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zephyr/subsys/bluetooth/host/rfcomm.c
Johan Hedberg 2975ca0754 Bluetooth: Kconfig: Rename CONFIG_BLUETOOTH_* to CONFIG_BT_* 
The API name space for Bluetooth is bt_* and BT_* so it makes sense to
align the Kconfig name space with this. The additional benefit is that
this also makes the names shorter. It is also in line with what Linux
uses for Bluetooth Kconfig entries.

Some Bluetooth-related Networking Kconfig defines are renamed as well
in order to be consistent, such as NET_L2_BLUETOOTH.

Signed-off-by: Johan Hedberg <johan.hedberg@intel.com>
2017-08-09 11:14:19 +03:00

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/* rfcomm.c - RFCOMM handling */
/*
* Copyright (c) 2016 Intel Corporation
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr.h>
#include <string.h>
#include <errno.h>
#include <atomic.h>
#include <misc/byteorder.h>
#include <misc/util.h>
#include <misc/stack.h>
#include <bluetooth/hci.h>
#include <bluetooth/bluetooth.h>
#include <bluetooth/conn.h>
#include <bluetooth/hci_driver.h>
#include <bluetooth/l2cap.h>
#define BT_DBG_ENABLED IS_ENABLED(CONFIG_BT_DEBUG_RFCOMM)
/* FIXME: #include "common/log.h" */
#include <bluetooth/rfcomm.h>
#include "hci_core.h"
#include "conn_internal.h"
#include "l2cap_internal.h"
#include "rfcomm_internal.h"
#define RFCOMM_CHANNEL_START 0x01
#define RFCOMM_CHANNEL_END 0x1e
#define RFCOMM_MIN_MTU BT_RFCOMM_SIG_MIN_MTU
#define RFCOMM_DEFAULT_MTU 127
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
#define RFCOMM_MAX_CREDITS (CONFIG_BT_ACL_RX_COUNT - 1)
#else
#define RFCOMM_MAX_CREDITS (CONFIG_BT_RX_BUF_COUNT - 1)
#endif
#define RFCOMM_CREDITS_THRESHOLD (RFCOMM_MAX_CREDITS / 2)
#define RFCOMM_DEFAULT_CREDIT RFCOMM_MAX_CREDITS
#define RFCOMM_CONN_TIMEOUT K_SECONDS(60)
#define RFCOMM_DISC_TIMEOUT K_SECONDS(20)
#define RFCOMM_IDLE_TIMEOUT K_SECONDS(2)
#define DLC_RTX(_w) CONTAINER_OF(_w, struct bt_rfcomm_dlc, rtx_work)
#define SESSION_RTX(_w) CONTAINER_OF(_w, struct bt_rfcomm_session, rtx_work)
static struct bt_rfcomm_server *servers;
/* Pool for dummy buffers to wake up the tx threads */
NET_BUF_POOL_DEFINE(dummy_pool, CONFIG_BT_MAX_CONN, 0, 0, NULL);
#define RFCOMM_SESSION(_ch) CONTAINER_OF(_ch, \
struct bt_rfcomm_session, br_chan.chan)
static struct bt_rfcomm_session bt_rfcomm_pool[CONFIG_BT_MAX_CONN];
/* reversed, 8-bit, poly=0x07 */
static const u8_t rfcomm_crc_table[256] = {
0x00, 0x91, 0xe3, 0x72, 0x07, 0x96, 0xe4, 0x75,
0x0e, 0x9f, 0xed, 0x7c, 0x09, 0x98, 0xea, 0x7b,
0x1c, 0x8d, 0xff, 0x6e, 0x1b, 0x8a, 0xf8, 0x69,
0x12, 0x83, 0xf1, 0x60, 0x15, 0x84, 0xf6, 0x67,
0x38, 0xa9, 0xdb, 0x4a, 0x3f, 0xae, 0xdc, 0x4d,
0x36, 0xa7, 0xd5, 0x44, 0x31, 0xa0, 0xd2, 0x43,
0x24, 0xb5, 0xc7, 0x56, 0x23, 0xb2, 0xc0, 0x51,
0x2a, 0xbb, 0xc9, 0x58, 0x2d, 0xbc, 0xce, 0x5f,
0x70, 0xe1, 0x93, 0x02, 0x77, 0xe6, 0x94, 0x05,
0x7e, 0xef, 0x9d, 0x0c, 0x79, 0xe8, 0x9a, 0x0b,
0x6c, 0xfd, 0x8f, 0x1e, 0x6b, 0xfa, 0x88, 0x19,
0x62, 0xf3, 0x81, 0x10, 0x65, 0xf4, 0x86, 0x17,
0x48, 0xd9, 0xab, 0x3a, 0x4f, 0xde, 0xac, 0x3d,
0x46, 0xd7, 0xa5, 0x34, 0x41, 0xd0, 0xa2, 0x33,
0x54, 0xc5, 0xb7, 0x26, 0x53, 0xc2, 0xb0, 0x21,
0x5a, 0xcb, 0xb9, 0x28, 0x5d, 0xcc, 0xbe, 0x2f,
0xe0, 0x71, 0x03, 0x92, 0xe7, 0x76, 0x04, 0x95,
0xee, 0x7f, 0x0d, 0x9c, 0xe9, 0x78, 0x0a, 0x9b,
0xfc, 0x6d, 0x1f, 0x8e, 0xfb, 0x6a, 0x18, 0x89,
0xf2, 0x63, 0x11, 0x80, 0xf5, 0x64, 0x16, 0x87,
0xd8, 0x49, 0x3b, 0xaa, 0xdf, 0x4e, 0x3c, 0xad,
0xd6, 0x47, 0x35, 0xa4, 0xd1, 0x40, 0x32, 0xa3,
0xc4, 0x55, 0x27, 0xb6, 0xc3, 0x52, 0x20, 0xb1,
0xca, 0x5b, 0x29, 0xb8, 0xcd, 0x5c, 0x2e, 0xbf,
0x90, 0x01, 0x73, 0xe2, 0x97, 0x06, 0x74, 0xe5,
0x9e, 0x0f, 0x7d, 0xec, 0x99, 0x08, 0x7a, 0xeb,
0x8c, 0x1d, 0x6f, 0xfe, 0x8b, 0x1a, 0x68, 0xf9,
0x82, 0x13, 0x61, 0xf0, 0x85, 0x14, 0x66, 0xf7,
0xa8, 0x39, 0x4b, 0xda, 0xaf, 0x3e, 0x4c, 0xdd,
0xa6, 0x37, 0x45, 0xd4, 0xa1, 0x30, 0x42, 0xd3,
0xb4, 0x25, 0x57, 0xc6, 0xb3, 0x22, 0x50, 0xc1,
0xba, 0x2b, 0x59, 0xc8, 0xbd, 0x2c, 0x5e, 0xcf
};
static u8_t rfcomm_calc_fcs(u16_t len, const u8_t *data)
{
u8_t fcs = 0xff;
while (len--) {
fcs = rfcomm_crc_table[fcs ^ *data++];
}
/* Ones compliment */
return (0xff - fcs);
}
static bool rfcomm_check_fcs(u16_t len, const u8_t *data,
u8_t recvd_fcs)
{
u8_t fcs = 0xff;
while (len--) {
fcs = rfcomm_crc_table[fcs ^ *data++];
}
/* Ones compliment */
fcs = rfcomm_crc_table[fcs ^ recvd_fcs];
/*0xCF is the reversed order of 11110011.*/
return (fcs == 0xcf);
}
static struct bt_rfcomm_dlc *rfcomm_dlcs_lookup_dlci(struct bt_rfcomm_dlc *dlcs,
u8_t dlci)
{
for (; dlcs; dlcs = dlcs->_next) {
if (dlcs->dlci == dlci) {
return dlcs;
}
}
return NULL;
}
static struct bt_rfcomm_dlc *rfcomm_dlcs_remove_dlci(struct bt_rfcomm_dlc *dlcs,
u8_t dlci)
{
struct bt_rfcomm_dlc *tmp;
if (!dlcs) {
return NULL;
}
/* If first node is the one to be removed */
if (dlcs->dlci == dlci) {
dlcs->session->dlcs = dlcs->_next;
return dlcs;
}
for (tmp = dlcs, dlcs = dlcs->_next; dlcs; dlcs = dlcs->_next) {
if (dlcs->dlci == dlci) {
