bluez/client/player.c

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
*
* BlueZ - Bluetooth protocol stack for Linux
*
* Copyright (C) 2020 Intel Corporation. All rights reserved.
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
* Copyright 2023-2024 NXP
*
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#define _GNU_SOURCE
#include <stdio.h>
#include <stdbool.h>
#include <inttypes.h>
#include <errno.h>
#include <unistd.h>
#include <stdlib.h>
#include <fcntl.h>
#include <string.h>
#include <sys/ioctl.h>
#include <sys/uio.h>
#include <wordexp.h>
#include <sys/timerfd.h>
#include <sys/stat.h>
#include <glib.h>
#include "gdbus/gdbus.h"
#include "lib/bluetooth.h"
#include "lib/uuid.h"
#include "lib/iso.h"
#include "profiles/audio/a2dp-codecs.h"
#include "src/shared/lc3.h"
#include "src/shared/util.h"
#include "src/shared/shell.h"
#include "src/shared/io.h"
#include "src/shared/queue.h"
#include "src/shared/bap-debug.h"
#include "print.h"
#include "player.h"
/* String display constants */
#define COLORED_NEW COLOR_GREEN "NEW" COLOR_OFF
#define COLORED_CHG COLOR_YELLOW "CHG" COLOR_OFF
#define COLORED_DEL COLOR_RED "DEL" COLOR_OFF
#define BLUEZ_MEDIA_INTERFACE "org.bluez.Media1"
#define BLUEZ_MEDIA_PLAYER_INTERFACE "org.bluez.MediaPlayer1"
#define BLUEZ_MEDIA_FOLDER_INTERFACE "org.bluez.MediaFolder1"
#define BLUEZ_MEDIA_ITEM_INTERFACE "org.bluez.MediaItem1"
#define BLUEZ_MEDIA_ENDPOINT_INTERFACE "org.bluez.MediaEndpoint1"
#define BLUEZ_MEDIA_TRANSPORT_INTERFACE "org.bluez.MediaTransport1"
#define BLUEZ_MEDIA_ENDPOINT_PATH "/local/endpoint"
#define NSEC_USEC(_t) (_t / 1000L)
#define SEC_USEC(_t) (_t * 1000000L)
#define TS_USEC(_ts) (SEC_USEC((_ts)->tv_sec) + NSEC_USEC((_ts)->tv_nsec))
#define ROUND_CLOSEST(_x, _y) (((_x) + (_y / 2)) / (_y))
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
#define EP_SRC_LOCATIONS 0x00000003
#define EP_SNK_LOCATIONS 0x00000003
#define EP_SRC_CTXT 0x000f
#define EP_SUPPORTED_SRC_CTXT EP_SRC_CTXT
#define EP_SNK_CTXT 0x0fff
#define EP_SUPPORTED_SNK_CTXT EP_SNK_CTXT
#if __BYTE_ORDER == __LITTLE_ENDIAN
struct avdtp_media_codec_capability {
uint8_t rfa0:4;
uint8_t media_type:4;
uint8_t media_codec_type;
uint8_t data[0];
} __attribute__ ((packed));
#elif __BYTE_ORDER == __BIG_ENDIAN
struct avdtp_media_codec_capability {
uint8_t media_type:4;
uint8_t rfa0:4;
uint8_t media_codec_type;
uint8_t data[0];
} __attribute__ ((packed));
#else
#error "Unknown byte order"
#endif
#define BCAST_CODE {0x01, 0x02, 0x68, 0x05, 0x53, 0xf1, 0x41, 0x5a, \
0xa2, 0x65, 0xbb, 0xaf, 0xc6, 0xea, 0x03, 0xb8}
struct endpoint {
char *path;
char *uuid;
uint8_t codec;
uint16_t cid;
uint16_t vid;
struct iovec *caps;
struct iovec *meta;
uint32_t locations;
uint16_t supported_context;
uint16_t context;
bool auto_accept;
uint8_t max_transports;
uint8_t iso_group;
uint8_t iso_stream;
struct queue *acquiring;
struct queue *transports;
DBusMessage *msg;
struct preset *preset;
struct codec_preset *codec_preset;
bool broadcast;
struct iovec *bcode;
};
static DBusConnection *dbus_conn;
static GDBusProxy *default_player;
static GList *medias = NULL;
static GList *players = NULL;
static GList *folders = NULL;
static GList *items = NULL;
static GList *endpoints = NULL;
static GList *local_endpoints = NULL;
static GList *transports = NULL;
static struct queue *ios = NULL;
static uint8_t bcast_code[] = BCAST_CODE;
struct transport {
GDBusProxy *proxy;
int sk;
uint16_t mtu[2];
char *filename;
int fd;
struct stat stat;
struct io *io;
uint32_t seq;
struct io *timer_io;
int num;
};
static void endpoint_unregister(void *data)
{
struct endpoint *ep = data;
bt_shell_printf("Endpoint %s unregistered\n", ep->path);
g_dbus_unregister_interface(dbus_conn, ep->path,
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
}
static void disconnect_handler(DBusConnection *connection, void *user_data)
{
g_list_free_full(local_endpoints, endpoint_unregister);
local_endpoints = NULL;
}
static bool check_default_player(void)
{
if (!default_player) {
bt_shell_printf("No default player available\n");
return FALSE;
}
return TRUE;
}
static char *generic_generator(const char *text, int state, GList *source)
{
static int index = 0;
if (!source)
return NULL;
if (!state)
index = 0;
return g_dbus_proxy_path_lookup(source, &index, text);
}
static char *player_generator(const char *text, int state)
{
return generic_generator(text, state, players);
}
static char *item_generator(const char *text, int state)
{
return generic_generator(text, state, items);
}
static void play_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to play: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Play successful\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void cmd_play(int argc, char *argv[])
{
GDBusProxy *proxy;
if (argc > 1) {
proxy = g_dbus_proxy_lookup(items, NULL, argv[1],
BLUEZ_MEDIA_ITEM_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Item %s not available\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
} else {
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
proxy = default_player;
}
if (g_dbus_proxy_method_call(proxy, "Play", NULL, play_reply,
NULL, NULL) == FALSE) {
bt_shell_printf("Failed to play\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to play %s\n", argv[1] ? : "");
}
static void pause_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to pause: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Pause successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_pause(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "Pause", NULL,
pause_reply, NULL, NULL) == FALSE) {
bt_shell_printf("Failed to play\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to pause\n");
}
static void stop_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to stop: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Stop successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_stop(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "Stop", NULL, stop_reply,
NULL, NULL) == FALSE) {
bt_shell_printf("Failed to stop\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to stop\n");
}
static void next_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to jump to next: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Next successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_next(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "Next", NULL, next_reply,
NULL, NULL) == FALSE) {
bt_shell_printf("Failed to jump to next\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to jump to next\n");
}
static void previous_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to jump to previous: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Previous successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_previous(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "Previous", NULL,
previous_reply, NULL, NULL) == FALSE) {
bt_shell_printf("Failed to jump to previous\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to jump to previous\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void fast_forward_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to fast forward: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("FastForward successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_fast_forward(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "FastForward", NULL,
fast_forward_reply, NULL, NULL) == FALSE) {
bt_shell_printf("Failed to jump to previous\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Fast forward playback\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void rewind_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to rewind: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Rewind successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_rewind(int argc, char *argv[])
{
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (g_dbus_proxy_method_call(default_player, "Rewind", NULL,
rewind_reply, NULL, NULL) == FALSE) {
bt_shell_printf("Failed to rewind\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Rewind playback\n");
}
static void generic_callback(const DBusError *error, void *user_data)
{
char *str = user_data;
if (dbus_error_is_set(error)) {
bt_shell_printf("Failed to set %s: %s\n", str, error->name);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
} else {
bt_shell_printf("Changing %s succeeded\n", str);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
}
static void cmd_equalizer(int argc, char *argv[])
{
char *value;
DBusMessageIter iter;
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (!g_dbus_proxy_get_property(default_player, "Equalizer", &iter)) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
value = g_strdup(argv[1]);
if (g_dbus_proxy_set_property_basic(default_player, "Equalizer",
DBUS_TYPE_STRING, &value,
generic_callback, value,
g_free) == FALSE) {
bt_shell_printf("Failed to setting equalizer\n");
g_free(value);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to set equalizer\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_repeat(int argc, char *argv[])
{
char *value;
DBusMessageIter iter;
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (!g_dbus_proxy_get_property(default_player, "Repeat", &iter)) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
value = g_strdup(argv[1]);
if (g_dbus_proxy_set_property_basic(default_player, "Repeat",
DBUS_TYPE_STRING, &value,
generic_callback, value,
g_free) == FALSE) {
bt_shell_printf("Failed to set repeat\n");
g_free(value);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to set repeat\n");
}
static void cmd_shuffle(int argc, char *argv[])
{
char *value;
DBusMessageIter iter;
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (!g_dbus_proxy_get_property(default_player, "Shuffle", &iter)) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
value = g_strdup(argv[1]);
if (g_dbus_proxy_set_property_basic(default_player, "Shuffle",
DBUS_TYPE_STRING, &value,
generic_callback, value,
g_free) == FALSE) {
bt_shell_printf("Failed to set shuffle\n");
g_free(value);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to set shuffle\n");
}
static void cmd_scan(int argc, char *argv[])
{
char *value;
DBusMessageIter iter;
if (!check_default_player())
return bt_shell_noninteractive_quit(EXIT_FAILURE);
if (!g_dbus_proxy_get_property(default_player, "Shuffle", &iter)) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
value = g_strdup(argv[1]);
if (g_dbus_proxy_set_property_basic(default_player, "Shuffle",
DBUS_TYPE_STRING, &value,
generic_callback, value,
g_free) == FALSE) {
bt_shell_printf("Failed to set scan\n");
g_free(value);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to set scan\n");
}
static char *proxy_description(GDBusProxy *proxy, const char *title,
const char *description)
{
const char *path;
path = g_dbus_proxy_get_path(proxy);
return g_strdup_printf("%s%s%s%s %s ",
description ? "[" : "",
description ? : "",
description ? "] " : "",
title, path);
}
static void print_media(GDBusProxy *proxy, const char *description)
{
char *str;
str = proxy_description(proxy, "Media", description);
bt_shell_printf("%s\n", str);
print_property(proxy, "SupportedUUIDs");
g_free(str);
}
static void print_player(void *data, void *user_data)
{
GDBusProxy *proxy = data;
const char *description = user_data;
char *str;
str = proxy_description(proxy, "Player", description);
bt_shell_printf("%s%s\n", str,
default_player == proxy ? "[default]" : "");
g_free(str);
}
static void cmd_list(int argc, char *arg[])
{
g_list_foreach(players, print_player, NULL);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_show_item(int argc, char *argv[])
{
GDBusProxy *proxy;
proxy = g_dbus_proxy_lookup(items, NULL, argv[1],
BLUEZ_MEDIA_ITEM_INTERFACE);
if (!proxy) {
bt_shell_printf("Item %s not available\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
bt_shell_printf("Item %s\n", g_dbus_proxy_get_path(proxy));
print_property(proxy, "Player");
print_property(proxy, "Name");
print_property(proxy, "Type");
print_property(proxy, "FolderType");
print_property(proxy, "Playable");
print_property(proxy, "Metadata");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_show(int argc, char *argv[])
{
GDBusProxy *proxy;
GDBusProxy *folder;
GDBusProxy *item;
DBusMessageIter iter;
const char *path;
if (argc < 2) {
if (check_default_player() == FALSE)
return bt_shell_noninteractive_quit(EXIT_FAILURE);
proxy = default_player;
} else {
proxy = g_dbus_proxy_lookup(players, NULL, argv[1],
BLUEZ_MEDIA_PLAYER_INTERFACE);
if (!proxy) {
bt_shell_printf("Player %s not available\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
bt_shell_printf("Player %s\n", g_dbus_proxy_get_path(proxy));
print_property(proxy, "Name");
print_property(proxy, "Repeat");
print_property(proxy, "Equalizer");
print_property(proxy, "Shuffle");
print_property(proxy, "Scan");
print_property(proxy, "Status");
print_property(proxy, "Position");
print_property(proxy, "Track");
folder = g_dbus_proxy_lookup(folders, NULL,
g_dbus_proxy_get_path(proxy),
BLUEZ_MEDIA_FOLDER_INTERFACE);
if (folder == NULL)
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
bt_shell_printf("Folder %s\n", g_dbus_proxy_get_path(proxy));
print_property(folder, "Name");
print_property(folder, "NumberOfItems");
if (!g_dbus_proxy_get_property(proxy, "Playlist", &iter))
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
dbus_message_iter_get_basic(&iter, &path);
item = g_dbus_proxy_lookup(items, NULL, path,
BLUEZ_MEDIA_ITEM_INTERFACE);
if (item == NULL)
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
bt_shell_printf("Playlist %s\n", path);
print_property(item, "Name");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_select(int argc, char *argv[])
{
GDBusProxy *proxy;
proxy = g_dbus_proxy_lookup(players, NULL, argv[1],
BLUEZ_MEDIA_PLAYER_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Player %s not available\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (default_player == proxy)
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
default_player = proxy;
print_player(proxy, NULL);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void change_folder_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to change folder: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("ChangeFolder successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void change_folder_setup(DBusMessageIter *iter, void *user_data)
{
const char *path = user_data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_OBJECT_PATH, &path);
}
static void cmd_change_folder(int argc, char *argv[])
{
GDBusProxy *proxy;
if (dbus_validate_path(argv[1], NULL) == FALSE) {
bt_shell_printf("Not a valid path\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (check_default_player() == FALSE)
return bt_shell_noninteractive_quit(EXIT_FAILURE);
proxy = g_dbus_proxy_lookup(folders, NULL,
g_dbus_proxy_get_path(default_player),
BLUEZ_MEDIA_FOLDER_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (g_dbus_proxy_method_call(proxy, "ChangeFolder", change_folder_setup,
change_folder_reply, argv[1], NULL) == FALSE) {
bt_shell_printf("Failed to change current folder\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to change folder\n");
}
struct list_items_args {
int start;
int end;
};
static void list_items_setup(DBusMessageIter *iter, void *user_data)
{
struct list_items_args *args = user_data;
DBusMessageIter dict;
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY,
DBUS_DICT_ENTRY_BEGIN_CHAR_AS_STRING
DBUS_TYPE_STRING_AS_STRING
DBUS_TYPE_VARIANT_AS_STRING
DBUS_DICT_ENTRY_END_CHAR_AS_STRING,
&dict);
if (args->start < 0)
goto done;
g_dbus_dict_append_entry(&dict, "Start",
DBUS_TYPE_UINT32, &args->start);
if (args->end < 0)
goto done;
g_dbus_dict_append_entry(&dict, "End", DBUS_TYPE_UINT32, &args->end);
done:
dbus_message_iter_close_container(iter, &dict);
}
static void list_items_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to list items: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("ListItems successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_list_items(int argc, char *argv[])
{
GDBusProxy *proxy;
struct list_items_args *args;
if (check_default_player() == FALSE)
return bt_shell_noninteractive_quit(EXIT_FAILURE);
