#include "FreeRTOS.h" #include "task.h" #include "wifi_conf.h" #include "wifi_ind.h" #include "sockets.h" #include #include #include #include "flash_api.h" #include #include "rom_wac_curve25519-donna.h" #include "gpio_api.h" #include "gpio_irq_api.h" #include "cJSON.h" #include "cloud_link.h" #include "wigadget.h" #include "shtc1.h" #if LWIP_SOCKET #define PORT 6866 #define MAX_BUFFER_SIZE 256 #define ENC_SIZE 64 #define CONTROL_TYPE 1 #define GPIO_SOFTAP_RESET_PIN PC_4 flash_t iot_flash; uint8_t aes_key[16]; static unsigned char tx_buffer[MAX_BUFFER_SIZE]; static unsigned char rx_buffer[MAX_BUFFER_SIZE]; extern struct netif xnetif[NET_IF_NUM]; #define DEBUG_IOT 1 #define IOT_LOG(level, fmt, ...) printf("\n\r[IOT %s] %s: " fmt "\n", level, __FUNCTION__, ##__VA_ARGS__) #if DEBUG_IOT == 2 #define IOT_DEBUG(fmt, ...) IOT_LOG("DEBUG", fmt, ##__VA_ARGS__) #else #define IOT_DEBUG(fmt, ...) #endif #if DEBUG_IOT #define IOT_ERROR(fmt, ...) IOT_LOG("ERROR", fmt, ##__VA_ARGS__) #else #define IOT_ERROR(fmt, ...) #endif void encrypt_data_aes(unsigned char *plaint_text, unsigned char *enc_data); void decrypt_data_aes(unsigned char *enc_data, unsigned char *dec_data, int data_len); #ifdef __GNUC__ #define GCC_VERSION (__GNUC__ * 10000 + __GNUC_MINOR__ * 100 + __GNUC_PATCHLEVEL__) #else #define GCC_VERSION 0 #endif /* Test for GCC < 5.4.0 */ #if GCC_VERSION > 50300 extern unsigned int _freertos_arc4random(void); #define wgg_arc4random _freertos_arc4random // or #define wgg_arc4random _ws_arc4random #else static unsigned int wgg_arc4random(void) { unsigned int res = xTaskGetTickCount(); static unsigned int seed = 0xDEADB00B; seed = ((seed & 0x007F00FF) << 7) ^ ((seed & 0x0F80FF00) >> 8) ^ // be sure to stir those low bits (res << 13) ^ (res >> 9); // using the clock too! return seed; } #endif static char *iot_itoa(int value) { char *val_str; int tmp = value, len = 1; while((tmp /= 10) > 0) len ++; val_str = (char *) malloc(len + 1); sprintf(val_str, "%d", value); return val_str; } void gen_json_data(char *i, char *j, unsigned char *json_data) { cJSON_Hooks memoryHook; memoryHook.malloc_fn = malloc; memoryHook.free_fn = free; cJSON_InitHooks(&memoryHook); memset(json_data, 0, ENC_SIZE); cJSON *IOTJSObject = NULL; char *data; if((IOTJSObject = cJSON_CreateObject()) != NULL) { cJSON_AddItemToObject(IOTJSObject, "TEM", cJSON_CreateString(i)); cJSON_AddItemToObject(IOTJSObject, "HUM", cJSON_CreateString(j)); data = cJSON_Print(IOTJSObject); memcpy(json_data, data, strlen(data)); cJSON_Delete(IOTJSObject); free(data); } } void encrypt_data_aes(unsigned char *plaint_text, unsigned char *enc_data) { unsigned char iv[16] = {0}; unsigned char* iv_bak = "AAAAAAAAAAAAAAAA"; aes_encrypt_ctx enc_ctx; memset(&enc_ctx, 0, sizeof(enc_ctx)); memset(iv, 