tmp->_next = dlcs->_next;
return dlcs;
}
tmp = dlcs;
}
return NULL;
}
static struct bt_rfcomm_server *rfcomm_server_lookup_channel(u8_t channel)
{
struct bt_rfcomm_server *server;
for (server = servers; server; server = server->_next) {
if (server->channel == channel) {
return server;
}
}
return NULL;
}
static struct bt_rfcomm_session *
rfcomm_sessions_lookup_bt_conn(struct bt_conn *conn)
{
int i;
for (i = 0; i < ARRAY_SIZE(bt_rfcomm_pool); i++) {
struct bt_rfcomm_session *session = &bt_rfcomm_pool[i];
if (session->br_chan.chan.conn == conn) {
return session;
}
}
return NULL;
}
int bt_rfcomm_server_register(struct bt_rfcomm_server *server)
{
if (server->channel < RFCOMM_CHANNEL_START ||
server->channel > RFCOMM_CHANNEL_END || !server->accept) {
return -EINVAL;
}
/* Check if given channel is already in use */
if (rfcomm_server_lookup_channel(server->channel)) {
BT_DBG("Channel already registered");
return -EADDRINUSE;
}
BT_DBG("Channel 0x%02x", server->channel);
server->_next = servers;
servers = server;
return 0;
}
static void rfcomm_dlc_tx_give_credits(struct bt_rfcomm_dlc *dlc,
u8_t credits)
{
BT_DBG("dlc %p credits %u", dlc, credits);
while (credits--) {
k_sem_give(&dlc->tx_credits);
}
BT_DBG("dlc %p updated credits %u", dlc,
k_sem_count_get(&dlc->tx_credits));
}
static void rfcomm_dlc_destroy(struct bt_rfcomm_dlc *dlc)
{
BT_DBG("dlc %p", dlc);
k_delayed_work_cancel(&dlc->rtx_work);
dlc->state = BT_RFCOMM_STATE_IDLE;
dlc->session = NULL;
STACK_ANALYZE("dlc stack", dlc->stack);
if (dlc->ops && dlc->ops->disconnected) {
dlc->ops->disconnected(dlc);
}
}
static void rfcomm_dlc_disconnect(struct bt_rfcomm_dlc *dlc)
{
u8_t old_state = dlc->state;
BT_DBG("dlc %p", dlc);
if (dlc->state == BT_RFCOMM_STATE_DISCONNECTED) {
return;
}
dlc->state = BT_RFCOMM_STATE_DISCONNECTED;
switch (old_state) {
case BT_RFCOMM_STATE_CONNECTED:
/* Queue a dummy buffer to wake up and stop the
* tx thread for states where it was running.
*/
net_buf_put(&dlc->tx_queue,
net_buf_alloc(&dummy_pool, K_NO_WAIT));
/* There could be a writer waiting for credits so return a
* dummy credit to wake it up.
*/
rfcomm_dlc_tx_give_credits(dlc, 1);
k_sem_give(&dlc->session->fc);
break;
default:
rfcomm_dlc_destroy(dlc);
break;
}
}
static void rfcomm_session_disconnected(struct bt_rfcomm_session *session)
{
struct bt_rfcomm_dlc *dlc;
BT_DBG("Session %p", session);
if (session->state == BT_RFCOMM_STATE_DISCONNECTED) {
return;
}
for (dlc = session->dlcs; dlc;) {
struct bt_rfcomm_dlc *next;
/* prefetch since disconnected callback may cleanup */
next = dlc->_next;
dlc->_next = NULL;
rfcomm_dlc_disconnect(dlc);
dlc = next;
}
session->state = BT_RFCOMM_STATE_DISCONNECTED;
session->dlcs = NULL;
}
struct net_buf *bt_rfcomm_create_pdu(struct net_buf_pool *pool)
{
/* Length in RFCOMM header can be 2 bytes depending on length of user
* data
*/
return bt_conn_create_pdu(pool,
sizeof(struct bt_l2cap_hdr) +
sizeof(struct bt_rfcomm_hdr) + 1);
}
static int rfcomm_send_sabm(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_hdr *hdr;
struct net_buf *buf;
u8_t cr, fcs;
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
cr = BT_RFCOMM_CMD_CR(session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlci, cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_SABM, BT_RFCOMM_PF_NON_UIH);
hdr->length = BT_RFCOMM_SET_LEN_8(0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_NON_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_disc(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_hdr *hdr;
struct net_buf *buf;
u8_t fcs, cr;
BT_DBG("dlci %d", dlci);
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
cr = BT_RFCOMM_RESP_CR(session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlci, cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_DISC, BT_RFCOMM_PF_NON_UIH);
hdr->length = BT_RFCOMM_SET_LEN_8(0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_NON_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static void rfcomm_session_disconnect(struct bt_rfcomm_session *session)
{
if (session->dlcs) {
return;
}
session->state = BT_RFCOMM_STATE_DISCONNECTING;
rfcomm_send_disc(session, 0);
k_delayed_work_submit(&session->rtx_work, RFCOMM_DISC_TIMEOUT);
}
static struct net_buf *rfcomm_make_uih_msg(struct bt_rfcomm_session *session,
u8_t cr, u8_t type,
u8_t len)
{
struct bt_rfcomm_hdr *hdr;
struct bt_rfcomm_msg_hdr *msg_hdr;
struct net_buf *buf;
u8_t hdr_cr;
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
hdr_cr = BT_RFCOMM_UIH_CR(session->role);
hdr->address = BT_RFCOMM_SET_ADDR(0, hdr_cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_UIH, BT_RFCOMM_PF_UIH);
hdr->length = BT_RFCOMM_SET_LEN_8(sizeof(*msg_hdr) + len);
msg_hdr = net_buf_add(buf, sizeof(*msg_hdr));
msg_hdr->type = BT_RFCOMM_SET_MSG_TYPE(type, cr);
msg_hdr->len = BT_RFCOMM_SET_LEN_8(len);
return buf;
}
static void rfcomm_connected(struct bt_l2cap_chan *chan)
{
struct bt_rfcomm_session *session = RFCOMM_SESSION(chan);
