subsys/bluetooth/controller/ll/ll.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Nordic Semiconductor ASA
  * Copyright (c) 2016 Vinayak Kariappa Chettimada
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <stdint.h>
 #include <string.h>

 #include <soc.h>

 #include "ccm.h"
 #include "radio.h"

 #include "mem.h"
 #include "util.h"
 #include "ticker.h"

 #include "pdu.h"
 #include "ctrl.h"
 #include "ll.h"

 #include "debug.h"

 static struct {
 	uint8_t pub_addr[BDADDR_SIZE];
 	uint8_t rnd_addr[BDADDR_SIZE];
 } _ll_context;

 static struct {
 	uint16_t interval;
 	uint8_t adv_type:4;
 	uint8_t tx_addr:1;
 	uint8_t rx_addr:1;
 	uint8_t filter_policy:2;
 	uint8_t chl_map:3;
 	uint8_t adv_addr[BDADDR_SIZE];
 	uint8_t direct_addr[BDADDR_SIZE];
 } _ll_adv_params;

 static struct {
 	uint16_t interval;
 	uint16_t window;
 	uint8_t scan_type:1;
 	uint8_t tx_addr:1;
 	uint8_t filter_policy:1;
 } _ll_scan_params;

 void ll_address_get(uint8_t addr_type, uint8_t *bdaddr)
 {
 	if (addr_type) {
 		memcpy(bdaddr, &_ll_context.rnd_addr[0], BDADDR_SIZE);
 	} else {
 		memcpy(bdaddr, &_ll_context.pub_addr[0], BDADDR_SIZE);
 	}
 }

 void ll_address_set(uint8_t addr_type, uint8_t const *const bdaddr)
 {
 	if (addr_type) {
 		memcpy(&_ll_context.rnd_addr[0], bdaddr, BDADDR_SIZE);
 	} else {
 		memcpy(&_ll_context.pub_addr[0], bdaddr, BDADDR_SIZE);
 	}
 }

 void ll_adv_params_set(uint16_t interval, uint8_t adv_type,
 		       uint8_t own_addr_type, uint8_t direct_addr_type,
 		       uint8_t const *const direct_addr, uint8_t chl_map,
 		       uint8_t filter_policy)
 {
 	struct radio_adv_data *radio_adv_data;
 	struct pdu_adv *pdu;

 	/** @todo check and fail if adv role active else
 	 * update (implemented below) current index elements for
 	 * both adv and scan data.
 	 */

 	/* remember params so that set adv/scan data and adv enable
 	 * interface can correctly update adv/scan data in the
 	 * double buffer between caller and controller context.
 	 */
 	_ll_adv_params.interval = interval;
 	_ll_adv_params.chl_map = chl_map;
 	_ll_adv_params.filter_policy = filter_policy;
 	_ll_adv_params.adv_type = adv_type;
 	_ll_adv_params.tx_addr = own_addr_type;
 	_ll_adv_params.rx_addr = 0;

 	/* update the current adv data */
 	radio_adv_data = radio_adv_data_get();
 	pdu = (struct pdu_adv *)&radio_adv_data->data[radio_adv_data->last][0];
 	pdu->type = _ll_adv_params.adv_type;
 	pdu->tx_addr = _ll_adv_params.tx_addr;
 	if (adv_type == PDU_ADV_TYPE_DIRECT_IND) {
 		_ll_adv_params.rx_addr = direct_addr_type;
 		memcpy(&_ll_adv_params.direct_addr[0], direct_addr,
 			 BDADDR_SIZE);
 		memcpy(&pdu->payload.direct_ind.init_addr[0],
 			 direct_addr, BDADDR_SIZE);
 		pdu->len = sizeof(struct pdu_adv_payload_direct_ind);
 	} else if (pdu->len == 0) {
 		pdu->len = BDADDR_SIZE;
 	}
 	pdu->rx_addr = _ll_adv_params.rx_addr;

 	/* update the current scan data */
 	radio_adv_data = radio_scan_data_get();
 	pdu = (struct pdu_adv *)&radio_adv_data->data[radio_adv_data->last][0];
 	pdu->type = PDU_ADV_TYPE_SCAN_RESP;
 	pdu->tx_addr = _ll_adv_params.tx_addr;
 	pdu->rx_addr = 0;
 	if (pdu->len == 0) {
 		pdu->len = BDADDR_SIZE;
 	}
 }

 void ll_adv_data_set(uint8_t len, uint8_t const *const data)
 {
 	struct radio_adv_data *radio_adv_data;
 	struct pdu_adv *pdu;
 	uint8_t last;

