/* * Copyright (c) 2014, Texas Instruments Incorporated - http://www.ti.com/ * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. */ /** * \addtogroup cc26xx-web-demo * @{ * * \file * Main module for the CC26XX web demo. Activates on-device resources, * takes sensor readings periodically and caches them for all other modules * to use. */ /*---------------------------------------------------------------------------*/ #include "contiki.h" #include "contiki-net.h" #include "rest-engine.h" #include "board-peripherals.h" #include "lib/sensors.h" #include "lib/list.h" #include "sys/process.h" #include "net/ipv6/sicslowpan.h" #include "button-sensor.h" #include "batmon-sensor.h" #include "httpd-simple.h" #include "cc26xx-web-demo.h" #include "mqtt-client.h" #include "coap-server.h" #include #include #include /*---------------------------------------------------------------------------*/ PROCESS_NAME(cetic_6lbr_client_process); PROCESS(cc26xx_web_demo_process, "CC26XX Web Demo"); /*---------------------------------------------------------------------------*/ /* * Update sensor readings in a staggered fashion every SENSOR_READING_PERIOD * ticks + a random interval between 0 and SENSOR_READING_RANDOM ticks */ #define SENSOR_READING_PERIOD (CLOCK_SECOND * 20) #define SENSOR_READING_RANDOM (CLOCK_SECOND << 4) struct ctimer batmon_timer; #if BOARD_SENSORTAG struct ctimer bmp_timer, hdc_timer, tmp_timer, opt_timer, mpu_timer; #endif /*---------------------------------------------------------------------------*/ /* Provide visible feedback via LEDS while searching for a network */ #define NO_NET_LED_DURATION (CC26XX_WEB_DEMO_NET_CONNECT_PERIODIC >> 1) static struct etimer et; static struct ctimer ct; /*---------------------------------------------------------------------------*/ /* Parent RSSI functionality */ #if CC26XX_WEB_DEMO_READ_PARENT_RSSI static struct uip_icmp6_echo_reply_notification echo_reply_notification; static struct etimer echo_request_timer; int def_rt_rssi = 0; #endif /*---------------------------------------------------------------------------*/ process_event_t cc26xx_web_demo_publish_event; process_event_t cc26xx_web_demo_config_loaded_event; process_event_t cc26xx_web_demo_load_config_defaults; /*---------------------------------------------------------------------------*/ /* Saved settings on flash: store, offset, magic */ #define CONFIG_FLASH_OFFSET 0 #define CONFIG_MAGIC 0xCC265002 cc26xx_web_demo_config_t cc26xx_web_demo_config; /*---------------------------------------------------------------------------*/ /* A cache of sensor values. Updated periodically or upon key press */ LIST(sensor_list); /*---------------------------------------------------------------------------*/ /* The objects representing sensors used in this demo */ #define DEMO_SENSOR(name, type, descr, xml_element, form_field, units) \ cc26xx_web_demo_sensor_reading_t name##_reading = \ { NULL, 0, 0, descr, xml_element, form_field, units, type, 1, 1 } /* CC26xx sensors */ DEMO_SENSOR(batmon_temp, CC26XX_WEB_DEMO_SENSOR_BATMON_TEMP, "Battery Temp", "battery-temp", "batmon_temp", CC26XX_WEB_DEMO_UNIT_TEMP); DEMO_SENSOR(batmon_volt, CC26XX_WEB_DEMO_SENSOR_BATMON_VOLT, "Battery Volt", "battery-volt", "batmon_volt", CC26XX_WEB_DEMO_UNIT_VOLT); /* Sensortag sensors */ #if BOARD_SENSORTAG DEMO_SENSOR(bmp_pres, CC26XX_WEB_DEMO_SENSOR_BMP_PRES, "Air Pressure", "air-pressure", "bmp_pres", CC26XX_WEB_DEMO_UNIT_PRES); DEMO_SENSOR(bmp_temp, CC26XX_WEB_DEMO_SENSOR_BMP_TEMP, "Air Temp", "air-temp", "bmp_temp", CC26XX_WEB_DEMO_UNIT_TEMP); DEMO_SENSOR(hdc_temp, CC26XX_WEB_DEMO_SENSOR_HDC_TEMP, "HDC Temp", "hdc-temp", "hdc_temp", CC26XX_WEB_DEMO_UNIT_TEMP); DEMO_SENSOR(hdc_hum, CC26XX_WEB_DEMO_SENSOR_HDC_HUMIDITY, "HDC