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pigweed / third_party / github / zephyrproject-rtos / zephyr / 04827ba71f560b73b951adb0ae8442e01c67d4b6 / . / subsys / bluetooth / mesh / rpr_srv.c
blob: 3d48260c80ebedd924f5df52cee7029838985a7e [file] [log] [blame]
/*
* Copyright (c) 2020 Nordic Semiconductor ASA
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdlib.h>
#include <zephyr/sys/slist.h>
#include <zephyr/random/rand32.h>
#include <zephyr/sys/byteorder.h>
#include <zephyr/bluetooth/hci.h>
#include <zephyr/bluetooth/mesh/rpr_srv.h>
#include <common/bt_str.h>
#include <zephyr/bluetooth/mesh/sar_cfg.h>
#include "access.h"
#include "adv.h"
#include "prov.h"
#include "crypto.h"
#include "rpr.h"
#include "net.h"
#include "mesh.h"
#define LOG_LEVEL CONFIG_BT_MESH_MODEL_LOG_LEVEL
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(bt_mesh_rpr_srv);
#define LINK_OPEN_TIMEOUT_DEFAULT 10
#define LINK_CTX(_cli, _send_rel) \
{ \
.net_idx = (_cli)->net_idx, .app_idx = BT_MESH_KEY_DEV_LOCAL, \
.addr = (_cli)->addr, .send_ttl = (_cli)->ttl, \
.send_rel = (_send_rel) \
}
enum {
SCANNING,
SCAN_REPORT_PENDING,
SCAN_EXT_HAS_ADDR,
NODE_REFRESH,
URI_MATCHED,
URI_REQUESTED,
RPR_SRV_NUM_FLAGS,
};
/** Remote provisioning server instance. */
static struct {
struct bt_mesh_model *mod;
ATOMIC_DEFINE(flags, RPR_SRV_NUM_FLAGS);
struct {
struct bt_mesh_rpr_unprov
devs[CONFIG_BT_MESH_RPR_SRV_SCANNED_ITEMS_MAX];
uint8_t max_devs;
enum bt_mesh_rpr_scan state;
struct k_work_delayable report;
struct k_work_delayable timeout;
/* Extended scanning */
bt_addr_le_t addr;
uint8_t ad[CONFIG_BT_MESH_RPR_AD_TYPES_MAX];
uint8_t ad_count;
/* Time to do regular scanning after extended scanning ends: */
uint32_t additional_time;
struct net_buf_simple *adv_data;
struct bt_mesh_rpr_node cli;
struct bt_mesh_rpr_unprov *dev;
} scan;
struct {
struct k_work report;
enum bt_mesh_rpr_link_state state;
enum bt_mesh_rpr_status status;
uint8_t close_reason;
uint8_t tx_pdu;
uint8_t rx_pdu;
struct bt_mesh_rpr_node cli;
struct bt_mesh_rpr_unprov *dev;
} link;
struct {
const struct prov_bearer_cb *cb;
enum bt_mesh_rpr_node_refresh procedure;
void *cb_data;
struct {
prov_bearer_send_complete_t cb;
void *cb_data;
} tx;
} refresh;
} srv = {
.scan = {
.adv_data = NET_BUF_SIMPLE(CONFIG_BT_MESH_RPR_SRV_AD_DATA_MAX)
}
};
enum bt_mesh_rpr_node_refresh bt_mesh_node_refresh_get(void)
{
return srv.refresh.procedure;
}
static struct bt_mesh_rpr_unprov *unprov_get(const uint8_t uuid[16])
{
int i;
for (i = 0; i < srv.scan.max_devs; ++i) {
if (uuid) {
if ((srv.scan.devs[i].flags & BT_MESH_RPR_UNPROV_ACTIVE) &&
!memcmp(srv.scan.devs[i].uuid, uuid, 16)) {
return &srv.scan.devs[i];
}
} else if (!(srv.scan.devs[i].flags & BT_MESH_RPR_UNPROV_ACTIVE)) {
return &srv.scan.devs[i];
}
}
return NULL;
}
static uint8_t *get_ad_type(uint8_t *list, size_t count, uint8_t ad)
{
int i;
for (i = 0; i < count; ++i) {
if (ad == list[i] || (ad == BT_DATA_NAME_SHORTENED &&
list[i] == BT_DATA_NAME_COMPLETE)) {
return &list[i];
}
}
return NULL;
}
static void cli_scan_clear(void)
{
srv.scan.cli.addr = BT_MESH_ADDR_UNASSIGNED;
srv.scan.cli.net_idx = BT_MESH_KEY_UNUSED;
}
static void cli_link_clear(void)
{
srv.link.cli.addr = BT_MESH_ADDR_UNASSIGNED;
srv.link.cli.net_idx = BT_MESH_KEY_UNUSED;
}
static void scan_status_send(struct bt_mesh_msg_ctx *ctx,
enum bt_mesh_rpr_status status)
{
uint8_t timeout = 0;
if (atomic_test_bit(srv.flags, SCANNING)) {
timeout = k_ticks_to_ms_floor32(
k_work_delayable_remaining_get(&srv.scan.timeout)) /
MSEC_PER_SEC;
}
BT_MESH_MODEL_BUF_DEFINE(rsp, RPR_OP_SCAN_STATUS, 4);
bt_mesh_model_msg_init(&rsp, RPR_OP_SCAN_STATUS);
net_buf_simple_add_u8(&rsp, status);
net_buf_simple_add_u8(&rsp, srv.scan.state);
net_buf_simple_add_u8(&rsp, srv.scan.max_devs);
net_buf_simple_add_u8(&rsp, timeout);
bt_mesh_model_send(srv.mod, ctx, &rsp, NULL, NULL);
}
static void link_status_send(struct bt_mesh_msg_ctx *ctx,
enum bt_mesh_rpr_status status)
{
BT_MESH_MODEL_BUF_DEFINE(buf, RPR_OP_LINK_STATUS, 2);
bt_mesh_model_msg_init(&buf, RPR_OP_LINK_STATUS);
net_buf_simple_add_u8(&buf, status);
net_buf_simple_add_u8(&buf, srv.link.state);
bt_mesh_model_send(srv.mod, ctx, &buf, NULL, NULL);
}
static void link_report_send(void)
{
struct bt_mesh_msg_ctx ctx = LINK_CTX(&srv.link.cli, true);
BT_MESH_MODEL_BUF_DEFINE(buf, RPR_OP_LINK_REPORT, 3);
bt_mesh_model_msg_init(&buf, RPR_OP_LINK_REPORT);
net_buf_simple_add_u8(&buf, srv.link.status);
net_buf_simple_add_u8(&buf, srv.link.state);