BT_DBG("Session %p", session);
/* Need to include UIH header and FCS*/
session->mtu = min(session->br_chan.rx.mtu,
session->br_chan.tx.mtu) -
BT_RFCOMM_HDR_SIZE + BT_RFCOMM_FCS_SIZE;
if (session->state == BT_RFCOMM_STATE_CONNECTING) {
rfcomm_send_sabm(session, 0);
}
}
static void rfcomm_disconnected(struct bt_l2cap_chan *chan)
{
struct bt_rfcomm_session *session = RFCOMM_SESSION(chan);
BT_DBG("Session %p", session);
k_delayed_work_cancel(&session->rtx_work);
rfcomm_session_disconnected(session);
session->state = BT_RFCOMM_STATE_IDLE;
}
static void rfcomm_dlc_rtx_timeout(struct k_work *work)
{
struct bt_rfcomm_dlc *dlc = DLC_RTX(work);
struct bt_rfcomm_session *session = dlc->session;
BT_WARN("dlc %p state %d timeout", dlc, dlc->state);
rfcomm_dlcs_remove_dlci(session->dlcs, dlc->dlci);
rfcomm_dlc_disconnect(dlc);
rfcomm_session_disconnect(session);
}
static void rfcomm_dlc_init(struct bt_rfcomm_dlc *dlc,
struct bt_rfcomm_session *session,
u8_t dlci,
bt_rfcomm_role_t role)
{
BT_DBG("dlc %p", dlc);
dlc->dlci = dlci;
dlc->session = session;
dlc->rx_credit = RFCOMM_DEFAULT_CREDIT;
dlc->state = BT_RFCOMM_STATE_INIT;
dlc->role = role;
k_delayed_work_init(&dlc->rtx_work, rfcomm_dlc_rtx_timeout);
/* Start a conn timer which includes auth as well */
k_delayed_work_submit(&dlc->rtx_work, RFCOMM_CONN_TIMEOUT);
dlc->_next = session->dlcs;
session->dlcs = dlc;
}
static struct bt_rfcomm_dlc *rfcomm_dlc_accept(struct bt_rfcomm_session *session,
u8_t dlci)
{
struct bt_rfcomm_server *server;
struct bt_rfcomm_dlc *dlc;
u8_t channel;
channel = BT_RFCOMM_GET_CHANNEL(dlci);
server = rfcomm_server_lookup_channel(channel);
if (!server) {
BT_ERR("Server Channel not registered");
return NULL;
}
if (server->accept(session->br_chan.chan.conn, &dlc) < 0) {
BT_DBG("Incoming connection rejected");
return NULL;
}
if (!BT_RFCOMM_CHECK_MTU(dlc->mtu)) {
rfcomm_dlc_destroy(dlc);
return NULL;
}
rfcomm_dlc_init(dlc, session, dlci, BT_RFCOMM_ROLE_ACCEPTOR);
dlc->mtu = min(dlc->mtu, session->mtu);
return dlc;
}
static int rfcomm_send_dm(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_hdr *hdr;
struct net_buf *buf;
u8_t fcs, cr;
BT_DBG("dlci %d", dlci);
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
cr = BT_RFCOMM_RESP_CR(session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlci, cr);
/* For DM PF bit is not relevant, we set it 1 */
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_DM, BT_RFCOMM_PF_NON_UIH);
hdr->length = BT_RFCOMM_SET_LEN_8(0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_NON_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static void rfcomm_check_fc(struct bt_rfcomm_dlc *dlc)
{
BT_DBG("%p", dlc);
BT_DBG("Wait for credits or MSC FC %p", dlc);
/* Wait for credits or MSC FC */
k_sem_take(&dlc->tx_credits, K_FOREVER);
if (dlc->session->cfc == BT_RFCOMM_CFC_SUPPORTED) {
return;
}
k_sem_take(&dlc->session->fc, K_FOREVER);
/* Give the sems immediately so that sem will be available for all
* the bufs in the queue. It will be blocked only once all the bufs
* are sent (which will preempt this thread) and FCOFF / FC bit
* with 1, is received.
*/
k_sem_give(&dlc->session->fc);
k_sem_give(&dlc->tx_credits);
}
static void rfcomm_dlc_tx_thread(void *p1, void *p2, void *p3)
{
struct bt_rfcomm_dlc *dlc = p1;
s32_t timeout = K_FOREVER;
struct net_buf *buf;
BT_DBG("Started for dlc %p", dlc);
while (dlc->state == BT_RFCOMM_STATE_CONNECTED ||
dlc->state == BT_RFCOMM_STATE_USER_DISCONNECT) {
/* Get next packet for dlc */
BT_DBG("Wait for buf %p", dlc);
buf = net_buf_get(&dlc->tx_queue, timeout);
/* If its dummy buffer or non user disconnect then break */
if ((dlc->state != BT_RFCOMM_STATE_CONNECTED &&
dlc->state != BT_RFCOMM_STATE_USER_DISCONNECT) ||
!buf || !buf->len) {
if (buf) {
net_buf_unref(buf);
}
break;
}
rfcomm_check_fc(dlc);
if (dlc->state != BT_RFCOMM_STATE_CONNECTED &&
dlc->state != BT_RFCOMM_STATE_USER_DISCONNECT) {
net_buf_unref(buf);
break;
}
if (bt_l2cap_chan_send(&dlc->session->br_chan.chan, buf) < 0) {
/* This fails only if channel is disconnected */
dlc->state = BT_RFCOMM_STATE_DISCONNECTED;
net_buf_unref(buf);
break;
}
if (dlc->state == BT_RFCOMM_STATE_USER_DISCONNECT) {
timeout = K_NO_WAIT;
}
}
BT_DBG("dlc %p disconnected - cleaning up", dlc);
/* Give back any allocated buffers */
while ((buf = net_buf_get(&dlc->tx_queue, K_NO_WAIT))) {
net_buf_unref(buf);
}
if (dlc->state == BT_RFCOMM_STATE_USER_DISCONNECT) {
dlc->state = BT_RFCOMM_STATE_DISCONNECTING;
}
if (dlc->state == BT_RFCOMM_STATE_DISCONNECTING) {
rfcomm_send_disc(dlc->session, dlc->dlci);
k_delayed_work_submit(&dlc->rtx_work, RFCOMM_DISC_TIMEOUT);
} else {
rfcomm_dlc_destroy(dlc);
}
BT_DBG("dlc %p exiting", dlc);
}
static int rfcomm_send_ua(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_hdr *hdr;
struct net_buf *buf;
u8_t cr, fcs;
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
cr = BT_RFCOMM_RESP_CR(session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlci, cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_UA, BT_RFCOMM_PF_NON_UIH);
