blob: c192e218dfd50d82f958fd8e57ca2825df076844 [file] [log] [blame]
/*
*
* BlueZ - Bluetooth protocol stack for Linux
*
* Copyright (C) 2006-2010 Nokia Corporation
* Copyright (C) 2004-2010 Marcel Holtmann <marcel@holtmann.org>
* Copyright (C) 2011 Texas Instruments, Inc.
*
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdlib.h>
#include <stdint.h>
#include <stdbool.h>
#include <errno.h>
#include <unistd.h>
#include <assert.h>
#include <signal.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <netinet/in.h>
#include <glib.h>
#include "lib/bluetooth.h"
#include "lib/sdp.h"
#include "lib/l2cap.h"
#include "lib/uuid.h"
#include "btio/btio.h"
#include "src/adapter.h"
#include "src/device.h"
#include "src/log.h"
#include "src/error.h"
#include "src/uinput.h"
#include "avctp.h"
#include "avrcp.h"
/* AV/C Panel 1.23, page 76:
* command with the pressed value is valid for two seconds
*/
#define AVC_PRESS_TIMEOUT 2
#define CONTROL_TIMEOUT 10
#define BROWSING_TIMEOUT 10
#define PASSTHROUGH_QUEUE 0
#define CONTROL_QUEUE 1
#define QUIRK_NO_RELEASE 1 << 0
/* Message types */
#define AVCTP_COMMAND 0
#define AVCTP_RESPONSE 1
/* Packet types */
#define AVCTP_PACKET_SINGLE 0
#define AVCTP_PACKET_START 1
#define AVCTP_PACKET_CONTINUE 2
#define AVCTP_PACKET_END 3
#if __BYTE_ORDER == __LITTLE_ENDIAN
struct avctp_header {
uint8_t ipid:1;
uint8_t cr:1;
uint8_t packet_type:2;
uint8_t transaction:4;
uint16_t pid;
} __attribute__ ((packed));
#define AVCTP_HEADER_LENGTH 3
struct avc_header {
uint8_t code:4;
uint8_t _hdr0:4;
uint8_t subunit_id:3;
uint8_t subunit_type:5;
uint8_t opcode;
} __attribute__ ((packed));
#elif __BYTE_ORDER == __BIG_ENDIAN
struct avctp_header {
uint8_t transaction:4;
uint8_t packet_type:2;
uint8_t cr:1;
uint8_t ipid:1;
uint16_t pid;
} __attribute__ ((packed));
#define AVCTP_HEADER_LENGTH 3
struct avc_header {
uint8_t _hdr0:4;
uint8_t code:4;
uint8_t subunit_type:5;
uint8_t subunit_id:3;
uint8_t opcode;
} __attribute__ ((packed));
#else
#error "Unknown byte order"
#endif
struct avctp_state_callback {
avctp_state_cb cb;
struct btd_device *dev;
unsigned int id;
void *user_data;
};
struct avctp_server {
struct btd_adapter *adapter;
GIOChannel *control_io;
GIOChannel *browsing_io;
GSList *sessions;
};
struct avctp_control_req {
struct avctp_pending_req *p;
uint8_t code;
uint8_t subunit;
uint8_t op;
uint8_t *operands;
uint16_t operand_count;
avctp_rsp_cb func;
void *user_data;
};
struct avctp_browsing_req {
struct avctp_pending_req *p;
uint8_t *operands;
uint16_t operand_count;
avctp_browsing_rsp_cb func;
void *user_data;
};
typedef int (*avctp_process_cb) (void *data);
struct avctp_pending_req {
struct avctp_queue *queue;
uint8_t transaction;
guint timeout;
bool retry;
int err;
avctp_process_cb process;
void *data;
GDestroyNotify destroy;
};
struct avctp_queue {
struct avctp_channel *chan;
struct avctp_pending_req *p;
GQueue *queue;
guint process_id;
};
struct avctp_channel {
struct avctp *session;
GIOChannel *io;
uint8_t transaction;
guint watch;
uint16_t imtu;
uint16_t omtu;
uint8_t *buffer;
GSList *handlers;
GSList *queues;
GSList *processed;
GDestroyNotify destroy;
};
struct key_pressed {
uint16_t op;
guint timer;
};
struct avctp {
struct avctp_server *server;
struct btd_device *device;
avctp_state_t state;
int uinput;
guint auth_id;
unsigned int passthrough_id;
unsigned int unit_id;
unsigned int subunit_id;
struct avctp_channel *control;
struct avctp_channel *browsing;
struct avctp_passthrough_handler *handler;
uint8_t key_quirks[256];
struct key_pressed key;
bool initiator;
};
struct avctp_passthrough_handler {
avctp_passthrough_cb cb;
void *user_data;
unsigned int id;
};
struct avctp_pdu_handler {
uint8_t opcode;
avctp_control_pdu_cb cb;
void *user_data;
unsigned int id;
};
struct avctp_browsing_pdu_handler {
avctp_browsing_pdu_cb cb;
void *user_data;
unsigned int id;
GDestroyNotify destroy;
};
static struct {
const char *name;
uint8_t avc;
uint16_t uinput;
} key_map[] = {
{ "SELECT", AVC_SELECT, KEY_SELECT },
{ "UP", AVC_UP, KEY_UP },
{ "DOWN", AVC_DOWN, KEY_DOWN },
{ "LEFT", AVC_LEFT, KEY_LEFT },
{ "RIGHT", AVC_RIGHT, KEY_RIGHT },
{ "ROOT MENU", AVC_ROOT_MENU, KEY_MENU },
{ "CONTENTS MENU", AVC_CONTENTS_MENU, KEY_PROGRAM },
{ "FAVORITE MENU", AVC_FAVORITE_MENU, KEY_FAVORITES },
{ "EXIT", AVC_EXIT, KEY_EXIT },
{ "ON DEMAND MENU", AVC_ON_DEMAND_MENU, KEY_MENU },
{ "APPS MENU", AVC_APPS_MENU, KEY_MENU },
{ "0", AVC_0, KEY_0 },
{ "1", AVC_1, KEY_1 },
{ "2", AVC_2, KEY_2 },
{ "3", AVC_3, KEY_3 },
{ "4", AVC_4, KEY_4 },
{ "5", AVC_5, KEY_5 },
{ "6", AVC_6, KEY_6 },
{ "7", AVC_7, KEY_7 },
{ "8", AVC_8, KEY_8 },
{ "9", AVC_9, KEY_9 },
{ "DOT", AVC_DOT, KEY_DOT },
{ "ENTER", AVC_ENTER, KEY_ENTER },
{ "CHANNEL UP", AVC_CHANNEL_UP, KEY_CHANNELUP },
{ "CHANNEL DOWN", AVC_CHANNEL_DOWN, KEY_CHANNELDOWN },
{ "CHANNEL PREVIOUS", AVC_CHANNEL_PREVIOUS, KEY_LAST },
{ "INPUT SELECT", AVC_INPUT_SELECT, KEY_CONFIG },
{ "INFO", AVC_INFO, KEY_INFO },
