/***
This file is part of PulseAudio.
Copyright 2008 Lennart Poettering
Copyright 2009 Tanu Kaskinen
PulseAudio is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published
by the Free Software Foundation; either version 2.1 of the License,
or (at your option) any later version.
PulseAudio is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with PulseAudio; if not, see .
***/
#ifdef HAVE_CONFIG_H
#include
#endif
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#ifdef HAVE_DBUS
#include
#include
#endif
PA_MODULE_AUTHOR("Lennart Poettering");
PA_MODULE_DESCRIPTION("Automatically restore the volume/mute/device state of streams");
PA_MODULE_VERSION(PACKAGE_VERSION);
PA_MODULE_LOAD_ONCE(true);
PA_MODULE_USAGE(
"restore_device= "
"restore_volume= "
"restore_muted= "
"on_hotplug= "
"on_rescue= "
"fallback_table=");
#define SAVE_INTERVAL (10 * PA_USEC_PER_SEC)
#define IDENTIFICATION_PROPERTY "module-stream-restore.id"
#define DEFAULT_FALLBACK_FILE PA_DEFAULT_CONFIG_DIR"/stream-restore.table"
#define DEFAULT_FALLBACK_FILE_USER "stream-restore.table"
#define WHITESPACE "\n\r \t"
static const char* const valid_modargs[] = {
"restore_device",
"restore_volume",
"restore_muted",
"on_hotplug",
"on_rescue",
"fallback_table",
NULL
};
struct userdata {
pa_core *core;
pa_module *module;
pa_subscription *subscription;
pa_hook_slot
*sink_input_new_hook_slot,
*sink_input_fixate_hook_slot,
*source_output_new_hook_slot,
*source_output_fixate_hook_slot,
*connection_unlink_hook_slot;
pa_time_event *save_time_event;
pa_database* database;
bool restore_device:1;
bool restore_volume:1;
bool restore_muted:1;
pa_native_protocol *protocol;
pa_idxset *subscribed;
#ifdef HAVE_DBUS
pa_dbus_protocol *dbus_protocol;
pa_hashmap *dbus_entries;
uint32_t next_index; /* For generating object paths for entries. */
#endif
};
#define ENTRY_VERSION 2
struct entry {
bool muted_valid, volume_valid, device_valid, card_valid;
bool muted;
pa_channel_map channel_map;
pa_cvolume volume;
char* device;
char* card;
};
enum {
SUBCOMMAND_TEST,
SUBCOMMAND_READ,
SUBCOMMAND_WRITE,
SUBCOMMAND_DELETE,
SUBCOMMAND_SUBSCRIBE,
SUBCOMMAND_EVENT
};
static struct entry* entry_new(void);
static void entry_free(struct entry *e);
static struct entry *entry_read(struct userdata *u, const char *name);
static bool entry_write(struct userdata *u, const char *name, const struct entry *e, bool replace);
static struct entry* entry_copy(const struct entry *e);
static void entry_apply(struct userdata *u, const char *name, struct entry *e);
static void trigger_save(struct userdata *u);
#ifdef HAVE_DBUS
#define OBJECT_PATH "/org/pulseaudio/stream_restore1"
#define ENTRY_OBJECT_NAME "entry"
#define INTERFACE_STREAM_RESTORE "org.PulseAudio.Ext.StreamRestore1"
#define INTERFACE_ENTRY INTERFACE_STREAM_RESTORE ".RestoreEntry"
#define DBUS_INTERFACE_REVISION 0
struct dbus_entry {
struct userdata *userdata;
char *entry_name;
uint32_t index;
char *object_path;
};
static void handle_get_interface_revision(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_get_entries(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_get_all(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_add_entry(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_get_entry_by_name(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_get_index(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_get_name(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_get_device(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_set_device(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata);
static void handle_entry_get_volume(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_set_volume(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata);
static void handle_entry_get_mute(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_set_mute(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata);
static void handle_entry_get_all(DBusConnection *conn, DBusMessage *msg, void *userdata);
static void handle_entry_remove(DBusConnection *conn, DBusMessage *msg, void *userdata);
enum property_handler_index {
PROPERTY_HANDLER_INTERFACE_REVISION,
PROPERTY_HANDLER_ENTRIES,
PROPERTY_HANDLER_MAX
};
enum entry_property_handler_index {
ENTRY_PROPERTY_HANDLER_INDEX,
ENTRY_PROPERTY_HANDLER_NAME,
ENTRY_PROPERTY_HANDLER_DEVICE,
ENTRY_PROPERTY_HANDLER_VOLUME,
ENTRY_PROPERTY_HANDLER_MUTE,
ENTRY_PROPERTY_HANDLER_MAX
};
static pa_dbus_property_handler property_handlers[PROPERTY_HANDLER_MAX] = {
[PROPERTY_HANDLER_INTERFACE_REVISION] = { .property_name = "InterfaceRevision", .type = "u", .get_cb = handle_get_interface_revision, .set_cb = NULL },
[PROPERTY_HANDLER_ENTRIES] = { .property_name = "Entries", .type = "ao", .get_cb = handle_get_entries, .set_cb = NULL }
};
static pa_dbus_property_handler entry_property_handlers[ENTRY_PROPERTY_HANDLER_MAX] = {
[ENTRY_PROPERTY_HANDLER_INDEX] = { .property_name = "Index", .type = "u", .get_cb = handle_entry_get_index, .set_cb = NULL },
[ENTRY_PROPERTY_HANDLER_NAME] = { .property_name = "Name", .type = "s", .get_cb = handle_entry_get_name, .set_cb = NULL },
[ENTRY_PROPERTY_HANDLER_DEVICE] = { .property_name = "Device", .type = "s", .get_cb = handle_entry_get_device, .set_cb = handle_entry_set_device },
[ENTRY_PROPERTY_HANDLER_VOLUME] = { .property_name = "Volume", .type = "a(uu)", .get_cb = handle_entry_get_volume, .set_cb = handle_entry_set_volume },
[ENTRY_PROPERTY_HANDLER_MUTE] = { .property_name = "Mute", .type = "b", .get_cb = handle_entry_get_mute, .set_cb = handle_entry_set_mute }
};
enum method_handler_index {
METHOD_HANDLER_ADD_ENTRY,
METHOD_HANDLER_GET_ENTRY_BY_NAME,
METHOD_HANDLER_MAX
};
enum entry_method_handler_index {
ENTRY_METHOD_HANDLER_REMOVE,
ENTRY_METHOD_HANDLER_MAX
};
static pa_dbus_arg_info add_entry_args[] = { { "name", "s", "in" },
{ "device", "s", "in" },
{ "volume", "a(uu)", "in" },
{ "mute", "b", "in" },
{ "apply_immediately", "b", "in" },
{ "entry", "o", "out" } };
static pa_dbus_arg_info get_entry_by_name_args[] = { { "name", "s", "in" }, { "entry", "o", "out" } };
static pa_dbus_method_handler method_handlers[METHOD_HANDLER_MAX] = {
[METHOD_HANDLER_ADD_ENTRY] = {
.method_name = "AddEntry",
.arguments = add_entry_args,
.n_arguments = sizeof(add_entry_args) / sizeof(pa_dbus_arg_info),
.receive_cb = handle_add_entry },
[METHOD_HANDLER_GET_ENTRY_BY_NAME] = {
.method_name = "GetEntryByName",
.arguments = get_entry_by_name_args,
.n_arguments = sizeof(get_entry_by_name_args) / sizeof(pa_dbus_arg_info),
.receive_cb = handle_get_entry_by_name }
};
static pa_dbus_method_handler entry_method_handlers[ENTRY_METHOD_HANDLER_MAX] = {
[ENTRY_METHOD_HANDLER_REMOVE] = {
.method_name = "Remove",
.arguments = NULL,
.n_arguments = 0,
.receive_cb = handle_entry_remove }
};
enum signal_index {
SIGNAL_NEW_ENTRY,
SIGNAL_ENTRY_REMOVED,
SIGNAL_MAX
};
enum entry_signal_index {
ENTRY_SIGNAL_DEVICE_UPDATED,
ENTRY_SIGNAL_VOLUME_UPDATED,
ENTRY_SIGNAL_MUTE_UPDATED,
ENTRY_SIGNAL_MAX
};
static pa_dbus_arg_info new_entry_args[] = { { "entry", "o", NULL } };
static pa_dbus_arg_info entry_removed_args[] = { { "entry", "o", NULL } };
static pa_dbus_arg_info entry_device_updated_args[] = { { "device", "s", NULL } };
static pa_dbus_arg_info entry_volume_updated_args[] = { { "volume", "a(uu)", NULL } };
static pa_dbus_arg_info entry_mute_updated_args[] = { { "muted", "b", NULL } };
static pa_dbus_signal_info signals[SIGNAL_MAX] = {
[SIGNAL_NEW_ENTRY] = { .name = "NewEntry", .arguments = new_entry_args, .n_arguments = 1 },
[SIGNAL_ENTRY_REMOVED] = { .name = "EntryRemoved", .arguments = entry_removed_args, .n_arguments = 1 }
};
static pa_dbus_signal_info entry_signals[ENTRY_SIGNAL_MAX] = {
[ENTRY_SIGNAL_DEVICE_UPDATED] = { .name = "DeviceUpdated", .arguments = entry_device_updated_args, .n_arguments = 1 },
[ENTRY_SIGNAL_VOLUME_UPDATED] = { .name = "VolumeUpdated", .arguments = entry_volume_updated_args, .n_arguments = 1 },
[ENTRY_SIGNAL_MUTE_UPDATED] = { .name = "MuteUpdated", .arguments = entry_mute_updated_args, .n_arguments = 1 }
};
static pa_dbus_interface_info stream_restore_interface_info = {
.name = INTERFACE_STREAM_RESTORE,
.method_handlers = method_handlers,
.n_method_handlers = METHOD_HANDLER_MAX,
.property_handlers = property_handlers,
