/* * COPYRIGHT (C) 2018, Real-Thread Information Technology Ltd * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2014-07-31 aozima the first version * 2014-09-18 aozima update command & response. * 2017-07-28 armink fix auto reconnect feature */ #include #include #include #include #include #include "lwipopts.h" #define WIFI_DEBUG_ON // #define ETH_RX_DUMP // #define ETH_TX_DUMP #ifdef WIFI_DEBUG_ON #define WIFI_DEBUG rt_kprintf("[RW009] ");rt_kprintf //#define SPI_DEBUG rt_kprintf("[SPI] ");rt_kprintf #define SPI_DEBUG(...) #else #define WIFI_DEBUG(...) #define SPI_DEBUG(...) #endif /* #ifdef WIFI_DEBUG_ON */ /********************************* RW009 **************************************/ #include "spi_wifi_rw009.h" /* tools */ #define node_entry(node, type, member) \ ((type *)((char *)(node) - (unsigned long)(&((type *)0)->member))) #define member_offset(type, member) \ ((unsigned long)(&((type *)0)->member)) #define MAX_SPI_PACKET_SIZE (member_offset(struct spi_data_packet, buffer) + SPI_MAX_DATA_LEN) #define MAX_SPI_BUFFER_SIZE (sizeof(struct spi_response) + MAX_SPI_PACKET_SIZE) #define MAX_ADDR_LEN 6 struct rw009_wifi { /* inherit from ethernet device */ struct eth_device parent; struct rt_spi_device *rt_spi_device; /* interface address info. */ rt_uint8_t dev_addr[MAX_ADDR_LEN]; /* hw address */ rt_uint8_t active; struct rt_mempool spi_tx_mp; struct rt_mempool spi_rx_mp; struct rt_mailbox spi_tx_mb; struct rt_mailbox eth_rx_mb; int spi_tx_mb_pool[SPI_TX_POOL_SIZE + 1]; int eth_rx_mb_pool[SPI_RX_POOL_SIZE + 1]; int rw009_cmd_mb_pool[3]; struct rt_mailbox rw009_cmd_mb; uint32_t last_cmd; ALIGN(4) rt_uint8_t spi_tx_mempool[(sizeof(struct spi_data_packet) + 4) * SPI_TX_POOL_SIZE]; ALIGN(4) rt_uint8_t spi_rx_mempool[(sizeof(struct spi_data_packet) + 4) * SPI_RX_POOL_SIZE]; ALIGN(4) uint8_t spi_hw_rx_buffer[MAX_SPI_BUFFER_SIZE]; /* status for RW009 */ rw009_ap_info ap_info; /* AP info for conn. */ rw009_ap_info *ap_scan; /* AP list for SCAN. */ uint32_t ap_scan_count; }; static struct rw009_wifi rw009_wifi_device; static struct rt_event spi_wifi_data_event; static void resp_handler(struct rw009_wifi *wifi_device, struct rw009_resp *resp) { struct rw009_resp *resp_return = RT_NULL; switch (resp->cmd) { case RW009_CMD_INIT: WIFI_DEBUG("resp_handler RW009_CMD_INIT\n"); resp_return = (struct rw009_resp *)rt_malloc(member_offset(struct rw009_resp, resp) + sizeof(rw009_resp_init)); //TODO: if(resp_return == RT_NULL) break; memcpy(resp_return, resp, member_offset(struct rw009_resp, resp) + sizeof(rw009_resp_init)); WIFI_DEBUG("sn:%-*.*s\n", sizeof(resp->resp.init.sn), sizeof(resp->resp.init.sn), resp->resp.init.sn); WIFI_DEBUG("version:%-*.*s\n", sizeof(resp->resp.init.version), sizeof(resp->resp.init.version), resp->resp.init.version); rt_memcpy(wifi_device->dev_addr, resp->resp.init.mac, 6); break; case RW009_CMD_SCAN: if( resp->len == sizeof(rw009_ap_info) ) { rw009_ap_info *ap_scan = rt_realloc(wifi_device->ap_scan, sizeof(rw009_ap_info) * (wifi_device->ap_scan_count + 1) ); if(ap_scan != RT_NULL) { memcpy( &ap_scan[wifi_device->ap_scan_count], &resp->resp.ap_info, sizeof(rw009_ap_info) ); //dump