0, sizeof(iv)); memcpy(iv, iv_bak, sizeof(iv)); memset(enc_data, 0, sizeof(enc_data)); aes_init(); aes_encrypt_key(aes_key, 16, &enc_ctx); aes_cbc_encrypt(plaint_text, enc_data, ENC_SIZE, iv, &enc_ctx); } void decrypt_data_aes(unsigned char *enc_data, unsigned char *dec_data, int data_len) { unsigned char iv[16] = {0}; unsigned char* iv_bak = "AAAAAAAAAAAAAAAA"; aes_decrypt_ctx dec_ctx; memset(&dec_ctx, 0, sizeof(dec_ctx)); memset(iv, 0, sizeof(iv)); memcpy(iv, iv_bak, sizeof(iv)); memset(dec_data, 0, sizeof(dec_data)); aes_init(); aes_decrypt_key(aes_key, 16, &dec_ctx); aes_cbc_decrypt(enc_data, dec_data, data_len, iv, &dec_ctx); IOT_DEBUG("Decrypt data: %s\r\n",dec_data); } void iotapp_platform_reset(void) { HAL_WRITE32(SYSTEM_CTRL_BASE, 0x14, 0x00000021); osDelay(100); HAL_WRITE32(0xE000ED00, 0x0C, (0x5FA << 16) | (HAL_READ32(0xE000ED00, 0x0C) & (7 << 8)) | (1 << 2)); while(1) osDelay(1000); } void iotapp_reset_irq_handler(uint32_t id, gpio_irq_event event) { printf("\n\r\n\r\n\r\n\r<<<<<>>>>>>\n\r\n\r\n\r\n\r"); flash_erase_sector(&iot_flash, FLASH_IOT_DATA); iotapp_platform_reset(); } int local_link(unsigned char *tx_data) { int sockfd, newsockfd; socklen_t client; struct sockaddr_in serv_addr, cli_addr; uint8_t rx_data[ENC_SIZE]; unsigned char enc_data[ENC_SIZE]; unsigned char dec_data[ENC_SIZE]; int ret = 0, opt = 1, k = 1, j; char *result = NULL, *backup = NULL; unsigned char *data = NULL; char *delims = ", "; sockfd = socket(AF_INET, SOCK_STREAM, 0); if (sockfd < 0) { IOT_ERROR("ERROR opening socket"); ret = -1; goto exit2; } if((setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, (const char *)&opt, sizeof(opt))) < 0){ IOT_ERROR("ERROR on setting socket option"); ret = -1; goto exit2; } memset((char *)&serv_addr, 0, sizeof(serv_addr)); serv_addr.sin_family = AF_INET; serv_addr.sin_addr.s_addr = INADDR_ANY; serv_addr.sin_port = htons(PORT); if (bind(sockfd, (struct sockaddr *)&serv_addr,sizeof(serv_addr)) < 0) { IOT_ERROR("ERROR on binding"); ret = -1; goto exit2; } if(listen(sockfd , 20) < 0){ IOT_ERROR("ERROR on listening"); ret = -1; goto exit2; } client = sizeof(cli_addr); if((newsockfd = accept(sockfd,(struct sockaddr *) &cli_addr,&client)) < 0){ IOT_ERROR("ERROR on accept"); ret = -1; goto exit; } if ((ret = read(newsockfd,rx_buffer,sizeof(rx_buffer))) < 0){ IOT_ERROR("ERROR reading from socket"); ret = -1; goto exit; } IOT_DEBUG("cmd received: %s, length: %d\r\n",rx_buffer, ret); //Changing received data to string if (!strncmp(rx_buffer, "[", strlen("["))){ data = rx_buffer + strlen("["); for(j = 1; j < 5; j++){ if (data[ret - j] == ']') data[ret -j] = '\0'; } } else strcpy(data, rx_buffer); memset(rx_data, 0, sizeof(rx_data)); result = strtok_r(data, delims, &backup); rx_data[0]=(uint8_t)atoi(result); while((result = strtok_r(NULL, delims, &backup)) != NULL) rx_data[k++]=(uint8_t)atoi(result); memset(dec_data, 0, sizeof(dec_data)); //Decrpyt the received data decrypt_data_aes(rx_data, dec_data, 16); if(strncmp(dec_data, "request", strlen("request")) == 0){ //Encrypt the sending data memset(enc_data, 0, strlen(enc_data)); encrypt_data_aes(tx_data, enc_data); //Changing encrpyt data to JAVA type string for (j = 0; j < ENC_SIZE; j++){ char *temp; temp = iot_itoa(enc_data[j]); if(j == 0) strcpy(tx_buffer, "["); strcat(tx_buffer,temp); if (j == (ENC_SIZE - 1)) strcat(tx_buffer,"]"); else strcat(tx_buffer,","); free(temp); temp = NULL; } IOT_DEBUG("Data reply to APP: %s\r\nLength of data: %d\r\n", tx_buffer, strlen(tx_buffer)); if ((ret = write(newsockfd,tx_buffer,strlen(tx_buffer))) < 0){ IOT_ERROR("ERROR writing to socket"); ret = -1; goto exit; } else IOT_DEBUG("Sending %d bytes data OK!\r\n", ret); } else if(strncmp(dec_data, "remove", strlen("remove")) == 0){ printf("\n\r\n\r\n\r\n\r<<<<<>>>>>>\n\r\n\r\n\r\n\r"); flash_erase_sector(&iot_flash, FLASH_IOT_DATA); write(newsockfd,"Remove OK",strlen("Remove OK")); close(newsockfd); close(sockfd); iotapp_platform_reset(); } else{ IOT_ERROR("ERROR wrong KEY or wrong request!"); write(newsockfd,"The KEY or the request is not correct!",strlen("The KEY or the request is not correct!")); ret = -1; goto exit; } exit: if(close(newsockfd) != 0) goto exit; exit2: if(close(sockfd) != 0) goto exit2; return ret; } static void local_link_task(void *param) { unsigned char data[ENC_SIZE] = {0}; vTaskDelay(1000); char i[16], j[16]; float temperature = 1.123f; float humidity = 2.456f; int ret = 0; while(1){ memset(i, 0, 16); memset(j, 0, 16); #if PSEUDO_DATA sprintf(i,"%.2f", temperature++); sprintf(j, "%.2f", humidity++); if(temperature > 60) temperature = 1.123f; if(humidity > 98) humidity = 2.456f; #else ret = SHTC_GetTempAndHumi(&temperature, &humidity); sprintf(i,"%.2f", temperature); sprintf(j, "%.2f", humidity); #endif if(ret < 0) printf("\r\n\r\n<-----LOCAL LINK FAILED!!(get infor failed)\r\n\r\n"); else{ printf("\r\n\r\n----->START LOCAL LINKING\r\n\r\n"); gen_json_data(i, j, data); printf("Sending data : %s\r\n", data); if (local_link(data) < 0) printf("\r\n\r\n<-----LOCAL LINK FAILED!!\r\n\r\n"); else printf("\r\n\r\n<-----LOCAL LINK OK!!\r\n\r\n"); vTaskDelay(1000); } } } void start_local_link(void) { if(xTaskCreate(local_link_task, ((const char*)"local_link_task"), 5376, NULL, tskIDLE_PRIORITY + 4, NULL) != pdPASS) printf("\n\r%s xTaskCreate failed", __FUNCTION__); } int pair_device(unsigned char *tx_buffer, unsigned char *rx_buffer, int handshake) { int sockfd, newsockfd; socklen_t clilen; struct sockaddr_in serv_addr, cli_addr; int ret = 0; int opt = 1; sockfd = socket(AF_INET, SOCK_STREAM, 