drivers/bluetooth/hci/spi.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /* spi.c - SPI based Bluetooth driver */

 #define DT_DRV_COMPAT zephyr_bt_hci_spi

 /*
  * Copyright (c) 2017 Linaro Ltd.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/drivers/gpio.h>
 #include <zephyr/init.h>
 #include <zephyr/drivers/spi.h>
 #include <zephyr/sys/byteorder.h>
 #include <zephyr/sys/util.h>

 #include <zephyr/bluetooth/hci.h>
 #include <zephyr/drivers/bluetooth/hci_driver.h>

 #define BT_DBG_ENABLED IS_ENABLED(CONFIG_BT_DEBUG_HCI_DRIVER)
 #define LOG_MODULE_NAME bt_driver
 #include "common/log.h"

 #define HCI_CMD			0x01
 #define HCI_ACL			0x02
 #define HCI_SCO			0x03
 #define HCI_EVT			0x04

 /* Special Values */
 #define SPI_WRITE		0x0A
 #define SPI_READ		0x0B
 #define READY_NOW		0x02

 #define EVT_BLUE_INITIALIZED	0x01

 /* Offsets */
 #define STATUS_HEADER_READY	0
 #define STATUS_HEADER_TOREAD	3

 #define PACKET_TYPE		0
 #define EVT_HEADER_TYPE		0
 #define EVT_HEADER_EVENT	1
 #define EVT_HEADER_SIZE		2
 #define EVT_VENDOR_CODE_LSB	3
 #define EVT_VENDOR_CODE_MSB	4

 #define CMD_OGF			1
 #define CMD_OCF			2

 /* Max SPI buffer length for transceive operations.
  *
  * Buffer size needs to be at least the size of the larger RX/TX buffer
  * required by the SPI slave, as the legacy spi_transceive requires both RX/TX
  * to be the same length. Size also needs to be compatible with the
  * slave device used (e.g. nRF5X max buffer length for SPIS is 255).
  */
 #define SPI_MAX_MSG_LEN		255 /* As defined by X-NUCLEO-IDB04A1 BSP */

 static uint8_t rxmsg[SPI_MAX_MSG_LEN];
 static uint8_t txmsg[SPI_MAX_MSG_LEN];

 static const struct gpio_dt_spec irq_gpio = GPIO_DT_SPEC_INST_GET(0, irq_gpios);
 static const struct gpio_dt_spec rst_gpio = GPIO_DT_SPEC_INST_GET(0, reset_gpios);

 static struct gpio_callback	gpio_cb;

 static K_SEM_DEFINE(sem_initialised, 0, 1);
 static K_SEM_DEFINE(sem_request, 0, 1);
 static K_SEM_DEFINE(sem_busy, 1, 1);

 static K_KERNEL_STACK_DEFINE(spi_rx_stack, 512);
 static struct k_thread spi_rx_thread_data;

 #if defined(CONFIG_BT_DEBUG_HCI_DRIVER)
 #include <zephyr/sys/printk.h>
 static inline void spi_dump_message(const uint8_t *pre, uint8_t *buf,
 				    uint8_t size)
 {
 	uint8_t i, c;

 	printk("%s (%d): ", pre, size);
 	for (i = 0U; i < size; i++) {
 		c = buf[i];
 		printk("%x ", c);
 		if (c >= 31U && c <= 126U) {
 			printk("[%c] ", c);
 		} else {
 			printk("[.] ");
 		}
 	}
 	printk("\n");
 }
 #else
 static inline
 void spi_dump_message(const uint8_t *pre, uint8_t *buf, uint8_t size) {}
 #endif

 #if defined(CONFIG_BT_SPI_BLUENRG)
 /* Define a limit when reading IRQ high */
 /* It can be required to be increased for */
 /* some particular cases. */
 #define IRQ_HIGH_MAX_READ 3
 static uint8_t attempts;
 #endif /* CONFIG_BT_SPI_BLUENRG */

 #if defined(CONFIG_BT_BLUENRG_ACI)
 #define BLUENRG_ACI_WRITE_CONFIG_DATA       BT_OP(BT_OGF_VS, 0x000C)
 #define BLUENRG_ACI_WRITE_CONFIG_CMD_LL     0x2C
 #define BLUENRG_ACI_LL_MODE                 0x01

 struct bluenrg_aci_cmd_ll_param {
     uint8_t cmd;
     uint8_t length;
     uint8_t value;
 };
 static int bt_spi_send_aci_config_data_controller_mode(void);
 #endif /* CONFIG_BT_BLUENRG_ACI */