if(1) { #ifdef WIFI_DEBUG_ON rw009_ap_info *ap_info = &resp->resp.ap_info; WIFI_DEBUG("SCAN SSID:%-32.32s\n", ap_info->ssid); WIFI_DEBUG("SCAN BSSID:%02X-%02X-%02X-%02X-%02X-%02X\n", ap_info->bssid[0], ap_info->bssid[1], ap_info->bssid[2], ap_info->bssid[3], ap_info->bssid[4], ap_info->bssid[5]); WIFI_DEBUG("SCAN rssi:%ddBm\n", ap_info->rssi); WIFI_DEBUG("SCAN rate:%dMbps\n", ap_info->max_data_rate/1000); WIFI_DEBUG("SCAN channel:%d\n", ap_info->channel); WIFI_DEBUG("SCAN security:%08X\n\n", ap_info->security); #endif /* WIFI_DEBUG_ON */ } wifi_device->ap_scan_count++; wifi_device->ap_scan = ap_scan; } return; /* wait for next ap */ } break; case RW009_CMD_JOIN: case RW009_CMD_EASY_JOIN: WIFI_DEBUG("resp_handler RW009_CMD_EASY_JOIN\n"); resp_return = (struct rw009_resp *)rt_malloc(member_offset(struct rw009_resp, resp) + sizeof(rw009_resp_join)); //TODO: if(resp_return == RT_NULL) break; memcpy(resp_return, resp, member_offset(struct rw009_resp, resp) + sizeof(rw009_resp_join)); if( resp->result == 0 ) { memcpy(&wifi_device->ap_info, &resp_return->resp.ap_info, sizeof(rw009_resp_join)); wifi_device->active = 1; eth_device_linkchange(&wifi_device->parent, RT_TRUE); } else { wifi_device->active = 1; eth_device_linkchange(&wifi_device->parent, RT_FALSE); WIFI_DEBUG("RW009_CMD_EASY_JOIN result: %d\n", resp->result ); } //dupm if(1) { #ifdef WIFI_DEBUG_ON rw009_ap_info *ap_info = &resp->resp.ap_info; WIFI_DEBUG("JOIN SSID:%-32.32s\n", ap_info->ssid); WIFI_DEBUG("JOIN BSSID:%02X-%02X-%02X-%02X-%02X-%02X\n", ap_info->bssid[0], ap_info->bssid[1], ap_info->bssid[2], ap_info->bssid[3], ap_info->bssid[4], ap_info->bssid[5]); WIFI_DEBUG("JOIN rssi:%ddBm\n", ap_info->rssi); WIFI_DEBUG("JOIN rate:%dMbps\n", ap_info->max_data_rate/1000); WIFI_DEBUG("JOIN channel:%d\n", ap_info->channel); WIFI_DEBUG("JOIN security:%08X\n\n", ap_info->security); #endif /* WIFI_DEBUG_ON */ } break; case RW009_CMD_RSSI: // TODO: client RSSI. { rw009_ap_info *ap_info = &resp->resp.ap_info; wifi_device->ap_info.rssi = ap_info->rssi; WIFI_DEBUG("current RSSI: %d\n", wifi_device->ap_info.rssi); } break; case RW009_CMD_SOFTAP: { if( resp->result == 0 ) { ; wifi_device->active = 1; eth_device_linkchange(&wifi_device->parent, RT_TRUE); } else { WIFI_DEBUG("RW009_CMD_EASY_JOIN result: %d\n", resp->result ); } } break; default: WIFI_DEBUG("resp_handler %d\n", resp->cmd); break; } if(resp->cmd == wifi_device->last_cmd) { rt_mb_send(&wifi_device->rw009_cmd_mb, (rt_uint32_t)resp_return); return; } else { rt_free(resp_return); } } static rt_err_t rw009_cmd(struct rw009_wifi *wifi_device, uint32_t cmd, void *args) { rt_err_t result = RT_EOK; rt_int32_t timeout = RW009_CMD_TIMEOUT; struct spi_data_packet *data_packet; struct rw009_cmd *wifi_cmd = RT_NULL; struct rw009_resp *resp = RT_NULL; wifi_device->last_cmd = cmd; data_packet = (struct spi_data_packet *)rt_mp_alloc(&wifi_device->spi_tx_mp, RT_WAITING_FOREVER); wifi_cmd = (struct rw009_cmd *)data_packet->buffer; wifi_cmd->cmd = cmd; wifi_cmd->len = 0; if( cmd == RW009_CMD_INIT ) { wifi_cmd->len = sizeof(rw009_cmd_init); } else if( cmd == RW009_CMD_SCAN ) { wifi_cmd->len = 0; timeout += RT_TICK_PER_SECOND*10; if(wifi_device->ap_scan) { rt_free(wifi_device->ap_scan); wifi_device->ap_scan = RT_NULL; wifi_device->ap_scan_count = 0; } } else if( cmd == RW009_CMD_JOIN ) { wifi_cmd->len = sizeof(rw009_cmd_join); } else if( cmd == RW009_CMD_EASY_JOIN ) { wifi_cmd->len = sizeof(rw009_cmd_easy_join); timeout += RT_TICK_PER_SECOND*5; } else if( cmd == RW009_CMD_RSSI ) { wifi_cmd->len = sizeof(rw009_cmd_rssi); } else if( cmd == RW009_CMD_SOFTAP ) { wifi_cmd->len = sizeof(rw009_cmd_softap); } else { WIFI_DEBUG("unkown RW009 CMD %d\n", cmd); result = -RT_ENOSYS; rt_mp_free(data_packet); data_packet = RT_NULL; } if(data_packet == RT_NULL) { goto _exit; } if(wifi_cmd->len) memcpy(&wifi_cmd->params, args, wifi_cmd->len); data_packet->data_type = data_type_cmd; data_packet->data_len = member_offset(struct rw009_cmd, params) + wifi_cmd->len; rt_mb_send(&wifi_device->spi_tx_mb, (rt_uint32_t)data_packet); rt_event_send(&spi_wifi_data_event, 1); result = rt_mb_recv(&wifi_device->rw009_cmd_mb, (rt_uint32_t *)&resp, timeout); if ( result != RT_EOK ) { WIFI_DEBUG("CMD %d error, resultL %d\n", cmd, result ); } if(resp != RT_NULL) result = resp->result; _exit: wifi_device->last_cmd = 0; if(resp) rt_free(resp); return result; } static rt_err_t spi_wifi_transfer(struct rw009_wifi *dev) { struct pbuf *p = RT_NULL; struct spi_cmd_request cmd; struct spi_response resp; rt_err_t result; const struct spi_data_packet *data_packet = RT_NULL; struct rw009_wifi *wifi_device = (struct rw009_wifi *)dev; struct rt_spi_device *rt_spi_device = wifi_device->rt_spi_device; spi_wifi_int_cmd(0); while (spi_wifi_is_busy()); SPI_DEBUG("sequence start!\n"); memset(&cmd, 0, sizeof(struct spi_cmd_request)); cmd.magic1 = CMD_MAGIC1; cmd.magic2 = CMD_MAGIC2; cmd.flag |= CMD_FLAG_MRDY; result = rt_mb_recv(&wifi_device->spi_tx_mb, (rt_uint32_t *)&data_packet, 0); if ((result == RT_EOK) && (data_packet != RT_NULL) && (data_packet->data_len > 0)) { cmd.M2S_len = data_packet->data_len + member_offset(struct spi_data_packet, buffer); //SPI_DEBUG("cmd.M2S_len = %d\n", cmd.M2S_len); } rt_spi_send(rt_spi_device, &cmd, sizeof(cmd)); while (spi_wifi_is_busy()); { struct rt_spi_message message; uint32_t max_data_len = 0; /* setup message */ message.send_buf = RT_NULL; message.recv_buf = &resp; message.length = sizeof(resp); message.cs_take = 1; message.cs_release = 0; rt_spi_take_bus(rt_spi_device); /* transfer message */ rt_spi_device->bus->ops->xfer(rt_spi_device, &message); if ((resp.magic1 != RESP_MAGIC1) || (resp.magic2 != RESP_MAGIC2)) { SPI_DEBUG("bad resp magic, abort!\n"); goto _bad_resp_magic; } if (resp.flag & RESP_FLAG_SRDY) { SPI_DEBUG("RESP_FLAG_SRDY\n"); max_data_len = cmd.M2S_len; } if (resp.S2M_len) { SPI_DEBUG("resp.S2M_len: %d\n", resp.S2M_len); if (resp.S2M_len > MAX_SPI_PACKET_SIZE) { SPI_DEBUG("resp.S2M_len %d > %d(MAX_SPI_PACKET_SIZE), drop!\n", resp.S2M_len, MAX_SPI_PACKET_SIZE); resp.S2M_len = 0;//drop } if (resp.S2M_len > max_data_len) max_data_len = resp.S2M_len; } if (max_data_len == 0) { SPI_DEBUG("no rx or tx data!