2024-12-26 19:12:21 +01:00
5 changed files with 160 additions and 44 deletions
--- a/main/control.c
+++ b/main/control.c
@ -35,7 +35,7 @@ void initControl(void)
    BaseType_t taskCreated = xTaskCreate(
        taskControl,   // Function to implement the task
        "taskControl", // Task name
-        4096,          // Stack size (in words, not bytes)
+        8192,          // Stack size (in words, not bytes)
        NULL,          // Parameters to the task function (none in this case)
        5,             // Task priority (higher number = higher priority)
        NULL           // Task handle (optional)
--- a/main/inputs.c
+++ b/main/inputs.c
@ -1,6 +1,8 @@
 #include "freertos/FreeRTOS.h"
 #include "freertos/task.h"
 #include "driver/gpio.h"
 #include <string.h>
 #include <math.h>
 #include "esp_log.h"
 #include <ds18x20.h>
@ -31,7 +33,10 @@ static sMeasurement sInletFlowTemperature;
 static sMeasurement sReturnFlowTemperature;
 void taskInput(void *pvParameters);
 void initMeasurement(sMeasurement *pMeasurement);
 void updateAverage(sMeasurement *pMeasurement);
 void updatePrediction(sMeasurement *pMeasurement);
 float linearRegressionPredict(const float *samples, size_t count, float futureIndex);
 void initInputs(void)
 {
@ -53,6 +58,11 @@ void initInputs(void)
    }
    xSemaphoreGiveRecursive(xMutexAccessInputs);
    initMeasurement(&sChamperTemperature);
    initMeasurement(&sOutdoorTemperature);
    initMeasurement(&sInletFlowTemperature);
    initMeasurement(&sReturnFlowTemperature);
    BaseType_t taskCreated = xTaskCreate(
        taskInput,   // Function to implement the task
        "taskInput", // Task name
@ -72,8 +82,36 @@ void initInputs(void)
    }
 }
 void initMeasurement(sMeasurement *pMeasurement)
 {
    if (!pMeasurement)
        return;
    pMeasurement->state = MEASUREMENT_FAULT;
    pMeasurement->fCurrentValue = 0.0f;
    pMeasurement->average10s.fValue = 0.0f;
    pMeasurement->average10s.bufferCount = 0U;
    pMeasurement->average10s.bufferIndex = 0U;
    memset(pMeasurement->average10s.samples, 0U, AVG10_SAMPLE_SIZE);
    pMeasurement->average60s.fValue = 0.0f;
    pMeasurement->average60s.bufferCount = 0U;
    pMeasurement->average60s.bufferIndex = 0U;
    memset(pMeasurement->average60s.samples, 0U, AVG60_SAMPLE_SIZE);
    pMeasurement->predict60s.fValue = 0.0f;
    pMeasurement->predict60s.bufferCount = 0U;
    pMeasurement->predict60s.bufferIndex = 0U;
    memset(pMeasurement->predict60s.samples, 0U, PRED60_SAMPLE_SIZE);
 }
 void updateAverage(sMeasurement *pMeasurement)
-{ /* Average form the last 10sec */
+{
    if (!pMeasurement)
        return;
    // Average form the last 10sec
    pMeasurement->average10s.samples[pMeasurement->average10s.bufferIndex] = pMeasurement->fCurrentValue;
    pMeasurement->average10s.bufferIndex = (pMeasurement->average10s.bufferIndex + 1) % AVG10_SAMPLE_SIZE;
@ -82,20 +120,15 @@ void updateAverage(sMeasurement *pMeasurement)
        pMeasurement->average10s.bufferCount++;
    }
    if (pMeasurement->average10s.bufferCount == 0U)
    {
        pMeasurement->average10s.fValue = pMeasurement->fCurrentValue;
    }
    float sum = 0.0;
-    for (int i = 0; i < pMeasurement->average10s.bufferCount; i++)
+    for (int i = 0; i <= pMeasurement->average10s.bufferCount; i++)
    {
        sum += pMeasurement->average10s.samples[i];
    }
    pMeasurement->average10s.fValue = sum / pMeasurement->average10s.bufferCount;
-    /* Average form the last 60sec */
+    // Average form the last 60sec
    pMeasurement->average60s.samples[pMeasurement->average60s.bufferIndex] = pMeasurement->fCurrentValue;
    pMeasurement->average60s.bufferIndex = (pMeasurement->average60s.bufferIndex + 1) % AVG60_SAMPLE_SIZE;
@ -104,13 +137,8 @@ void updateAverage(sMeasurement *pMeasurement)
        pMeasurement->average60s.bufferCount++;
    }
    if (pMeasurement->average60s.bufferCount == 0U)
    {
        pMeasurement->average60s.fValue = pMeasurement->fCurrentValue;
    }
    sum = 0.0;
-    for (int i = 0; i < pMeasurement->average60s.bufferCount; i++)
+    for (int i = 0; i <= pMeasurement->average60s.bufferCount; i++)
    {
        sum += pMeasurement->average60s.samples[i];
    }
@ -118,6 +146,25 @@ void updateAverage(sMeasurement *pMeasurement)
