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gerrit.omnirom.org / android_system_core / 8df4619e09b8944c1aa3b743b556a63a283d8768 / . / init / init.c
blob: 8c2a0582e4b8dd0d71d2f2fa53c7f53d15b57352 [file] [log] [blame]
/*
* Copyright (C) 2008 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <fcntl.h>
#include <ctype.h>
#include <signal.h>
#include <sys/wait.h>
#include <sys/mount.h>
#include <sys/stat.h>
#include <sys/poll.h>
#include <time.h>
#include <errno.h>
#include <stdarg.h>
#include <mtd/mtd-user.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <sys/un.h>
#include <sys/reboot.h>
#include <cutils/sockets.h>
#include <termios.h>
#include <linux/kd.h>
#include <linux/keychord.h>
#include <sys/system_properties.h>
#include "devices.h"
#include "init.h"
#include "property_service.h"
#include "bootchart.h"
static int property_triggers_enabled = 0;
#if BOOTCHART
static int bootchart_count;
#endif
static char console[32];
static char serialno[32];
static char bootmode[32];
static char baseband[32];
static char carrier[32];
static char bootloader[32];
static char hardware[32];
static unsigned revision = 0;
static char qemu[32];
static struct input_keychord *keychords = 0;
static int keychords_count = 0;
static int keychords_length = 0;
static void drain_action_queue(void);
static void notify_service_state(const char *name, const char *state)
{
char pname[PROP_NAME_MAX];
int len = strlen(name);
if ((len + 10) > PROP_NAME_MAX)
return;
snprintf(pname, sizeof(pname), "init.svc.%s", name);
property_set(pname, state);
}
static int have_console;
static char *console_name = "/dev/console";
static time_t process_needs_restart;
static const char *ENV[32];
/* add_environment - add "key=value" to the current environment */
int add_environment(const char *key, const char *val)
{
int n;
for (n = 0; n < 31; n++) {
if (!ENV[n]) {
size_t len = strlen(key) + strlen(val) + 2;
char *entry = malloc(len);
snprintf(entry, len, "%s=%s", key, val);
ENV[n] = entry;
return 0;
}
}
return 1;
}
static void zap_stdio(void)
{
int fd;
fd = open("/dev/null", O_RDWR);
dup2(fd, 0);
dup2(fd, 1);
dup2(fd, 2);
close(fd);
}
static void open_console()
{
int fd;
if ((fd = open(console_name, O_RDWR)) < 0) {
fd = open("/dev/null", O_RDWR);
}
dup2(fd, 0);
dup2(fd, 1);
dup2(fd, 2);
close(fd);
}
/*
* gettime() - returns the time in seconds of the system's monotonic clock or
* zero on error.
*/
static time_t gettime(void)
{
struct timespec ts;
int ret;
ret = clock_gettime(CLOCK_MONOTONIC, &ts);
if (ret < 0) {
ERROR("clock_gettime(CLOCK_MONOTONIC) failed: %s\n", strerror(errno));
return 0;
}
return ts.tv_sec;
}
static void publish_socket(const char *name, int fd)
{
char key[64] = ANDROID_SOCKET_ENV_PREFIX;
char val[64];
strlcpy(key + sizeof(ANDROID_SOCKET_ENV_PREFIX) - 1,
name,
sizeof(key) - sizeof(ANDROID_SOCKET_ENV_PREFIX));
snprintf(val, sizeof(val), "%d", fd);
add_environment(key, val);
/* make sure we don't close-on-exec */
fcntl(fd, F_SETFD, 0);
}
void service_start(struct service *svc, const char *dynamic_args)
{
struct stat s;
pid_t pid;
int needs_console;
int n;
/* starting a service removes it from the disabled
* state and immediately takes it out of the restarting
* state if it was in there
*/
svc->flags &= (~(SVC_DISABLED|SVC_RESTARTING));
svc->time_started = 0;
/* running processes require no additional work -- if
* they're in the process of exiting, we've ensured
* that they will immediately restart on exit, unless
* they are ONESHOT
*/
if (svc->flags & SVC_RUNNING) {
return;
}
needs_console = (svc->flags & SVC_CONSOLE) ? 1 : 0;
if (needs_console && (!have_console)) {
ERROR("service '%s' requires console\n", svc->name);
svc->flags |= SVC_DISABLED;
return;
}
if (stat(svc->args[0], &s) != 0) {
ERROR("cannot find '%s', disabling '%s'\n", svc->args[0], svc->name);
svc->flags |= SVC_DISABLED;
return;
}
if ((!(svc->flags & SVC_ONESHOT)) && dynamic_args) {
ERROR("service '%s' must be one-shot to use dynamic args, disabling\n",
svc->args[0]);
svc->flags |= SVC_DISABLED;
return;
}
NOTICE("starting '%s'\n", svc->name);
pid = fork();
if (pid == 0) {
struct socketinfo *si;
struct svcenvinfo *ei;
char tmp[32];
int fd, sz;
get_property_workspace(&fd, &sz);
sprintf(tmp, "%d,%d", dup(fd), sz);
add_environment("ANDROID_PROPERTY_WORKSPACE", tmp);
for (ei = svc->envvars; ei; ei = ei->next)
add_environment(ei->name, ei->value);
for (si = svc->sockets; si; si = si->next) {
int s = create_socket(si->name,
!strcmp(si->type, "dgram") ?