if (srv.link.status == BT_MESH_RPR_ERR_LINK_CLOSED_BY_SERVER ||
srv.link.status == BT_MESH_RPR_ERR_LINK_CLOSED_BY_DEVICE) {
net_buf_simple_add_u8(&buf, srv.link.close_reason);
}
LOG_DBG("%u %u", srv.link.status, srv.link.state);
bt_mesh_model_send(srv.mod, &ctx, &buf, NULL, NULL);
}
static void scan_report_schedule(void)
{
uint32_t delay;
if (k_work_delayable_remaining_get(&srv.scan.report) ||
atomic_test_bit(srv.flags, SCAN_REPORT_PENDING)) {
return;
}
delay = (sys_rand32_get() % 480) + 20;
k_work_reschedule(&srv.scan.report, K_MSEC(delay));
}
static void scan_report_sent(int err, void *cb_data)
{
atomic_clear_bit(srv.flags, SCAN_REPORT_PENDING);
k_work_reschedule(&srv.scan.report, K_NO_WAIT);
}
static const struct bt_mesh_send_cb report_cb = {
.end = scan_report_sent,
};
static void scan_report_send(void)
{
struct bt_mesh_msg_ctx ctx = LINK_CTX(&srv.scan.cli, true);
int i, err;
if (atomic_test_bit(srv.flags, SCAN_REPORT_PENDING)) {
return;
}
for (i = 0; i < srv.scan.max_devs; ++i) {
struct bt_mesh_rpr_unprov *dev = &srv.scan.devs[i];
if (!(dev->flags & BT_MESH_RPR_UNPROV_FOUND) ||
(dev->flags & BT_MESH_RPR_UNPROV_REPORTED)) {
continue;
}
BT_MESH_MODEL_BUF_DEFINE(buf, RPR_OP_SCAN_REPORT, 23);
bt_mesh_model_msg_init(&buf, RPR_OP_SCAN_REPORT);
net_buf_simple_add_u8(&buf, dev->rssi);
net_buf_simple_add_mem(&buf, dev->uuid, 16);
net_buf_simple_add_be16(&buf, dev->oob);
if (dev->flags & BT_MESH_RPR_UNPROV_HASH) {
net_buf_simple_add_be32(&buf, dev->hash);
}
atomic_set_bit(srv.flags, SCAN_REPORT_PENDING);
err = bt_mesh_model_send(srv.mod, &ctx, &buf, &report_cb, NULL);
if (err) {
atomic_clear_bit(srv.flags, SCAN_REPORT_PENDING);
LOG_DBG("tx failed: %d", err);
break;
}
LOG_DBG("Reported unprov #%u", i);
dev->flags |= BT_MESH_RPR_UNPROV_REPORTED;
break;
}
}
static void scan_ext_report_send(void)
{
struct bt_mesh_msg_ctx ctx = LINK_CTX(&srv.scan.cli, true);
int err;
BT_MESH_MODEL_BUF_DEFINE(buf, RPR_OP_EXTENDED_SCAN_REPORT,
19 + CONFIG_BT_MESH_RPR_SRV_AD_DATA_MAX);
bt_mesh_model_msg_init(&buf, RPR_OP_EXTENDED_SCAN_REPORT);
net_buf_simple_add_u8(&buf, BT_MESH_RPR_SUCCESS);
net_buf_simple_add_mem(&buf, srv.scan.dev->uuid, 16);
if (!(srv.scan.dev->flags & BT_MESH_RPR_UNPROV_FOUND)) {
LOG_DBG("not found");
goto send;
}
if (srv.scan.dev->flags & BT_MESH_RPR_UNPROV_EXT_ADV_RXD) {
net_buf_simple_add_le16(&buf, srv.scan.dev->oob);
net_buf_simple_add_mem(&buf, srv.scan.adv_data->data,
srv.scan.adv_data->len);
LOG_DBG("adv data: %s",
bt_hex(srv.scan.adv_data->data, srv.scan.adv_data->len));
}
srv.scan.dev->flags &= ~BT_MESH_RPR_UNPROV_EXT_ADV_RXD;
send:
err = bt_mesh_model_send(srv.mod, &ctx, &buf, NULL, NULL);
if (!err) {
srv.scan.dev->flags |= BT_MESH_RPR_UNPROV_REPORTED;
}
}
static void scan_stop(void)
{
LOG_DBG("");
k_work_cancel_delayable(&srv.scan.report);
k_work_cancel_delayable(&srv.scan.timeout);
srv.scan.state = BT_MESH_RPR_SCAN_IDLE;
cli_scan_clear();
atomic_clear_bit(srv.flags, SCANNING);
}
static void scan_report_timeout(struct k_work *work)
{
scan_report_send();
}
static void scan_ext_stop(uint32_t remaining_time)
{
atomic_clear_bit(srv.flags, URI_MATCHED);
atomic_clear_bit(srv.flags, URI_REQUESTED);
if ((remaining_time + srv.scan.additional_time) &&
srv.scan.state != BT_MESH_RPR_SCAN_IDLE) {
k_work_reschedule(
&srv.scan.timeout,
K_MSEC(remaining_time + srv.scan.additional_time));
} else if (srv.scan.state == BT_MESH_RPR_SCAN_MULTI) {
/* Extended scan might have finished early */
scan_ext_report_send();
} else if (srv.scan.state != BT_MESH_RPR_SCAN_IDLE) {
scan_report_send();
scan_stop();
} else {
atomic_clear_bit(srv.flags, SCANNING);
}
if (!(srv.scan.dev->flags & BT_MESH_RPR_UNPROV_REPORTED)) {
scan_ext_report_send();
}
bt_mesh_scan_active_set(false);
srv.scan.dev = NULL;
}
static void adv_handle_ext_scan(const struct bt_le_scan_recv_info *info,
struct net_buf_simple *buf);
static void scan_timeout(struct k_work *work)
{
LOG_DBG("%s", (srv.scan.dev ? "Extended scanning" : "Normal scanning"));
if (srv.scan.dev) {
scan_ext_stop(0);
} else {
scan_report_send();
scan_stop();
}
}
static void link_close(enum bt_mesh_rpr_status status,
enum prov_bearer_link_status reason)
{
srv.link.status = status;
srv.link.close_reason = reason;
srv.link.state = BT_MESH_RPR_LINK_CLOSING;
LOG_DBG("status: %u reason: %u", status, reason);
if (atomic_test_and_clear_bit(srv.flags, NODE_REFRESH)) {
/* Link closing is an atomic operation: */
srv.link.state = BT_MESH_RPR_LINK_IDLE;
link_report_send();
srv.refresh.cb->link_closed(&pb_remote_srv, srv.refresh.cb_data,