.n_property_handlers = PROPERTY_HANDLER_MAX,
.get_all_properties_cb = handle_get_all,
.signals = signals,
.n_signals = SIGNAL_MAX
};
static pa_dbus_interface_info entry_interface_info = {
.name = INTERFACE_ENTRY,
.method_handlers = entry_method_handlers,
.n_method_handlers = ENTRY_METHOD_HANDLER_MAX,
.property_handlers = entry_property_handlers,
.n_property_handlers = ENTRY_PROPERTY_HANDLER_MAX,
.get_all_properties_cb = handle_entry_get_all,
.signals = entry_signals,
.n_signals = ENTRY_SIGNAL_MAX
};
static struct dbus_entry *dbus_entry_new(struct userdata *u, const char *entry_name) {
struct dbus_entry *de;
pa_assert(u);
pa_assert(entry_name);
pa_assert(*entry_name);
de = pa_xnew(struct dbus_entry, 1);
de->userdata = u;
de->entry_name = pa_xstrdup(entry_name);
de->index = u->next_index++;
de->object_path = pa_sprintf_malloc("%s/%s%u", OBJECT_PATH, ENTRY_OBJECT_NAME, de->index);
pa_assert_se(pa_dbus_protocol_add_interface(u->dbus_protocol, de->object_path, &entry_interface_info, de) >= 0);
return de;
}
static void dbus_entry_free(struct dbus_entry *de) {
pa_assert(de);
pa_assert_se(pa_dbus_protocol_remove_interface(de->userdata->dbus_protocol, de->object_path, entry_interface_info.name) >= 0);
pa_xfree(de->entry_name);
pa_xfree(de->object_path);
pa_xfree(de);
}
/* Reads an array [(UInt32, UInt32)] from the iterator. The struct items are
* are a channel position and a volume value, respectively. The result is
* stored in the map and vol arguments. The iterator must point to a "a(uu)"
* element. If the data is invalid, an error reply is sent and a negative
* number is returned. In case of a failure we make no guarantees about the
* state of map and vol. In case of an empty array the channels field of both
* map and vol are set to 0. This function calls dbus_message_iter_next(iter)
* before returning. */
static int get_volume_arg(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, pa_channel_map *map, pa_cvolume *vol) {
DBusMessageIter array_iter;
DBusMessageIter struct_iter;
char *signature;
pa_assert(conn);
pa_assert(msg);
pa_assert(iter);
pa_assert(map);
pa_assert(vol);
pa_assert_se(signature = dbus_message_iter_get_signature(iter));
pa_assert(pa_streq(signature, "a(uu)"));
dbus_free(signature);
pa_channel_map_init(map);
pa_cvolume_init(vol);
map->channels = 0;
vol->channels = 0;
dbus_message_iter_recurse(iter, &array_iter);
while (dbus_message_iter_get_arg_type(&array_iter) != DBUS_TYPE_INVALID) {
dbus_uint32_t chan_pos;
dbus_uint32_t chan_vol;
dbus_message_iter_recurse(&array_iter, &struct_iter);
dbus_message_iter_get_basic(&struct_iter, &chan_pos);
if (chan_pos >= PA_CHANNEL_POSITION_MAX) {
pa_dbus_send_error(conn, msg, DBUS_ERROR_INVALID_ARGS, "Invalid channel position: %u", chan_pos);
return -1;
}
pa_assert_se(dbus_message_iter_next(&struct_iter));
dbus_message_iter_get_basic(&struct_iter, &chan_vol);
if (!PA_VOLUME_IS_VALID(chan_vol)) {
pa_dbus_send_error(conn, msg, DBUS_ERROR_INVALID_ARGS, "Invalid volume: %u", chan_vol);
return -1;
}
if (map->channels < PA_CHANNELS_MAX) {
map->map[map->channels] = chan_pos;
vol->values[map->channels] = chan_vol;
}
++map->channels;
++vol->channels;
dbus_message_iter_next(&array_iter);
}
if (map->channels > PA_CHANNELS_MAX) {
pa_dbus_send_error(conn, msg, DBUS_ERROR_INVALID_ARGS, "Too many channels: %u. The maximum is %u.", map->channels, PA_CHANNELS_MAX);
return -1;
}
dbus_message_iter_next(iter);
return 0;
}
static void append_volume(DBusMessageIter *iter, struct entry *e) {
DBusMessageIter array_iter;
DBusMessageIter struct_iter;
unsigned i;
pa_assert(iter);
pa_assert(e);
pa_assert_se(dbus_message_iter_open_container(iter, DBUS_TYPE_ARRAY, "(uu)", &array_iter));
if (!e->volume_valid) {
pa_assert_se(dbus_message_iter_close_container(iter, &array_iter));
return;
}
for (i = 0; i < e->channel_map.channels; ++i) {
pa_assert_se(dbus_message_iter_open_container(&array_iter, DBUS_TYPE_STRUCT, NULL, &struct_iter));
pa_assert_se(dbus_message_iter_append_basic(&struct_iter, DBUS_TYPE_UINT32, &e->channel_map.map[i]));
pa_assert_se(dbus_message_iter_append_basic(&struct_iter, DBUS_TYPE_UINT32, &e->volume.values[i]));
pa_assert_se(dbus_message_iter_close_container(&array_iter, &struct_iter));
}
pa_assert_se(dbus_message_iter_close_container(iter, &array_iter));
}
static void append_volume_variant(DBusMessageIter *iter, struct entry *e) {
DBusMessageIter variant_iter;
pa_assert(iter);
pa_assert(e);
pa_assert_se(dbus_message_iter_open_container(iter, DBUS_TYPE_VARIANT, "a(uu)", &variant_iter));
append_volume(&variant_iter, e);
pa_assert_se(dbus_message_iter_close_container(iter, &variant_iter));
}
static void send_new_entry_signal(struct dbus_entry *entry) {
DBusMessage *signal_msg;
pa_assert(entry);
pa_assert_se(signal_msg = dbus_message_new_signal(OBJECT_PATH, INTERFACE_STREAM_RESTORE, signals[SIGNAL_NEW_ENTRY].name));
pa_assert_se(dbus_message_append_args(signal_msg, DBUS_TYPE_OBJECT_PATH, &entry->object_path, DBUS_TYPE_INVALID));
pa_dbus_protocol_send_signal(entry->userdata->dbus_protocol, signal_msg);
dbus_message_unref(signal_msg);
}
static void send_entry_removed_signal(struct dbus_entry *entry) {
DBusMessage *signal_msg;
pa_assert(entry);
pa_assert_se(signal_msg = dbus_message_new_signal(OBJECT_PATH, INTERFACE_STREAM_RESTORE, signals[SIGNAL_ENTRY_REMOVED].name));
pa_assert_se(dbus_message_append_args(signal_msg, DBUS_TYPE_OBJECT_PATH, &entry->object_path, DBUS_TYPE_INVALID));
pa_dbus_protocol_send_signal(entry->userdata->dbus_protocol, signal_msg);
dbus_message_unref(signal_msg);
}
static void send_device_updated_signal(struct dbus_entry *de, struct entry *e) {
DBusMessage *signal_msg;
const char *device;
pa_assert(de);
pa_assert(e);
device = e->device_valid ? e->device : "";
pa_assert_se(signal_msg = dbus_message_new_signal(de->object_path, INTERFACE_ENTRY, entry_signals[ENTRY_SIGNAL_DEVICE_UPDATED].name));
pa_assert_se(dbus_message_append_args(signal_msg, DBUS_TYPE_STRING, &device, DBUS_TYPE_INVALID));
pa_dbus_protocol_send_signal(de->userdata->dbus_protocol, signal_msg);
dbus_message_unref(signal_msg);
}
static void send_volume_updated_signal(struct dbus_entry *de, struct entry *e) {
DBusMessage *signal_msg;
DBusMessageIter msg_iter;
pa_assert(de);
pa_assert(e);
pa_assert_se(signal_msg = dbus_message_new_signal(de->object_path, INTERFACE_ENTRY, entry_signals[ENTRY_SIGNAL_VOLUME_UPDATED].name));
dbus_message_iter_init_append(signal_msg, &msg_iter);
append_volume(&msg_iter, e);
pa_dbus_protocol_send_signal(de->userdata->dbus_protocol, signal_msg);
dbus_message_unref(signal_msg);
}
static void send_mute_updated_signal(struct dbus_entry *de, struct entry *e) {
DBusMessage *signal_msg;
dbus_bool_t muted;
pa_assert(de);
pa_assert(e);
pa_assert(e->muted_valid);
muted = e->muted;
pa_assert_se(signal_msg = dbus_message_new_signal(de->object_path, INTERFACE_ENTRY, entry_signals[ENTRY_SIGNAL_MUTE_UPDATED].name));
pa_assert_se(dbus_message_append_args(signal_msg, DBUS_TYPE_BOOLEAN, &muted, DBUS_TYPE_INVALID));
pa_dbus_protocol_send_signal(de->userdata->dbus_protocol, signal_msg);
dbus_message_unref(signal_msg);
}
static void handle_get_interface_revision(DBusConnection *conn, DBusMessage *msg, void *userdata) {
dbus_uint32_t interface_revision = DBUS_INTERFACE_REVISION;
pa_assert(conn);
pa_assert(msg);
pa_dbus_send_basic_variant_reply(conn, msg, DBUS_TYPE_UINT32, &interface_revision);
}
/* The caller frees the array, but not the strings. */
static const char **get_entries(struct userdata *u, unsigned *n) {
const char **entries;
unsigned i = 0;
void *state = NULL;
struct dbus_entry *de;
pa_assert(u);
pa_assert(n);
*n = pa_hashmap_size(u->dbus_entries);
if (*n == 0)
return NULL;
entries = pa_xnew(const char *, *n);
PA_HASHMAP_FOREACH(de, u->dbus_entries, state)
entries[i++] = de->object_path;
return entries;
}
static void handle_get_entries(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct userdata *u = userdata;
const char **entries;
unsigned n;
pa_assert(conn);
pa_assert(msg);
pa_assert(u);
entries = get_entries(u, &n);
pa_dbus_send_basic_array_variant_reply(conn, msg, DBUS_TYPE_OBJECT_PATH, entries, n);
pa_xfree(entries);
}
static void handle_get_all(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct userdata *u = userdata;
DBusMessage *reply = NULL;
