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zephyr/subsys/bluetooth/mesh/pb_adv.c
Michał Narajowski 497d9df96a Bluetooth: Mesh: Send Link Close message when closing link 
Instead of silently closing the link we should send a Link Close message
three times before resetting provisioning state.

From Mesh Profile Specification v1.0.1.:
```
5.3.1.4.3 Link Close message

The Link Close message is used to close a link.
```

```
5.3.2 Link Establishment procedure

The device shall start the link timer, set to 60 seconds, when the link
is open. When the link timer expires, then the device shall close the
link.
```

```
5.3.3 Generic Provisioning behavior

If the sender does not receive a Transaction Acknowledgment message
within 30 seconds after sending the first message in a transaction,
the sender shall cancel the transaction, cancel the provisioning
process and close the link.
```

From Mesh Profile Test Specification p6:
```
MESH/PVNR/PBADV/BV-01-C

Test Procedure:
[...]
6. The IUT is induced to send a Link Close message with the Reason field
set to 0x02 to terminate the link. The message is sent at least three
times to ensure the message is received by the Lower Tester.
```

Signed-off-by: Michał Narajowski <michal.narajowski@codecoup.pl>
2021-03-15 16:54:44 +02:00

904 lines
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/* Bluetooth Mesh */
/*
* Copyright (c) 2017 Intel Corporation
* Copyright (c) 2020 Nordic Semiconductor ASA
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stdint.h>
#include <string.h>
#include <bluetooth/conn.h>
#include <bluetooth/mesh.h>
#include <net/buf.h>
#include "host/testing.h"
#include "net.h"
#include "adv.h"
#include "crypto.h"
#include "beacon.h"
#include "prov.h"
#define BT_DBG_ENABLED IS_ENABLED(CONFIG_BT_MESH_DEBUG_PROV)
#define LOG_MODULE_NAME bt_mesh_pb_adv
#include "common/log.h"
#define GPCF(gpc) (gpc & 0x03)
#define GPC_START(last_seg) (((last_seg) << 2) | 0x00)
#define GPC_ACK 0x01
#define GPC_CONT(seg_id) (((seg_id) << 2) | 0x02)
#define GPC_CTL(op) (((op) << 2) | 0x03)
#define START_PAYLOAD_MAX 20
#define CONT_PAYLOAD_MAX 23
#define START_LAST_SEG(gpc) (gpc >> 2)
#define CONT_SEG_INDEX(gpc) (gpc >> 2)
#define BEARER_CTL(gpc) (gpc >> 2)
#define LINK_OPEN 0x00
#define LINK_ACK 0x01
#define LINK_CLOSE 0x02
#define XACT_SEG_DATA(_seg) (&link.rx.buf->data[20 + ((_seg - 1) * 23)])
#define XACT_SEG_RECV(_seg) (link.rx.seg &= ~(1 << (_seg)))
#define XACT_ID_MAX 0x7f
#define XACT_ID_NVAL 0xff
#define SEG_NVAL 0xff
#define RETRANSMIT_TIMEOUT K_MSEC(CONFIG_BT_MESH_PB_ADV_RETRANS_TIMEOUT)
#define BUF_TIMEOUT K_MSEC(400)
#define CLOSING_TIMEOUT (3 * MSEC_PER_SEC)
#define TRANSACTION_TIMEOUT (30 * MSEC_PER_SEC)
/* Acked messages, will do retransmissions manually, taking acks into account:
*/
#define RETRANSMITS_RELIABLE 0
/* Unacked messages: */
#define RETRANSMITS_UNRELIABLE 2
/* PDU acks: */
#define RETRANSMITS_ACK 2
enum {
ADV_LINK_ACTIVE, /* Link has been opened */
ADV_LINK_ACK_RECVD, /* Ack for link has been received */
ADV_LINK_CLOSING, /* Link is closing down */
ADV_LINK_INVALID, /* Error occurred during provisioning */
ADV_ACK_PENDING, /* An acknowledgment is being sent */
ADV_PROVISIONER, /* The link was opened as provisioner */
ADV_NUM_FLAGS,
};
struct pb_adv {
uint32_t id; /* Link ID */
ATOMIC_DEFINE(flags, ADV_NUM_FLAGS);
const struct prov_bearer_cb *cb;
void *cb_data;
struct {
uint8_t id; /* Most recent transaction ID */
uint8_t seg; /* Bit-field of unreceived segments */
uint8_t last_seg; /* Last segment (to check length) */
uint8_t fcs; /* Expected FCS value */
struct net_buf_simple *buf;
} rx;
struct {
/* Start timestamp of the transaction */
int64_t start;
/* Transaction id */
uint8_t id;
/* Current ack id */
uint8_t pending_ack;
/* Pending outgoing buffer(s) */
struct net_buf *buf[3];
prov_bearer_send_complete_t cb;
void *cb_data;
/* Retransmit timer */
struct k_delayed_work retransmit;
} tx;
/* Protocol timeout */
struct k_delayed_work prot_timer;
};
struct prov_rx {
uint32_t link_id;
uint8_t xact_id;
uint8_t gpc;
};
NET_BUF_SIMPLE_DEFINE_STATIC(rx_buf, 65);
static struct pb_adv link = { .rx = { .buf = &rx_buf } };
static void gen_prov_ack_send(uint8_t xact_id);
static void link_open(struct prov_rx *rx, struct net_buf_simple *buf);
static void link_ack(struct prov_rx *rx, struct net_buf_simple *buf);
static void link_close(struct prov_rx *rx, struct net_buf_simple *buf);
static void prov_link_close(enum prov_bearer_link_status status);
static void buf_sent(int err, void *user_data)
{
if (!link.tx.buf[0]) {
return;
}
k_delayed_work_submit(&link.tx.retransmit, RETRANSMIT_TIMEOUT);
}
static struct bt_mesh_send_cb buf_sent_cb = {
.end = buf_sent,
};
static uint8_t last_seg(uint8_t len)
{
if (len <= START_PAYLOAD_MAX) {
return 0;
}
len -= START_PAYLOAD_MAX;
return 1 + (len / CONT_PAYLOAD_MAX);
}
static void free_segments(void)
{
int i;
for (i = 0; i < ARRAY_SIZE(link.tx.buf); i++) {
struct net_buf *buf = link.tx.buf[i];
if (!buf) {
break;
}
link.tx.buf[i] = NULL;
/* Mark as canceled */
BT_MESH_ADV(buf)->busy = 0U;
net_buf_unref(buf);
}
}
static uint8_t next_transaction_id(uint8_t id)
{
return (((id + 1) & XACT_ID_MAX) | (id & (XACT_ID_MAX+1)));
}
static void prov_clear_tx(void)
{
BT_DBG("");
k_delayed_work_cancel(&link.tx.retransmit);
free_segments();
}
static void reset_adv_link(void)
{
BT_DBG("");
prov_clear_tx();
k_delayed_work_cancel(&link.prot_timer);
if (atomic_test_bit(link.flags, ADV_PROVISIONER)) {
/* Clear everything except the retransmit and protocol timer
* delayed work objects.
