/* Iperf Example - iperf implementation This example code is in the Public Domain (or CC0 licensed, at your option.) / Unless required by applicable law or agreed to in writing, this software is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. */ #include #include #include #include #include #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "esp_check.h" #include "esp_log.h" #include "esp_rom_sys.h" #include "esp_timer.h" #include "iperf.h" #include "wifi_stats.h" typedef struct { iperf_cfg_t cfg; bool finish; uint32_t actual_len; uint32_t buffer_len; uint8_t *buffer; uint32_t sockfd; } iperf_ctrl_t; static bool s_iperf_is_running = false; static iperf_ctrl_t s_iperf_ctrl; static const char *TAG = "iperf"; inline static bool iperf_is_udp_client(void) { return ((s_iperf_ctrl.cfg.flag & IPERF_FLAG_CLIENT) && (s_iperf_ctrl.cfg.flag & IPERF_FLAG_UDP)); } inline static bool iperf_is_udp_server(void) { return ((s_iperf_ctrl.cfg.flag & IPERF_FLAG_SERVER) && (s_iperf_ctrl.cfg.flag & IPERF_FLAG_UDP)); } inline static bool iperf_is_tcp_client(void) { return ((s_iperf_ctrl.cfg.flag & IPERF_FLAG_CLIENT) && (s_iperf_ctrl.cfg.flag & IPERF_FLAG_TCP)); } inline static bool iperf_is_tcp_server(void) { return ((s_iperf_ctrl.cfg.flag & IPERF_FLAG_SERVER) && (s_iperf_ctrl.cfg.flag & IPERF_FLAG_TCP)); } static int iperf_get_socket_error_code(int sockfd) { return errno; } static int iperf_show_socket_error_reason(const char *str, int sockfd) { int err = errno; if (err != 0) { ESP_LOGW(TAG, "%s error, error code: %d, reason: %s", str, err, strerror(err)); } return err; } static void iperf_report_task(void *arg) { uint32_t interval = s_iperf_ctrl.cfg.interval; uint32_t time = s_iperf_ctrl.cfg.time; TickType_t delay_interval = (interval * 1000) / portTICK_PERIOD_MS; uint32_t cur = 0; double average = 0; double actual_bandwidth = 0; int k = 1; const double coefficient[3] = {1048576.0, 1024.0, 1.0}; const char unit[3] = {'M', 'K', '\0'}; iperf_output_format format = s_iperf_ctrl.cfg.format; printf("\n%16s %s\n", "Interval", "Bandwidth"); while (!s_iperf_ctrl.finish) { vTaskDelay(delay_interval); actual_bandwidth = (s_iperf_ctrl.actual_len / coefficient[format] * 8) / interval; printf("%4" PRIi32 "-%4" PRIi32 " sec %.2f %cbits/sec\n", cur, cur + interval, actual_bandwidth, unit[format]); cur += interval; average = ((average * (k - 1) / k) + (actual_bandwidth / k)); k++; s_iperf_ctrl.actual_len = 0; if (cur >= time) { printf("%4d-%4" PRIu32 " sec %.2f %cbits/sec\n", 0, time, average, unit[format]); break; } } s_iperf_ctrl.finish = true; vTaskDelete(NULL); } static esp_err_t iperf_start_report(void) { int ret; ret = xTaskCreatePinnedToCore(iperf_report_task, IPERF_REPORT_TASK_NAME, IPERF_REPORT_TASK_STACK, NULL, IPERF_REPORT_TASK_PRIORITY, NULL, portNUM_PROCESSORS - 1); if (ret != pdPASS) { ESP_LOGE(TAG, "create task %s failed", IPERF_REPORT_TASK_NAME); return ESP_FAIL; } return ESP_OK; } static void IRAM_ATTR socket_recv(int recv_socket, struct sockaddr_storage listen_addr, uint8_t type) { bool iperf_recv_start = true; uint8_t *buffer; int want_recv = 0; int actual_recv = 0; #ifdef CONFIG_LWIP_IPV6 socklen_t socklen = (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) ? sizeof(struct sockaddr_in6) : sizeof(struct sockaddr_in); #else socklen_t socklen = sizeof(struct sockaddr_in); #endif const char *error_log = (type == IPERF_TRANS_TYPE_TCP) ? "tcp server recv" : "udp server recv"; buffer = s_iperf_ctrl.buffer; want_recv = s_iperf_ctrl.buffer_len; while (!s_iperf_ctrl.finish) { actual_recv = recvfrom(recv_socket, buffer, want_recv, 0, (struct sockaddr *)&listen_addr, &socklen); if (actual_recv < 0) { iperf_show_socket_error_reason(error_log, recv_socket); s_iperf_ctrl.finish = true; break; } else { if (iperf_recv_start) { iperf_start_report(); iperf_recv_start = false; } s_iperf_ctrl.actual_len += actual_recv; } } } static void IRAM_ATTR socket_send(int send_socket, struct sockaddr_storage dest_addr, uint8_t type, int