{ "HELP", AVC_HELP, KEY_HELP },
{ "POWER", AVC_POWER, KEY_POWER2 },
{ "VOLUME UP", AVC_VOLUME_UP, KEY_VOLUMEUP },
{ "VOLUME DOWN", AVC_VOLUME_DOWN, KEY_VOLUMEDOWN },
{ "MUTE", AVC_MUTE, KEY_MUTE },
{ "PLAY", AVC_PLAY, KEY_PLAYCD },
{ "STOP", AVC_STOP, KEY_STOPCD },
{ "PAUSE", AVC_PAUSE, KEY_PAUSECD },
{ "FORWARD", AVC_FORWARD, KEY_NEXTSONG },
{ "BACKWARD", AVC_BACKWARD, KEY_PREVIOUSSONG },
{ "RECORD", AVC_RECORD, KEY_RECORD },
{ "REWIND", AVC_REWIND, KEY_REWIND },
{ "FAST FORWARD", AVC_FAST_FORWARD, KEY_FASTFORWARD },
{ "LIST", AVC_LIST, KEY_LIST },
{ "F1", AVC_F1, KEY_F1 },
{ "F2", AVC_F2, KEY_F2 },
{ "F3", AVC_F3, KEY_F3 },
{ "F4", AVC_F4, KEY_F4 },
{ "F5", AVC_F5, KEY_F5 },
{ "F6", AVC_F6, KEY_F6 },
{ "F7", AVC_F7, KEY_F7 },
{ "F8", AVC_F8, KEY_F8 },
{ "F9", AVC_F9, KEY_F9 },
{ "RED", AVC_RED, KEY_RED },
{ "GREEN", AVC_GREEN, KEY_GREEN },
{ "BLUE", AVC_BLUE, KEY_BLUE },
{ "YELLOW", AVC_YELLOW, KEY_YELLOW },
{ NULL }
};
static GSList *callbacks = NULL;
static GSList *servers = NULL;
static void auth_cb(DBusError *derr, void *user_data);
static gboolean process_queue(gpointer user_data);
static gboolean avctp_passthrough_rsp(struct avctp *session, uint8_t code,
uint8_t subunit, uint8_t transaction,
uint8_t *operands, size_t operand_count,
void *user_data);
static int send_event(int fd, uint16_t type, uint16_t code, int32_t value)
{
struct uinput_event event;
memset(&event, 0, sizeof(event));
event.type = type;
event.code = code;
event.value = value;
return write(fd, &event, sizeof(event));
}
static void send_key(int fd, uint16_t key, int pressed)
{
if (fd < 0)
return;
send_event(fd, EV_KEY, key, pressed);
send_event(fd, EV_SYN, SYN_REPORT, 0);
}
static gboolean auto_release(gpointer user_data)
{
struct avctp *session = user_data;
session->key.timer = 0;
DBG("AV/C: key press timeout");
send_key(session->uinput, session->key.op, 0);
return FALSE;
}
static void handle_press(struct avctp *session, uint16_t op)
{
if (session->key.timer > 0) {
g_source_remove(session->key.timer);
/* Only auto release if keys are different */
if (session->key.op == op)
goto done;
send_key(session->uinput, session->key.op, 0);
}
session->key.op = op;
send_key(session->uinput, op, 1);
done:
session->key.timer = g_timeout_add_seconds(AVC_PRESS_TIMEOUT,
auto_release, session);
}
static void handle_release(struct avctp *session, uint16_t op)
{
if (session->key.timer > 0) {
g_source_remove(session->key.timer);
session->key.timer = 0;
}
send_key(session->uinput, op, 0);
}
static size_t handle_panel_passthrough(struct avctp *session,
uint8_t transaction, uint8_t *code,
uint8_t *subunit, uint8_t *operands,
size_t operand_count, void *user_data)
{
struct avctp_passthrough_handler *handler = session->handler;
const char *status;
int pressed, i;
if (*code != AVC_CTYPE_CONTROL || *subunit != AVC_SUBUNIT_PANEL) {
*code = AVC_CTYPE_REJECTED;
return operand_count;
}
if (operand_count == 0)
goto done;
if (operands[0] & 0x80) {
status = "released";
pressed = 0;
} else {
status = "pressed";
pressed = 1;
}
if (session->key.timer == 0 && handler != NULL) {
if (handler->cb(session, operands[0] & 0x7F,
pressed, handler->user_data))
goto done;
}
for (i = 0; key_map[i].name != NULL; i++) {
uint8_t key_quirks;
if ((operands[0] & 0x7F) != key_map[i].avc)
continue;
DBG("AV/C: %s %s", key_map[i].name, status);
key_quirks = session->key_quirks[key_map[i].avc];
if (key_quirks & QUIRK_NO_RELEASE) {
if (!pressed) {
DBG("AV/C: Ignoring release");
break;
}
DBG("AV/C: treating key press as press + release");
send_key(session->uinput, key_map[i].uinput, 1);
send_key(session->uinput, key_map[i].uinput, 0);
break;
}
if (pressed)
handle_press(session, key_map[i].uinput);
else
handle_release(session, key_map[i].uinput);
break;
}
if (key_map[i].name == NULL) {
DBG("AV/C: unknown button 0x%02X %s",
operands[0] & 0x7F, status);
*code = AVC_CTYPE_NOT_IMPLEMENTED;
return operand_count;
}
done:
*code = AVC_CTYPE_ACCEPTED;
return operand_count;
}
static size_t handle_unit_info(struct avctp *session,
uint8_t transaction, uint8_t *code,
uint8_t *subunit, uint8_t *operands,
size_t operand_count, void *user_data)
{
if (*code != AVC_CTYPE_STATUS) {
*code = AVC_CTYPE_REJECTED;
return 0;
}
*code = AVC_CTYPE_STABLE;
/* The first operand should be 0x07 for the UNITINFO response.
* Neither AVRCP (section 22.1, page 117) nor AVC Digital
* Interface Command Set (section 9.2.1, page 45) specs
* explain this value but both use it */
if (operand_count >= 1)
operands[0] = 0x07;
if (operand_count >= 2)
operands[1] = AVC_SUBUNIT_PANEL << 3;
DBG("reply to AVC_OP_UNITINFO");
return operand_count;
}
static size_t handle_subunit_info(struct avctp *session,
uint8_t transaction, uint8_t *code,
uint8_t *subunit, uint8_t *operands,
size_t operand_count, void *user_data)
{
if (*code != AVC_CTYPE_STATUS) {
*code = AVC_CTYPE_REJECTED;
return 0;
}
*code = AVC_CTYPE_STABLE;
/* The first operand should be 0x07 for the UNITINFO response.