Humidity", "hdc-humidity", "hdc_hum", CC26XX_WEB_DEMO_UNIT_HUMIDITY); DEMO_SENSOR(tmp_amb, CC26XX_WEB_DEMO_SENSOR_TMP_AMBIENT, "Ambient Temp", "ambient-temp", "tmp_amb", CC26XX_WEB_DEMO_UNIT_TEMP); DEMO_SENSOR(tmp_obj, CC26XX_WEB_DEMO_SENSOR_TMP_OBJECT, "Object Temp", "object-temp", "tmp_obj", CC26XX_WEB_DEMO_UNIT_TEMP); DEMO_SENSOR(opt, CC26XX_WEB_DEMO_SENSOR_OPT_LIGHT, "Light", "light", "light", CC26XX_WEB_DEMO_UNIT_LIGHT); /* MPU Readings */ DEMO_SENSOR(mpu_acc_x, CC26XX_WEB_DEMO_SENSOR_MPU_ACC_X, "Acc X", "acc-x", "acc_x", CC26XX_WEB_DEMO_UNIT_ACC); DEMO_SENSOR(mpu_acc_y, CC26XX_WEB_DEMO_SENSOR_MPU_ACC_Y, "Acc Y", "acc-y", "acc_y", CC26XX_WEB_DEMO_UNIT_ACC); DEMO_SENSOR(mpu_acc_z, CC26XX_WEB_DEMO_SENSOR_MPU_ACC_Z, "Acc Z", "acc-z", "acc_z", CC26XX_WEB_DEMO_UNIT_ACC); DEMO_SENSOR(mpu_gyro_x, CC26XX_WEB_DEMO_SENSOR_MPU_GYRO_X, "Gyro X", "gyro-x", "gyro_x", CC26XX_WEB_DEMO_UNIT_GYRO); DEMO_SENSOR(mpu_gyro_y, CC26XX_WEB_DEMO_SENSOR_MPU_GYRO_Y, "Gyro Y", "gyro-y", "gyro_y", CC26XX_WEB_DEMO_UNIT_GYRO); DEMO_SENSOR(mpu_gyro_z, CC26XX_WEB_DEMO_SENSOR_MPU_GYRO_Z, "Gyro Z", "gyro-z", "gyro_Z", CC26XX_WEB_DEMO_UNIT_GYRO); #endif /*---------------------------------------------------------------------------*/ #if BOARD_SENSORTAG static void init_bmp_reading(void *data); static void init_light_reading(void *data); static void init_hdc_reading(void *data); static void init_tmp_reading(void *data); static void init_mpu_reading(void *data); #endif /*---------------------------------------------------------------------------*/ static void publish_led_off(void *d) { leds_off(CC26XX_WEB_DEMO_STATUS_LED); } /*---------------------------------------------------------------------------*/ static void save_config() { /* Dump current running config to flash */ #if BOARD_SENSORTAG || BOARD_LAUNCHPAD int rv; cc26xx_web_demo_sensor_reading_t *reading = NULL; rv = ext_flash_open(); if(!rv) { printf("Could not open flash to save config\n"); ext_flash_close(); return; } rv = ext_flash_erase(CONFIG_FLASH_OFFSET, sizeof(cc26xx_web_demo_config_t)); if(!rv) { printf("Error erasing flash\n"); } else { cc26xx_web_demo_config.magic = CONFIG_MAGIC; cc26xx_web_demo_config.len = sizeof(cc26xx_web_demo_config_t); cc26xx_web_demo_config.sensors_bitmap = 0; for(reading = list_head(sensor_list); reading != NULL; reading = list_item_next(reading)) { if(reading->publish) { cc26xx_web_demo_config.sensors_bitmap |= (1 << reading->type); } } rv = ext_flash_write(CONFIG_FLASH_OFFSET, sizeof(cc26xx_web_demo_config_t), (uint8_t *)&cc26xx_web_demo_config); if(!rv) { printf("Error saving config\n"); } } ext_flash_close(); #endif } /*---------------------------------------------------------------------------*/ static void load_config() { #if BOARD_SENSORTAG || BOARD_LAUNCHPAD /* Read from flash into a temp buffer */ cc26xx_web_demo_config_t tmp_cfg; cc26xx_web_demo_sensor_reading_t *reading = NULL; int rv = ext_flash_open(); if(!rv) { printf("Could not open flash to load config\n"); ext_flash_close(); return; } rv = ext_flash_read(CONFIG_FLASH_OFFSET, sizeof(tmp_cfg), (uint8_t *)&tmp_cfg); ext_flash_close(); if(!rv) { printf("Error loading config\n"); return; } if(tmp_cfg.magic == CONFIG_MAGIC && tmp_cfg.len == sizeof(tmp_cfg)) { memcpy(&cc26xx_web_demo_config, &tmp_cfg, sizeof(cc26xx_web_demo_config)); } for(reading = list_head(sensor_list); reading != NULL; reading = list_item_next(reading)) { if(cc26xx_web_demo_config.sensors_bitmap & (1 << reading->type)) { reading->publish = 1; } else { reading->publish = 0; snprintf(reading->converted, CC26XX_WEB_DEMO_CONVERTED_LEN, "\"N/A\""); } } #endif } /*---------------------------------------------------------------------------*/ /* Don't start everything here, we need to dictate order of initialisation */ AUTOSTART_PROCESSES(&cc26xx_web_demo_process); /*---------------------------------------------------------------------------*/ int cc26xx_web_demo_ipaddr_sprintf(char *buf, uint8_t buf_len, const uip_ipaddr_t *addr) { uint16_t a; uint8_t len = 0; int i, f; for(i = 0, f = 0; i < sizeof(uip_ipaddr_t); i += 2) { a = (addr->u8[i] << 8) + addr->u8[i + 1]; if(a == 0 && f >= 0) { if(f++ == 0) { len += snprintf(&buf[len], buf_len - len, "::"); } } else { if(f > 0) { f = -1; } else if(i > 0) { len += snprintf(&buf[len], buf_len - len, ":"); } len += snprintf(&buf[len], buf_len - len, "%x", a); } } return len; } /*---------------------------------------------------------------------------*/ const cc26xx_web_demo_sensor_reading_t * cc26xx_web_demo_sensor_lookup(int sens_type) { cc26xx_web_demo_sensor_reading_t *reading = NULL; for(reading = list_head(sensor_list); reading != NULL; reading = list_item_next(reading)) { if(reading->type == sens_type) { return reading; } } return NULL; } /*---------------------------------------------------------------------------*/ const cc26xx_web_demo_sensor_reading_t * cc26xx_web_demo_sensor_first() { return list_head(sensor_list); } /*---------------------------------------------------------------------------*/ void cc26xx_web_demo_restore_defaults(void) { cc26xx_web_demo_sensor_reading_t *reading = NULL; leds_on(LEDS_ALL); for(reading = list_head(sensor_list); reading != NULL; reading = list_item_next(reading)) { reading->publish = 1; } #if CC26XX_WEB_DEMO_MQTT_CLIENT process_post_synch(&mqtt_client_process, cc26xx_web_demo_load_config_defaults, NULL); #endif #if CC26XX_WEB_DEMO_NET_UART process_post_synch(&net_uart_process, cc26xx_web_demo_load_config_defaults, NULL); #endif save_config(); leds_off(LEDS_ALL); } /*---------------------------------------------------------------------------*/ static int defaults_post_handler(char *key, int key_len, char *val, int val_len) { if(key_len != strlen("defaults") || strncasecmp(key, "defaults", strlen("defaults")) != 0) { /* Not ours */ return HTTPD_SIMPLE_POST_HANDLER_UNKNOWN; } cc26xx_web_demo_restore_defaults(); return HTTPD_SIMPLE_POST_HANDLER_OK; } /*---------------------------------------------------------------------------*/ static int sensor_readings_handler(char *key, int key_len, char *val, int val_len) { cc26xx_web_demo_sensor_reading_t *reading = NULL; int rv; for(reading = list_head(sensor_list); reading != NULL; reading = list_item_next(reading)) { if(key_len == strlen(reading->form_field) && strncmp(reading->form_field, key, strlen(key)) == 0) { rv = atoi(val); /* Be pedantic: only accept 0 and 1, not just any non-zero value */ if(rv == 0) { reading->publish = 0; snprintf(reading->converted, CC26XX_WEB_DEMO_CONVERTED_LEN, "\"N/A\""); } else if(rv == 1) { reading->publish = 1; } else { return HTTPD_SIMPLE_POST_HANDLER_ERROR; } return HTTPD_SIMPLE_POST_HANDLER_OK; } } return HTTPD_SIMPLE_POST_HANDLER_UNKNOWN; } /*---------------------------------------------------------------------------*/ #if CC26XX_WEB_DEMO_READ_PARENT_RSSI static int ping_interval_post_handler(char *key, int key_len, char *val, int val_len) { int rv = 0; if(key_len != strlen("ping_interval") || strncasecmp(key, "ping_interval", strlen("ping_interval")) != 0) { /* Not ours */ return HTTPD_SIMPLE_POST_HANDLER_UNKNOWN; } rv = atoi(val); if(rv < CC26XX_WEB_DEMO_RSSI_MEASURE_INTERVAL_MIN || rv > CC26XX_WEB_DEMO_RSSI_MEASURE_INTERVAL_MAX) { return HTTPD_SIMPLE_POST_HANDLER_ERROR; } cc26xx_web_demo_config.def_rt_ping_interval = rv * CLOCK_SECOND; return