bw_lim) { uint8_t *buffer; uint32_t *pkt_id_p; uint32_t pkt_cnt = 0; int actual_send = 0; int want_send = 0; int period_us = -1; int delay_us = 0; int64_t prev_time = 0; int64_t send_time = 0; int err = 0; #ifdef CONFIG_LWIP_IPV6 const socklen_t socklen = (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) ? sizeof(struct sockaddr_in6) : sizeof(struct sockaddr_in); #else const socklen_t socklen = sizeof(struct sockaddr_in); #endif const char *error_log = (type == IPERF_TRANS_TYPE_TCP) ? "tcp client send" : "udp client send"; buffer = s_iperf_ctrl.buffer; pkt_id_p = (uint32_t *)s_iperf_ctrl.buffer; want_send = s_iperf_ctrl.buffer_len; iperf_start_report(); if (bw_lim > 0) { period_us = want_send * 8 / bw_lim; } while (!s_iperf_ctrl.finish) { if (period_us > 0) { send_time = esp_timer_get_time(); if (actual_send > 0){ // Last packet "send" was successful, check how much off the previous loop duration was to the ideal send period. Result will adjust the // next send delay. delay_us += period_us + (int32_t)(prev_time - send_time); } else { // Last packet "send" was not successful. Ideally we should try to catch up the whole previous loop duration (e.g. prev_time - send_time). // However, that's not possible since the most probable reason why the send was unsuccessful is the HW was not able to process the packet. // Hence, we cannot queue more packets with shorter (or no) delay to catch up since we are already at the performance edge. The best we // can do is to reset the send delay (which is probably big negative number) and start all over again. delay_us = 0; } prev_time = send_time; } *pkt_id_p = htonl(pkt_cnt++); // datagrams need to be sequentially numbered actual_send = sendto(send_socket, buffer, want_send, 0, (struct sockaddr *)&dest_addr, socklen); if (actual_send != want_send) { if (type == IPERF_TRANS_TYPE_UDP) { err = iperf_get_socket_error_code(send_socket); // ENOMEM is expected under heavy load => do not print it if (err != ENOMEM) { iperf_show_socket_error_reason(error_log, send_socket); } } else if (type == IPERF_TRANS_TYPE_TCP) { iperf_show_socket_error_reason(error_log, send_socket); break; } } else { s_iperf_ctrl.actual_len += actual_send; } // The send delay may be negative, it indicates we are trying to catch up and hence to not delay the loop at all. if (delay_us > 0) { esp_rom_delay_us(delay_us); } } } static esp_err_t iperf_run_tcp_server(void) { int listen_socket = -1; int client_socket = -1; int opt = 1; int err = 0; esp_err_t ret = ESP_OK; struct sockaddr_in remote_addr; struct timeval timeout = { 0 }; socklen_t addr_len = sizeof(struct sockaddr); struct sockaddr_storage listen_addr = { 0 }; struct sockaddr_in listen_addr4 = { 0 }; #ifdef CONFIG_LWIP_IPV6 struct sockaddr_in6 listen_addr6 = { 0 }; ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6 || s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #else ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Invalid AF types"); #endif #ifdef CONFIG_LWIP_IPV6 if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) { // The TCP server listen at the address "::", which means all addresses can be listened to. inet6_aton("::", &listen_addr6.sin6_addr); listen_addr6.sin6_family = AF_INET6; listen_addr6.sin6_port = htons(s_iperf_ctrl.cfg.sport); listen_socket = socket(AF_INET6, SOCK_STREAM, IPPROTO_IPV6); ESP_GOTO_ON_FALSE((listen_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); setsockopt(listen_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); setsockopt(listen_socket, IPPROTO_IPV6, IPV6_V6ONLY, &opt, sizeof(opt)); ESP_LOGI(TAG, "Socket created"); err = bind(listen_socket, (struct sockaddr *)&listen_addr6, sizeof(listen_addr6)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to bind: errno %d, IPPROTO: %d", errno, AF_INET6); err = listen(listen_socket, 1); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Error occurred during listen: errno %d", errno); memcpy(&listen_addr, &listen_addr6, sizeof(listen_addr6)); } else #endif if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4) { listen_addr4.sin_family = AF_INET; listen_addr4.sin_port = htons(s_iperf_ctrl.cfg.sport); listen_addr4.sin_addr.s_addr = s_iperf_ctrl.cfg.source_ip4; listen_socket = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP); ESP_GOTO_ON_FALSE((listen_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); setsockopt(listen_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); ESP_LOGI(TAG, "Socket created"); err = bind(listen_socket, (struct sockaddr *)&listen_addr4, sizeof(listen_addr4)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to bind: errno %d, IPPROTO: %d", errno, AF_INET); err = listen(listen_socket, 5); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Error occurred during listen: errno %d", errno); memcpy(&listen_addr, &listen_addr4, sizeof(listen_addr4)); } timeout.tv_sec = IPERF_SOCKET_RX_TIMEOUT; setsockopt(listen_socket, SOL_SOCKET, SO_RCVTIMEO, &timeout, sizeof(timeout)); client_socket = accept(listen_socket, (struct sockaddr *)&remote_addr, &addr_len); ESP_GOTO_ON_FALSE((client_socket >= 0), ESP_FAIL, exit, TAG, "Unable to accept connection: errno %d", errno); ESP_LOGI(TAG, "accept: %s,%d\n", inet_ntoa(remote_addr.sin_addr), htons(remote_addr.sin_port)); timeout.tv_sec = IPERF_SOCKET_RX_TIMEOUT; setsockopt(client_socket, SOL_SOCKET, SO_RCVTIMEO, &timeout, sizeof(timeout)); #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_clr_tx_statistics(0, NULL); #endif #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_clr_rx_statistics(0, NULL); #endif socket_recv(client_socket, listen_addr, IPERF_TRANS_TYPE_TCP); #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_get_rx_statistics(0, NULL); #endif #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_get_tx_statistics(0, NULL); #endif exit: if (client_socket != -1) { close(client_socket); } if (listen_socket != -1) { shutdown(listen_socket, 0); close(listen_socket); ESP_LOGI(TAG, "TCP Socket server is closed."); } s_iperf_ctrl.finish = true; return ret; } static esp_err_t iperf_run_tcp_client(void) { int client_socket = -1; int err = 0; esp_err_t ret = ESP_OK; struct sockaddr_storage dest_addr = { 0 }; struct sockaddr_in dest_addr4 = { 0 }; struct timeval timeout = { 0 }; #ifdef CONFIG_LWIP_IPV6 struct sockaddr_in6 dest_addr6 = { 0 }; ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6 || s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #else ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Invalid AF types"); #endif #ifdef CONFIG_LWIP_IPV6 if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) { client_socket = socket(AF_INET6, SOCK_STREAM, IPPROTO_IPV6); ESP_GOTO_ON_FALSE((client_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); inet6_aton(s_iperf_ctrl.cfg.destination_ip6, &dest_addr6.sin6_addr); dest_addr6.sin6_family = AF_INET6; dest_addr6.sin6_port = htons(s_iperf_ctrl.cfg.dport); err = connect(client_socket, (struct sockaddr *)&dest_addr6, sizeof(struct sockaddr_in6)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to connect: errno %d", errno); ESP_LOGI(TAG, "Successfully connected"); memcpy(&dest_addr, &dest_addr6, sizeof(dest_addr6)); } else #endif if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4) { client_socket = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP); ESP_GOTO_ON_FALSE((client_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); dest_addr4.sin_family = AF_INET; dest_addr4.sin_port = htons(s_iperf_ctrl.cfg.dport); dest_addr4.sin_addr.s_addr = s_iperf_ctrl.cfg.destination_ip4; err = connect(client_socket, (struct sockaddr *)&dest_addr4, sizeof(struct sockaddr_in)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to connect: errno %d", errno); ESP_LOGI(TAG, "Successfully connected"); memcpy(&dest_addr, &dest_addr4, sizeof(dest_addr4)); } timeout.tv_sec = IPERF_SOCKET_TCP_TX_TIMEOUT; setsockopt(client_socket, SOL_SOCKET, SO_SNDTIMEO, &timeout, sizeof(timeout)); #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_clr_rx_statistics(0, NULL); #endif #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_clr_tx_statistics(0, NULL); #endif socket_send(client_socket, dest_addr, IPERF_TRANS_TYPE_TCP, s_iperf_ctrl.cfg.bw_lim); #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_get_rx_statistics(0, NULL); #endif #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_get_tx_statistics(0, NULL); #endif exit: if (client_socket != -1) { shutdown(client_socket, 0); close(client_socket); ESP_LOGI(TAG, "TCP Socket client is closed."); } s_iperf_ctrl.finish = true; return ret; } static esp_err_t iperf_run_udp_server(void) { int listen_socket = -1; int opt = 1; int err = 0; esp_err_t ret = ESP_OK; struct timeval timeout = { 0 }; struct sockaddr_storage listen_addr = { 0 }; struct sockaddr_in listen_addr4 = { 0 }; #ifdef CONFIG_LWIP_IPV6 struct sockaddr_in6 listen_addr6 = { 0 }; ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6 || s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #else ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #endif #ifdef CONFIG_LWIP_IPV6 if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) { // The UDP server listen at the address "::", which means all addresses can be listened to. inet6_aton("::", &listen_addr6.sin6_addr); listen_addr6.sin6_family = AF_INET6; listen_addr6.sin6_port = htons(s_iperf_ctrl.cfg.sport); listen_socket = socket(AF_INET6, SOCK_DGRAM, IPPROTO_UDP); ESP_GOTO_ON_FALSE((listen_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); ESP_LOGI(TAG, "Socket created"); setsockopt(listen_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); err = bind(listen_socket, (struct sockaddr *)&listen_addr6, sizeof(struct sockaddr_in6)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to bind: errno %d", errno); ESP_LOGI(TAG, "Socket bound, port %" PRIu16, listen_addr6.sin6_port); memcpy(&listen_addr, &listen_addr6, sizeof(listen_addr6)); } else #endif if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4) { listen_addr4.sin_family = AF_INET; listen_addr4.sin_port = htons(s_iperf_ctrl.cfg.sport); listen_addr4.sin_addr.s_addr = s_iperf_ctrl.cfg.source_ip4; listen_socket = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); ESP_GOTO_ON_FALSE((listen_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); ESP_LOGI(TAG, "Socket created"); setsockopt(listen_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); err = bind(listen_socket, (struct sockaddr *)&listen_addr4, sizeof(struct sockaddr_in)); ESP_GOTO_ON_FALSE((err == 0), ESP_FAIL, exit, TAG, "Socket unable to bind: errno %d", errno); ESP_LOGI(TAG, "Socket bound, port %d", listen_addr4.sin_port); memcpy(&listen_addr, &listen_addr4, sizeof(listen_addr4)); } timeout.tv_sec = IPERF_SOCKET_RX_TIMEOUT; setsockopt(listen_socket, SOL_SOCKET, SO_RCVTIMEO, &timeout, sizeof(timeout)); #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_clr_rx_statistics(0, NULL); #endif socket_recv(listen_socket, listen_addr, IPERF_TRANS_TYPE_UDP); #if CONFIG_ESP_WIFI_ENABLE_WIFI_RX_STATS wifi_cmd_get_rx_statistics(0, NULL); #endif exit: if (listen_socket != -1) { shutdown(listen_socket, 0); close(listen_socket); } ESP_LOGI(TAG, "Udp socket server is closed."); s_iperf_ctrl.finish = true; return ret; } static esp_err_t iperf_run_udp_client(void) { int client_socket = -1; int opt = 1; esp_err_t ret = ESP_OK; struct sockaddr_storage dest_addr = { 0 }; struct sockaddr_in dest_addr4 = { 0 }; #ifdef CONFIG_LWIP_IPV6 struct sockaddr_in6 dest_addr6 = { 0 }; ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6 || s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #else ESP_GOTO_ON_FALSE((s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4), ESP_FAIL, exit, TAG, "Ivalid AF types"); #endif #ifdef CONFIG_LWIP_IPV6 if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) { inet6_aton(s_iperf_ctrl.cfg.destination_ip6, &dest_addr6.sin6_addr); dest_addr6.sin6_family = AF_INET6; dest_addr6.sin6_port = htons(s_iperf_ctrl.cfg.dport); client_socket = socket(AF_INET6, SOCK_DGRAM, IPPROTO_IPV6); ESP_GOTO_ON_FALSE((client_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); ESP_LOGI(TAG, "Socket created, sending to %s:%" PRIu16, s_iperf_ctrl.cfg.destination_ip6, s_iperf_ctrl.cfg.dport); setsockopt(client_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); memcpy(&dest_addr, &dest_addr6, sizeof(dest_addr6)); } else #endif if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV4) { dest_addr4.sin_family = AF_INET; dest_addr4.sin_port = htons(s_iperf_ctrl.cfg.dport); dest_addr4.sin_addr.s_addr = s_iperf_ctrl.cfg.destination_ip4; client_socket = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); ESP_GOTO_ON_FALSE((client_socket >= 0), ESP_FAIL, exit, TAG, "Unable to create socket: errno %d", errno); ESP_LOGI(TAG, "Socket created, sending to %d.%d.%d.%d:%" PRIu16, (uint16_t) s_iperf_ctrl.cfg.destination_ip4 & 0xFF, (uint16_t) (s_iperf_ctrl.cfg.destination_ip4 >> 8) & 0xFF, (uint16_t) (s_iperf_ctrl.cfg.destination_ip4 >> 16) & 0xFF, (uint16_t) (s_iperf_ctrl.cfg.destination_ip4 >> 24) & 0xFF, s_iperf_ctrl.cfg.dport); setsockopt(client_socket, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); memcpy(&dest_addr, &dest_addr4, sizeof(dest_addr4)); } #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_clr_tx_statistics(0, NULL); #endif socket_send(client_socket, dest_addr, IPERF_TRANS_TYPE_UDP, s_iperf_ctrl.cfg.bw_lim); #if CONFIG_ESP_WIFI_ENABLE_WIFI_TX_STATS wifi_cmd_get_tx_statistics(0, NULL); #endif exit: if (client_socket != -1) { shutdown(client_socket, 0); close(client_socket); } s_iperf_ctrl.finish = true; ESP_LOGI(TAG, "UDP Socket client is closed"); return ret; } static void iperf_task_traffic(void *arg) { if (iperf_is_udp_client()) { iperf_run_udp_client(); } else if (iperf_is_udp_server()) { iperf_run_udp_server(); } else if (iperf_is_tcp_client()) { iperf_run_tcp_client(); } else { iperf_run_tcp_server(); } if (s_iperf_ctrl.buffer) { free(s_iperf_ctrl.buffer); s_iperf_ctrl.buffer = NULL; } ESP_LOGI(TAG, "iperf exit"); s_iperf_is_running = false; vTaskDelete(NULL); } static uint32_t iperf_get_buffer_len(void) { if (iperf_is_udp_client()) { #ifdef CONFIG_LWIP_IPV6 if (s_iperf_ctrl.cfg.len_send_buf) { return s_iperf_ctrl.cfg.len_send_buf; } else if (s_iperf_ctrl.cfg.type == IPERF_IP_TYPE_IPV6) { return IPERF_DEFAULT_IPV6_UDP_TX_LEN; } else { return IPERF_DEFAULT_IPV4_UDP_TX_LEN; } #else return (s_iperf_ctrl.cfg.len_send_buf == 0 ? IPERF_DEFAULT_IPV4_UDP_TX_LEN : s_iperf_ctrl.cfg.len_send_buf); #endif } else if (iperf_is_udp_server()) { return IPERF_DEFAULT_UDP_RX_LEN; } else if (iperf_is_tcp_client()) { return (s_iperf_ctrl.cfg.len_send_buf == 0 ? IPERF_DEFAULT_TCP_TX_LEN : s_iperf_ctrl.cfg.len_send_buf); } else { return IPERF_DEFAULT_TCP_RX_LEN; } return 0; } esp_err_t iperf_start(iperf_cfg_t *cfg) { BaseType_t ret; if (!cfg) { return ESP_FAIL; } if (s_iperf_is_running) { ESP_LOGW(TAG, "iperf is running"); return ESP_FAIL; } memset(&s_iperf_ctrl, 0, sizeof(s_iperf_ctrl)); memcpy(&s_iperf_ctrl.cfg, cfg, sizeof(*cfg)); s_iperf_is_running = true; s_iperf_ctrl.finish = false; s_iperf_ctrl.buffer_len = iperf_get_buffer_len(); s_iperf_ctrl.buffer = (uint8_t *)malloc(s_iperf_ctrl.buffer_len); if (!s_iperf_ctrl.buffer) { ESP_LOGE(TAG, "create buffer: not enough memory"); return ESP_FAIL; } memset(s_iperf_ctrl.buffer, 0, s_iperf_ctrl.buffer_len); ret = xTaskCreatePinnedToCore(iperf_task_traffic, IPERF_TRAFFIC_TASK_NAME, IPERF_TRAFFIC_TASK_STACK, NULL, IPERF_TRAFFIC_TASK_PRIORITY, NULL, portNUM_PROCESSORS - 1); if (ret != pdPASS) { ESP_LOGE(TAG, "create task %s failed", IPERF_TRAFFIC_TASK_NAME); free(s_iperf_ctrl.buffer); s_iperf_ctrl.buffer = NULL; return ESP_FAIL; } return ESP_OK; } esp_err_t iperf_stop(void) { if (s_iperf_is_running) { s_iperf_ctrl.finish = true; } while (s_iperf_is_running) { ESP_LOGI(TAG, "wait current iperf to stop ..."); vTaskDelay(300 / portTICK_PERIOD_MS); } return ESP_OK; }