* Neither AVRCP (section 22.1, page 117) nor AVC Digital
* Interface Command Set (section 9.2.1, page 45) specs
* explain this value but both use it */
if (operand_count >= 2)
operands[1] = AVC_SUBUNIT_PANEL << 3;
DBG("reply to AVC_OP_SUBUNITINFO");
return operand_count;
}
static struct avctp_pdu_handler *find_handler(GSList *list, uint8_t opcode)
{
for (; list; list = list->next) {
struct avctp_pdu_handler *handler = list->data;
if (handler->opcode == opcode)
return handler;
}
return NULL;
}
static void pending_destroy(gpointer data, gpointer user_data)
{
struct avctp_pending_req *req = data;
if (req->destroy)
req->destroy(req->data);
if (req->timeout > 0)
g_source_remove(req->timeout);
g_free(req);
}
static void avctp_queue_destroy(void *data)
{
struct avctp_queue *queue = data;
if (queue->process_id > 0)
g_source_remove(queue->process_id);
if (queue->p)
pending_destroy(queue->p, NULL);
g_queue_foreach(queue->queue, pending_destroy, NULL);
g_queue_free(queue->queue);
g_free(queue);
}
static void avctp_channel_destroy(struct avctp_channel *chan)
{
g_io_channel_shutdown(chan->io, TRUE, NULL);
g_io_channel_unref(chan->io);
if (chan->watch)
g_source_remove(chan->watch);
if (chan->destroy)
chan->destroy(chan);
g_free(chan->buffer);
g_slist_free_full(chan->queues, avctp_queue_destroy);
g_slist_foreach(chan->processed, pending_destroy, NULL);
g_slist_free(chan->processed);
g_slist_free_full(chan->handlers, g_free);
g_free(chan);
}
static void avctp_disconnected(struct avctp *session)
{
struct avctp_server *server;
if (!session)
return;
if (session->browsing)
avctp_channel_destroy(session->browsing);
if (session->control)
avctp_channel_destroy(session->control);
if (session->auth_id != 0) {
btd_cancel_authorization(session->auth_id);
session->auth_id = 0;
}
if (session->key.timer > 0)
g_source_remove(session->key.timer);
if (session->uinput >= 0) {
char address[18];
ba2str(device_get_address(session->device), address);
DBG("AVCTP: closing uinput for %s", address);
ioctl(session->uinput, UI_DEV_DESTROY);
close(session->uinput);
session->uinput = -1;
}
server = session->server;
server->sessions = g_slist_remove(server->sessions, session);
btd_device_unref(session->device);
g_free(session);
}
static void avctp_set_state(struct avctp *session, avctp_state_t new_state,
int err)
{
GSList *l;
avctp_state_t old_state = session->state;
session->state = new_state;
for (l = callbacks; l != NULL; l = l->next) {
struct avctp_state_callback *cb = l->data;
if (cb->dev && cb->dev != session->device)
continue;
cb->cb(session->device, old_state, new_state, err,
cb->user_data);
}
switch (new_state) {
case AVCTP_STATE_DISCONNECTED:
DBG("AVCTP Disconnected");
avctp_disconnected(session);
break;
case AVCTP_STATE_CONNECTING:
DBG("AVCTP Connecting");
break;
case AVCTP_STATE_CONNECTED:
DBG("AVCTP Connected");
break;
case AVCTP_STATE_BROWSING_CONNECTING:
DBG("AVCTP Browsing Connecting");
break;
case AVCTP_STATE_BROWSING_CONNECTED:
DBG("AVCTP Browsing Connected");
break;
default:
error("Invalid AVCTP state %d", new_state);
return;
}
}
static uint8_t chan_get_transaction(struct avctp_channel *chan)
{
GSList *l, *tmp;
uint8_t transaction;
if (!chan->processed)
goto done;
tmp = g_slist_copy(chan->processed);
/* Find first unused transaction id */
for (l = tmp; l; l = g_slist_next(l)) {
struct avctp_pending_req *req = l->data;
if (req->transaction == chan->transaction) {
chan->transaction++;
chan->transaction %= 16;
tmp = g_slist_delete_link(tmp, l);
l = tmp;
}
}
g_slist_free(tmp);
done:
transaction = chan->transaction;
chan->transaction++;
chan->transaction %= 16;
return transaction;
}
static int avctp_send(struct avctp_channel *control, uint8_t transaction,
uint8_t cr, uint8_t code,
uint8_t subunit, uint8_t opcode,
uint8_t *operands, size_t operand_count)
{
struct avctp_header *avctp;
struct avc_header *avc;
struct msghdr msg;
struct iovec iov[2];
int sk, err = 0;
iov[0].iov_base = control->buffer;
iov[0].iov_len = sizeof(*avctp) + sizeof(*avc);
iov[1].iov_base = operands;
iov[1].iov_len = operand_count;
if (control->omtu < (iov[0].iov_len + iov[1].iov_len))
return -EOVERFLOW;
sk = g_io_channel_unix_get_fd(control->io);
memset(control->buffer, 0, iov[0].iov_len);
avctp = (void *) control->buffer;
avc = (void *) avctp + sizeof(*avctp);
if (transaction > 16)
transaction = chan_get_transaction(control);
avctp->transaction = transaction;
avctp->packet_type = AVCTP_PACKET_SINGLE;
avctp->cr = cr;
avctp->pid = htons(AV_REMOTE_SVCLASS_ID);
avc->code = code;
avc->subunit_type = subunit;
avc->opcode = opcode;
memset(&msg, 0, sizeof(msg));
msg.msg_iov = iov;
msg.msg_iovlen = 2;
if (sendmsg(sk, &msg, 0) < 0)
err = -errno;
return err;
}
static int avctp_browsing_send(struct avctp_queue *queue,
uint8_t transaction, uint8_t cr,
uint8_t *operands, size_t operand_count)
{
struct avctp_channel *browsing = queue->chan;
struct avctp_header *avctp;
struct msghdr msg;
struct iovec iov[2];
int sk, err = 0;
iov[0].iov_base = browsing->buffer;
iov[0].iov_len = sizeof(*avctp);
iov[1].iov_base = operands;
iov[1].iov_len = operand_count;
if (browsing->omtu < (iov[0].iov_len + iov[1].iov_len))
return -EOVERFLOW;
sk = g_io_channel_unix_get_fd(browsing->io);
memset(browsing->buffer, 0, iov[0].iov_len);
avctp = (void *) browsing->buffer;
avctp->transaction = transaction;
avctp->packet_type = AVCTP_PACKET_SINGLE;
avctp->cr = cr;
avctp->pid = htons(AV_REMOTE_SVCLASS_ID);
memset(&msg, 0, sizeof(msg));
msg.msg_iov = iov;
msg.msg_iovlen = 2;
if (sendmsg(sk, &msg, 0) < 0)
err = -errno;
return err;
}
static void control_req_destroy(void *data)
{
struct avctp_control_req *req = data;
struct avctp_pending_req *p = req->p;
struct avctp *session = p->queue->chan->session;
if (p->err == 0 || req->func == NULL)
goto done;
req->func(session, AVC_CTYPE_REJECTED, req->subunit, p->transaction,
NULL, 0, req->user_data);
done:
g_free(req->operands);
g_free(req);
}
static void browsing_req_destroy(void *data)
{
struct avctp_browsing_req *req = data;