proxy = g_dbus_proxy_lookup(folders, NULL,
g_dbus_proxy_get_path(default_player),
BLUEZ_MEDIA_FOLDER_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
args = g_new0(struct list_items_args, 1);
args->start = -1;
args->end = -1;
if (argc < 2)
goto done;
errno = 0;
args->start = strtol(argv[1], NULL, 10);
if (errno != 0) {
bt_shell_printf("%s(%d)\n", strerror(errno), errno);
g_free(args);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (argc < 3)
goto done;
errno = 0;
args->end = strtol(argv[2], NULL, 10);
if (errno != 0) {
bt_shell_printf("%s(%d)\n", strerror(errno), errno);
g_free(args);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
done:
if (g_dbus_proxy_method_call(proxy, "ListItems", list_items_setup,
list_items_reply, args, g_free) == FALSE) {
bt_shell_printf("Failed to change current folder\n");
g_free(args);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to list items\n");
}
static void search_setup(DBusMessageIter *iter, void *user_data)
{
char *string = user_data;
DBusMessageIter dict;
dbus_message_iter_append_basic(iter, DBUS_TYPE_STRING, &string);
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY,
DBUS_DICT_ENTRY_BEGIN_CHAR_AS_STRING
DBUS_TYPE_STRING_AS_STRING
DBUS_TYPE_VARIANT_AS_STRING
DBUS_DICT_ENTRY_END_CHAR_AS_STRING,
&dict);
dbus_message_iter_close_container(iter, &dict);
}
static void search_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to search: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Search successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_search(int argc, char *argv[])
{
GDBusProxy *proxy;
char *string;
if (check_default_player() == FALSE)
return bt_shell_noninteractive_quit(EXIT_FAILURE);
proxy = g_dbus_proxy_lookup(folders, NULL,
g_dbus_proxy_get_path(default_player),
BLUEZ_MEDIA_FOLDER_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Operation not supported\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
string = g_strdup(argv[1]);
if (g_dbus_proxy_method_call(proxy, "Search", search_setup,
search_reply, string, g_free) == FALSE) {
bt_shell_printf("Failed to search\n");
g_free(string);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to search\n");
}
static void add_to_nowplaying_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to queue: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("AddToNowPlaying successful\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_queue(int argc, char *argv[])
{
GDBusProxy *proxy;
proxy = g_dbus_proxy_lookup(items, NULL, argv[1],
BLUEZ_MEDIA_ITEM_INTERFACE);
if (proxy == NULL) {
bt_shell_printf("Item %s not available\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (g_dbus_proxy_method_call(proxy, "AddtoNowPlaying", NULL,
add_to_nowplaying_reply, NULL,
NULL) == FALSE) {
bt_shell_printf("Failed to play\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Attempting to queue %s\n", argv[1]);
}
static const struct bt_shell_menu player_menu = {
.name = "player",
.desc = "Media Player Submenu",
.entries = {
{ "list", NULL, cmd_list, "List available players" },
{ "show", "[player]", cmd_show, "Player information",
player_generator},
{ "select", "<player>", cmd_select, "Select default player",
player_generator},
{ "play", "[item]", cmd_play, "Start playback",
item_generator},
{ "pause", NULL, cmd_pause, "Pause playback" },
{ "stop", NULL, cmd_stop, "Stop playback" },
{ "next", NULL, cmd_next, "Jump to next item" },
{ "previous", NULL, cmd_previous, "Jump to previous item" },
{ "fast-forward", NULL, cmd_fast_forward,
"Fast forward playback" },
{ "rewind", NULL, cmd_rewind, "Rewind playback" },
{ "equalizer", "<on/off>", cmd_equalizer,
"Enable/Disable equalizer"},
{ "repeat", "<singletrack/alltrack/group/off>", cmd_repeat,
"Set repeat mode"},
{ "shuffle", "<alltracks/group/off>", cmd_shuffle,
"Set shuffle mode"},
{ "scan", "<alltracks/group/off>", cmd_scan,
"Set scan mode"},
{ "change-folder", "<item>", cmd_change_folder,
"Change current folder",
item_generator},
{ "list-items", "[start] [end]", cmd_list_items,
"List items of current folder" },
{ "search", "<string>", cmd_search,
"Search items containing string" },
{ "queue", "<item>", cmd_queue, "Add item to playlist queue",
item_generator},
{ "show-item", "<item>", cmd_show_item, "Show item information",
item_generator},
{} },
};
static char *local_endpoint_generator(const char *text, int state)
{
int len = strlen(text);
GList *l;
static int index = 0;
if (!state)
index = 0;
for (l = g_list_nth(local_endpoints, index); l; l = g_list_next(l)) {
struct endpoint *ep = l->data;
index++;
if (!strncasecmp(ep->path, text, len))
return strdup(ep->path);
}
return NULL;
}
static char *endpoint_generator(const char *text, int state)
{
char *ret;
ret = generic_generator(text, state, endpoints);
if (ret)
return ret;
return local_endpoint_generator(text, state);
}
static void print_endpoint(void *data, void *user_data)
{
GDBusProxy *proxy = data;
const char *description = user_data;
char *str;
str = proxy_description(proxy, "Endpoint", description);
bt_shell_printf("%s\n", str);
g_free(str);
}
static void cmd_list_endpoints(int argc, char *argv[])
{
GList *l;
if (argc > 1) {
if (strcmp("local", argv[1])) {
bt_shell_printf("Endpoint list %s not available\n",
argv[1]);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
for (l = local_endpoints; l; l = g_list_next(l)) {
struct endpoint *ep = l->data;
bt_shell_printf("%s\n", ep->path);
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
for (l = endpoints; l; l = g_list_next(l)) {
GDBusProxy *proxy = l->data;
print_endpoint(proxy, NULL);
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void confirm_response(const char *input, void *user_data)
{
DBusMessage *msg = user_data;
if (!strcasecmp(input, "y") || !strcasecmp(input, "yes"))
g_dbus_send_reply(dbus_conn, msg, DBUS_TYPE_INVALID);
else if (!strcasecmp(input, "n") || !strcmp(input, "no"))
g_dbus_send_error(dbus_conn, msg, "org.bluez.Error.Rejected",
NULL);
else
g_dbus_send_error(dbus_conn, msg, "org.bluez.Error.Canceled",
NULL);
}
static DBusMessage *endpoint_set_configuration(DBusConnection *conn,
DBusMessage *msg, void *user_data)
{
struct endpoint *ep = user_data;
DBusMessageIter args, props;
const char *path;
dbus_message_iter_init(msg, &args);
dbus_message_iter_get_basic(&args, &path);
dbus_message_iter_next(&args);
dbus_message_iter_recurse(&args, &props);
if (dbus_message_iter_get_arg_type(&props) != DBUS_TYPE_DICT_ENTRY)
return g_dbus_create_error(msg,
"org.bluez.Error.InvalidArguments",
NULL);
bt_shell_printf("Endpoint: SetConfiguration\n");
bt_shell_printf("\tTransport %s\n", path);
print_iter("\t", "Properties", &props);
if (!ep->max_transports) {
bt_shell_printf("Maximum transports reached: rejecting\n");
return g_dbus_create_error(msg,
"org.bluez.Error.Rejected",
"Maximum transports reached");
}
ep->max_transports--;
if (!ep->transports)
ep->transports = queue_new();
queue_push_tail(ep->transports, strdup(path));
if (ep->auto_accept) {
bt_shell_printf("Auto Accepting...\n");
return g_dbus_create_reply(msg, DBUS_TYPE_INVALID);
}
bt_shell_prompt_input("Endpoint", "Accept (yes/no):", confirm_response,
dbus_message_ref(msg));
return NULL;
}
#define CODEC_CAPABILITIES(_name, _uuid, _codec_id, _data, _meta) \
{ \
.name = _name, \
.uuid = _uuid, \
.codec_id = _codec_id, \
.data = _data, \
.meta = _meta, \
}
#define LC3_DATA(_freq, _duration, _len_min, _len_max) \
UTIL_IOV_INIT(0x03, LC3_FREQ, _freq, _freq >> 8, \
0x02, LC3_DURATION, _duration, \
0x05, LC3_FRAME_LEN, _len_min, _len_min >> 8, \
_len_max, _len_max >> 8)
static const struct capabilities {
const char *name;
const char *uuid;
uint8_t codec_id;
struct iovec data;
struct iovec meta;
} caps[] = {
/* A2DP SBC Source:
*
* Channel Modes: Mono DualChannel Stereo JointStereo
* Frequencies: 16Khz 32Khz 44.1Khz 48Khz
* Subbands: 4 8
* Blocks: 4 8 12 16
* Bitpool Range: 2-64
*/
CODEC_CAPABILITIES("a2dp_src/sbc", A2DP_SOURCE_UUID, A2DP_CODEC_SBC,
UTIL_IOV_INIT(0xff, 0xff, 2, 64),
UTIL_IOV_INIT()),
/* A2DP SBC Sink:
*
* Channel Modes: Mono DualChannel Stereo JointStereo
* Frequencies: 16Khz 32Khz 44.1Khz 48Khz
* Subbands: 4 8
* Blocks: 4 8 12 16
* Bitpool Range: 2-64
*/
CODEC_CAPABILITIES("a2dp_snk/sbc", A2DP_SINK_UUID, A2DP_CODEC_SBC,
UTIL_IOV_INIT(0xff, 0xff, 2, 64),
UTIL_IOV_INIT()),
/* PAC LC3 Sink:
*
* Frequencies: 8Khz 11Khz 16Khz 22Khz 24Khz 32Khz 44.1Khz 48Khz
* Duration: 7.5 ms 10 ms
* Frame length: 26-240
*/
CODEC_CAPABILITIES("pac_snk/lc3", PAC_SINK_UUID, LC3_ID,
LC3_DATA(LC3_FREQ_ANY, LC3_DURATION_ANY, 26,
240),
UTIL_IOV_INIT()),
/* PAC LC3 Source:
*
* Frequencies: 8Khz 11Khz 16Khz 22Khz 24Khz 32Khz 44.1Khz 48Khz
* Duration: 7.5 ms 10 ms
* Channel count: 3
* Frame length: 26-240
*/
CODEC_CAPABILITIES("pac_src/lc3", PAC_SOURCE_UUID, LC3_ID,
LC3_DATA(LC3_FREQ_ANY, LC3_DURATION_ANY, 26,
240),
UTIL_IOV_INIT()),
/* Broadcast LC3 Source:
*
* Frequencies: 8Khz 11Khz 16Khz 22Khz 24Khz 32Khz 44.1Khz 48Khz
* Duration: 7.5 ms 10 ms
* Channel count: 3
* Frame length: 26-240
*/
CODEC_CAPABILITIES("bcaa/lc3", BCAA_SERVICE_UUID, LC3_ID,
LC3_DATA(LC3_FREQ_ANY, LC3_DURATION_ANY, 26,
240),
UTIL_IOV_INIT()),
/* Broadcast LC3 Sink:
*
* Frequencies: 8Khz 11Khz 16Khz 22Khz 24Khz 32Khz 44.1Khz 48Khz
* Duration: 7.5 ms 10 ms
* Channel count: 3
* Frame length: 26-240
*/
CODEC_CAPABILITIES("baa/lc3", BAA_SERVICE_UUID, LC3_ID,
LC3_DATA(LC3_FREQ_ANY, LC3_DURATION_ANY, 26,
240),
UTIL_IOV_INIT()),
};
struct codec_preset {
char *name;
const struct iovec data;
const struct iovec meta;
struct bt_bap_qos qos;
uint8_t target_latency;
uint32_t chan_alloc;
bool custom;
bool alt;
struct codec_preset *alt_preset;
};
#define SBC_PRESET(_name, _data) \
{ \
.name = _name, \
.data = _data, \
}
static struct codec_preset sbc_presets[] = {
/* Table 4.7: Recommended sets of SBC parameters in the SRC device
* Other settings: Block length = 16, Allocation method = Loudness,
* Subbands = 8.
* A2DP spec sets maximum bitrates as follows:
* This profile limits the available maximum bit rate to 320kb/s for
* mono, and 512kb/s for two-channel modes.
*/
SBC_PRESET("MQ_MONO_44_1",
UTIL_IOV_INIT(0x28, 0x15, 2, SBC_BITPOOL_MQ_MONO_44100)),
SBC_PRESET("MQ_MONO_48",
UTIL_IOV_INIT(0x18, 0x15, 2, SBC_BITPOOL_MQ_MONO_48000)),
SBC_PRESET("MQ_STEREO_44_1",
UTIL_IOV_INIT(0x21, 0x15, 2,
SBC_BITPOOL_MQ_JOINT_STEREO_44100)),
SBC_PRESET("MQ_STEREO_48",
UTIL_IOV_INIT(0x11, 0x15, 2,
SBC_BITPOOL_MQ_JOINT_STEREO_48000)),
SBC_PRESET("HQ_MONO_44_1",
UTIL_IOV_INIT(0x28, 0x15, 2, SBC_BITPOOL_HQ_MONO_44100)),
SBC_PRESET("HQ_MONO_48",
UTIL_IOV_INIT(0x18, 0x15, 2, SBC_BITPOOL_HQ_MONO_48000)),
SBC_PRESET("HQ_STEREO_44_1",
UTIL_IOV_INIT(0x21, 0x15, 2,
SBC_BITPOOL_HQ_JOINT_STEREO_44100)),
SBC_PRESET("HQ_STEREO_48",
UTIL_IOV_INIT(0x11, 0x15, 2,
SBC_BITPOOL_HQ_JOINT_STEREO_48000)),
/* Higher bitrates not recommended by A2DP spec, it dual channel to
* avoid going above 53 bitpool:
*
* https://habr.com/en/post/456476/
* https://gitlab.freedesktop.org/pulseaudio/pulseaudio/-/issues/1092
*/
SBC_PRESET("XQ_DUAL_44_1", UTIL_IOV_INIT(0x24, 0x15, 2, 43)),
SBC_PRESET("XQ_DUAL_48", UTIL_IOV_INIT(0x14, 0x15, 2, 39)),
/* Ultra high bitpool that fits in 512 kbps mandatory bitrate */
SBC_PRESET("UQ_STEREO_44_1", UTIL_IOV_INIT(0x21, 0x15, 2, 64)),
SBC_PRESET("UQ_STEREO_48", UTIL_IOV_INIT(0x11, 0x15, 2, 58)),
};
#define LC3_PRESET_LL(_name, _data, _qos) \
{ \
.name = _name, \
.data = _data, \
.qos = _qos, \
.target_latency = 0x01, \
}
#define LC3_PRESET(_name, _data, _qos) \
{ \
.name = _name, \
.data = _data, \
.qos = _qos, \
.target_latency = 0x02, \
}
#define LC3_PRESET_HR(_name, _data, _qos) \
{ \
.name = _name, \
.data = _data, \
.qos = _qos, \
.target_latency = 0x03, \
}
#define LC3_PRESET_B(_name, _data, _qos) \
{ \
.name = _name, \
.data = _data, \
.qos = _qos, \
.target_latency = 0x00, \
}
static struct codec_preset lc3_ucast_presets[] = {
/* Table 4.43: QoS configuration support setting requirements */
LC3_PRESET("8_1_1", LC3_CONFIG_8_1, LC3_QOS_8_1_1),
LC3_PRESET("8_2_1", LC3_CONFIG_8_2, LC3_QOS_8_2_1),
LC3_PRESET("16_1_1", LC3_CONFIG_16_1, LC3_QOS_16_1_1),
LC3_PRESET("16_2_1", LC3_CONFIG_16_2, LC3_QOS_16_2_1),
LC3_PRESET("24_1_1", LC3_CONFIG_24_1, LC3_QOS_24_1_1),
LC3_PRESET("24_2_1", LC3_CONFIG_24_2, LC3_QOS_24_2_1),
LC3_PRESET("32_1_1", LC3_CONFIG_32_1, LC3_QOS_32_1_1),
LC3_PRESET("32_2_1", LC3_CONFIG_32_2, LC3_QOS_32_1_1),
LC3_PRESET("44_1_1", LC3_CONFIG_44_1, LC3_QOS_44_1_1),
LC3_PRESET("44_2_1", LC3_CONFIG_44_2, LC3_QOS_44_2_1),
LC3_PRESET("48_1_1", LC3_CONFIG_48_1, LC3_QOS_48_1_1),
LC3_PRESET("48_2_1", LC3_CONFIG_48_2, LC3_QOS_48_2_1),
LC3_PRESET("48_3_1", LC3_CONFIG_48_3, LC3_QOS_48_3_1),
LC3_PRESET("48_4_1", LC3_CONFIG_48_4, LC3_QOS_48_4_1),
LC3_PRESET("48_5_1", LC3_CONFIG_48_5, LC3_QOS_48_5_1),
LC3_PRESET("48_6_1", LC3_CONFIG_48_6, LC3_QOS_48_6_1),
/* QoS Configuration settings for high reliability audio data */
LC3_PRESET_HR("8_1_2", LC3_CONFIG_8_1, LC3_QOS_8_1_2),
LC3_PRESET_HR("8_2_2", LC3_CONFIG_8_2, LC3_QOS_8_2_2),
LC3_PRESET_HR("16_1_2", LC3_CONFIG_16_1, LC3_QOS_16_1_2),
LC3_PRESET_HR("16_2_2", LC3_CONFIG_16_2, LC3_QOS_16_2_2),
LC3_PRESET_HR("24_1_2", LC3_CONFIG_24_1, LC3_QOS_24_1_2),
LC3_PRESET_HR("24_2_2", LC3_CONFIG_24_2, LC3_QOS_24_2_2),
LC3_PRESET_HR("32_1_2", LC3_CONFIG_32_1, LC3_QOS_32_1_2),
LC3_PRESET_HR("32_2_2", LC3_CONFIG_32_2, LC3_QOS_32_2_2),
LC3_PRESET_HR("44_1_2", LC3_CONFIG_44_1, LC3_QOS_44_1_2),
LC3_PRESET_HR("44_2_2", LC3_CONFIG_44_2, LC3_QOS_44_2_2),
LC3_PRESET_HR("48_1_2", LC3_CONFIG_48_1, LC3_QOS_48_1_2),
LC3_PRESET_HR("48_2_2", LC3_CONFIG_48_2, LC3_QOS_48_2_2),
LC3_PRESET_HR("48_3_2", LC3_CONFIG_48_3, LC3_QOS_48_3_2),
LC3_PRESET_HR("48_4_2", LC3_CONFIG_48_4, LC3_QOS_48_4_2),
LC3_PRESET_HR("48_5_2", LC3_CONFIG_48_5, LC3_QOS_48_5_2),
LC3_PRESET_HR("48_6_2", LC3_CONFIG_48_6, LC3_QOS_48_6_2),
/* QoS configuration support setting requirements for the UGG and UGT */
LC3_PRESET_LL("16_1_gs", LC3_CONFIG_16_1, LC3_QOS_16_1_GS),
LC3_PRESET_LL("16_2_gs", LC3_CONFIG_16_2, LC3_QOS_16_2_GS),
LC3_PRESET_LL("32_1_gs", LC3_CONFIG_32_1, LC3_QOS_32_1_GS),
LC3_PRESET_LL("32_2_gs", LC3_CONFIG_32_2, LC3_QOS_32_2_GS),
LC3_PRESET_LL("48_1_gs", LC3_CONFIG_48_1, LC3_QOS_48_1_GS),
LC3_PRESET_LL("48_2_gs", LC3_CONFIG_48_2, LC3_QOS_48_2_GS),
LC3_PRESET_LL("32_1_gr", LC3_CONFIG_32_1, LC3_QOS_32_1_GR),
LC3_PRESET_LL("32_2_gr", LC3_CONFIG_32_2, LC3_QOS_32_2_GR),
LC3_PRESET_LL("48_1_gr", LC3_CONFIG_48_1, LC3_QOS_48_1_GR),
LC3_PRESET_LL("48_2_gr", LC3_CONFIG_48_2, LC3_QOS_48_2_GR),
LC3_PRESET_LL("48_3_gr", LC3_CONFIG_48_3, LC3_QOS_48_3_GR),
LC3_PRESET_LL("48_4_gr", LC3_CONFIG_48_4, LC3_QOS_48_4_GR),
LC3_PRESET_LL("32_1_gr_l+r", LC3_CONFIG_32_1_AC(2),
LC3_QOS_32_1_GR_AC(2)),
LC3_PRESET_LL("32_2_gr_l+r", LC3_CONFIG_32_2_AC(2),
LC3_QOS_32_2_GR_AC(2)),
LC3_PRESET_LL("48_1_gr_l+r", LC3_CONFIG_48_1_AC(2),
LC3_QOS_48_1_GR_AC(2)),
LC3_PRESET_LL("48_2_gr_l+r", LC3_CONFIG_48_2_AC(2),
LC3_QOS_48_2_GR_AC(2)),
LC3_PRESET_LL("48_3_gr_l+r", LC3_CONFIG_48_3_AC(2),
LC3_QOS_48_3_GR_AC(2)),
LC3_PRESET_LL("48_4_gr_l+r", LC3_CONFIG_48_4_AC(2),
LC3_QOS_48_4_GR_AC(2)),
};
static struct codec_preset lc3_bcast_presets[] = {
/* Table 6.4: Broadcast Audio Stream configuration support requirements
* for the Broadcast Source and Broadcast Sink
*/
LC3_PRESET_B("8_1_1", LC3_CONFIG_8_1, LC3_QOS_8_1_1_B),
LC3_PRESET_B("8_2_1", LC3_CONFIG_8_2, LC3_QOS_8_2_1_B),
LC3_PRESET_B("16_1_1", LC3_CONFIG_16_1, LC3_QOS_16_1_1_B),
LC3_PRESET_B("16_2_1", LC3_CONFIG_16_2, LC3_QOS_16_2_1_B),
LC3_PRESET_B("24_1_1", LC3_CONFIG_24_1, LC3_QOS_24_1_1_B),
LC3_PRESET_B("24_2_1", LC3_CONFIG_24_2, LC3_QOS_24_2_1_B),
LC3_PRESET_B("32_1_1", LC3_CONFIG_32_1, LC3_QOS_32_1_1_B),
LC3_PRESET_B("32_2_1", LC3_CONFIG_32_2, LC3_QOS_32_2_1_B),
LC3_PRESET_B("44_1_1", LC3_CONFIG_44_1, LC3_QOS_44_1_1_B),
LC3_PRESET_B("44_2_1", LC3_CONFIG_44_2, LC3_QOS_44_2_1_B),
LC3_PRESET_B("48_1_1", LC3_CONFIG_48_1, LC3_QOS_48_1_1_B),
LC3_PRESET_B("48_2_1", LC3_CONFIG_48_2, LC3_QOS_48_2_1_B),
LC3_PRESET_B("48_3_1", LC3_CONFIG_48_3, LC3_QOS_48_3_1_B),
LC3_PRESET_B("48_4_1", LC3_CONFIG_48_4, LC3_QOS_48_4_1_B),
LC3_PRESET_B("48_5_1", LC3_CONFIG_48_5, LC3_QOS_48_5_1_B),
LC3_PRESET_B("48_6_1", LC3_CONFIG_48_6, LC3_QOS_48_6_1_B),
/* Broadcast Audio Stream configuration settings for high-reliability
* audio data.