0); if (sockfd < 0) { IOT_ERROR("ERROR opening socket"); ret = -1; goto exit; } if((setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, (const char *)&opt, sizeof(opt))) < 0){ IOT_ERROR("ERROR on setting socket option"); ret = -1; goto exit; } memset((char *)&serv_addr, 0, sizeof(serv_addr)); serv_addr.sin_family = AF_INET; serv_addr.sin_len = sizeof(serv_addr); serv_addr.sin_addr.s_addr = INADDR_ANY; serv_addr.sin_port = htons(PORT); if ((bind(sockfd, (struct sockaddr *)&serv_addr, sizeof(serv_addr))) < 0) { IOT_ERROR("ERROR on binding"); ret = -1; goto exit; } if ((listen(sockfd, 5)) < 0){ IOT_ERROR("ERROR on listening tcp server socket fd"); ret = -1; goto exit; } clilen = sizeof(cli_addr); newsockfd = accept(sockfd, (struct sockaddr *) &cli_addr, (socklen_t*)&clilen); if (newsockfd < 0) { IOT_ERROR("ERROR on accept"); ret = -1; goto exit2; } ret = read(newsockfd, rx_buffer, MAX_BUFFER_SIZE); if (ret <= 0){ IOT_ERROR("ERROR reading from socket"); ret = -1; goto exit2; } IOT_DEBUG("Request received: %s, byte: %d\r\n",rx_buffer, ret); if(handshake == 1){ if(strncmp(rx_buffer,"PAIR", strlen("PAIR")) != 0){ write(newsockfd, "ERROR", strlen("ERROR")); IOT_ERROR("ERROR on first handshake!"); ret = -1; goto exit2; } } else if(handshake == 2){ if((rx_buffer == NULL) ||(strlen(rx_buffer) < 32)){ write(newsockfd, "ERROR", strlen("ERROR")); IOT_ERROR("ERROR on second handshake!"); ret = -1; goto exit2; } } else if(handshake == 3){ unsigned char account[64]; unsigned char enc_acc[64]; char *result = NULL, *backup = NULL; unsigned char *data = NULL; char *delims = ", "; int j, k = 1; if (!strncmp(rx_buffer, "[", strlen("["))){ data = rx_buffer + strlen("["); for(j = 1; j < 5; j++){ if (data[ret - j] == ']') data[ret -j] = '\0'; } } else strcpy(data, rx_buffer); memset(enc_acc, 0, sizeof(enc_acc)); result = strtok_r(data, delims, &backup); enc_acc[0]=(uint8_t)atoi(result); while((result = strtok_r(NULL, delims, &backup)) != NULL) enc_acc[k++]=(uint8_t)atoi(result); IOT_DEBUG("The value of k: %d", k); memset(account, 0, sizeof(account)); decrypt_data_aes(enc_acc, account, k); if((strncmp(account,"https://", strlen("https://"))) != 0){ write(newsockfd, "ERROR", strlen("ERROR")); IOT_ERROR("ERROR on third handshake!"); ret = -1; goto exit2; } else{ IOT_DEBUG("The received Firebase URL:%s", account); memset(rx_buffer, 0, strlen(rx_buffer)); memcpy(rx_buffer, (account+strlen("https://")), (strlen(account) + strlen("https://"))); } } ret = write(newsockfd, tx_buffer, strlen(tx_buffer)); IOT_DEBUG("Data send: %s\r\n",tx_buffer); if (ret < 0){ IOT_ERROR("ERROR writing to socket"); } exit: if(close(newsockfd) != 0) goto exit; exit2: if(close(sockfd) != 0) goto exit2; return ret; } static void pair_device_task(void) { int