struct avctp_pending_req *p = req->p;
struct avctp *session = p->queue->chan->session;
if (p->err == 0 || req->func == NULL)
goto done;
req->func(session, NULL, 0, req->user_data);
done:
g_free(req->operands);
g_free(req);
}
static gboolean req_timeout(gpointer user_data)
{
struct avctp_queue *queue = user_data;
struct avctp_pending_req *p = queue->p;
DBG("transaction %u retry %s", p->transaction, p->retry ? "true" :
"false");
p->timeout = 0;
if (p->retry) {
p->process(p->data);
return FALSE;
}
p->err = -ETIMEDOUT;
pending_destroy(p, NULL);
queue->p = NULL;
if (queue->process_id == 0)
queue->process_id = g_idle_add(process_queue, queue);
return FALSE;
}
static int process_passthrough(void *data)
{
struct avctp_control_req *req = data;
struct avctp_pending_req *p = req->p;
int ret;
ret = avctp_send(p->queue->chan, p->transaction, AVCTP_COMMAND,
req->code, req->subunit, req->op, req->operands,
req->operand_count);
if (ret < 0)
return ret;
p->timeout = g_timeout_add_seconds(AVC_PRESS_TIMEOUT, req_timeout,
p->queue);
return 0;
}
static int process_control(void *data)
{
struct avctp_control_req *req = data;
struct avctp_pending_req *p = req->p;
int ret;
ret = avctp_send(p->queue->chan, p->transaction, AVCTP_COMMAND,
req->code, req->subunit, req->op, req->operands,
req->operand_count);
if (ret < 0)
return ret;
p->retry = !p->retry;
p->timeout = g_timeout_add_seconds(CONTROL_TIMEOUT, req_timeout,
p->queue);
return 0;
}
static int process_browsing(void *data)
{
struct avctp_browsing_req *req = data;
struct avctp_pending_req *p = req->p;
int ret;
ret = avctp_browsing_send(p->queue, p->transaction, AVCTP_COMMAND,
req->operands, req->operand_count);
if (ret < 0)
return ret;
p->timeout = g_timeout_add_seconds(BROWSING_TIMEOUT, req_timeout,
p->queue);
return 0;
}
static gboolean process_queue(void *user_data)
{
struct avctp_queue *queue = user_data;
struct avctp_pending_req *p = queue->p;
queue->process_id = 0;
if (p != NULL)
return FALSE;
while ((p = g_queue_pop_head(queue->queue))) {
if (p->process(p->data) == 0)
break;
pending_destroy(p, NULL);
}
if (p == NULL)
return FALSE;
queue->p = p;
return FALSE;
}
static void control_response(struct avctp_channel *control,
struct avctp_header *avctp,
struct avc_header *avc,
uint8_t *operands,
size_t operand_count)
{
struct avctp_pending_req *p;
struct avctp_control_req *req;
struct avctp_queue *queue;
GSList *l;
if (avc->opcode == AVC_OP_PASSTHROUGH)
queue = g_slist_nth_data(control->queues, PASSTHROUGH_QUEUE);
else
queue = g_slist_nth_data(control->queues, CONTROL_QUEUE);
p = queue->p;
if (p && p->transaction == avctp->transaction) {
req = p->data;
if (req->op != avc->opcode)
goto done;
control->processed = g_slist_prepend(control->processed, p);
if (p->timeout > 0) {
g_source_remove(p->timeout);
p->timeout = 0;
}
queue->p = NULL;
if (queue->process_id == 0)
queue->process_id = g_idle_add(process_queue, queue);
}
done:
for (l = control->processed; l; l = l->next) {
p = l->data;
req = p->data;
if (p->transaction != avctp->transaction)
continue;
if (req->op != avc->opcode)
continue;
if (req->func && req->func(control->session, avc->code,
avc->subunit_type, p->transaction,
operands, operand_count,
req->user_data))
return;
control->processed = g_slist_remove(control->processed, p);
pending_destroy(p, NULL);
return;
}
}
static void browsing_response(struct avctp_channel *browsing,
struct avctp_header *avctp,
uint8_t *operands,
size_t operand_count)
{
struct avctp_pending_req *p;
struct avctp_browsing_req *req;
struct avctp_queue *queue;
GSList *l;
queue = g_slist_nth_data(browsing->queues, 0);
p = queue->p;
if (p && p->transaction == avctp->transaction) {
browsing->processed = g_slist_prepend(browsing->processed, p);
if (p->timeout > 0) {
g_source_remove(p->timeout);
p->timeout = 0;
}
queue->p = NULL;
if (queue->process_id == 0)
queue->process_id = g_idle_add(process_queue, queue);
}
for (l = browsing->processed; l; l = l->next) {
p = l->data;
req = p->data;
if (p->transaction != avctp->transaction)
continue;
if (req->func && req->func(browsing->session, operands,
operand_count, req->user_data))
return;
browsing->processed = g_slist_remove(browsing->processed, p);
pending_destroy(p, NULL);
return;
}
}
static gboolean session_browsing_cb(GIOChannel *chan, GIOCondition cond,
gpointer data)
{
struct avctp *session = data;
struct avctp_channel *browsing = session->browsing;
uint8_t *buf = browsing->buffer;
uint8_t *operands;
struct avctp_header *avctp;
int sock, ret, packet_size, operand_count;
struct avctp_browsing_pdu_handler *handler;
if (cond & (G_IO_ERR | G_IO_HUP | G_IO_NVAL))
goto failed;
sock = g_io_channel_unix_get_fd(chan);
ret = read(sock, buf, browsing->imtu);
if (ret <= 0)
goto failed;
avctp = (struct avctp_header *) buf;
if (avctp->packet_type != AVCTP_PACKET_SINGLE)
goto failed;
operands = buf + AVCTP_HEADER_LENGTH;
ret -= AVCTP_HEADER_LENGTH;
operand_count = ret;
if (avctp->cr == AVCTP_RESPONSE) {
browsing_response(browsing, avctp, operands, operand_count);
return TRUE;
}
packet_size = AVCTP_HEADER_LENGTH;
avctp->cr = AVCTP_RESPONSE;
handler = g_slist_nth_data(browsing->handlers, 0);
if (handler == NULL) {
DBG("handler not found");
packet_size += avrcp_browsing_general_reject(operands);
goto send;
}
packet_size += handler->cb(session, avctp->transaction,
operands, operand_count,
handler->user_data);
send:
if (packet_size != 0) {
ret = write(sock, buf, packet_size);
if (ret != packet_size)
goto failed;
}
return TRUE;
failed:
DBG("AVCTP Browsing: disconnected");
avctp_set_state(session, AVCTP_STATE_CONNECTED, 0);
if (session->browsing) {
avctp_channel_destroy(session->browsing);
session->browsing = NULL;
}
return FALSE;
}
static gboolean session_cb(GIOChannel *chan, GIOCondition cond, gpointer data)
{
struct avctp *session = data;
struct avctp_channel *control = session->control;
uint8_t *buf = control->buffer;
uint8_t *operands, code, subunit;
struct avctp_header *avctp;
struct avc_header *avc;