*/
LC3_PRESET_B("8_1_2", LC3_CONFIG_8_1, LC3_QOS_8_1_1_B),
LC3_PRESET_B("8_2_2", LC3_CONFIG_8_2, LC3_QOS_8_2_2_B),
LC3_PRESET_B("16_1_2", LC3_CONFIG_16_1, LC3_QOS_16_1_2_B),
LC3_PRESET_B("16_2_2", LC3_CONFIG_16_2, LC3_QOS_16_2_2_B),
LC3_PRESET_B("24_1_2", LC3_CONFIG_24_1, LC3_QOS_24_1_2_B),
LC3_PRESET_B("24_2_2", LC3_CONFIG_24_2, LC3_QOS_24_2_2_B),
LC3_PRESET_B("32_1_2", LC3_CONFIG_32_1, LC3_QOS_32_1_2_B),
LC3_PRESET_B("32_2_2", LC3_CONFIG_32_2, LC3_QOS_32_2_2_B),
LC3_PRESET_B("44_1_2", LC3_CONFIG_44_1, LC3_QOS_44_1_2_B),
LC3_PRESET_B("44_2_2", LC3_CONFIG_44_2, LC3_QOS_44_2_2_B),
LC3_PRESET_B("48_1_2", LC3_CONFIG_48_1, LC3_QOS_48_1_2_B),
LC3_PRESET_B("48_2_2", LC3_CONFIG_48_2, LC3_QOS_48_2_2_B),
LC3_PRESET_B("48_3_2", LC3_CONFIG_48_3, LC3_QOS_48_3_2_B),
LC3_PRESET_B("48_4_2", LC3_CONFIG_48_4, LC3_QOS_48_4_2_B),
LC3_PRESET_B("48_5_2", LC3_CONFIG_48_5, LC3_QOS_48_5_2_B),
LC3_PRESET_B("48_6_2", LC3_CONFIG_48_6, LC3_QOS_48_6_2_B),
};
static void print_ltv(const char *str, void *user_data)
{
const char *label = user_data;
bt_shell_printf("\t%s.%s\n", label, str);
}
static void print_lc3_caps(uint8_t *data, int len)
{
const char *label = "Capabilities";
bt_bap_debug_caps(data, len, print_ltv, (void *)label);
}
static void print_lc3_cfg(void *data, int len)
{
const char *label = "Configuration";
bt_bap_debug_config(data, len, print_ltv, (void *)label);
}
static void print_lc3_meta(void *data, int len)
{
const char *label = "Metadata";
bt_bap_debug_metadata(data, len, print_ltv, (void *)label);
}
#define PRESET(_uuid, _codec, _presets, _default_index) \
{ \
.uuid = _uuid, \
.codec = _codec, \
.default_preset = &_presets[_default_index], \
.presets = _presets, \
.num_presets = ARRAY_SIZE(_presets), \
}
static struct preset {
const char *uuid;
uint8_t codec;
uint16_t cid;
uint16_t vid;
struct queue *custom;
struct codec_preset *default_preset;
struct codec_preset *presets;
size_t num_presets;
} presets[] = {
PRESET(A2DP_SOURCE_UUID, A2DP_CODEC_SBC, sbc_presets, 6),
PRESET(A2DP_SINK_UUID, A2DP_CODEC_SBC, sbc_presets, 6),
PRESET(PAC_SINK_UUID, LC3_ID, lc3_ucast_presets, 3),
PRESET(PAC_SOURCE_UUID, LC3_ID, lc3_ucast_presets, 3),
PRESET(BCAA_SERVICE_UUID, LC3_ID, lc3_bcast_presets, 3),
PRESET(BAA_SERVICE_UUID, LC3_ID, lc3_bcast_presets, 3),
};
static void parse_vendor_codec(const char *codec, uint16_t *vid, uint16_t *cid)
{
char **list;
char *endptr = NULL;
if (!codec)
return;
list = g_strsplit(codec, ":", 2);
if (vid)
*vid = strtol(list[0], &endptr, 0);
if (cid)
*cid = strtol(list[1], &endptr, 0);
g_strfreev(list);
}
static struct preset *find_presets(const char *uuid, uint8_t codec,
uint16_t vid, uint16_t cid)
{
size_t i;
if (codec == 0xff) {
GList *l;
for (l = local_endpoints; l; l = g_list_next(l)) {
struct endpoint *ep = l->data;
if (strcasecmp(ep->uuid, uuid) || ep->codec != codec)
continue;
if (ep->codec == 0xff && (ep->vid != vid ||
ep->cid != cid))
continue;
return ep->preset;
}
return NULL;
}
for (i = 0; i < ARRAY_SIZE(presets); i++) {
struct preset *preset = &presets[i];
if (preset->codec != codec)
continue;
if (!strcasecmp(preset->uuid, uuid))
return preset;
}
return NULL;
}
static struct preset *find_vendor_presets(const char *uuid, const char *codec)
{
uint16_t cid;
uint16_t vid;
if (!uuid || !codec)
return NULL;
parse_vendor_codec(codec, &vid, &cid);
return find_presets(uuid, 0xff, vid, cid);
}
static struct preset *find_presets_name(const char *uuid, const char *codec)
{
uint8_t id;
char *endptr = NULL;
if (!uuid || !codec)
return NULL;
if (strrchr(codec, ':'))
return find_vendor_presets(uuid, codec);
id = strtol(codec, &endptr, 0);
return find_presets(uuid, id, 0x0000, 0x0000);
}
static bool match_custom_name(const void *data, const void *match_data)
{
const struct codec_preset *preset = data;
const char *name = match_data;
return !strcmp(preset->name, name);
}
static struct codec_preset *preset_find_name(struct preset *preset,
const char *name)
{
size_t i;
if (!preset)
return NULL;
if (!name)
return preset->default_preset;
for (i = 0; i < preset->num_presets; i++) {
struct codec_preset *p;
p = &preset->presets[i];
if (!strcmp(p->name, name))
return p;
}
return queue_find(preset->custom, match_custom_name, name);
}
static DBusMessage *endpoint_select_config_reply(DBusMessage *msg,
uint8_t *data, size_t len)
{
DBusMessage *reply;
DBusMessageIter args, array;
reply = dbus_message_new_method_return(msg);
if (!reply)
return NULL;
dbus_message_iter_init_append(reply, &args);
dbus_message_iter_open_container(&args, DBUS_TYPE_ARRAY,
DBUS_TYPE_BYTE_AS_STRING,
&array);
dbus_message_iter_append_fixed_array(&array, DBUS_TYPE_BYTE, &data,
len);
dbus_message_iter_close_container(&args, &array);
return reply;
}
static uint8_t *str2bytearray(char *arg, size_t *val_len)
{
uint8_t value[UINT8_MAX];
char *entry;
unsigned int i;
for (i = 0; (entry = strsep(&arg, " \t")) != NULL; i++) {
long val;
char *endptr = NULL;
if (*entry == '\0')
continue;
if (i >= G_N_ELEMENTS(value)) {
bt_shell_printf("Too much data\n");
return NULL;
}
val = strtol(entry, &endptr, 0);
if (!endptr || *endptr != '\0' || val > UINT8_MAX) {
bt_shell_printf("Invalid value at index %d\n", i);
return NULL;
}
value[i] = val;
}
*val_len = i;
return util_memdup(value, i);
}
static void select_config_response(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
struct codec_preset *p;
DBusMessage *reply;
uint8_t *data;
size_t len;
p = preset_find_name(ep->preset, input);
if (p) {
data = p->data.iov_base;
len = p->data.iov_len;
goto done;
}
data = str2bytearray((void *) input, &len);
if (!data) {
g_dbus_send_error(dbus_conn, ep->msg,
"org.bluez.Error.Rejected", NULL);
ep->msg = NULL;
return;
}
done:
reply = endpoint_select_config_reply(ep->msg, data, len);
if (!reply)
return;
if (!p)
free(data);
g_dbus_send_message(dbus_conn, reply);
dbus_message_unref(ep->msg);
ep->msg = NULL;
}
static DBusMessage *endpoint_select_configuration(DBusConnection *conn,
DBusMessage *msg, void *user_data)
{
struct endpoint *ep = user_data;
struct codec_preset *p;
DBusMessageIter args;
DBusMessage *reply;
dbus_message_iter_init(msg, &args);
bt_shell_printf("Endpoint: SelectConfiguration\n");
print_iter("\t", "Capabilities", &args);
if (!ep->max_transports) {
bt_shell_printf("Maximum transports reached: rejecting\n");
return g_dbus_create_error(msg,
"org.bluez.Error.Rejected",
"Maximum transports reached");
}
if (!ep->auto_accept) {
ep->msg = dbus_message_ref(msg);
bt_shell_prompt_input("Endpoint", "Enter preset/configuration:",
select_config_response, ep);
return NULL;
}
p = preset_find_name(ep->preset, NULL);
if (!p) {
reply = g_dbus_create_error(msg, "org.bluez.Error.Rejected",
NULL);
return reply;
}
reply = endpoint_select_config_reply(msg, p->data.iov_base,
p->data.iov_len);
if (!reply) {
reply = g_dbus_create_error(msg, "org.bluez.Error.Rejected",
NULL);
return reply;
}
bt_shell_printf("Auto Accepting using %s...\n", p->name);
return reply;
}
struct endpoint_config {
GDBusProxy *proxy;
struct endpoint *ep;
struct iovec *caps; /* Codec Specific Configuration LTVs */
struct iovec *meta; /* Metadata LTVs*/
uint8_t target_latency;
struct bt_bap_qos qos; /* BAP QOS configuration parameters */
};
static void append_io_qos(DBusMessageIter *iter, struct bt_bap_io_qos *qos)
{
bt_shell_printf("Interval %u\n", qos->interval);
g_dbus_dict_append_entry(iter, "Interval", DBUS_TYPE_UINT32,
&qos->interval);
bt_shell_printf("PHY 0x%02x\n", qos->phy);
g_dbus_dict_append_entry(iter, "PHY", DBUS_TYPE_BYTE, &qos->phy);
bt_shell_printf("SDU %u\n", qos->sdu);
g_dbus_dict_append_entry(iter, "SDU", DBUS_TYPE_UINT16, &qos->sdu);
bt_shell_printf("Retransmissions %u\n", qos->rtn);
g_dbus_dict_append_entry(iter, "Retransmissions", DBUS_TYPE_BYTE,
&qos->rtn);
bt_shell_printf("Latency %u\n", qos->latency);
g_dbus_dict_append_entry(iter, "Latency", DBUS_TYPE_UINT16,
&qos->latency);
}
static void append_ucast_qos(DBusMessageIter *iter, struct endpoint_config *cfg)
{
struct bt_bap_ucast_qos *qos = &cfg->qos.ucast;
if (cfg->ep->iso_group != BT_ISO_QOS_GROUP_UNSET) {
bt_shell_printf("CIG 0x%2.2x\n", cfg->ep->iso_group);
g_dbus_dict_append_entry(iter, "CIG", DBUS_TYPE_BYTE,
&cfg->ep->iso_group);
}
if (cfg->ep->iso_stream != BT_ISO_QOS_STREAM_UNSET) {
bt_shell_printf("CIS 0x%2.2x\n", cfg->ep->iso_stream);
g_dbus_dict_append_entry(iter, "CIS", DBUS_TYPE_BYTE,
&cfg->ep->iso_stream);
}
bt_shell_printf("Framing 0x%02x\n", qos->framing);
g_dbus_dict_append_entry(iter, "Framing", DBUS_TYPE_BYTE,
&qos->framing);
bt_shell_printf("PresentationDelay %u\n", qos->delay);
g_dbus_dict_append_entry(iter, "PresentationDelay",
DBUS_TYPE_UINT32, &qos->delay);
if (cfg->target_latency) {
bt_shell_printf("TargetLatency 0x%02x\n", cfg->target_latency);
g_dbus_dict_append_entry(iter, "TargetLatency", DBUS_TYPE_BYTE,
&cfg->target_latency);
}
append_io_qos(iter, &qos->io_qos);
}
static void append_bcast_qos(DBusMessageIter *iter, struct endpoint_config *cfg)
{
struct bt_bap_bcast_qos *qos = &cfg->qos.bcast;
if (cfg->ep->iso_group != BT_ISO_QOS_BIG_UNSET) {
bt_shell_printf("BIG 0x%2.2x\n", cfg->ep->iso_group);
g_dbus_dict_append_entry(iter, "BIG", DBUS_TYPE_BYTE,
&cfg->ep->iso_group);
}
if (cfg->ep->iso_stream != BT_ISO_QOS_BIS_UNSET) {
bt_shell_printf("BIS 0x%2.2x\n", cfg->ep->iso_stream);
g_dbus_dict_append_entry(iter, "BIS", DBUS_TYPE_BYTE,
&cfg->ep->iso_stream);
}
if (qos->sync_factor) {
bt_shell_printf("SyncFactor %u\n", qos->sync_factor);
g_dbus_dict_append_entry(iter, "SyncFactor", DBUS_TYPE_BYTE,
&qos->sync_factor);
}
if (qos->options) {
bt_shell_printf("Options %u\n", qos->options);
g_dbus_dict_append_entry(iter, "Options", DBUS_TYPE_BYTE,
&qos->options);
}
if (qos->skip) {
bt_shell_printf("Skip %u\n", qos->skip);
g_dbus_dict_append_entry(iter, "Skip", DBUS_TYPE_UINT16,
&qos->skip);
}
if (qos->sync_timeout) {
bt_shell_printf("SyncTimeout %u\n", qos->sync_timeout);
g_dbus_dict_append_entry(iter, "SyncTimeout", DBUS_TYPE_UINT16,
&qos->sync_timeout);
}
if (qos->sync_cte_type) {
bt_shell_printf("SyncCteType %u\n", qos->sync_cte_type);
g_dbus_dict_append_entry(iter, "SyncCteType", DBUS_TYPE_BYTE,
&qos->sync_cte_type);
}
if (qos->mse) {
bt_shell_printf("MSE %u\n", qos->mse);
g_dbus_dict_append_entry(iter, "MSE", DBUS_TYPE_BYTE,
&qos->mse);
}
if (qos->timeout) {
bt_shell_printf("Timeout %u\n", qos->timeout);
g_dbus_dict_append_entry(iter, "Timeout", DBUS_TYPE_UINT16,
&qos->timeout);
}
if (cfg->ep->bcode->iov_len != 0) {
const char *key = "BCode";
bt_shell_printf("BCode:\n");
bt_shell_hexdump(cfg->ep->bcode->iov_base,
cfg->ep->bcode->iov_len);
g_dbus_dict_append_basic_array(iter, DBUS_TYPE_STRING,
&key, DBUS_TYPE_BYTE,
&cfg->ep->bcode->iov_base,
cfg->ep->bcode->iov_len);
}
bt_shell_printf("Framing 0x%02x\n", qos->framing);
g_dbus_dict_append_entry(iter, "Framing", DBUS_TYPE_BYTE,
&qos->framing);
bt_shell_printf("PresentationDelay %u\n", qos->delay);
g_dbus_dict_append_entry(iter, "PresentationDelay",
DBUS_TYPE_UINT32, &qos->delay);
/* Add BAP codec QOS configuration */
append_io_qos(iter, &qos->io_qos);
}
static void append_qos(DBusMessageIter *iter, struct endpoint_config *cfg)
{
DBusMessageIter entry, var, dict;
const char *key = "QoS";
dbus_message_iter_open_container(iter, DBUS_TYPE_DICT_ENTRY,
NULL, &entry);
dbus_message_iter_append_basic(&entry, DBUS_TYPE_STRING, &key);
dbus_message_iter_open_container(&entry, DBUS_TYPE_VARIANT,
"a{sv}", &var);
dbus_message_iter_open_container(&var, DBUS_TYPE_ARRAY, "{sv}",
&dict);
if (cfg->ep->broadcast)
append_bcast_qos(&dict, cfg);
else
append_ucast_qos(&dict, cfg);
dbus_message_iter_close_container(&var, &dict);
dbus_message_iter_close_container(&entry, &var);
dbus_message_iter_close_container(iter, &entry);
}
static void append_properties(DBusMessageIter *iter,
struct endpoint_config *cfg)
{
DBusMessageIter dict;
const char *key = "Capabilities";
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY, "{sv}", &dict);
if (cfg->ep->codec == LC3_ID) {
print_lc3_cfg(cfg->caps->iov_base, cfg->caps->iov_len);
} else {
bt_shell_printf("Capabilities: ");
bt_shell_hexdump(cfg->caps->iov_base, cfg->caps->iov_len);
}
g_dbus_dict_append_basic_array(&dict, DBUS_TYPE_STRING, &key,
DBUS_TYPE_BYTE, &cfg->caps->iov_base,
cfg->caps->iov_len);
if (cfg->meta && cfg->meta->iov_len) {
const char *meta = "Metadata";
g_dbus_dict_append_basic_array(&dict, DBUS_TYPE_STRING, &meta,
DBUS_TYPE_BYTE, &cfg->meta->iov_base,
cfg->meta->iov_len);
if (cfg->ep->codec == LC3_ID) {
print_lc3_meta(cfg->meta->iov_base, cfg->meta->iov_len);
} else {
bt_shell_printf("Metadata:\n");
bt_shell_hexdump(cfg->meta->iov_base,
cfg->meta->iov_len);
}
}
append_qos(&dict, cfg);
dbus_message_iter_close_container(iter, &dict);
}
static int parse_chan_alloc(DBusMessageIter *iter, uint32_t *location,
uint8_t *channels)
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
{
while (dbus_message_iter_get_arg_type(iter) == DBUS_TYPE_DICT_ENTRY) {
const char *key;
DBusMessageIter value, entry;
int var;
dbus_message_iter_recurse(iter, &entry);
dbus_message_iter_get_basic(&entry, &key);
dbus_message_iter_next(&entry);
dbus_message_iter_recurse(&entry, &value);
var = dbus_message_iter_get_arg_type(&value);
if (!strcasecmp(key, "ChannelAllocation")) {
if (var != DBUS_TYPE_UINT32)
return -EINVAL;
dbus_message_iter_get_basic(&value, location);
if (*channels)
*channels = __builtin_popcount(*location);
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
return 0;
} else if (!strcasecmp(key, "Locations")) {
uint32_t tmp;
if (var != DBUS_TYPE_UINT32)
return -EINVAL;
dbus_message_iter_get_basic(&value, &tmp);
*location &= tmp;
if (*channels)
*channels = __builtin_popcount(*location);
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
}
dbus_message_iter_next(iter);
}
return *location ? 0 : -EINVAL;
}
static void ltv_find(size_t i, uint8_t l, uint8_t t, uint8_t *v,
void *user_data)
{
bool *found = user_data;
*found = true;
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
}
static DBusMessage *endpoint_select_properties_reply(struct endpoint *ep,
DBusMessage *msg,
struct codec_preset *preset)
{
DBusMessage *reply;
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
DBusMessageIter iter, props;
struct endpoint_config *cfg;
struct bt_bap_io_qos *qos;
uint32_t location = ep->locations;
uint8_t channels = 1;
if (!preset)
return NULL;
reply = dbus_message_new_method_return(msg);
if (!reply)
return NULL;
cfg = new0(struct endpoint_config, 1);
cfg->ep = ep;
/* Copy capabilities */
cfg->caps = util_iov_dup(&preset->data, 1);
cfg->target_latency = preset->target_latency;
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
dbus_message_iter_init(msg, &iter);
dbus_message_iter_recurse(&iter, &props);
if (!parse_chan_alloc(&props, &location, &channels)) {
uint32_t chan_alloc = 0;
uint8_t type = LC3_CONFIG_CHAN_ALLOC;
bool found = false;
if (preset->chan_alloc & location)
chan_alloc = preset->chan_alloc & location;
else if (preset->alt_preset &&
preset->alt_preset->chan_alloc &
location) {
chan_alloc = preset->alt_preset->chan_alloc & location;
preset = preset->alt_preset;
/* Copy alternate capabilities */
util_iov_free(cfg->caps, 1);
cfg->caps = util_iov_dup(&preset->data, 1);
cfg->target_latency = preset->target_latency;
} else
chan_alloc = location;
/* Check if Channel Allocation is present in caps */
util_ltv_foreach(cfg->caps->iov_base, cfg->caps->iov_len,
&type, ltv_find, &found);
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
/* If Channel Allocation has not been set directly via
* preset->data then attempt to set it if chan_alloc has been
* set.