hdr->length = BT_RFCOMM_SET_LEN_8(0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_NON_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_msc(struct bt_rfcomm_dlc *dlc, u8_t cr,
u8_t v24_signal)
{
struct bt_rfcomm_msc *msc;
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(dlc->session, cr, BT_RFCOMM_MSC,
sizeof(*msc));
msc = net_buf_add(buf, sizeof(*msc));
/* cr bit should be always 1 in MSC */
msc->dlci = BT_RFCOMM_SET_ADDR(dlc->dlci, 1);
msc->v24_signal = v24_signal;
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&dlc->session->br_chan.chan, buf);
}
static int rfcomm_send_rls(struct bt_rfcomm_dlc *dlc, u8_t cr,
u8_t line_status)
{
struct bt_rfcomm_rls *rls;
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(dlc->session, cr, BT_RFCOMM_RLS,
sizeof(*rls));
rls = net_buf_add(buf, sizeof(*rls));
/* cr bit should be always 1 in RLS */
rls->dlci = BT_RFCOMM_SET_ADDR(dlc->dlci, 1);
rls->line_status = line_status;
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&dlc->session->br_chan.chan, buf);
}
static int rfcomm_send_rpn(struct bt_rfcomm_session *session, u8_t cr,
struct bt_rfcomm_rpn *rpn)
{
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(session, cr, BT_RFCOMM_RPN, sizeof(*rpn));
net_buf_add_mem(buf, rpn, sizeof(*rpn));
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_test(struct bt_rfcomm_session *session, u8_t cr,
u8_t *pattern, u8_t len)
{
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(session, cr, BT_RFCOMM_TEST, len);
net_buf_add_mem(buf, pattern, len);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_nsc(struct bt_rfcomm_session *session, u8_t cmd_type)
{
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(session, BT_RFCOMM_MSG_RESP_CR,
BT_RFCOMM_NSC, sizeof(cmd_type));
net_buf_add_u8(buf, cmd_type);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_fcon(struct bt_rfcomm_session *session, u8_t cr)
{
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(session, cr, BT_RFCOMM_FCON, 0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static int rfcomm_send_fcoff(struct bt_rfcomm_session *session, u8_t cr)
{
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(session, cr, BT_RFCOMM_FCOFF, 0);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&session->br_chan.chan, buf);
}
static void rfcomm_dlc_connected(struct bt_rfcomm_dlc *dlc)
{
dlc->state = BT_RFCOMM_STATE_CONNECTED;
rfcomm_send_msc(dlc, BT_RFCOMM_MSG_CMD_CR, BT_RFCOMM_DEFAULT_V24_SIG);
if (dlc->session->cfc == BT_RFCOMM_CFC_UNKNOWN) {
/* This means PN negotiation is not done for this session and
* can happen only for 1.0b device.
*/
dlc->session->cfc = BT_RFCOMM_CFC_NOT_SUPPORTED;
}
if (dlc->session->cfc == BT_RFCOMM_CFC_NOT_SUPPORTED) {
BT_DBG("CFC not supported %p", dlc);
rfcomm_send_fcon(dlc->session, BT_RFCOMM_MSG_CMD_CR);
/* Use tx_credits as binary sem for MSC FC */
k_sem_init(&dlc->tx_credits, 0, 1);
}
/* Cancel conn timer */
k_delayed_work_cancel(&dlc->rtx_work);
k_fifo_init(&dlc->tx_queue);
k_thread_create(&dlc->tx_thread, dlc->stack,
K_THREAD_STACK_SIZEOF(dlc->stack),
rfcomm_dlc_tx_thread, dlc, NULL, NULL, K_PRIO_COOP(7),
0, K_NO_WAIT);
if (dlc->ops && dlc->ops->connected) {
dlc->ops->connected(dlc);
}
}
enum security_result {
RFCOMM_SECURITY_PASSED,
RFCOMM_SECURITY_REJECT,
RFCOMM_SECURITY_PENDING
};
static enum security_result rfcomm_dlc_security(struct bt_rfcomm_dlc *dlc)
{
struct bt_conn *conn = dlc->session->br_chan.chan.conn;
BT_DBG("dlc %p", dlc);
/* If current security level is greater than or equal to required
* security level then return SUCCESS.
* For SSP devices the current security will be atleast MEDIUM
* since L2CAP is enforcing it
*/
if (conn->sec_level >= dlc->required_sec_level) {
return RFCOMM_SECURITY_PASSED;
}
if (!bt_conn_security(conn, dlc->required_sec_level)) {
/* If Security elevation is initiated or in progress */
return RFCOMM_SECURITY_PENDING;
}
/* Security request failed */
return RFCOMM_SECURITY_REJECT;
}
static void rfcomm_dlc_drop(struct bt_rfcomm_dlc *dlc)
{
BT_DBG("dlc %p", dlc);
rfcomm_dlcs_remove_dlci(dlc->session->dlcs, dlc->dlci);
rfcomm_dlc_destroy(dlc);
}
static int rfcomm_dlc_close(struct bt_rfcomm_dlc *dlc)
{
BT_DBG("dlc %p", dlc);
switch (dlc->state) {
case BT_RFCOMM_STATE_SECURITY_PENDING:
if (dlc->role == BT_RFCOMM_ROLE_ACCEPTOR) {
rfcomm_send_dm(dlc->session, dlc->dlci);
}
/* Fall Through */
case BT_RFCOMM_STATE_INIT:
rfcomm_dlc_drop(dlc);
break;
case BT_RFCOMM_STATE_CONNECTING:
case BT_RFCOMM_STATE_CONFIG:
dlc->state = BT_RFCOMM_STATE_DISCONNECTING;
rfcomm_send_disc(dlc->session, dlc->dlci);
k_delayed_work_submit(&dlc->rtx_work, RFCOMM_DISC_TIMEOUT);
break;
case BT_RFCOMM_STATE_CONNECTED:
dlc->state = BT_RFCOMM_STATE_DISCONNECTING;
/* Queue a dummy buffer to wake up and stop the
* tx thread.
*/
net_buf_put(&dlc->tx_queue,
net_buf_alloc(&dummy_pool, K_NO_WAIT));
/* There could be a writer waiting for credits so return a
* dummy credit to wake it up.