SOCK_DGRAM : SOCK_STREAM,
si->perm, si->uid, si->gid);
if (s >= 0) {
publish_socket(si->name, s);
}
}
if (needs_console) {
setsid();
open_console();
} else {
zap_stdio();
}
#if 0
for (n = 0; svc->args[n]; n++) {
INFO("args[%d] = '%s'\n", n, svc->args[n]);
}
for (n = 0; ENV[n]; n++) {
INFO("env[%d] = '%s'\n", n, ENV[n]);
}
#endif
setpgid(0, getpid());
/* as requested, set our gid, supplemental gids, and uid */
if (svc->gid) {
setgid(svc->gid);
}
if (svc->nr_supp_gids) {
setgroups(svc->nr_supp_gids, svc->supp_gids);
}
if (svc->uid) {
setuid(svc->uid);
}
if (!dynamic_args) {
if (execve(svc->args[0], (char**) svc->args, (char**) ENV) < 0) {
ERROR("cannot execve('%s'): %s\n", svc->args[0], strerror(errno));
}
} else {
char *arg_ptrs[SVC_MAXARGS+1];
int arg_idx = svc->nargs;
char *tmp = strdup(dynamic_args);
char *next = tmp;
char *bword;
/* Copy the static arguments */
memcpy(arg_ptrs, svc->args, (svc->nargs * sizeof(char *)));
while((bword = strsep(&next, " "))) {
arg_ptrs[arg_idx++] = bword;
if (arg_idx == SVC_MAXARGS)
break;
}
arg_ptrs[arg_idx] = '\0';
execve(svc->args[0], (char**) arg_ptrs, (char**) ENV);
}
_exit(127);
}
if (pid < 0) {
ERROR("failed to start '%s'\n", svc->name);
svc->pid = 0;
return;
}
svc->time_started = gettime();
svc->pid = pid;
svc->flags |= SVC_RUNNING;
notify_service_state(svc->name, "running");
}
void service_stop(struct service *svc)
{
/* we are no longer running, nor should we
* attempt to restart
*/
svc->flags &= (~(SVC_RUNNING|SVC_RESTARTING));
/* if the service has not yet started, prevent
* it from auto-starting with its class
*/
svc->flags |= SVC_DISABLED;
if (svc->pid) {
NOTICE("service '%s' is being killed\n", svc->name);
kill(-svc->pid, SIGTERM);
notify_service_state(svc->name, "stopping");
} else {
notify_service_state(svc->name, "stopped");
}
}
void property_changed(const char *name, const char *value)
{
if (property_triggers_enabled) {
queue_property_triggers(name, value);
drain_action_queue();
}
}
#define CRITICAL_CRASH_THRESHOLD 4 /* if we crash >4 times ... */
#define CRITICAL_CRASH_WINDOW (4*60) /* ... in 4 minutes, goto recovery*/
static int wait_for_one_process(int block)
{
pid_t pid;
int status;
struct service *svc;
struct socketinfo *si;
time_t now;
struct listnode *node;
struct command *cmd;
while ( (pid = waitpid(-1, &status, block ? 0 : WNOHANG)) == -1 && errno == EINTR );
if (pid <= 0) return -1;
INFO("waitpid returned pid %d, status = %08x\n", pid, status);
svc = service_find_by_pid(pid);
if (!svc) {
ERROR("untracked pid %d exited\n", pid);
return 0;
}
NOTICE("process '%s', pid %d exited\n", svc->name, pid);
if (!(svc->flags & SVC_ONESHOT)) {
kill(-pid, SIGKILL);
NOTICE("process '%s' killing any children in process group\n", svc->name);
}
/* remove any sockets we may have created */
for (si = svc->sockets; si; si = si->next) {
char tmp[128];
snprintf(tmp, sizeof(tmp), ANDROID_SOCKET_DIR"/%s", si->name);
unlink(tmp);
}
svc->pid = 0;
svc->flags &= (~SVC_RUNNING);
/* oneshot processes go into the disabled state on exit */
if (svc->flags & SVC_ONESHOT) {
svc->flags |= SVC_DISABLED;
}
/* disabled processes do not get restarted automatically */