DBusMessageIter msg_iter;
DBusMessageIter dict_iter;
dbus_uint32_t interface_revision;
const char **entries;
unsigned n_entries;
pa_assert(conn);
pa_assert(msg);
pa_assert(u);
interface_revision = DBUS_INTERFACE_REVISION;
entries = get_entries(u, &n_entries);
pa_assert_se((reply = dbus_message_new_method_return(msg)));
dbus_message_iter_init_append(reply, &msg_iter);
pa_assert_se(dbus_message_iter_open_container(&msg_iter, DBUS_TYPE_ARRAY, "{sv}", &dict_iter));
pa_dbus_append_basic_variant_dict_entry(&dict_iter, property_handlers[PROPERTY_HANDLER_INTERFACE_REVISION].property_name, DBUS_TYPE_UINT32, &interface_revision);
pa_dbus_append_basic_array_variant_dict_entry(&dict_iter, property_handlers[PROPERTY_HANDLER_ENTRIES].property_name, DBUS_TYPE_OBJECT_PATH, entries, n_entries);
pa_assert_se(dbus_message_iter_close_container(&msg_iter, &dict_iter));
pa_assert_se(dbus_connection_send(conn, reply, NULL));
dbus_message_unref(reply);
pa_xfree(entries);
}
static void handle_add_entry(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct userdata *u = userdata;
DBusMessageIter msg_iter;
const char *name = NULL;
const char *device = NULL;
pa_channel_map map;
pa_cvolume vol;
dbus_bool_t muted = FALSE;
dbus_bool_t apply_immediately = FALSE;
struct dbus_entry *dbus_entry = NULL;
struct entry *e = NULL;
pa_assert(conn);
pa_assert(msg);
pa_assert(u);
pa_assert_se(dbus_message_iter_init(msg, &msg_iter));
dbus_message_iter_get_basic(&msg_iter, &name);
pa_assert_se(dbus_message_iter_next(&msg_iter));
dbus_message_iter_get_basic(&msg_iter, &device);
pa_assert_se(dbus_message_iter_next(&msg_iter));
if (get_volume_arg(conn, msg, &msg_iter, &map, &vol) < 0)
return;
dbus_message_iter_get_basic(&msg_iter, &muted);
pa_assert_se(dbus_message_iter_next(&msg_iter));
dbus_message_iter_get_basic(&msg_iter, &apply_immediately);
if (!*name) {
pa_dbus_send_error(conn, msg, DBUS_ERROR_INVALID_ARGS, "An empty string was given as the entry name.");
return;
}
if ((dbus_entry = pa_hashmap_get(u->dbus_entries, name))) {
bool mute_updated = false;
bool volume_updated = false;
bool device_updated = false;
pa_assert_se(e = entry_read(u, name));
mute_updated = e->muted != muted;
e->muted = muted;
e->muted_valid = true;
volume_updated = (e->volume_valid != !!map.channels) || !pa_cvolume_equal(&e->volume, &vol);
e->volume = vol;
e->channel_map = map;
e->volume_valid = !!map.channels;
device_updated = (e->device_valid != !!device[0]) || !pa_safe_streq(e->device, device);
pa_xfree(e->device);
e->device = pa_xstrdup(device);
e->device_valid = !!device[0];
if (mute_updated)
send_mute_updated_signal(dbus_entry, e);
if (volume_updated)
send_volume_updated_signal(dbus_entry, e);
if (device_updated)
send_device_updated_signal(dbus_entry, e);
} else {
dbus_entry = dbus_entry_new(u, name);
pa_assert_se(pa_hashmap_put(u->dbus_entries, dbus_entry->entry_name, dbus_entry) == 0);
e = entry_new();
e->muted_valid = true;
e->volume_valid = !!map.channels;
e->device_valid = !!device[0];
e->muted = muted;
e->volume = vol;
e->channel_map = map;
e->device = pa_xstrdup(device);
send_new_entry_signal(dbus_entry);
}
pa_assert_se(entry_write(u, name, e, true));
if (apply_immediately)
entry_apply(u, name, e);
trigger_save(u);
pa_dbus_send_empty_reply(conn, msg);
entry_free(e);
}
static void handle_get_entry_by_name(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct userdata *u = userdata;
const char *name;
struct dbus_entry *de;
pa_assert(conn);
pa_assert(msg);
pa_assert(u);
pa_assert_se(dbus_message_get_args(msg, NULL, DBUS_TYPE_STRING, &name, DBUS_TYPE_INVALID));
if (!(de = pa_hashmap_get(u->dbus_entries, name))) {
pa_dbus_send_error(conn, msg, PA_DBUS_ERROR_NOT_FOUND, "No such stream restore entry.");
return;
}
pa_dbus_send_basic_value_reply(conn, msg, DBUS_TYPE_OBJECT_PATH, &de->object_path);
}
static void handle_entry_get_index(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_dbus_send_basic_variant_reply(conn, msg, DBUS_TYPE_UINT32, &de->index);
}
static void handle_entry_get_name(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_dbus_send_basic_variant_reply(conn, msg, DBUS_TYPE_STRING, &de->entry_name);
}
static void handle_entry_get_device(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
struct entry *e;
const char *device;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
device = e->device_valid ? e->device : "";
pa_dbus_send_basic_variant_reply(conn, msg, DBUS_TYPE_STRING, &device);
entry_free(e);
}
static void handle_entry_set_device(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata) {
struct dbus_entry *de = userdata;
const char *device;
struct entry *e;
bool updated;
pa_assert(conn);
pa_assert(msg);
pa_assert(iter);
pa_assert(de);
dbus_message_iter_get_basic(iter, &device);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
updated = (e->device_valid != !!device[0]) || !pa_safe_streq(e->device, device);
if (updated) {
pa_xfree(e->device);
e->device = pa_xstrdup(device);
e->device_valid = !!device[0];
pa_assert_se(entry_write(de->userdata, de->entry_name, e, true));
entry_apply(de->userdata, de->entry_name, e);
send_device_updated_signal(de, e);
trigger_save(de->userdata);
}
pa_dbus_send_empty_reply(conn, msg);
entry_free(e);
}
static void handle_entry_get_volume(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
DBusMessage *reply;
DBusMessageIter msg_iter;
struct entry *e;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
pa_assert_se(reply = dbus_message_new_method_return(msg));
dbus_message_iter_init_append(reply, &msg_iter);
append_volume_variant(&msg_iter, e);
pa_assert_se(dbus_connection_send(conn, reply, NULL));
entry_free(e);
}
static void handle_entry_set_volume(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata) {
struct dbus_entry *de = userdata;
pa_channel_map map;
pa_cvolume vol;
struct entry *e = NULL;
bool updated = false;
pa_assert(conn);
pa_assert(msg);
pa_assert(iter);
pa_assert(de);
if (get_volume_arg(conn, msg, iter, &map, &vol) < 0)
return;
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
updated = (e->volume_valid != !!map.channels) || !pa_cvolume_equal(&e->volume, &vol);
if (updated) {
e->volume = vol;
e->channel_map = map;
e->volume_valid = !!map.channels;
pa_assert_se(entry_write(de->userdata, de->entry_name, e, true));
entry_apply(de->userdata, de->entry_name, e);
send_volume_updated_signal(de, e);
trigger_save(de->userdata);
}
pa_dbus_send_empty_reply(conn, msg);
entry_free(e);
}
static void handle_entry_get_mute(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
struct entry *e;
dbus_bool_t mute;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
mute = e->muted_valid ? e->muted : FALSE;
pa_dbus_send_basic_variant_reply(conn, msg, DBUS_TYPE_BOOLEAN, &mute);
entry_free(e);
}
static void handle_entry_set_mute(DBusConnection *conn, DBusMessage *msg, DBusMessageIter *iter, void *userdata) {
struct dbus_entry *de = userdata;
dbus_bool_t mute;
struct entry *e;
bool updated;
pa_assert(conn);
pa_assert(msg);
pa_assert(iter);
pa_assert(de);
dbus_message_iter_get_basic(iter, &mute);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
updated = !e->muted_valid || e->muted != mute;
if (updated) {
e->muted = mute;
e->muted_valid = true;
pa_assert_se(entry_write(de->userdata, de->entry_name, e, true));
entry_apply(de->userdata, de->entry_name, e);
send_mute_updated_signal(de, e);
trigger_save(de->userdata);
}
pa_dbus_send_empty_reply(conn, msg);
entry_free(e);
}
static void handle_entry_get_all(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
struct entry *e;
DBusMessage *reply = NULL;
DBusMessageIter msg_iter;
DBusMessageIter dict_iter;
DBusMessageIter dict_entry_iter;
const char *device;
dbus_bool_t mute;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
pa_assert_se(e = entry_read(de->userdata, de->entry_name));
device = e->device_valid ? e->device : "";
mute = e->muted_valid ? e->muted : FALSE;
pa_assert_se((reply = dbus_message_new_method_return(msg)));
dbus_message_iter_init_append(reply, &msg_iter);
pa_assert_se(dbus_message_iter_open_container(&msg_iter, DBUS_TYPE_ARRAY, "{sv}", &dict_iter));
pa_dbus_append_basic_variant_dict_entry(&dict_iter, entry_property_handlers[ENTRY_PROPERTY_HANDLER_INDEX].property_name, DBUS_TYPE_UINT32, &de->index);