*/
(void)memset(&link, 0, offsetof(struct pb_adv, tx.retransmit));
link.rx.id = XACT_ID_NVAL;
} else {
/* Accept another provisioning attempt */
link.id = 0;
atomic_clear(link.flags);
link.rx.id = XACT_ID_MAX;
link.tx.id = XACT_ID_NVAL;
}
link.tx.pending_ack = XACT_ID_NVAL;
link.rx.buf = &rx_buf;
net_buf_simple_reset(link.rx.buf);
}
static void close_link(enum prov_bearer_link_status reason)
{
const struct prov_bearer_cb *cb = link.cb;
void *cb_data = link.cb_data;
reset_adv_link();
cb->link_closed(&pb_adv, cb_data, reason);
}
static struct net_buf *adv_buf_create(uint8_t retransmits)
{
struct net_buf *buf;
buf = bt_mesh_adv_create(BT_MESH_ADV_PROV,
BT_MESH_TRANSMIT(retransmits, 20),
BUF_TIMEOUT);
if (!buf) {
BT_ERR("Out of provisioning buffers");
return NULL;
}
return buf;
}
static void ack_complete(uint16_t duration, int err, void *user_data)
{
BT_DBG("xact 0x%x complete", (uint8_t)link.tx.pending_ack);
atomic_clear_bit(link.flags, ADV_ACK_PENDING);
}
static bool ack_pending(void)
{
return atomic_test_bit(link.flags, ADV_ACK_PENDING);
}
static void prov_failed(uint8_t err)
{
BT_DBG("%u", err);
link.cb->error(&pb_adv, link.cb_data, err);
atomic_set_bit(link.flags, ADV_LINK_INVALID);
}
static void prov_msg_recv(void)
{
k_delayed_work_submit(&link.prot_timer, PROTOCOL_TIMEOUT);
if (!bt_mesh_fcs_check(link.rx.buf, link.rx.fcs)) {
BT_ERR("Incorrect FCS");
return;
}
gen_prov_ack_send(link.rx.id);
if (atomic_test_bit(link.flags, ADV_LINK_INVALID)) {
BT_WARN("Unexpected msg 0x%02x on invalidated link",
link.rx.buf->data[0]);
prov_failed(PROV_ERR_UNEXP_PDU);
return;
}
link.cb->recv(&pb_adv, link.cb_data, link.rx.buf);
}
static void protocol_timeout(struct k_work *work)
{
BT_DBG("");
link.rx.seg = 0U;
prov_link_close(PROV_BEARER_LINK_STATUS_TIMEOUT);
}
/*******************************************************************************
* Generic provisioning
******************************************************************************/
static void gen_prov_ack_send(uint8_t xact_id)
{
static const struct bt_mesh_send_cb cb = {
.start = ack_complete,
};
const struct bt_mesh_send_cb *complete;
struct net_buf *buf;
bool pending = atomic_test_and_set_bit(link.flags, ADV_ACK_PENDING);
BT_DBG("xact_id 0x%x", xact_id);
if (pending && link.tx.pending_ack == xact_id) {
BT_DBG("Not sending duplicate ack");
return;
}
buf = adv_buf_create(RETRANSMITS_ACK);
if (!buf) {
atomic_clear_bit(link.flags, ADV_ACK_PENDING);
return;
}
if (pending) {
complete = NULL;
} else {
link.tx.pending_ack = xact_id;
complete = &cb;
}
net_buf_add_be32(buf, link.id);
net_buf_add_u8(buf, xact_id);
net_buf_add_u8(buf, GPC_ACK);
bt_mesh_adv_send(buf, complete, NULL);
net_buf_unref(buf);
}
static void gen_prov_cont(struct prov_rx *rx, struct net_buf_simple *buf)
{
uint8_t seg = CONT_SEG_INDEX(rx->gpc);
BT_DBG("len %u, seg_index %u", buf->len, seg);
if (!link.rx.seg && link.rx.id == rx->xact_id) {
if (!ack_pending()) {
BT_DBG("Resending ack");
gen_prov_ack_send(rx->xact_id);