if (svc->flags & SVC_DISABLED) {
notify_service_state(svc->name, "stopped");
return 0;
}
now = gettime();
if (svc->flags & SVC_CRITICAL) {
if (svc->time_crashed + CRITICAL_CRASH_WINDOW >= now) {
if (++svc->nr_crashed > CRITICAL_CRASH_THRESHOLD) {
ERROR("critical process '%s' exited %d times in %d minutes; "
"rebooting into recovery mode\n", svc->name,
CRITICAL_CRASH_THRESHOLD, CRITICAL_CRASH_WINDOW / 60);
sync();
__reboot(LINUX_REBOOT_MAGIC1, LINUX_REBOOT_MAGIC2,
LINUX_REBOOT_CMD_RESTART2, "recovery");
return 0;
}
} else {
svc->time_crashed = now;
svc->nr_crashed = 1;
}
}
/* Execute all onrestart commands for this service. */
list_for_each(node, &svc->onrestart.commands) {
cmd = node_to_item(node, struct command, clist);
cmd->func(cmd->nargs, cmd->args);
}
svc->flags |= SVC_RESTARTING;
notify_service_state(svc->name, "restarting");
return 0;
}
static void restart_service_if_needed(struct service *svc)
{
time_t next_start_time = svc->time_started + 5;
if (next_start_time <= gettime()) {
svc->flags &= (~SVC_RESTARTING);
service_start(svc, NULL);
return;
}
if ((next_start_time < process_needs_restart) ||
(process_needs_restart == 0)) {
process_needs_restart = next_start_time;
}
}
static void restart_processes()
{
process_needs_restart = 0;
service_for_each_flags(SVC_RESTARTING,
restart_service_if_needed);
}
static int signal_fd = -1;
static void sigchld_handler(int s)
{
write(signal_fd, &s, 1);
}
static void msg_start(const char *name)
{
struct service *svc;
char *tmp = NULL;
char *args = NULL;
if (!strchr(name, ':'))
svc = service_find_by_name(name);
else {
tmp = strdup(name);
args = strchr(tmp, ':');
*args = '\0';
args++;
svc = service_find_by_name(tmp);
}
if (svc) {
service_start(svc, args);
} else {
ERROR("no such service '%s'\n", name);
}
if (tmp)
free(tmp);
}
static void msg_stop(const char *name)
{
struct service *svc = service_find_by_name(name);
if (svc) {
service_stop(svc);
} else {
ERROR("no such service '%s'\n", name);
}
}
void handle_control_message(const char *msg, const char *arg)
{
if (!strcmp(msg,"start")) {
msg_start(arg);
} else if (!strcmp(msg,"stop")) {
msg_stop(arg);
} else {
ERROR("unknown control msg '%s'\n", msg);
}
}
#define MAX_MTD_PARTITIONS 16
static struct {
char name[16];
int number;
} mtd_part_map[MAX_MTD_PARTITIONS];
static int mtd_part_count = -1;
static void find_mtd_partitions(void)
{
int fd;
char buf[1024];
char *pmtdbufp;
ssize_t pmtdsize;
int r;
fd = open("/proc/mtd", O_RDONLY);
if (fd < 0)
return;
buf[sizeof(buf) - 1] = '\0';
pmtdsize = read(fd, buf, sizeof(buf) - 1);
pmtdbufp = buf;
while (pmtdsize > 0) {
int mtdnum, mtdsize, mtderasesize;
char mtdname[16];
mtdname[0] = '\0';
mtdnum = -1;
r = sscanf(pmtdbufp, "mtd%d: %x %x %15s",
&mtdnum, &mtdsize, &mtderasesize, mtdname);
if ((r == 4) && (mtdname[0] == '"')) {
char *x = strchr(mtdname + 1, '"');
if (x) {
*x = 0;
}
INFO("mtd partition %d, %s\n", mtdnum, mtdname + 1);
if (mtd_part_count < MAX_MTD_PARTITIONS) {
strcpy(mtd_part_map[mtd_part_count].name, mtdname + 1);
mtd_part_map[mtd_part_count].number = mtdnum;
mtd_part_count++;
} else {
ERROR("too many mtd partitions\n");
}
}