int ret, packet_size, operand_count, sock;
struct avctp_pdu_handler *handler;
if (cond & (G_IO_ERR | G_IO_HUP | G_IO_NVAL))
goto failed;
sock = g_io_channel_unix_get_fd(chan);
ret = read(sock, buf, control->imtu);
if (ret <= 0)
goto failed;
if (ret < AVCTP_HEADER_LENGTH) {
error("Too small AVCTP packet");
goto failed;
}
avctp = (struct avctp_header *) buf;
ret -= AVCTP_HEADER_LENGTH;
if (ret < AVC_HEADER_LENGTH) {
error("Too small AVC packet");
goto failed;
}
avc = (struct avc_header *) (buf + AVCTP_HEADER_LENGTH);
ret -= AVC_HEADER_LENGTH;
operands = (uint8_t *) avc + AVC_HEADER_LENGTH;
operand_count = ret;
if (avctp->cr == AVCTP_RESPONSE) {
control_response(control, avctp, avc, operands, operand_count);
return TRUE;
}
packet_size = AVCTP_HEADER_LENGTH + AVC_HEADER_LENGTH;
avctp->cr = AVCTP_RESPONSE;
if (avctp->packet_type != AVCTP_PACKET_SINGLE) {
avc->code = AVC_CTYPE_NOT_IMPLEMENTED;
goto done;
}
if (avctp->pid != htons(AV_REMOTE_SVCLASS_ID)) {
avctp->ipid = 1;
packet_size = AVCTP_HEADER_LENGTH;
goto done;
}
handler = find_handler(control->handlers, avc->opcode);
if (!handler) {
DBG("handler not found for 0x%02x", avc->opcode);
packet_size += avrcp_handle_vendor_reject(&code, operands);
avc->code = code;
goto done;
}
code = avc->code;
subunit = avc->subunit_type;
packet_size += handler->cb(session, avctp->transaction, &code,
&subunit, operands, operand_count,
handler->user_data);
avc->code = code;
avc->subunit_type = subunit;
done:
ret = write(sock, buf, packet_size);
if (ret != packet_size)
goto failed;
return TRUE;
failed:
DBG("AVCTP session %p got disconnected", session);
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
return FALSE;
}
static int uinput_create(char *name)
{
struct uinput_dev dev;
int fd, err, i;
fd = open("/dev/uinput", O_RDWR);
if (fd < 0) {
fd = open("/dev/input/uinput", O_RDWR);
if (fd < 0) {
fd = open("/dev/misc/uinput", O_RDWR);
if (fd < 0) {
err = -errno;
error("Can't open input device: %s (%d)",
strerror(-err), -err);
return err;
}
}
}
memset(&dev, 0, sizeof(dev));
if (name)
strncpy(dev.name, name, UINPUT_MAX_NAME_SIZE - 1);
dev.id.bustype = BUS_BLUETOOTH;
dev.id.vendor = 0x0000;
dev.id.product = 0x0000;
dev.id.version = 0x0000;
if (write(fd, &dev, sizeof(dev)) < 0) {
err = -errno;
error("Can't write device information: %s (%d)",
strerror(-err), -err);
close(fd);
return err;
}
ioctl(fd, UI_SET_EVBIT, EV_KEY);
ioctl(fd, UI_SET_EVBIT, EV_REL);
ioctl(fd, UI_SET_EVBIT, EV_REP);
ioctl(fd, UI_SET_EVBIT, EV_SYN);
for (i = 0; key_map[i].name != NULL; i++)
ioctl(fd, UI_SET_KEYBIT, key_map[i].uinput);
if (ioctl(fd, UI_DEV_CREATE, NULL) < 0) {
err = -errno;
error("Can't create uinput device: %s (%d)",
strerror(-err), -err);
close(fd);
return err;
}
send_event(fd, EV_REP, REP_DELAY, 300);
return fd;
}
static void init_uinput(struct avctp *session)
{
char address[18], name[248 + 1];
device_get_name(session->device, name, sizeof(name));
if (g_str_equal(name, "Nokia CK-20W")) {
session->key_quirks[AVC_FORWARD] |= QUIRK_NO_RELEASE;
session->key_quirks[AVC_BACKWARD] |= QUIRK_NO_RELEASE;
session->key_quirks[AVC_PLAY] |= QUIRK_NO_RELEASE;
session->key_quirks[AVC_PAUSE] |= QUIRK_NO_RELEASE;
}
ba2str(device_get_address(session->device), address);
session->uinput = uinput_create(address);
if (session->uinput < 0)
error("AVRCP: failed to init uinput for %s", address);
else
DBG("AVRCP: uinput initialized for %s", address);
}
static struct avctp_queue *avctp_queue_create(struct avctp_channel *chan)
{
struct avctp_queue *queue;
queue = g_new0(struct avctp_queue, 1);
queue->chan = chan;
queue->queue = g_queue_new();
return queue;
}
static struct avctp_channel *avctp_channel_create(struct avctp *session,
GIOChannel *io,
int queues,
GDestroyNotify destroy)
{
struct avctp_channel *chan;
chan = g_new0(struct avctp_channel, 1);
chan->session = session;
chan->io = g_io_channel_ref(io);
chan->destroy = destroy;
while (queues--) {
struct avctp_queue *queue;
queue = avctp_queue_create(chan);
chan->queues = g_slist_prepend(chan->queues, queue);
}
return chan;
}
static void handler_free(void *data)
{
struct avctp_browsing_pdu_handler *handler = data;
if (handler->destroy)
handler->destroy(handler->user_data);
g_free(data);
}
static void avctp_destroy_browsing(void *data)
{
struct avctp_channel *chan = data;
g_slist_free_full(chan->handlers, handler_free);
chan->handlers = NULL;
}
static void avctp_connect_browsing_cb(GIOChannel *chan, GError *err,
gpointer data)
{
struct avctp *session = data;
struct avctp_channel *browsing = session->browsing;
struct avctp_queue *queue;
char address[18];
uint16_t imtu, omtu;
GError *gerr = NULL;
if (err) {
error("Browsing: %s", err->message);
goto fail;
}
bt_io_get(chan, &gerr,
BT_IO_OPT_DEST, &address,
BT_IO_OPT_IMTU, &imtu,
BT_IO_OPT_OMTU, &omtu,
BT_IO_OPT_INVALID);
if (gerr) {
error("%s", gerr->message);
g_io_channel_shutdown(chan, TRUE, NULL);
g_io_channel_unref(chan);
g_error_free(gerr);
goto fail;
}
DBG("AVCTP Browsing: connected to %s", address);
if (browsing == NULL) {
browsing = avctp_channel_create(session, chan, 1,
avctp_destroy_browsing);
session->browsing = browsing;
}
browsing->imtu = imtu;
browsing->omtu = omtu;
browsing->buffer = g_malloc0(MAX(imtu, omtu));
browsing->watch = g_io_add_watch(session->browsing->io,
G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL,
(GIOFunc) session_browsing_cb, session);
avctp_set_state(session, AVCTP_STATE_BROWSING_CONNECTED, 0);
/* Process any request that was pending the connection to complete */
queue = g_slist_nth_data(browsing->queues, 0);
if (queue->process_id == 0 && !g_queue_is_empty(queue->queue))
queue->process_id = g_idle_add(process_queue, queue);
return;
fail:
avctp_set_state(session, AVCTP_STATE_CONNECTED, 0);
if (session->browsing) {
avctp_channel_destroy(session->browsing);
session->browsing = NULL;
}
}
static void avctp_connect_cb(GIOChannel *chan, GError *err, gpointer data)
{
struct avctp *session = data;
char address[18];
uint16_t imtu, omtu;