srv.link.close_reason);
cli_link_clear();
} else {
bt_mesh_pb_adv.link_close(reason);
}
}
static void outbound_pdu_report_send(void)
{
struct bt_mesh_msg_ctx ctx = LINK_CTX(&srv.link.cli, true);
BT_MESH_MODEL_BUF_DEFINE(buf, RPR_OP_PDU_OUTBOUND_REPORT, 1);
bt_mesh_model_msg_init(&buf, RPR_OP_PDU_OUTBOUND_REPORT);
net_buf_simple_add_u8(&buf, srv.link.tx_pdu);
LOG_DBG("%u", srv.link.tx_pdu);
bt_mesh_model_send(srv.mod, &ctx, &buf, NULL, NULL);
}
static void pdu_send_complete(int err, void *cb_data)
{
if (err) {
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_SEND_PDU,
PROV_BEARER_LINK_STATUS_FAIL);
} else if (srv.link.state == BT_MESH_RPR_LINK_SENDING) {
srv.link.state = BT_MESH_RPR_LINK_ACTIVE;
srv.link.tx_pdu++;
outbound_pdu_report_send();
}
}
static int inbound_pdu_send(struct net_buf_simple *buf,
const struct bt_mesh_send_cb *cb)
{
struct bt_mesh_msg_ctx ctx = LINK_CTX(&srv.link.cli, true);
BT_MESH_MODEL_BUF_DEFINE(msg, RPR_OP_PDU_REPORT, 66);
bt_mesh_model_msg_init(&msg, RPR_OP_PDU_REPORT);
net_buf_simple_add_u8(&msg, srv.link.rx_pdu);
net_buf_simple_add_mem(&msg, buf->data, buf->len);
return bt_mesh_model_send(srv.mod, &ctx, &msg, cb, NULL);
}
static void subnet_evt_handler(struct bt_mesh_subnet *subnet,
enum bt_mesh_key_evt evt)
{
if (!srv.mod || evt != BT_MESH_KEY_DELETED) {
return;
}
LOG_DBG("Subnet deleted");
if (srv.link.state != BT_MESH_RPR_LINK_IDLE &&
subnet->net_idx == srv.link.cli.net_idx) {
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_BY_SERVER,
PROV_BEARER_LINK_STATUS_FAIL);
/* Skip the link closing stage, as specified in the Bluetooth
* Mesh Profile specification, section 4.4.5.4.
*/
srv.link.state = BT_MESH_RPR_LINK_IDLE;
} else if (atomic_test_bit(srv.flags, SCANNING) &&
subnet->net_idx == srv.scan.cli.net_idx) {
scan_stop();
}
}
BT_MESH_SUBNET_CB_DEFINE(rpr_srv) = {
.evt_handler = subnet_evt_handler
};
/*******************************************************************************
* Prov bearer interface
******************************************************************************/
static void pb_link_opened(const struct prov_bearer *bearer, void *cb_data)
{
LOG_DBG("");
srv.link.state = BT_MESH_RPR_LINK_ACTIVE;
srv.link.status = BT_MESH_RPR_SUCCESS;
link_report_send();
}
static void link_report_send_and_clear(struct k_work *work)
{
link_report_send();
cli_link_clear();
}
static void pb_link_closed(const struct prov_bearer *bearer, void *cb_data,
enum prov_bearer_link_status reason)
{
if (srv.link.state == BT_MESH_RPR_LINK_IDLE) {
return;
}
LOG_DBG("%u", reason);
if (srv.link.state == BT_MESH_RPR_LINK_OPENING) {
srv.link.status = BT_MESH_RPR_ERR_LINK_OPEN_FAILED;
} else if (reason == PROV_BEARER_LINK_STATUS_TIMEOUT) {
if (srv.link.state == BT_MESH_RPR_LINK_SENDING) {
srv.link.status =
BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_SEND_PDU;
} else {
srv.link.status = BT_MESH_RPR_ERR_LINK_CLOSED_BY_SERVER;
}
} else if (reason == PROV_BEARER_LINK_STATUS_FAIL &&
srv.link.status != BT_MESH_RPR_ERR_LINK_CLOSED_BY_CLIENT &&
srv.link.status != BT_MESH_RPR_ERR_LINK_CLOSED_BY_SERVER) {
srv.link.status = BT_MESH_RPR_ERR_LINK_CLOSED_BY_DEVICE;
}
if (reason == PROV_BEARER_LINK_STATUS_SUCCESS) {
srv.link.close_reason = PROV_BEARER_LINK_STATUS_SUCCESS;
} else {
srv.link.close_reason = PROV_BEARER_LINK_STATUS_FAIL;
}
srv.link.state = BT_MESH_RPR_LINK_IDLE;
k_work_submit(&srv.link.report);
}
static void pb_error(const struct prov_bearer *bearer, void *cb_data,
uint8_t err)
{
if (srv.link.state == BT_MESH_RPR_LINK_IDLE) {
return;
}
LOG_DBG("%d", err);
srv.link.close_reason = err;
srv.link.state = BT_MESH_RPR_LINK_IDLE;
srv.link.status = BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_RECEIVE_PDU;
link_report_send();
cli_link_clear();
}
static void pb_rx(const struct prov_bearer *bearer, void *cb_data,
struct net_buf_simple *buf)
{
int err;
if (srv.link.state != BT_MESH_RPR_LINK_ACTIVE &&
srv.link.state != BT_MESH_RPR_LINK_SENDING) {
return;
}
srv.link.rx_pdu++;
LOG_DBG("");
err = inbound_pdu_send(buf, NULL);
if (err) {
LOG_ERR("PDU send fail: %d", err);
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_SEND_PDU,
PROV_BEARER_LINK_STATUS_FAIL);
bt_mesh_pb_adv.link_close(PROV_ERR_RESOURCES);
}
}
static const struct prov_bearer_cb prov_bearer_cb = {
.link_opened = pb_link_opened,
.link_closed = pb_link_closed,
.error = pb_error,
.recv = pb_rx,
};
/*******************************************************************************
* Message handlers