}
return;
}
if (!link.rx.seg &&
next_transaction_id(link.rx.id) == rx->xact_id) {
BT_DBG("Start segment lost");
link.rx.id = rx->xact_id;
net_buf_simple_reset(link.rx.buf);
link.rx.seg = SEG_NVAL;
link.rx.last_seg = SEG_NVAL;
prov_clear_tx();
} else if (rx->xact_id != link.rx.id) {
BT_WARN("Data for unknown transaction (0x%x != 0x%x)",
rx->xact_id, link.rx.id);
return;
}
if (seg > link.rx.last_seg) {
BT_ERR("Invalid segment index %u", seg);
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
if (!(link.rx.seg & BIT(seg))) {
BT_DBG("Ignoring already received segment");
return;
}
memcpy(XACT_SEG_DATA(seg), buf->data, buf->len);
XACT_SEG_RECV(seg);
if (seg == link.rx.last_seg && !(link.rx.seg & BIT(0))) {
uint8_t expect_len;
expect_len = (link.rx.buf->len - 20U -
((link.rx.last_seg - 1) * 23U));
if (expect_len != buf->len) {
BT_ERR("Incorrect last seg len: %u != %u", expect_len,
buf->len);
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
}
if (!link.rx.seg) {
prov_msg_recv();
}
}
static void gen_prov_ack(struct prov_rx *rx, struct net_buf_simple *buf)
{
BT_DBG("len %u", buf->len);
if (!link.tx.buf[0]) {
return;
}
if (rx->xact_id == link.tx.id) {
/* Don't clear resending of link_close messages */
if (!atomic_test_bit(link.flags, ADV_LINK_CLOSING)) {
prov_clear_tx();
}
if (link.tx.cb) {
link.tx.cb(0, link.tx.cb_data);
}
}
}
static void gen_prov_start(struct prov_rx *rx, struct net_buf_simple *buf)
{
uint8_t seg = SEG_NVAL;
if (rx->xact_id == link.rx.id) {
if (!link.rx.seg) {
if (!ack_pending()) {
BT_DBG("Resending ack");
gen_prov_ack_send(rx->xact_id);
}
return;
}
if (!(link.rx.seg & BIT(0))) {
BT_DBG("Ignoring duplicate segment");
return;
}
} else if (rx->xact_id != next_transaction_id(link.rx.id)) {
BT_WARN("Unexpected xact 0x%x, expected 0x%x", rx->xact_id,
next_transaction_id(link.rx.id));
return;
}
net_buf_simple_reset(link.rx.buf);
link.rx.buf->len = net_buf_simple_pull_be16(buf);
link.rx.id = rx->xact_id;
link.rx.fcs = net_buf_simple_pull_u8(buf);
BT_DBG("len %u last_seg %u total_len %u fcs 0x%02x", buf->len,
START_LAST_SEG(rx->gpc), link.rx.buf->len, link.rx.fcs);
if (link.rx.buf->len < 1) {
BT_ERR("Ignoring zero-length provisioning PDU");
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
if (link.rx.buf->len > link.rx.buf->size) {
BT_ERR("Too large provisioning PDU (%u bytes)",
link.rx.buf->len);
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
if (START_LAST_SEG(rx->gpc) > 0 && link.rx.buf->len <= 20U) {
BT_ERR("Too small total length for multi-segment PDU");
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
prov_clear_tx();
link.rx.last_seg = START_LAST_SEG(rx->gpc);
if ((link.rx.seg & BIT(0)) &&
(find_msb_set((~link.rx.seg) & SEG_NVAL) - 1 > link.rx.last_seg)) {
BT_ERR("Invalid segment index %u", seg);
prov_failed(PROV_ERR_NVAL_FMT);
return;
}
if (link.rx.seg) {
seg = link.rx.seg;
}
link.rx.seg = seg & ((1 << (START_LAST_SEG(rx->gpc) + 1)) - 1);
memcpy(link.rx.buf->data, buf->data, buf->len);