 #if defined(CONFIG_BT_SPI_BLUENRG)
 /* In case of BlueNRG-MS, it is necessary to prevent SPI driver to release CS,
  * and instead, let current driver manage CS release. see kick_cs()/release_cs()
  * So, add SPI_HOLD_ON_CS to operation field.
  */
 static const struct spi_dt_spec bus = SPI_DT_SPEC_INST_GET(
 	0, SPI_OP_MODE_MASTER | SPI_TRANSFER_MSB | SPI_WORD_SET(8) | SPI_HOLD_ON_CS, 0);
 #else
 static const struct spi_dt_spec bus = SPI_DT_SPEC_INST_GET(
 	0, SPI_OP_MODE_MASTER | SPI_TRANSFER_MSB | SPI_WORD_SET(8), 0);
 #endif

 static struct spi_buf spi_tx_buf;
 static struct spi_buf spi_rx_buf;
 static const struct spi_buf_set spi_tx = {
 	.buffers = &spi_tx_buf,
 	.count = 1
 };
 static const struct spi_buf_set spi_rx = {
 	.buffers = &spi_rx_buf,
 	.count = 1
 };

 static inline int bt_spi_transceive(void *tx, uint32_t tx_len,
 				    void *rx, uint32_t rx_len)
 {
 	spi_tx_buf.buf = tx;
 	spi_tx_buf.len = (size_t)tx_len;
 	spi_rx_buf.buf = rx;
 	spi_rx_buf.len = (size_t)rx_len;
 	return spi_transceive_dt(&bus, &spi_tx, &spi_rx);
 }

 static inline uint16_t bt_spi_get_cmd(uint8_t *txmsg)
 {
 	return (txmsg[CMD_OCF] << 8) | txmsg[CMD_OGF];
 }

 static inline uint16_t bt_spi_get_evt(uint8_t *rxmsg)
 {
 	return (rxmsg[EVT_VENDOR_CODE_MSB] << 8) | rxmsg[EVT_VENDOR_CODE_LSB];
 }

 static void bt_spi_isr(const struct device *unused1,
 		       struct gpio_callback *unused2,
 		       uint32_t unused3)
 {
 	BT_DBG("");

 	k_sem_give(&sem_request);
 }

 static void bt_spi_handle_vendor_evt(uint8_t *rxmsg)
 {
 	switch (bt_spi_get_evt(rxmsg)) {
 	case EVT_BLUE_INITIALIZED:
 		k_sem_give(&sem_initialised);
 #if defined(CONFIG_BT_BLUENRG_ACI)
 		/* force BlueNRG to be on controller mode */
 		bt_spi_send_aci_config_data_controller_mode();
 #endif
 	default:
 		break;
 	}
 }

 #if defined(CONFIG_BT_SPI_BLUENRG)
 /* BlueNRG has a particuliar way to wake up from sleep and be ready.
  * All is done through its CS line:
  * If it is in sleep mode, the first transaction will not return ready
  * status. At this point, it's necessary to release the CS and retry
  * within 2ms the same transaction. And again when it's required to
  * know the amount of byte to read.
  * (See section 5.2 of BlueNRG-MS datasheet)
  */
 static int configure_cs(void)
 {
 	/* Configure pin as output and set to active */
 	return gpio_pin_configure_dt(&bus.config.cs->gpio, GPIO_OUTPUT_ACTIVE);
 }

 static void kick_cs(void)
 {
 	gpio_pin_set_dt(&bus.config.cs->gpio, 0);
 	gpio_pin_set_dt(&bus.config.cs->gpio, 1);
 }

 static void release_cs(void)
 {
 	gpio_pin_set_dt(&bus.config.cs->gpio, 0);
 }

 static bool irq_pin_high(void)
 {
 	int pin_state;

 	pin_state = gpio_pin_get_dt(&irq_gpio);

 	BT_DBG("IRQ Pin: %d", pin_state);

 	return pin_state > 0;
 }

 static void init_irq_high_loop(void)
 {
 	attempts = IRQ_HIGH_MAX_READ;
 }

 static bool exit_irq_high_loop(void)
 {
 	/* Limit attempts on BlueNRG-MS as we might */
 	/* enter this loop with nothing to read */

 	attempts--;

 	return attempts;
 }

 #else

 #define configure_cs(...) 0
 #define kick_cs(...)
 #define release_cs(...)
 #define irq_pin_high(...) 0
 #define init_irq_high_loop(...)
 #define exit_irq_high_loop(...) 1