*/
if (!found && chan_alloc) {
uint8_t chan_alloc_ltv[] = {
0x05, LC3_CONFIG_CHAN_ALLOC, chan_alloc & 0xff,
chan_alloc >> 8, chan_alloc >> 16,
chan_alloc >> 24
};
put_le32(chan_alloc, &chan_alloc_ltv[2]);
util_iov_append(cfg->caps, &chan_alloc_ltv,
sizeof(chan_alloc_ltv));
}
client/player: Use ChannelAllocation given on SelectProperties This makes use of ChannelAllocation when present on SelectProperties dictionary which is then passed on to bluetoothd and send over as part of Codec Configuration: < ACL Data TX: Handle 2048 flags 0x00 dlen 109 ATT: Write Command (0x52) len 104 Handle: 0x0098 Type: ASE Control Point (0x2bc6) Data: 0104050202060000000010020103020201030428000503010000000 6020206000000001002010302020103042800050302000000010202060000 0000100201030202010304280005030100000002020206000000001002010 302020103042800050302000000 Opcode: Codec Configuration (0x01) Number of ASE(s): 4 ASE: #0 ASE ID: 0x05 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #1 ASE ID: 0x06 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002) ASE: #2 ASE ID: 0x01 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000001 Front Left (0x00000001) ASE: #3 ASE ID: 0x02 Target Latency: Balance Latency/Reliability (0x02) PHY: 0x02 LE 2M PHY (0x02) Codec: LC3 (0x06) Codec Specific Configuration: #0: len 0x02 type 0x01 Sampling Frequency: 16 Khz (0x03) Codec Specific Configuration: #1: len 0x02 type 0x02 Frame Duration: 10 ms (0x01) Codec Specific Configuration: #2: len 0x03 type 0x04 Frame Length: 40 (0x0028) Codec Specific Configuration: #3: len 0x05 type 0x03 Location: 0x00000002 Front Right (0x00000002)
2023-12-08 23:45:21 +08:00
}
/* Copy metadata */
if (preset->meta.iov_len)
cfg->meta = util_iov_dup(&preset->meta, 1);
else
cfg->meta = util_iov_dup(ep->meta, 1);
if (ep->broadcast)
qos = &preset->qos.bcast.io_qos;
else
qos = &preset->qos.ucast.io_qos;
if (qos->phy) {
/* Set QoS parameters */
cfg->qos = preset->qos;
/* Adjust the SDU size based on the number of
* locations/channels that is being requested.
*/
if (channels > 1)
qos->sdu *= channels;
}
dbus_message_iter_init_append(reply, &iter);
bt_shell_printf("selecting %s...\n", preset->name);
append_properties(&iter, cfg);
free(cfg);
return reply;
}
static struct codec_preset *endpoint_find_codec_preset(struct endpoint *ep,
const char *name)
{
if (ep->codec_preset &&
(!name || !strcmp(ep->codec_preset->name, name)))
return ep->codec_preset;
return preset_find_name(ep->preset, name);
}
static void select_properties_response(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
struct codec_preset *p;
DBusMessage *reply;
p = endpoint_find_codec_preset(ep, input);
if (p) {
reply = endpoint_select_properties_reply(ep, ep->msg, p);
goto done;
}
bt_shell_printf("Preset %s not found\n", input);
reply = g_dbus_create_error(ep->msg, "org.bluez.Error.Rejected", NULL);
done:
g_dbus_send_message(dbus_conn, reply);
dbus_message_unref(ep->msg);
ep->msg = NULL;
}
static DBusMessage *endpoint_select_properties(DBusConnection *conn,
DBusMessage *msg, void *user_data)
{
struct endpoint *ep = user_data;
struct codec_preset *p;
DBusMessageIter args;
DBusMessage *reply;
dbus_message_iter_init(msg, &args);
bt_shell_printf("Endpoint: SelectProperties\n");
print_iter("\t", "Properties", &args);
if (!ep->max_transports) {
bt_shell_printf("Maximum transports reached: rejecting\n");
return g_dbus_create_error(msg,
"org.bluez.Error.Rejected",
"Maximum transports reached");
}
if (!ep->auto_accept) {
ep->msg = dbus_message_ref(msg);
bt_shell_prompt_input("Endpoint", "Enter preset/configuration:",
select_properties_response, ep);
return NULL;
}
p = endpoint_find_codec_preset(ep, NULL);
if (!p)
return NULL;
reply = endpoint_select_properties_reply(ep, msg, p);
if (!reply)
return NULL;
return reply;
}
static bool match_str(const void *data, const void *user_data)
{
return !strcmp(data, user_data);
}
static DBusMessage *endpoint_clear_configuration(DBusConnection *conn,
DBusMessage *msg, void *user_data)
{
struct endpoint *ep = user_data;
DBusMessageIter args;
const char *path;
dbus_message_iter_init(msg, &args);
dbus_message_iter_get_basic(&args, &path);
if (ep->max_transports != UINT8_MAX)
ep->max_transports++;
queue_remove_if(ep->transports, match_str, (void *)path);
return g_dbus_create_reply(msg, DBUS_TYPE_INVALID);
}
static struct endpoint *endpoint_find(const char *pattern)
{
GList *l;
for (l = local_endpoints; l; l = g_list_next(l)) {
struct endpoint *ep = l->data;
/* match object path */
if (!strcmp(ep->path, pattern))
return ep;
/* match UUID */
if (!strcmp(ep->uuid, pattern))
return ep;
}
return NULL;
}
static void print_aptx_common(a2dp_aptx_t *aptx)
{
bt_shell_printf("\n\t\tFrequencies: ");
if (aptx->frequency & APTX_SAMPLING_FREQ_16000)
bt_shell_printf("16kHz ");
if (aptx->frequency & APTX_SAMPLING_FREQ_32000)
bt_shell_printf("32kHz ");
if (aptx->frequency & APTX_SAMPLING_FREQ_44100)
bt_shell_printf("44.1kHz ");
if (aptx->frequency & APTX_SAMPLING_FREQ_48000)
bt_shell_printf("48kHz ");
bt_shell_printf("\n\t\tChannel modes: ");
if (aptx->channel_mode & APTX_CHANNEL_MODE_MONO)
bt_shell_printf("Mono ");
if (aptx->channel_mode & APTX_CHANNEL_MODE_STEREO)
bt_shell_printf("Stereo ");
}
static void print_aptx(a2dp_aptx_t *aptx, uint8_t size)
{
bt_shell_printf("\t\tVendor Specific Value (aptX)");
if (size < sizeof(*aptx)) {
bt_shell_printf(" (broken)\n");
return;
}
print_aptx_common(aptx);
bt_shell_printf("\n");
}
static void print_faststream(a2dp_faststream_t *faststream, uint8_t size)
{
bt_shell_printf("\t\tVendor Specific Value (FastStream)");
if (size < sizeof(*faststream)) {
bt_shell_printf(" (broken)\n");
return;
}
bt_shell_printf("\n\t\tDirections: ");
if (faststream->direction & FASTSTREAM_DIRECTION_SINK)
bt_shell_printf("sink ");
if (faststream->direction & FASTSTREAM_DIRECTION_SOURCE)
bt_shell_printf("source ");
if (faststream->direction & FASTSTREAM_DIRECTION_SINK) {
bt_shell_printf("\n\t\tSink Frequencies: ");
if (faststream->sink_frequency &
FASTSTREAM_SINK_SAMPLING_FREQ_44100)
bt_shell_printf("44.1kHz ");
if (faststream->sink_frequency &
FASTSTREAM_SINK_SAMPLING_FREQ_48000)
bt_shell_printf("48kHz ");
}
if (faststream->direction & FASTSTREAM_DIRECTION_SOURCE) {
bt_shell_printf("\n\t\tSource Frequencies: ");
if (faststream->source_frequency &
FASTSTREAM_SOURCE_SAMPLING_FREQ_16000)
bt_shell_printf("16kHz ");
}
bt_shell_printf("\n");
}
static void print_aptx_ll(a2dp_aptx_ll_t *aptx_ll, uint8_t size)
{
a2dp_aptx_ll_new_caps_t *aptx_ll_new;
bt_shell_printf("\t\tVendor Specific Value (aptX Low Latency)");
if (size < sizeof(*aptx_ll)) {
bt_shell_printf(" (broken)\n");
return;
}
print_aptx_common(&aptx_ll->aptx);
bt_shell_printf("\n\tBidirectional link: %s",
aptx_ll->bidirect_link ? "Yes" : "No");
aptx_ll_new = &aptx_ll->new_caps[0];
if (aptx_ll->has_new_caps &&
size >= sizeof(*aptx_ll) + sizeof(*aptx_ll_new)) {
bt_shell_printf("\n\tTarget codec buffer level: %u",
(unsigned int)aptx_ll_new->target_level2 |
((unsigned int)(aptx_ll_new->target_level1) << 8));
bt_shell_printf("\n\tInitial codec buffer level: %u",
(unsigned int)aptx_ll_new->initial_level2 |
((unsigned int)(aptx_ll_new->initial_level1) << 8));
bt_shell_printf("\n\tSRA max rate: %g",
aptx_ll_new->sra_max_rate / 10000.0);
bt_shell_printf("\n\tSRA averaging time: %us",
(unsigned int)aptx_ll_new->sra_avg_time);
bt_shell_printf("\n\tGood working codec buffer level: %u",
(unsigned int)aptx_ll_new->good_working_level2 |
((unsigned int)(aptx_ll_new->good_working_level1) << 8)
);
}
bt_shell_printf("\n");
}
static void print_aptx_hd(a2dp_aptx_hd_t *aptx_hd, uint8_t size)
{
bt_shell_printf("\t\tVendor Specific Value (aptX HD)");
if (size < sizeof(*aptx_hd)) {
bt_shell_printf(" (broken)\n");
return;
}
print_aptx_common(&aptx_hd->aptx);
bt_shell_printf("\n");
}
static void print_ldac(a2dp_ldac_t *ldac, uint8_t size)
{
bt_shell_printf("\t\tVendor Specific Value (LDAC)");
if (size < sizeof(*ldac)) {
bt_shell_printf(" (broken)\n");
return;
}
bt_shell_printf("\n\t\tFrequencies: ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_44100)
bt_shell_printf("44.1kHz ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_48000)
bt_shell_printf("48kHz ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_88200)
bt_shell_printf("88.2kHz ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_96000)
bt_shell_printf("96kHz ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_176400)
bt_shell_printf("176.4kHz ");
if (ldac->frequency & LDAC_SAMPLING_FREQ_192000)
bt_shell_printf("192kHz ");
bt_shell_printf("\n\t\tChannel modes: ");
if (ldac->channel_mode & LDAC_CHANNEL_MODE_MONO)
bt_shell_printf("Mono ");
if (ldac->channel_mode & LDAC_CHANNEL_MODE_DUAL)
bt_shell_printf("Dual ");
if (ldac->channel_mode & LDAC_CHANNEL_MODE_STEREO)
bt_shell_printf("Stereo ");
bt_shell_printf("\n");
}
static void print_opus_g(a2dp_opus_g_t *opus, uint8_t size)
{
bt_shell_printf("\t\tVendor Specific Value (Opus [Google])");
if (size < sizeof(*opus)) {
bt_shell_printf(" (broken)\n");
return;
}
bt_shell_printf("\n\t\tFrequencies: ");
if (opus->data & OPUS_G_FREQUENCY_48000)
bt_shell_printf("48kHz ");
bt_shell_printf("\n\t\tChannel modes: ");
if (opus->data & OPUS_G_CHANNELS_MONO)
bt_shell_printf("Mono ");
if (opus->data & OPUS_G_CHANNELS_STEREO)
bt_shell_printf("Stereo ");
if (opus->data & OPUS_G_CHANNELS_DUAL)
bt_shell_printf("Dual Mono ");
bt_shell_printf("\n\t\tFrame durations: ");
if (opus->data & OPUS_G_DURATION_100)
bt_shell_printf("10 ms ");
if (opus->data & OPUS_G_DURATION_200)
bt_shell_printf("20 ms ");
bt_shell_printf("\n");
}
static void print_vendor(a2dp_vendor_codec_t *vendor, uint8_t size)
{
uint32_t vendor_id;
uint16_t codec_id;
int i;
if (size < sizeof(*vendor)) {
bt_shell_printf("\tMedia Codec: Vendor Specific A2DP Codec "
"(broken)");
return;
}
vendor_id = A2DP_GET_VENDOR_ID(*vendor);
codec_id = A2DP_GET_CODEC_ID(*vendor);
bt_shell_printf("\tMedia Codec: Vendor Specific A2DP Codec");
bt_shell_printf("\n\tVendor ID 0x%08x", vendor_id);
bt_shell_printf("\n\tVendor Specific Codec ID 0x%04x", codec_id);
bt_shell_printf("\n\tVendor Specific Data:");
for (i = 6; i < size; ++i)
bt_shell_printf(" 0x%.02x", ((unsigned char *)vendor)[i]);
bt_shell_printf("\n");
if (vendor_id == APTX_VENDOR_ID && codec_id == APTX_CODEC_ID)
print_aptx((void *) vendor, size);
else if (vendor_id == FASTSTREAM_VENDOR_ID &&
codec_id == FASTSTREAM_CODEC_ID)
print_faststream((void *) vendor, size);
else if (vendor_id == APTX_LL_VENDOR_ID && codec_id == APTX_LL_CODEC_ID)
print_aptx_ll((void *) vendor, size);
else if (vendor_id == APTX_HD_VENDOR_ID && codec_id == APTX_HD_CODEC_ID)
print_aptx_hd((void *) vendor, size);
else if (vendor_id == LDAC_VENDOR_ID && codec_id == LDAC_CODEC_ID)
print_ldac((void *) vendor, size);
else if (vendor_id == OPUS_G_VENDOR_ID && codec_id == OPUS_G_CODEC_ID)
print_opus_g((void *) vendor, size);
}
static void print_mpeg24(a2dp_aac_t *aac, uint8_t size)
{
unsigned int freq, bitrate;
if (size < sizeof(*aac)) {
bt_shell_printf("\tMedia Codec: MPEG24 (broken)\n");
return;
}
freq = AAC_GET_FREQUENCY(*aac);
bitrate = AAC_GET_BITRATE(*aac);
bt_shell_printf("\tMedia Codec: MPEG24\n\tObject Types: ");
if (aac->object_type & AAC_OBJECT_TYPE_MPEG2_AAC_LC)
bt_shell_printf("MPEG-2 AAC LC ");
if (aac->object_type & AAC_OBJECT_TYPE_MPEG4_AAC_LC)
bt_shell_printf("MPEG-4 AAC LC ");
if (aac->object_type & AAC_OBJECT_TYPE_MPEG4_AAC_LTP)
bt_shell_printf("MPEG-4 AAC LTP ");
if (aac->object_type & AAC_OBJECT_TYPE_MPEG4_AAC_SCA)
bt_shell_printf("MPEG-4 AAC scalable ");
bt_shell_printf("\n\tFrequencies: ");
if (freq & AAC_SAMPLING_FREQ_8000)
bt_shell_printf("8kHz ");
if (freq & AAC_SAMPLING_FREQ_11025)
bt_shell_printf("11.025kHz ");
if (freq & AAC_SAMPLING_FREQ_12000)
bt_shell_printf("12kHz ");
if (freq & AAC_SAMPLING_FREQ_16000)
bt_shell_printf("16kHz ");
if (freq & AAC_SAMPLING_FREQ_22050)
bt_shell_printf("22.05kHz ");
if (freq & AAC_SAMPLING_FREQ_24000)
bt_shell_printf("24kHz ");
if (freq & AAC_SAMPLING_FREQ_32000)
bt_shell_printf("32kHz ");
if (freq & AAC_SAMPLING_FREQ_44100)
bt_shell_printf("44.1kHz ");
if (freq & AAC_SAMPLING_FREQ_48000)
bt_shell_printf("48kHz ");
if (freq & AAC_SAMPLING_FREQ_64000)
bt_shell_printf("64kHz ");
if (freq & AAC_SAMPLING_FREQ_88200)
bt_shell_printf("88.2kHz ");
if (freq & AAC_SAMPLING_FREQ_96000)
bt_shell_printf("96kHz ");
bt_shell_printf("\n\tChannels: ");
if (aac->channels & AAC_CHANNELS_1)
bt_shell_printf("1 ");
if (aac->channels & AAC_CHANNELS_2)
bt_shell_printf("2 ");
bt_shell_printf("\n\tBitrate: %u", bitrate);
bt_shell_printf("\n\tVBR: %s", aac->vbr ? "Yes\n" : "No\n");
}
static void print_mpeg12(a2dp_mpeg_t *mpeg, uint8_t size)
{
uint16_t bitrate;
if (size < sizeof(*mpeg)) {
bt_shell_printf("\tMedia Codec: MPEG12 (broken)\n");
return;
}
bitrate = MPEG_GET_BITRATE(*mpeg);
bt_shell_printf("\tMedia Codec: MPEG12\n\tChannel Modes: ");
if (mpeg->channel_mode & MPEG_CHANNEL_MODE_MONO)
bt_shell_printf("Mono ");
if (mpeg->channel_mode & MPEG_CHANNEL_MODE_DUAL_CHANNEL)
bt_shell_printf("DualChannel ");
if (mpeg->channel_mode & MPEG_CHANNEL_MODE_STEREO)
bt_shell_printf("Stereo ");
if (mpeg->channel_mode & MPEG_CHANNEL_MODE_JOINT_STEREO)
bt_shell_printf("JointStereo");
bt_shell_printf("\n\tFrequencies: ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_16000)
bt_shell_printf("16Khz ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_22050)
bt_shell_printf("22.05Khz ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_24000)
bt_shell_printf("24Khz ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_32000)
bt_shell_printf("32Khz ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_44100)
bt_shell_printf("44.1Khz ");
if (mpeg->frequency & MPEG_SAMPLING_FREQ_48000)
bt_shell_printf("48Khz ");
bt_shell_printf("\n\tCRC: %s", mpeg->crc ? "Yes" : "No");
bt_shell_printf("\n\tLayer: ");
if (mpeg->layer & MPEG_LAYER_MP1)
bt_shell_printf("1 ");
if (mpeg->layer & MPEG_LAYER_MP2)
bt_shell_printf("2 ");
if (mpeg->layer & MPEG_LAYER_MP3)
bt_shell_printf("3 ");
if (bitrate & MPEG_BIT_RATE_FREE) {
bt_shell_printf("\n\tBit Rate: Free format");
} else {
if (mpeg->layer & MPEG_LAYER_MP1) {
bt_shell_printf("\n\tLayer 1 Bit Rate: ");
if (bitrate & MPEG_MP1_BIT_RATE_32000)
bt_shell_printf("32kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_64000)
bt_shell_printf("64kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_96000)
bt_shell_printf("96kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_128000)
bt_shell_printf("128kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_160000)
bt_shell_printf("160kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_192000)
bt_shell_printf("192kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_224000)
bt_shell_printf("224kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_256000)
bt_shell_printf("256kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_320000)
bt_shell_printf("320kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_352000)
bt_shell_printf("352kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_384000)
bt_shell_printf("384kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_416000)
bt_shell_printf("416kbps ");
if (bitrate & MPEG_MP1_BIT_RATE_448000)
bt_shell_printf("448kbps ");
}
if (mpeg->layer & MPEG_LAYER_MP2) {
bt_shell_printf("\n\tLayer 2 Bit Rate: ");
if (bitrate & MPEG_MP2_BIT_RATE_32000)
bt_shell_printf("32kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_48000)
bt_shell_printf("48kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_56000)
bt_shell_printf("56kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_64000)
bt_shell_printf("64kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_80000)
bt_shell_printf("80kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_96000)
bt_shell_printf("96kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_112000)
bt_shell_printf("112kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_128000)
bt_shell_printf("128kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_160000)
bt_shell_printf("160kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_192000)
bt_shell_printf("192kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_224000)
bt_shell_printf("224kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_256000)
bt_shell_printf("256kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_320000)
bt_shell_printf("320kbps ");
if (bitrate & MPEG_MP2_BIT_RATE_384000)
bt_shell_printf("384kbps ");
}
if (mpeg->layer & MPEG_LAYER_MP3) {
bt_shell_printf("\n\tLayer 3 Bit Rate: ");
if (bitrate & MPEG_MP3_BIT_RATE_32000)
bt_shell_printf("32kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_40000)
bt_shell_printf("40kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_48000)
bt_shell_printf("48kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_56000)
bt_shell_printf("56kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_64000)
bt_shell_printf("64kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_80000)
bt_shell_printf("80kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_96000)
bt_shell_printf("96kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_112000)
bt_shell_printf("112kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_128000)
bt_shell_printf("128kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_160000)
bt_shell_printf("160kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_192000)
bt_shell_printf("192kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_224000)
bt_shell_printf("224kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_256000)
bt_shell_printf("256kbps ");
if (bitrate & MPEG_MP3_BIT_RATE_320000)