*/
rfcomm_dlc_tx_give_credits(dlc, 1);
break;
case BT_RFCOMM_STATE_DISCONNECTING:
case BT_RFCOMM_STATE_DISCONNECTED:
break;
case BT_RFCOMM_STATE_IDLE:
default:
return -EINVAL;
}
return 0;
}
static void rfcomm_handle_sabm(struct bt_rfcomm_session *session, u8_t dlci)
{
if (!dlci) {
if (rfcomm_send_ua(session, dlci) < 0) {
return;
}
session->state = BT_RFCOMM_STATE_CONNECTED;
} else {
struct bt_rfcomm_dlc *dlc;
enum security_result result;
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, dlci);
if (!dlc) {
dlc = rfcomm_dlc_accept(session, dlci);
if (!dlc) {
rfcomm_send_dm(session, dlci);
return;
}
}
result = rfcomm_dlc_security(dlc);
switch (result) {
case RFCOMM_SECURITY_PENDING:
dlc->state = BT_RFCOMM_STATE_SECURITY_PENDING;
return;
case RFCOMM_SECURITY_PASSED:
break;
case RFCOMM_SECURITY_REJECT:
default:
rfcomm_send_dm(session, dlci);
rfcomm_dlc_drop(dlc);
return;
}
if (rfcomm_send_ua(session, dlci) < 0) {
return;
}
/* Cancel idle timer if any */
k_delayed_work_cancel(&session->rtx_work);
rfcomm_dlc_connected(dlc);
}
}
static int rfcomm_send_pn(struct bt_rfcomm_dlc *dlc, u8_t cr)
{
struct bt_rfcomm_pn *pn;
struct net_buf *buf;
u8_t fcs;
buf = rfcomm_make_uih_msg(dlc->session, cr, BT_RFCOMM_PN, sizeof(*pn));
BT_DBG("mtu %x", dlc->mtu);
pn = net_buf_add(buf, sizeof(*pn));
pn->dlci = dlc->dlci;
pn->mtu = sys_cpu_to_le16(dlc->mtu);
if (dlc->state == BT_RFCOMM_STATE_CONFIG &&
(dlc->session->cfc == BT_RFCOMM_CFC_UNKNOWN ||
dlc->session->cfc == BT_RFCOMM_CFC_SUPPORTED)) {
pn->credits = dlc->rx_credit;
if (cr) {
pn->flow_ctrl = BT_RFCOMM_PN_CFC_CMD;
} else {
pn->flow_ctrl = BT_RFCOMM_PN_CFC_RESP;
}
} else {
/* If PN comes in already opened dlc or cfc not supported
* these should be 0
*/
pn->credits = 0;
pn->flow_ctrl = 0;
}
pn->max_retrans = 0;
pn->ack_timer = 0;
pn->priority = 0;
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&dlc->session->br_chan.chan, buf);
}
static int rfcomm_send_credit(struct bt_rfcomm_dlc *dlc, u8_t credits)
{
struct bt_rfcomm_hdr *hdr;
struct net_buf *buf;
u8_t fcs, cr;
BT_DBG("Dlc %p credits %d", dlc, credits);
buf = bt_l2cap_create_pdu(NULL, 0);
hdr = net_buf_add(buf, sizeof(*hdr));
cr = BT_RFCOMM_UIH_CR(dlc->session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlc->dlci, cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_UIH,
BT_RFCOMM_PF_UIH_CREDIT);
hdr->length = BT_RFCOMM_SET_LEN_8(0);
net_buf_add_u8(buf, credits);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
return bt_l2cap_chan_send(&dlc->session->br_chan.chan, buf);
}
static int rfcomm_dlc_start(struct bt_rfcomm_dlc *dlc)
{
enum security_result result;
BT_DBG("dlc %p", dlc);
result = rfcomm_dlc_security(dlc);
switch (result) {
case RFCOMM_SECURITY_PASSED:
dlc->mtu = min(dlc->mtu, dlc->session->mtu);
dlc->state = BT_RFCOMM_STATE_CONFIG;
rfcomm_send_pn(dlc, BT_RFCOMM_MSG_CMD_CR);
break;
case RFCOMM_SECURITY_PENDING:
dlc->state = BT_RFCOMM_STATE_SECURITY_PENDING;
break;
case RFCOMM_SECURITY_REJECT:
default:
return -EIO;
}
return 0;
}
static void rfcomm_handle_ua(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_dlc *dlc, *next;
int err;
if (!dlci) {
switch (session->state) {
case BT_RFCOMM_STATE_CONNECTING:
session->state = BT_RFCOMM_STATE_CONNECTED;
for (dlc = session->dlcs; dlc; dlc = next) {
next = dlc->_next;
if (dlc->role == BT_RFCOMM_ROLE_INITIATOR &&
dlc->state == BT_RFCOMM_STATE_INIT) {
if (rfcomm_dlc_start(dlc) < 0) {
rfcomm_dlc_drop(dlc);
}
}
}
/* Disconnect session if there is no dlcs left */
rfcomm_session_disconnect(session);
break;
case BT_RFCOMM_STATE_DISCONNECTING:
session->state = BT_RFCOMM_STATE_DISCONNECTED;
/* Cancel disc timer */
k_delayed_work_cancel(&session->rtx_work);
err = bt_l2cap_chan_disconnect(&session->br_chan.chan);
if (err < 0) {
session->state = BT_RFCOMM_STATE_IDLE;
}
break;
default:
break;
}
} else {
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, dlci);
if (!dlc) {
return;
}
switch (dlc->state) {
case BT_RFCOMM_STATE_CONNECTING:
rfcomm_dlc_connected(dlc);
break;
case BT_RFCOMM_STATE_DISCONNECTING:
rfcomm_dlc_drop(dlc);
rfcomm_session_disconnect(session);
break;
default:
break;
}
}
}
static void rfcomm_handle_dm(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_dlc *dlc;
BT_DBG("dlci %d", dlci);
dlc = rfcomm_dlcs_remove_dlci(session->dlcs, dlci);
if (!dlc) {
return;
}
rfcomm_dlc_disconnect(dlc);
rfcomm_session_disconnect(session);
}
static void rfcomm_handle_msc(struct bt_rfcomm_session *session,
struct net_buf *buf, u8_t cr)
{
struct bt_rfcomm_msc *msc = (void *)buf->data;
struct bt_rfcomm_dlc *dlc;
u8_t dlci = BT_RFCOMM_GET_DLCI(msc->dlci);
BT_DBG("dlci %d", dlci);
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, dlci);
if (!dlc) {
return;
}
if (cr == BT_RFCOMM_MSG_RESP_CR) {
return;
}
if (dlc->session->cfc == BT_RFCOMM_CFC_NOT_SUPPORTED) {
/* Only FC bit affects the flow on RFCOMM level */
if (BT_RFCOMM_GET_FC(msc->v24_signal)) {
/* If FC bit is 1 the device is unable to accept frames.
* Take the semaphore with timeout K_NO_WAIT so that
* dlc thread will be blocked when it tries sem_take
* before sending the data. K_NO_WAIT timeout will make
* sure that RX thread will not be blocked while taking
* the semaphore.
*/
k_sem_take(&dlc->tx_credits, K_NO_WAIT);
} else {
/* Give the sem so that it will unblock the waiting dlc
* thread in sem_take().