i, j, k, HANDSHAKE; uint8_t PAIR_STATE[1] = {0}; if(CONTROL_TYPE == 1){ printf("\r\n\r\n<<<<<>>>>>\r\n\r\n"); HANDSHAKE = 3; } else{ printf("\r\n\r\n<<<<<>>>>>\r\n\r\n"); HANDSHAKE = 2; } printf("\r\n\r\n=========>PAIR_STATE = 0 Start to pair\r\n\r\n"); for(i = 0; i < HANDSHAKE; i++){ static const uint8_t basepoint[32] = {9}; uint8_t mysecret[32]; uint8_t mypublic[32]; uint8_t theirpublic[32] = {0}; uint8_t shared_key[32]; //First handshake if(i == 0){ printf("\r\n\r\n===>Start the first handshake\r\n\r\n"); memset(tx_buffer, 0, sizeof(tx_buffer)); memset(rx_buffer, 0, sizeof(rx_buffer)); for(j = 0; j < 32; j ++) mysecret[j] = (uint8_t) wgg_arc4random(); mysecret[j] = '\0'; curve25519_donna(mypublic, mysecret, basepoint); for (j = 0; j < 32; j++){ char *temp; temp = iot_itoa(mypublic[j]); if(j == 0) strcpy(tx_buffer, "["); strcat(tx_buffer,temp); if (j == 31) strcat(tx_buffer,"]"); else strcat(tx_buffer,","); free(temp); temp = NULL; } if(pair_device(tx_buffer, rx_buffer, 1) >= 0) printf("\r\n\r\n<===First handshake OK!!\r\n\r\n"); else{ i--; printf("\r\n\r\n<===First handshake FAILED!!\r\n\r\n"); } } //Second handshake if(i == 1){ printf("\r\n\r\n=====>Start the second handshake\r\n\r\n"); vTaskDelay(200); memset(tx_buffer, 0, sizeof(tx_buffer)); if(CONTROL_TYPE == 1) memcpy(tx_buffer, "FIREBASE URL", sizeof("FIREBASE URL")); else memcpy(tx_buffer, "PAIR OK", sizeof("PAIR OK")); memset(rx_buffer, 0, sizeof(rx_buffer)); if(pair_device(tx_buffer, rx_buffer, 2) >= 0){ char *result = NULL, *backup = NULL; unsigned char *data = NULL; char *delims = ", "; k = 1; if (!strncmp(rx_buffer, "[", strlen("["))){ data = rx_buffer + strlen("["); int len; len = strlen(data); for(j = 1; j < 5; j++){ if (data[len - j] == ']') data[len -j] = '\0'; } } else strcpy(data, rx_buffer); memset(theirpublic, 0, sizeof(theirpublic)); result = strtok_r(data, delims, &backup); theirpublic[0]=(uint8_t)atoi(result); while((result = strtok_r(NULL, delims, &backup)) != NULL) theirpublic[k++] = (uint8_t)atoi(result); curve25519_donna(shared_key, mysecret, theirpublic); for(j = 0; j < 16; j ++) aes_key[j] = shared_key[j]; //Store the KEY in FLASH if(CONTROL_TYPE == 0){ PAIR_STATE[0] = 1; uint8_t data[33]; memset(data, 0, 33); memcpy(data, PAIR_STATE, 1); memcpy(data+1, shared_key, 32); flash_erase_sector(&iot_flash, FLASH_IOT_DATA); flash_stream_write(&iot_flash, FLASH_IOT_DATA, 33, (uint8_t *) data); IOT_DEBUG("PAIR_STATE: %d\r\n", PAIR_STATE[0]); } printf("\r\n\r\n<=====Second handshake OK!!\r\n\r\n"); } else{ i = i - 2; printf("\r\n\r\n<=====Second handshake FAILED!!