 	/** @todo dont update data if directed adv type. */

 	/* use the last index in double buffer, */
 	radio_adv_data = radio_adv_data_get();
 	if (radio_adv_data->first == radio_adv_data->last) {
 		last = radio_adv_data->last + 1;
 		if (last == DOUBLE_BUFFER_SIZE) {
 			last = 0;
 		}
 	} else {
 		last = radio_adv_data->last;
 	}

 	/* update adv pdu fields. */
 	pdu = (struct pdu_adv *)&radio_adv_data->data[last][0];
 	pdu->type = _ll_adv_params.adv_type;
 	pdu->tx_addr = _ll_adv_params.tx_addr;
 	pdu->rx_addr = _ll_adv_params.rx_addr;
 	memcpy(&pdu->payload.adv_ind.addr[0],
 		 &_ll_adv_params.adv_addr[0], BDADDR_SIZE);
 	if (_ll_adv_params.adv_type == PDU_ADV_TYPE_DIRECT_IND) {
 		memcpy(&pdu->payload.direct_ind.init_addr[0],
 			 &_ll_adv_params.direct_addr[0], BDADDR_SIZE);
 		pdu->len = sizeof(struct pdu_adv_payload_direct_ind);
 	} else {
 		memcpy(&pdu->payload.adv_ind.data[0], data, len);
 		pdu->len = BDADDR_SIZE + len;
 	}

 	/* commit the update so controller picks it. */
 	radio_adv_data->last = last;
 }

 void ll_scan_data_set(uint8_t len, uint8_t const *const data)
 {
 	struct radio_adv_data *radio_scan_data;
 	struct pdu_adv *pdu;
 	uint8_t last;

 	/* use the last index in double buffer, */
 	radio_scan_data = radio_scan_data_get();
 	if (radio_scan_data->first == radio_scan_data->last) {
 		last = radio_scan_data->last + 1;
 		if (last == DOUBLE_BUFFER_SIZE) {
 			last = 0;
 		}
 	} else {
 		last = radio_scan_data->last;
 	}

 	/* update scan pdu fields. */
 	pdu = (struct pdu_adv *)&radio_scan_data->data[last][0];
 	pdu->type = PDU_ADV_TYPE_SCAN_RESP;
 	pdu->tx_addr = _ll_adv_params.tx_addr;
 	pdu->rx_addr = 0;
 	pdu->len = BDADDR_SIZE + len;
 	memcpy(&pdu->payload.scan_resp.addr[0],
 		 &_ll_adv_params.adv_addr[0], BDADDR_SIZE);
 	memcpy(&pdu->payload.scan_resp.data[0], data, len);

 	/* commit the update so controller picks it. */
 	radio_scan_data->last = last;
 }

 uint32_t ll_adv_enable(uint8_t enable)
 {
 	uint32_t status;

 	if (enable) {
 		struct radio_adv_data *radio_adv_data;
 		struct radio_adv_data *radio_scan_data;
 		struct pdu_adv *pdu_adv;
 		struct pdu_adv *pdu_scan;

 		/** @todo move the addr remembered into controller
 		 * this way when implementing Privacy 1.2, generated
 		 * new resolvable addresses can be used instantly.
 		 */

 		/* remember addr to use and also update the addr in
 		 * both adv and scan PDUs.
 		 */
 		radio_adv_data = radio_adv_data_get();
 		radio_scan_data = radio_scan_data_get();
 		pdu_adv = (struct pdu_adv *)&radio_adv_data->data
 				[radio_adv_data->last][0];
 		pdu_scan = (struct pdu_adv *)&radio_scan_data->data
 				[radio_scan_data->last][0];
 		if (_ll_adv_params.tx_addr) {
 			memcpy(&_ll_adv_params.adv_addr[0],
 				 &_ll_context.rnd_addr[0], BDADDR_SIZE);
 			memcpy(&pdu_adv->payload.adv_ind.addr[0],
 				 &_ll_context.rnd_addr[0], BDADDR_SIZE);
 			memcpy(&pdu_scan->payload.scan_resp.addr[0],
 				 &_ll_context.rnd_addr[0], BDADDR_SIZE);
 		} else {
 			memcpy(&_ll_adv_params.adv_addr[0],
 				 &_ll_context.pub_addr[0], BDADDR_SIZE);
 			memcpy(&pdu_adv->payload.adv_ind.addr[0],
 				 &_ll_context.pub_addr[0], BDADDR_SIZE);
 			memcpy(&pdu_scan->payload.scan_resp.addr[0],
 				 &_ll_context.pub_addr[0], BDADDR_SIZE);
 		}

