--- /dev/null
+/**
+ * @file sensor.c
+ * @brief Implementation of sensor thread
+ * TODO: Finalise implementation
+ */
+
+#include "common.h"
+#include "sensor.h"
+#include "options.h"
+#include <math.h>
+
+/** Array of sensors, initialised by Sensor_Init **/
+static Sensor g_sensors[NUMSENSORS]; //global to this file
+
+/** Human readable names for the sensors **/
+const char * g_sensor_names[NUMSENSORS] = {
+ "analog_test0", "analog_test1",
+ "analog_fail0", "digital_test0",
+ "digital_test1", "digital_fail0"
+};
+
+/**
+ * One off initialisation of *all* sensors
+ */
+void Sensor_Init()
+{
+ for (int i = 0; i < NUMSENSORS; ++i)
+ {
+ g_sensors[i].id = i;
+ Data_Init(&(g_sensors[i].data_file));
+ g_sensors[i].record_data = false;
+ }
+}
+
+/**
+ * Start a Sensor recording DataPoints
+ * @param s - The Sensor to start
+ * @param experiment_name - Prepended to DataFile filename
+ */
+void Sensor_Start(Sensor * s, const char * experiment_name)
+{
+ // Set filename
+ char filename[BUFSIZ];
+ if (sprintf(filename, "%s_%d", experiment_name, s->id) >= BUFSIZ)
+ {
+ Fatal("Experiment name \"%s\" too long (>%d)", experiment_name, BUFSIZ);
+ }
+
+ Log(LOGDEBUG, "Sensor %d with DataFile \"%s\"", s->id, filename);
+ // Open DataFile
+ Data_Open(&(s->data_file), filename);
+
+ s->record_data = true; // Don't forget this!
+
+ // Create the thread
+ pthread_create(&(s->thread), NULL, Sensor_Loop, (void*)(s));
+}
+
+/**
+ * Stop a Sensor from recording DataPoints. Blocks until it has stopped.
+ * @param s - The Sensor to stop
+ */
+void Sensor_Stop(Sensor * s)
+{
+ // Stop
+ if (s->record_data)
+ {
+ s->record_data = false;
+ pthread_join(s->thread, NULL); // Wait for thread to exit
+ Data_Close(&(s->data_file)); // Close DataFile
+ s->newest_data.time_stamp = 0;
+ s->newest_data.value = 0;
+ }
+}
+
+/**
+ * Stop all Sensors
+ */
+void Sensor_StopAll()
+{
+ for (int i = 0; i < NUMSENSORS; ++i)
+ Sensor_Stop(g_sensors+i);
+}
+
+/**
+ * Start all Sensors
+ */
+void Sensor_StartAll(const char * experiment_name)
+{
+ for (int i = 0; i < NUMSENSORS; ++i)
+ Sensor_Start(g_sensors+i, experiment_name);
+}
+
+
+/**
+ * Checks the sensor data for unsafe or unexpected results
+ * @param sensor_id - The ID of the sensor
+ * @param value - The value from the sensor to test
+ */
+void Sensor_CheckData(SensorId id, double value)
+{
+ switch (sensor_id)
+ {
+ case ANALOG_FAIL0:
+ {
+ if( value > ANALOG_FAIL0_SAFETY || value < ANALOG_FAIL0_MIN_SAFETY)
+ {
+ Log(LOGERR, "Sensor analog_fail0 is above or below its safety value of %d or %d\n", ANALOG_FAIL0_SAFETY, ANALOG_FAIL0_MIN_SAFETY);
+ //new function that stops actuators?
+ }
+ else if( value > ANALOG_FAIL0_WARN || value < ANALOG_FAIL0_MIN_WARN)
+ {
+ Log(LOGWARN, "Sensor analog_test0 is above or below its warning value of %d or %d\n", ANALOG_FAIL0_WARN, ANALOG_FAIL0_MIN_WARN);
+ }
+ break;
+ }
+ case DIGITAL_FAIL0:
+ {
+ if( value != 0 && value != 1)
+ {
+ Log(LOGERR, "Sensor digital_fail0 is not 0 or 1\n");
+ }
+ break;
+ }
+ default:
+ {
+ //So it doesn't complain about the missing cases - in practice we will need all sensors to be checked as above, no need to include a default as we should only pass valid sensor_id's; unless for some reason we have a sensor we don't need to check (but then why would you pass to this function in the first place :P)
+ }
+ }
+}
+
+
+/**
+ * Read a DataPoint from a Sensor; block until value is read
+ * @param id - The ID of the sensor
+ * @param d - DataPoint to set
+ * @returns True if the DataPoint was different from the most recently recorded.
