https://devzone.nordicsemi.com/f/nordic-q-a/93614/add-coded-phy-feature-in-central-uart-ncsHI DevZone, I am trying to add the coded phy features in Peripheral_Uart and Central_Uart examples of NCS. I hope Coded phy features are successfully added into Peripheral_Uart because i am seeing the Coded Phy LE packet on Wireshark.And got the followingen-USTelligent Community 13Wed, 04 Jun 2025 13:22:48 GMThttps://devzone.nordicsemi.com/thread/538072?ContentTypeID=1Wed, 04 Jun 2025 13:22:48 GMT137ad170-7792-4731-bb38-c0d22fbe4515:83e69018-5758-4e35-80c3-719023ce10ceSimonr<p>Please open a separate ticket with a thorough question on what you&#39;re looking for. As you said this ticket is 3 years old at this point, so it&#39;s better to start anew here.</p> <p>Best regards,</p> <p>Simon</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/537936?ContentTypeID=1Tue, 03 Jun 2025 18:26:42 GMT137ad170-7792-4731-bb38-c0d22fbe4515:4706f0a6-b38d-4b27-af39-fa36d9aa538bAvi<p>This discussion is 3 years ago, but till now I still couldn&#39;t find any working example for a multi nus central with coded phy. Is it supported by Zephyr?</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/396047?ContentTypeID=1Wed, 16 Nov 2022 15:23:55 GMT137ad170-7792-4731-bb38-c0d22fbe4515:42166851-7a6f-4f04-b4d0-e6862e72d7d6Muhammad Usman<p>thanks</p> <p>BR<br />Muhammad Usman</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395992?ContentTypeID=1Wed, 16 Nov 2022 13:25:05 GMT137ad170-7792-4731-bb38-c0d22fbe4515:7c0efd9b-d420-460f-acea-6c3fd6860689Joakim Jakobsen<p>I&#39;m not sure. I&#39;ll test the example and see if I can reproduce and figure out why that is.</p> <p>For now you can use the workaround by filtering for device name.</p> <p>&nbsp;Br, <br />Joakim</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395799?ContentTypeID=1Tue, 15 Nov 2022 13:26:19 GMT137ad170-7792-4731-bb38-c0d22fbe4515:6a1e5502-b365-4951-afdc-a99dfa5377d0Muhammad Usman<p>&nbsp;Hi Joakim!</p> <p>&nbsp;Thank you for the response!</p> <p>&nbsp;Can you please answer the question in my previous post?</p> <p><span>&quot;Can you please help me that why we can&#39;t connect with the UUID filter and by NUS_Service?&quot;</span></p> <p><span>&nbsp;Thanks &amp; Regards,</span></p> <p><span>&nbsp; Muhammad Usman</span></p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395709?ContentTypeID=1Tue, 15 Nov 2022 08:50:44 GMT137ad170-7792-4731-bb38-c0d22fbe4515:2867fd77-c519-4520-92ea-0dc232484591Joakim Jakobsen<p>Thank you very much for sharing the solution.&nbsp;</p> <p>Hopefully others can benefit from this.</p> <p></p> <p>Br,&nbsp;<br />Joakim</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395616?ContentTypeID=1Mon, 14 Nov 2022 15:47:50 GMT137ad170-7792-4731-bb38-c0d22fbe4515:4edf1472-636f-44c1-9ac8-4e0aa0de0b35Muhammad Usman<p>Hi&nbsp;<a href="https://devzone.nordicsemi.com/members/joakim_2d00_jakobsen">Joakim Jakobsen</a>&nbsp;!</p> <p></p> <p>Today, I tried to connect the&nbsp;Peripheral_Uart&nbsp; and Central_Uart examples of NCS by adding the coded PHY features. They were not connecting so I read a post on devzone</p> <p>&nbsp;<a href="https://devzone.nordicsemi.com/f/nordic-q-a/78890/help-to-set-uart-example-to-work-only-on-coded-phy/326776">RE: Help to set UART example to work only on coded PHY</a>&nbsp;</p> <p>in which it was mentioned that&nbsp;&quot;<span>changing the filter of connection of UUID to Name of device&quot; .So I did that now it&#39;s connecting with coded PHY.</span></p> <div> <div><span>err = bt_scan_filter_add(BT_SCAN_FILTER_TYPE_UUID, BT_UUID_NUS_SERVICE);</span></div> <div><span></span></div> <div><span>to this line&nbsp;</span></div> <div><span></span></div> <div><span>err</span><span> = </span><span>bt_scan_filter_add</span><span>(</span><span>BT_SCAN_FILTER_TYPE_NAME</span><span>,</span><span>perName1</span><span>);</span></div> </div> <p><span>Can you please help me that why we can&#39;t connect with the UUID filter and by NUS_Service?