 		status = radio_adv_enable(_ll_adv_params.interval,
 						_ll_adv_params.chl_map,
 						_ll_adv_params.filter_policy);
 	} else {
 		status = radio_adv_disable();
 	}

 	return status;
 }

 void ll_scan_params_set(uint8_t scan_type, uint16_t interval, uint16_t window,
 			uint8_t own_addr_type, uint8_t filter_policy)
 {
 	_ll_scan_params.scan_type = scan_type;
 	_ll_scan_params.interval = interval;
 	_ll_scan_params.window = window;
 	_ll_scan_params.tx_addr = own_addr_type;
 	_ll_scan_params.filter_policy = filter_policy;
 }

 uint32_t ll_scan_enable(uint8_t enable)
 {
 	uint32_t status;

 	if (enable) {
 		status = radio_scan_enable(_ll_scan_params.scan_type,
 				_ll_scan_params.tx_addr,
 				(_ll_scan_params.tx_addr) ?
 					&_ll_context.rnd_addr[0] :
 					&_ll_context.pub_addr[0],
 				_ll_scan_params.interval,
 				_ll_scan_params.window,
 				_ll_scan_params.filter_policy);
 	} else {
 		status = radio_scan_disable();
 	}

 	return status;
 }

 uint32_t ll_create_connection(uint16_t scan_interval, uint16_t scan_window,
 			      uint8_t filter_policy, uint8_t peer_addr_type,
 			      uint8_t *peer_addr, uint8_t own_addr_type,
 			      uint16_t interval, uint16_t latency,
 			      uint16_t timeout)
 {
 	uint32_t status;

 	status = radio_connect_enable(peer_addr_type, peer_addr, interval,
 					latency, timeout);

 	if (status) {
 		return status;
 	}

 	return radio_scan_enable(0, own_addr_type, (own_addr_type) ?
 			&_ll_context.rnd_addr[0] :
 			&_ll_context.pub_addr[0],
 		scan_interval, scan_window, filter_policy);
 }
	/*
	* Copyright (c) 2016 Nordic Semiconductor ASA
	* Copyright (c) 2016 Vinayak Kariappa Chettimada
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <stdint.h>
	#include <string.h>

	#include <soc.h>

	#include "ccm.h"
	#include "radio.h"

	#include "mem.h"
	#include "util.h"
	#include "ticker.h"

	#include "pdu.h"
	#include "ctrl.h"
	#include "ll.h"

	#include "debug.h"

	static struct {
	uint8_t pub_addr[BDADDR_SIZE];
	uint8_t rnd_addr[BDADDR_SIZE];
	} _ll_context;

	static struct {
	uint16_t interval;
	uint8_t adv_type:4;
	uint8_t tx_addr:1;
	uint8_t rx_addr:1;
	uint8_t filter_policy:2;
	uint8_t chl_map:3;
	uint8_t adv_addr[BDADDR_SIZE];
	uint8_t direct_addr[BDADDR_SIZE];
	} _ll_adv_params;

	static struct {
	uint16_t interval;
	uint16_t window;
	uint8_t scan_type:1;
	uint8_t tx_addr:1;
	uint8_t filter_policy:1;
	} _ll_scan_params;

	void ll_address_get(uint8_t addr_type, uint8_t *bdaddr)
	{
	if (addr_type) {
	memcpy(bdaddr, &_ll_context.rnd_addr[0], BDADDR_SIZE);
	} else {
	memcpy(bdaddr, &_ll_context.pub_addr[0], BDADDR_SIZE);
	}
	}

	void ll_address_set(uint8_t addr_type, uint8_t const *const bdaddr)
	{
	if (addr_type) {
	memcpy(&_ll_context.rnd_addr[0], bdaddr, BDADDR_SIZE);
	} else {
	memcpy(&_ll_context.pub_addr[0], bdaddr, BDADDR_SIZE);
	}
	}

	void ll_adv_params_set(uint16_t interval, uint8_t adv_type,
	uint8_t own_addr_type, uint8_t direct_addr_type,
	uint8_t const *const direct_addr, uint8_t chl_map,
	uint8_t filter_policy)
	{
	struct radio_adv_data *radio_adv_data;
	struct pdu_adv *pdu;