pa_dbus_append_basic_variant_dict_entry(&dict_iter, entry_property_handlers[ENTRY_PROPERTY_HANDLER_NAME].property_name, DBUS_TYPE_STRING, &de->entry_name);
pa_dbus_append_basic_variant_dict_entry(&dict_iter, entry_property_handlers[ENTRY_PROPERTY_HANDLER_DEVICE].property_name, DBUS_TYPE_STRING, &device);
pa_assert_se(dbus_message_iter_open_container(&dict_iter, DBUS_TYPE_DICT_ENTRY, NULL, &dict_entry_iter));
pa_assert_se(dbus_message_iter_append_basic(&dict_entry_iter, DBUS_TYPE_STRING, &entry_property_handlers[ENTRY_PROPERTY_HANDLER_VOLUME].property_name));
append_volume_variant(&dict_entry_iter, e);
pa_assert_se(dbus_message_iter_close_container(&dict_iter, &dict_entry_iter));
pa_dbus_append_basic_variant_dict_entry(&dict_iter, entry_property_handlers[ENTRY_PROPERTY_HANDLER_MUTE].property_name, DBUS_TYPE_BOOLEAN, &mute);
pa_assert_se(dbus_message_iter_close_container(&msg_iter, &dict_iter));
pa_assert_se(dbus_connection_send(conn, reply, NULL));
dbus_message_unref(reply);
entry_free(e);
}
static void handle_entry_remove(DBusConnection *conn, DBusMessage *msg, void *userdata) {
struct dbus_entry *de = userdata;
pa_datum key;
pa_assert(conn);
pa_assert(msg);
pa_assert(de);
key.data = de->entry_name;
key.size = strlen(de->entry_name);
pa_assert_se(pa_database_unset(de->userdata->database, &key) == 0);
send_entry_removed_signal(de);
trigger_save(de->userdata);
pa_assert_se(pa_hashmap_remove_and_free(de->userdata->dbus_entries, de->entry_name) >= 0);
pa_dbus_send_empty_reply(conn, msg);
}
#endif /* HAVE_DBUS */
static void save_time_callback(pa_mainloop_api*a, pa_time_event* e, const struct timeval *t, void *userdata) {
struct userdata *u = userdata;
pa_assert(a);
pa_assert(e);
pa_assert(u);
pa_assert(e == u->save_time_event);
u->core->mainloop->time_free(u->save_time_event);
u->save_time_event = NULL;
pa_database_sync(u->database);
pa_log_info("Synced.");
}
static struct entry* entry_new(void) {
struct entry *r = pa_xnew0(struct entry, 1);
return r;
}
static void entry_free(struct entry* e) {
pa_assert(e);
pa_xfree(e->device);
pa_xfree(e->card);
pa_xfree(e);
}
static bool entry_write(struct userdata *u, const char *name, const struct entry *e, bool replace) {
pa_tagstruct *t;
pa_datum key, data;
bool r;
pa_assert(u);
pa_assert(name);
pa_assert(e);
t = pa_tagstruct_new();
pa_tagstruct_putu8(t, ENTRY_VERSION);
pa_tagstruct_put_boolean(t, e->volume_valid);
pa_tagstruct_put_channel_map(t, &e->channel_map);
pa_tagstruct_put_cvolume(t, &e->volume);
pa_tagstruct_put_boolean(t, e->muted_valid);
pa_tagstruct_put_boolean(t, e->muted);
pa_tagstruct_put_boolean(t, e->device_valid);
pa_tagstruct_puts(t, e->device);
pa_tagstruct_put_boolean(t, e->card_valid);
pa_tagstruct_puts(t, e->card);
key.data = (char *) name;
key.size = strlen(name);
data.data = (void*)pa_tagstruct_data(t, &data.size);
r = (pa_database_set(u->database, &key, &data, replace) == 0);
pa_tagstruct_free(t);
return r;
}
#ifdef ENABLE_LEGACY_DATABASE_ENTRY_FORMAT
#define LEGACY_ENTRY_VERSION 3
static struct entry *legacy_entry_read(struct userdata *u, const char *name) {
struct legacy_entry {
uint8_t version;
bool muted_valid:1, volume_valid:1, device_valid:1, card_valid:1;
bool muted:1;
pa_channel_map channel_map;
pa_cvolume volume;
char device[PA_NAME_MAX];
char card[PA_NAME_MAX];
} PA_GCC_PACKED;
pa_datum key;
pa_datum data;
struct legacy_entry *le;
struct entry *e;
pa_channel_map channel_map;
pa_cvolume volume;
pa_assert(u);
pa_assert(name);
key.data = (char *) name;
key.size = strlen(name);
pa_zero(data);
if (!pa_database_get(u->database, &key, &data))
goto fail;
if (data.size != sizeof(struct legacy_entry)) {
pa_log_debug("Size does not match.");
goto fail;
}
le = (struct legacy_entry *) data.data;
if (le->version != LEGACY_ENTRY_VERSION) {
pa_log_debug("Version mismatch.");
goto fail;
}
if (!memchr(le->device, 0, sizeof(le->device))) {
pa_log_warn("Device has missing NUL byte.");
goto fail;
}
if (!memchr(le->card, 0, sizeof(le->card))) {
pa_log_warn("Card has missing NUL byte.");
goto fail;
}
if (le->device_valid && !pa_namereg_is_valid_name(le->device)) {
pa_log_warn("Invalid device name stored in database for legacy stream");
goto fail;
}
if (le->card_valid && !pa_namereg_is_valid_name(le->card)) {
pa_log_warn("Invalid card name stored in database for legacy stream");
goto fail;
}
/* Read these out before accessing contents via pointers as struct legacy_entry may not be adequately aligned for these
* members to be accessed directly */
channel_map = le->channel_map;
volume = le->volume;
if (le->volume_valid && !pa_channel_map_valid(&channel_map)) {
pa_log_warn("Invalid channel map stored in database for legacy stream");
goto fail;
}
if (le->volume_valid && (!pa_cvolume_valid(&volume) || !pa_cvolume_compatible_with_channel_map(&volume, &channel_map))) {
pa_log_warn("Invalid volume stored in database for legacy stream");
goto fail;
}
e = entry_new();
e->muted_valid = le->muted_valid;
e->muted = le->muted;
e->volume_valid = le->volume_valid;
e->channel_map = le->channel_map;
e->volume = le->volume;
e->device_valid = le->device_valid;
e->device = pa_xstrdup(le->device);
e->card_valid = le->card_valid;
e->card = pa_xstrdup(le->card);
return e;
fail:
pa_datum_free(&data);
return NULL;
}
#endif
static struct entry *entry_read(struct userdata *u, const char *name) {
pa_datum key, data;
struct entry *e = NULL;
pa_tagstruct *t = NULL;
uint8_t version;
const char *device, *card;
pa_assert(u);
pa_assert(name);
key.data = (char*) name;
key.size = strlen(name);
pa_zero(data);
if (!pa_database_get(u->database, &key, &data))
goto fail;
t = pa_tagstruct_new_fixed(data.data, data.size);
e = entry_new();
if (pa_tagstruct_getu8(t, &version) < 0 ||
version > ENTRY_VERSION ||
pa_tagstruct_get_boolean(t, &e->volume_valid) < 0 ||
pa_tagstruct_get_channel_map(t, &e->channel_map) < 0 ||
pa_tagstruct_get_cvolume(t, &e->volume) < 0 ||
pa_tagstruct_get_boolean(t, &e->muted_valid) < 0 ||
pa_tagstruct_get_boolean(t, &e->muted) < 0 ||
pa_tagstruct_get_boolean(t, &e->device_valid) < 0 ||
pa_tagstruct_gets(t, &device) < 0 ||
pa_tagstruct_get_boolean(t, &e->card_valid) < 0 ||
pa_tagstruct_gets(t, &card) < 0) {
goto fail;
}
e->device = pa_xstrdup(device);
e->card = pa_xstrdup(card);
if (!pa_tagstruct_eof(t))
goto fail;
if (e->device_valid && (!e->device || !pa_namereg_is_valid_name(e->device))) {
pa_log_warn("Invalid device name stored in database for stream %s", name);
goto fail;
}
if (e->card_valid && (!e->card || !pa_namereg_is_valid_name(e->card))) {
pa_log_warn("Invalid card name stored in database for stream %s", name);
goto fail;
}
if (e->volume_valid && !pa_channel_map_valid(&e->channel_map)) {
pa_log_warn("Invalid channel map stored in database for stream %s", name);
goto fail;
}
if (e->volume_valid && (!pa_cvolume_valid(&e->volume) || !pa_cvolume_compatible_with_channel_map(&e->volume, &e->channel_map))) {
pa_log_warn("Invalid volume stored in database for stream %s", name);
goto fail;
}
pa_tagstruct_free(t);
pa_datum_free(&data);
#ifdef STREAM_RESTORE_CLEAR_OLD_DEVICES
if (version < 2 && e->device_valid) {
/* Prior to PulseAudio 14.0, GNOME's sound settings overwrote the
* routing for all entries in the stream-restore database when
* selecting a device. PulseAudio 14.0 prevents that from happening,
* but the old overwritten settings can still be in the database after
* updating to PulseAudio 14.0, and they can cause problems, as
* documented here:
* https://gitlab.freedesktop.org/pulseaudio/pulseaudio/-/issues/832
*
* We can't distinguish between devices set by GNOME's sound settings
* and devices set by the user, so we discard all old device settings,
* even though that is going to cause PulseAudio to forget routing
* settings for many users. This is less bad than keeping the incorrect
* routing settings in the database, because it's difficult for users
* to figure out how to fix the situation when e.g. speaker test tones
* go to the internal speakers no matter what device is selected as the
* default, whereas old manual configuration can be restored restored
* by doing the manual configuration again. Also, it's probably more
* common to have at some point changed the default device in GNOME's
* sound settings than it is to have any manual per-stream routing