\n"); } //SPI_DEBUG("max_data_len = %d\n", max_data_len); _bad_resp_magic: /* setup message */ message.send_buf = data_packet;//&tx_buffer; message.recv_buf = wifi_device->spi_hw_rx_buffer;//&rx_buffer; message.length = max_data_len; message.cs_take = 0; message.cs_release = 1; /* transfer message */ rt_spi_device->bus->ops->xfer(rt_spi_device, &message); rt_spi_release_bus(rt_spi_device); if (cmd.M2S_len && (resp.flag & RESP_FLAG_SRDY)) { rt_mp_free((void *)data_packet); } if ((resp.S2M_len) && (resp.S2M_len <= MAX_SPI_PACKET_SIZE)) { data_packet = (struct spi_data_packet *)wifi_device->spi_hw_rx_buffer; if (data_packet->data_type == data_type_eth_data) { if (wifi_device->active) { p = pbuf_alloc(PBUF_LINK, data_packet->data_len, PBUF_RAM); pbuf_take(p, (rt_uint8_t *)data_packet->buffer, data_packet->data_len); rt_mb_send(&wifi_device->eth_rx_mb, (rt_uint32_t)p); eth_device_ready((struct eth_device *)dev); } else { SPI_DEBUG("!active, RX drop.\n"); } } else if (data_packet->data_type == data_type_resp) { SPI_DEBUG("data_type_resp\n"); resp_handler(dev, (struct rw009_resp *)data_packet->buffer); } else { SPI_DEBUG("data_type: %d, %dbyte\n", data_packet->data_type, data_packet->data_len); } } } spi_wifi_int_cmd(1); SPI_DEBUG("sequence finish!\n\n"); if ((cmd.M2S_len == 0) && (resp.S2M_len == 0)) { return -RT_ERROR; } return RT_EOK; } #if defined(ETH_RX_DUMP) || defined(ETH_TX_DUMP) static void packet_dump(const char *msg, const struct pbuf *p) { const struct pbuf* q; rt_uint32_t i,j; rt_uint8_t *ptr = p->payload; rt_kprintf("%s %d byte\n", msg, p->tot_len); i=0; for(q=p; q != RT_NULL; q= q->next) { ptr = q->payload; for(j=0; jlen; j++) { if( (i%8) == 0 ) { rt_kprintf(" "); } if( (i%16) == 0 ) { rt_kprintf("\r\n"); } rt_kprintf("%02x ",*ptr); i++; ptr++; } } rt_kprintf("\n\n"); } #endif /* dump */ /********************************* RT-Thread Ethernet interface begin **************************************/ static rt_err_t rw009_wifi_init(rt_device_t dev) { return RT_EOK; } static rt_err_t rw009_wifi_open(rt_device_t dev, rt_uint16_t oflag) { return RT_EOK; } static rt_err_t rw009_wifi_close(rt_device_t dev) { return RT_EOK; } static rt_size_t rw009_wifi_read(rt_device_t dev, rt_off_t pos, void *buffer, rt_size_t size) { rt_set_errno(-RT_ENOSYS); return 0; } static rt_size_t rw009_wifi_write(rt_device_t dev, rt_off_t pos, const void *buffer, rt_size_t size) { rt_set_errno(-RT_ENOSYS); return 0; } static rt_err_t rw009_wifi_control(rt_device_t dev, int cmd, void *args) { struct rw009_wifi *wifi_device = (struct rw009_wifi *)dev; rt_err_t result = RT_EOK; if (cmd == NIOCTL_GADDR) { memcpy(args, wifi_device->dev_addr, 6); } else { result = rw009_cmd(wifi_device, cmd, args); } return result; } /* transmit packet. */ rt_err_t rw009_wifi_tx(rt_device_t dev, struct pbuf *p) { rt_err_t result = RT_EOK; struct spi_data_packet *data_packet; struct rw009_wifi *wifi_device = (struct rw009_wifi *)dev; if (!wifi_device->active) { WIFI_DEBUG("!active, TX drop!