******************************************************************************/
static int handle_scan_caps_get(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
BT_MESH_MODEL_BUF_DEFINE(rsp, RPR_OP_SCAN_CAPS_STATUS, 2);
bt_mesh_model_msg_init(&rsp, RPR_OP_SCAN_CAPS_STATUS);
net_buf_simple_add_u8(&rsp, CONFIG_BT_MESH_RPR_SRV_SCANNED_ITEMS_MAX);
net_buf_simple_add_u8(&rsp, true);
bt_mesh_model_send(srv.mod, ctx, &rsp, NULL, NULL);
return 0;
}
static int handle_scan_get(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
scan_status_send(ctx, BT_MESH_RPR_SUCCESS);
return 0;
}
static int handle_scan_start(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
struct bt_mesh_rpr_node cli = RPR_NODE(ctx);
enum bt_mesh_rpr_status status;
const uint8_t *uuid = NULL;
uint8_t max_devs;
uint8_t timeout;
int i;
max_devs = net_buf_simple_pull_u8(buf);
timeout = net_buf_simple_pull_u8(buf);
if (!timeout) {
return -EINVAL;
}
if (buf->len == 16) {
uuid = net_buf_simple_pull_mem(buf, 16);
} else if (buf->len) {
return -EINVAL;
}
LOG_DBG("max %u devs, %u s %s", max_devs, timeout,
uuid ? bt_hex(uuid, 16) : "");
if (max_devs > CONFIG_BT_MESH_RPR_SRV_SCANNED_ITEMS_MAX) {
status = BT_MESH_RPR_ERR_SCANNING_CANNOT_START;
goto rsp;
}
if (srv.scan.state != BT_MESH_RPR_SCAN_IDLE &&
!rpr_node_equal(&cli, &srv.scan.cli)) {
status = BT_MESH_RPR_ERR_INVALID_STATE;
goto rsp;
}
for (i = 0; i < ARRAY_SIZE(srv.scan.devs); ++i) {
srv.scan.devs[i].flags = 0;
}
if (uuid) {
srv.scan.state = BT_MESH_RPR_SCAN_SINGLE;
srv.scan.devs[0].flags = BT_MESH_RPR_UNPROV_ACTIVE;
memcpy(srv.scan.devs[0].uuid, uuid, 16);
} else {
srv.scan.state = BT_MESH_RPR_SCAN_MULTI;
}
srv.scan.max_devs =
(max_devs ? max_devs :
CONFIG_BT_MESH_RPR_SRV_SCANNED_ITEMS_MAX);
srv.scan.cli = cli;
status = BT_MESH_RPR_SUCCESS;
atomic_set_bit(srv.flags, SCANNING);
k_work_reschedule(&srv.scan.timeout, K_SECONDS(timeout));
rsp:
scan_status_send(ctx, status);
return 0;
}
static int handle_extended_scan_start(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
BT_MESH_MODEL_BUF_DEFINE(rsp, RPR_OP_EXTENDED_SCAN_REPORT,
19 + CONFIG_BT_MESH_RPR_SRV_AD_DATA_MAX);
struct bt_mesh_rpr_node cli = RPR_NODE(ctx);
enum bt_mesh_rpr_status status;
const uint8_t *uuid;
uint8_t *ad = NULL;
uint8_t ad_count;
uint8_t timeout;
int i;
/* According to the Bluetooth Mesh specification, section 4.4.5.5.1.7, scan reports shall be
* sent as segmented messages.
*/
ctx->send_rel = true;
ad_count = net_buf_simple_pull_u8(buf);
if (buf->len < ad_count || ad_count == 0 || ad_count > 0x10) {
/* Prohibited */
return -EINVAL;
}
ad = net_buf_simple_pull_mem(buf, ad_count);
for (i = 0; i < ad_count; ++i) {
if (ad[i] == BT_DATA_NAME_SHORTENED ||
ad[i] == BT_DATA_UUID16_SOME ||
ad[i] == BT_DATA_UUID32_SOME ||
ad[i] == BT_DATA_UUID128_SOME) {
return -EINVAL;
}
for (int j = 0; j < i; j++) {
if (ad[i] == ad[j]) {
/* Duplicate entry */
return -EINVAL;
}
}
}
ad_count = MIN(ad_count, CONFIG_BT_MESH_RPR_AD_TYPES_MAX);
if (!buf->len) {
const struct bt_mesh_prov *prov = bt_mesh_prov_get();
LOG_DBG("Self scan");
/* Want our local info. Could also include additional adv data,
* but there's no functionality for this in the mesh stack at
* the moment, so we'll only include the URI (if requested)
*/
bt_mesh_model_msg_init(&rsp, RPR_OP_EXTENDED_SCAN_REPORT);
net_buf_simple_add_u8(&rsp, BT_MESH_RPR_SUCCESS);
net_buf_simple_add_mem(&rsp, prov->uuid, 16);
net_buf_simple_add_le16(&rsp, prov->oob_info);
if (prov->uri && get_ad_type(ad, ad_count, BT_DATA_URI)) {
uint8_t uri_len = strlen(prov->uri);
if (uri_len < CONFIG_BT_MESH_RPR_SRV_AD_DATA_MAX - 2) {
net_buf_simple_add_u8(&rsp, uri_len + 1);
net_buf_simple_add_u8(&rsp, BT_DATA_URI);
net_buf_simple_add_mem(&rsp, prov->uri,
uri_len);
LOG_DBG("URI added: %s", prov->uri);
} else {
LOG_WRN("URI data won't fit in scan report");
}
}
bt_mesh_model_send(mod, ctx, &rsp, NULL, NULL);
return 0;
}
if (buf->len != 17) {
return -EINVAL;
}
uuid = net_buf_simple_pull_mem(buf, 16);
timeout = net_buf_simple_pull_u8(buf);
if (IS_ENABLED(CONFIG_BT_MESH_MODEL_LOG_LEVEL_DBG)) {
struct bt_uuid_128 uuid_repr = { .uuid = { BT_UUID_TYPE_128 } };
memcpy(uuid_repr.val, uuid, 16);
LOG_DBG("%s AD types: %s", bt_uuid_str(&uuid_repr.uuid),
bt_hex(ad, ad_count));
}
if (timeout < BT_MESH_RPR_EXT_SCAN_TIME_MIN ||
timeout > BT_MESH_RPR_EXT_SCAN_TIME_MAX) {
LOG_ERR("Invalid extended scan timeout %u", timeout);
return -EINVAL;
}
if (srv.link.state != BT_MESH_RPR_LINK_IDLE) {
status = BT_MESH_RPR_ERR_LIMITED_RESOURCES;
goto rsp;
}