    pMeasurement->average60s.fValue = sum / pMeasurement->average60s.bufferCount;
 }
 void updatePrediction(sMeasurement *pMeasurement)
 {
    if (!pMeasurement)
        return;
    // Update predict60s buffer
    sPredict *predict60s = &pMeasurement->predict60s;
    predict60s->samples[predict60s->bufferIndex] = pMeasurement->fCurrentValue;
    predict60s->bufferIndex = (predict60s->bufferIndex + 1) % PRED60_SAMPLE_SIZE;
    if (predict60s->bufferCount < PRED60_SAMPLE_SIZE)
        predict60s->bufferCount++;
    // Predict 60s future value using linear regression
    predict60s->fValue = linearRegressionPredict(
        predict60s->samples,
        predict60s->bufferCount,
        predict60s->bufferCount + 60.0f);
 }
 void taskInput(void *pvParameters)
 {
    while (1)
@ -163,7 +210,7 @@ void taskInput(void *pvParameters)
                    if (ds18x20_measure_and_read_multi(uDS18B20Pin, uOneWireAddresses, sSensorCount, fDS18B20Temps) != ESP_OK)
                    {
                        ESP_LOGE(TAG, "1-Wire devices read error");
-                        vTaskDelay(PERIODIC_INTERVAL * 100U / portTICK_PERIOD_MS); //Wait 100ms if bus error occurred
+                        vTaskDelay(PERIODIC_INTERVAL * 100U / portTICK_PERIOD_MS); // Wait 100ms if bus error occurred
                    }
                    else
                    {
@ -178,21 +225,25 @@ void taskInput(void *pvParameters)
                                sChamperTemperature.fCurrentValue = temp_c;
                                sChamperTemperature.state = MEASUREMENT_NO_ERROR;
                                updateAverage(&sChamperTemperature);
                                updatePrediction(&sChamperTemperature);
                                break;
                            case ((uint64_t)uOutdoorTempSensorAddr):
                                sOutdoorTemperature.fCurrentValue = temp_c;
                                sOutdoorTemperature.state = MEASUREMENT_NO_ERROR;
                                updateAverage(&sOutdoorTemperature);
                                updatePrediction(&sOutdoorTemperature);
                                break;
                            case ((uint64_t)uInletFlowTempSensorAddr):
                                sInletFlowTemperature.fCurrentValue = temp_c;
                                sInletFlowTemperature.state = MEASUREMENT_NO_ERROR;
                                updateAverage(&sInletFlowTemperature);
                                updatePrediction(&sInletFlowTemperature);
                                break;
                            case ((uint64_t)uReturnFlowTempSensorAddr):
                                sReturnFlowTemperature.fCurrentValue = temp_c;
                                sReturnFlowTemperature.state = MEASUREMENT_NO_ERROR;
                                updateAverage(&sReturnFlowTemperature);
                                updatePrediction(&sReturnFlowTemperature);
                                break;
                            default:
                                break;
@ -216,6 +267,36 @@ void taskInput(void *pvParameters)
    }
 }
 float linearRegressionPredict(const float *samples, size_t count, float futureIndex)
 {
    if (count == 0)
        return 0.0f; // No prediction possible with no data
    float sumX = 0.0f, sumY = 0.0f, sumXY = 0.0f, sumX2 = 0.0f;
    for (size_t i = 0; i < count; i++)
    {
        float x = (float)i;   // Time index
        float y = samples[i]; // Sample value
        sumX += x;
        sumY += y;
        sumXY += x * y;
        sumX2 += x * x;
    }
    // Calculate slope (m) and intercept (b) of the line: y = mx + b
    float denominator = (count * sumX2 - sumX * sumX);
    if (fabs(denominator) < 1e-6)  // Avoid division by zero
        return samples[count - 1]; // Return last value as prediction
    float m = (count * sumXY - sumX * sumY) / denominator;
    float b = (sumY - m * sumX) / count;
    // Predict value at futureIndex
    return m * futureIndex + b;
 }
 sMeasurement getChamberTemperature(void)
 {
    sMeasurement ret;
--- a/main/inputs.h
+++ b/main/inputs.h
@ -3,6 +3,7 @@
 #define MAX(a, b) ((a) > (b) ? (a) : (b))
 #define AVG10_SAMPLE_SIZE 10U
 #define AVG60_SAMPLE_SIZE 60U
 #define PRED60_SAMPLE_SIZE 60U
 typedef enum _BurnerErrorState