</span></p> <p><span>Pheripheral_Uart_Coded&nbsp;</span></p> <p><span><pre class="ui-code" data-mode="c_cpp">/* * Copyright (c) 2018 Nordic Semiconductor ASA * * SPDX-License-Identifier: LicenseRef-Nordic-5-Clause */ /** @file * @brief Nordic UART Bridge Service (NUS) sample */ #include &quot;uart_async_adapter.h&quot; #include &lt;zephyr/types.h&gt; #include &lt;zephyr/kernel.h&gt; #include &lt;zephyr/drivers/uart.h&gt; #include &lt;zephyr/usb/usb_device.h&gt; #include &lt;zephyr/device.h&gt; #include &lt;zephyr/devicetree.h&gt; #include &lt;soc.h&gt; #include &lt;zephyr/bluetooth/bluetooth.h&gt; #include &lt;zephyr/bluetooth/uuid.h&gt; #include &lt;zephyr/bluetooth/gatt.h&gt; #include &lt;zephyr/bluetooth/hci.h&gt; #include &lt;bluetooth/services/nus.h&gt; #include &lt;dk_buttons_and_leds.h&gt; #include &lt;zephyr/settings/settings.h&gt; #include &lt;stdio.h&gt; #include &lt;zephyr/logging/log.h&gt; #define LOG_MODULE_NAME peripheral_uart LOG_MODULE_REGISTER(LOG_MODULE_NAME); #define STACKSIZE CONFIG_BT_NUS_THREAD_STACK_SIZE #define PRIORITY 7 #define DEVICE_NAME CONFIG_BT_DEVICE_NAME #define DEVICE_NAME_LEN (sizeof(DEVICE_NAME) - 1) #define RUN_STATUS_LED DK_LED1 #define RUN_LED_BLINK_INTERVAL 1000 #define CON_STATUS_LED DK_LED2 #define KEY_PASSKEY_ACCEPT DK_BTN1_MSK #define KEY_PASSKEY_REJECT DK_BTN2_MSK #define UART_BUF_SIZE CONFIG_BT_NUS_UART_BUFFER_SIZE #define UART_WAIT_FOR_BUF_DELAY K_MSEC(50) #define UART_WAIT_FOR_RX CONFIG_BT_NUS_UART_RX_WAIT_TIME static struct k_work start_advertising_worker; static struct bt_le_ext_adv *adv; static K_SEM_DEFINE(ble_init_ok, 0, 1); static struct bt_conn *current_conn; static struct bt_conn *auth_conn; static const struct device *uart = DEVICE_DT_GET(DT_CHOSEN(nordic_nus_uart)); static struct k_work_delayable uart_work; struct uart_data_t { void *fifo_reserved; uint8_t data[UART_BUF_SIZE]; uint16_t len; }; static K_FIFO_DEFINE(fifo_uart_tx_data); static K_FIFO_DEFINE(fifo_uart_rx_data); static const struct bt_data ad[] = { BT_DATA_BYTES(BT_DATA_FLAGS, (BT_LE_AD_GENERAL | BT_LE_AD_NO_BREDR)), BT_DATA(BT_DATA_NAME_COMPLETE, DEVICE_NAME, DEVICE_NAME_LEN), }; static const struct bt_data sd[] = { BT_DATA_BYTES(BT_DATA_UUID128_ALL, BT_UUID_NUS_VAL), }; #if CONFIG_BT_NUS_UART_ASYNC_ADAPTER UART_ASYNC_ADAPTER_INST_DEFINE(async_adapter); #else static const struct device *const async_adapter; #endif static void uart_cb(const struct device *dev, struct uart_event *evt, void *user_data) { ARG_UNUSED(dev); static size_t aborted_len; struct uart_data_t *buf; static uint8_t *aborted_buf; static bool disable_req; switch (evt-&gt;type) { case UART_TX_DONE: LOG_DBG(&quot;UART_TX_DONE&quot;); if ((evt-&gt;data.tx.len == 0) || (!evt-&gt;data.tx.buf)) { return; } if (aborted_buf) { buf = CONTAINER_OF(aborted_buf, struct uart_data_t, data); aborted_buf = NULL; aborted_len = 0; } else { buf = CONTAINER_OF(evt-&gt;data.tx.buf, struct uart_data_t, data); } k_free(buf); buf = k_fifo_get(&amp;fifo_uart_tx_data, K_NO_WAIT); if (!buf) { return; } if (uart_tx(uart, buf-&gt;data, buf-&gt;len, SYS_FOREVER_MS)) { LOG_WRN(&quot;Failed to send data over UART&quot;); } break; case UART_RX_RDY: LOG_DBG(&quot;UART_RX_RDY&quot;); buf = CONTAINER_OF(evt-&gt;data.rx.buf, struct uart_data_t, data); buf-&gt;len += evt-&gt;data.rx.len; if (disable_req) { return; } if ((evt-&gt;data.rx.buf[buf-&gt;len - 1] == &#39;\n&#39;) || (evt-&gt;data.rx.buf[buf-&gt;len - 1] == &#39;\r&#39;)) { disable_req = true; uart_rx_disable(uart); } break; case UART_RX_DISABLED: LOG_DBG(&quot;UART_RX_DISABLED&quot;); disable_req = false; buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); k_work_reschedule(&amp;uart_work, UART_WAIT_FOR_BUF_DELAY); return; } uart_rx_enable(uart, buf-&gt;data, sizeof(buf-&gt;data), UART_WAIT_FOR_RX); break; case UART_RX_BUF_REQUEST: LOG_DBG(&quot;UART_RX_BUF_REQUEST&quot;); buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; uart_rx_buf_rsp(uart, buf-&gt;data, sizeof(buf-&gt;data)); } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); } break; case UART_RX_BUF_RELEASED: LOG_DBG(&quot;UART_RX_BUF_RELEASED&quot;); buf = CONTAINER_OF(evt-&gt;data.rx_buf.buf, struct uart_data_t, data); if (buf-&gt;len &gt; 0) { k_fifo_put(&amp;fifo_uart_rx_data, buf); } else { k_free(buf); } break; case UART_TX_ABORTED: LOG_DBG(&quot;UART_TX_ABORTED&quot;); if (!aborted_buf) { aborted_buf = (uint8_t *)evt-&gt;data.tx.buf; } aborted_len += evt-&gt;data.tx.len; buf = CONTAINER_OF(aborted_buf, struct uart_data_t, data); uart_tx(uart, &amp;buf-&gt;data[aborted_len], buf-&gt;len - aborted_len, SYS_FOREVER_MS); break; default: break; } } static void uart_work_handler(struct k_work *item) { struct uart_data_t *buf; buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); k_work_reschedule(&amp;uart_work, UART_WAIT_FOR_BUF_DELAY); return; } uart_rx_enable(uart, buf-&gt;data, sizeof(buf-&gt;data), UART_WAIT_FOR_RX); } static bool uart_test_async_api(const struct device *dev) { const struct uart_driver_api *api = (const struct uart_driver_api *)dev-&gt;api; return (api-&gt;callback_set != NULL); } static int uart_init(void) { int err; int pos; struct uart_data_t *rx; struct uart_data_t *tx; if (!device_is_ready(uart)) { return -ENODEV; } if (IS_ENABLED(CONFIG_USB_DEVICE_STACK)) { err = usb_enable(NULL); if (err) { LOG_ERR(&quot;Failed to enable USB&quot;); return err; } } rx = k_malloc(sizeof(*rx)); if (rx) { rx-&gt;len = 0; } else { return -ENOMEM; } k_work_init_delayable(&amp;uart_work, uart_work_handler); if (IS_ENABLED(CONFIG_BT_NUS_UART_ASYNC_ADAPTER) &amp;&amp; !uart_test_async_api(uart)) { /* Implement API adapter */ uart_async_adapter_init(async_adapter, uart); uart = async_adapter; } err = uart_callback_set(uart, uart_cb, NULL); if (err) { LOG_ERR(&quot;Cannot initialize UART callback&quot;); return err; } if (IS_ENABLED(CONFIG_UART_LINE_CTRL)) { LOG_INF(&quot;Wait for DTR&quot;); while (true) { uint32_t dtr = 0; uart_line_ctrl_get(uart, UART_LINE_CTRL_DTR, &amp;dtr); if (dtr) { break; } /* Give CPU resources to low priority threads. */ k_sleep(K_MSEC(100)); } LOG_INF(&quot;DTR set&quot;); err = uart_line_ctrl_set(uart, UART_LINE_CTRL_DCD, 1); if (err) { LOG_WRN(&quot;Failed to set DCD, ret code %d&quot;, err); } err = uart_line_ctrl_set(uart, UART_LINE_CTRL_DSR, 1); if (err) { LOG_WRN(&quot;Failed to set DSR, ret code %d&quot;, err); } } tx = k_malloc(sizeof(*tx)); if (tx) { pos = snprintf(tx-&gt;data, sizeof(tx-&gt;data), &quot;Starting Nordic UART service example\r\n&quot;); if ((pos &lt; 0) || (pos &gt;= sizeof(tx-&gt;data))) { k_free(tx); LOG_ERR(&quot;snprintf returned %d&quot;, pos); return -ENOMEM; } tx-&gt;len = pos; } else { return -ENOMEM; } err = uart_tx(uart, tx-&gt;data, tx-&gt;len, SYS_FOREVER_MS); if (err) { LOG_ERR(&quot;Cannot display welcome message (err: %d)&quot;, err); return err; } return uart_rx_enable(uart, rx-&gt;data, sizeof(rx-&gt;data), 50); } static void connected(struct bt_conn *conn, uint8_t err) { char addr[BT_ADDR_LE_STR_LEN]; if (err) { LOG_ERR(&quot;Connection failed (err %u)&quot;, err); return; } bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Connected %s&quot;, log_strdup(addr)); current_conn = bt_conn_ref(conn); dk_set_led_on(CON_STATUS_LED); } static void disconnected(struct bt_conn *conn, uint8_t reason) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Disconnected: %s (reason %u)&quot;, log_strdup(addr), reason); if (auth_conn) { bt_conn_unref(auth_conn); auth_conn = NULL; } if (current_conn) { bt_conn_unref(current_conn); current_conn = NULL; dk_set_led_off(CON_STATUS_LED); } } #ifdef CONFIG_BT_NUS_SECURITY_ENABLED static void security_changed(struct bt_conn *conn, bt_security_t level, enum bt_security_err err) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); if (!err) { LOG_INF(&quot;Security changed: %s level %u&quot;, log_strdup(addr), level); } else { LOG_WRN(&quot;Security failed: %s level %u err %d&quot;, log_strdup(addr), level, err); } } #endif BT_CONN_CB_DEFINE(conn_callbacks) = { .connected = connected, .disconnected = disconnected, #ifdef CONFIG_BT_NUS_SECURITY_ENABLED .security_changed = security_changed, #endif }; #if defined(CONFIG_BT_NUS_SECURITY_ENABLED) static void auth_passkey_display(struct bt_conn *conn, unsigned int passkey) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Passkey for %s: %06u&quot;, log_strdup(addr), passkey); } static void auth_passkey_confirm(struct bt_conn *conn, unsigned int passkey) { char addr[BT_ADDR_LE_STR_LEN]; auth_conn = bt_conn_ref(conn); bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Passkey for %s: %06u&quot;, log_strdup(addr), passkey); LOG_INF(&quot;Press Button 1 to confirm, Button 2 to reject.