\n"); return RT_EOK; } /* get free tx buffer */ data_packet = (struct spi_data_packet *)rt_mp_alloc(&wifi_device->spi_tx_mp, RT_WAITING_FOREVER); if (data_packet != RT_NULL) { data_packet->data_type = data_type_eth_data; data_packet->data_len = p->tot_len; pbuf_copy_partial(p, data_packet->buffer, data_packet->data_len, 0); rt_mb_send(&wifi_device->spi_tx_mb, (rt_uint32_t)data_packet); rt_event_send(&spi_wifi_data_event, 1); } else return -RT_ERROR; #ifdef ETH_TX_DUMP packet_dump("TX dump", p); #endif /* ETH_TX_DUMP */ /* Return SUCCESS */ return result; } /* reception packet. */ struct pbuf *rw009_wifi_rx(rt_device_t dev) { struct pbuf *p = RT_NULL; struct rw009_wifi *wifi_device = (struct rw009_wifi *)dev; if (rt_mb_recv(&wifi_device->eth_rx_mb, (rt_uint32_t *)&p, 0) != RT_EOK) { return RT_NULL; } #ifdef ETH_RX_DUMP if(p) packet_dump("RX dump", p); #endif /* ETH_RX_DUMP */ return p; } /********************************* RT-Thread Ethernet interface end **************************************/ static void spi_wifi_data_thread_entry(void *parameter) { rt_uint32_t e; rt_err_t result; while (1) { /* receive first event */ if (rt_event_recv(&spi_wifi_data_event, 1, RT_EVENT_FLAG_AND | RT_EVENT_FLAG_CLEAR, RT_WAITING_FOREVER, &e) != RT_EOK) { continue; } result = spi_wifi_transfer(&rw009_wifi_device); if (result == RT_EOK) { rt_event_send(&spi_wifi_data_event, 1); } } } #ifdef RT_USING_DEVICE_OPS const static struct rt_device_ops rw009_ops = { rw009_wifi_init, rw009_wifi_open, rw009_wifi_close, rw009_wifi_read, rw009_wifi_write, rw009_wifi_control }; #endif rt_err_t rt_hw_wifi_init(const char *spi_device_name, wifi_mode_t mode) { /* align and struct size check. */ RT_ASSERT( (SPI_MAX_DATA_LEN & 0x03) == 0); RT_ASSERT( sizeof(struct rw009_resp) <= SPI_MAX_DATA_LEN); memset(&rw009_wifi_device, 0, sizeof(struct rw009_wifi)); rw009_wifi_device.rt_spi_device = (struct rt_spi_device *)rt_device_find(spi_device_name); if (rw009_wifi_device.rt_spi_device == RT_NULL) { SPI_DEBUG("spi device %s not found!\r\n", spi_device_name); return -RT_ENOSYS; } /* config spi */ { struct rt_spi_configuration cfg; cfg.data_width = 8; cfg.mode = RT_SPI_MODE_0 | RT_SPI_MSB; /* SPI Compatible: Mode 0. */ cfg.max_hz = 15 * 1000000; /* 10M */ rt_spi_configure(rw009_wifi_device.rt_spi_device, &cfg); } #ifdef RT_USING_DEVICE_OPS rw009_wifi_device.parent.parent.ops = &rw009_ops; #else rw009_wifi_device.parent.parent.init = rw009_wifi_init; rw009_wifi_device.parent.parent.open = rw009_wifi_open; rw009_wifi_device.parent.parent.close = rw009_wifi_close; rw009_wifi_device.parent.parent.read = rw009_wifi_read; rw009_wifi_device.parent.parent.write = rw009_wifi_write; rw009_wifi_device.parent.parent.control = rw009_wifi_control; #endif rw009_wifi_device.parent.parent.user_data = RT_NULL; rw009_wifi_device.parent.eth_rx = rw009_wifi_rx; rw009_wifi_device.parent.eth_tx = rw009_wifi_tx; rt_mp_init(&rw009_wifi_device.spi_tx_mp, "spi_tx", &rw009_wifi_device.spi_tx_mempool[0], sizeof(rw009_wifi_device.spi_tx_mempool), sizeof(struct spi_data_packet)); rt_mp_init(&rw009_wifi_device.spi_rx_mp, "spi_rx", &rw009_wifi_device.spi_rx_mempool[0], sizeof(rw009_wifi_device.spi_rx_mempool), sizeof(struct spi_data_packet)); rt_mb_init(&rw009_wifi_device.spi_tx_mb, "spi_tx", &rw009_wifi_device.spi_tx_mb_pool[0], SPI_TX_POOL_SIZE, RT_IPC_FLAG_PRIO); rt_mb_init(&rw009_wifi_device.eth_rx_mb, "eth_rx", &rw009_wifi_device.eth_rx_mb_pool[0], SPI_TX_POOL_SIZE, RT_IPC_FLAG_PRIO); rt_mb_init(&rw009_wifi_device.rw009_cmd_mb, "wifi_cmd", &rw009_wifi_device.rw009_cmd_mb_pool[0], sizeof(rw009_wifi_device.rw009_cmd_mb_pool) / 