XACT_SEG_RECV(0);
if (!link.rx.seg) {
prov_msg_recv();
}
}
static void gen_prov_ctl(struct prov_rx *rx, struct net_buf_simple *buf)
{
BT_DBG("op 0x%02x len %u", BEARER_CTL(rx->gpc), buf->len);
switch (BEARER_CTL(rx->gpc)) {
case LINK_OPEN:
link_open(rx, buf);
break;
case LINK_ACK:
if (!atomic_test_bit(link.flags, ADV_LINK_ACTIVE)) {
return;
}
link_ack(rx, buf);
break;
case LINK_CLOSE:
if (!atomic_test_bit(link.flags, ADV_LINK_ACTIVE)) {
return;
}
link_close(rx, buf);
break;
default:
BT_ERR("Unknown bearer opcode: 0x%02x", BEARER_CTL(rx->gpc));
if (IS_ENABLED(CONFIG_BT_TESTING)) {
bt_test_mesh_prov_invalid_bearer(BEARER_CTL(rx->gpc));
}
return;
}
}
static const struct {
void (*func)(struct prov_rx *rx, struct net_buf_simple *buf);
bool require_link;
uint8_t min_len;
} gen_prov[] = {
{ gen_prov_start, true, 3 },
{ gen_prov_ack, true, 0 },
{ gen_prov_cont, true, 0 },
{ gen_prov_ctl, false, 0 },
};
static void gen_prov_recv(struct prov_rx *rx, struct net_buf_simple *buf)
{
if (buf->len < gen_prov[GPCF(rx->gpc)].min_len) {
BT_ERR("Too short GPC message type %u", GPCF(rx->gpc));
return;
}
if (!atomic_test_bit(link.flags, ADV_LINK_ACTIVE) &&
gen_prov[GPCF(rx->gpc)].require_link) {
BT_DBG("Ignoring message that requires active link");
return;
}
gen_prov[GPCF(rx->gpc)].func(rx, buf);
}
/*******************************************************************************
* TX
******************************************************************************/
static void send_reliable(void)
{
int i;
link.tx.start = k_uptime_get();
for (i = 0; i < ARRAY_SIZE(link.tx.buf); i++) {
struct net_buf *buf = link.tx.buf[i];
if (!buf) {
break;
}
if (i + 1 < ARRAY_SIZE(link.tx.buf) && link.tx.buf[i + 1]) {
bt_mesh_adv_send(buf, NULL, NULL);
} else {
bt_mesh_adv_send(buf, &buf_sent_cb, NULL);
}
}
}
static void prov_retransmit(struct k_work *work)
{
int32_t timeout_ms;
int i;
BT_DBG("");
if (!atomic_test_bit(link.flags, ADV_LINK_ACTIVE)) {
BT_WARN("Link not active");
return;
}
/*
* According to mesh profile spec (5.3.1.4.3), the close message should
* be restransmitted at least three times. Retransmit the link_close
* message until CLOSING_TIMEOUT has elapsed.
*/
if (atomic_test_bit(link.flags, ADV_LINK_CLOSING)) {
timeout_ms = CLOSING_TIMEOUT;
} else {
timeout_ms = TRANSACTION_TIMEOUT;
}
if (k_uptime_get() - link.tx.start > timeout_ms) {
if (atomic_test_bit(link.flags, ADV_LINK_CLOSING)) {
close_link(PROV_BEARER_LINK_STATUS_SUCCESS);
} else {
BT_WARN("Giving up transaction");
prov_link_close(PROV_BEARER_LINK_STATUS_FAIL);
}
return;
}
for (i = 0; i < ARRAY_SIZE(link.tx.buf); i++) {
struct net_buf *buf = link.tx.buf[i];
if (!buf) {
break;
}
if (BT_MESH_ADV(buf)->busy) {
continue;
}
BT_DBG("%u bytes: %s", buf->len, bt_hex(buf->data, buf->len));
if (i + 1 < ARRAY_SIZE(link.tx.buf) && link.tx.buf[i + 1]) {
bt_mesh_adv_send(buf, NULL, NULL);
} else {
bt_mesh_adv_send(buf, &buf_sent_cb, NULL);
}
}
}
static int bearer_ctl_send(uint8_t op, const void *data, uint8_t data_len,