\r\n\r\n"); } } //Third handshake if(i == 2){ printf("\r\n\r\n=======>Start the third handshake\r\n\r\n"); vTaskDelay(200); memset(tx_buffer, 0, sizeof(tx_buffer)); memcpy(tx_buffer, "PAIR OK", sizeof("PAIR OK")); memset(rx_buffer, 0, sizeof(rx_buffer)); if(pair_device(tx_buffer, rx_buffer, 3) >= 0){ IOT_DEBUG("rx_buffer: %s, sizeof rx_buffer:%d\r\n", rx_buffer, sizeof(rx_buffer)); PAIR_STATE[0] = 1; uint8_t data[97]; memset(data, 0, 97); memcpy(data, PAIR_STATE, 1); memcpy(data+1, shared_key, 32); memcpy(data+33, rx_buffer, 64); flash_erase_sector(&iot_flash, FLASH_IOT_DATA); flash_stream_write(&iot_flash, FLASH_IOT_DATA, 97, (uint8_t *) data); IOT_DEBUG("PAIR_STATE: %d\r\n", PAIR_STATE[0]); printf("\r\n\r\n<=======Third handshake OK!!\r\n\r\n"); } else{ i = i - 3; printf("\r\n\r\n<=======Third handshake FAILED!!\r\n\r\n"); } } } printf("\r\n\r\n<=========Pairing OK!!\r\n\r\n"); } static void mdns_task(void *param) { DNSServiceRef dnsServiceRef = NULL; TXTRecordRef txtRecord; unsigned char txt_buf[128]; uint8_t *mac, *ip; int j, ret = 0; uint8_t *flash_data; uint8_t PAIR_STATE[1] = {0}; static unsigned char MAC_ADD[21]; static unsigned char IP[16]; static unsigned char port[6]; uint16_t shtc1_id; // Delay to wait for IP by DHCP and get the information of IP and MAC printf("\n\r\n\r\n\r\n\r<<<<<>>>>>>\n\r\n\r\n\r\n\r"); vTaskDelay(20000); ip = LwIP_GetIP(&xnetif[0]); mac = LwIP_GetMAC(&xnetif[0]); sprintf(MAC_ADD, "%02x%02x%02x%02x%02x%02x", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); sprintf(IP, "%d.%d.%d.%d", ip[0], ip[1], ip[2], ip[3]); sprintf(port, "%d", PORT); IOT_DEBUG("MAC => %s\r\n", MAC_ADD) ; IOT_DEBUG("IP => %s\r\n", IP); IOT_DEBUG("PORT => %s\r\n", port); //Get the value of PAIR_STATE and the AES key in flash flash_data = (uint8_t *)malloc(33); flash_stream_read(&iot_flash, FLASH_IOT_DATA, 33, (uint8_t *)flash_data); memcpy(PAIR_STATE, flash_data, 1); if(PAIR_STATE[0] != 0x1) PAIR_STATE[0] = 0; else{ for(j = 0;j < 16; j++){ aes_key[j] = flash_data[j+1]; } } free(flash_data); IOT_DEBUG("PAIR_STATE now: %d\r\n", PAIR_STATE[0]); IOT_DEBUG("=>mDNS Init\r\n"); if(mDNSResponderInit() == 0) { printf("\r\n\r\n========>Start to register mDNS service\r\n\r\n"); //The device not paired before if(PAIR_STATE[0] == 0){ TXTRecordCreate(&txtRecord, sizeof(txt_buf), txt_buf); TXTRecordSetValue(&txtRecord, "IP", strlen(IP), IP); TXTRecordSetValue(&txtRecord, "PORT", strlen(port), port); TXTRecordSetValue(&txtRecord, "MAC_ADDR", strlen(MAC_ADD), MAC_ADD); TXTRecordSetValue(&txtRecord, "PAIR_STATE", strlen("0"), "0"); TXTRecordSetValue(&txtRecord, "SERVICE_NAME", strlen("ht_sensor"), "ht_sensor"); if(CONTROL_TYPE == 1) TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("1"), "1"); else TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("0"), "0"); dnsServiceRef = mDNSRegisterService("ht_sensor", "_Ameba._tcp", "local", PORT, &txtRecord); TXTRecordDeallocate(&txtRecord); printf("\r\n\r\n<========Registering mDNS service OK!!