GError *gerr = NULL;
if (err) {
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
error("%s", err->message);
return;
}
bt_io_get(chan, &gerr,
BT_IO_OPT_DEST, &address,
BT_IO_OPT_IMTU, &imtu,
BT_IO_OPT_IMTU, &omtu,
BT_IO_OPT_INVALID);
if (gerr) {
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
error("%s", gerr->message);
g_error_free(gerr);
return;
}
DBG("AVCTP: connected to %s", address);
if (session->control == NULL)
session->control = avctp_channel_create(session, chan, 2, NULL);
session->control->imtu = imtu;
session->control->omtu = omtu;
session->control->buffer = g_malloc0(MAX(imtu, omtu));
session->control->watch = g_io_add_watch(session->control->io,
G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL,
(GIOFunc) session_cb, session);
session->passthrough_id = avctp_register_pdu_handler(session,
AVC_OP_PASSTHROUGH,
handle_panel_passthrough,
NULL);
session->unit_id = avctp_register_pdu_handler(session,
AVC_OP_UNITINFO,
handle_unit_info,
NULL);
session->subunit_id = avctp_register_pdu_handler(session,
AVC_OP_SUBUNITINFO,
handle_subunit_info,
NULL);
init_uinput(session);
avctp_set_state(session, AVCTP_STATE_CONNECTED, 0);
}
static void auth_cb(DBusError *derr, void *user_data)
{
struct avctp *session = user_data;
GError *err = NULL;
session->auth_id = 0;
if (session->control->watch > 0) {
g_source_remove(session->control->watch);
session->control->watch = 0;
}
if (derr && dbus_error_is_set(derr)) {
error("Access denied: %s", derr->message);
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
return;
}
if (!bt_io_accept(session->control->io, avctp_connect_cb, session,
NULL, &err)) {
error("bt_io_accept: %s", err->message);
g_error_free(err);
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
}
}
static struct avctp_server *find_server(GSList *list, struct btd_adapter *a)
{
for (; list; list = list->next) {
struct avctp_server *server = list->data;
if (server->adapter == a)
return server;
}
return NULL;
}
static struct avctp *find_session(GSList *list, struct btd_device *device)
{
for (; list != NULL; list = g_slist_next(list)) {
struct avctp *s = list->data;
if (s->device == device)
return s;
}
return NULL;
}
static struct avctp *avctp_get_internal(struct btd_device *device)
{
struct avctp_server *server;
struct avctp *session;
server = find_server(servers, device_get_adapter(device));
if (server == NULL)
return NULL;
session = find_session(server->sessions, device);
if (session)
return session;
session = g_new0(struct avctp, 1);
session->server = server;
session->device = btd_device_ref(device);
session->state = AVCTP_STATE_DISCONNECTED;
session->uinput = -1;
server->sessions = g_slist_append(server->sessions, session);
return session;
}
static void avctp_control_confirm(struct avctp *session, GIOChannel *chan,
struct btd_device *dev)
{
const bdaddr_t *src;
const bdaddr_t *dst;
if (session->control != NULL) {
error("Control: Refusing unexpected connect");
g_io_channel_shutdown(chan, TRUE, NULL);
/*
* Close AVCTP channel if remote tried connect
* at the same time
* AVRCP SPEC V1.5 4.1.1 Connection Establishment
*/
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EAGAIN);
return;
}
avctp_set_state(session, AVCTP_STATE_CONNECTING, 0);
session->control = avctp_channel_create(session, chan, 2, NULL);
src = btd_adapter_get_address(device_get_adapter(dev));
dst = device_get_address(dev);
session->auth_id = btd_request_authorization(src, dst,
AVRCP_REMOTE_UUID,
auth_cb, session);
if (session->auth_id == 0)
goto drop;
session->control->watch = g_io_add_watch(chan, G_IO_ERR | G_IO_HUP |
G_IO_NVAL, session_cb, session);
return;
drop:
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
}
static void avctp_browsing_confirm(struct avctp *session, GIOChannel *chan,
struct btd_device *dev)
{
GError *err = NULL;
if (session->control == NULL || session->browsing != NULL) {
error("Browsing: Refusing unexpected connect");
g_io_channel_shutdown(chan, TRUE, NULL);
return;
}
if (bt_io_accept(chan, avctp_connect_browsing_cb, session, NULL,
&err)) {
avctp_set_state(session, AVCTP_STATE_BROWSING_CONNECTING, 0);
return;
}
error("Browsing: %s", err->message);
g_error_free(err);
return;
}
static void avctp_confirm_cb(GIOChannel *chan, gpointer data)
{
struct avctp *session;
char address[18];
bdaddr_t src, dst;
GError *err = NULL;
uint16_t psm;
struct btd_device *device;
bt_io_get(chan, &err,
BT_IO_OPT_SOURCE_BDADDR, &src,
BT_IO_OPT_DEST_BDADDR, &dst,
BT_IO_OPT_DEST, address,
BT_IO_OPT_PSM, &psm,
BT_IO_OPT_INVALID);
if (err) {
error("%s", err->message);
g_error_free(err);
g_io_channel_shutdown(chan, TRUE, NULL);
return;
}
DBG("AVCTP: incoming connect from %s", address);
device = btd_adapter_find_device(adapter_find(&src), &dst,
BDADDR_BREDR);
if (!device)
return;
session = avctp_get_internal(device);
if (session == NULL)
return;
if (btd_device_get_service(device, AVRCP_REMOTE_UUID) == NULL)
btd_device_add_uuid(device, AVRCP_REMOTE_UUID);
if (btd_device_get_service(device, AVRCP_TARGET_UUID) == NULL)
btd_device_add_uuid(device, AVRCP_TARGET_UUID);
switch (psm) {
case AVCTP_CONTROL_PSM:
avctp_control_confirm(session, chan, device);
break;
case AVCTP_BROWSING_PSM:
avctp_browsing_confirm(session, chan, device);
break;
}
return;
}
static GIOChannel *avctp_server_socket(const bdaddr_t *src, gboolean master,
uint8_t mode, uint16_t psm)
{
GError *err = NULL;
GIOChannel *io;
io = bt_io_listen(NULL, avctp_confirm_cb, NULL,
NULL, &err,
BT_IO_OPT_SOURCE_BDADDR, src,
BT_IO_OPT_PSM, psm,
BT_IO_OPT_SEC_LEVEL, BT_IO_SEC_MEDIUM,
BT_IO_OPT_MASTER, master,
BT_IO_OPT_MODE, mode,
BT_IO_OPT_INVALID);
if (!io) {
error("%s", err->message);
g_error_free(err);
}
return io;
}
int avctp_register(struct btd_adapter *adapter, gboolean master)
{
struct avctp_server *server;
const bdaddr_t *src = btd_adapter_get_address(adapter);
server = g_new0(struct avctp_server, 1);
server->control_io = avctp_server_socket(src, master, L2CAP_MODE_BASIC,
AVCTP_CONTROL_PSM);
if (!server->control_io) {