 #endif /* CONFIG_BT_SPI_BLUENRG */

 #if defined(CONFIG_BT_BLUENRG_ACI)
 static int bt_spi_send_aci_config_data_controller_mode(void)
 {
 	struct bluenrg_aci_cmd_ll_param *param;
 	struct net_buf *buf;

 	buf = bt_hci_cmd_create(BLUENRG_ACI_WRITE_CONFIG_DATA, sizeof(*param));
 	if (!buf) {
 		return -ENOBUFS;
 	}

 	param = net_buf_add(buf, sizeof(*param));
 	param->cmd = BLUENRG_ACI_WRITE_CONFIG_CMD_LL;
 	param->length = 0x1;
 	/* Force BlueNRG-MS roles to Link Layer only mode */
 	param->value = BLUENRG_ACI_LL_MODE;

 	bt_hci_cmd_send(BLUENRG_ACI_WRITE_CONFIG_DATA, buf);

 	return 0;
 }
 #endif /* CONFIG_BT_BLUENRG_ACI */

 static void bt_spi_rx_thread(void)
 {
 	bool discardable = false;
 	k_timeout_t timeout = K_FOREVER;
 	struct net_buf *buf;
 	uint8_t header_master[5] = { SPI_READ, 0x00, 0x00, 0x00, 0x00 };
 	uint8_t header_slave[5];
 	struct bt_hci_acl_hdr acl_hdr;
 	uint8_t size = 0U;
 	int ret;
 	int len;

 	(void)memset(&txmsg, 0xFF, SPI_MAX_MSG_LEN);

 	while (true) {
 		k_sem_take(&sem_request, K_FOREVER);
 		/* Disable IRQ pin callback to avoid spurious IRQs */

 		gpio_pin_interrupt_configure_dt(&irq_gpio, GPIO_INT_DISABLE);
 		k_sem_take(&sem_busy, K_FOREVER);

 		BT_DBG("");

 		do {
 			init_irq_high_loop();
 			do {
 				kick_cs();
 				ret = bt_spi_transceive(header_master, 5,
 							header_slave, 5);
 			} while ((((header_slave[STATUS_HEADER_TOREAD] == 0U ||
 				    header_slave[STATUS_HEADER_TOREAD] == 0xFF) &&
 				   !ret)) && exit_irq_high_loop());

 			size = header_slave[STATUS_HEADER_TOREAD];
 			if (!ret || size != 0) {
 				do {
 					ret = bt_spi_transceive(&txmsg, size,
 								&rxmsg, size);
 				} while (rxmsg[0] == 0U && ret == 0);
 			}

 			release_cs();
 			gpio_pin_interrupt_configure_dt(
 				&irq_gpio, GPIO_INT_EDGE_TO_ACTIVE);

 			k_sem_give(&sem_busy);

 			if (ret || size == 0) {
 				if (ret) {
 					BT_ERR("Error %d", ret);
 				}
 				continue;
 			}

 			spi_dump_message("RX:ed", rxmsg, size);

 			switch (rxmsg[PACKET_TYPE]) {
 			case HCI_EVT:
 				switch (rxmsg[EVT_HEADER_EVENT]) {
 				case BT_HCI_EVT_VENDOR:
 					/* Vendor events are currently unsupported */
 					bt_spi_handle_vendor_evt(rxmsg);
 					continue;
 				default:
 					if (rxmsg[1] == BT_HCI_EVT_LE_META_EVENT &&
 					    (rxmsg[3] == BT_HCI_EVT_LE_ADVERTISING_REPORT)) {
 						discardable = true;
 						timeout = K_NO_WAIT;
 					}

 					buf = bt_buf_get_evt(rxmsg[EVT_HEADER_EVENT],
 							     discardable, timeout);
 					if (!buf) {
 						BT_DBG("Discard adv report due to insufficient buf");
 						continue;
 					}
 				}

 				len = sizeof(struct bt_hci_evt_hdr) + rxmsg[EVT_HEADER_SIZE];
 				if (len > net_buf_tailroom(buf)) {
 					BT_ERR("Event too long: %d", len);
 					net_buf_unref(buf);
 					continue;
 				}
 				net_buf_add_mem(buf, &rxmsg[1], len);
 				break;
 			case HCI_ACL:
 				buf = bt_buf_get_rx(BT_BUF_ACL_IN, K_FOREVER);
 				memcpy(&acl_hdr, &rxmsg[1], sizeof(acl_hdr));
 				len = sizeof(acl_hdr) + sys_le16_to_cpu(acl_hdr.len);
 				if (len > net_buf_tailroom(buf)) {
 					BT_ERR("ACL too long: %d", len);
 					net_buf_unref(buf);
 					continue;
 				}
 				net_buf_add_mem(buf, &rxmsg[1], len);
 				break;
 			default:
 				BT_ERR("Unknown BT buf type %d", rxmsg[0]);
 				continue;
 			}

 			bt_recv(buf);

 		/* On BlueNRG-MS, host is expected to read */
 		/* as long as IRQ pin is high */
 		} while (irq_pin_high());
 	}
 }

 static int bt_spi_send(struct net_buf *buf)
 {
 	uint8_t header[5] = { SPI_WRITE, 0x00,  0x00,  0x00,  0x00 };
 	int pending;
 	int ret;

 	BT_DBG("");

 	/* Buffer needs an additional byte for type */
 	if (buf->len >= SPI_MAX_MSG_LEN) {
 		BT_ERR("Message too long");
 		return -EINVAL;
 	}