if (srv.scan.dev && (memcmp(srv.scan.dev->uuid, uuid, 16) ||
!rpr_node_equal(&srv.scan.cli, &cli))) {
LOG_WRN("Extended scan fail: Busy");
status = BT_MESH_RPR_ERR_LIMITED_RESOURCES;
goto rsp;
}
if (srv.scan.state == BT_MESH_RPR_SCAN_IDLE) {
srv.scan.max_devs = 1;
srv.scan.devs[0].flags = 0;
}
srv.scan.dev = unprov_get(uuid);
if (!srv.scan.dev) {
srv.scan.dev = unprov_get(NULL);
if (!srv.scan.dev) {
LOG_WRN("Extended scan fail: No memory");
status = BT_MESH_RPR_ERR_LIMITED_RESOURCES;
goto rsp;
}
memcpy(srv.scan.dev->uuid, uuid, 16);
srv.scan.dev->oob = 0;
srv.scan.dev->flags = 0;
}
memcpy(srv.scan.ad, ad, ad_count);
srv.scan.ad_count = ad_count;
net_buf_simple_reset(srv.scan.adv_data);
atomic_set_bit(srv.flags, SCANNING);
atomic_clear_bit(srv.flags, SCAN_EXT_HAS_ADDR);
srv.scan.dev->flags &= ~BT_MESH_RPR_UNPROV_REPORTED;
srv.scan.dev->flags |= BT_MESH_RPR_UNPROV_ACTIVE | BT_MESH_RPR_UNPROV_EXT;
if (srv.scan.state == BT_MESH_RPR_SCAN_IDLE) {
srv.scan.additional_time = 0;
srv.scan.cli = cli;
} else if (k_ticks_to_ms_floor32(
k_work_delayable_remaining_get(&srv.scan.timeout)) <
(timeout * MSEC_PER_SEC)) {
srv.scan.additional_time = 0;
} else {
srv.scan.additional_time =
k_ticks_to_ms_floor32(k_work_delayable_remaining_get(&srv.scan.timeout)) -
(timeout * MSEC_PER_SEC);
}
bt_mesh_scan_active_set(true);
k_work_reschedule(&srv.scan.timeout, K_SECONDS(timeout));
return 0;
rsp:
bt_mesh_model_msg_init(&rsp, RPR_OP_EXTENDED_SCAN_REPORT);
net_buf_simple_add_u8(&rsp, status);
net_buf_simple_add_mem(&rsp, uuid, 16);
bt_mesh_model_send(mod, ctx, &rsp, NULL, NULL);
return 0;
}
static int handle_scan_stop(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
if (atomic_test_bit(srv.flags, SCANNING)) {
scan_report_send();
scan_stop();
}
scan_status_send(ctx, BT_MESH_RPR_SUCCESS);
return 0;
}
static int handle_link_get(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
LOG_DBG("");
link_status_send(ctx, BT_MESH_RPR_SUCCESS);
return 0;
}
static int handle_link_open(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
bool is_refresh_procedure = (buf->len == 1);
struct bt_mesh_rpr_node cli = RPR_NODE(ctx);
int8_t timeout = LINK_OPEN_TIMEOUT_DEFAULT;
enum bt_mesh_rpr_status status;
const uint8_t *uuid;
uint8_t refresh;
int err;
if (buf->len != 1 && buf->len != 16 && buf->len != 17) {
return -EINVAL;
}
if (srv.link.state == BT_MESH_RPR_LINK_CLOSING ||
srv.link.state == BT_MESH_RPR_LINK_SENDING) {
status = BT_MESH_RPR_ERR_INVALID_STATE;
LOG_ERR("Invalid state: %u", srv.link.state);
goto rsp;
}
if (srv.link.state == BT_MESH_RPR_LINK_OPENING ||
srv.link.state == BT_MESH_RPR_LINK_ACTIVE) {
if (!rpr_node_equal(&cli, &srv.link.cli)) {
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
goto rsp;
}
if (is_refresh_procedure) {
refresh = net_buf_simple_pull_u8(buf);
if (!atomic_test_bit(srv.flags, NODE_REFRESH) ||
srv.refresh.procedure != refresh) {
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
} else {
status = BT_MESH_RPR_SUCCESS;
}
goto rsp;
}
if (atomic_test_bit(srv.flags, NODE_REFRESH)) {
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
goto rsp;
}
uuid = net_buf_simple_pull_mem(buf, 16);
if (memcmp(uuid, srv.link.dev->uuid, 16)) {
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
} else {
status = BT_MESH_RPR_SUCCESS;
}
goto rsp;
}
/* Link state is IDLE */
if (is_refresh_procedure) {
refresh = net_buf_simple_pull_u8(buf);
if (refresh > BT_MESH_RPR_NODE_REFRESH_COMPOSITION) {
LOG_ERR("Invalid refresh: %u", refresh);
return -EINVAL;
}
if (refresh == BT_MESH_RPR_NODE_REFRESH_COMPOSITION &&
!atomic_test_bit(bt_mesh.flags, BT_MESH_COMP_DIRTY)) {
LOG_WRN("Composition data page 128 missing");
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
goto rsp;
}
LOG_DBG("Node Refresh: %u", refresh);
atomic_set_bit(srv.flags, NODE_REFRESH);
srv.refresh.procedure = refresh;
srv.link.cli = cli;
srv.link.rx_pdu = 0;
srv.link.tx_pdu = 0;
srv.link.state = BT_MESH_RPR_LINK_ACTIVE;
srv.link.status = BT_MESH_RPR_SUCCESS;
srv.refresh.cb->link_opened(&pb_remote_srv, &srv);
status = BT_MESH_RPR_SUCCESS;
link_report_send();
goto rsp;
}
uuid = net_buf_simple_pull_mem(buf, 16);
if (buf->len) {
timeout = net_buf_simple_pull_u8(buf);
if (!timeout || timeout > 0x3c) {
LOG_ERR("Invalid timeout: %u", timeout);
return -EINVAL;
}
}
LOG_DBG("0x%04x: %s", cli.addr, bt_hex(uuid, 16));
/* Attempt to reuse the scanned unprovisioned device, to preserve as
* much information as possible, but fall back to hijacking the first
* slot if none was found.
