate(
@@ -349,7 +349,7 @@ void rtIgnitionTask::run()
            m_partial_save = false; // reset partial save flag on new data cycle
            std::swap(m_active_history, m_save_history);
            if (m_enable_save)
-                save_history(*m_save_history, m_history_path); // directly call the save task function to save without delay
+                saveHistory(*m_save_history, m_history_path); // directly call the save task function to save without delay
        }
        // update filtered data
@@ -361,8 +361,16 @@ void rtIgnitionTask::run()
    }
    else
    {
-        if (millis() - m_last_data > c_idle_time)
+        if (millis() - m_last_data > c_idle_time){
            if (m_counter_status > 0 && !m_partial_save){
                m_active_history->resize(m_counter_status);
                saveHistory(*m_active_history, m_history_path);
                m_active_history->resize(m_max_history);
                m_counter_status = 0;
                m_partial_save = true;
            }
            m_manager_status = rtTaskStatus::IDLE;
        }
        delay(5); // yeld to another task
    }
 }
--- a/RotaxMonitor/src/tasks.h
+++ b/RotaxMonitor/src/tasks.h
@@ -13,6 +13,7 @@
 #include <filesystem>
 #include <FS.h>
 #include <LittleFS.h>
 #include <datasave.h>
 // ISR
 #include "isr.h"
@@ -39,6 +40,8 @@ static const std::map<const uint32_t, const char *> names = {
 class rtIgnitionTask
 {
    using PSHistory = PSRAMVector<ignitionBoxStatus>;
 public:
    // RT task Interrupt parameters
    struct rtTaskInterruptParams
    {
@@ -55,19 +58,19 @@ class rtIgnitionTask
    struct rtTaskIOParams
    {
        const uint32_t expander_addr;
-        const uint8_t pot_cs_a12;
+        const uint8_t pot_cs_12;
-        const uint8_t pot_cs_a34;
+        const uint8_t pot_cs_34;
-        const uint8_t ss_force_a;
+        const uint8_t ss_force;
-        const uint8_t ss_inhibit_a12;
+        const uint8_t ss_inhibit_12;
-        const uint8_t ss_inhibit_a34;
+        const uint8_t ss_inhibit_34;
-        const uint8_t sh_disch_a12;
+        const uint8_t sh_disch_12;
-        const uint8_t sh_disch_a34;
+        const uint8_t sh_disch_34;
-        const uint8_t sh_arm_a12;
+        const uint8_t sh_arm_12;
-        const uint8_t sh_arm_a34;
+        const uint8_t sh_arm_34;
-        const uint8_t relay_in_a12;
+        const uint8_t relay_in_12;
-        const uint8_t relay_in_a34;
+        const uint8_t relay_in_34;
-        const uint8_t relay_out_a12;
+        const uint8_t relay_out_12;
-        const uint8_t relay_out_a34;
+        const uint8_t relay_out_34;
    };
    // RT task parameters
@@ -75,12 +78,12 @@ class rtIgnitionTask
    {
        bool rt_running; // run flag, false to terminate
        const std::string name;
        const std::shared_ptr<Devices> dev;
        const uint32_t rt_stack_size;
        const uint32_t rt_priority;
        const rtTaskInterruptParams rt_int; // interrupt pins to attach
        const rtTaskIOParams rt_io;         // reset ping for peak detectors
        QueueHandle_t rt_queue;             // queue for task io
        const std::shared_ptr<Devices> dev;
    };
    enum rtTaskStatus
@@ -109,7 +112,7 @@ public:
    void enableSave(const bool enable, const std::filesystem::path filename);
 private:
-    void rtIgnitionTask::saveHistory(const rtIgnitionTask::PSHistory &history, const std::filesystem::path &file_name);
+    void saveHistory(const rtIgnitionTask::PSHistory &history, const std::filesystem::path &file_name);
 private: // static functions for FreeRTOS
    static void rtIgnitionTask_manager(void *pvParameters);
@@ -128,6 +131,7 @@ private:
    bool m_enable_save = false;
    std::filesystem::path m_history_path;
    const uint32_t m_max_history;
    PSHistory m_history_0;
    PSHistory m_history_1;
    std::unique_ptr<PSHistory> m_active_history;
@@ -144,7 +148,7 @@ private:
    ignitionBoxStatusFiltered m_info_filtered;
    static const uint32_t c_idle_time = 2000;       // in mS
-    static const uint8_t c_spark_timeout_max = 500; // uS
+    static const uint32_t c_spark_timeout_max = 500; // uS
    static const uint8_t c_adc_time = 4;            // in mS
    static const uint8_t c_io_time = 2;             // in mS
 };