&quot;); } static void auth_cancel(struct bt_conn *conn) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Pairing cancelled: %s&quot;, log_strdup(addr)); } static void pairing_complete(struct bt_conn *conn, bool bonded) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Pairing completed: %s, bonded: %d&quot;, log_strdup(addr), bonded); } static void pairing_failed(struct bt_conn *conn, enum bt_security_err reason) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Pairing failed conn: %s, reason %d&quot;, log_strdup(addr), reason); } static struct bt_conn_auth_cb conn_auth_callbacks = { .passkey_display = auth_passkey_display, .passkey_confirm = auth_passkey_confirm, .cancel = auth_cancel, }; static struct bt_conn_auth_info_cb conn_auth_info_callbacks = { .pairing_complete = pairing_complete, .pairing_failed = pairing_failed }; #else static struct bt_conn_auth_cb conn_auth_callbacks; #endif static void bt_receive_cb(struct bt_conn *conn, const uint8_t *const data, uint16_t len) { int err; char addr[BT_ADDR_LE_STR_LEN] = {0}; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, ARRAY_SIZE(addr)); LOG_INF(&quot;Received data from: %s&quot;, log_strdup(addr)); for (uint16_t pos = 0; pos != len;) { struct uart_data_t *tx = k_malloc(sizeof(*tx)); if (!tx) { LOG_WRN(&quot;Not able to allocate UART send data buffer&quot;); return; } /* Keep the last byte of TX buffer for potential LF char. */ size_t tx_data_size = sizeof(tx-&gt;data) - 1; if ((len - pos) &gt; tx_data_size) { tx-&gt;len = tx_data_size; } else { tx-&gt;len = (len - pos); } memcpy(tx-&gt;data, &amp;data[pos], tx-&gt;len); pos += tx-&gt;len; /* Append the LF character when the CR character triggered * transmission from the peer. */ if ((pos == len) &amp;&amp; (data[len - 1] == &#39;\r&#39;)) { tx-&gt;data[tx-&gt;len] = &#39;\n&#39;; tx-&gt;len++; } err = uart_tx(uart, tx-&gt;data, tx-&gt;len, SYS_FOREVER_MS); if (err) { k_fifo_put(&amp;fifo_uart_tx_data, tx); } } } static struct bt_nus_cb nus_cb = { .received = bt_receive_cb, }; void error(void) { dk_set_leds_state(DK_ALL_LEDS_MSK, DK_NO_LEDS_MSK); while (true) { /* Spin for ever */ k_sleep(K_MSEC(1000)); } } #ifdef CONFIG_BT_NUS_SECURITY_ENABLED static void num_comp_reply(bool accept) { if (accept) { bt_conn_auth_passkey_confirm(auth_conn); LOG_INF(&quot;Numeric Match, conn %p&quot;, (void *)auth_conn); } else { bt_conn_auth_cancel(auth_conn); LOG_INF(&quot;Numeric Reject, conn %p&quot;, (void *)auth_conn); } bt_conn_unref(auth_conn); auth_conn = NULL; } void button_changed(uint32_t button_state, uint32_t has_changed) { uint32_t buttons = button_state &amp; has_changed; if (auth_conn) { if (buttons &amp; KEY_PASSKEY_ACCEPT) { num_comp_reply(true); } if (buttons &amp; KEY_PASSKEY_REJECT) { num_comp_reply(false); } } } #endif /* CONFIG_BT_NUS_SECURITY_ENABLED */ static void configure_gpio(void) { int err; #ifdef CONFIG_BT_NUS_SECURITY_ENABLED err = dk_buttons_init(button_changed); if (err) { LOG_ERR(&quot;Cannot init buttons (err: %d)&quot;, err); } #endif /* CONFIG_BT_NUS_SECURITY_ENABLED */ err = dk_leds_init(); if (err) { LOG_ERR(&quot;Cannot init LEDs (err: %d)&quot;, err); } } static void start_advertising_coded(struct k_work *item) { int err; err = bt_le_ext_adv_start(adv, NULL); if (err) { printk(&quot;Failed to start advertising set (%d)\n&quot;, err); return; } printk(&quot;Advertiser %p set started\n&quot;, adv); } static int create_advertising_coded(void) { int err; struct bt_le_adv_param param = BT_LE_ADV_PARAM_INIT(BT_LE_ADV_OPT_CONNECTABLE | BT_LE_ADV_OPT_EXT_ADV | BT_LE_ADV_OPT_CODED, BT_GAP_ADV_FAST_INT_MIN_2, BT_GAP_ADV_FAST_INT_MAX_2, NULL); err = bt_le_ext_adv_create(&amp;param, NULL, &amp;adv); if (err) { printk(&quot;Failed to create advertiser set (%d)\n&quot;, err); return err; } printk(&quot;Created adv: %p\n&quot;, adv); err = bt_le_ext_adv_set_data(adv, ad, ARRAY_SIZE(ad), NULL, 0); if (err) { printk(&quot;Failed to set advertising data (%d)\n&quot;, err); return err; } return 0; } static void bt_ready(void) { int err = 0; printk(&quot;Bluetooth initialized\n&quot;); k_work_init(&amp;start_advertising_worker, start_advertising_coded); err = create_advertising_coded(); if (err) { printk(&quot;Advertising failed to create (err %d)\n&quot;, err); return; } k_work_submit(&amp;start_advertising_worker); } void main(void) { int blink_status = 0; int err = 0; configure_gpio(); err = uart_init(); if (err) { error(); } if (IS_ENABLED(CONFIG_BT_NUS_SECURITY_ENABLED)) { err = bt_conn_auth_cb_register(&amp;conn_auth_callbacks); if (err) { printk(&quot;Failed to register authorization callbacks.\n&quot;); return; } err = bt_conn_auth_info_cb_register(&amp;conn_auth_info_callbacks); if (err) { printk(&quot;Failed to register authorization info callbacks.