*/
srv.link.dev = unprov_get(uuid);
if (!srv.link.dev) {
srv.link.dev = &srv.scan.devs[0];
memcpy(srv.link.dev->uuid, uuid, 16);
srv.link.dev->flags = 0;
}
err = bt_mesh_pb_adv.link_open(uuid, timeout, &prov_bearer_cb, &srv);
if (err) {
status = BT_MESH_RPR_ERR_LINK_CANNOT_OPEN;
goto rsp;
}
srv.link.cli = cli;
srv.link.rx_pdu = 0;
srv.link.tx_pdu = 0;
srv.link.state = BT_MESH_RPR_LINK_OPENING;
srv.link.status = BT_MESH_RPR_SUCCESS;
srv.link.dev->flags |= BT_MESH_RPR_UNPROV_HAS_LINK;
status = BT_MESH_RPR_SUCCESS;
rsp:
link_status_send(ctx, status);
return 0;
}
static int handle_link_close(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
struct bt_mesh_rpr_node cli = RPR_NODE(ctx);
enum prov_bearer_link_status reason;
reason = net_buf_simple_pull_u8(buf);
if (reason != PROV_BEARER_LINK_STATUS_SUCCESS &&
reason != PROV_BEARER_LINK_STATUS_FAIL) {
return -EINVAL;
}
LOG_DBG("");
if (srv.link.state == BT_MESH_RPR_LINK_IDLE ||
srv.link.state == BT_MESH_RPR_LINK_CLOSING) {
link_status_send(ctx, BT_MESH_RPR_SUCCESS);
return 0;
}
if (!rpr_node_equal(&cli, &srv.link.cli)) {
link_status_send(ctx, BT_MESH_RPR_ERR_INVALID_STATE);
return 0;
}
srv.link.state = BT_MESH_RPR_LINK_CLOSING;
/* Note: The response status isn't the same as the link status state,
* which will be used in the link report when the link is fully closed.
*/
link_status_send(ctx, BT_MESH_RPR_SUCCESS);
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_BY_CLIENT, reason);
return 0;
}
static int handle_pdu_send(struct bt_mesh_model *mod, struct bt_mesh_msg_ctx *ctx,
struct net_buf_simple *buf)
{
struct bt_mesh_rpr_node cli = RPR_NODE(ctx);
uint8_t pdu_num;
int err;
pdu_num = net_buf_simple_pull_u8(buf);
if (srv.link.state != BT_MESH_RPR_LINK_ACTIVE) {
LOG_WRN("Sending PDU while busy (state %u)", srv.link.state);
return 0;
}
if (!rpr_node_equal(&cli, &srv.link.cli)) {
LOG_WRN("Unknown client 0x%04x", cli.addr);
return 0;
}
if (pdu_num != srv.link.tx_pdu + 1) {
LOG_WRN("Invalid pdu number: %u, expected %u", pdu_num,
srv.link.tx_pdu + 1);
outbound_pdu_report_send();
return 0;
}
LOG_DBG("0x%02x", buf->data[0]);
if (atomic_test_bit(srv.flags, NODE_REFRESH)) {
srv.link.tx_pdu++;
outbound_pdu_report_send();
srv.refresh.cb->recv(&pb_remote_srv, srv.refresh.cb_data, buf);
} else {
srv.link.state = BT_MESH_RPR_LINK_SENDING;
err = bt_mesh_pb_adv.send(buf, pdu_send_complete, &srv);
if (err) {
link_close(
BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_SEND_PDU,
PROV_BEARER_LINK_STATUS_FAIL);
}
}
return 0;
}
const struct bt_mesh_model_op _bt_mesh_rpr_srv_op[] = {
{ RPR_OP_SCAN_CAPS_GET, BT_MESH_LEN_EXACT(0), handle_scan_caps_get },
{ RPR_OP_SCAN_GET, BT_MESH_LEN_EXACT(0), handle_scan_get },
{ RPR_OP_SCAN_START, BT_MESH_LEN_MIN(2), handle_scan_start },
{ RPR_OP_EXTENDED_SCAN_START, BT_MESH_LEN_MIN(1), handle_extended_scan_start },
{ RPR_OP_SCAN_STOP, BT_MESH_LEN_EXACT(0), handle_scan_stop },
{ RPR_OP_LINK_GET, BT_MESH_LEN_EXACT(0), handle_link_get },
{ RPR_OP_LINK_OPEN, BT_MESH_LEN_MIN(1), handle_link_open },
{ RPR_OP_LINK_CLOSE, BT_MESH_LEN_EXACT(1), handle_link_close },
{ RPR_OP_PDU_SEND, BT_MESH_LEN_MIN(1), handle_pdu_send },
BT_MESH_MODEL_OP_END,
};
static struct bt_mesh_rpr_unprov *
adv_handle_beacon(const struct bt_le_scan_recv_info *info,
struct bt_data *ad)
{
struct bt_uuid_128 uuid_repr = { .uuid = { BT_UUID_TYPE_128 } };
struct bt_mesh_rpr_unprov *dev = NULL;
const uint8_t *uuid;
if (ad->data[0] != 0x00 || (ad->data_len != 19 && ad->data_len != 23)) {
return NULL;
}
uuid = &ad->data[1];
dev = unprov_get(uuid);
if (!dev) {
if (srv.scan.state != BT_MESH_RPR_SCAN_MULTI) {
return NULL;
}
dev = unprov_get(NULL);
if (!dev) {
return NULL;
}
memcpy(dev->uuid, uuid, 16);
dev->flags = BT_MESH_RPR_UNPROV_ACTIVE;
} else if (dev->flags & BT_MESH_RPR_UNPROV_FOUND) {
return dev;
}
dev->oob = sys_get_be16(&ad->data[17]);
dev->rssi = info->rssi;