bt_shell_printf("320kbps ");
}
}
bt_shell_printf("\n\tVBR: %s", mpeg->vbr ? "Yes" : "No");
bt_shell_printf("\n\tPayload Format: ");
if (mpeg->mpf)
bt_shell_printf("RFC-2250 RFC-3119\n");
else
bt_shell_printf("RFC-2250\n");
}
static void print_sbc(a2dp_sbc_t *sbc, uint8_t size)
{
if (size < sizeof(*sbc)) {
bt_shell_printf("\tMedia Codec: SBC (broken)\n");
return;
}
bt_shell_printf("\tMedia Codec: SBC\n\tChannel Modes: ");
if (sbc->channel_mode & SBC_CHANNEL_MODE_MONO)
bt_shell_printf("Mono ");
if (sbc->channel_mode & SBC_CHANNEL_MODE_DUAL_CHANNEL)
bt_shell_printf("DualChannel ");
if (sbc->channel_mode & SBC_CHANNEL_MODE_STEREO)
bt_shell_printf("Stereo ");
if (sbc->channel_mode & SBC_CHANNEL_MODE_JOINT_STEREO)
bt_shell_printf("JointStereo");
bt_shell_printf("\n\tFrequencies: ");
if (sbc->frequency & SBC_SAMPLING_FREQ_16000)
bt_shell_printf("16Khz ");
if (sbc->frequency & SBC_SAMPLING_FREQ_32000)
bt_shell_printf("32Khz ");
if (sbc->frequency & SBC_SAMPLING_FREQ_44100)
bt_shell_printf("44.1Khz ");
if (sbc->frequency & SBC_SAMPLING_FREQ_48000)
bt_shell_printf("48Khz ");
bt_shell_printf("\n\tSubbands: ");
if (sbc->allocation_method & SBC_SUBBANDS_4)
bt_shell_printf("4 ");
if (sbc->allocation_method & SBC_SUBBANDS_8)
bt_shell_printf("8");
bt_shell_printf("\n\tBlocks: ");
if (sbc->block_length & SBC_BLOCK_LENGTH_4)
bt_shell_printf("4 ");
if (sbc->block_length & SBC_BLOCK_LENGTH_8)
bt_shell_printf("8 ");
if (sbc->block_length & SBC_BLOCK_LENGTH_12)
bt_shell_printf("12 ");
if (sbc->block_length & SBC_BLOCK_LENGTH_16)
bt_shell_printf("16 ");
bt_shell_printf("\n\tBitpool Range: %d-%d\n",
sbc->min_bitpool, sbc->max_bitpool);
}
static int print_a2dp_codec(uint8_t codec, void *data, uint8_t size)
{
int i;
switch (codec) {
case A2DP_CODEC_SBC:
print_sbc(data, size);
break;
case A2DP_CODEC_MPEG12:
print_mpeg12(data, size);
break;
case A2DP_CODEC_MPEG24:
print_mpeg24(data, size);
break;
case A2DP_CODEC_VENDOR:
print_vendor(data, size);
break;
default:
bt_shell_printf("\tMedia Codec: Unknown\n");
bt_shell_printf("\t\tCodec Data:");
for (i = 0; i < size - 2; ++i)
bt_shell_printf(" 0x%.02x", ((unsigned char *)data)[i]);
bt_shell_printf("\n");
}
return 0;
}
static void print_hexdump(const char *label, struct iovec *iov)
{
if (!iov)
return;
bt_shell_printf("%s:\n", label);
bt_shell_hexdump(iov->iov_base, iov->iov_len);
}
static void print_codec(const char *uuid, uint8_t codec, struct iovec *caps,
struct iovec *meta)
{
if (!strcasecmp(uuid, A2DP_SINK_UUID) ||
!strcasecmp(uuid, A2DP_SOURCE_UUID)) {
print_a2dp_codec(codec, caps->iov_base, caps->iov_len);
return;
}
if (codec != LC3_ID) {
print_hexdump("Capabilities", caps);
print_hexdump("Metadata", meta);
return;
}
print_lc3_caps(caps->iov_base, caps->iov_len);
if (!meta)
return;
print_lc3_meta(meta->iov_base, meta->iov_len);
}
static void print_capabilities(GDBusProxy *proxy)
{
DBusMessageIter iter, subiter;
const char *uuid;
uint8_t codec;
struct iovec caps, meta;
if (!g_dbus_proxy_get_property(proxy, "UUID", &iter))
return;
dbus_message_iter_get_basic(&iter, &uuid);
if (!g_dbus_proxy_get_property(proxy, "Codec", &iter))
return;
dbus_message_iter_get_basic(&iter, &codec);
if (!g_dbus_proxy_get_property(proxy, "Capabilities", &iter))
return;
dbus_message_iter_recurse(&iter, &subiter);
dbus_message_iter_get_fixed_array(&subiter, &caps.iov_base,
(int *)&caps.iov_len);
if (g_dbus_proxy_get_property(proxy, "Metadata", &iter)) {
dbus_message_iter_recurse(&iter, &subiter);
dbus_message_iter_get_fixed_array(&subiter, &meta.iov_base,
(int *)&meta.iov_len);
} else {
meta.iov_base = NULL;
meta.iov_len = 0;
}
print_codec(uuid, codec, &caps, &meta);
}
static void print_preset(struct codec_preset *codec, uint8_t codec_id)
{
bt_shell_printf("\tPreset %s\n", codec->name);
if (codec_id == LC3_ID)
print_lc3_cfg(codec->data.iov_base, codec->data.iov_len);
}
static void print_local_endpoint(struct endpoint *ep)
{
bt_shell_printf("Endpoint %s\n", ep->path);
bt_shell_printf("\tUUID %s\n", ep->uuid);
bt_shell_printf("\tCodec 0x%02x (%u)\n", ep->codec, ep->codec);
if (ep->caps)
print_codec(ep->uuid, ep->codec, ep->caps, ep->meta);
if (ep->codec_preset)
print_preset(ep->codec_preset, ep->codec);
if (ep->locations)
bt_shell_printf("\tLocations 0x%08x (%u)\n", ep->locations,
ep->locations);
if (ep->supported_context)
bt_shell_printf("\tSupportedContext 0x%08x (%u)\n",
ep->supported_context, ep->supported_context);
if (ep->context)
bt_shell_printf("\tContext 0x%08x (%u)\n", ep->context,
ep->context);
}
static void print_endpoint_properties(GDBusProxy *proxy)
{
bt_shell_printf("Endpoint %s\n", g_dbus_proxy_get_path(proxy));
print_property(proxy, "UUID");
print_property(proxy, "Codec");
print_capabilities(proxy);
print_property(proxy, "Device");
print_property(proxy, "DelayReporting");
print_property(proxy, "Locations");
print_property(proxy, "SupportedContext");
print_property(proxy, "Context");
print_property(proxy, "QoS");
}
static void print_endpoints(void *data, void *user_data)
{
print_endpoint_properties(data);
}
static void print_local_endpoints(void *data, void *user_data)
{
print_local_endpoint(data);
}
static void cmd_show_endpoint(int argc, char *argv[])
{
GDBusProxy *proxy;
/* Show all endpoints if no argument is given */
if (argc != 2) {
g_list_foreach(endpoints, print_endpoints, NULL);
g_list_foreach(local_endpoints, print_local_endpoints, NULL);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
proxy = g_dbus_proxy_lookup(endpoints, NULL, argv[1],
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
if (!proxy) {
struct endpoint *ep;
ep = endpoint_find(argv[1]);
if (ep)
return print_local_endpoint(ep);
bt_shell_printf("Endpoint %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
print_endpoint_properties(proxy);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static const GDBusMethodTable endpoint_methods[] = {
{ GDBUS_ASYNC_METHOD("SetConfiguration",
GDBUS_ARGS({ "endpoint", "o" },
{ "properties", "a{sv}" } ),
NULL, endpoint_set_configuration) },
{ GDBUS_ASYNC_METHOD("SelectConfiguration",
GDBUS_ARGS({ "caps", "ay" } ),
GDBUS_ARGS({ "cfg", "ay" } ),
endpoint_select_configuration) },
{ GDBUS_ASYNC_METHOD("SelectProperties",
GDBUS_ARGS({ "properties", "a{sv}" } ),
GDBUS_ARGS({ "properties", "a{sv}" } ),
endpoint_select_properties) },
{ GDBUS_ASYNC_METHOD("ClearConfiguration",
GDBUS_ARGS({ "transport", "o" } ),
NULL, endpoint_clear_configuration) },
{ },
};
static void endpoint_free(void *data)
{
struct endpoint *ep = data;
util_iov_free(ep->caps, 1);
util_iov_free(ep->meta, 1);
if (ep->msg)
dbus_message_unref(ep->msg);
queue_destroy(ep->preset->custom, free);
ep->preset->custom = NULL;
if (ep->codec == 0xff)
free(ep->preset);
queue_destroy(ep->acquiring, NULL);
queue_destroy(ep->transports, free);
g_free(ep->path);
g_free(ep->uuid);
g_free(ep);
}
static gboolean endpoint_get_uuid(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_STRING, &ep->uuid);
return TRUE;
}
static gboolean endpoint_get_codec(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_BYTE, &ep->codec);
return TRUE;
}
static gboolean endpoint_get_capabilities(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
DBusMessageIter array;
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY,
DBUS_TYPE_BYTE_AS_STRING, &array);
dbus_message_iter_append_fixed_array(&array, DBUS_TYPE_BYTE,
&ep->caps->iov_base,
ep->caps->iov_len);
dbus_message_iter_close_container(iter, &array);
return TRUE;
}
struct vendor {
uint16_t cid;
uint16_t vid;
} __packed;
static gboolean endpoint_get_vendor(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
struct vendor vendor = { ep->cid, ep->vid };
dbus_message_iter_append_basic(iter, DBUS_TYPE_UINT32, &vendor);
return TRUE;
}
static gboolean endpoint_vendor_exists(const GDBusPropertyTable *property,
void *data)
{
struct endpoint *ep = data;
return ep->cid && ep->vid;
}
static gboolean endpoint_get_metadata(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
DBusMessageIter array;
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY,
DBUS_TYPE_BYTE_AS_STRING, &array);
dbus_message_iter_append_fixed_array(&array, DBUS_TYPE_BYTE,
&ep->meta->iov_base,
ep->meta->iov_len);
dbus_message_iter_close_container(iter, &array);
return TRUE;
}
static gboolean endpoint_metadata_exists(const GDBusPropertyTable *property,
void *data)
{
struct endpoint *ep = data;
return ep->meta ? TRUE : FALSE;
}
static gboolean endpoint_get_locations(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_UINT32, &ep->locations);
return TRUE;
}
static gboolean endpoint_locations_exists(const GDBusPropertyTable *property,
void *data)
{
struct endpoint *ep = data;
return ep->supported_context ? TRUE : FALSE;
}
static gboolean
endpoint_get_supported_context(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_UINT16,
&ep->supported_context);
return TRUE;
}
static gboolean
endpoint_supported_context_exists(const GDBusPropertyTable *property,
void *data)
{
struct endpoint *ep = data;
return ep->supported_context ? TRUE : FALSE;
}
static gboolean endpoint_get_context(const GDBusPropertyTable *property,
DBusMessageIter *iter, void *data)
{
struct endpoint *ep = data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_UINT16, &ep->context);
return TRUE;
}
static gboolean endpoint_context_exists(const GDBusPropertyTable *property,
void *data)
{
struct endpoint *ep = data;
return ep->context ? TRUE : FALSE;
}
static const GDBusPropertyTable endpoint_properties[] = {
{ "UUID", "s", endpoint_get_uuid, NULL, NULL },
{ "Codec", "y", endpoint_get_codec, NULL, NULL },
{ "Capabilities", "ay", endpoint_get_capabilities, NULL, NULL },
{ "Metadata", "ay", endpoint_get_metadata, NULL,
endpoint_metadata_exists },
{ "Vendor", "u", endpoint_get_vendor, NULL, endpoint_vendor_exists },
{ "Locations", "u", endpoint_get_locations, NULL,
endpoint_locations_exists },
{ "SupportedContext", "q", endpoint_get_supported_context, NULL,
endpoint_supported_context_exists },
{ "Context", "q", endpoint_get_context, NULL, endpoint_context_exists },
{ }
};
static void register_endpoint_setup(DBusMessageIter *iter, void *user_data)
{
struct endpoint *ep = user_data;
DBusMessageIter dict;
const char *key = "Capabilities";
const char *meta = "Metadata";
dbus_message_iter_append_basic(iter, DBUS_TYPE_OBJECT_PATH, &ep->path);
dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY, "{sv}", &dict);
g_dbus_dict_append_entry(&dict, "UUID", DBUS_TYPE_STRING, &ep->uuid);
g_dbus_dict_append_entry(&dict, "Codec", DBUS_TYPE_BYTE, &ep->codec);
if (ep->cid && ep->vid) {
struct vendor vendor = { ep->cid, ep->vid };
g_dbus_dict_append_entry(&dict, "Vendor", DBUS_TYPE_UINT32,
&vendor);
}
if (ep->caps) {
g_dbus_dict_append_basic_array(&dict, DBUS_TYPE_STRING, &key,
DBUS_TYPE_BYTE, &ep->caps->iov_base,
ep->caps->iov_len);
bt_shell_printf("Capabilities:\n");
bt_shell_hexdump(ep->caps->iov_base, ep->caps->iov_len);
}
if (ep->meta) {
g_dbus_dict_append_basic_array(&dict, DBUS_TYPE_STRING, &meta,
DBUS_TYPE_BYTE, &ep->meta->iov_base,
ep->meta->iov_len);
bt_shell_printf("Metadata:\n");
bt_shell_hexdump(ep->meta->iov_base, ep->meta->iov_len);
}
if (ep->locations)
g_dbus_dict_append_entry(&dict, "Locations", DBUS_TYPE_UINT32,
&ep->locations);
if (ep->supported_context)
g_dbus_dict_append_entry(&dict, "SupportedContext",
DBUS_TYPE_UINT16,
&ep->supported_context);
if (ep->context)
g_dbus_dict_append_entry(&dict, "Context", DBUS_TYPE_UINT16,
&ep->context);
dbus_message_iter_close_container(iter, &dict);
}
static void register_endpoint_reply(DBusMessage *message, void *user_data)
{
struct endpoint *ep = user_data;
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message)) {
bt_shell_printf("Failed to register endpoint: %s\n",
error.name);
dbus_error_free(&error);
if (g_list_find(local_endpoints, ep)) {
local_endpoints = g_list_remove(local_endpoints, ep);
g_dbus_unregister_interface(dbus_conn, ep->path,
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
}
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Endpoint %s registered\n", ep->path);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static bool media_supports_uuid(GDBusProxy *proxy, const char *uuid)
{
DBusMessageIter iter, array;
if (!g_dbus_proxy_get_property(proxy, "SupportedUUIDs", &iter))
return false;
dbus_message_iter_recurse(&iter, &array);
while (dbus_message_iter_get_arg_type(&array) == DBUS_TYPE_STRING) {
const char *support_uuid;
dbus_message_iter_get_basic(&array, &support_uuid);
if (!strcasecmp(uuid, support_uuid))
return true;
dbus_message_iter_next(&array);
}
return false;
}
static void endpoint_register(struct endpoint *ep)
{
GList *l;
int registered = 0;
if (!g_dbus_register_interface(dbus_conn, ep->path,
BLUEZ_MEDIA_ENDPOINT_INTERFACE,
endpoint_methods, NULL,
endpoint_properties, ep,
endpoint_free)) {
goto fail;
}
for (l = medias; l; l = g_list_next(l)) {
if (!media_supports_uuid(l->data, ep->uuid))
continue;
if (!g_dbus_proxy_method_call(l->data, "RegisterEndpoint",
register_endpoint_setup,
register_endpoint_reply,
ep, NULL)) {
g_dbus_unregister_interface(dbus_conn, ep->path,
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
goto fail;
}
registered++;
}
if (!registered)
goto fail;
return;
fail:
bt_shell_printf("Failed register endpoint\n");
local_endpoints = g_list_remove(local_endpoints, ep);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void endpoint_iso_stream(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
if (!strcasecmp(input, "a") || !strcasecmp(input, "auto")) {
ep->iso_stream = BT_ISO_QOS_STREAM_UNSET;
} else {
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT8_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->iso_stream = value;
}
endpoint_register(ep);
}
static void endpoint_iso_group(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
if (!strcasecmp(input, "a") || !strcasecmp(input, "auto")) {
ep->iso_group = BT_ISO_QOS_GROUP_UNSET;
} else {
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT8_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->iso_group = value;
}
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
bt_shell_prompt_input(ep->path, "CIS (auto/value):",
endpoint_iso_stream, ep);
}
static void endpoint_context(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT16_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->context = value;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
bt_shell_prompt_input(ep->path, "CIG (auto/value):",
endpoint_iso_group, ep);
}
static void endpoint_supported_context(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT16_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->supported_context = value;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
if (ep->broadcast) {
endpoint_register(ep);
return;
}
bt_shell_prompt_input(ep->path, "Context (value):", endpoint_context,
ep);
}
static void endpoint_locations(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
uint8_t channels;
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->locations = value;
channels = __builtin_popcount(value);
/* Automatically set LC3_CHAN_COUNT if only 1 location is supported */
if (channels == 1)
util_ltv_push(ep->caps, sizeof(channels), LC3_CHAN_COUNT,
&channels);
bt_shell_prompt_input(ep->path, "Supported Context (value):",
endpoint_supported_context, ep);
}
static void endpoint_max_transports(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
char *endptr = NULL;
int value;
if (!strcasecmp(input, "a") || !strcasecmp(input, "auto")) {
ep->max_transports = UINT8_MAX;
} else {
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT8_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ep->max_transports = value;
}
bt_shell_prompt_input(ep->path, "Locations:", endpoint_locations, ep);
}
static void endpoint_auto_accept(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
if (!strcasecmp(input, "y") || !strcasecmp(input, "yes")) {
ep->auto_accept = true;
bt_shell_prompt_input(ep->path, "Max Transports (auto/value):",
endpoint_max_transports, ep);
return;
} else if (!strcasecmp(input, "n") || !strcasecmp(input, "no")) {
ep->auto_accept = false;
bt_shell_prompt_input(ep->path, "Max Transports (auto/value):",
endpoint_max_transports, ep);
return;
} else {
bt_shell_printf("Invalid input for Auto Accept\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
static void endpoint_set_metadata(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
struct iovec iov;
if (!strcasecmp(input, "n") || !strcasecmp(input, "no")) {
util_iov_free(ep->meta, 1);
ep->meta = NULL;
goto done;
}
iov.iov_base = str2bytearray((char *) input, &iov.iov_len);
if (iov.iov_base) {
util_iov_free(ep->meta, 1);
ep->meta = util_iov_dup(&iov, 1);
}
done:
bt_shell_prompt_input(ep->path, "Auto Accept (yes/no):",
endpoint_auto_accept, ep);
}
static void endpoint_set_capabilities(const char *input, void *user_data)
{
struct endpoint *ep = user_data;
struct iovec iov;
if (!strcasecmp(input, "n") || !strcasecmp(input, "no")) {
util_iov_free(ep->caps, 1);
ep->caps = NULL;
goto done;
}
iov.iov_base = str2bytearray((char *) input, &iov.iov_len);
if (iov.iov_base) {
util_iov_free(ep->caps, 1);
ep->caps = util_iov_dup(&iov, 1);
}
done:
bt_shell_prompt_input(ep->path, "Enter Metadata (value/no):",
endpoint_set_metadata, ep);
}
static char *uuid_generator(const char *text, int state)
{
int len = strlen(text);
static int index = 0;
size_t i;
if (!state) {
index = 0;
}
for (i = index; i < ARRAY_SIZE(caps); i++) {
const struct capabilities *cap = &caps[i];
index++;
if (!strncasecmp(cap->uuid, text, len))
return strdup(cap->uuid);
}