\n&quot;); return; } } err = bt_enable(NULL); if (err) { error(); } LOG_INF(&quot;Bluetooth initialized&quot;); k_sem_give(&amp;ble_init_ok); if (IS_ENABLED(CONFIG_SETTINGS)) { settings_load(); } bt_ready(); err = bt_nus_init(&amp;nus_cb); if (err) { LOG_ERR(&quot;Failed to initialize UART service (err: %d)&quot;, err); return; } /*err = bt_le_adv_start(BT_LE_ADV_CONN, ad, ARRAY_SIZE(ad), sd, ARRAY_SIZE(sd)); if (err) { LOG_ERR(&quot;Advertising failed to start (err %d)&quot;, err); printk(&quot;Advertising failed to start (err %d)&quot;, err); return; } */ // for (;;) { // //dk_set_led(led0, (++blink_status) % 2); // k_sleep(K_MSEC(RUN_LED_BLINK_INTERVAL)); // } } void ble_write_thread(void) { /* Don&#39;t go any further until BLE is initialized */ k_sem_take(&amp;ble_init_ok, K_FOREVER); for (;;) { /* Wait indefinitely for data to be sent over bluetooth */ struct uart_data_t *buf = k_fifo_get(&amp;fifo_uart_rx_data, K_FOREVER); for(int i=0; i&lt;buf-&gt;len; i++) printk(&quot;%c&quot;,buf-&gt;data[i]); if (bt_nus_send(NULL, buf-&gt;data, buf-&gt;len)) { LOG_WRN(&quot;Failed to send data over BLE connection&quot;); } k_free(buf); } } K_THREAD_DEFINE(ble_write_thread_id, STACKSIZE, ble_write_thread, NULL, NULL, NULL, PRIORITY, 0, 0); </pre></span></p> <p><span></span></p> <p><span>Central_Uart_Coded</span></p> <p><span><pre class="ui-code" data-mode="c_cpp">/* * Copyright (c) 2018 Nordic Semiconductor ASA * * SPDX-License-Identifier: LicenseRef-Nordic-5-Clause */ /** @file * @brief Nordic UART Service Client sample */ #include &lt;errno.h&gt; #include &lt;zephyr/kernel.h&gt; #include &lt;zephyr/device.h&gt; #include &lt;zephyr/devicetree.h&gt; #include &lt;zephyr/sys/byteorder.h&gt; #include &lt;zephyr/sys/printk.h&gt; #include &lt;zephyr/bluetooth/bluetooth.h&gt; #include &lt;zephyr/bluetooth/hci.h&gt; #include &lt;zephyr/bluetooth/conn.h&gt; #include &lt;zephyr/bluetooth/uuid.h&gt; #include &lt;zephyr/bluetooth/gatt.h&gt; #include &lt;bluetooth/services/nus.h&gt; #include &lt;bluetooth/services/nus_client.h&gt; #include &lt;bluetooth/gatt_dm.h&gt; #include &lt;bluetooth/scan.h&gt; #include &lt;zephyr/settings/settings.h&gt; #include &lt;zephyr/drivers/uart.h&gt; #include &lt;zephyr/logging/log.h&gt; #define LOG_MODULE_NAME central_uart LOG_MODULE_REGISTER(LOG_MODULE_NAME); /* UART payload buffer element size. */ #define UART_BUF_SIZE 20 #define KEY_PASSKEY_ACCEPT DK_BTN1_MSK #define KEY_PASSKEY_REJECT DK_BTN2_MSK #define NUS_WRITE_TIMEOUT K_MSEC(150) #define UART_WAIT_FOR_BUF_DELAY K_MSEC(50) #define UART_RX_TIMEOUT 50 static const struct device *uart = DEVICE_DT_GET(DT_NODELABEL(uart0)); static struct k_work_delayable uart_work; K_SEM_DEFINE(nus_write_sem, 0, 1); struct uart_data_t { void *fifo_reserved; uint8_t data[UART_BUF_SIZE]; uint16_t len; }; static K_FIFO_DEFINE(fifo_uart_tx_data); static K_FIFO_DEFINE(fifo_uart_rx_data); static struct bt_conn *default_conn; static struct bt_nus_client nus_client; struct bt_le_scan_param m_scan_param = { .type = BT_LE_SCAN_TYPE_ACTIVE, .interval = BT_GAP_SCAN_FAST_INTERVAL, .window = BT_GAP_SCAN_FAST_WINDOW, .options = BT_LE_SCAN_OPT_CODED | BT_LE_SCAN_OPT_NO_1M }; static void ble_data_sent(struct bt_nus_client *nus, uint8_t err, const uint8_t *const data, uint16_t len) { ARG_UNUSED(nus); struct uart_data_t *buf; /* Retrieve buffer context. */ buf = CONTAINER_OF(data, struct uart_data_t, data); k_free(buf); k_sem_give(&amp;nus_write_sem); if (err) { LOG_WRN(&quot;ATT error code: 0x%02X&quot;, err); } } static uint8_t ble_data_received(struct bt_nus_client *nus, const uint8_t *data, uint16_t len) { ARG_UNUSED(nus); int err; for (uint16_t pos = 0; pos != len;) { struct uart_data_t *tx = k_malloc(sizeof(*tx)); if (!tx) { LOG_WRN(&quot;Not able to allocate UART send data buffer&quot;); return BT_GATT_ITER_CONTINUE; } /* Keep the last byte of TX buffer for potential LF char. */ size_t tx_data_size = sizeof(tx-&gt;data) - 1; if ((len - pos) &gt; tx_data_size) { tx-&gt;len = tx_data_size; } else { tx-&gt;len = (len - pos); } memcpy(tx-&gt;data, &amp;data[pos], tx-&gt;len); pos += tx-&gt;len; /* Append the LF character when the CR character triggered * transmission from the peer. */ if ((pos == len) &amp;&amp; (data[len - 1] == &#39;\r&#39;)) { tx-&gt;data[tx-&gt;len] = &#39;\n&#39;; tx-&gt;len++; } err = uart_tx(uart, tx-&gt;data, tx-&gt;len, SYS_FOREVER_MS); if (err) { k_fifo_put(&amp;fifo_uart_tx_data, tx); } } return BT_GATT_ITER_CONTINUE; } static void uart_cb(const struct device *dev, struct uart_event *evt, void *user_data) { ARG_UNUSED(dev); static size_t aborted_len; struct uart_data_t *buf; static uint8_t *aborted_buf; static bool disable_req; switch (evt-&gt;type) { case UART_TX_DONE: LOG_DBG(&quot;UART_TX_DONE&quot;); if ((evt-&gt;data.tx.len == 0) || (!evt-&gt;data.tx.buf)) { return; } if (aborted_buf) { buf = CONTAINER_OF(aborted_buf, struct uart_data_t, data); aborted_buf = NULL; aborted_len = 0; } else { buf = CONTAINER_OF(evt-&gt;data.tx.buf, struct uart_data_t, data); } k_free(buf); buf = k_fifo_get(&amp;fifo_uart_tx_data, K_NO_WAIT); if (!buf) { return; } if (uart_tx(uart, buf-&gt;data, buf-&gt;len, SYS_FOREVER_MS)) { LOG_WRN(&quot;Failed to send data over UART&quot;); } break; case UART_RX_RDY: LOG_DBG(&quot;UART_RX_RDY&quot;); buf = CONTAINER_OF(evt-&gt;data.rx.buf, struct uart_data_t, data); buf-&gt;len += evt-&gt;data.rx.len; if (disable_req) { return; } if ((evt-&gt;data.rx.buf[buf-&gt;len - 1] == &#39;\n&#39;) || (evt-&gt;data.rx.buf[buf-&gt;len - 1] == &#39;\r&#39;)) { disable_req = true; uart_rx_disable(uart); } break; case UART_RX_DISABLED: LOG_DBG(&quot;UART_RX_DISABLED&quot;); disable_req = false; buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); k_work_reschedule(&amp;uart_work, UART_WAIT_FOR_BUF_DELAY); return; } uart_rx_enable(uart, buf-&gt;data, sizeof(buf-&gt;data), UART_RX_TIMEOUT); break; case UART_RX_BUF_REQUEST: LOG_DBG(&quot;UART_RX_BUF_REQUEST&quot;); buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; uart_rx_buf_rsp(uart, buf-&gt;data, sizeof(buf-&gt;data)); } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); } break; case UART_RX_BUF_RELEASED: LOG_DBG(&quot;UART_RX_BUF_RELEASED&quot;); buf = CONTAINER_OF(evt-&gt;data.rx_buf.buf, struct uart_data_t, data); if (buf-&gt;len &gt; 0) { k_fifo_put(&amp;fifo_uart_rx_data, buf); } else { k_free(buf); } break; case UART_TX_ABORTED: LOG_DBG(&quot;UART_TX_ABORTED&quot;); if (!aborted_buf) { aborted_buf = (uint8_t *)evt-&gt;data.tx.buf; } aborted_len += evt-&gt;data.tx.len; buf = CONTAINER_OF(aborted_buf, struct uart_data_t, data); uart_tx(uart, &amp;buf-&gt;data[aborted_len], buf-&gt;len - aborted_len, SYS_FOREVER_MS); break; default: break; } } static void uart_work_handler(struct k_work *item) { struct uart_data_t *buf; buf = k_malloc(sizeof(*buf)); if (buf) { buf-&gt;len = 0; } else { LOG_WRN(&quot;Not able to allocate UART receive buffer&quot;); k_work_reschedule(&amp;uart_work, UART_WAIT_FOR_BUF_DELAY); return; } uart_rx_enable(uart, buf-&gt;data, sizeof(buf-&gt;data), UART_RX_TIMEOUT); } static int uart_init(void) { int err; struct uart_data_t *rx; if (!device_is_ready(uart)) { LOG_ERR(&quot;UART device not ready&quot;); return -ENODEV; } rx = k_malloc(sizeof(*rx)); if (rx) { rx-&gt;len = 0; } else { return -ENOMEM; } k_work_init_delayable(&amp;uart_work, uart_work_handler); err = uart_callback_set(uart, uart_cb, NULL); if (err) { return err; } return uart_rx_enable(uart, rx-&gt;data, sizeof(rx-&gt;data), UART_RX_TIMEOUT); } static void discovery_complete(struct bt_gatt_dm *dm, void *context) { struct bt_nus_client *nus = context; LOG_INF(&quot;Service discovery completed&quot;); bt_gatt_dm_data_print(dm); bt_nus_handles_assign(dm, nus); bt_nus_subscribe_receive(nus); bt_gatt_dm_data_release(dm); } static void discovery_service_not_found(struct bt_conn *conn, void *context) { LOG_INF(&quot;Service not found&quot;); } static void discovery_error(struct bt_conn *conn, int err, void *context) { LOG_WRN(&quot;Error while discovering GATT database: (%d)&quot;, err); } struct bt_gatt_dm_cb discovery_cb = { .completed = discovery_complete, .service_not_found = discovery_service_not_found, .error_found = discovery_error, }; static void gatt_discover(struct bt_conn *conn) { int err; if (conn != default_conn) { return; } err = bt_gatt_dm_start(conn, BT_UUID_NUS_SERVICE, &amp;discovery_cb, &amp;nus_client); if (err) { LOG_ERR(&quot;could not start the discovery procedure, error &quot; &quot;code: %d&quot;, err); } } static void exchange_func(struct bt_conn *conn, uint8_t err, struct bt_gatt_exchange_params *params) { if (!err) { LOG_INF(&quot;MTU exchange done&quot;); } else { LOG_WRN(&quot;MTU exchange failed (err %&quot; PRIu8 &quot;)&quot;, err); } } static void connected(struct bt_conn *conn, uint8_t conn_err) { char addr[BT_ADDR_LE_STR_LEN]; int err; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); if (conn_err) { LOG_INF(&quot;Failed to connect to %s (%d)&quot;, log_strdup(addr), conn_err); printk(&quot;Failed to connect to %s (%d)&quot;, log_strdup(addr), conn_err); if (default_conn == conn) { bt_conn_unref(default_conn); default_conn = NULL; err = bt_scan_start(BT_SCAN_TYPE_SCAN_ACTIVE); if (err) { LOG_ERR(&quot;Scanning failed to start (err %d)&quot;, err); printk(&quot;Scanning failed to start (err %d)&quot;, err); } } return; } LOG_INF(&quot;Connected: %s&quot;, log_strdup(addr)); static struct bt_gatt_exchange_params exchange_params; exchange_params.func = exchange_func; err = bt_gatt_exchange_mtu(conn, &amp;exchange_params); if (err) { LOG_WRN(&quot;MTU exchange failed (err %d)&quot;, err); } err = bt_conn_set_security(conn, BT_SECURITY_L2); if (err) { LOG_WRN(&quot;Failed to set security: %d&quot;, err); gatt_discover(conn); } err = bt_scan_stop(); if ((!err) &amp;&amp; (err != -EALREADY)) { LOG_ERR(&quot;Stop LE scan failed (err %d)&quot;, err); } } static void disconnected(struct bt_conn *conn, uint8_t reason) { char addr[BT_ADDR_LE_STR_LEN]; int err; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Disconnected: %s (reason %u)&quot;, log_strdup(addr), reason); if (default_conn != conn) { return; } bt_conn_unref(default_conn); default_conn = NULL; err = bt_scan_start(BT_SCAN_TYPE_SCAN_ACTIVE); if (err) { LOG_ERR(&quot;Scanning failed to start (err %d)&quot;, err); } } static void security_changed(struct bt_conn *conn, bt_security_t level, enum bt_security_err err) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); if (!err) { LOG_INF(&quot;Security changed: %s level %u&quot;, log_strdup(addr), level); } else { LOG_WRN(&quot;Security failed: %s level %u err %d&quot;, log_strdup(addr), level, err); } gatt_discover(conn); } BT_CONN_CB_DEFINE(conn_callbacks) = { .connected = connected, .disconnected = disconnected, .security_changed = security_changed }; static void scan_filter_match(struct bt_scan_device_info *device_info, struct bt_scan_filter_match *filter_match, bool connectable) { int err; char addr[BT_ADDR_LE_STR_LEN]; struct bt_conn_le_create_param *conn_params; bt_addr_le_to_str(device_info-&gt;recv_info-&gt;addr, addr, sizeof(addr)); printk(&quot;Filters matched. Address: %s connectable: %s\n&quot;, addr, connectable ? &quot;yes&quot; : &quot;no&quot;); err = bt_scan_stop(); if (err) { printk(&quot;Stop LE scan failed (err %d)\n&quot;, err); } conn_params = BT_CONN_LE_CREATE_PARAM( BT_CONN_LE_OPT_CODED | BT_CONN_LE_OPT_NO_1M, BT_GAP_SCAN_FAST_INTERVAL, BT_GAP_SCAN_FAST_INTERVAL); err = bt_conn_le_create(device_info-&gt;recv_info-&gt;addr, conn_params, BT_LE_CONN_PARAM_DEFAULT, &amp;default_conn); if (err) { printk(&quot;Create conn failed (err %d)\n&quot;, err); err = bt_scan_start(BT_SCAN_TYPE_SCAN_ACTIVE); if (err) { printk(&quot;Scanning failed to start (err %d)\n&quot;, err); return; } } printk(&quot;Connection pending\n&quot;); } //BT_SCAN_CB_INIT(scan_cb, scan_filter_match, NULL, NULL, NULL); //BT_SCAN_CB_INIT(scan_cb, scan_filter_match, NULL,scan_connecting_error, scan_connecting); static void scan_connecting_error(struct bt_scan_device_info *device_info) { LOG_WRN(&quot;Connecting failed&quot;); } static void scan_connecting(struct bt_scan_device_info *device_info, struct bt_conn *conn) { default_conn = bt_conn_ref(conn); } static int nus_client_init(void) { int err; struct bt_nus_client_init_param init = { .cb = { .received = ble_data_received, .sent = ble_data_sent, } }; err = bt_nus_client_init(&amp;nus_client, &amp;init); if (err) { LOG_ERR(&quot;NUS Client initialization failed (err %d)&quot;, err); return err; } LOG_INF(&quot;NUS Client module initialized&quot;); return err; } BT_SCAN_CB_INIT(scan_cb, scan_filter_match, NULL,scan_connecting_error, scan_connecting); static void scan_init(void) { int err; /* Use active scanning and disable duplicate filtering to handle any * devices that might update their advertising data at runtime. */ const char *perName1=&quot;Nordic_UART_Service&quot;; struct bt_le_conn_param m_conn_param={ .interval_min=120, .interval_max=220, .timeout=100, }; struct bt_scan_init_param scan_init = { .connect_if_match = 1, //1 .scan_param = &amp;m_scan_param, .conn_param = &amp;m_conn_param, //NULL // }; bt_scan_init(&amp;scan_init); bt_scan_cb_register(&amp;scan_cb); //err = bt_scan_filter_add(BT_SCAN_FILTER_TYPE_UUID, BT_UUID_NUS_SERVICE); err = bt_scan_filter_add(BT_SCAN_FILTER_TYPE_NAME,perName1); if (err) { printk(&quot;Scanning filters cannot be set (err %d)\n&quot;, err); return; } //err = bt_scan_filter_enable(BT_SCAN_UUID_FILTER, false); err = bt_scan_filter_enable(BT_SCAN_NAME_FILTER, false); if (err) { printk(&quot;Filters cannot be turned on (err %d)\n&quot;, err); } } /* static int scan_init(void) { int err; struct bt_scan_init_param scan_init = { .connect_if_match = 1, }; bt_scan_init(&amp;scan_init); bt_scan_cb_register(&amp;scan_cb); err = bt_scan_filter_add(BT_SCAN_FILTER_TYPE_UUID, BT_UUID_NUS_SERVICE); if (err) { LOG_ERR(&quot;Scanning filters cannot be set (err %d)&quot;, err); return err; } err = bt_scan_filter_enable(BT_SCAN_UUID_FILTER, false); if (err) { LOG_ERR(&quot;Filters cannot be turned on (err %d)&quot;, err); return err; } LOG_INF(&quot;Scan module initialized&quot;); return err; } */ static void auth_cancel(struct bt_conn *conn) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Pairing cancelled: %s&quot;, log_strdup(addr)); } static void pairing_complete(struct bt_conn *conn, bool bonded) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_INF(&quot;Pairing completed: %s, bonded: %d&quot;, log_strdup(addr), bonded); } static void pairing_failed(struct bt_conn *conn, enum bt_security_err reason) { char addr[BT_ADDR_LE_STR_LEN]; bt_addr_le_to_str(bt_conn_get_dst(conn), addr, sizeof(addr)); LOG_WRN(&quot;Pairing failed conn: %s, reason %d&quot;, log_strdup(addr), reason); } static struct bt_conn_auth_cb conn_auth_callbacks = { .cancel = auth_cancel, }; static struct bt_conn_auth_info_cb conn_auth_info_callbacks = { .pairing_complete = pairing_complete, .pairing_failed = pairing_failed }; void main(void) { int err; err = bt_conn_auth_cb_register(&amp;conn_auth_callbacks); if (err) { LOG_ERR(&quot;Failed to register authorization callbacks.&quot;); return; } /* err = bt_conn_auth_info_cb_register(&amp;conn_auth_info_callbacks); if (err) { printk(&quot;Failed to register authorization info callbacks.\n&quot;); return; } */ err = bt_enable(NULL); if (err) { LOG_ERR(&quot;Bluetooth init failed (err %d)&quot;, err); return; } LOG_INF(&quot;Bluetooth initialized&quot;); if (IS_ENABLED(CONFIG_SETTINGS)) { settings_load(); } // bt_conn_cb_register(&amp;conn_callback); int (*module_init[])(void) = {uart_init, scan_init, nus_client_init}; for (size_t i = 0; i &lt; ARRAY_SIZE(module_init); i++) { err = (*module_init[i])(); if (err) { return; } } printk(&quot;Starting Bluetooth Central UART example\n&quot;); err = bt_scan_start(BT_SCAN_TYPE_SCAN_ACTIVE); if (err) { LOG_ERR(&quot;Scanning failed to start (err %d)&quot;, err); return; } LOG_INF(&quot;Scanning successfully started&quot;); for (;;) { // Wait indefinitely for data to be sent over Bluetooth // struct uart_data_t *buf = k_fifo_get(&amp;fifo_uart_rx_data, K_FOREVER); err = bt_nus_client_send(&amp;nus_client, buf-&gt;data, buf-&gt;len); if (err) { LOG_WRN(&quot;Failed to send data over BLE connection&quot; &quot;(err %d)&quot;, err); printk(&quot;Failed to send data over BLE connection&quot; &quot;(err %d)&quot;, err); } err = k_sem_take(&amp;nus_write_sem, NUS_WRITE_TIMEOUT); if (err) { LOG_WRN(&quot;NUS send timeout&quot;); printk(&quot;NUS send timeout&quot;); } } } </pre></span></p> <p><span>Thanks in Advance!</span></p> <p><span>BR<br /><br /></span></p> <p><span>Muhammad Usman</span></p> <p><span></span></p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395092?ContentTypeID=1Thu, 10 Nov 2022 12:11:19 GMT137ad170-7792-4731-bb38-c0d22fbe4515:3d928d49-d0b9-49b5-a935-325ccbdc23ccMuhammad Usman<p>Hi,</p> <p>Thank you so much I will wait for your response!</p> <p>BR</p> <p>Muhammad Usman</p><div style="clear:both;"></div>https://devzone.nordicsemi.com/thread/395083?ContentTypeID=1Thu, 10 Nov 2022 11:22:58 GMT137ad170-7792-4731-bb38-c0d22fbe4515:0334727f-c1de-459b-b52a-5f37733bdec4Joakim Jakobsen<p>Hi!&nbsp;</p> <p>Sorry about the delay.&nbsp;</p> <p>I&#39;ll start working on your ticket, and get back to you by the end of day tomorrow.&nbsp;</p> <p>Thank you for your patience.&nbsp;<br />Br,&nbsp;<br />Joakim</p><div style="clear:both;"></div>