*/
k_sem_give(&dlc->tx_credits);
}
}
rfcomm_send_msc(dlc, BT_RFCOMM_MSG_RESP_CR, msc->v24_signal);
}
static void rfcomm_handle_rls(struct bt_rfcomm_session *session,
struct net_buf *buf, u8_t cr)
{
struct bt_rfcomm_rls *rls = (void *)buf->data;
u8_t dlci = BT_RFCOMM_GET_DLCI(rls->dlci);
struct bt_rfcomm_dlc *dlc;
BT_DBG("dlci %d", dlci);
if (!cr) {
/* Ignore if its a response */
return;
}
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, dlci);
if (!dlc) {
return;
}
/* As per the ETSI same line status has to returned in the response */
rfcomm_send_rls(dlc, BT_RFCOMM_MSG_RESP_CR, rls->line_status);
}
static void rfcomm_handle_rpn(struct bt_rfcomm_session *session,
struct net_buf *buf, u8_t cr)
{
struct bt_rfcomm_rpn default_rpn, *rpn = (void *)buf->data;
u8_t dlci = BT_RFCOMM_GET_DLCI(rpn->dlci);
u8_t data_bits, stop_bits, parity_bits;
/* Exclude fcs to get number of value bytes */
u8_t value_len = buf->len - 1;
BT_DBG("dlci %d", dlci);
if (!cr) {
/* Ignore if its a response */
return;
}
if (value_len == sizeof(*rpn)) {
/* Accept all the values proposed by the sender */
rpn->param_mask = sys_cpu_to_le16(BT_RFCOMM_RPN_PARAM_MASK_ALL);
rfcomm_send_rpn(session, BT_RFCOMM_MSG_RESP_CR, rpn);
return;
}
if (value_len != 1) {
return;
}
/* If only one value byte then current port settings has to be returned
* We will send default values
*/
default_rpn.dlci = BT_RFCOMM_SET_ADDR(dlci, 1);
default_rpn.baud_rate = BT_RFCOMM_RPN_BAUD_RATE_9600;
default_rpn.flow_control = BT_RFCOMM_RPN_FLOW_NONE;
default_rpn.xoff_char = BT_RFCOMM_RPN_XOFF_CHAR;
default_rpn.xon_char = BT_RFCOMM_RPN_XON_CHAR;
data_bits = BT_RFCOMM_RPN_DATA_BITS_8;
stop_bits = BT_RFCOMM_RPN_STOP_BITS_1;
parity_bits = BT_RFCOMM_RPN_PARITY_NONE;
default_rpn.line_settings = BT_RFCOMM_SET_LINE_SETTINGS(data_bits,
stop_bits,
parity_bits);
default_rpn.param_mask = sys_cpu_to_le16(BT_RFCOMM_RPN_PARAM_MASK_ALL);
rfcomm_send_rpn(session, BT_RFCOMM_MSG_RESP_CR, &default_rpn);
}
static void rfcomm_handle_pn(struct bt_rfcomm_session *session,
struct net_buf *buf, u8_t cr)
{
struct bt_rfcomm_pn *pn = (void *)buf->data;
struct bt_rfcomm_dlc *dlc;
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, pn->dlci);
if (!dlc) {
/* Ignore if it is a response */
if (!cr) {
return;
}
if (!BT_RFCOMM_CHECK_MTU(pn->mtu)) {
BT_ERR("Invalid mtu %d", pn->mtu);
rfcomm_send_dm(session, pn->dlci);
return;
}
dlc = rfcomm_dlc_accept(session, pn->dlci);
if (!dlc) {
rfcomm_send_dm(session, pn->dlci);
return;
}
BT_DBG("Incoming connection accepted dlc %p", dlc);
dlc->mtu = min(dlc->mtu, sys_le16_to_cpu(pn->mtu));
if (pn->flow_ctrl == BT_RFCOMM_PN_CFC_CMD) {
if (session->cfc == BT_RFCOMM_CFC_UNKNOWN) {
session->cfc = BT_RFCOMM_CFC_SUPPORTED;
}
k_sem_init(&dlc->tx_credits, 0, UINT32_MAX);
rfcomm_dlc_tx_give_credits(dlc, pn->credits);
} else {
session->cfc = BT_RFCOMM_CFC_NOT_SUPPORTED;
}
dlc->state = BT_RFCOMM_STATE_CONFIG;
rfcomm_send_pn(dlc, BT_RFCOMM_MSG_RESP_CR);
/* Cancel idle timer if any */
k_delayed_work_cancel(&session->rtx_work);
} else {
/* If its a command */
if (cr) {
if (!BT_RFCOMM_CHECK_MTU(pn->mtu)) {
BT_ERR("Invalid mtu %d", pn->mtu);
rfcomm_dlc_close(dlc);
return;
}
dlc->mtu = min(dlc->mtu, sys_le16_to_cpu(pn->mtu));
rfcomm_send_pn(dlc, BT_RFCOMM_MSG_RESP_CR);
} else {
if (dlc->state != BT_RFCOMM_STATE_CONFIG) {
return;
}
dlc->mtu = min(dlc->mtu, sys_le16_to_cpu(pn->mtu));
if (pn->flow_ctrl == BT_RFCOMM_PN_CFC_RESP) {
if (session->cfc == BT_RFCOMM_CFC_UNKNOWN) {
session->cfc = BT_RFCOMM_CFC_SUPPORTED;
}
k_sem_init(&dlc->tx_credits, 0, UINT32_MAX);
rfcomm_dlc_tx_give_credits(dlc, pn->credits);
} else {
session->cfc = BT_RFCOMM_CFC_NOT_SUPPORTED;
}
dlc->state = BT_RFCOMM_STATE_CONNECTING;
rfcomm_send_sabm(session, dlc->dlci);
}
}
}
static void rfcomm_handle_disc(struct bt_rfcomm_session *session, u8_t dlci)
{
struct bt_rfcomm_dlc *dlc;
BT_DBG("Dlci %d", dlci);
if (dlci) {
dlc = rfcomm_dlcs_remove_dlci(session->dlcs, dlci);
if (!dlc) {
rfcomm_send_dm(session, dlci);
return;
}
rfcomm_send_ua(session, dlci);
rfcomm_dlc_disconnect(dlc);
if (!session->dlcs) {
/* Start a session idle timer */
k_delayed_work_submit(&dlc->session->rtx_work,
RFCOMM_IDLE_TIMEOUT);
}
} else {
/* Cancel idle timer */
k_delayed_work_cancel(&session->rtx_work);
rfcomm_send_ua(session, 0);
rfcomm_session_disconnected(session);
}
}
static void rfcomm_handle_msg(struct bt_rfcomm_session *session,
struct net_buf *buf)
{
struct bt_rfcomm_msg_hdr *hdr = (void *)buf->data;
u8_t msg_type, len, cr;
msg_type = BT_RFCOMM_GET_MSG_TYPE(hdr->type);
cr = BT_RFCOMM_GET_MSG_CR(hdr->type);
len = BT_RFCOMM_GET_LEN(hdr->len);
BT_DBG("msg type %x cr %x", msg_type, cr);
net_buf_pull(buf, sizeof(*hdr));
switch (msg_type) {
case BT_RFCOMM_PN:
rfcomm_handle_pn(session, buf, cr);
break;
case BT_RFCOMM_MSC:
rfcomm_handle_msc(session, buf, cr);
break;
case BT_RFCOMM_RLS:
rfcomm_handle_rls(session, buf, cr);
break;
case BT_RFCOMM_RPN:
rfcomm_handle_rpn(session, buf, cr);
break;
case BT_RFCOMM_TEST:
if (!cr) {
break;
}
rfcomm_send_test(session, BT_RFCOMM_MSG_RESP_CR, buf->data,
buf->len - 1);
break;
case BT_RFCOMM_FCON:
if (session->cfc == BT_RFCOMM_CFC_SUPPORTED) {
BT_ERR("FCON received when CFC is supported ");
return;
}
if (!cr) {
break;
}
/* Give the sem so that it will unblock the waiting dlc threads
* of this session in sem_take().