 	/* Allow time for the read thread to handle interrupt */
 	while (true) {
 		pending = gpio_pin_get_dt(&irq_gpio);
 		if (pending <= 0) {
 			break;
 		}
 		k_sleep(K_MSEC(1));
 	}

 	k_sem_take(&sem_busy, K_FOREVER);

 	switch (bt_buf_get_type(buf)) {
 	case BT_BUF_ACL_OUT:
 		net_buf_push_u8(buf, HCI_ACL);
 		break;
 	case BT_BUF_CMD:
 		net_buf_push_u8(buf, HCI_CMD);
 		break;
 	default:
 		BT_ERR("Unsupported type");
 		k_sem_give(&sem_busy);
 		return -EINVAL;
 	}

 	/* Poll sanity values until device has woken-up */
 	do {
 		kick_cs();
 		ret = bt_spi_transceive(header, 5, rxmsg, 5);

 		/*
 		 * RX Header (rxmsg) must contain a sanity check Byte and size
 		 * information.  If it does not contain BOTH then it is
 		 * sleeping or still in the initialisation stage (waking-up).
 		 */
 	} while ((rxmsg[STATUS_HEADER_READY] != READY_NOW ||
 		  (rxmsg[1] | rxmsg[2] | rxmsg[3] | rxmsg[4]) == 0U) && !ret);


 	k_sem_give(&sem_busy);

 	if (!ret) {
 		/* Transmit the message */
 		do {
 			ret = bt_spi_transceive(buf->data, buf->len,
 						rxmsg, buf->len);
 		} while (rxmsg[0] == 0U && !ret);
 	}

 	release_cs();

 	if (ret) {
 		BT_ERR("Error %d", ret);
 		goto out;
 	}

 	spi_dump_message("TX:ed", buf->data, buf->len);

 #if defined(CONFIG_BT_SPI_BLUENRG)
 	/*
 	 * Since a RESET has been requested, the chip will now restart.
 	 * Unfortunately the BlueNRG will reply with "reset received" but
 	 * since it does not send back a NOP, we have no way to tell when the
 	 * RESET has actually taken place.  Instead, we use the vendor command
 	 * EVT_BLUE_INITIALIZED as an indication that it is safe to proceed.
 	 */
 	if (bt_spi_get_cmd(buf->data) == BT_HCI_OP_RESET) {
 		k_sem_take(&sem_initialised, K_FOREVER);
 	}
 #endif /* CONFIG_BT_SPI_BLUENRG */
 out:
 	net_buf_unref(buf);

 	return ret;
 }

 static int bt_spi_open(void)
 {
 	/* Configure RST pin and hold BLE in Reset */
 	gpio_pin_configure_dt(&rst_gpio, GPIO_OUTPUT_ACTIVE);

 	/* Configure IRQ pin and the IRQ call-back/handler */
 	gpio_pin_configure_dt(&irq_gpio, GPIO_INPUT);

 	gpio_init_callback(&gpio_cb, bt_spi_isr, BIT(irq_gpio.pin));

 	if (gpio_add_callback(irq_gpio.port, &gpio_cb)) {
 		return -EINVAL;
 	}

 	gpio_pin_interrupt_configure_dt(&irq_gpio, GPIO_INT_EDGE_TO_ACTIVE);

 	/* Start RX thread */
 	k_thread_create(&spi_rx_thread_data, spi_rx_stack,
 			K_KERNEL_STACK_SIZEOF(spi_rx_stack),
 			(k_thread_entry_t)bt_spi_rx_thread, NULL, NULL, NULL,
 			K_PRIO_COOP(CONFIG_BT_DRIVER_RX_HIGH_PRIO),
 			0, K_NO_WAIT);

 	/* Take BLE out of reset */
 	gpio_pin_set_dt(&rst_gpio, 0);

 	/* Device will let us know when it's ready */
 	k_sem_take(&sem_initialised, K_FOREVER);

 	return 0;
 }

 static const struct bt_hci_driver drv = {
 	.name		= DT_INST_LABEL(0),
 	.bus		= BT_HCI_DRIVER_BUS_SPI,
 #if defined(CONFIG_BT_BLUENRG_ACI)
 	.quirks		= BT_QUIRK_NO_RESET,
 #endif /* CONFIG_BT_BLUENRG_ACI */
 	.open		= bt_spi_open,
 	.send		= bt_spi_send,
 };

 static int bt_spi_init(const struct device *unused)
 {
 	ARG_UNUSED(unused);

 	if (!spi_is_ready(&bus)) {
 		BT_ERR("SPI device not ready");
 		return -ENODEV;
 	}

 	if (configure_cs()) {
 		return -EIO;
 	}

 	if (!device_is_ready(irq_gpio.port)) {
 		BT_ERR("IRQ GPIO device not ready");
 		return -ENODEV;
 	}

 	if (!device_is_ready(rst_gpio.port)) {
 		BT_ERR("Reset GPIO device not ready");
 		return -ENODEV;
 	}

 	bt_hci_driver_register(&drv);


