#include "afs.h"
#include "net.h"
#include "server.h"
+#include "daemon.h"
#include "ipc.h"
#include "list.h"
#include "sched.h"
TBLNUM_AUDIO_FILES,
/** The table for the paraslash attributes. See \ref attribute.c. */
TBLNUM_ATTRIBUTES,
- /**
- * Paraslash's scoring system is based on Gaussian normal
- * distributions, and the relevant data is stored in the rbtrees of an
- * osl table containing only volatile columns. See \ref score.c for
- * details.
+ /*
+ * Moods and playlists organize the current set of admissible files in
+ * an osl table which contains only volatile columns. Each row consists
+ * of a pointer to an audio file and the score value of this file.
*/
TBLNUM_SCORES,
/**
extern uint32_t afs_socket_cookie;
/**
- * Struct to let command handlers execute a callback in afs context.
+ * Passed from command handlers to afs.
*
- * Commands that need to change the state of afs can't change the relevant data
- * structures directly because commands are executed in a child process, i.e.
- * they get their own virtual address space.
+ * Command handlers cannot change the afs database directly because they run in
+ * a separate process. The callback query structure circumvents this
+ * restriction as follows. To instruct the afs process to execute a particular
+ * function, the command hander writes an instance of this structure to a
+ * shared memory area, along with the arguments to the callback function. The
+ * identifier of the shared memory area is transferred to the afs process via
+ * the command socket.
*
- * This structure is used by \p send_callback_request() (executed from handler
- * context) in order to let the afs process call the specified function. An
- * instance of that structure is written to a shared memory area together with
- * the arguments to the callback function. The identifier of the shared memory
- * area is written to the command socket.
+ * The afs process reads the shared memory id from the command socket, attaches
+ * the corresponding area, and calls the callback function whose address is
+ * stored in the area.
*
- * The afs process accepts connections on the command socket and reads the
- * shared memory id, attaches the corresponding area, calls the given handler to
- * perform the desired action and to optionally compute a result.
- *
- * The result and a \p callback_result structure is then written to another
- * shared memory area. The identifier for that area is written to the handler's
- * command socket, so that the handler process can read the id, attach the
- * shared memory area and use the result.
+ * The command output, if any, is transferred back to the command handler in
+ * the same way: The afs process writes the output to a second shared memory
+ * area together with a fixed size metadata header whose format corresponds to
+ * the \ref callback_result structure. The identifier of this area is sent back
+ * to the command handler which attaches the area and forwards the output to
+ * the remote client.
*
* \sa \ref struct callback_result.
*/
if (num_admissible)
*num_admissible = ret;
current_play_mode = mode;
+ /*
+ * We get called with arg == current_mop from the signal dispatcher
+ * after SIGHUP and from the error path of the select command to
+ * re-select the current mood or playlist. In this case the assignment
+ * to current_mop below would result in a use-after-free condition.
+ */
if (arg != current_mop) {
free(current_mop);
if (arg) {
static void close_afs_tables(void)
{
int i;
- PARA_NOTICE_LOG("closing afs_tables\n");
+ PARA_NOTICE_LOG("closing afs tables\n");
for (i = 0; i < NUM_AFS_TABLES; i++)
afs_tables[i].close();
free(database_dir);
else {
char *home = para_homedir();
database_dir = make_message(
- "%s/.paraslash/afs_database-0.4", home);
+ "%s/.paraslash/afs_database-0.7", home);
free(home);
}
}
return ret;
}
-static int afs_signal_post_select(struct sched *s, __a_unused void *context)
+static int afs_signal_post_monitor(struct sched *s, __a_unused void *context)
{
int signum, ret;