return NULL;
}
static const struct capabilities *find_capabilities(const char *uuid,
uint8_t codec_id)
{
size_t i;
for (i = 0; i < ARRAY_SIZE(caps); i++) {
const struct capabilities *cap = &caps[i];
if (strcasecmp(cap->uuid, uuid))
continue;
if (cap->codec_id == codec_id)
return cap;
}
return NULL;
}
static struct codec_preset *codec_preset_new(const char *name)
{
struct codec_preset *codec;
codec = new0(struct codec_preset, 1);
codec->name = strdup(name);
codec->custom = true;
return codec;
}
static struct codec_preset *codec_preset_add(struct preset *preset,
const char *name)
{
struct codec_preset *codec;
codec = preset_find_name(preset, name);
if (codec)
return codec;
codec = codec_preset_new(name);
if (!preset->custom)
preset->custom = queue_new();
queue_push_tail(preset->custom, codec);
return codec;
}
static void cmd_register_endpoint(int argc, char *argv[])
{
struct endpoint *ep;
char *endptr = NULL;
ep = g_new0(struct endpoint, 1);
ep->uuid = g_strdup(argv[1]);
ep->codec = strtol(argv[2], &endptr, 0);
ep->cid = 0x0000;
ep->vid = 0x0000;
ep->path = g_strdup_printf("%s/ep%u", BLUEZ_MEDIA_ENDPOINT_PATH,
g_list_length(local_endpoints));
local_endpoints = g_list_append(local_endpoints, ep);
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
if (!strcmp(ep->uuid, BCAA_SERVICE_UUID) ||
!strcmp(ep->uuid, BAA_SERVICE_UUID)) {
ep->broadcast = true;
} else {
ep->broadcast = false;
}
if (strrchr(argv[2], ':')) {
ep->codec = 0xff;
parse_vendor_codec(argv[2], &ep->vid, &ep->cid);
ep->preset = new0(struct preset, 1);
ep->preset->default_preset = codec_preset_add(ep->preset,
"custom");
} else {
ep->preset = find_presets_name(ep->uuid, argv[2]);
}
if (argc > 3)
endpoint_set_capabilities(argv[3], ep);
else {
const struct capabilities *cap;
cap = find_capabilities(ep->uuid, ep->codec);
if (cap) {
/* Copy capabilities */
util_iov_free(ep->caps, 1);
ep->caps = util_iov_dup(&cap->data, 1);
/* Copy metadata */
util_iov_free(ep->meta, 1);
ep->meta = util_iov_dup(&cap->meta, 1);
bt_shell_prompt_input(ep->path, "Auto Accept (yes/no):",
endpoint_auto_accept, ep);
} else
bt_shell_prompt_input(ep->path, "Enter capabilities:",
endpoint_set_capabilities, ep);
}
}
static void unregister_endpoint_setup(DBusMessageIter *iter, void *user_data)
{
struct endpoint *ep = user_data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_OBJECT_PATH, &ep->path);
}
static void unregister_endpoint_reply(DBusMessage *message, void *user_data)
{
struct endpoint *ep = user_data;
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message)) {
bt_shell_printf("Failed to unregister endpoint: %s\n",
error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Endpoint %s unregistered\n", ep->path);
local_endpoints = g_list_remove(local_endpoints, ep);
g_dbus_unregister_interface(dbus_conn, ep->path,
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_unregister_endpoint(int argc, char *argv[])
{
struct endpoint *ep;
GList *l;
ep = endpoint_find(argv[1]);
if (!ep) {
bt_shell_printf("Unable to find endpoint object: %s\n",
argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
for (l = medias; l; l = g_list_next(l)) {
if (!g_dbus_proxy_method_call(l->data, "UnregisterEndpoint",
unregister_endpoint_setup,
unregister_endpoint_reply,
ep, NULL)) {
bt_shell_printf("Failed unregister endpoint\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void config_endpoint_setup(DBusMessageIter *iter, void *user_data)
{
struct endpoint_config *cfg = user_data;
dbus_message_iter_append_basic(iter, DBUS_TYPE_OBJECT_PATH,
&cfg->ep->path);
append_properties(iter, cfg);
}
static void config_endpoint_reply(DBusMessage *message, void *user_data)
{
struct endpoint_config *cfg = user_data;
struct endpoint *ep = cfg->ep;
DBusError error;
free(cfg->caps->iov_base);
free(cfg->caps);
free(cfg);
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message)) {
bt_shell_printf("Failed to config endpoint: %s\n",
error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Endpoint %s configured\n", ep->path);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void endpoint_set_config(struct endpoint_config *cfg)
{
if (!g_dbus_proxy_method_call(cfg->proxy, "SetConfiguration",
config_endpoint_setup,
config_endpoint_reply,
cfg, NULL)) {
bt_shell_printf("Failed to config endpoint\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
static void endpoint_config(const char *input, void *user_data)
{
struct endpoint_config *cfg = user_data;
uint8_t *data;
size_t len = 0;
data = str2bytearray((char *) input, &len);
util_iov_append(cfg->caps, data, len);
free(data);
endpoint_set_config(cfg);
}
static struct endpoint *endpoint_new(const struct capabilities *cap);
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
static void endpoint_set_metadata_cfg(const char *input, void *user_data)
{
struct endpoint_config *cfg = user_data;
if (!strcasecmp(input, "n") || !strcasecmp(input, "no"))
goto done;
if (!cfg->meta)
cfg->meta = g_new0(struct iovec, 1);
cfg->meta->iov_base = str2bytearray((char *) input,
&cfg->meta->iov_len);
if (!cfg->meta->iov_base) {
free(cfg->meta);
cfg->meta = NULL;
}
done:
endpoint_set_config(cfg);
}
static void config_endpoint_channel_location(const char *input, void *user_data)
{
struct endpoint_config *cfg = user_data;
char *endptr = NULL;
uint32_t location;
uint8_t channels = 1;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
if (!strcasecmp(input, "n") || !strcasecmp(input, "no"))
goto add_meta;
location = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
/* Add Channel Allocation LTV in capabilities */
location = cpu_to_le32(location);
util_ltv_push(cfg->caps, LC3_CONFIG_CHAN_ALLOC_LEN - 1,
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
LC3_CONFIG_CHAN_ALLOC, &location);
/* Adjust the SDU size based on the number of
* locations/channels that is being requested.
*/
channels = __builtin_popcount(location);
if (channels > 1)
cfg->qos.bcast.io_qos.sdu *= channels;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
add_meta:
/* Add metadata */
bt_shell_prompt_input(cfg->ep->path, "Enter Metadata (value/no):",
endpoint_set_metadata_cfg, cfg);
}
static void config_endpoint_iso_group(const char *input, void *user_data)
{
struct endpoint_config *cfg = user_data;
char *endptr = NULL;
int value;
uint8_t type = LC3_CONFIG_CHAN_ALLOC;
bool found = false;
if (!strcasecmp(input, "a") || !strcasecmp(input, "auto")) {
cfg->ep->iso_group = BT_ISO_QOS_GROUP_UNSET;
} else {
value = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0' || value > UINT8_MAX) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
cfg->ep->iso_group = value;
}
/* Check if Channel Allocation is present in caps */
util_ltv_foreach(cfg->caps->iov_base,
cfg->caps->iov_len, &type,
ltv_find, &found);
/* Add Channel Allocation if it is not present in caps */
if (!found) {
bt_shell_prompt_input(cfg->ep->path,
"Enter channel location (value/no):",
config_endpoint_channel_location, cfg);
} else {
/* Add metadata */
bt_shell_prompt_input(cfg->ep->path,
"Enter Metadata (value/no):",
endpoint_set_metadata_cfg, cfg);
}
}
static void endpoint_set_config_bcast(struct endpoint_config *cfg)
{
cfg->ep->bcode = g_new0(struct iovec, 1);
util_iov_append(cfg->ep->bcode, bcast_code,
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
sizeof(bcast_code));
if ((strcmp(cfg->ep->uuid, BAA_SERVICE_UUID) == 0)) {
/* A broadcast sink endpoint config does not need
* user input.
*/
endpoint_set_config(cfg);
return;
}
bt_shell_prompt_input(cfg->ep->path,
"BIG (auto/value):",
config_endpoint_iso_group, cfg);
}
static void cmd_config_endpoint(int argc, char *argv[])
{
struct endpoint_config *cfg;
const struct codec_preset *preset;
cfg = new0(struct endpoint_config, 1);
/* Search for the remote endpoint name on DBUS */
cfg->proxy = g_dbus_proxy_lookup(endpoints, NULL, argv[1],
BLUEZ_MEDIA_ENDPOINT_INTERFACE);
if (!cfg->proxy) {
bt_shell_printf("Endpoint %s not found\n", argv[1]);
goto fail;
}
/* Search for the local endpoint */
cfg->ep = endpoint_find(argv[2]);
if (!cfg->ep) {
bt_shell_printf("Local Endpoint %s not found\n", argv[2]);
goto fail;
}
if (argc > 3) {
preset = preset_find_name(cfg->ep->preset, argv[3]);
if (!preset) {
bt_shell_printf("Preset %s not found\n", argv[3]);
goto fail;
}
cfg->caps = g_new0(struct iovec, 1);
/* Copy capabilities */
util_iov_append(cfg->caps, preset->data.iov_base,
preset->data.iov_len);
cfg->target_latency = preset->target_latency;
/* Set QoS parameters */
cfg->qos = preset->qos;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
if (cfg->ep->broadcast)
endpoint_set_config_bcast(cfg);
else
endpoint_set_config(cfg);
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
return;
}
bt_shell_prompt_input(cfg->ep->path, "Enter configuration:",
endpoint_config, cfg);
return;
fail:
g_free(cfg);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void custom_delay(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct bt_bap_qos *qos = (void *)&p->qos;
char *endptr = NULL;
if (!p->target_latency)
qos->bcast.delay = strtol(input, &endptr, 0);
else
qos->ucast.delay = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void custom_latency(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct bt_bap_qos *qos = (void *)&p->qos;
char *endptr = NULL;
if (!p->target_latency)
qos->bcast.io_qos.latency = strtol(input, &endptr, 0);
else
qos->ucast.io_qos.latency = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_prompt_input("QoS", "Enter Presentation Delay (us):",
custom_delay, user_data);
}
static void custom_rtn(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct bt_bap_qos *qos = (void *)&p->qos;
char *endptr = NULL;
if (!p->target_latency)
qos->bcast.io_qos.rtn = strtol(input, &endptr, 0);
else
qos->ucast.io_qos.rtn = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_prompt_input("QoS", "Enter Max Transport Latency (ms):",
custom_latency, user_data);
}
static void custom_sdu(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct bt_bap_qos *qos = (void *)&p->qos;
char *endptr = NULL;
if (!p->target_latency)
qos->bcast.io_qos.sdu = strtol(input, &endptr, 0);
else
qos->ucast.io_qos.sdu = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_prompt_input("QoS", "Enter RTN:", custom_rtn, user_data);
}
static void custom_phy(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct bt_bap_io_qos *qos;
if (!p->target_latency)
qos = &p->qos.bcast.io_qos;
else
qos = &p->qos.ucast.io_qos;
if (!strcmp(input, "1M"))
qos->phy = 0x01;
else if (!strcmp(input, "2M"))
qos->phy = 0x02;
else {
char *endptr = NULL;
uint8_t phy = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
switch (phy) {
case 0x01:
case 0x02:
qos->phy = phy;
break;
default:
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
bt_shell_prompt_input("QoS", "Enter Max SDU:", custom_sdu, user_data);
}
static void custom_framing(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
uint8_t *framing;
if (!p->target_latency)
framing = &p->qos.bcast.framing;
else
framing = &p->qos.ucast.framing;
if (!strcasecmp(input, "Unframed"))
*framing = 0x00;
else if (!strcasecmp(input, "Framed"))
*framing = 0x01;
else {
char *endptr = NULL;
*framing = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
bt_shell_prompt_input("QoS", "Enter PHY (1M, 2M):", custom_phy,
user_data);
}
static void custom_interval(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
char *endptr = NULL;
struct bt_bap_io_qos *qos;
if (!p->target_latency)
qos = &p->qos.bcast.io_qos;
else
qos = &p->qos.ucast.io_qos;
qos->interval = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_prompt_input("QoS", "Enter Framing (Unframed, Framed):",
custom_framing, user_data);
}
static void custom_target_latency(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
if (!strcasecmp(input, "Low"))
p->target_latency = 0x01;
else if (!strcasecmp(input, "Balance"))
p->target_latency = 0x02;
else if (!strcasecmp(input, "High"))
p->target_latency = 0x03;
else {
char *endptr = NULL;
p->target_latency = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
bt_shell_prompt_input("QoS", "Enter SDU Interval (us):",
custom_interval, user_data);
}
static void custom_length(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct iovec *iov = (void *)&p->data;
uint8_t ltv[4] = { 0x03, LC3_CONFIG_FRAME_LEN };
uint16_t len;
char *endptr = NULL;
len = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
ltv[2] = len;
ltv[3] = len >> 8;
util_iov_append(iov, ltv, sizeof(ltv));
bt_shell_prompt_input("QoS", "Enter Target Latency "
"(Low, Balance, High):",
custom_target_latency, user_data);
}
static void custom_location(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct iovec *iov = (void *)&p->data;
uint32_t location;
char *endptr = NULL;
location = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
/* Only add Channel Allocation if set */
if (location) {
uint8_t ltv[6] = { 0x05, LC3_CONFIG_CHAN_ALLOC };
location = cpu_to_le32(location);
memcpy(&ltv[2], &location, sizeof(location));
util_iov_append(iov, ltv, sizeof(ltv));
}
bt_shell_prompt_input("Codec", "Enter frame length:",
custom_length, user_data);
}
static uint8_t val2duration(uint32_t val)
{
switch (val) {
case 7:
return 0x00;
case 10:
return 0x01;
default:
return 0xff;
}
}
static void custom_duration(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct iovec *iov = (void *)&p->data;
uint8_t ltv[3] = { 0x02, LC3_CONFIG_DURATION, 0x00 };
char *endptr = NULL;
uint32_t val;
val = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (strncmp(input, "0x", 2))
ltv[2] = val2duration(val);
else
ltv[2] = val;
if (ltv[2] == 0xff) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
util_iov_append(iov, ltv, sizeof(ltv));
bt_shell_prompt_input("Codec", "Enter channel allocation:",
custom_location, user_data);
}
static uint8_t val2freq(uint32_t val)
{
switch (val) {
case 8:
return 0x01;
case 11:
return 0x02;
case 16:
return 0x03;
case 22:
return 0x04;
case 24:
return 0x05;
case 32:
return 0x06;
case 44:
return 0x07;
case 48:
return 0x08;
case 88:
return 0x09;
case 96:
return 0x0a;
case 174:
return 0x0b;
case 192:
return 0x0c;
case 384:
return 0x0d;
default:
return 0x00;
}
}
static void custom_frequency(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
struct iovec *iov = (void *)&p->data;
uint8_t ltv[3] = { 0x02, LC3_CONFIG_FREQ, 0x00 };
uint32_t val;
char *endptr = NULL;
val = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (strncmp(input, "0x", 2))
ltv[2] = val2freq(val);
else
ltv[2] = val;
if (!ltv[2]) {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
/* Reset iov to start over the codec configuration */
free(iov->iov_base);
iov->iov_base = NULL;
iov->iov_len = 0;
util_iov_append(iov, ltv, sizeof(ltv));
bt_shell_prompt_input("Codec", "Enter frame duration (ms):",
custom_duration, user_data);
}
static void foreach_custom_preset_print(void *data, void *user_data)
{
struct codec_preset *p = data;
struct preset *preset = user_data;
bt_shell_printf("%s%s\n", p == preset->default_preset ? "*" : "",
p->name);
}
static void print_presets(struct preset *preset)
{
size_t i;
struct codec_preset *p;
for (i = 0; i < preset->num_presets; i++) {
p = &preset->presets[i];
if (p == preset->default_preset)
bt_shell_printf("*%s\n", p->name);
else if (preset->default_preset &&
p == preset->default_preset->alt_preset)
bt_shell_printf("**%s\n", p->name);
else
bt_shell_printf("%s\n", p->name);
}
queue_foreach(preset->custom, foreach_custom_preset_print, preset);
}
static void custom_chan_alloc(const char *input, void *user_data)
{
struct codec_preset *p = user_data;
char *endptr = NULL;
p->chan_alloc = strtol(input, &endptr, 0);
if (!endptr || *endptr != '\0') {
bt_shell_printf("Invalid argument: %s\n", input);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (p->alt_preset)
bt_shell_prompt_input(p->alt_preset->name,
"Enter Channel Allocation: ",
custom_chan_alloc, p->alt_preset);
else
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_presets_endpoint(int argc, char *argv[])
{
struct preset *preset;
struct codec_preset *default_preset = NULL;
struct endpoint *ep = NULL;
preset = find_presets_name(argv[1], argv[2]);
if (!preset) {
ep = endpoint_find(argv[1]);
if (!ep) {
bt_shell_printf("No preset found\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
preset = ep->preset;
argv++;
argc--;
} else {
argv += 2;
argc -= 2;
}
if (argc > 1) {
default_preset = codec_preset_add(preset, argv[1]);
if (!default_preset) {
bt_shell_printf("Preset %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (ep)
ep->codec_preset = default_preset;
else
preset->default_preset = default_preset;
if (argc > 2) {
struct codec_preset *alt_preset;
struct iovec *caps = (void *)&default_preset->data;
struct iovec *meta = (void *)&default_preset->meta;
/* Check if and alternative preset was given */
alt_preset = preset_find_name(preset, argv[2]);
if (alt_preset) {
default_preset->alt_preset = alt_preset;
bt_shell_prompt_input(default_preset->name,
"Enter Channel Allocation: ",
custom_chan_alloc,
default_preset);
return;
}
/* Check if Codec Configuration was entered */
if (strlen(argv[2])) {
caps->iov_base = str2bytearray(argv[2],
&caps->iov_len);
if (!caps->iov_base) {
bt_shell_printf("Invalid configuration "
"%s\n",
argv[2]);
return bt_shell_noninteractive_quit(
EXIT_FAILURE);
}
}
/* Check if metadata was entered */
if (argc > 3) {
meta->iov_base = str2bytearray(argv[3],
&meta->iov_len);
if (!meta->iov_base) {
bt_shell_printf("Invalid metadata %s\n",
argv[5]);
return bt_shell_noninteractive_quit(
EXIT_FAILURE);
}
}
/* If configuration was left empty then ask the
* parameters.