 {
@ -24,11 +25,20 @@ typedef struct _Average
    size_t bufferCount;
 } sAverage;
 typedef struct _Predict
 {
    float fValue;
    float samples[PRED60_SAMPLE_SIZE];
    size_t bufferIndex;
    size_t bufferCount;
 } sPredict;
 typedef struct _Measurement
 {
    float fCurrentValue;
    sAverage average10s;
    sAverage average60s;
    sPredict predict60s;
    eMeasurementErrorState state;
 } sMeasurement;
--- a/main/metrics.c
+++ b/main/metrics.c
@ -32,7 +32,7 @@ void initMetrics(void)
    BaseType_t taskCreated = xTaskCreate(
        taskMetrics,   // Function to implement the task
        "taskMetrics", // Task name
-        16384,         // Stack size (in words, not bytes)
+        32768,         // Stack size (in words, not bytes)
        NULL,          // Parameters to the task function (none in this case)
        5,             // Task priority (higher number = higher priority)
        NULL           // Task handle (optional)
@ -56,13 +56,13 @@ void taskMetrics(void *pvParameters)
        u16MetricCounter = 0U;
-        /*Burner Error State*/
+        // Burner Error State
        strcpy(aMetrics[u16MetricCounter].caMetricName, "burner_fault_pending");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getBurnerError();
        u16MetricCounter++;
-        /*Circulation Pump State*/
+        // Circulation Pump State
        if (getCirculationPumpState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "circulation_pump_enabled");
@ -78,7 +78,7 @@ void taskMetrics(void *pvParameters)
            u16MetricCounter++;
        }
-        /*Burner State*/
+        // Burner State
        if (getBurnerState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "burner_enabled");
@ -94,7 +94,7 @@ void taskMetrics(void *pvParameters)
            u16MetricCounter++;
        }
-        /*Safety Contact State*/
+        // Safety Contact State
        if (getSafetyControlState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "safety_contact_enabled");
@ -110,79 +110,103 @@ void taskMetrics(void *pvParameters)
            u16MetricCounter++;
        }
-        /*Chamber Temperature*/
+        // Chamber Temperature
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().fCurrentValue;
        u16MetricCounter++;
-        /*Chamber Temperature Average 10s*/
+        // Chamber Temperature Average 10s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().average10s.fValue;
        u16MetricCounter++;
-        /*Chamber Temperature Average 60s*/
+        // Chamber Temperature Average 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().average60s.fValue;
        u16MetricCounter++;
-        /*Inlet Flow Temperature*/
+        // Chamber Temperature Predict 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature_pred60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().predict60s.fValue;
        u16MetricCounter++;
        // Inlet Flow Temperature
        strcpy(aMetrics[u16MetricCounter].caMetricName, "inlet_flow_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getInletFlowTemperature().fCurrentValue;
        u16MetricCounter++;
-        /*Inlet Flow Temperature Average 10s*/
+        // Inlet Flow Temperature Average 10s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "inlet_flow_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getInletFlowTemperature().average10s.fValue;
        u16MetricCounter++;
-        /*Inlet Flow Temperature Average 60s*/
+        // Inlet Flow Temperature Average 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "inlet_flow_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getInletFlowTemperature().average60s.fValue;
        u16MetricCounter++;
-        /*Outdoor Temperature*/
+        // Inlet Flow Temperature Predict 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "inlet_flow_temperature_pred60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getInletFlowTemperature().predict60s.fValue;
        u16MetricCounter++;
        // Outdoor Temperature
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().fCurrentValue;
        u16MetricCounter++;
-        /*Outdoor Temperature Average 10s*/
+        // Outdoor Temperature Average 10s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().average10s.fValue;
        u16MetricCounter++;