 	BT_DBG("BT SPI initialized");

 	return 0;
 }

 SYS_INIT(bt_spi_init, POST_KERNEL, CONFIG_BT_SPI_INIT_PRIORITY);
	/* spi.c - SPI based Bluetooth driver */

	#define DT_DRV_COMPAT zephyr_bt_hci_spi

	/*
	* Copyright (c) 2017 Linaro Ltd.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/drivers/gpio.h>
	#include <zephyr/init.h>
	#include <zephyr/drivers/spi.h>
	#include <zephyr/sys/byteorder.h>
	#include <zephyr/sys/util.h>

	#include <zephyr/bluetooth/hci.h>
	#include <zephyr/drivers/bluetooth/hci_driver.h>

	#define BT_DBG_ENABLED IS_ENABLED(CONFIG_BT_DEBUG_HCI_DRIVER)
	#define LOG_MODULE_NAME bt_driver
	#include "common/log.h"

	#define HCI_CMD 0x01
	#define HCI_ACL 0x02
	#define HCI_SCO 0x03
	#define HCI_EVT 0x04

	/* Special Values */
	#define SPI_WRITE 0x0A
	#define SPI_READ 0x0B
	#define READY_NOW 0x02

	#define EVT_BLUE_INITIALIZED 0x01

	/* Offsets */
	#define STATUS_HEADER_READY 0
	#define STATUS_HEADER_TOREAD 3

	#define PACKET_TYPE 0
	#define EVT_HEADER_TYPE 0
	#define EVT_HEADER_EVENT 1
	#define EVT_HEADER_SIZE 2
	#define EVT_VENDOR_CODE_LSB 3
	#define EVT_VENDOR_CODE_MSB 4

	#define CMD_OGF 1
	#define CMD_OCF 2

	/* Max SPI buffer length for transceive operations.
	*
	* Buffer size needs to be at least the size of the larger RX/TX buffer
	* required by the SPI slave, as the legacy spi_transceive requires both RX/TX
	* to be the same length. Size also needs to be compatible with the
	* slave device used (e.g. nRF5X max buffer length for SPIS is 255).
	*/
	#define SPI_MAX_MSG_LEN 255 /* As defined by X-NUCLEO-IDB04A1 BSP */

	static uint8_t rxmsg[SPI_MAX_MSG_LEN];
	static uint8_t txmsg[SPI_MAX_MSG_LEN];

	static const struct gpio_dt_spec irq_gpio = GPIO_DT_SPEC_INST_GET(0, irq_gpios);
	static const struct gpio_dt_spec rst_gpio = GPIO_DT_SPEC_INST_GET(0, reset_gpios);

	static struct gpio_callback gpio_cb;

	static K_SEM_DEFINE(sem_initialised, 0, 1);
	static K_SEM_DEFINE(sem_request, 0, 1);
	static K_SEM_DEFINE(sem_busy, 1, 1);

	static K_KERNEL_STACK_DEFINE(spi_rx_stack, 512);
	static struct k_thread spi_rx_thread_data;

	#if defined(CONFIG_BT_DEBUG_HCI_DRIVER)
	#include <zephyr/sys/printk.h>
	static inline void spi_dump_message(const uint8_t pre, uint8_t buf,
	uint8_t size)
	{
	uint8_t i, c;

	printk("%s (%d): ", pre, size);
	for (i = 0U; i < size; i++) {
	c = buf[i];
	printk("%x ", c);
	if (c >= 31U && c <= 126U) {
	printk("[%c] ", c);
	} else {
	printk("[.] ");
	}
	}
	printk("\n");
	}
	#else
	static inline
	void spi_dump_message(const uint8_t pre, uint8_t buf, uint8_t size) {}
	#endif

	#if defined(CONFIG_BT_SPI_BLUENRG)
	/* Define a limit when reading IRQ high */
	/* It can be required to be increased for */
	/* some particular cases. */
	#define IRQ_HIGH_MAX_READ 3
	static uint8_t attempts;
	#endif /* CONFIG_BT_SPI_BLUENRG */

	#if defined(CONFIG_BT_BLUENRG_ACI)
	#define BLUENRG_ACI_WRITE_CONFIG_DATA BT_OP(BT_OGF_VS, 0x000C)
	#define BLUENRG_ACI_WRITE_CONFIG_CMD_LL 0x2C
	#define BLUENRG_ACI_LL_MODE 0x01

	struct bluenrg_aci_cmd_ll_param {
	uint8_t cmd;
	uint8_t length;
	uint8_t value;
	};
	static int bt_spi_send_aci_config_data_controller_mode(void);
	#endif /* CONFIG_BT_BLUENRG_ACI */