	/** @todo check and fail if adv role active else
	* update (implemented below) current index elements for
	* both adv and scan data.
	*/

	/* remember params so that set adv/scan data and adv enable
	* interface can correctly update adv/scan data in the
	* double buffer between caller and controller context.
	*/
	_ll_adv_params.interval = interval;
	_ll_adv_params.chl_map = chl_map;
	_ll_adv_params.filter_policy = filter_policy;
	_ll_adv_params.adv_type = adv_type;
	_ll_adv_params.tx_addr = own_addr_type;
	_ll_adv_params.rx_addr = 0;

	/* update the current adv data */
	radio_adv_data = radio_adv_data_get();
	pdu = (struct pdu_adv *)&radio_adv_data->data[radio_adv_data->last][0];
	pdu->type = _ll_adv_params.adv_type;
	pdu->tx_addr = _ll_adv_params.tx_addr;
	if (adv_type == PDU_ADV_TYPE_DIRECT_IND) {
	_ll_adv_params.rx_addr = direct_addr_type;
	memcpy(&_ll_adv_params.direct_addr[0], direct_addr,
	BDADDR_SIZE);
	memcpy(&pdu->payload.direct_ind.init_addr[0],
	direct_addr, BDADDR_SIZE);
	pdu->len = sizeof(struct pdu_adv_payload_direct_ind);
	} else if (pdu->len == 0) {
	pdu->len = BDADDR_SIZE;
	}
	pdu->rx_addr = _ll_adv_params.rx_addr;

	/* update the current scan data */
	radio_adv_data = radio_scan_data_get();
	pdu = (struct pdu_adv *)&radio_adv_data->data[radio_adv_data->last][0];
	pdu->type = PDU_ADV_TYPE_SCAN_RESP;
	pdu->tx_addr = _ll_adv_params.tx_addr;
	pdu->rx_addr = 0;
	if (pdu->len == 0) {
	pdu->len = BDADDR_SIZE;
	}
	}

	void ll_adv_data_set(uint8_t len, uint8_t const *const data)
	{
	struct radio_adv_data *radio_adv_data;
	struct pdu_adv *pdu;
	uint8_t last;

	/** @todo dont update data if directed adv type. */

	/* use the last index in double buffer, */
	radio_adv_data = radio_adv_data_get();
	if (radio_adv_data->first == radio_adv_data->last) {
	last = radio_adv_data->last + 1;
	if (last == DOUBLE_BUFFER_SIZE) {
	last = 0;
	}
	} else {
	last = radio_adv_data->last;
	}

	/* update adv pdu fields. */
	pdu = (struct pdu_adv *)&radio_adv_data->data[last][0];
	pdu->type = _ll_adv_params.adv_type;
	pdu->tx_addr = _ll_adv_params.tx_addr;
	pdu->rx_addr = _ll_adv_params.rx_addr;
	memcpy(&pdu->payload.adv_ind.addr[0],
	&_ll_adv_params.adv_addr[0], BDADDR_SIZE);
	if (_ll_adv_params.adv_type == PDU_ADV_TYPE_DIRECT_IND) {
	memcpy(&pdu->payload.direct_ind.init_addr[0],
	&_ll_adv_params.direct_addr[0], BDADDR_SIZE);
	pdu->len = sizeof(struct pdu_adv_payload_direct_ind);
	} else {
	memcpy(&pdu->payload.adv_ind.data[0], data, len);
	pdu->len = BDADDR_SIZE + len;
	}

	/* commit the update so controller picks it. */
	radio_adv_data->last = last;
	}

	void ll_scan_data_set(uint8_t len, uint8_t const *const data)
	{
	struct radio_adv_data *radio_scan_data;
	struct pdu_adv *pdu;
	uint8_t last;

	/* use the last index in double buffer, */
	radio_scan_data = radio_scan_data_get();
	if (radio_scan_data->first == radio_scan_data->last) {
	last = radio_scan_data->last + 1;
	if (last == DOUBLE_BUFFER_SIZE) {
	last = 0;
	}
	} else {
	last = radio_scan_data->last;
	}