if (ad->data_len == 23) {
dev->hash = sys_get_le32(&ad->data[19]);
dev->flags |= BT_MESH_RPR_UNPROV_HASH;
}
dev->flags |= BT_MESH_RPR_UNPROV_FOUND;
memcpy(uuid_repr.val, uuid, 16);
LOG_DBG("Unprov #%u: %s OOB: 0x%04x %s", dev - &srv.scan.devs[0],
bt_uuid_str(&uuid_repr.uuid), dev->oob,
(dev->flags & BT_MESH_RPR_UNPROV_HASH) ? bt_hex(&dev->hash, 4) :
"(no hash)");
if (dev != srv.scan.dev && !(dev->flags & BT_MESH_RPR_UNPROV_REPORTED)) {
scan_report_schedule();
}
return dev;
}
static bool pull_ad_data(struct net_buf_simple *buf, struct bt_data *ad)
{
uint8_t len;
if (!buf->len) {
return false;
}
len = net_buf_simple_pull_u8(buf);
if (!len || len > buf->len) {
return false;
}
ad->type = net_buf_simple_pull_u8(buf);
ad->data_len = len - sizeof(ad->type);
ad->data = net_buf_simple_pull_mem(buf, ad->data_len);
return true;
}
static void adv_handle_ext_scan(const struct bt_le_scan_recv_info *info,
struct net_buf_simple *buf)
{
struct bt_mesh_rpr_unprov *dev = NULL;
struct net_buf_simple_state initial;
struct bt_data ad;
bool uri_match = false;
bool uri_present = false;
bool is_beacon = false;
if (atomic_test_bit(srv.flags, SCAN_EXT_HAS_ADDR) &&
!bt_addr_le_cmp(&srv.scan.addr, info->addr)) {
dev = srv.scan.dev;
}
/* Do AD data walk in two rounds: First to figure out which
* unprovisioned device this is (if any), and the second to copy out
* relevant AD data to the extended scan report.
*/
net_buf_simple_save(buf, &initial);
while (pull_ad_data(buf, &ad)) {
if (ad.type == BT_DATA_URI) {
uri_present = true;
}
if (ad.type == BT_DATA_MESH_BEACON && !dev) {
dev = adv_handle_beacon(info, &ad);
is_beacon = true;
} else if (ad.type == BT_DATA_URI &&
(srv.scan.dev->flags & BT_MESH_RPR_UNPROV_HASH)) {
uint8_t hash[16];
if (bt_mesh_s1(ad.data, ad.data_len, hash) ||
memcmp(hash, &srv.scan.dev->hash, 4)) {
continue;
}
LOG_DBG("Found matching URI");
uri_match = true;
dev = srv.scan.dev;
srv.scan.dev->flags |= BT_MESH_RPR_UNPROV_EXT_ADV_RXD;
}
}
if (uri_match) {
atomic_set_bit(srv.flags, URI_MATCHED);
}
if (!dev) {
return;
}
/* Do not process advertisement if it was not identified by URI hash from beacon */
if (!(dev->flags & BT_MESH_RPR_UNPROV_EXT_ADV_RXD)) {
return;
}
srv.scan.addr = *info->addr;
atomic_set_bit(srv.flags, SCAN_EXT_HAS_ADDR);
if (IS_ENABLED(CONFIG_BT_MESH_DEBUG_MODEL)) {
struct bt_uuid_128 uuid_repr = { .uuid = { BT_UUID_TYPE_128 } };
memcpy(uuid_repr.val, dev->uuid, 16);
LOG_DBG("Is %s", bt_uuid_str(&uuid_repr.uuid));
}
net_buf_simple_restore(buf, &initial);
/* The ADTypeFilter field of the Remote Provisioning Extended Scan Start message
* contains only the URI AD Type, and the URI Hash is not available for the device
* with the Device UUID that was requested in the Remote Provisioning Extended Scan
* Start message.
*/
if (srv.scan.ad_count == 1 &&
get_ad_type(srv.scan.ad, 1, BT_DATA_URI) &&
!uri_match) {
goto complete;
}
while (srv.scan.ad_count && pull_ad_data(buf, &ad)) {
uint8_t *ad_entry;
ad_entry = get_ad_type(srv.scan.ad, srv.scan.ad_count, ad.type);
if (!ad_entry || (ad.type == BT_DATA_URI && !uri_match)) {
continue;
}
LOG_DBG("AD type 0x%02x", ad.type);
if (ad.type == BT_DATA_URI) {
atomic_set_bit(srv.flags, URI_REQUESTED);
}
if (ad.data_len + 2 >
net_buf_simple_tailroom(srv.scan.adv_data)) {
LOG_WRN("Can't fit AD 0x%02x in scan report", ad.type);
continue;
}
net_buf_simple_add_u8(srv.scan.adv_data, ad.data_len + 1);
net_buf_simple_add_u8(srv.scan.adv_data, ad.type);
net_buf_simple_add_mem(srv.scan.adv_data, ad.data, ad.data_len);
*ad_entry = srv.scan.ad[--srv.scan.ad_count];
}
/* The Remote Provisioning Server collects AD structures corresponding to all
* AD Types specified in the ADTypeFilter field of the Remote Provisioning Extended
* Scan Start message. The timeout specified in the Timeout field of the Remote
* Provisioning Extended Scan Start message expires.