+ */
+bool Sensor_Read(Sensor * s, DataPoint * d)
+{
+
+ // Set time stamp
+ struct timeval t;
+ gettimeofday(&t, NULL);
+ d->time_stamp = TIMEVAL_DIFF(t, g_options.start_time);
+
+ // Read value based on Sensor Id
+ switch (s->id)
+ {
+ case ANALOG_TEST0:
+ d->value = (double)(rand() % 100) / 100;
+ break;
+
+ case ANALOG_TEST1:
+ {
+ static int count = 0;
+ d->value = count++;
+ break;
+ }
+ case ANALOG_FAIL0:
+ d->value = (double)(rand() % 6) * -( rand() % 2) / ( rand() % 100 + 1);
+ //Gives a value between -5 and 5
+ CheckSensor(sensor_id, d->value);
+ break;
+ case DIGITAL_TEST0:
+ d->value = t.tv_sec % 2;
+ break;
+ case DIGITAL_TEST1:
+ d->value = (t.tv_sec+1)%2;
+ break;
+ case DIGITAL_FAIL0:
+ if( rand() % 100 > 98)
+ d->value = 2;
+ d->value = rand() % 2;
+ //Gives 0 or 1 or a 2 every 1/100 times
+ CheckSensor(sensor_id, d->value);
+ break;
+ default:
+ Fatal("Unknown sensor id: %d", s->id);
+ break;
+ }
+ usleep(100000); // simulate delay in sensor polling
+
+ // Perform sanity check based on Sensor's ID and the DataPoint
+ Sensor_CheckData(s->id, d);
+
+ // Update latest DataPoint if necessary
+ bool result = (d->value != s->newest_data.value);
+ if (result)
+ {
+ s->newest_data.time_stamp = d->time_stamp;
+ s->newest_data.value = d->value;
+ }
+ return result;
+}
+
+/**
+ * Record data from a single Sensor; to be run in a seperate thread
+ * @param arg - Cast to Sensor* - Sensor that the thread will handle
+ * @returns NULL (void* required to use the function with pthreads)
+ */
+void * Sensor_Loop(void * arg)
+{
+ Sensor * s = (Sensor*)(arg);
+ Log(LOGDEBUG, "Sensor %d starts", s->id);
+
+ // Until the sensor is stopped, record data points
+ while (s->record_data)
+ {
+ DataPoint d;
+ //Log(LOGDEBUG, "Sensor %d reads data [%f,%f]", s->id, d.time_stamp, d.value);
+ if (Sensor_Read(s, &d)) // If new DataPoint is read:
+ {
+ //Log(LOGDEBUG, "Sensor %d saves data [%f,%f]", s->id, d.time_stamp, d.value);
+ Data_Save(&(s->data_file), &d, 1); // Record it
+ }
+ }
+
+ // Needed to keep pthreads happy
+
+ Log(LOGDEBUG, "Sensor %d finished", s->id);
+ return NULL;
+}
+
+/**
+ * Get a Sensor given an ID string
+ * @param id_str ID string
+ * @returns Sensor* identified by the string; NULL on error
+ */
+Sensor * Sensor_Identify(const char * id_str)
+{
+ char * end;
+ // Parse string as integer
+ int id = strtol(id_str, &end, 10);
+ if (*end != '\0')
+ {
+ return NULL;
+ }
+ // Bounds check
+ if (id < 0 || id >= NUMSENSORS)
+ return NULL;
+
+
+ Log(LOGDEBUG, "Sensor \"%s\" identified", g_sensor_names[id]);
+ return g_sensors+id;
+}
+
+/**
+ * Helper: Begin sensor response in a given format
+ * @param context - the FCGIContext
+ * @param format - Format
+ * @param id - ID of sensor
+ */
+void Sensor_BeginResponse(FCGIContext * context, SensorId id, DataFormat format)
+{
+ // Begin response
+ switch (format)
+ {
+ case JSON:
+ FCGI_BeginJSON(context, STATUS_OK);
+ FCGI_JSONLong("id", id);
+ FCGI_JSONKey("data");
+ break;
+ default:
+ FCGI_PrintRaw("Content-type: text/plain\r\n\r\n");
+ break;
+ }
+}
+
+/**
+ * Helper: End sensor response in a given format
+ * @param context - the FCGIContext
+ * @param id - ID of the sensor
+ * @param format - Format
+ */
+void Sensor_EndResponse(FCGIContext * context, SensorId id, DataFormat format)
+{
+ // End response
+ switch (format)
+ {
+ case JSON:
+ FCGI_EndJSON();
+ break;
+ default:
+ break;
+ }
+}
+
+/**
+ * Handle a request to the sensor module
+ * @param context - The context to work in
+ * @param params - Parameters passed
+ */
+void Sensor_Handler(FCGIContext *context, char * params)
+{
+ struct timeval now;
+ gettimeofday(&now, NULL);
+ double current_time = TIMEVAL_DIFF(now, g_options.start_time);
+
+ int id = 0;
+ double start_time = 0;
+ double end_time = current_time;
+ char * fmt_str;
+
+ // key/value pairs
+ FCGIValue values[] = {
+ {"id", &id, FCGI_REQUIRED(FCGI_LONG_T)},
+ {"format", &fmt_str, FCGI_STRING_T},
+ {"start_time", &start_time, FCGI_DOUBLE_T},
+ {"end_time", &end_time, FCGI_DOUBLE_T},
+ };
+
+ // enum to avoid the use of magic numbers
+ typedef enum {
+ ID,
+ FORMAT,
+ START_TIME,
+ END_TIME,
+ } SensorParams;
+
+ // Fill values appropriately
+ if (!FCGI_ParseRequest(context, params, values, sizeof(values)/sizeof(FCGIValue)))
+ {
+ // Error occured; FCGI_RejectJSON already called
+ return;
+ }
+
+ // Get Sensor
+ Sensor * s = NULL;
+
+ // Error checking on sensor id
+ if (id < 0 || id >= NUMSENSORS)
+ {
+ Log(LOGERR, "Invalid id %d", id);
+ }
+ else
+ {
+ s = g_sensors+id;
+ }
+
+ DataFormat format = JSON;
+
+ // Check if format type was specified
+ if (FCGI_RECEIVED(values[FORMAT].flags))
+ {
+ if (strcmp(fmt_str, "json") == 0)
+ format = JSON;
+ else if (strcmp(fmt_str, "tsv") == 0)
+ format = TSV;
+ else
+ Log(LOGERR, "Unknown format type \"%s\"", fmt_str);
+ }
+
+
+
+ // Begin response
+ Sensor_BeginResponse(context, id, format);
+
+ // If a time was specified
+ if ((s != NULL) && (FCGI_RECEIVED(values[START_TIME].flags) || FCGI_RECEIVED(values[END_TIME].flags)))
+ {
+ // Wrap times relative to the current time
+ if (start_time < 0)
+ start_time += current_time;
+ if (end_time < 0)
+ end_time += current_time;
+
+ // Print points by time range
+ Data_PrintByTimes(&(s->data_file), start_time, end_time, format);
+
+ }
+ else if (s != NULL) // No time was specified; just return a recent set of points
+ {
+ pthread_mutex_lock(&(s->data_file.mutex));
+ int start_index = s->data_file.num_points-DATA_BUFSIZ;
+ int end_index = s->data_file.num_points-1;
+ pthread_mutex_unlock(&(s->data_file.mutex));
+
+ // Bounds check
+ if (start_index < 0)
+ start_index = 0;
+ if (end_index < 0)
+ end_index = 0;
+
+ // Print points by indexes
+ Log(LOGDEBUG, "Sensor %d file \"%s\" indexes %d->%d", s->id, s->data_file.filename, start_index, end_index);
+ Data_PrintByIndexes(&(s->data_file), start_index, end_index, format);
+ }
+
+ // Finish response
+ Sensor_EndResponse(context, id, format);
+
+}
+
+
+
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