HTTPD_SIMPLE_POST_HANDLER_OK; } #endif /*---------------------------------------------------------------------------*/ HTTPD_SIMPLE_POST_HANDLER(sensor, sensor_readings_handler); HTTPD_SIMPLE_POST_HANDLER(defaults, defaults_post_handler); #if CC26XX_WEB_DEMO_READ_PARENT_RSSI HTTPD_SIMPLE_POST_HANDLER(ping_interval, ping_interval_post_handler); /*---------------------------------------------------------------------------*/ static void echo_reply_handler(uip_ipaddr_t *source, uint8_t ttl, uint8_t *data, uint16_t datalen) { if(uip_ip6addr_cmp(source, uip_ds6_defrt_choose())) { def_rt_rssi = sicslowpan_get_last_rssi(); } } /*---------------------------------------------------------------------------*/ static void ping_parent(void) { if(uip_ds6_get_global(ADDR_PREFERRED) == NULL) { return; } uip_icmp6_send(uip_ds6_defrt_choose(), ICMP6_ECHO_REQUEST, 0, CC26XX_WEB_DEMO_ECHO_REQ_PAYLOAD_LEN); } #endif /*---------------------------------------------------------------------------*/ static void get_batmon_reading(void *data) { int value; char *buf; clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); if(batmon_temp_reading.publish) { value = batmon_sensor.value(BATMON_SENSOR_TYPE_TEMP); if(value != CC26XX_SENSOR_READING_ERROR) { batmon_temp_reading.raw = value; buf = batmon_temp_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d", value); } } if(batmon_volt_reading.publish) { value = batmon_sensor.value(BATMON_SENSOR_TYPE_VOLT); if(value != CC26XX_SENSOR_READING_ERROR) { batmon_volt_reading.raw = value; buf = batmon_volt_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d", (value * 125) >> 5); } } ctimer_set(&batmon_timer, next, get_batmon_reading, NULL); } /*---------------------------------------------------------------------------*/ #if BOARD_SENSORTAG /*---------------------------------------------------------------------------*/ static void compare_and_update(cc26xx_web_demo_sensor_reading_t *reading) { if(reading->last == reading->raw) { reading->changed = 0; } else { reading->last = reading->raw; reading->changed = 1; } } /*---------------------------------------------------------------------------*/ static void print_mpu_reading(int reading, char *buf) { char *loc_buf = buf; if(reading < 0) { sprintf(loc_buf, "-"); reading = -reading; loc_buf++; } sprintf(loc_buf, "%d.%02d", reading / 100, reading % 100); } /*---------------------------------------------------------------------------*/ static void get_bmp_reading() { int value; char *buf; clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); if(bmp_pres_reading.publish) { value = bmp_280_sensor.value(BMP_280_SENSOR_TYPE_PRESS); if(value != CC26XX_SENSOR_READING_ERROR) { bmp_pres_reading.raw = value; compare_and_update(&bmp_pres_reading); buf = bmp_pres_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%02d", value / 100, value % 100); } } if(bmp_temp_reading.publish) { value = bmp_280_sensor.value(BMP_280_SENSOR_TYPE_TEMP); if(value != CC26XX_SENSOR_READING_ERROR) { bmp_temp_reading.raw = value; compare_and_update(&bmp_temp_reading); buf = bmp_temp_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%02d", value / 100, value % 100); } } SENSORS_DEACTIVATE(bmp_280_sensor); ctimer_set(&bmp_timer, next, init_bmp_reading, NULL); } /*---------------------------------------------------------------------------*/ static void get_tmp_reading() { int value; char *buf; clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); if(tmp_amb_reading.publish || tmp_obj_reading.publish) { if(tmp_007_sensor.value(TMP_007_SENSOR_TYPE_ALL) == CC26XX_SENSOR_READING_ERROR) { SENSORS_DEACTIVATE(tmp_007_sensor); ctimer_set(&tmp_timer, next, init_tmp_reading, NULL); } } if(tmp_amb_reading.publish) { value = tmp_007_sensor.value(TMP_007_SENSOR_TYPE_AMBIENT); tmp_amb_reading.raw = value; compare_and_update(&tmp_amb_reading); buf = tmp_amb_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%03d", value / 1000, value % 1000); } if(tmp_obj_reading.publish) { value = tmp_007_sensor.value(TMP_007_SENSOR_TYPE_OBJECT); tmp_obj_reading.raw = value; compare_and_update(&tmp_obj_reading); buf = tmp_obj_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%03d", value / 1000, value % 1000); } SENSORS_DEACTIVATE(tmp_007_sensor); ctimer_set(&tmp_timer, next, init_tmp_reading, NULL); } /*---------------------------------------------------------------------------*/ static void get_hdc_reading() { int value; char *buf; clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); if(hdc_temp_reading.publish) { value = hdc_1000_sensor.value(HDC_1000_SENSOR_TYPE_TEMP); if(value != CC26XX_SENSOR_READING_ERROR) { hdc_temp_reading.raw = value; compare_and_update(&hdc_temp_reading); buf = hdc_temp_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%02d", value / 100, value % 100); } } if(hdc_hum_reading.publish) { value = hdc_1000_sensor.value(HDC_1000_SENSOR_TYPE_HUMIDITY); if(value != CC26XX_SENSOR_READING_ERROR) { hdc_hum_reading.raw = value; compare_and_update(&hdc_hum_reading); buf = hdc_hum_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%02d", value / 100, value % 100); } } ctimer_set(&hdc_timer, next, init_hdc_reading, NULL); } /*---------------------------------------------------------------------------*/ static void get_light_reading() { int value; char *buf; clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); value = opt_3001_sensor.value(0); if(value != CC26XX_SENSOR_READING_ERROR) { opt_reading.raw = value; compare_and_update(&opt_reading); buf = opt_reading.converted; memset(buf, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); snprintf(buf, CC26XX_WEB_DEMO_CONVERTED_LEN, "%d.%02d", value / 100, value % 100); } /* The OPT will turn itself off, so we don't need to call its DEACTIVATE */ ctimer_set(&opt_timer, next, init_light_reading, NULL); } /*---------------------------------------------------------------------------*/ static void get_mpu_reading() { clock_time_t next = SENSOR_READING_PERIOD + (random_rand() % SENSOR_READING_RANDOM); int raw; if(mpu_gyro_x_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_GYRO_X); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_gyro_x_reading.raw = raw; } } if(mpu_gyro_y_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_GYRO_Y); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_gyro_y_reading.raw = raw; } } if(mpu_gyro_z_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_GYRO_Z); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_gyro_z_reading.raw = raw; } } if(mpu_acc_x_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_ACC_X); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_acc_x_reading.raw = raw; } } if(mpu_acc_y_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_ACC_Y); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_acc_y_reading.raw = raw; } } if(mpu_acc_z_reading.publish) { raw = mpu_9250_sensor.value(MPU_9250_SENSOR_TYPE_ACC_Z); if(raw != CC26XX_SENSOR_READING_ERROR) { mpu_acc_z_reading.raw = raw; } } SENSORS_DEACTIVATE(mpu_9250_sensor); if(mpu_gyro_x_reading.publish) { compare_and_update(&mpu_gyro_x_reading); memset(mpu_gyro_x_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_gyro_x_reading.raw, mpu_gyro_x_reading.converted); } if(mpu_gyro_y_reading.publish) { compare_and_update(&mpu_gyro_y_reading); memset(mpu_gyro_y_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_gyro_y_reading.raw, mpu_gyro_y_reading.converted); } if(mpu_gyro_z_reading.publish) { compare_and_update(&mpu_gyro_z_reading); memset(mpu_gyro_z_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_gyro_z_reading.raw, mpu_gyro_z_reading.converted); } if(mpu_acc_x_reading.publish) { compare_and_update(&mpu_acc_x_reading); memset(mpu_acc_x_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_acc_x_reading.raw, mpu_acc_x_reading.converted); } if(mpu_acc_y_reading.publish) { compare_and_update(&mpu_acc_y_reading); memset(mpu_acc_y_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_acc_y_reading.raw, mpu_acc_y_reading.converted); } if(mpu_acc_z_reading.publish) { compare_and_update(&mpu_acc_z_reading); memset(mpu_acc_z_reading.converted, 0, CC26XX_WEB_DEMO_CONVERTED_LEN); print_mpu_reading(mpu_acc_z_reading.raw, mpu_acc_z_reading.converted); } /* We only use the single timer */ ctimer_set(&mpu_timer, next, init_mpu_reading, NULL); } /*---------------------------------------------------------------------------*/ static void init_tmp_reading(void *data) { if(tmp_amb_reading.publish || tmp_obj_reading.publish) { SENSORS_ACTIVATE(tmp_007_sensor); } else { ctimer_set(&tmp_timer, CLOCK_SECOND, init_tmp_reading, NULL); } } /*---------------------------------------------------------------------------*/ static void init_bmp_reading(void *data) { if(bmp_pres_reading.publish || bmp_temp_reading.publish) { SENSORS_ACTIVATE(bmp_280_sensor); } else { ctimer_set(&bmp_timer, CLOCK_SECOND, init_bmp_reading, NULL); } } /*---------------------------------------------------------------------------*/ static void init_hdc_reading(void *data) { if(hdc_hum_reading.publish || hdc_temp_reading.publish) { SENSORS_ACTIVATE(hdc_1000_sensor); } else { ctimer_set(&hdc_timer, CLOCK_SECOND, init_hdc_reading, NULL); } } /*---------------------------------------------------------------------------*/ static void init_light_reading(void *data) { if(opt_reading.publish) { SENSORS_ACTIVATE(opt_3001_sensor); } else { ctimer_set(&opt_timer, CLOCK_SECOND, init_light_reading, NULL); } } /*---------------------------------------------------------------------------*/ static void init_mpu_reading(void *data) { int readings_bitmap = 0; if(mpu_acc_x_reading.publish || mpu_acc_y_reading.publish || mpu_acc_z_reading.publish) { readings_bitmap |= MPU_9250_SENSOR_TYPE_ACC; } if(mpu_gyro_x_reading.publish || mpu_gyro_y_reading.publish || mpu_gyro_z_reading.publish) { readings_bitmap |= MPU_9250_SENSOR_TYPE_GYRO; } if(readings_bitmap) { mpu_9250_sensor.configure(SENSORS_ACTIVE, readings_bitmap); } else { ctimer_set(&mpu_timer, CLOCK_SECOND, init_mpu_reading, NULL); } } #endif /*---------------------------------------------------------------------------*/ static void init_sensor_readings(void) { /* * Make a first pass and get all initial sensor readings. This will also * trigger periodic value updates */ get_batmon_reading(NULL); #if BOARD_SENSORTAG init_bmp_reading(NULL); init_light_reading(NULL); init_hdc_reading(NULL); init_tmp_reading(NULL); init_mpu_reading(NULL); #endif /* BOARD_SENSORTAG */ return; } /*---------------------------------------------------------------------------*/ static void init_sensors(void) { list_add(sensor_list, &batmon_temp_reading); list_add(sensor_list, &batmon_volt_reading); SENSORS_ACTIVATE(batmon_sensor); #if BOARD_SENSORTAG list_add(sensor_list, &bmp_pres_reading); list_add(sensor_list, &bmp_temp_reading); list_add(sensor_list, &tmp_obj_reading); list_add(sensor_list, &tmp_amb_reading); list_add(sensor_list, &opt_reading); list_add(sensor_list, &hdc_hum_reading); list_add(sensor_list, &hdc_temp_reading); list_add(sensor_list, &mpu_acc_x_reading); list_add(sensor_list, &mpu_acc_y_reading); list_add(sensor_list, &mpu_acc_z_reading); list_add(sensor_list, &mpu_gyro_x_reading); list_add(sensor_list, &mpu_gyro_y_reading); list_add(sensor_list, &mpu_gyro_z_reading); SENSORS_ACTIVATE(reed_relay_sensor); #endif } /*---------------------------------------------------------------------------*/ PROCESS_THREAD(cc26xx_web_demo_process, ev, data) { PROCESS_BEGIN(); printf("CC26XX Web Demo Process\n"); init_sensors(); cc26xx_web_demo_publish_event = process_alloc_event(); cc26xx_web_demo_config_loaded_event = process_alloc_event(); cc26xx_web_demo_load_config_defaults = process_alloc_event(); /* Start all other (enabled) processes first */ process_start(&httpd_simple_process, NULL); #if CC26XX_WEB_DEMO_COAP_SERVER process_start(&coap_server_process, NULL); #endif #if CC26XX_WEB_DEMO_6LBR_CLIENT process_start(&cetic_6lbr_client_process, NULL); #endif #if CC26XX_WEB_DEMO_MQTT_CLIENT process_start(&mqtt_client_process, NULL); #endif #if CC26XX_WEB_DEMO_NET_UART process_start(&net_uart_process, NULL); #endif /* * Now that processes have set their own config default values, set our * own defaults and restore saved config from flash... */ cc26xx_web_demo_config.sensors_bitmap = 0xFFFFFFFF; /* all on by default */ cc26xx_web_demo_config.def_rt_ping_interval = CC26XX_WEB_DEMO_DEFAULT_RSSI_MEAS_INTERVAL; load_config(); /* * Notify all other processes (basically the ones in this demo) that the * configuration has been loaded from flash, in case they care */ process_post(PROCESS_BROADCAST, cc26xx_web_demo_config_loaded_event, NULL); init_sensor_readings(); httpd_simple_register_post_handler(&sensor_handler); httpd_simple_register_post_handler(&defaults_handler); #if CC26XX_WEB_DEMO_READ_PARENT_RSSI httpd_simple_register_post_handler(&ping_interval_handler); def_rt_rssi = 0x8000000; uip_icmp6_echo_reply_callback_add(&echo_reply_notification, echo_reply_handler); etimer_set(&echo_request_timer, CC26XX_WEB_DEMO_NET_CONNECT_PERIODIC); #endif etimer_set(&et, CC26XX_WEB_DEMO_NET_CONNECT_PERIODIC); /* * Update all sensor readings on a configurable sensors_event * (e.g a button press / or reed trigger) */ while(1) { if(ev == PROCESS_EVENT_TIMER && etimer_expired(&et)) { if(uip_ds6_get_global(ADDR_PREFERRED) == NULL) { leds_on(CC26XX_WEB_DEMO_STATUS_LED); ctimer_set(&ct, NO_NET_LED_DURATION, publish_led_off, NULL); etimer_set(&et, CC26XX_WEB_DEMO_NET_CONNECT_PERIODIC); } } #if CC26XX_WEB_DEMO_READ_PARENT_RSSI if(ev == PROCESS_EVENT_TIMER && etimer_expired(&echo_request_timer)) { if(uip_ds6_get_global(ADDR_PREFERRED) == NULL) { etimer_set(&echo_request_timer, CC26XX_WEB_DEMO_NET_CONNECT_PERIODIC); } else { ping_parent(); etimer_set(&echo_request_timer, cc26xx_web_demo_config.def_rt_ping_interval); } } #endif if(ev == sensors_event && data == CC26XX_WEB_DEMO_SENSOR_READING_TRIGGER) { if((CC26XX_WEB_DEMO_SENSOR_READING_TRIGGER)->value( BUTTON_SENSOR_VALUE_DURATION) > CLOCK_SECOND * 5) { printf("Restoring defaults!\n"); cc26xx_web_demo_restore_defaults(); } else { init_sensor_readings(); process_post(PROCESS_BROADCAST, cc26xx_web_demo_publish_event, NULL); } } else if(ev == httpd_simple_event_new_config) { save_config(); #if BOARD_SENSORTAG } else if(ev == sensors_event && data == &bmp_280_sensor) { get_bmp_reading(); } else if(ev == sensors_event && data == &opt_3001_sensor) { get_light_reading(); } else if(ev == sensors_event && data == &hdc_1000_sensor) { get_hdc_reading(); } else if(ev == sensors_event && data == &tmp_007_sensor) { get_tmp_reading(); } else if(ev == sensors_event && data == &mpu_9250_sensor) { get_mpu_reading(); #endif } PROCESS_YIELD(); } PROCESS_END(); } /*---------------------------------------------------------------------------*/ /** * @} */