* settings. */
pa_log_warn("Device set, but it might be incorrect. Clearing the device. If this messes up your manual stream "
"routing configuration, sorry about that. This is a workaround for this bug: "
"https://gitlab.freedesktop.org/pulseaudio/pulseaudio/-/issues/832");
pa_log_warn("%s: device: %s -> (unset)", name, e->device);
pa_xfree(e->device);
e->device = NULL;
e->device_valid = false;
if (e->card_valid) {
pa_log_warn("%s: card: %s -> (unset)", name, e->card);
pa_xfree(e->card);
e->card = NULL;
e->card_valid = false;
}
entry_write(u, name, e, true);
trigger_save(u);
}
#endif
return e;
fail:
if (e)
entry_free(e);
if (t)
pa_tagstruct_free(t);
pa_datum_free(&data);
return NULL;
}
static struct entry* entry_copy(const struct entry *e) {
struct entry* r;
pa_assert(e);
r = entry_new();
*r = *e;
r->device = pa_xstrdup(e->device);
r->card = pa_xstrdup(e->card);
return r;
}
static void trigger_save(struct userdata *u) {
pa_native_connection *c;
uint32_t idx;
PA_IDXSET_FOREACH(c, u->subscribed, idx) {
pa_tagstruct *t;
t = pa_tagstruct_new();
pa_tagstruct_putu32(t, PA_COMMAND_EXTENSION);
pa_tagstruct_putu32(t, 0);
pa_tagstruct_putu32(t, u->module->index);
pa_tagstruct_puts(t, u->module->name);
pa_tagstruct_putu32(t, SUBCOMMAND_EVENT);
pa_pstream_send_tagstruct(pa_native_connection_get_pstream(c), t);
}
if (u->save_time_event)
return;
u->save_time_event = pa_core_rttime_new(u->core, pa_rtclock_now() + SAVE_INTERVAL, save_time_callback, u);
}
static bool entries_equal(const struct entry *a, const struct entry *b) {
pa_cvolume t;
pa_assert(a);
pa_assert(b);
if (a->device_valid != b->device_valid ||
(a->device_valid && !pa_streq(a->device, b->device)))
return false;
if (a->card_valid != b->card_valid ||
(a->card_valid && !pa_streq(a->card, b->card)))
return false;
if (a->muted_valid != b->muted_valid ||
(a->muted_valid && (a->muted != b->muted)))
return false;
t = b->volume;
if (a->volume_valid != b->volume_valid ||
(a->volume_valid && !pa_cvolume_equal(pa_cvolume_remap(&t, &b->channel_map, &a->channel_map), &a->volume)))
return false;
return true;
}
static void subscribe_callback(pa_core *c, pa_subscription_event_type_t t, uint32_t idx, void *userdata) {
struct userdata *u = userdata;
struct entry *entry, *old = NULL;
char *name = NULL;
/* These are only used when D-Bus is enabled, but in order to reduce ifdef
* clutter these are defined here unconditionally. */
bool created_new_entry = true;
bool volume_updated = false;
bool mute_updated = false;
#ifdef HAVE_DBUS
struct dbus_entry *de = NULL;
#endif
pa_assert(c);
pa_assert(u);
if (t != (PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_NEW) &&
t != (PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_CHANGE) &&
t != (PA_SUBSCRIPTION_EVENT_SOURCE_OUTPUT|PA_SUBSCRIPTION_EVENT_NEW) &&
t != (PA_SUBSCRIPTION_EVENT_SOURCE_OUTPUT|PA_SUBSCRIPTION_EVENT_CHANGE))
return;
if ((t & PA_SUBSCRIPTION_EVENT_FACILITY_MASK) == PA_SUBSCRIPTION_EVENT_SINK_INPUT) {
pa_sink_input *sink_input;
if (!(sink_input = pa_idxset_get_by_index(c->sink_inputs, idx)))
return;
/* Ignore this sink input if it is connecting a filter sink to
* the master */
if (sink_input->origin_sink)
return;
if (!(name = pa_proplist_get_stream_group(sink_input->proplist, "sink-input", IDENTIFICATION_PROPERTY)))
return;
if ((old = entry_read(u, name))) {
entry = entry_copy(old);
created_new_entry = false;
} else
entry = entry_new();
if (sink_input->save_volume && pa_sink_input_is_volume_readable(sink_input)) {
pa_assert(sink_input->volume_writable);
entry->channel_map = sink_input->channel_map;
pa_sink_input_get_volume(sink_input, &entry->volume, false);
entry->volume_valid = true;
volume_updated = !created_new_entry
&& (!old->volume_valid
|| !pa_channel_map_equal(&entry->channel_map, &old->channel_map)
|| !pa_cvolume_equal(&entry->volume, &old->volume));
}
if (sink_input->save_muted) {
entry->muted = sink_input->muted;
entry->muted_valid = true;
mute_updated = !created_new_entry && (!old->muted_valid || entry->muted != old->muted);
}
} else {
pa_source_output *source_output;
pa_assert((t & PA_SUBSCRIPTION_EVENT_FACILITY_MASK) == PA_SUBSCRIPTION_EVENT_SOURCE_OUTPUT);
if (!(source_output = pa_idxset_get_by_index(c->source_outputs, idx)))
return;
/* Ignore this source output if it is connecting a filter source to
* the master */
if (source_output->destination_source)
return;
if (!(name = pa_proplist_get_stream_group(source_output->proplist, "source-output", IDENTIFICATION_PROPERTY)))
return;
if ((old = entry_read(u, name))) {
entry = entry_copy(old);
created_new_entry = false;
} else
entry = entry_new();
if (source_output->save_volume && pa_source_output_is_volume_readable(source_output)) {
pa_assert(source_output->volume_writable);
entry->channel_map = source_output->channel_map;
pa_source_output_get_volume(source_output, &entry->volume, false);
entry->volume_valid = true;
volume_updated = !created_new_entry
&& (!old->volume_valid
|| !pa_channel_map_equal(&entry->channel_map, &old->channel_map)
|| !pa_cvolume_equal(&entry->volume, &old->volume));
}
if (source_output->save_muted) {
entry->muted = source_output->muted;
entry->muted_valid = true;
mute_updated = !created_new_entry && (!old->muted_valid || entry->muted != old->muted);
}
}
pa_assert(entry);
if (old) {
if (entries_equal(old, entry)) {
entry_free(old);
entry_free(entry);
pa_xfree(name);
return;
}
entry_free(old);
}
pa_log_info("Storing volume/mute for stream %s.", name);
if (entry_write(u, name, entry, true)) {
trigger_save(u);
} else {
pa_log_error("Could not store volume/mute for stream %s.", name);
}
#ifdef HAVE_DBUS
if (!(de = pa_hashmap_get(u->dbus_entries, name))) {
de = dbus_entry_new(u, name);
pa_assert_se(pa_hashmap_put(u->dbus_entries, de->entry_name, de) == 0);
send_new_entry_signal(de);
} else {
if (volume_updated)
send_volume_updated_signal(de, entry);
if (mute_updated)
send_mute_updated_signal(de, entry);
}
#else
/* Silence compiler warnings */
(void) volume_updated;
(void) mute_updated;
#endif
entry_free(entry);
pa_xfree(name);
}
static pa_hook_result_t sink_input_new_hook_callback(pa_core *c, pa_sink_input_new_data *new_data, struct userdata *u) {
char *name;
struct entry *e;
pa_assert(c);
pa_assert(new_data);
pa_assert(u);
pa_assert(u->restore_device);
if (!(name = pa_proplist_get_stream_group(new_data->proplist, "sink-input", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (new_data->sink)
pa_log_debug("Not restoring device for stream %s, because already set to '%s'.", name, new_data->sink->name);
else if (new_data->origin_sink)
pa_log_debug("Not restoring device for stream %s, because it connects a filter to the master sink.", name);
else if ((e = entry_read(u, name))) {
pa_sink *s = NULL;
if (e->device_valid) {
s = pa_namereg_get(c, e->device, PA_NAMEREG_SINK);
new_data->preferred_sink = pa_xstrdup(e->device);
}
if (!s && e->card_valid) {
pa_card *card;
if ((card = pa_namereg_get(c, e->card, PA_NAMEREG_CARD)))
s = pa_idxset_first(card->sinks, NULL);
}
/* It might happen that a stream and a sink are set up at the
same time, in which case we want to make sure we don't
interfere with that */
if (s && PA_SINK_IS_LINKED(s->state))
if (!s->active_port || s->active_port->available != PA_AVAILABLE_NO) {
if (pa_sink_input_new_data_set_sink(new_data, s, true, false))
pa_log_info("Restoring device for stream %s.", name);
}
entry_free(e);
}
pa_xfree(name);
return PA_HOOK_OK;
}
static pa_hook_result_t sink_input_fixate_hook_callback(pa_core *c, pa_sink_input_new_data *new_data, struct userdata *u) {
char *name;
struct entry *e;
pa_assert(c);
pa_assert(new_data);
pa_assert(u);
pa_assert(u->restore_volume || u->restore_muted);
if (!(name = pa_proplist_get_stream_group(new_data->proplist, "sink-input", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (new_data->origin_sink) {
pa_log_debug("Not restoring volume for sink input %s, because it connects a filter to the master sink.", name);
return PA_HOOK_OK;
}
if ((e = entry_read(u, name))) {
if (u->restore_volume && e->volume_valid) {
if (!new_data->volume_writable)
pa_log_debug("Not restoring volume for sink input %s, because its volume can't be changed.", name);
else if (new_data->volume_is_set)