*/
if (!caps->iov_base || !caps->iov_len)
goto enter_cc;
bt_shell_prompt_input("QoS", "Enter Target Latency "
"(Low, Balance, High):",
custom_target_latency,
default_preset);
return;
}
} else if (ep && (ep->codec_preset))
print_preset(ep->codec_preset, ep->codec);
else
print_presets(preset);
enter_cc:
if (default_preset && default_preset->custom) {
bt_shell_prompt_input("Codec", "Enter frequency (Khz):",
custom_frequency, default_preset);
return;
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static const struct bt_shell_menu endpoint_menu = {
.name = "endpoint",
.desc = "Media Endpoint Submenu",
.entries = {
{ "list", "[local]", cmd_list_endpoints,
"List available endpoints" },
{ "show", "[endpoint]", cmd_show_endpoint,
"Endpoint information",
endpoint_generator },
{ "register", "<UUID> <codec[:company]> [capabilities...]",
cmd_register_endpoint,
"Register Endpoint",
uuid_generator },
{ "unregister", "<UUID/object>", cmd_unregister_endpoint,
"Register Endpoint",
local_endpoint_generator },
{ "config", "<endpoint> [local endpoint] [preset]",
cmd_config_endpoint,
"Configure Endpoint",
endpoint_generator },
{ "presets", "<endpoint>/<UUID> [codec[:company]] [preset] "
"[codec config] [metadata]",
cmd_presets_endpoint,
"List or add presets",
uuid_generator },
{} },
};
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
static void endpoint_init_bcast(struct endpoint *ep)
{
if (!strcmp(ep->uuid, BAA_SERVICE_UUID)) {
ep->locations = EP_SNK_LOCATIONS;
ep->supported_context = EP_SUPPORTED_SNK_CTXT;
} else {
ep->locations = EP_SRC_LOCATIONS;
ep->supported_context = EP_SUPPORTED_SRC_CTXT;
}
}
static void endpoint_init_ucast(struct endpoint *ep)
{
if (!strcmp(ep->uuid, PAC_SINK_UUID)) {
ep->locations = EP_SNK_LOCATIONS;
ep->supported_context = EP_SUPPORTED_SNK_CTXT;
ep->context = EP_SNK_CTXT;
} else if (!strcmp(ep->uuid, PAC_SOURCE_UUID)) {
ep->locations = EP_SRC_LOCATIONS;
ep->supported_context = EP_SUPPORTED_SRC_CTXT;
ep->context = EP_SRC_CTXT;
}
}
static void endpoint_init_defaults(struct endpoint *ep)
{
ep->preset = find_presets(ep->uuid, ep->codec, ep->vid, ep->cid);
ep->max_transports = UINT8_MAX;
ep->auto_accept = true;
if (!strcmp(ep->uuid, A2DP_SOURCE_UUID) ||
!strcmp(ep->uuid, A2DP_SOURCE_UUID))
return;
ep->iso_group = BT_ISO_QOS_GROUP_UNSET;
ep->iso_stream = BT_ISO_QOS_STREAM_UNSET;
ep->broadcast = (strcmp(ep->uuid, BCAA_SERVICE_UUID) &&
strcmp(ep->uuid, BAA_SERVICE_UUID)) ? false : true;
client/player: Update bcast endpoint input prompts This updates the input prompts for broadcast endpoint register and config. To register a broadcast endpoint, the user will be asked to enter the supported stream locations and context types. At broadcast source endpoint config, the user will provide stream config options: The BIG that the new stream will be part of, the stream Channel Allocation, and the metadata of the subgroup to include the stream. These options will be used to configure the BASE and the BIG. The flow to create a Broadcast Source is the following: [bluetooth]# endpoint.register 00001852-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [NEW] Endpoint /org/bluez/hci0/pac_bcast0 Endpoint /local/endpoint/ep0 registered [bluetooth]# endpoint.config /org/bluez/hci0/pac_bcast0 /local/endpoint/ep0 16_2_1 [/local/endpoint/ep0] BIG (auto/value): 1 [/local/endpoint/ep0] Enter channel location (value/no): 3 [/local/endpoint/ep0] Enter Metadata (value/no): 0x03 0x02 0x04 0x00 To create a Broadcast Sink, enter the following: [bluetooth]# endpoint.register 00001851-0000-1000-8000- 00805f9b34fb 0x06 [/local/endpoint/ep0] Auto Accept (yes/no): y [/local/endpoint/ep0] Max Transports (auto/value): a [/local/endpoint/ep0] Locations: 3 [/local/endpoint/ep0] Supported Context (value): 15 [bluetooth]# scan on [NEW] Endpoint /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/ pac_bcast0 [bluetooth]# endpoint.config /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/pac_bcast0 /local/endpoint/ep0 16_2_1
2024-01-30 23:44:12 +08:00
if (ep->broadcast)
endpoint_init_bcast(ep);
else
endpoint_init_ucast(ep);
}
static struct endpoint *endpoint_new(const struct capabilities *cap)
{
struct endpoint *ep;
ep = new0(struct endpoint, 1);
ep->uuid = g_strdup(cap->uuid);
ep->codec = cap->codec_id;
ep->path = g_strdup_printf("%s/%s", BLUEZ_MEDIA_ENDPOINT_PATH,
cap->name);
/* Copy capabilities */
ep->caps = util_iov_dup(&cap->data, 1);
/* Copy metadata */
ep->meta = util_iov_dup(&cap->meta, 1);
local_endpoints = g_list_append(local_endpoints, ep);
return ep;
}
static void register_endpoints(GDBusProxy *proxy)
{
struct endpoint *ep;
size_t i;
for (i = 0; i < ARRAY_SIZE(caps); i++) {
const struct capabilities *cap = &caps[i];
if (!media_supports_uuid(proxy, cap->uuid))
continue;
ep = endpoint_new(cap);
endpoint_init_defaults(ep);
endpoint_register(ep);
}
}
static void media_added(GDBusProxy *proxy)
{
medias = g_list_append(medias, proxy);
print_media(proxy, COLORED_NEW);
if (bt_shell_get_env("AUTO_REGISTER_ENDPOINT"))
register_endpoints(proxy);
}
static void player_added(GDBusProxy *proxy)
{
players = g_list_append(players, proxy);
if (default_player == NULL)
default_player = proxy;
print_player(proxy, COLORED_NEW);
}
static void print_folder(GDBusProxy *proxy, const char *description)
{
const char *path;
path = g_dbus_proxy_get_path(proxy);
bt_shell_printf("%s%s%sFolder %s\n", description ? "[" : "",
description ? : "",
description ? "] " : "",
path);
}
static void folder_added(GDBusProxy *proxy)
{
folders = g_list_append(folders, proxy);
print_folder(proxy, COLORED_NEW);
}
static void print_item(GDBusProxy *proxy, const char *description)
{
const char *path, *name;
DBusMessageIter iter;
path = g_dbus_proxy_get_path(proxy);
if (g_dbus_proxy_get_property(proxy, "Name", &iter))
dbus_message_iter_get_basic(&iter, &name);
else
name = "<unknown>";
bt_shell_printf("%s%s%sItem %s %s\n", description ? "[" : "",
description ? : "",
description ? "] " : "",
path, name);
}
static void item_added(GDBusProxy *proxy)
{
items = g_list_append(items, proxy);
print_item(proxy, COLORED_NEW);
}
static void endpoint_added(GDBusProxy *proxy)
{
endpoints = g_list_append(endpoints, proxy);
print_endpoint(proxy, COLORED_NEW);
}
static void print_transport(void *data, void *user_data)
{
GDBusProxy *proxy = data;
const char *description = user_data;
char *str;
str = proxy_description(proxy, "Transport", description);
bt_shell_printf("%s\n", str);
g_free(str);
}
static void transport_added(GDBusProxy *proxy)
{
transports = g_list_append(transports, proxy);
print_transport(proxy, COLORED_NEW);
}
static void proxy_added(GDBusProxy *proxy, void *user_data)
{
const char *interface;
interface = g_dbus_proxy_get_interface(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_INTERFACE))
media_added(proxy);
else if (!strcmp(interface, BLUEZ_MEDIA_PLAYER_INTERFACE))
player_added(proxy);
else if (!strcmp(interface, BLUEZ_MEDIA_FOLDER_INTERFACE))
folder_added(proxy);
else if (!strcmp(interface, BLUEZ_MEDIA_ITEM_INTERFACE))
item_added(proxy);
else if (!strcmp(interface, BLUEZ_MEDIA_ENDPOINT_INTERFACE))
endpoint_added(proxy);
else if (!strcmp(interface, BLUEZ_MEDIA_TRANSPORT_INTERFACE))
transport_added(proxy);
}
static void media_removed(GDBusProxy *proxy)
{
print_media(proxy, COLORED_DEL);
medias = g_list_remove(medias, proxy);
}
static void player_removed(GDBusProxy *proxy)
{
print_player(proxy, COLORED_DEL);
if (default_player == proxy)
default_player = NULL;
players = g_list_remove(players, proxy);
}
static void folder_removed(GDBusProxy *proxy)
{
folders = g_list_remove(folders, proxy);
print_folder(proxy, COLORED_DEL);
}
static void item_removed(GDBusProxy *proxy)
{
items = g_list_remove(items, proxy);
print_item(proxy, COLORED_DEL);
}
static void endpoint_removed(GDBusProxy *proxy)
{
endpoints = g_list_remove(endpoints, proxy);
print_endpoint(proxy, COLORED_DEL);
}
static void transport_removed(GDBusProxy *proxy)
{
transports = g_list_remove(transports, proxy);
print_transport(proxy, COLORED_DEL);
}
static void proxy_removed(GDBusProxy *proxy, void *user_data)
{
const char *interface;
interface = g_dbus_proxy_get_interface(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_INTERFACE))
media_removed(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_PLAYER_INTERFACE))
player_removed(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_FOLDER_INTERFACE))
folder_removed(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_ITEM_INTERFACE))
item_removed(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_ENDPOINT_INTERFACE))
endpoint_removed(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_TRANSPORT_INTERFACE))
transport_removed(proxy);
}
static void player_property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter)
{
char *str;
str = proxy_description(proxy, "Player", COLORED_CHG);
print_iter(str, name, iter);
g_free(str);
}
static void folder_property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter)
{
char *str;
str = proxy_description(proxy, "Folder", COLORED_CHG);
print_iter(str, name, iter);
g_free(str);
}
static void item_property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter)
{
char *str;
str = proxy_description(proxy, "Item", COLORED_CHG);
print_iter(str, name, iter);
g_free(str);
}
static void endpoint_property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter)
{
char *str;
str = proxy_description(proxy, "Endpoint", COLORED_CHG);
print_iter(str, name, iter);
g_free(str);
}
static struct endpoint *find_ep_by_transport(const char *path)
{
GList *l;
for (l = local_endpoints; l; l = g_list_next(l)) {
struct endpoint *ep = l->data;
if (queue_find(ep->transports, match_str, path))
return ep;
}
return NULL;
}
static GDBusProxy *find_link_by_proxy(GDBusProxy *proxy)
{
DBusMessageIter iter, array;
if (!g_dbus_proxy_get_property(proxy, "Links", &iter))
return NULL;
dbus_message_iter_recurse(&iter, &array);
while (dbus_message_iter_get_arg_type(&array) ==
DBUS_TYPE_OBJECT_PATH) {
const char *transport;
dbus_message_iter_get_basic(&array, &transport);
proxy = g_dbus_proxy_lookup(transports, NULL, transport,
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (proxy)
return proxy;
}
return NULL;
}
static void transport_close(struct transport *transport)
{
if (transport->fd < 0)
return;
close(transport->fd);
transport->fd = -1;
free(transport->filename);
}
static void transport_free(void *data)
{
struct transport *transport = data;
io_destroy(transport->timer_io);
io_destroy(transport->io);
free(transport);
}
static bool transport_disconnected(struct io *io, void *user_data)
{
struct transport *transport = user_data;
bt_shell_printf("Transport fd disconnected\n");
if (queue_remove(ios, transport))
transport_free(transport);
return false;
}
static bool transport_recv(struct io *io, void *user_data)
{
struct transport *transport = user_data;
uint8_t buf[1024];
int ret, len;
ret = io_get_fd(io);
if (ret < 0) {
bt_shell_printf("io_get_fd() returned %d\n", ret);
return true;
}
ret = read(ret, buf, sizeof(buf));
if (ret < 0) {
bt_shell_printf("Failed to read: %s (%d)\n", strerror(errno),
-errno);
return true;
}
bt_shell_echo("[seq %d] recv: %u bytes", transport->seq, ret);
transport->seq++;
if (transport->filename) {
len = write(transport->fd, buf, ret);
if (len < 0)
bt_shell_printf("Unable to write: %s (%d)\n",
strerror(errno), -errno);
}
return true;
}
static void transport_new(GDBusProxy *proxy, int sk, uint16_t mtu[2])
{
struct transport *transport;
transport = new0(struct transport, 1);
transport->proxy = proxy;
transport->sk = sk;
transport->mtu[0] = mtu[0];
transport->mtu[1] = mtu[1];
transport->io = io_new(sk);
transport->fd = -1;
io_set_disconnect_handler(transport->io, transport_disconnected,
transport, NULL);
io_set_read_handler(transport->io, transport_recv, transport, NULL);
if (!ios)
ios = queue_new();
queue_push_tail(ios, transport);
}
static void ep_set_acquiring(struct endpoint *ep, GDBusProxy *proxy, bool value)
{
bt_shell_printf("Transport %s %s\n", g_dbus_proxy_get_path(proxy),
value ? "acquiring" : "acquiring complete");
if (value && !ep->acquiring)
ep->acquiring = queue_new();
if (value)
queue_push_tail(ep->acquiring, proxy);
else
queue_remove(ep->acquiring, proxy);
}
static void transport_set_acquiring(GDBusProxy *proxy, bool value)
{
struct endpoint *ep;
GDBusProxy *link;
ep = find_ep_by_transport(g_dbus_proxy_get_path(proxy));
if (!ep)
return;
ep_set_acquiring(ep, proxy, value);
if (!ep->broadcast) {
link = find_link_by_proxy(proxy);
if (link) {
ep = find_ep_by_transport(g_dbus_proxy_get_path(link));
if (!ep)
return;
ep_set_acquiring(ep, link, value);
}
}
}
static void acquire_reply(DBusMessage *message, void *user_data)
{
GDBusProxy *proxy = user_data;
DBusError error;
int sk;
uint16_t mtu[2];
transport_set_acquiring(proxy, false);
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to acquire: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (!dbus_message_get_args(message, &error,
DBUS_TYPE_UNIX_FD, &sk,
DBUS_TYPE_UINT16, &mtu[0],
DBUS_TYPE_UINT16, &mtu[1],
DBUS_TYPE_INVALID)) {
bt_shell_printf("Failed to parse Acquire() reply: %s",
error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Acquire successful: fd %d MTU %u:%u\n", sk, mtu[0],
mtu[1]);
transport_new(proxy, sk, mtu);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void select_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to select: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Select successful");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void unselect_reply(DBusMessage *message, void *user_data)
{
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to unselect: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Select successful");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void prompt_acquire(const char *input, void *user_data)
{
GDBusProxy *proxy = user_data;
if (!strcasecmp(input, "y") || !strcasecmp(input, "yes")) {
if (g_dbus_proxy_method_call(proxy, "Acquire", NULL,
acquire_reply, proxy, NULL)) {
transport_set_acquiring(proxy, true);
return;
}
bt_shell_printf("Failed acquire transport\n");
}
}
static void transport_acquire(GDBusProxy *proxy, bool prompt)
{
struct endpoint *ep;
GDBusProxy *link;
/* only attempt to acquire if transport is configured with a local
* endpoint.