bool reliable)
{
struct net_buf *buf;
BT_DBG("op 0x%02x data_len %u", op, data_len);
prov_clear_tx();
k_delayed_work_submit(&link.prot_timer, PROTOCOL_TIMEOUT);
buf = adv_buf_create(reliable ? RETRANSMITS_RELIABLE :
RETRANSMITS_UNRELIABLE);
if (!buf) {
return -ENOBUFS;
}
net_buf_add_be32(buf, link.id);
/* Transaction ID, always 0 for Bearer messages */
net_buf_add_u8(buf, 0x00);
net_buf_add_u8(buf, GPC_CTL(op));
net_buf_add_mem(buf, data, data_len);
if (reliable) {
link.tx.buf[0] = buf;
send_reliable();
} else {
bt_mesh_adv_send(buf, &buf_sent_cb, NULL);
net_buf_unref(buf);
}
return 0;
}
static int prov_send_adv(struct net_buf_simple *msg,
prov_bearer_send_complete_t cb, void *cb_data)
{
struct net_buf *start, *buf;
uint8_t seg_len, seg_id;
prov_clear_tx();
k_delayed_work_submit(&link.prot_timer, PROTOCOL_TIMEOUT);
start = adv_buf_create(RETRANSMITS_RELIABLE);
if (!start) {
return -ENOBUFS;
}
link.tx.id = next_transaction_id(link.tx.id);
net_buf_add_be32(start, link.id);
net_buf_add_u8(start, link.tx.id);
net_buf_add_u8(start, GPC_START(last_seg(msg->len)));
net_buf_add_be16(start, msg->len);
net_buf_add_u8(start, bt_mesh_fcs_calc(msg->data, msg->len));
link.tx.buf[0] = start;
link.tx.cb = cb;
link.tx.cb_data = cb_data;
BT_DBG("xact_id: 0x%x len: %u", link.tx.id, msg->len);
seg_len = MIN(msg->len, START_PAYLOAD_MAX);
BT_DBG("seg 0 len %u: %s", seg_len, bt_hex(msg->data, seg_len));
net_buf_add_mem(start, msg->data, seg_len);
net_buf_simple_pull(msg, seg_len);
buf = start;
for (seg_id = 1U; msg->len > 0; seg_id++) {
if (seg_id >= ARRAY_SIZE(link.tx.buf)) {
BT_ERR("Too big message");
free_segments();
return -E2BIG;
}
buf = adv_buf_create(RETRANSMITS_RELIABLE);
if (!buf) {
free_segments();
return -ENOBUFS;
}
link.tx.buf[seg_id] = buf;
seg_len = MIN(msg->len, CONT_PAYLOAD_MAX);
BT_DBG("seg %u len %u: %s", seg_id, seg_len,
bt_hex(msg->data, seg_len));
net_buf_add_be32(buf, link.id);
net_buf_add_u8(buf, link.tx.id);
net_buf_add_u8(buf, GPC_CONT(seg_id));
net_buf_add_mem(buf, msg->data, seg_len);
net_buf_simple_pull(msg, seg_len);
}
send_reliable();
return 0;
}
/*******************************************************************************
* Link management rx
******************************************************************************/
static void link_open(struct prov_rx *rx, struct net_buf_simple *buf)
{
BT_DBG("len %u", buf->len);
if (buf->len < 16) {
BT_ERR("Too short bearer open message (len %u)", buf->len);
return;
}
if (atomic_test_bit(link.flags, ADV_LINK_ACTIVE)) {
/* Send another link ack if the provisioner missed the last */
if (link.id == rx->link_id) {
BT_DBG("Resending link ack");
bearer_ctl_send(LINK_ACK, NULL, 0, false);
} else {
BT_DBG("Ignoring bearer open: link already active");
}
return;
}
if (memcmp(buf->data, bt_mesh_prov_get()->uuid, 16)) {
BT_DBG("Bearer open message not for us");
return;
}
link.id = rx->link_id;
atomic_set_bit(link.flags, ADV_LINK_ACTIVE);
net_buf_simple_reset(link.rx.buf);