-        /*Outdoor Temperature Average 60s*/
+        // Outdoor Temperature Average 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().average60s.fValue;
        u16MetricCounter++;
-        /*Return Flow Temperature*/
+        // Outdoor Temperature Predict 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature_pred60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().predict60s.fValue;
        u16MetricCounter++;
        // Return Flow Temperature
        strcpy(aMetrics[u16MetricCounter].caMetricName, "return_flow_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getReturnFlowTemperature().fCurrentValue;
        u16MetricCounter++;
-        /*Return Flow Temperature Average 10s*/
+        // Return Flow Temperature Average 10s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "return_flow_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getReturnFlowTemperature().average10s.fValue;
        u16MetricCounter++;
-        /*Return Flow Temperature Average 60s*/
+        // Return Flow Temperature Average 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "return_flow_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getReturnFlowTemperature().average60s.fValue;
        u16MetricCounter++;
-        /*Sensor State*/
+        // Return Flow Temperature Predict 60s
        strcpy(aMetrics[u16MetricCounter].caMetricName, "return_flow_temperature_pred60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getReturnFlowTemperature().predict60s.fValue;
        u16MetricCounter++;
        // Sensor State
        sSensorSanityCheck aChecks[NUMBER_OF_SENSOR_SANITY_CHECKS];
        getSensorSanityStates(aChecks);
        for (size_t i = 0; i < NUMBER_OF_SENSOR_SANITY_CHECKS; i++)
@ -194,25 +218,25 @@ void taskMetrics(void *pvParameters)
            u16MetricCounter++;
        }
-        /*Safety State*/
+        // Safety State
        strcpy(aMetrics[u16MetricCounter].caMetricName, "safety_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getSafetyState();
        u16MetricCounter++;
-        /*Control State*/
+        // Control State
        strcpy(aMetrics[u16MetricCounter].caMetricName, "control_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getControlState();
        u16MetricCounter++;
-        /*SNTP State*/
+        // SNTP State
        strcpy(aMetrics[u16MetricCounter].caMetricName, "sntp_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getSntpState();
        u16MetricCounter++;
-        /*System Time*/
+        // System Time
        time_t now;
        time(&now);
        strcpy(aMetrics[u16MetricCounter].caMetricName, "system_unixtime");
@ -220,13 +244,13 @@ void taskMetrics(void *pvParameters)
        aMetrics[u16MetricCounter].i64MetricValue = now;
        u16MetricCounter++;
-        /*Uptime*/
+        // Uptime
        strcpy(aMetrics[u16MetricCounter].caMetricName, "uptime_seconds");
        aMetrics[u16MetricCounter].type = INTEGER_64;
        aMetrics[u16MetricCounter].i64MetricValue = (esp_timer_get_time() / 1000000U);
        u16MetricCounter++;
-        /*Wifi RSSI*/
+        // Wifi RSSI
        wifi_ap_record_t ap;
        esp_wifi_sta_get_ap_info(&ap);
        strcpy(aMetrics[u16MetricCounter].caMetricName, "wifi_rssi");
@ -243,7 +267,7 @@ void vSetMetrics(sMetric *paMetrics, uint16_t u16Size)
    if (xSemaphoreTakeRecursive(xMutexAccessMetricResponse, pdMS_TO_TICKS(5000)) == pdTRUE)
    {
-        memset(caHtmlResponse, 0, strlen(caHtmlResponse));
+        memset(caHtmlResponse, 0U, strlen(caHtmlResponse));
        for (uint16_t u16Index = 0U; u16Index < u16Size; u16Index++)
        {
            char caValueBuffer[64];
@ -263,6 +287,7 @@ void vSetMetrics(sMetric *paMetrics, uint16_t u16Size)
                break;
            }
            // printf("%s\n", paMetrics[u16Index].caMetricName);
            // printf("%s\n", caValueBuffer);
            strcat(caHtmlResponse, paMetrics[u16Index].caMetricName);
            strcat(caHtmlResponse, caValueBuffer);
--- a/main/metrics.h
+++ b/main/metrics.h
@ -2,9 +2,9 @@
 #include <esp_http_server.h>
-#define HTML_RESPONSE_SIZE 1024U
+#define HTML_RESPONSE_SIZE 4096U
-#define METRIC_NAME_MAX_SIZE 256U
+#define METRIC_NAME_MAX_SIZE 64U
-#define METRIC_MAX_COUNT 64U
+#define METRIC_MAX_COUNT 32U
 typedef enum _MetricValueType
 {