g_free(server);
return -1;
}
server->browsing_io = avctp_server_socket(src, master, L2CAP_MODE_ERTM,
AVCTP_BROWSING_PSM);
if (!server->browsing_io) {
if (server->control_io) {
g_io_channel_shutdown(server->control_io, TRUE, NULL);
g_io_channel_unref(server->control_io);
server->control_io = NULL;
}
g_free(server);
return -1;
}
server->adapter = btd_adapter_ref(adapter);
servers = g_slist_append(servers, server);
return 0;
}
void avctp_unregister(struct btd_adapter *adapter)
{
struct avctp_server *server;
server = find_server(servers, adapter);
if (!server)
return;
while (server->sessions)
avctp_disconnected(server->sessions->data);
servers = g_slist_remove(servers, server);
g_io_channel_shutdown(server->browsing_io, TRUE, NULL);
g_io_channel_unref(server->browsing_io);
server->browsing_io = NULL;
g_io_channel_shutdown(server->control_io, TRUE, NULL);
g_io_channel_unref(server->control_io);
btd_adapter_unref(server->adapter);
g_free(server);
}
static struct avctp_pending_req *pending_create(struct avctp_queue *queue,
avctp_process_cb process,
void *data,
GDestroyNotify destroy)
{
struct avctp_pending_req *p;
p = g_new0(struct avctp_pending_req, 1);
p->queue = queue;
p->transaction = chan_get_transaction(queue->chan);
p->process = process;
p->data = data;
p->destroy = destroy;
return p;
}
static int avctp_send_req(struct avctp *session, uint8_t code,
uint8_t subunit, uint8_t opcode,
uint8_t *operands, size_t operand_count,
avctp_rsp_cb func, void *user_data)
{
struct avctp_channel *control = session->control;
struct avctp_queue *queue;
struct avctp_pending_req *p;
struct avctp_control_req *req;
if (control == NULL)
return -ENOTCONN;
/* If the request set a callback send it directly */
if (!func)
return avctp_send(session->control, -1, AVCTP_COMMAND,
code, subunit, opcode, operands, operand_count);
req = g_new0(struct avctp_control_req, 1);
req->code = code;
req->subunit = subunit;
req->op = opcode;
req->func = func;
req->operands = g_memdup(operands, operand_count);
req->operand_count = operand_count;
req->user_data = user_data;
if (opcode == AVC_OP_PASSTHROUGH) {
queue = g_slist_nth_data(control->queues, PASSTHROUGH_QUEUE);
p = pending_create(queue, process_passthrough, req,
control_req_destroy);
} else {
queue = g_slist_nth_data(control->queues, CONTROL_QUEUE);
p = pending_create(queue, process_control, req,
control_req_destroy);
}
req->p = p;
g_queue_push_tail(queue->queue, p);
if (queue->process_id == 0)
queue->process_id = g_idle_add(process_queue, queue);
return 0;
}
int avctp_send_browsing_req(struct avctp *session,
uint8_t *operands, size_t operand_count,
avctp_browsing_rsp_cb func, void *user_data)
{
struct avctp_channel *browsing = session->browsing;
struct avctp_queue *queue;
struct avctp_pending_req *p;
struct avctp_browsing_req *req;
if (browsing == NULL)
return -ENOTCONN;
req = g_new0(struct avctp_browsing_req, 1);
req->func = func;
req->operands = g_memdup(operands, operand_count);
req->operand_count = operand_count;
req->user_data = user_data;
queue = g_slist_nth_data(browsing->queues, 0);
p = pending_create(queue, process_browsing, req, browsing_req_destroy);
req->p = p;
g_queue_push_tail(queue->queue, p);
/* Connection did not complete, delay process of the request */
if (browsing->watch == 0)
return 0;
if (queue->process_id == 0)
queue->process_id = g_idle_add(process_queue, queue);
return 0;
}
static const char *op2str(uint8_t op)
{
int i;
for (i = 0; key_map[i].name != NULL; i++) {
if ((op & 0x7F) == key_map[i].avc)
return key_map[i].name;
}
return "UNKNOWN";
}
static int avctp_passthrough_press(struct avctp *session, uint8_t op)
{
uint8_t operands[2];
DBG("%s", op2str(op));
/* Button pressed */
operands[0] = op & 0x7f;
operands[1] = 0;
return avctp_send_req(session, AVC_CTYPE_CONTROL,
AVC_SUBUNIT_PANEL, AVC_OP_PASSTHROUGH,
operands, sizeof(operands),
avctp_passthrough_rsp, NULL);
}
static int avctp_passthrough_release(struct avctp *session, uint8_t op)
{
uint8_t operands[2];
DBG("%s", op2str(op));
/* Button released */
operands[0] = op | 0x80;
operands[1] = 0;
return avctp_send_req(session, AVC_CTYPE_CONTROL,
AVC_SUBUNIT_PANEL, AVC_OP_PASSTHROUGH,
operands, sizeof(operands),
NULL, NULL);
}
static gboolean repeat_timeout(gpointer user_data)
{
struct avctp *session = user_data;
avctp_passthrough_release(session, session->key.op);
avctp_passthrough_press(session, session->key.op);
return TRUE;
}
static void release_pressed(struct avctp *session)
{
avctp_passthrough_release(session, session->key.op);
if (session->key.timer > 0)
g_source_remove(session->key.timer);
session->key.timer = 0;
}
static bool set_pressed(struct avctp *session, uint8_t op)
{
if (session->key.timer > 0) {
if (session->key.op == op)
return TRUE;
release_pressed(session);
}
if (op != AVC_FAST_FORWARD && op != AVC_REWIND)
return FALSE;
session->key.op = op;
session->key.timer = g_timeout_add_seconds(AVC_PRESS_TIMEOUT,
repeat_timeout,
session);
return TRUE;
}
static gboolean avctp_passthrough_rsp(struct avctp *session, uint8_t code,
uint8_t subunit, uint8_t transaction,
uint8_t *operands, size_t operand_count,
void *user_data)
{
if (code != AVC_CTYPE_ACCEPTED)
return FALSE;
if (set_pressed(session, operands[0]))
return FALSE;
avctp_passthrough_release(session, operands[0]);
return FALSE;
}
int avctp_send_passthrough(struct avctp *session, uint8_t op)
{
/* Auto release if key pressed */
if (session->key.timer > 0)
release_pressed(session);
return avctp_passthrough_press(session, op);
}
int avctp_send_vendordep(struct avctp *session, uint8_t transaction,
uint8_t code, uint8_t subunit,
uint8_t *operands, size_t operand_count)
{
struct avctp_channel *control = session->control;
if (control == NULL)
return -ENOTCONN;
return avctp_send(control, transaction, AVCTP_RESPONSE, code, subunit,
AVC_OP_VENDORDEP, operands, operand_count);
}
int avctp_send_vendordep_req(struct avctp *session, uint8_t code,
uint8_t subunit, uint8_t *operands,
size_t operand_count,