\r\n\r\n"); pair_device_task(); } //The device was paired else if(PAIR_STATE[0] == 0x1){ TXTRecordCreate(&txtRecord, sizeof(txt_buf), txt_buf); TXTRecordSetValue(&txtRecord, "IP", strlen(ip), ip); TXTRecordSetValue(&txtRecord, "PORT", strlen(port), port); TXTRecordSetValue(&txtRecord, "MAC_ADDR", strlen(MAC_ADD), MAC_ADD); TXTRecordSetValue(&txtRecord, "PAIR_STATE", strlen("1"), "1"); TXTRecordSetValue(&txtRecord, "SERVICE_NAME", strlen("ht_sensor"), "ht_sensor"); if(CONTROL_TYPE == 1) TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("1"), "1"); else TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("0"), "0"); dnsServiceRef = mDNSRegisterService("ht_sensor", "_Ameba._tcp", "local", PORT, &txtRecord); TXTRecordDeallocate(&txtRecord); printf("\r\n\r\n<========Registering mDNS service OK!! PAIR_STATE = 1\r\n\r\n"); } #if PSEUDO_DATA printf("\r\n\r\n========>Using the speudo data\r\n\r\n"); if(CONTROL_TYPE == 1) start_cloud_link(); start_local_link(); #else //Init the shtc1 sensor printf("\r\n\r\n========>Init the temperature and humidity sensor\r\n\r\n"); ret = SHTC_Init(&shtc1_id); if ( ret == NO_ERROR ){ printf("\r\n\r\n<========Senser init OK! ID = 0x%x \r\n\r\n", shtc1_id); if(CONTROL_TYPE == 1) start_cloud_link(); start_local_link(); } else { printf("\r\n\r\n<========Senser init FAILED! ID = 0x%x \r\n\r\n", shtc1_id); ret = -1; } #endif } else ret = -1; if(ret == 0){ while(1){ IOT_DEBUG("Update the mDNS textrecord!\r\n"); TXTRecordCreate(&txtRecord, sizeof(txt_buf), txt_buf); TXTRecordSetValue(&txtRecord, "IP", strlen(IP), IP); TXTRecordSetValue(&txtRecord, "PORT", strlen(port), port); TXTRecordSetValue(&txtRecord, "MAC_ADDR", strlen(MAC_ADD), MAC_ADD); TXTRecordSetValue(&txtRecord, "PAIR_STATE", strlen("1"), "1"); if(CONTROL_TYPE == 1) TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("1"), "1"); else TXTRecordSetValue(&txtRecord, "CONTROL_TYPE", strlen("0"), "0"); TXTRecordSetValue(&txtRecord, "SERVICE_NAME", strlen("ht_sensor"), "ht_sensor"); mDNSUpdateService(dnsServiceRef, &txtRecord, 0); TXTRecordDeallocate(&txtRecord); vTaskDelay(2*60*1000); } } else{ if(dnsServiceRef) mDNSDeregisterService(dnsServiceRef); IOT_DEBUG("<=mDNS Deinit\r\n\r\n"); mDNSResponderDeinit(); } } void example_wigadget(void) { if(xTaskCreate(mdns_task, ((const char*)"mdns_task"), 3072, NULL, tskIDLE_PRIORITY + 1, NULL) != pdPASS) printf("\n\r%s xTaskCreate failed", __FUNCTION__); gpio_t gpio_softap_reset_button; gpio_irq_t gpioirq_softap_reset_button; gpio_irq_init(&gpioirq_softap_reset_button, GPIO_SOFTAP_RESET_PIN, iotapp_reset_irq_handler, (uint32_t)(&gpio_softap_reset_button)); gpio_irq_set(&gpioirq_softap_reset_button, IRQ_FALL, 1); gpio_irq_enable(&gpioirq_softap_reset_button); } #endif // LWIP_SOCKET