pa_log_debug("Not restoring volume for sink input %s, because already set.", name);
else {
pa_cvolume v;
pa_log_info("Restoring volume for sink input %s.", name);
v = e->volume;
pa_cvolume_remap(&v, &e->channel_map, &new_data->channel_map);
pa_sink_input_new_data_set_volume(new_data, &v);
new_data->volume_is_absolute = false;
new_data->save_volume = true;
}
}
if (u->restore_muted && e->muted_valid) {
if (!new_data->muted_is_set) {
pa_log_info("Restoring mute state for sink input %s.", name);
pa_sink_input_new_data_set_muted(new_data, e->muted);
new_data->save_muted = true;
} else
pa_log_debug("Not restoring mute state for sink input %s, because already set.", name);
}
entry_free(e);
}
pa_xfree(name);
return PA_HOOK_OK;
}
static void update_preferred_device(struct userdata *u, const char *name, const char *device, const char *card) {
struct entry *old;
struct entry *entry;
#ifdef HAVE_DBUS
bool created_new_entry = false;
struct dbus_entry *de;
#endif
pa_assert(u);
pa_assert(name);
if ((old = entry_read(u, name)))
entry = entry_copy(old);
else {
entry = entry_new();
#ifdef HAVE_DBUS
created_new_entry = true;
#endif
}
pa_xfree(entry->device);
entry->device = pa_xstrdup(device);
entry->device_valid = !!device;
pa_xfree(entry->card);
entry->card = pa_xstrdup(card);
entry->card_valid = !!card;
pa_log_info("Storing device for stream %s.", name);
entry_write(u, name, entry, true);
trigger_save(u);
#if HAVE_DBUS
if (!(de = pa_hashmap_get(u->dbus_entries, name))) {
de = dbus_entry_new(u, name);
pa_assert_se(pa_hashmap_put(u->dbus_entries, de->entry_name, de) == 0);
send_new_entry_signal(de);
} else {
/* We send a D-Bus signal when the device changes, but not when the
* card changes. That's becaues the D-Bus interface doesn't expose the
* card field to clients at all. */
if (!created_new_entry && !pa_safe_streq(entry->device, old->device))
send_device_updated_signal(de, entry);
}
#endif
entry_free(entry);
if (old)
entry_free(old);
}
static pa_hook_result_t sink_input_preferred_sink_changed_cb(pa_core *c, pa_sink_input *sink_input, struct userdata *u) {
char *name;
pa_sink *sink;
const char *card_name = NULL;
pa_assert(c);
pa_assert(sink_input);
pa_assert(u);
if (!(name = pa_proplist_get_stream_group(sink_input->proplist, "sink-input", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (sink_input->preferred_sink && (sink = pa_namereg_get(c, sink_input->preferred_sink, PA_NAMEREG_SINK)) && sink->card)
card_name = sink->card->name;
update_preferred_device(u, name, sink_input->preferred_sink, card_name);
pa_xfree(name);
return PA_HOOK_OK;
}
static pa_hook_result_t source_output_new_hook_callback(pa_core *c, pa_source_output_new_data *new_data, struct userdata *u) {
char *name;
struct entry *e;
pa_assert(c);
pa_assert(new_data);
pa_assert(u);
pa_assert(u->restore_device);
if (new_data->direct_on_input)
return PA_HOOK_OK;
if (!(name = pa_proplist_get_stream_group(new_data->proplist, "source-output", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (new_data->source)
pa_log_debug("Not restoring device for stream %s, because already set", name);
else if (new_data->destination_source)
pa_log_debug("Not restoring device for stream %s, because it connects a filter to the master source.", name);
else if ((e = entry_read(u, name))) {
pa_source *s = NULL;
if (e->device_valid) {
s = pa_namereg_get(c, e->device, PA_NAMEREG_SOURCE);
new_data->preferred_source = pa_xstrdup(e->device);
}
if (!s && e->card_valid) {
pa_card *card;
if ((card = pa_namereg_get(c, e->card, PA_NAMEREG_CARD)))
s = pa_idxset_first(card->sources, NULL);
}
/* It might happen that a stream and a sink are set up at the
same time, in which case we want to make sure we don't
interfere with that */
if (s && PA_SOURCE_IS_LINKED(s->state)) {
if (!s->active_port || s->active_port->available != PA_AVAILABLE_NO) {
pa_log_info("Restoring device for stream %s.", name);
pa_source_output_new_data_set_source(new_data, s, true, false);
}
}
entry_free(e);
}
pa_xfree(name);
return PA_HOOK_OK;
}
static pa_hook_result_t source_output_fixate_hook_callback(pa_core *c, pa_source_output_new_data *new_data, struct userdata *u) {
char *name;
struct entry *e;
pa_assert(c);
pa_assert(new_data);
pa_assert(u);
pa_assert(u->restore_volume || u->restore_muted);
if (!(name = pa_proplist_get_stream_group(new_data->proplist, "source-output", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (new_data->destination_source) {
pa_log_debug("Not restoring volume for source output %s, because it connects a filter to the master source.", name);
return PA_HOOK_OK;
}
if ((e = entry_read(u, name))) {
if (u->restore_volume && e->volume_valid) {
if (!new_data->volume_writable)
pa_log_debug("Not restoring volume for source output %s, because its volume can't be changed.", name);
else if (new_data->volume_is_set)
pa_log_debug("Not restoring volume for source output %s, because already set.", name);
else {
pa_cvolume v;
pa_log_info("Restoring volume for source output %s.", name);
v = e->volume;
pa_cvolume_remap(&v, &e->channel_map, &new_data->channel_map);
pa_source_output_new_data_set_volume(new_data, &v);
new_data->volume_is_absolute = false;
new_data->save_volume = true;
}
}
if (u->restore_muted && e->muted_valid) {
if (!new_data->muted_is_set) {
pa_log_info("Restoring mute state for source output %s.", name);
pa_source_output_new_data_set_muted(new_data, e->muted);
new_data->save_muted = true;
} else
pa_log_debug("Not restoring mute state for source output %s, because already set.", name);
}
entry_free(e);
}
pa_xfree(name);
return PA_HOOK_OK;
}
static pa_hook_result_t source_output_preferred_source_changed_cb(pa_core *c, pa_source_output *source_output, struct userdata *u) {
char *name;
pa_source *source;
const char *card_name = NULL;
pa_assert(c);
pa_assert(source_output);
pa_assert(u);
if (!(name = pa_proplist_get_stream_group(source_output->proplist, "source-output", IDENTIFICATION_PROPERTY)))
return PA_HOOK_OK;
if (source_output->preferred_source && (source = pa_namereg_get(c, source_output->preferred_source, PA_NAMEREG_SOURCE)) && source->card)
card_name = source->card->name;
update_preferred_device(u, name, source_output->preferred_source, card_name);
pa_xfree(name);
return PA_HOOK_OK;
}
static int fill_db(struct userdata *u, const char *filename) {
FILE *f;
int n = 0;
int ret = -1;
char *fn = NULL;
pa_assert(u);
if (filename)
f = fopen(fn = pa_xstrdup(filename), "r");
else
f = pa_open_config_file(DEFAULT_FALLBACK_FILE, DEFAULT_FALLBACK_FILE_USER, NULL, &fn);
if (!f) {
if (filename)
pa_log("Failed to open %s: %s", filename, pa_cstrerror(errno));
else
ret = 0;
goto finish;
}
while (!feof(f)) {
char ln[256];
char *d, *v;
double db;
if (!fgets(ln, sizeof(ln), f))
break;
n++;
pa_strip_nl(ln);
if (!*ln || ln[0] == '#' || ln[0] == ';')
continue;
d = ln+strcspn(ln, WHITESPACE);
v = d+strspn(d, WHITESPACE);
if (!*v) {
pa_log("[%s:%u] failed to parse line - too few words", fn, n);
goto finish;
}
*d = 0;
if (pa_atod(v, &db) >= 0) {
if (db <= 0.0) {
struct entry e;
pa_zero(e);
e.volume_valid = true;
pa_cvolume_set(&e.volume, 1, pa_sw_volume_from_dB(db));
pa_channel_map_init_mono(&e.channel_map);
if (entry_write(u, ln, &e, false))
pa_log_debug("Setting %s to %0.2f dB.", ln, db);
} else
pa_log_warn("[%s:%u] Positive dB values are not allowed, not setting entry %s.", fn, n, ln);
} else
pa_log_warn("[%s:%u] Couldn't parse '%s' as a double, not setting entry %s.", fn, n, v, ln);
}
trigger_save(u);
ret = 0;
finish:
if (f)
fclose(f);
pa_xfree(fn);
return ret;
}
static void entry_apply(struct userdata *u, const char *name, struct entry *e) {
pa_sink_input *si;
pa_source_output *so;
uint32_t idx;
pa_assert(u);
pa_assert(name);
pa_assert(e);
PA_IDXSET_FOREACH(si, u->core->sink_inputs, idx) {
char *n;
pa_sink *s;
if (!(n = pa_proplist_get_stream_group(si->proplist, "sink-input", IDENTIFICATION_PROPERTY)))
continue;
if (!pa_streq(name, n)) {
pa_xfree(n);
continue;
}
pa_xfree(n);
if (u->restore_volume && e->volume_valid && si->volume_writable) {
pa_cvolume v;
v = e->volume;
pa_log_info("Restoring volume for sink input %s.", name);
pa_cvolume_remap(&v, &e->channel_map, &si->channel_map);
pa_sink_input_set_volume(si, &v, true, false);
}
if (u->restore_muted && e->muted_valid) {
pa_log_info("Restoring mute state for sink input %s.", name);
