smart-oil-heating-control-system/main/metrics.c

#include <string.h>
#include "esp_timer.h"
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "esp_wifi.h"
#include "esp_log.h"
#include <time.h>
#include <sys/time.h>

#include "metrics.h"
#include "outputs.h"
#include "inputs.h"
#include "safety.h"
#include "sntp.h"
#include "control.h"

static const char *TAG = "smart-oil-heater-control-system-metrics";

char caHtmlResponse[HTML_RESPONSE_SIZE];
SemaphoreHandle_t xMutexAccessMetricResponse = NULL;
static sMetric aMetrics[METRIC_MAX_COUNT];
static uint16_t u16MetricCounter = 0U;

void taskMetrics(void *pvParameters);
httpd_handle_t setup_server(void);
esp_err_t get_metrics_handler(httpd_req_t *req);

void initMetrics(void)
{
    setup_server();

    BaseType_t taskCreated = xTaskCreate(
        taskMetrics,   // Function to implement the task
        "taskMetrics", // Task name
        16384,         // 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)
    );

    if (taskCreated == pdPASS)
    {
        ESP_LOGI(TAG, "Task created successfully!");
    }
    else
    {
        ESP_LOGE(TAG, "Failed to create task");
    }
}

void taskMetrics(void *pvParameters)
{
    while (1)
    {
        vTaskDelay(1000U / portTICK_PERIOD_MS);

        u16MetricCounter = 0U;

        /*Burner Error State*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "burner_fault_pending");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getBurnerError();
        u16MetricCounter++;

        /*Circulation Pump State*/
        if (getCirculationPumpState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "circulation_pump_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 1U;
            u16MetricCounter++;
        }
        else
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "circulation_pump_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 0U;
            u16MetricCounter++;
        }

        /*Burner State*/
        if (getBurnerState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "burner_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 1U;
            u16MetricCounter++;
        }
        else
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "burner_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 0U;
            u16MetricCounter++;
        }

        /*Safety Contact State*/
        if (getSafetyControlState() == ENABLED)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "safety_contact_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 1U;
            u16MetricCounter++;
        }
        else
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, "safety_contact_enabled");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = 0U;
            u16MetricCounter++;
        }

        /*Chamber Temperature*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().fCurrentValue;
        u16MetricCounter++;

        /*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*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "chamber_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getChamberTemperature().average60s.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*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "inlet_flow_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getInletFlowTemperature().average10s.fValue;
        u16MetricCounter++;

        /*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*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().fCurrentValue;
        u16MetricCounter++;

        /*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*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "outdoor_temperature_avg60");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getOutdoorTemperature().average60s.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*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "return_flow_temperature_avg10");
        aMetrics[u16MetricCounter].type = FLOAT;
        aMetrics[u16MetricCounter].fMetricValue = getReturnFlowTemperature().average10s.fValue;
        u16MetricCounter++;

        /*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*/
        sSensorSanityCheck aChecks[NUMBER_OF_SENSOR_SANITY_CHECKS];
        getSensorSanityStates(aChecks);
        for (size_t i = 0; i < NUMBER_OF_SENSOR_SANITY_CHECKS; i++)
        {
            strcpy(aMetrics[u16MetricCounter].caMetricName, aChecks[i].name);
            strcat(aMetrics[u16MetricCounter].caMetricName, "_state");
            aMetrics[u16MetricCounter].type = INTEGER_U8;
            aMetrics[u16MetricCounter].u8MetricValue = aChecks[i].state;
            u16MetricCounter++;
        }

        /*Safety State*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "safety_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getSafetyState();
        u16MetricCounter++;

        /*Control State*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "control_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getControlState();
        u16MetricCounter++;

        /*SNTP State*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "sntp_state");
        aMetrics[u16MetricCounter].type = INTEGER_U8;
        aMetrics[u16MetricCounter].u8MetricValue = getSntpState();
        u16MetricCounter++;