PARA_EMERG_LOG("para_server died\n");
goto shutdown;
}
- signum = para_next_signal(&s->rfds);
+ signum = para_next_signal();
if (signum == 0)
return 0;
if (signum == SIGHUP) {
signal_task->task = task_register(&(struct task_info) {
.name = "signal",
- .pre_select = signal_pre_select,
- .post_select = afs_signal_post_select,
+ .pre_monitor = signal_pre_monitor,
+ .post_monitor = afs_signal_post_monitor,
.context = signal_task,
}, s);
struct timeval connect_time;
};
-static void command_pre_select(struct sched *s, void *context)
+static void command_pre_monitor(struct sched *s, void *context)
{
struct command_task *ct = context;
struct afs_client *client;
- para_fd_set(server_socket, &s->rfds, &s->max_fileno);
- para_fd_set(ct->fd, &s->rfds, &s->max_fileno);
+ sched_monitor_readfd(server_socket, s);
+ sched_monitor_readfd(ct->fd, s);
list_for_each_entry(client, &afs_client_list, node)
- para_fd_set(client->fd, &s->rfds, &s->max_fileno);
+ sched_monitor_readfd(client->fd, s);
}
/**
return ret;
}
-static int execute_server_command(fd_set *rfds)
+static int execute_server_command(void)
{
char buf[8];
size_t n;
- int ret = read_nonblock(server_socket, buf, sizeof(buf) - 1, rfds, &n);
+ int ret = read_nonblock(server_socket, buf, sizeof(buf) - 1, &n);
if (ret < 0 || n == 0)
return ret;
}
/* returns 0 if no data available, 1 else */
-static int execute_afs_command(int fd, fd_set *rfds)
+static int execute_afs_command(int fd)
{
uint32_t cookie;
int query_shmid;
char buf[sizeof(cookie) + sizeof(query_shmid)];
size_t n;
- int ret = read_nonblock(fd, buf, sizeof(buf), rfds, &n);
+ int ret = read_nonblock(fd, buf, sizeof(buf), &n);
if (ret < 0)
goto err;
/** Shutdown connection if query has not arrived until this many seconds. */
#define AFS_CLIENT_TIMEOUT 3
-static int command_post_select(struct sched *s, void *context)
+static int command_post_monitor(struct sched *s, void *context)
{
struct command_task *ct = context;
struct sockaddr_un unix_addr;
ret = task_get_notification(ct->task);
if (ret < 0)
return ret;
- ret = execute_server_command(&s->rfds);
+ ret = execute_server_command();
if (ret < 0) {
PARA_EMERG_LOG("%s\n", para_strerror(-ret));
task_notify_all(s, -ret);
}
/* Check the list of connected clients. */
list_for_each_entry_safe(client, tmp, &afs_client_list, node) {
- ret = execute_afs_command(client->fd, &s->rfds);
+ ret = execute_afs_command(client->fd);
if (ret == 0) { /* prevent bogus connection flooding */
struct timeval diff;
tv_diff(now, &client->connect_time, &diff);
free(client);
}
/* Accept connections on the local socket. */
- ret = para_accept(ct->fd, &s->rfds, &unix_addr, sizeof(unix_addr), &fd);
+ ret = para_accept(ct->fd, &unix_addr, sizeof(unix_addr), &fd);
if (ret < 0)
PARA_NOTICE_LOG("%s\n", para_strerror(-ret));
if (ret <= 0)
close(fd);
return 0;
}
- client = para_malloc(sizeof(*client));
+ client = alloc(sizeof(*client));
client->fd = fd;
client->connect_time = *now;
para_list_add(&client->node, &afs_client_list);
ct->task = task_register(&(struct task_info) {
.name = "afs command",
- .pre_select = command_pre_select,
- .post_select = command_post_select,
+ .pre_monitor = command_pre_monitor,
+ .post_monitor = command_post_monitor,
.context = ct,
}, s);
}
+static int afs_poll(struct pollfd *fds, nfds_t nfds, int timeout)
+{
+ mutex_lock(mmd_mutex);
+ daemon_set_loglevel(mmd->loglevel);
+ mutex_unlock(mmd_mutex);
+ return xpoll(fds, nfds, timeout);
+}
+
/**
* Initialize the audio file selector process.
*
int i, ret;
register_signal_task(&s);
- INIT_LIST_HEAD(&afs_client_list);
+ init_list_head(&afs_client_list);
for (i = 0; i < NUM_AFS_TABLES; i++)
afs_tables[i].init(&afs_tables[i]);
ret = open_afs_tables();
PARA_INFO_LOG("server_socket: %d\n", server_socket);
init_admissible_files(OPT_STRING_VAL(AFS_INITIAL_MODE));
register_command_task(&s);
- s.default_timeout.tv_sec = 0;
- s.default_timeout.tv_usec = 999 * 1000;
+ s.default_timeout = 1000;
+ s.poll_function = afs_poll;
ret = write(socket_fd, "\0", 1);
if (ret != 1) {
if (ret == 0)