	/* update scan pdu fields. */
	pdu = (struct pdu_adv *)&radio_scan_data->data[last][0];
	pdu->type = PDU_ADV_TYPE_SCAN_RESP;
	pdu->tx_addr = _ll_adv_params.tx_addr;
	pdu->rx_addr = 0;
	pdu->len = BDADDR_SIZE + len;
	memcpy(&pdu->payload.scan_resp.addr[0],
	&_ll_adv_params.adv_addr[0], BDADDR_SIZE);
	memcpy(&pdu->payload.scan_resp.data[0], data, len);

	/* commit the update so controller picks it. */
	radio_scan_data->last = last;
	}

	uint32_t ll_adv_enable(uint8_t enable)
	{
	uint32_t status;

	if (enable) {
	struct radio_adv_data *radio_adv_data;
	struct radio_adv_data *radio_scan_data;
	struct pdu_adv *pdu_adv;
	struct pdu_adv *pdu_scan;

	/** @todo move the addr remembered into controller
	* this way when implementing Privacy 1.2, generated
	* new resolvable addresses can be used instantly.
	*/

	/* remember addr to use and also update the addr in
	* both adv and scan PDUs.
	*/
	radio_adv_data = radio_adv_data_get();
	radio_scan_data = radio_scan_data_get();
	pdu_adv = (struct pdu_adv *)&radio_adv_data->data
	[radio_adv_data->last][0];
	pdu_scan = (struct pdu_adv *)&radio_scan_data->data
	[radio_scan_data->last][0];
	if (_ll_adv_params.tx_addr) {
	memcpy(&_ll_adv_params.adv_addr[0],
	&_ll_context.rnd_addr[0], BDADDR_SIZE);
	memcpy(&pdu_adv->payload.adv_ind.addr[0],
	&_ll_context.rnd_addr[0], BDADDR_SIZE);
	memcpy(&pdu_scan->payload.scan_resp.addr[0],
	&_ll_context.rnd_addr[0], BDADDR_SIZE);
	} else {
	memcpy(&_ll_adv_params.adv_addr[0],
	&_ll_context.pub_addr[0], BDADDR_SIZE);
	memcpy(&pdu_adv->payload.adv_ind.addr[0],
	&_ll_context.pub_addr[0], BDADDR_SIZE);
	memcpy(&pdu_scan->payload.scan_resp.addr[0],
	&_ll_context.pub_addr[0], BDADDR_SIZE);
	}

	status = radio_adv_enable(_ll_adv_params.interval,
	_ll_adv_params.chl_map,
	_ll_adv_params.filter_policy);
	} else {
	status = radio_adv_disable();
	}

	return status;
	}

	void ll_scan_params_set(uint8_t scan_type, uint16_t interval, uint16_t window,
	uint8_t own_addr_type, uint8_t filter_policy)
	{
	_ll_scan_params.scan_type = scan_type;
	_ll_scan_params.interval = interval;
	_ll_scan_params.window = window;
	_ll_scan_params.tx_addr = own_addr_type;
	_ll_scan_params.filter_policy = filter_policy;
	}

	uint32_t ll_scan_enable(uint8_t enable)
	{
	uint32_t status;

	if (enable) {
	status = radio_scan_enable(_ll_scan_params.scan_type,
	_ll_scan_params.tx_addr,
	(_ll_scan_params.tx_addr) ?
	&_ll_context.rnd_addr[0] :
	&_ll_context.pub_addr[0],
	_ll_scan_params.interval,
	_ll_scan_params.window,
	_ll_scan_params.filter_policy);
	} else {
	status = radio_scan_disable();
	}

	return status;
	}

	uint32_t ll_create_connection(uint16_t scan_interval, uint16_t scan_window,
	uint8_t filter_policy, uint8_t peer_addr_type,
	uint8_t *peer_addr, uint8_t own_addr_type,
	uint16_t interval, uint16_t latency,
	uint16_t timeout)
	{
	uint32_t status;

	status = radio_connect_enable(peer_addr_type, peer_addr, interval,
	latency, timeout);

	if (status) {
	return status;
	}

	return radio_scan_enable(0, own_addr_type, (own_addr_type) ?
	&_ll_context.rnd_addr[0] :
	&_ll_context.pub_addr[0],
	scan_interval, scan_window, filter_policy);
	}