*/
k_sem_give(&session->fc);
rfcomm_send_fcon(session, BT_RFCOMM_MSG_RESP_CR);
break;
case BT_RFCOMM_FCOFF:
if (session->cfc == BT_RFCOMM_CFC_SUPPORTED) {
BT_ERR("FCOFF received when CFC is supported ");
return;
}
if (!cr) {
break;
}
/* Take the semaphore with timeout K_NO_WAIT so that all the
* dlc threads in this session will be blocked when it tries
* sem_take before sending the data. K_NO_WAIT timeout will
* make sure that RX thread will not be blocked while taking
* the semaphore.
*/
k_sem_take(&session->fc, K_NO_WAIT);
rfcomm_send_fcoff(session, BT_RFCOMM_MSG_RESP_CR);
break;
default:
BT_WARN("Unknown/Unsupported RFCOMM Msg type 0x%02x", msg_type);
rfcomm_send_nsc(session, hdr->type);
break;
}
}
static void rfcomm_dlc_update_credits(struct bt_rfcomm_dlc *dlc)
{
u8_t credits;
if (dlc->session->cfc == BT_RFCOMM_CFC_NOT_SUPPORTED) {
return;
}
BT_DBG("dlc %p credits %u", dlc, dlc->rx_credit);
/* Only give more credits if it went below the defined threshold */
if (dlc->rx_credit > RFCOMM_CREDITS_THRESHOLD) {
return;
}
/* Restore credits */
credits = RFCOMM_MAX_CREDITS - dlc->rx_credit;
dlc->rx_credit += credits;
rfcomm_send_credit(dlc, credits);
}
static void rfcomm_handle_data(struct bt_rfcomm_session *session,
struct net_buf *buf, u8_t dlci, u8_t pf)
{
struct bt_rfcomm_dlc *dlc;
BT_DBG("dlci %d, pf %d", dlci, pf);
dlc = rfcomm_dlcs_lookup_dlci(session->dlcs, dlci);
if (!dlc) {
BT_ERR("Data recvd in non existing DLC");
rfcomm_send_dm(session, dlci);
return;
}
BT_DBG("dlc %p rx credit %d", dlc, dlc->rx_credit);
if (dlc->state != BT_RFCOMM_STATE_CONNECTED) {
return;
}
if (pf == BT_RFCOMM_PF_UIH_CREDIT) {
rfcomm_dlc_tx_give_credits(dlc, net_buf_pull_u8(buf));
}
if (buf->len > BT_RFCOMM_FCS_SIZE) {
if (dlc->session->cfc == BT_RFCOMM_CFC_SUPPORTED &&
!dlc->rx_credit) {
BT_ERR("Data recvd when rx credit is 0");
rfcomm_dlc_close(dlc);
return;
}
/* Remove FCS */
buf->len -= BT_RFCOMM_FCS_SIZE;
if (dlc->ops && dlc->ops->recv) {
dlc->ops->recv(dlc, buf);
}
dlc->rx_credit--;
rfcomm_dlc_update_credits(dlc);
}
}
int bt_rfcomm_dlc_send(struct bt_rfcomm_dlc *dlc, struct net_buf *buf)
{
struct bt_rfcomm_hdr *hdr;
u8_t fcs, cr;
if (!buf) {
return -EINVAL;
}
BT_DBG("dlc %p tx credit %d", dlc, k_sem_count_get(&dlc->tx_credits));
if (dlc->state != BT_RFCOMM_STATE_CONNECTED) {
return -ENOTCONN;
}
if (buf->len > dlc->mtu) {
return -EMSGSIZE;
}
if (buf->len > BT_RFCOMM_MAX_LEN_8) {
u16_t *len;
/* Length is 2 byte */
hdr = net_buf_push(buf, sizeof(*hdr) + 1);
len = (u16_t *)&hdr->length;
*len = BT_RFCOMM_SET_LEN_16(sys_cpu_to_le16(buf->len -
sizeof(*hdr) + 1));
} else {
hdr = net_buf_push(buf, sizeof(*hdr));
hdr->length = BT_RFCOMM_SET_LEN_8(buf->len - sizeof(*hdr));
}
cr = BT_RFCOMM_UIH_CR(dlc->session->role);
hdr->address = BT_RFCOMM_SET_ADDR(dlc->dlci, cr);
hdr->control = BT_RFCOMM_SET_CTRL(BT_RFCOMM_UIH,
BT_RFCOMM_PF_UIH_NO_CREDIT);
fcs = rfcomm_calc_fcs(BT_RFCOMM_FCS_LEN_UIH, buf->data);
net_buf_add_u8(buf, fcs);
net_buf_put(&dlc->tx_queue, buf);
return buf->len;
}
static void rfcomm_recv(struct bt_l2cap_chan *chan, struct net_buf *buf)
{
struct bt_rfcomm_session *session = RFCOMM_SESSION(chan);
struct bt_rfcomm_hdr *hdr = (void *)buf->data;
u8_t dlci, frame_type, fcs, fcs_len;
/* Need to consider FCS also*/
if (buf->len < (sizeof(*hdr) + 1)) {
BT_ERR("Too small RFCOMM Frame");
return;
}
dlci = BT_RFCOMM_GET_DLCI(hdr->address);
frame_type = BT_RFCOMM_GET_FRAME_TYPE(hdr->control);
BT_DBG("session %p dlci %x type %x", session, dlci, frame_type);
fcs_len = (frame_type == BT_RFCOMM_UIH) ? BT_RFCOMM_FCS_LEN_UIH :
BT_RFCOMM_FCS_LEN_NON_UIH;
fcs = *(net_buf_tail(buf) - 1);
if (!rfcomm_check_fcs(fcs_len, buf->data, fcs)) {
BT_ERR("FCS check failed");
return;
}
if (BT_RFCOMM_LEN_EXTENDED(hdr->length)) {
net_buf_pull(buf, sizeof(*hdr) + 1);
} else {
net_buf_pull(buf, sizeof(*hdr));
}
switch (frame_type) {
case BT_RFCOMM_SABM:
rfcomm_handle_sabm(session, dlci);
break;
case BT_RFCOMM_UIH:
if (!dlci) {
rfcomm_handle_msg(session, buf);
} else {
rfcomm_handle_data(session, buf, dlci,
BT_RFCOMM_GET_PF(hdr->control));
}
break;
case BT_RFCOMM_DISC:
rfcomm_handle_disc(session, dlci);
break;
case BT_RFCOMM_UA:
rfcomm_handle_ua(session, dlci);
break;
case BT_RFCOMM_DM:
rfcomm_handle_dm(session, dlci);
break;
default:
BT_WARN("Unknown/Unsupported RFCOMM Frame type 0x%02x",
frame_type);
break;
}
}
static void rfcomm_encrypt_change(struct bt_l2cap_chan *chan,
u8_t hci_status)
{
struct bt_rfcomm_session *session = RFCOMM_SESSION(chan);
struct bt_conn *conn = chan->conn;
struct bt_rfcomm_dlc *dlc, *next;
BT_DBG("session %p status 0x%02x encr 0x%02x", session, hci_status,