4, RT_IPC_FLAG_PRIO); rt_event_init(&spi_wifi_data_event, "wifi", RT_IPC_FLAG_FIFO); spi_wifi_hw_init(); { rt_thread_t tid; tid = rt_thread_create("wifi", spi_wifi_data_thread_entry, RT_NULL, 2048, RT_THREAD_PRIORITY_MAX - 2, 20); if (tid != RT_NULL) rt_thread_startup(tid); } /* init: get mac address */ { rw009_cmd_init init; init.mode = mode; WIFI_DEBUG("wifi_control RW009_CMD_INIT\n"); rw009_wifi_control((rt_device_t)&rw009_wifi_device, RW009_CMD_INIT, (void *)&init); // 0: firmware, 1: STA, 2:AP } /* register eth device */ eth_device_init(&(rw009_wifi_device.parent), "w0"); eth_device_linkchange(&rw009_wifi_device.parent, RT_FALSE); return RT_EOK; } void spi_wifi_isr(int vector) { /* enter interrupt */ rt_interrupt_enter(); SPI_DEBUG("spi_wifi_isr\n"); rt_event_send(&spi_wifi_data_event, 1); /* leave interrupt */ rt_interrupt_leave(); } /********************************* RW009 tools **************************************/ rt_err_t rw009_join(const char * SSID, const char * passwd) { rt_err_t result; rt_device_t wifi_device; rw009_cmd_easy_join easy_join; wifi_device = rt_device_find("w0"); if(wifi_device == RT_NULL) return -RT_ENOSYS; strncpy( easy_join.ssid, SSID, sizeof(easy_join.ssid) ); strncpy( easy_join.passwd, passwd, sizeof(easy_join.passwd) ); result = rt_device_control(wifi_device, RW009_CMD_EASY_JOIN, (void *)&easy_join); return result; } rt_err_t rw009_softap(const char * SSID, const char * passwd,uint32_t security,uint32_t channel) { rt_err_t result; rt_device_t wifi_device; rw009_cmd_softap softap; wifi_device = rt_device_find("w0"); if(wifi_device == RT_NULL) return -RT_ENOSYS; strncpy( softap.ssid, SSID, sizeof(softap.ssid) ); strncpy( softap.passwd, passwd, sizeof(softap.passwd) ); softap.security = security; softap.channel = channel; result = rt_device_control(wifi_device, RW009_CMD_SOFTAP, (void *)&softap); return result; } int32_t rw009_rssi(void) { rt_err_t result; struct rw009_wifi * wifi_device; wifi_device = (struct rw009_wifi *)rt_device_find("w0"); if(wifi_device == RT_NULL) return 0; if(wifi_device->active == 0) return 0; // SCAN result = rt_device_control((rt_device_t)wifi_device, RW009_CMD_RSSI, RT_NULL); if(result == RT_EOK) { return wifi_device->ap_info.rssi; } return 0; } #ifdef RT_USING_FINSH #include static rt_err_t rw009_scan(void) { rt_err_t result; struct rw009_wifi * wifi_device; wifi_device = (struct rw009_wifi *)rt_device_find("w0"); rt_kprintf("\nCMD RW009_CMD_SCAN \n"); result = rt_device_control((rt_device_t)wifi_device, RW009_CMD_SCAN, RT_NULL); rt_kprintf("CMD RW009_CMD_SCAN result:%d\n", result); if(result == RT_EOK) { uint32_t i; rw009_ap_info *ap_info; for(i=0; iap_scan_count; i++) { ap_info = &wifi_device->ap_scan[i]; rt_kprintf("AP #%02d SSID: %-32.32s\n", i, ap_info->ssid ); } } return result; } FINSH_FUNCTION_EXPORT(rw009_scan, SACN and list AP.); FINSH_FUNCTION_EXPORT(rw009_join, RW009 join to AP.); FINSH_FUNCTION_EXPORT(rw009_rssi, get RW009 current AP rssi.); #endif // RT_USING_FINSH