*/
ep = find_ep_by_transport(g_dbus_proxy_get_path(proxy));
if (!ep || queue_find(ep->acquiring, NULL, proxy))
return;
if (!ep->broadcast) {
link = find_link_by_proxy(proxy);
if (link) {
ep = find_ep_by_transport(g_dbus_proxy_get_path(link));
/* if link already acquiring wait it to be complete */
if (!ep || queue_find(ep->acquiring, NULL, link))
return;
}
}
if (ep->auto_accept || !prompt) {
if (!prompt)
bt_shell_printf("auto acquiring...\n");
if (!g_dbus_proxy_method_call(proxy, "Acquire", NULL,
acquire_reply, proxy, NULL)) {
bt_shell_printf("failed acquire transport\n");
return;
}
transport_set_acquiring(proxy, true);
return;
}
bt_shell_prompt_input(g_dbus_proxy_get_path(proxy), "acquire (yes/no):",
prompt_acquire, proxy);
}
static void transport_property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter)
{
char *str;
str = proxy_description(proxy, "Transport", COLORED_CHG);
print_iter(str, name, iter);
g_free(str);
if (strcmp(name, "State"))
return;
dbus_message_iter_get_basic(iter, &str);
if (strcmp(str, "pending"))
return;
transport_acquire(proxy, true);
}
static void property_changed(GDBusProxy *proxy, const char *name,
DBusMessageIter *iter, void *user_data)
{
const char *interface;
interface = g_dbus_proxy_get_interface(proxy);
if (!strcmp(interface, BLUEZ_MEDIA_PLAYER_INTERFACE))
player_property_changed(proxy, name, iter);
else if (!strcmp(interface, BLUEZ_MEDIA_FOLDER_INTERFACE))
folder_property_changed(proxy, name, iter);
else if (!strcmp(interface, BLUEZ_MEDIA_ITEM_INTERFACE))
item_property_changed(proxy, name, iter);
else if (!strcmp(interface, BLUEZ_MEDIA_ENDPOINT_INTERFACE))
endpoint_property_changed(proxy, name, iter);
else if (!strcmp(interface, BLUEZ_MEDIA_TRANSPORT_INTERFACE))
transport_property_changed(proxy, name, iter);
}
static char *transport_generator(const char *text, int state)
{
return generic_generator(text, state, transports);
}
static void cmd_list_transport(int argc, char *argv[])
{
GList *l;
for (l = transports; l; l = g_list_next(l)) {
GDBusProxy *proxy = l->data;
print_transport(proxy, NULL);
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void print_configuration(GDBusProxy *proxy)
{
DBusMessageIter iter, subiter;
const char *uuid;
uint8_t codec;
uint8_t *data;
int len;
if (!g_dbus_proxy_get_property(proxy, "UUID", &iter))
return;
dbus_message_iter_get_basic(&iter, &uuid);
if (!g_dbus_proxy_get_property(proxy, "Codec", &iter))
return;
dbus_message_iter_get_basic(&iter, &codec);
if (!g_dbus_proxy_get_property(proxy, "Configuration", &iter))
return;
dbus_message_iter_recurse(&iter, &subiter);
dbus_message_iter_get_fixed_array(&subiter, &data, &len);
if (!strcasecmp(uuid, A2DP_SINK_UUID) ||
!strcasecmp(uuid, A2DP_SOURCE_UUID)) {
print_a2dp_codec(codec, (void *)data, len);
return;
}
if (codec != LC3_ID) {
print_property(proxy, "Configuration");
return;
}
print_lc3_cfg(data, len);
if (!g_dbus_proxy_get_property(proxy, "Metadata", &iter))
return;
dbus_message_iter_recurse(&iter, &subiter);
dbus_message_iter_get_fixed_array(&subiter, &data, &len);
print_lc3_meta(data, len);
}
static void print_transport_properties(GDBusProxy *proxy)
{
bt_shell_printf("Transport %s\n", g_dbus_proxy_get_path(proxy));
print_property(proxy, "UUID");
print_property(proxy, "Codec");
print_configuration(proxy);
print_property(proxy, "Device");
print_property(proxy, "State");
print_property(proxy, "Delay");
print_property(proxy, "Volume");
print_property(proxy, "Endpoint");
print_property(proxy, "QoS");
print_property(proxy, "Location");
print_property(proxy, "Links");
}
static void print_transports(void *data, void *user_data)
{
print_transport_properties(data);
}
static void cmd_show_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
/* Show all transports if no argument is given */
if (argc != 2) {
g_list_foreach(transports, print_transports, NULL);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
proxy = g_dbus_proxy_lookup(transports, NULL, argv[1],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
print_transport_properties(proxy);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static bool match_proxy(const void *data, const void *user_data)
{
const struct transport *transport = data;
const GDBusProxy *proxy = user_data;
return transport->proxy == proxy;
}
static struct transport *find_transport(GDBusProxy *proxy)
{
return queue_find(ios, match_proxy, proxy);
}
static void cmd_acquire_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
int i;
for (i = 1; i < argc; i++) {
proxy = g_dbus_proxy_lookup(transports, NULL, argv[i],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (find_transport(proxy)) {
bt_shell_printf("Transport %s already acquired\n",
argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport_acquire(proxy, false);
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void set_bcode_cb(const DBusError *error, void *user_data)
{
GDBusProxy *proxy = user_data;
if (dbus_error_is_set(error)) {
bt_shell_printf("Failed to set broadcast code: %s\n",
error->name);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Setting broadcast code succeeded\n");
if (!g_dbus_proxy_method_call(proxy, "Select", NULL,
select_reply, proxy, NULL))
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void set_bcode(const char *input, void *user_data)
{
GDBusProxy *proxy = user_data;
char *bcode;
if (!strcasecmp(input, "n") || !strcasecmp(input, "no"))
bcode = g_new0(char, 16);
else
bcode = g_strdup(input);
if (g_dbus_proxy_set_property_dict(proxy, "QoS",
set_bcode_cb, user_data,
NULL, "BCode", DBUS_TYPE_ARRAY, DBUS_TYPE_BYTE,
strlen(bcode), bcode, NULL) == FALSE) {
bt_shell_printf("Setting broadcast code failed\n");
g_free(bcode);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
g_free(bcode);
}
static void transport_select(GDBusProxy *proxy, bool prompt)
{
DBusMessageIter iter, array, entry, value;
unsigned char encryption;
const char *key;
if (g_dbus_proxy_get_property(proxy, "QoS", &iter) == FALSE)
return;
dbus_message_iter_recurse(&iter, &array);
while (dbus_message_iter_get_arg_type(&array) !=
DBUS_TYPE_INVALID) {
dbus_message_iter_recurse(&array, &entry);
dbus_message_iter_get_basic(&entry, &key);
if (!strcasecmp(key, "Encryption")) {
dbus_message_iter_next(&entry);
dbus_message_iter_recurse(&entry, &value);
dbus_message_iter_get_basic(&value, &encryption);
if (encryption == 1) {
bt_shell_prompt_input("",
"Enter brocast code[value/no]:",
set_bcode, proxy);
return;
}
break;
}
dbus_message_iter_next(&array);
}
if (!g_dbus_proxy_method_call(proxy, "Select", NULL,
select_reply, proxy, NULL)) {
bt_shell_printf("Failed select transport\n");
return;
}
}
static void transport_unselect(GDBusProxy *proxy, bool prompt)
{
if (!g_dbus_proxy_method_call(proxy, "Unselect", NULL,
unselect_reply, proxy, NULL)) {
bt_shell_printf("Failed unselect transport\n");
return;
}
}
static void cmd_select_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
int i;
for (i = 1; i < argc; i++) {
proxy = g_dbus_proxy_lookup(transports, NULL, argv[i],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (find_transport(proxy)) {
bt_shell_printf("Transport %s already acquired\n",
argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport_select(proxy, false);
}
}
static void cmd_unselect_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
int i;
for (i = 1; i < argc; i++) {
proxy = g_dbus_proxy_lookup(transports, NULL, argv[i],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport_unselect(proxy, false);
}
}
static void release_reply(DBusMessage *message, void *user_data)
{
struct transport *transport = user_data;
DBusError error;
dbus_error_init(&error);
if (dbus_set_error_from_message(&error, message) == TRUE) {
bt_shell_printf("Failed to release: %s\n", error.name);
dbus_error_free(&error);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (queue_remove(ios, transport))
transport_free(transport);
bt_shell_printf("Release successful\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
static void cmd_release_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
int i;
for (i = 1; i < argc; i++) {
struct transport *transport;
proxy = g_dbus_proxy_lookup(transports, NULL, argv[i],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport = find_transport(proxy);
if (!transport) {
bt_shell_printf("Transport %s not acquired\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (!g_dbus_proxy_method_call(proxy, "Release", NULL,
release_reply, transport, NULL)) {
bt_shell_printf("Failed release transport\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static int open_file(const char *filename, int flags)
{
int fd = -1;
bt_shell_printf("Opening %s ...\n", filename);
if (flags & O_CREAT)
fd = open(filename, flags, 0755);
else
fd = open(filename, flags);
if (fd <= 0)
bt_shell_printf("Can't open file %s: %s\n", filename,
strerror(errno));
return fd;
}
static int elapsed_time(bool reset, int *secs, int *nsecs)
{
static struct timespec start;
struct timespec curr;
if (reset) {
if (clock_gettime(CLOCK_MONOTONIC, &start) < 0) {
bt_shell_printf("clock_gettime: %s (%d)",
strerror(errno), errno);
return -errno;
}
}
if (clock_gettime(CLOCK_MONOTONIC, &curr) < 0) {
bt_shell_printf("clock_gettime: %s (%d)", strerror(errno),
errno);
return -errno;
}
*secs = curr.tv_sec - start.tv_sec;
*nsecs = curr.tv_nsec - start.tv_nsec;
if (*nsecs < 0) {
(*secs)--;
*nsecs += 1000000000;
}
return 0;
}
static int transport_send_seq(struct transport *transport, int fd, uint32_t num)
{
uint8_t *buf;
uint32_t i;
if (!num)
return 0;
buf = malloc(transport->mtu[1]);
if (!buf)
return -ENOMEM;
for (i = 0; i < num; i++, transport->seq++) {
ssize_t ret;
int secs = 0, nsecs = 0;
off_t offset;
ret = read(fd, buf, transport->mtu[1]);
if (ret <= 0) {
if (ret < 0)
bt_shell_printf("read failed: %s (%d)",
strerror(errno), errno);
free(buf);
return ret;
}
ret = send(transport->sk, buf, ret, 0);
if (ret <= 0) {
bt_shell_printf("send failed: %s (%d)",
strerror(errno), errno);
free(buf);
return -errno;
}
elapsed_time(!transport->seq, &secs, &nsecs);
if (!transport->seq && fstat(fd, &transport->stat) < 0) {
bt_shell_printf("fstat failed: %s (%d)",
strerror(errno), errno);
free(buf);
return -errno;
}
offset = lseek(fd, 0, SEEK_CUR);
bt_shell_echo("[seq %d %d.%03ds] send: %zd/%zd bytes",
transport->seq, secs,
(nsecs + 500000) / 1000000,
offset, transport->stat.st_size);
}
free(buf);
return i;
}
static bool transport_timer_read(struct io *io, void *user_data)
{
struct transport *transport = user_data;
struct bt_iso_qos qos;
socklen_t len;
int ret, fd;
uint64_t exp;
if (transport->fd < 0)
return false;
fd = io_get_fd(io);
if (fd < 0) {
bt_shell_printf("io_get_fd() returned %d\n", fd);
return false;
}
ret = read(fd, &exp, sizeof(exp));
if (ret < 0) {
bt_shell_printf("Failed to read: %s (%d)\n", strerror(errno),
-errno);
return false;
}
/* Read QoS if available */
memset(&qos, 0, sizeof(qos));
len = sizeof(qos);
if (getsockopt(transport->sk, SOL_BLUETOOTH, BT_ISO_QOS, &qos,
&len) < 0) {
bt_shell_printf("Failed to getsockopt(BT_ISO_QOS): %s (%d)\n",
strerror(errno), -errno);
return false;
}
ret = transport_send_seq(transport, transport->fd, transport->num);
if (ret < 0) {
bt_shell_printf("Unable to send: %s (%d)\n",
strerror(-ret), ret);
return false;
}
if (!ret) {
transport_close(transport);
return false;
}
return true;
}
static int transport_send(struct transport *transport, int fd,
struct bt_iso_io_qos *qos)
{
struct itimerspec ts;
int timer_fd;
transport->seq = 0;
if (!qos)
return transport_send_seq(transport, fd, UINT32_MAX);
if (transport->fd >= 0)
return -EALREADY;
timer_fd = timerfd_create(CLOCK_MONOTONIC, 0);
if (timer_fd < 0)
return -errno;
/* Send data in bursts of
* num = ROUND_CLOSEST(Transport_Latency (ms) / SDU_Interval (us))
* with average data rate = 1 packet / SDU_Interval
*/
transport->num = ROUND_CLOSEST(qos->latency * 1000, qos->interval);
if (!transport->num)
transport->num = 1;
memset(&ts, 0, sizeof(ts));
ts.it_value.tv_nsec = 1;
ts.it_interval.tv_nsec = transport->num * qos->interval * 1000;
if (timerfd_settime(timer_fd, TFD_TIMER_ABSTIME, &ts, NULL) < 0) {
close(timer_fd);
return -errno;
}
transport->fd = fd;
transport->timer_io = io_new(timer_fd);
io_set_read_handler(transport->timer_io, transport_timer_read,
transport, NULL);
/* One extra packet to buffers immediately */
return transport_send_seq(transport, fd, 1);
}
static void cmd_send_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
struct transport *transport;
int fd = -1, err;
struct bt_iso_qos qos;
socklen_t len;
int i;
for (i = 1; i < argc; i++) {
proxy = g_dbus_proxy_lookup(transports, NULL, argv[i],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport = find_transport(proxy);
if (!transport) {
bt_shell_printf("Transport %s not acquired\n", argv[i]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (transport->sk < 0) {
bt_shell_printf("No Transport Socked found\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (i + 1 < argc) {
fd = open_file(argv[++i], O_RDONLY);
if (fd < 0)
return bt_shell_noninteractive_quit(
EXIT_FAILURE);
}
bt_shell_printf("Sending ...\n");
/* Read QoS if available */
memset(&qos, 0, sizeof(qos));
len = sizeof(qos);
if (getsockopt(transport->sk, SOL_BLUETOOTH, BT_ISO_QOS, &qos,
&len) < 0) {
bt_shell_printf("Unable to getsockopt(BT_ISO_QOS): %s",
strerror(errno));
err = transport_send(transport, fd, NULL);
} else {
struct sockaddr_iso addr;
socklen_t optlen = sizeof(addr);
err = getpeername(transport->sk,
(struct sockaddr *)&addr, &optlen);
if (!err) {
if (!(bacmp(&addr.iso_bdaddr, BDADDR_ANY)))
err = transport_send(transport, fd,
&qos.bcast.out);
else
err = transport_send(transport, fd,
&qos.ucast.out);
}
}
if (err < 0) {
bt_shell_printf("Unable to send: %s (%d)\n",
strerror(-err), -err);
close(fd);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_receive_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
struct transport *transport;
proxy = g_dbus_proxy_lookup(transports, NULL, argv[1],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport = find_transport(proxy);
if (!transport) {
bt_shell_printf("Transport %s not acquired\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (transport->sk < 0) {
bt_shell_printf("No Transport Socked found\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
transport_close(transport);
transport->fd = open_file(argv[2], O_RDWR | O_CREAT);
if (transport->fd < 0)
return bt_shell_noninteractive_quit(EXIT_FAILURE);
transport->filename = strdup(argv[2]);
bt_shell_printf("Filename: %s\n", transport->filename);
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void volume_callback(const DBusError *error, void *user_data)
{
if (dbus_error_is_set(error)) {
bt_shell_printf("Failed to set Volume: %s\n", error->name);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
bt_shell_printf("Changing Volume succeeded\n");
return bt_shell_noninteractive_quit(EXIT_SUCCESS);
}
static void cmd_volume_transport(int argc, char *argv[])
{
GDBusProxy *proxy;
char *endptr = NULL;
int volume;
proxy = g_dbus_proxy_lookup(transports, NULL, argv[1],
BLUEZ_MEDIA_TRANSPORT_INTERFACE);
if (!proxy) {
bt_shell_printf("Transport %s not found\n", argv[1]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (argc == 2) {
print_property(proxy, "Volume");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
volume = strtol(argv[2], &endptr, 0);
if (!endptr || *endptr != '\0' || volume > UINT16_MAX) {
bt_shell_printf("Invalid argument: %s\n", argv[2]);
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
if (!g_dbus_proxy_set_property_basic(proxy, "Volume", DBUS_TYPE_UINT16,
&volume, volume_callback,
NULL, NULL)) {
bt_shell_printf("Failed release transport\n");
return bt_shell_noninteractive_quit(EXIT_FAILURE);
}
}
static const struct bt_shell_menu transport_menu = {
.name = "transport",
.desc = "Media Transport Submenu",
.entries = {
{ "list", NULL, cmd_list_transport,
"List available transports" },
{ "show", "[transport]", cmd_show_transport,
"Transport information",
transport_generator },
{ "acquire", "<transport> [transport1...]", cmd_acquire_transport,
"Acquire Transport",
transport_generator },
{ "release", "<transport> [transport1...]", cmd_release_transport,
"Release Transport",
transport_generator },
{ "send", "<transport> <filename> [transport1...]",
cmd_send_transport,
"Send contents of a file",
transport_generator },
{ "receive", "<transport> [filename]", cmd_receive_transport,
"Get/Set file to receive",
transport_generator },
{ "volume", "<transport> [value]", cmd_volume_transport,
"Get/Set transport volume",
transport_generator },
{ "select", "<transport> [transport1...]", cmd_select_transport,
"Select Transport",
transport_generator },
{ "unselect", "<transport> [transport1...]", cmd_unselect_transport,
"Unselect Transport",
transport_generator },
{} },
};
static GDBusClient *client;
void player_add_submenu(void)
{
bt_shell_add_submenu(&player_menu);
bt_shell_add_submenu(&endpoint_menu);
bt_shell_add_submenu(&transport_menu);
dbus_conn = bt_shell_get_env("DBUS_CONNECTION");
if (!dbus_conn || client)
return;
client = g_dbus_client_new(dbus_conn, "org.bluez", "/org/bluez");
g_dbus_client_set_proxy_handlers(client, proxy_added, proxy_removed,
property_changed, NULL);
g_dbus_client_set_disconnect_watch(client, disconnect_handler, NULL);
}
void player_remove_submenu(void)
{
g_dbus_client_unref(client);
queue_destroy(ios, transport_free);
}