conn->encrypt);
for (dlc = session->dlcs; dlc; dlc = next) {
next = dlc->_next;
if (dlc->state != BT_RFCOMM_STATE_SECURITY_PENDING) {
continue;
}
if (hci_status || !conn->encrypt ||
conn->sec_level < dlc->required_sec_level) {
rfcomm_dlc_close(dlc);
continue;
}
if (dlc->role == BT_RFCOMM_ROLE_ACCEPTOR) {
rfcomm_send_ua(session, dlc->dlci);
rfcomm_dlc_connected(dlc);
} else {
dlc->mtu = min(dlc->mtu, session->mtu);
dlc->state = BT_RFCOMM_STATE_CONFIG;
rfcomm_send_pn(dlc, BT_RFCOMM_MSG_CMD_CR);
}
}
}
static void rfcomm_session_rtx_timeout(struct k_work *work)
{
struct bt_rfcomm_session *session = SESSION_RTX(work);
BT_WARN("session %p state %d timeout", session, session->state);
switch (session->state) {
case BT_RFCOMM_STATE_CONNECTED:
rfcomm_session_disconnect(session);
break;
case BT_RFCOMM_STATE_DISCONNECTING:
session->state = BT_RFCOMM_STATE_DISCONNECTED;
if (bt_l2cap_chan_disconnect(&session->br_chan.chan) < 0) {
session->state = BT_RFCOMM_STATE_IDLE;
}
break;
}
}
static struct bt_rfcomm_session *rfcomm_session_new(bt_rfcomm_role_t role)
{
int i;
static struct bt_l2cap_chan_ops ops = {
.connected = rfcomm_connected,
.disconnected = rfcomm_disconnected,
.recv = rfcomm_recv,
.encrypt_change = rfcomm_encrypt_change,
};
for (i = 0; i < ARRAY_SIZE(bt_rfcomm_pool); i++) {
struct bt_rfcomm_session *session = &bt_rfcomm_pool[i];
if (session->br_chan.chan.conn) {
continue;
}
BT_DBG("session %p initialized", session);
session->br_chan.chan.ops = &ops;
session->br_chan.rx.mtu = CONFIG_BT_RFCOMM_L2CAP_MTU;
session->state = BT_RFCOMM_STATE_INIT;
session->role = role;
session->cfc = BT_RFCOMM_CFC_UNKNOWN;
k_delayed_work_init(&session->rtx_work,
rfcomm_session_rtx_timeout);
k_sem_init(&session->fc, 0, 1);
return session;
}
return NULL;
}
int bt_rfcomm_dlc_connect(struct bt_conn *conn, struct bt_rfcomm_dlc *dlc,
u8_t channel)
{
struct bt_rfcomm_session *session;
struct bt_l2cap_chan *chan;
u8_t dlci;
int ret;
BT_DBG("conn %p dlc %p channel %d", conn, dlc, channel);
if (!dlc) {
return -EINVAL;
}
if (!conn || conn->state != BT_CONN_CONNECTED) {
return -ENOTCONN;
}
if (channel < RFCOMM_CHANNEL_START || channel > RFCOMM_CHANNEL_END) {
return -EINVAL;
}
if (!BT_RFCOMM_CHECK_MTU(dlc->mtu)) {
return -EINVAL;
}
session = rfcomm_sessions_lookup_bt_conn(conn);
if (!session) {
session = rfcomm_session_new(BT_RFCOMM_ROLE_INITIATOR);
if (!session) {
return -ENOMEM;
}
}
dlci = BT_RFCOMM_DLCI(session->role, channel);
if (rfcomm_dlcs_lookup_dlci(session->dlcs, dlci)) {
return -EBUSY;
}
rfcomm_dlc_init(dlc, session, dlci, BT_RFCOMM_ROLE_INITIATOR);
switch (session->state) {
case BT_RFCOMM_STATE_INIT:
if (session->role == BT_RFCOMM_ROLE_ACCEPTOR) {
/* There is an ongoing incoming conn */
break;
}
chan = &session->br_chan.chan;
chan->required_sec_level = dlc->required_sec_level;
ret = bt_l2cap_chan_connect(conn, chan, BT_L2CAP_PSM_RFCOMM);
if (ret < 0) {
session->state = BT_RFCOMM_STATE_IDLE;
goto fail;
}
session->state = BT_RFCOMM_STATE_CONNECTING;
break;
case BT_RFCOMM_STATE_CONNECTING:
break;
case BT_RFCOMM_STATE_CONNECTED:
ret = rfcomm_dlc_start(dlc);
if (ret < 0) {
goto fail;
}
/* Cancel idle timer if any */
k_delayed_work_cancel(&session->rtx_work);
break;
default:
BT_ERR("Invalid session state %d", session->state);
ret = -EINVAL;
goto fail;
}
return 0;
fail:
rfcomm_dlcs_remove_dlci(session->dlcs, dlc->dlci);
dlc->state = BT_RFCOMM_STATE_IDLE;
dlc->session = NULL;
return ret;
}
int bt_rfcomm_dlc_disconnect(struct bt_rfcomm_dlc *dlc)
{
BT_DBG("dlc %p", dlc);
if (!dlc) {
return -EINVAL;
}
if (dlc->state == BT_RFCOMM_STATE_CONNECTED) {
/* This is to handle user initiated disconnect to send pending
* bufs in the queue before disconnecting
* Queue a dummy buffer (in case if queue is empty) to wake up
* and stop the tx thread.
*/
dlc->state = BT_RFCOMM_STATE_USER_DISCONNECT;
net_buf_put(&dlc->tx_queue,
net_buf_alloc(&dummy_pool, K_NO_WAIT));
k_delayed_work_submit(&dlc->rtx_work, RFCOMM_DISC_TIMEOUT);
return 0;
}
return rfcomm_dlc_close(dlc);
}
static int rfcomm_accept(struct bt_conn *conn, struct bt_l2cap_chan **chan)
{
struct bt_rfcomm_session *session;
BT_DBG("conn %p", conn);
session = rfcomm_session_new(BT_RFCOMM_ROLE_ACCEPTOR);
if (session) {
*chan = &session->br_chan.chan;
return 0;
}
BT_ERR("No available RFCOMM context for conn %p", conn);
return -ENOMEM;
}
void bt_rfcomm_init(void)
{
static struct bt_l2cap_server server = {
.psm = BT_L2CAP_PSM_RFCOMM,
.accept = rfcomm_accept,
.sec_level = BT_SECURITY_LOW,
};
bt_l2cap_br_server_register(&server);
}
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