bearer_ctl_send(LINK_ACK, NULL, 0, false);
link.cb->link_opened(&pb_adv, link.cb_data);
}
static void link_ack(struct prov_rx *rx, struct net_buf_simple *buf)
{
BT_DBG("len %u", buf->len);
if (atomic_test_bit(link.flags, ADV_PROVISIONER)) {
if (atomic_test_and_set_bit(link.flags, ADV_LINK_ACK_RECVD)) {
return;
}
prov_clear_tx();
link.cb->link_opened(&pb_adv, link.cb_data);
}
}
static void link_close(struct prov_rx *rx, struct net_buf_simple *buf)
{
BT_DBG("len %u", buf->len);
if (buf->len != 1) {
return;
}
close_link(net_buf_simple_pull_u8(buf));
}
/*******************************************************************************
* Higher level functionality
******************************************************************************/
void bt_mesh_pb_adv_recv(struct net_buf_simple *buf)
{
struct prov_rx rx;
if (!link.cb) {
return;
}
if (buf->len < 6) {
BT_WARN("Too short provisioning packet (len %u)", buf->len);
return;
}
rx.link_id = net_buf_simple_pull_be32(buf);
rx.xact_id = net_buf_simple_pull_u8(buf);
rx.gpc = net_buf_simple_pull_u8(buf);
if (atomic_test_bit(link.flags, ADV_LINK_ACTIVE) && link.id != rx.link_id) {
return;
}
BT_DBG("link_id 0x%08x xact_id 0x%x", rx.link_id, rx.xact_id);
gen_prov_recv(&rx, buf);
}
static int prov_link_open(const uint8_t uuid[16], k_timeout_t timeout,
const struct prov_bearer_cb *cb, void *cb_data)
{
int err;
BT_DBG("uuid %s", bt_hex(uuid, 16));
err = bt_mesh_adv_enable();
if (err) {
BT_ERR("Failed enabling advertiser");
return err;
}
if (atomic_test_and_set_bit(link.flags, ADV_LINK_ACTIVE)) {
return -EBUSY;
}
atomic_set_bit(link.flags, ADV_PROVISIONER);
bt_rand(&link.id, sizeof(link.id));
link.tx.id = XACT_ID_MAX;
link.rx.id = XACT_ID_NVAL;
link.cb = cb;
link.cb_data = cb_data;
net_buf_simple_reset(link.rx.buf);
bearer_ctl_send(LINK_OPEN, uuid, 16, true);
return 0;
}
static int prov_link_accept(const struct prov_bearer_cb *cb, void *cb_data)
{
int err;
err = bt_mesh_adv_enable();
if (err) {
BT_ERR("Failed enabling advertiser");
return err;
}
if (atomic_test_bit(link.flags, ADV_LINK_ACTIVE)) {
return -EBUSY;
}
link.rx.id = XACT_ID_MAX;
link.tx.id = XACT_ID_NVAL;
link.cb = cb;
link.cb_data = cb_data;
/* Make sure we're scanning for provisioning inviations */
bt_mesh_scan_enable();
/* Enable unprovisioned beacon sending */
bt_mesh_beacon_enable();
return 0;
}
static void prov_link_close(enum prov_bearer_link_status status)
{
if (atomic_test_and_set_bit(link.flags, ADV_LINK_CLOSING)) {
return;
}
bearer_ctl_send(LINK_CLOSE, &status, 1, true);
}
void pb_adv_init(void)
{
k_delayed_work_init(&link.prot_timer, protocol_timeout);
k_delayed_work_init(&link.tx.retransmit, prov_retransmit);
}
void pb_adv_reset(void)
{
reset_adv_link();
}
const struct prov_bearer pb_adv = {
.type = BT_MESH_PROV_ADV,
.link_open = prov_link_open,
.link_accept = prov_link_accept,
.link_close = prov_link_close,
.send = prov_send_adv,
.clear_tx = prov_clear_tx,
};
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