	#if defined(CONFIG_BT_SPI_BLUENRG)
	/* In case of BlueNRG-MS, it is necessary to prevent SPI driver to release CS,
	* and instead, let current driver manage CS release. see kick_cs()/release_cs()
	* So, add SPI_HOLD_ON_CS to operation field.
	*/
	static const struct spi_dt_spec bus = SPI_DT_SPEC_INST_GET(
	0, SPI_OP_MODE_MASTER \| SPI_TRANSFER_MSB \| SPI_WORD_SET(8) \| SPI_HOLD_ON_CS, 0);
	#else
	static const struct spi_dt_spec bus = SPI_DT_SPEC_INST_GET(
	0, SPI_OP_MODE_MASTER \| SPI_TRANSFER_MSB \| SPI_WORD_SET(8), 0);
	#endif

	static struct spi_buf spi_tx_buf;
	static struct spi_buf spi_rx_buf;
	static const struct spi_buf_set spi_tx = {
	.buffers = &spi_tx_buf,
	.count = 1
	};
	static const struct spi_buf_set spi_rx = {
	.buffers = &spi_rx_buf,
	.count = 1
	};

	static inline int bt_spi_transceive(void *tx, uint32_t tx_len,
	void *rx, uint32_t rx_len)
	{
	spi_tx_buf.buf = tx;
	spi_tx_buf.len = (size_t)tx_len;
	spi_rx_buf.buf = rx;
	spi_rx_buf.len = (size_t)rx_len;
	return spi_transceive_dt(&bus, &spi_tx, &spi_rx);
	}

	static inline uint16_t bt_spi_get_cmd(uint8_t *txmsg)
	{
	return (txmsg[CMD_OCF] << 8) \| txmsg[CMD_OGF];
	}

	static inline uint16_t bt_spi_get_evt(uint8_t *rxmsg)
	{
	return (rxmsg[EVT_VENDOR_CODE_MSB] << 8) \| rxmsg[EVT_VENDOR_CODE_LSB];
	}

	static void bt_spi_isr(const struct device *unused1,
	struct gpio_callback *unused2,
	uint32_t unused3)
	{
	BT_DBG("");

	k_sem_give(&sem_request);
	}

	static void bt_spi_handle_vendor_evt(uint8_t *rxmsg)
	{
	switch (bt_spi_get_evt(rxmsg)) {
	case EVT_BLUE_INITIALIZED:
	k_sem_give(&sem_initialised);
	#if defined(CONFIG_BT_BLUENRG_ACI)
	/* force BlueNRG to be on controller mode */
	bt_spi_send_aci_config_data_controller_mode();
	#endif
	default:
	break;
	}
	}

	#if defined(CONFIG_BT_SPI_BLUENRG)
	/* BlueNRG has a particuliar way to wake up from sleep and be ready.
	* All is done through its CS line:
	* If it is in sleep mode, the first transaction will not return ready
	* status. At this point, it's necessary to release the CS and retry
	* within 2ms the same transaction. And again when it's required to
	* know the amount of byte to read.
	* (See section 5.2 of BlueNRG-MS datasheet)
	*/
	static int configure_cs(void)
	{
	/* Configure pin as output and set to active */
	return gpio_pin_configure_dt(&bus.config.cs->gpio, GPIO_OUTPUT_ACTIVE);
	}

	static void kick_cs(void)
	{
	gpio_pin_set_dt(&bus.config.cs->gpio, 0);
	gpio_pin_set_dt(&bus.config.cs->gpio, 1);
	}

	static void release_cs(void)
	{
	gpio_pin_set_dt(&bus.config.cs->gpio, 0);
	}

	static bool irq_pin_high(void)
	{
	int pin_state;

	pin_state = gpio_pin_get_dt(&irq_gpio);

	BT_DBG("IRQ Pin: %d", pin_state);

	return pin_state > 0;
	}

	static void init_irq_high_loop(void)
	{
	attempts = IRQ_HIGH_MAX_READ;
	}

	static bool exit_irq_high_loop(void)
	{
	/* Limit attempts on BlueNRG-MS as we might */
	/* enter this loop with nothing to read */

	attempts--;

	return attempts;
	}

	#else

	#define configure_cs(...) 0
	#define kick_cs(...)
	#define release_cs(...)
	#define irq_pin_high(...) 0
	#define init_irq_high_loop(...)
	#define exit_irq_high_loop(...) 1