* OR
* The ADTypeFilter field of the Remote Provisioning Extended Scan Start message
* contains only the URI AD Type, and the Remote Provisioning Server has received
* an advertising report or scan response with the URI corresponding to the URI Hash
* of the device with the Device UUID that was requested in the Remote Provisioning
* Extended Scan Start message.
*/
if (!srv.scan.ad_count) {
goto complete;
}
/* The ADTypeFilter field of the Remote Provisioning Extended Scan Start message does
* not contain the URI AD Type, and the Remote Provisioning Server receives and processes
* the scan response data from the device with Device UUID requested in the Remote
* Provisioning Extended Scan Start message.
*/
if (!is_beacon && !uri_present &&
info->adv_type == BT_GAP_ADV_TYPE_SCAN_RSP) {
goto complete;
}
/* The ADTypeFilter field of the Remote Provisioning Extended Scan Start message contains
* the URI AD Type and at least one different AD Type in the ADTypeFilter field, and the
* Remote Provisioning Server has received an advertising report or scan response with the
* URI corresponding to the URI Hash of the device with the Device UUID that was requested
* in the Remote Provisioning Extended Scan Start message, and the Remote Provisioning
* Server received the scan response from the same device.
* OR
* The ADTypeFilter field of the Remote Provisioning Extended Scan Start message contains
* the URI AD Type and at least one different AD Type in the ADTypeFilter field, and the
* URI Hash is not available for the device with the Device UUID that was requested in the
* Remote Provisioning Extended Scan Start message, and the Remote Provisioning Server
* received the scan response from the same device.
*/
if (atomic_get(srv.flags) & URI_REQUESTED &&
(atomic_get(srv.flags) & URI_MATCHED ||
(dev->flags & ~BT_MESH_RPR_UNPROV_HASH)) &&
info->adv_type == BT_GAP_ADV_TYPE_SCAN_RSP) {
goto complete;
}
return;
complete:
srv.scan.additional_time = 0;
if (srv.scan.state != BT_MESH_RPR_SCAN_MULTI) {
k_work_cancel_delayable(&srv.scan.timeout);
}
scan_ext_stop(0);
}
static void adv_handle_scan(const struct bt_le_scan_recv_info *info,
struct net_buf_simple *buf)
{
struct bt_data ad;
if (info->adv_type != BT_HCI_ADV_NONCONN_IND) {
return;
}
while (pull_ad_data(buf, &ad)) {
if (ad.type == BT_DATA_MESH_BEACON) {
adv_handle_beacon(info, &ad);
return;
}
}
}
static void scan_packet_recv(const struct bt_le_scan_recv_info *info,
struct net_buf_simple *buf)
{
if (!atomic_test_bit(srv.flags, SCANNING)) {
return;
}
if (srv.scan.dev) {
adv_handle_ext_scan(info, buf);
} else {
adv_handle_scan(info, buf);
}
}
static struct bt_le_scan_cb scan_cb = {
.recv = scan_packet_recv,
};
static int rpr_srv_init(struct bt_mesh_model *mod)
{
if (mod->elem_idx || srv.mod) {
LOG_ERR("Remote provisioning server must be initialized "
"on first element");
return -EINVAL;
}
srv.mod = mod;
net_buf_simple_init(srv.scan.adv_data, 0);
k_work_init_delayable(&srv.scan.timeout, scan_timeout);
k_work_init_delayable(&srv.scan.report, scan_report_timeout);
k_work_init(&srv.link.report, link_report_send_and_clear);
bt_le_scan_cb_register(&scan_cb);
mod->keys[0] = BT_MESH_KEY_DEV_LOCAL;
mod->flags |= BT_MESH_MOD_DEVKEY_ONLY;
return 0;
}
static void rpr_srv_reset(struct bt_mesh_model *mod)
{
cli_link_clear();
cli_scan_clear();
srv.scan.state = BT_MESH_RPR_SCAN_IDLE;
srv.link.state = BT_MESH_RPR_LINK_IDLE;
k_work_cancel_delayable(&srv.scan.timeout);
k_work_cancel_delayable(&srv.scan.report);
net_buf_simple_init(srv.scan.adv_data, 0);
atomic_clear(srv.flags);
srv.link.dev = NULL;
srv.scan.dev = NULL;
srv.mod = NULL;
}
const struct bt_mesh_model_cb _bt_mesh_rpr_srv_cb = {
.init = rpr_srv_init,
.reset = rpr_srv_reset,
};
static int node_refresh_link_accept(const struct prov_bearer_cb *cb,
void *cb_data)
{
srv.refresh.cb = cb;
srv.refresh.cb_data = cb_data;
return 0;
}
static void node_refresh_tx_complete(int err, void *cb_data)
{
if (err) {
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_AS_CANNOT_SEND_PDU,
PROV_BEARER_LINK_STATUS_FAIL);
return;
}
if (srv.refresh.tx.cb) {
srv.refresh.tx.cb(err, srv.refresh.tx.cb_data);
}
}
static int node_refresh_buf_send(struct net_buf_simple *buf,
prov_bearer_send_complete_t cb, void *cb_data)
{
static const struct bt_mesh_send_cb send_cb = {
.end = node_refresh_tx_complete,
};
int err;
if (!atomic_test_bit(srv.flags, NODE_REFRESH)) {
return -EBUSY;
}
srv.refresh.tx.cb = cb;
srv.refresh.tx.cb_data = cb_data;
srv.link.rx_pdu++;
LOG_DBG("%u", srv.link.rx_pdu);
err = inbound_pdu_send(buf, &send_cb);
if (err) {
link_close(BT_MESH_RPR_ERR_LINK_CLOSED_BY_SERVER,
PROV_BEARER_LINK_STATUS_FAIL);
}
return err;
}
static void node_refresh_clear_tx(void)
{
/* Nothing can be done */
}
const struct prov_bearer pb_remote_srv = {
.type = BT_MESH_PROV_REMOTE,
.link_accept = node_refresh_link_accept,
.send = node_refresh_buf_send,
.clear_tx = node_refresh_clear_tx,
};