pa_sink_input_set_mute(si, e->muted, true);
}
if (u->restore_device) {
if (!e->device_valid) {
if (si->preferred_sink != NULL) {
pa_log_info("Ensuring device is not saved for stream %s.", name);
/* If the device is not valid we should make sure the
preferred_sink is cleared as the user may have specifically
removed the sink element from the rule. */
pa_sink_input_set_preferred_sink(si, NULL);
}
} else if ((s = pa_namereg_get(u->core, e->device, PA_NAMEREG_SINK))) {
pa_log_info("Restoring device for stream %s.", name);
pa_sink_input_set_preferred_sink(si, s);
}
}
}
PA_IDXSET_FOREACH(so, u->core->source_outputs, idx) {
char *n;
pa_source *s;
if (!(n = pa_proplist_get_stream_group(so->proplist, "source-output", IDENTIFICATION_PROPERTY)))
continue;
if (!pa_streq(name, n)) {
pa_xfree(n);
continue;
}
pa_xfree(n);
if (u->restore_volume && e->volume_valid && so->volume_writable) {
pa_cvolume v;
v = e->volume;
pa_log_info("Restoring volume for source output %s.", name);
pa_cvolume_remap(&v, &e->channel_map, &so->channel_map);
pa_source_output_set_volume(so, &v, true, false);
}
if (u->restore_muted && e->muted_valid) {
pa_log_info("Restoring mute state for source output %s.", name);
pa_source_output_set_mute(so, e->muted, true);
}
if (u->restore_device) {
if (!e->device_valid) {
if (so->preferred_source != NULL) {
pa_log_info("Ensuring device is not saved for stream %s.", name);
/* If the device is not valid we should make sure the
preferred_source is cleared as the user may have specifically
removed the source element from the rule. */
pa_source_output_set_preferred_source(so, NULL);
}
} else if ((s = pa_namereg_get(u->core, e->device, PA_NAMEREG_SOURCE))) {
pa_log_info("Restoring device for stream %s.", name);
pa_source_output_set_preferred_source(so, s);
}
}
}
}
#ifdef DEBUG_VOLUME
PA_GCC_UNUSED static void stream_restore_dump_database(struct userdata *u) {
pa_datum key;
bool done;
done = !pa_database_first(u->database, &key, NULL);
while (!done) {
pa_datum next_key;
struct entry *e;
char *name;
done = !pa_database_next(u->database, &key, &next_key, NULL);
name = pa_xstrndup(key.data, key.size);
pa_datum_free(&key);
if ((e = entry_read(u, name))) {
char t[256];
pa_log("name=%s", name);
pa_log("device=%s %s", e->device, pa_yes_no(e->device_valid));
pa_log("channel_map=%s", pa_channel_map_snprint(t, sizeof(t), &e->channel_map));
pa_log("volume=%s %s",
pa_cvolume_snprint_verbose(t, sizeof(t), &e->volume, &e->channel_map, true),
pa_yes_no(e->volume_valid));
pa_log("mute=%s %s", pa_yes_no(e->muted), pa_yes_no(e->volume_valid));
entry_free(e);
}
pa_xfree(name);
key = next_key;
}
}
#endif
#define EXT_VERSION 1
static int extension_cb(pa_native_protocol *p, pa_module *m, pa_native_connection *c, uint32_t tag, pa_tagstruct *t) {
struct userdata *u;
uint32_t command;
pa_tagstruct *reply = NULL;
pa_assert(p);
pa_assert(m);
pa_assert(c);
pa_assert(t);
u = m->userdata;
if (pa_tagstruct_getu32(t, &command) < 0)
goto fail;
reply = pa_tagstruct_new();
pa_tagstruct_putu32(reply, PA_COMMAND_REPLY);
pa_tagstruct_putu32(reply, tag);
switch (command) {
case SUBCOMMAND_TEST: {
if (!pa_tagstruct_eof(t))
goto fail;
pa_tagstruct_putu32(reply, EXT_VERSION);
break;
}
case SUBCOMMAND_READ: {
pa_datum key;
bool done;
if (!pa_tagstruct_eof(t))
goto fail;
done = !pa_database_first(u->database, &key, NULL);
while (!done) {
pa_datum next_key;
struct entry *e;
char *name;
done = !pa_database_next(u->database, &key, &next_key, NULL);
name = pa_xstrndup(key.data, key.size);
pa_datum_free(&key);
if ((e = entry_read(u, name))) {
pa_cvolume r;
pa_channel_map cm;
pa_tagstruct_puts(reply, name);
pa_tagstruct_put_channel_map(reply, e->volume_valid ? &e->channel_map : pa_channel_map_init(&cm));
pa_tagstruct_put_cvolume(reply, e->volume_valid ? &e->volume : pa_cvolume_init(&r));
pa_tagstruct_puts(reply, e->device_valid ? e->device : NULL);
pa_tagstruct_put_boolean(reply, e->muted_valid ? e->muted : false);
entry_free(e);
}
pa_xfree(name);
key = next_key;
}
break;
}
case SUBCOMMAND_WRITE: {
uint32_t mode;
bool apply_immediately = false;
if (pa_tagstruct_getu32(t, &mode) < 0 ||
pa_tagstruct_get_boolean(t, &apply_immediately) < 0)
goto fail;
if (mode != PA_UPDATE_MERGE &&
mode != PA_UPDATE_REPLACE &&
mode != PA_UPDATE_SET)
goto fail;
if (mode == PA_UPDATE_SET) {
#ifdef HAVE_DBUS
struct dbus_entry *de;
void *state = NULL;
PA_HASHMAP_FOREACH(de, u->dbus_entries, state) {
send_entry_removed_signal(de);
pa_hashmap_remove_and_free(u->dbus_entries, de->entry_name);
}
#endif
pa_database_clear(u->database);
}
while (!pa_tagstruct_eof(t)) {
const char *name, *device, *client_name;
bool muted;
struct entry *entry;
#ifdef HAVE_DBUS
struct entry *old;
#endif
entry = entry_new();
if (pa_tagstruct_gets(t, &name) < 0 ||
pa_tagstruct_get_channel_map(t, &entry->channel_map) ||
pa_tagstruct_get_cvolume(t, &entry->volume) < 0 ||
pa_tagstruct_gets(t, &device) < 0 ||
pa_tagstruct_get_boolean(t, &muted) < 0) {
entry_free(entry);
goto fail;
}
if (!name || !*name) {
entry_free(entry);
goto fail;
}
entry->volume_valid = entry->volume.channels > 0;
if (entry->volume_valid)
if (!pa_cvolume_compatible_with_channel_map(&entry->volume, &entry->channel_map)) {
entry_free(entry);
goto fail;
}
entry->muted = muted;
entry->muted_valid = true;
entry->device = pa_xstrdup(device);
entry->device_valid = device && !!entry->device[0];
if (entry->device_valid && !pa_namereg_is_valid_name(entry->device)) {
entry_free(entry);
goto fail;
}
/* When users select an output device from gnome-control-center, the gnome-control-center will change all entries
* in the database to bind the sink of this output device, this is not correct since at this moment, the sink is
* default_sink and we shouldn't bind a stream to default_sink via preferred_sink or database. This also applies
* to source, default_source and preferred_source.
* After gnome-control-center fix the issue, let us remove this code */
client_name = pa_strnull(pa_proplist_gets(pa_native_connection_get_client(c)->proplist, PA_PROP_APPLICATION_PROCESS_BINARY));
if (pa_safe_streq(client_name, "gnome-control-center")) {
if (entry->device_valid && ((m->core->default_sink && pa_safe_streq(device, m->core->default_sink->name)) ||
(m->core->default_source && pa_safe_streq(device, m->core->default_source->name)))) {
entry_free(entry);
pa_pstream_send_tagstruct(pa_native_connection_get_pstream(c), reply);
return 0;
}
}
#ifdef HAVE_DBUS
old = entry_read(u, name);
#endif
pa_log_debug("Client %s changes entry %s.",
pa_strnull(pa_proplist_gets(pa_native_connection_get_client(c)->proplist, PA_PROP_APPLICATION_PROCESS_BINARY)),
name);
if (entry_write(u, name, entry, mode == PA_UPDATE_REPLACE)) {
#ifdef HAVE_DBUS
struct dbus_entry *de;
if (old) {
pa_assert_se((de = pa_hashmap_get(u->dbus_entries, name)));
if ((old->device_valid != entry->device_valid)
|| (entry->device_valid && !pa_streq(entry->device, old->device)))
send_device_updated_signal(de, entry);
if ((old->volume_valid != entry->volume_valid)
|| (entry->volume_valid && (!pa_cvolume_equal(&entry->volume, &old->volume)
|| !pa_channel_map_equal(&entry->channel_map, &old->channel_map))))
send_volume_updated_signal(de, entry);
if (!old->muted_valid || (entry->muted != old->muted))
send_mute_updated_signal(de, entry);
} else {
de = dbus_entry_new(u, name);
pa_assert_se(pa_hashmap_put(u->dbus_entries, de->entry_name, de) == 0);
send_new_entry_signal(de);
}
#endif
if (apply_immediately)
entry_apply(u, name, entry);
}
#ifdef HAVE_DBUS
if (old)
entry_free(old);
#endif
entry_free(entry);
}
trigger_save(u);
break;
}
case SUBCOMMAND_DELETE:
while (!pa_tagstruct_eof(t)) {
const char *name;
pa_datum key;
#ifdef HAVE_DBUS
struct dbus_entry *de;
#endif
if (pa_tagstruct_gets(t, &name) < 0)
goto fail;
#ifdef HAVE_DBUS
if ((de = pa_hashmap_get(u->dbus_entries, name))) {
send_entry_removed_signal(de);
pa_hashmap_remove_and_free(u->dbus_entries, name);
}
#endif
key.data = (char*) name;
key.size = strlen(name);
pa_database_unset(u->database, &key);
}
trigger_save(u);
break;
case SUBCOMMAND_SUBSCRIBE: {
bool enabled;
if (pa_tagstruct_get_boolean(t, &enabled) < 0 ||
!pa_tagstruct_eof(t))
goto fail;
if (enabled)
pa_idxset_put(u->subscribed, c, NULL);
else