	#endif /* CONFIG_BT_SPI_BLUENRG */

	#if defined(CONFIG_BT_BLUENRG_ACI)
	static int bt_spi_send_aci_config_data_controller_mode(void)
	{
	struct bluenrg_aci_cmd_ll_param *param;
	struct net_buf *buf;

	buf = bt_hci_cmd_create(BLUENRG_ACI_WRITE_CONFIG_DATA, sizeof(*param));
	if (!buf) {
	return -ENOBUFS;
	}

	param = net_buf_add(buf, sizeof(*param));
	param->cmd = BLUENRG_ACI_WRITE_CONFIG_CMD_LL;
	param->length = 0x1;
	/* Force BlueNRG-MS roles to Link Layer only mode */
	param->value = BLUENRG_ACI_LL_MODE;

	bt_hci_cmd_send(BLUENRG_ACI_WRITE_CONFIG_DATA, buf);

	return 0;
	}
	#endif /* CONFIG_BT_BLUENRG_ACI */

	static void bt_spi_rx_thread(void)
	{
	bool discardable = false;
	k_timeout_t timeout = K_FOREVER;
	struct net_buf *buf;
	uint8_t header_master[5] = { SPI_READ, 0x00, 0x00, 0x00, 0x00 };
	uint8_t header_slave[5];
	struct bt_hci_acl_hdr acl_hdr;
	uint8_t size = 0U;
	int ret;
	int len;

	(void)memset(&txmsg, 0xFF, SPI_MAX_MSG_LEN);

	while (true) {
	k_sem_take(&sem_request, K_FOREVER);
	/* Disable IRQ pin callback to avoid spurious IRQs */

	gpio_pin_interrupt_configure_dt(&irq_gpio, GPIO_INT_DISABLE);
	k_sem_take(&sem_busy, K_FOREVER);

	BT_DBG("");

	do {
	init_irq_high_loop();
	do {
	kick_cs();
	ret = bt_spi_transceive(header_master, 5,
	header_slave, 5);
	} while ((((header_slave[STATUS_HEADER_TOREAD] == 0U \|\|
	header_slave[STATUS_HEADER_TOREAD] == 0xFF) &&
	!ret)) && exit_irq_high_loop());

	size = header_slave[STATUS_HEADER_TOREAD];
	if (!ret \|\| size != 0) {
	do {
	ret = bt_spi_transceive(&txmsg, size,
	&rxmsg, size);
	} while (rxmsg[0] == 0U && ret == 0);
	}

	release_cs();
	gpio_pin_interrupt_configure_dt(
	&irq_gpio, GPIO_INT_EDGE_TO_ACTIVE);

	k_sem_give(&sem_busy);

	if (ret \|\| size == 0) {
	if (ret) {
	BT_ERR("Error %d", ret);
	}
	continue;
	}

	spi_dump_message("RX:ed", rxmsg, size);

	switch (rxmsg[PACKET_TYPE]) {
	case HCI_EVT:
	switch (rxmsg[EVT_HEADER_EVENT]) {
	case BT_HCI_EVT_VENDOR:
	/* Vendor events are currently unsupported */
	bt_spi_handle_vendor_evt(rxmsg);
	continue;
	default:
	if (rxmsg[1] == BT_HCI_EVT_LE_META_EVENT &&
	(rxmsg[3] == BT_HCI_EVT_LE_ADVERTISING_REPORT)) {
	discardable = true;
	timeout = K_NO_WAIT;
	}

	buf = bt_buf_get_evt(rxmsg[EVT_HEADER_EVENT],
	discardable, timeout);
	if (!buf) {
	BT_DBG("Discard adv report due to insufficient buf");
	continue;
	}
	}

	len = sizeof(struct bt_hci_evt_hdr) + rxmsg[EVT_HEADER_SIZE];
	if (len > net_buf_tailroom(buf)) {
	BT_ERR("Event too long: %d", len);
	net_buf_unref(buf);
	continue;
	}
	net_buf_add_mem(buf, &rxmsg[1], len);
	break;
	case HCI_ACL:
	buf = bt_buf_get_rx(BT_BUF_ACL_IN, K_FOREVER);
	memcpy(&acl_hdr, &rxmsg[1], sizeof(acl_hdr));
	len = sizeof(acl_hdr) + sys_le16_to_cpu(acl_hdr.len);
	if (len > net_buf_tailroom(buf)) {
	BT_ERR("ACL too long: %d", len);
	net_buf_unref(buf);
	continue;
	}
	net_buf_add_mem(buf, &rxmsg[1], len);
	break;
	default:
	BT_ERR("Unknown BT buf type %d", rxmsg[0]);
	continue;
	}

	bt_recv(buf);

	/* On BlueNRG-MS, host is expected to read */
	/* as long as IRQ pin is high */
	} while (irq_pin_high());
	}
	}

	static int bt_spi_send(struct net_buf *buf)
	{
	uint8_t header[5] = { SPI_WRITE, 0x00, 0x00, 0x00, 0x00 };
	int pending;
	int ret;

	BT_DBG("");

	/* Buffer needs an additional byte for type */
	if (buf->len >= SPI_MAX_MSG_LEN) {
	BT_ERR("Message too long");
	return -EINVAL;
	}