        /*System Time*/
        time_t now;
        time(&now);
        strcpy(aMetrics[u16MetricCounter].caMetricName, "system_unixtime");
        aMetrics[u16MetricCounter].type = INTEGER_64;
        aMetrics[u16MetricCounter].i64MetricValue = now;
        u16MetricCounter++;

        /*Uptime*/
        strcpy(aMetrics[u16MetricCounter].caMetricName, "uptime_seconds");
        aMetrics[u16MetricCounter].type = INTEGER_64;
        aMetrics[u16MetricCounter].i64MetricValue = (esp_timer_get_time() / 1000000U);
        u16MetricCounter++;

        /*Wifi RSSI*/
        wifi_ap_record_t ap;
        esp_wifi_sta_get_ap_info(&ap);
        strcpy(aMetrics[u16MetricCounter].caMetricName, "wifi_rssi");
        aMetrics[u16MetricCounter].type = INTEGER_64;
        aMetrics[u16MetricCounter].i64MetricValue = ap.rssi;
        u16MetricCounter++;

        vSetMetrics(aMetrics, u16MetricCounter);
    }
}

void vSetMetrics(sMetric *paMetrics, uint16_t u16Size)
{

    if (xSemaphoreTakeRecursive(xMutexAccessMetricResponse, pdMS_TO_TICKS(5000)) == pdTRUE)
    {
        memset(caHtmlResponse, 0, strlen(caHtmlResponse));
        for (uint16_t u16Index = 0U; u16Index < u16Size; u16Index++)
        {
            char caValueBuffer[64];

            switch (paMetrics[u16Index].type)
            {
            case FLOAT:
                sprintf(caValueBuffer, " %f", paMetrics[u16Index].fMetricValue);
                break;
            case INTEGER_64:
                sprintf(caValueBuffer, " %lli", paMetrics[u16Index].i64MetricValue);
                break;
            case INTEGER_U8:
                sprintf(caValueBuffer, " %u", paMetrics[u16Index].u8MetricValue);
                break;
            default:
                break;
            }

            // printf("%s\n", caValueBuffer);
            strcat(caHtmlResponse, paMetrics[u16Index].caMetricName);
            strcat(caHtmlResponse, caValueBuffer);
            strcat(caHtmlResponse, "\n");
        }
        xSemaphoreGiveRecursive(xMutexAccessMetricResponse);
    }
    else
    {
        ESP_LOGI(TAG, "[SET] Unable to obtain mutex for metric response");
    }
}

esp_err_t get_metrics_handler(httpd_req_t *req)
{
    if (xSemaphoreTakeRecursive(xMutexAccessMetricResponse, pdMS_TO_TICKS(5000)) == pdTRUE)
    {
        esp_err_t err = httpd_resp_send(req, caHtmlResponse, HTTPD_RESP_USE_STRLEN);
        xSemaphoreGiveRecursive(xMutexAccessMetricResponse);
        return err;
    }
    else
    {
        ESP_LOGI(TAG, "[GET] Unable to obtain mutex for metric response");
        return httpd_resp_send(req, 0, 0);
    }
}

httpd_handle_t setup_server(void)
{
    httpd_config_t config = HTTPD_DEFAULT_CONFIG();
    config.server_port = 9100;
    httpd_handle_t server = NULL;

    httpd_uri_t uri_get = {
        .uri = "/metrics",
        .method = HTTP_GET,
        .handler = get_metrics_handler,
        .user_ctx = NULL};

    xMutexAccessMetricResponse = xSemaphoreCreateRecursiveMutex();
    if (xMutexAccessMetricResponse == NULL)
    {
        ESP_LOGE(TAG, "Unable to create mutex for metric response");
    }
    xSemaphoreGiveRecursive(xMutexAccessMetricResponse);

    if (httpd_start(&server, &config) == ESP_OK)
    {
        httpd_register_uri_handler(server, &uri_get);
    }

    return server;
}