pa_idxset_remove_by_data(u->subscribed, c, NULL);
break;
}
default:
goto fail;
}
pa_pstream_send_tagstruct(pa_native_connection_get_pstream(c), reply);
return 0;
fail:
if (reply)
pa_tagstruct_free(reply);
return -1;
}
static pa_hook_result_t connection_unlink_hook_cb(pa_native_protocol *p, pa_native_connection *c, struct userdata *u) {
pa_assert(p);
pa_assert(c);
pa_assert(u);
pa_idxset_remove_by_data(u->subscribed, c, NULL);
return PA_HOOK_OK;
}
static void clean_up_db(struct userdata *u) {
struct clean_up_item {
PA_LLIST_FIELDS(struct clean_up_item);
char *entry_name;
struct entry *entry;
};
PA_LLIST_HEAD(struct clean_up_item, to_be_removed);
#ifdef ENABLE_LEGACY_DATABASE_ENTRY_FORMAT
PA_LLIST_HEAD(struct clean_up_item, to_be_converted);
#endif
bool done = false;
pa_datum key;
struct clean_up_item *item = NULL;
struct clean_up_item *next = NULL;
pa_assert(u);
/* It would be convenient to remove or replace the entries in the database
* in the same loop that iterates through the database, but modifying the
* database is not supported while iterating through it. That's why we
* collect the entries that need to be removed or replaced to these
* lists. */
PA_LLIST_HEAD_INIT(struct clean_up_item, to_be_removed);
#ifdef ENABLE_LEGACY_DATABASE_ENTRY_FORMAT
PA_LLIST_HEAD_INIT(struct clean_up_item, to_be_converted);
#endif
done = !pa_database_first(u->database, &key, NULL);
while (!done) {
pa_datum next_key;
char *entry_name = NULL;
struct entry *e = NULL;
entry_name = pa_xstrndup(key.data, key.size);
/* Use entry_read() to check whether this entry is valid. */
if (!(e = entry_read(u, entry_name))) {
item = pa_xnew0(struct clean_up_item, 1);
PA_LLIST_INIT(struct clean_up_item, item);
item->entry_name = entry_name;
#ifdef ENABLE_LEGACY_DATABASE_ENTRY_FORMAT
/* entry_read() failed, but what about legacy_entry_read()? */
if (!(e = legacy_entry_read(u, entry_name)))
/* Not a legacy entry either, let's remove this. */
PA_LLIST_PREPEND(struct clean_up_item, to_be_removed, item);
else {
/* Yay, it's valid after all! Now let's convert the entry to the current format. */
item->entry = e;
PA_LLIST_PREPEND(struct clean_up_item, to_be_converted, item);
}
#else
/* Invalid entry, let's remove this. */
PA_LLIST_PREPEND(struct clean_up_item, to_be_removed, item);
#endif
} else {
pa_xfree(entry_name);
entry_free(e);
}
done = !pa_database_next(u->database, &key, &next_key, NULL);
pa_datum_free(&key);
key = next_key;
}
PA_LLIST_FOREACH_SAFE(item, next, to_be_removed) {
key.data = item->entry_name;
key.size = strlen(item->entry_name);
pa_log_debug("Removing an invalid entry: %s", item->entry_name);
pa_assert_se(pa_database_unset(u->database, &key) >= 0);
trigger_save(u);
PA_LLIST_REMOVE(struct clean_up_item, to_be_removed, item);
pa_xfree(item->entry_name);
pa_xfree(item);
}
#ifdef ENABLE_LEGACY_DATABASE_ENTRY_FORMAT
PA_LLIST_FOREACH_SAFE(item, next, to_be_converted) {
pa_log_debug("Upgrading a legacy entry to the current format: %s", item->entry_name);
pa_assert_se(entry_write(u, item->entry_name, item->entry, true));
trigger_save(u);
PA_LLIST_REMOVE(struct clean_up_item, to_be_converted, item);
pa_xfree(item->entry_name);
entry_free(item->entry);
pa_xfree(item);
}
#endif
}
int pa__init(pa_module*m) {
pa_modargs *ma = NULL;
struct userdata *u;
char *state_path;
pa_sink_input *si;
pa_source_output *so;
uint32_t idx;
bool restore_device = true, restore_volume = true, restore_muted = true;
#ifdef HAVE_DBUS
pa_datum key;
bool done;
#endif
pa_assert(m);
if (!(ma = pa_modargs_new(m->argument, valid_modargs))) {
pa_log("Failed to parse module arguments");
goto fail;
}
if (pa_modargs_get_value_boolean(ma, "restore_device", &restore_device) < 0 ||
pa_modargs_get_value_boolean(ma, "restore_volume", &restore_volume) < 0 ||
pa_modargs_get_value_boolean(ma, "restore_muted", &restore_muted) < 0) {
pa_log("restore_device=, restore_volume= and restore_muted= expect boolean arguments");
goto fail;
}
if (pa_modargs_get_value(ma, "on_hotplug", NULL) != NULL ||
pa_modargs_get_value(ma, "on_rescue", NULL) != NULL)
pa_log("on_hotplug and on_rescue are obsolete arguments, please remove them from your configuration");
if (!restore_muted && !restore_volume && !restore_device)
pa_log_warn("Neither restoring volume, nor restoring muted, nor restoring device enabled!");
m->userdata = u = pa_xnew0(struct userdata, 1);
u->core = m->core;
u->module = m;
u->restore_device = restore_device;
u->restore_volume = restore_volume;
u->restore_muted = restore_muted;
u->subscribed = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func);
u->protocol = pa_native_protocol_get(m->core);
pa_native_protocol_install_ext(u->protocol, m, extension_cb);
pa_module_hook_connect(m, &pa_native_protocol_hooks(u->protocol)[PA_NATIVE_HOOK_CONNECTION_UNLINK], PA_HOOK_NORMAL, (pa_hook_cb_t) connection_unlink_hook_cb, u);
u->subscription = pa_subscription_new(m->core, PA_SUBSCRIPTION_MASK_SINK_INPUT|PA_SUBSCRIPTION_MASK_SOURCE_OUTPUT, subscribe_callback, u);
if (restore_device) {
/* A little bit earlier than module-intended-roles ... */
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_NEW], PA_HOOK_EARLY, (pa_hook_cb_t) sink_input_new_hook_callback, u);
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_NEW], PA_HOOK_EARLY, (pa_hook_cb_t) source_output_new_hook_callback, u);
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_PREFERRED_SINK_CHANGED], PA_HOOK_NORMAL,
(pa_hook_cb_t) sink_input_preferred_sink_changed_cb, u);
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_PREFERRED_SOURCE_CHANGED], PA_HOOK_NORMAL,
(pa_hook_cb_t) source_output_preferred_source_changed_cb, u);
}
if (restore_volume || restore_muted) {
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_FIXATE], PA_HOOK_EARLY, (pa_hook_cb_t) sink_input_fixate_hook_callback, u);
pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_FIXATE], PA_HOOK_EARLY, (pa_hook_cb_t) source_output_fixate_hook_callback, u);
}
if (!(state_path = pa_state_path(NULL, true)))
goto fail;
if (!(u->database = pa_database_open(state_path, "stream-volumes", true, true))) {
pa_xfree(state_path);
goto fail;
}
pa_xfree(state_path);
clean_up_db(u);
if (fill_db(u, pa_modargs_get_value(ma, "fallback_table", NULL)) < 0)
goto fail;
#ifdef HAVE_DBUS
u->dbus_protocol = pa_dbus_protocol_get(u->core);
u->dbus_entries = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) dbus_entry_free);
pa_assert_se(pa_dbus_protocol_add_interface(u->dbus_protocol, OBJECT_PATH, &stream_restore_interface_info, u) >= 0);
pa_assert_se(pa_dbus_protocol_register_extension(u->dbus_protocol, INTERFACE_STREAM_RESTORE) >= 0);
/* Create the initial dbus entries. */
done = !pa_database_first(u->database, &key, NULL);
while (!done) {
pa_datum next_key;
char *name;
struct dbus_entry *de;
name = pa_xstrndup(key.data, key.size);
de = dbus_entry_new(u, name);
pa_assert_se(pa_hashmap_put(u->dbus_entries, de->entry_name, de) == 0);
pa_xfree(name);
done = !pa_database_next(u->database, &key, &next_key, NULL);
pa_datum_free(&key);
key = next_key;
}
#endif
PA_IDXSET_FOREACH(si, m->core->sink_inputs, idx)
subscribe_callback(m->core, PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_NEW, si->index, u);
PA_IDXSET_FOREACH(so, m->core->source_outputs, idx)
subscribe_callback(m->core, PA_SUBSCRIPTION_EVENT_SOURCE_OUTPUT|PA_SUBSCRIPTION_EVENT_NEW, so->index, u);
pa_modargs_free(ma);
return 0;
fail:
pa__done(m);
if (ma)
pa_modargs_free(ma);
return -1;
}
void pa__done(pa_module*m) {
struct userdata* u;
pa_assert(m);
if (!(u = m->userdata))
return;
#ifdef HAVE_DBUS
if (u->dbus_protocol) {
pa_assert(u->dbus_entries);
pa_assert_se(pa_dbus_protocol_unregister_extension(u->dbus_protocol, INTERFACE_STREAM_RESTORE) >= 0);
pa_assert_se(pa_dbus_protocol_remove_interface(u->dbus_protocol, OBJECT_PATH, stream_restore_interface_info.name) >= 0);
pa_hashmap_free(u->dbus_entries);
pa_dbus_protocol_unref(u->dbus_protocol);
}
#endif
if (u->subscription)
pa_subscription_free(u->subscription);
if (u->save_time_event)
u->core->mainloop->time_free(u->save_time_event);
if (u->database)
pa_database_close(u->database);
if (u->protocol) {
pa_native_protocol_remove_ext(u->protocol, m);
pa_native_protocol_unref(u->protocol);
}
if (u->subscribed)
pa_idxset_free(u->subscribed, NULL);
pa_xfree(u);
}