	/* Allow time for the read thread to handle interrupt */
	while (true) {
	pending = gpio_pin_get_dt(&irq_gpio);
	if (pending <= 0) {
	break;
	}
	k_sleep(K_MSEC(1));
	}

	k_sem_take(&sem_busy, K_FOREVER);

	switch (bt_buf_get_type(buf)) {
	case BT_BUF_ACL_OUT:
	net_buf_push_u8(buf, HCI_ACL);
	break;
	case BT_BUF_CMD:
	net_buf_push_u8(buf, HCI_CMD);
	break;
	default:
	BT_ERR("Unsupported type");
	k_sem_give(&sem_busy);
	return -EINVAL;
	}

	/* Poll sanity values until device has woken-up */
	do {
	kick_cs();
	ret = bt_spi_transceive(header, 5, rxmsg, 5);

	/*
	* RX Header (rxmsg) must contain a sanity check Byte and size
	* information. If it does not contain BOTH then it is
	* sleeping or still in the initialisation stage (waking-up).
	*/
	} while ((rxmsg[STATUS_HEADER_READY] != READY_NOW \|\|
	(rxmsg[1] \| rxmsg[2] \| rxmsg[3] \| rxmsg[4]) == 0U) && !ret);


	k_sem_give(&sem_busy);

	if (!ret) {
	/* Transmit the message */
	do {
	ret = bt_spi_transceive(buf->data, buf->len,
	rxmsg, buf->len);
	} while (rxmsg[0] == 0U && !ret);
	}

	release_cs();

	if (ret) {
	BT_ERR("Error %d", ret);
	goto out;
	}

	spi_dump_message("TX:ed", buf->data, buf->len);

	#if defined(CONFIG_BT_SPI_BLUENRG)
	/*
	* Since a RESET has been requested, the chip will now restart.
	* Unfortunately the BlueNRG will reply with "reset received" but
	* since it does not send back a NOP, we have no way to tell when the
	* RESET has actually taken place. Instead, we use the vendor command
	* EVT_BLUE_INITIALIZED as an indication that it is safe to proceed.
	*/
	if (bt_spi_get_cmd(buf->data) == BT_HCI_OP_RESET) {
	k_sem_take(&sem_initialised, K_FOREVER);
	}
	#endif /* CONFIG_BT_SPI_BLUENRG */
	out:
	net_buf_unref(buf);

	return ret;
	}

	static int bt_spi_open(void)
	{
	/* Configure RST pin and hold BLE in Reset */
	gpio_pin_configure_dt(&rst_gpio, GPIO_OUTPUT_ACTIVE);

	/* Configure IRQ pin and the IRQ call-back/handler */
	gpio_pin_configure_dt(&irq_gpio, GPIO_INPUT);

	gpio_init_callback(&gpio_cb, bt_spi_isr, BIT(irq_gpio.pin));

	if (gpio_add_callback(irq_gpio.port, &gpio_cb)) {
	return -EINVAL;
	}

	gpio_pin_interrupt_configure_dt(&irq_gpio, GPIO_INT_EDGE_TO_ACTIVE);

	/* Start RX thread */
	k_thread_create(&spi_rx_thread_data, spi_rx_stack,
	K_KERNEL_STACK_SIZEOF(spi_rx_stack),
	(k_thread_entry_t)bt_spi_rx_thread, NULL, NULL, NULL,
	K_PRIO_COOP(CONFIG_BT_DRIVER_RX_HIGH_PRIO),
	0, K_NO_WAIT);

	/* Take BLE out of reset */
	gpio_pin_set_dt(&rst_gpio, 0);

	/* Device will let us know when it's ready */
	k_sem_take(&sem_initialised, K_FOREVER);

	return 0;
	}

	static const struct bt_hci_driver drv = {
	.name = DT_INST_LABEL(0),
	.bus = BT_HCI_DRIVER_BUS_SPI,
	#if defined(CONFIG_BT_BLUENRG_ACI)
	.quirks = BT_QUIRK_NO_RESET,
	#endif /* CONFIG_BT_BLUENRG_ACI */
	.open = bt_spi_open,
	.send = bt_spi_send,
	};

	static int bt_spi_init(const struct device *unused)
	{
	ARG_UNUSED(unused);

	if (!spi_is_ready(&bus)) {
	BT_ERR("SPI device not ready");
	return -ENODEV;
	}

	if (configure_cs()) {
	return -EIO;
	}

	if (!device_is_ready(irq_gpio.port)) {
	BT_ERR("IRQ GPIO device not ready");
	return -ENODEV;
	}

	if (!device_is_ready(rst_gpio.port)) {
	BT_ERR("Reset GPIO device not ready");
	return -ENODEV;
	}

	bt_hci_driver_register(&drv);


	BT_DBG("BT SPI initialized");

	return 0;
	}

	SYS_INIT(bt_spi_init, POST_KERNEL, CONFIG_BT_SPI_INIT_PRIORITY);