avctp_rsp_cb func, void *user_data)
{
return avctp_send_req(session, code, subunit, AVC_OP_VENDORDEP,
operands, operand_count,
func, user_data);
}
unsigned int avctp_add_state_cb(struct btd_device *dev, avctp_state_cb cb,
void *user_data)
{
struct avctp_state_callback *state_cb;
static unsigned int id = 0;
state_cb = g_new(struct avctp_state_callback, 1);
state_cb->cb = cb;
state_cb->dev = dev;
state_cb->id = ++id;
state_cb->user_data = user_data;
callbacks = g_slist_append(callbacks, state_cb);
return state_cb->id;
}
gboolean avctp_remove_state_cb(unsigned int id)
{
GSList *l;
for (l = callbacks; l != NULL; l = l->next) {
struct avctp_state_callback *cb = l->data;
if (cb && cb->id == id) {
callbacks = g_slist_remove(callbacks, cb);
g_free(cb);
return TRUE;
}
}
return FALSE;
}
unsigned int avctp_register_passthrough_handler(struct avctp *session,
avctp_passthrough_cb cb,
void *user_data)
{
struct avctp_channel *control = session->control;
struct avctp_passthrough_handler *handler;
static unsigned int id = 0;
if (control == NULL || session->handler != NULL)
return 0;
handler = g_new(struct avctp_passthrough_handler, 1);
handler->cb = cb;
handler->user_data = user_data;
handler->id = ++id;
session->handler = handler;
return handler->id;
}
bool avctp_unregister_passthrough_handler(unsigned int id)
{
GSList *l;
for (l = servers; l; l = l->next) {
struct avctp_server *server = l->data;
GSList *s;
for (s = server->sessions; s; s = s->next) {
struct avctp *session = s->data;
if (session->handler == NULL)
continue;
if (session->handler->id == id) {
g_free(session->handler);
session->handler = NULL;
return true;
}
}
}
return false;
}
unsigned int avctp_register_pdu_handler(struct avctp *session, uint8_t opcode,
avctp_control_pdu_cb cb,
void *user_data)
{
struct avctp_channel *control = session->control;
struct avctp_pdu_handler *handler;
static unsigned int id = 0;
if (control == NULL)
return 0;
handler = find_handler(control->handlers, opcode);
if (handler)
return 0;
handler = g_new(struct avctp_pdu_handler, 1);
handler->opcode = opcode;
handler->cb = cb;
handler->user_data = user_data;
handler->id = ++id;
control->handlers = g_slist_append(control->handlers, handler);
return handler->id;
}
unsigned int avctp_register_browsing_pdu_handler(struct avctp *session,
avctp_browsing_pdu_cb cb,
void *user_data,
GDestroyNotify destroy)
{
struct avctp_channel *browsing = session->browsing;
struct avctp_browsing_pdu_handler *handler;
static unsigned int id = 0;
if (browsing == NULL)
return 0;
if (browsing->handlers != NULL)
return 0;
handler = g_new(struct avctp_browsing_pdu_handler, 1);
handler->cb = cb;
handler->user_data = user_data;
handler->id = ++id;
handler->destroy = destroy;
browsing->handlers = g_slist_append(browsing->handlers, handler);
return handler->id;
}
gboolean avctp_unregister_pdu_handler(unsigned int id)
{
GSList *l;
for (l = servers; l; l = l->next) {
struct avctp_server *server = l->data;
GSList *s;
for (s = server->sessions; s; s = s->next) {
struct avctp *session = s->data;
struct avctp_channel *control = session->control;
GSList *h;
if (control == NULL)
continue;
for (h = control->handlers; h; h = h->next) {
struct avctp_pdu_handler *handler = h->data;
if (handler->id != id)
continue;
control->handlers = g_slist_remove(
control->handlers,
handler);
g_free(handler);
return TRUE;
}
}
}
return FALSE;
}
gboolean avctp_unregister_browsing_pdu_handler(unsigned int id)
{
GSList *l;
for (l = servers; l; l = l->next) {
struct avctp_server *server = l->data;
GSList *s;
for (s = server->sessions; s; s = s->next) {
struct avctp *session = s->data;
struct avctp_channel *browsing = session->browsing;
GSList *h;
if (browsing == NULL)
continue;
for (h = browsing->handlers; h; h = h->next) {
struct avctp_browsing_pdu_handler *handler =
h->data;
if (handler->id != id)
continue;
browsing->handlers = g_slist_remove(
browsing->handlers,
handler);
g_free(handler);
return TRUE;
}
}
}
return FALSE;
}
struct avctp *avctp_connect(struct btd_device *device)
{
struct avctp *session;
GError *err = NULL;
GIOChannel *io;
const bdaddr_t *src;
session = avctp_get_internal(device);
if (!session)
return NULL;
if (session->state > AVCTP_STATE_DISCONNECTED)
return session;
avctp_set_state(session, AVCTP_STATE_CONNECTING, 0);
src = btd_adapter_get_address(session->server->adapter);
io = bt_io_connect(avctp_connect_cb, session, NULL, &err,
BT_IO_OPT_SOURCE_BDADDR, src,
BT_IO_OPT_DEST_BDADDR,
device_get_address(session->device),
BT_IO_OPT_SEC_LEVEL, BT_IO_SEC_MEDIUM,
BT_IO_OPT_PSM, AVCTP_CONTROL_PSM,
BT_IO_OPT_INVALID);
if (err) {
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
error("%s", err->message);
g_error_free(err);
return NULL;
}
session->control = avctp_channel_create(session, io, 2, NULL);
session->initiator = true;
g_io_channel_unref(io);
return session;
}
int avctp_connect_browsing(struct avctp *session)
{
const bdaddr_t *src;
GError *err = NULL;
GIOChannel *io;
if (session->state != AVCTP_STATE_CONNECTED)
return -ENOTCONN;
if (session->browsing != NULL)
return 0;
avctp_set_state(session, AVCTP_STATE_BROWSING_CONNECTING, 0);
src = btd_adapter_get_address(session->server->adapter);
io = bt_io_connect(avctp_connect_browsing_cb, session, NULL, &err,
BT_IO_OPT_SOURCE_BDADDR, src,
BT_IO_OPT_DEST_BDADDR,
device_get_address(session->device),
BT_IO_OPT_SEC_LEVEL, BT_IO_SEC_MEDIUM,
BT_IO_OPT_PSM, AVCTP_BROWSING_PSM,
BT_IO_OPT_MODE, L2CAP_MODE_ERTM,
BT_IO_OPT_INVALID);
if (err) {
error("%s", err->message);
g_error_free(err);
return -EIO;
}
session->browsing = avctp_channel_create(session, io, 1,
avctp_destroy_browsing);
g_io_channel_unref(io);
return 0;
}
void avctp_disconnect(struct avctp *session)
{
if (session->state == AVCTP_STATE_DISCONNECTED)
return;
avctp_set_state(session, AVCTP_STATE_DISCONNECTED, -EIO);
}
struct avctp *avctp_get(struct btd_device *device)
{
return avctp_get_internal(device);
}
bool avctp_is_initiator(struct avctp *session)
{
return session->initiator;
}