while (pmtdsize > 0 && *pmtdbufp != '\n') {
pmtdbufp++;
pmtdsize--;
}
if (pmtdsize > 0) {
pmtdbufp++;
pmtdsize--;
}
}
close(fd);
}
int mtd_name_to_number(const char *name)
{
int n;
if (mtd_part_count < 0) {
mtd_part_count = 0;
find_mtd_partitions();
}
for (n = 0; n < mtd_part_count; n++) {
if (!strcmp(name, mtd_part_map[n].name)) {
return mtd_part_map[n].number;
}
}
return -1;
}
static void import_kernel_nv(char *name, int in_qemu)
{
char *value = strchr(name, '=');
if (value == 0) return;
*value++ = 0;
if (*name == 0) return;
if (!in_qemu)
{
/* on a real device, white-list the kernel options */
if (!strcmp(name,"qemu")) {
strlcpy(qemu, value, sizeof(qemu));
} else if (!strcmp(name,"androidboot.console")) {
strlcpy(console, value, sizeof(console));
} else if (!strcmp(name,"androidboot.mode")) {
strlcpy(bootmode, value, sizeof(bootmode));
} else if (!strcmp(name,"androidboot.serialno")) {
strlcpy(serialno, value, sizeof(serialno));
} else if (!strcmp(name,"androidboot.baseband")) {
strlcpy(baseband, value, sizeof(baseband));
} else if (!strcmp(name,"androidboot.carrier")) {
strlcpy(carrier, value, sizeof(carrier));
} else if (!strcmp(name,"androidboot.bootloader")) {
strlcpy(bootloader, value, sizeof(bootloader));
} else if (!strcmp(name,"androidboot.hardware")) {
strlcpy(hardware, value, sizeof(hardware));
} else {
qemu_cmdline(name, value);
}
} else {
/* in the emulator, export any kernel option with the
* ro.kernel. prefix */
char buff[32];
int len = snprintf( buff, sizeof(buff), "ro.kernel.%s", name );
if (len < (int)sizeof(buff)) {
property_set( buff, value );
}
}
}
static void import_kernel_cmdline(int in_qemu)
{
char cmdline[1024];
char *ptr;
int fd;
fd = open("/proc/cmdline", O_RDONLY);
if (fd >= 0) {
int n = read(fd, cmdline, 1023);
if (n < 0) n = 0;
/* get rid of trailing newline, it happens */
if (n > 0 && cmdline[n-1] == '\n') n--;
cmdline[n] = 0;
close(fd);
} else {
cmdline[0] = 0;
}
ptr = cmdline;
while (ptr && *ptr) {
char *x = strchr(ptr, ' ');
if (x != 0) *x++ = 0;
import_kernel_nv(ptr, in_qemu);
ptr = x;
}
/* don't expose the raw commandline to nonpriv processes */
chmod("/proc/cmdline", 0440);
}
static void get_hardware_name(void)
{
char data[1024];
int fd, n;
char *x, *hw, *rev;
/* Hardware string was provided on kernel command line */
if (hardware[0])
return;
fd = open("/proc/cpuinfo", O_RDONLY);
if (fd < 0) return;
n = read(fd, data, 1023);
close(fd);
if (n < 0) return;
data[n] = 0;
hw = strstr(data, "\nHardware");
rev = strstr(data, "\nRevision");
if (hw) {
x = strstr(hw, ": ");
if (x) {
x += 2;
n = 0;
while (*x && !isspace(*x)) {
hardware[n++] = tolower(*x);
x++;
if (n == 31) break;
}
hardware[n] = 0;
}
}
if (rev) {
x = strstr(rev, ": ");
if (x) {
revision = strtoul(x + 2, 0, 16);
}
}
}
static void drain_action_queue(void)
{
struct listnode *node;
struct command *cmd;
struct action *act;
int ret;
while ((act = action_remove_queue_head())) {
INFO("processing action %p (%s)\n", act, act->name);
list_for_each(node, &act->commands) {
cmd = node_to_item(node, struct command, clist);
ret = cmd->func(cmd->nargs, cmd->args);
INFO("command '%s' r=%d\n", cmd->args[0], ret);
}
}
}
void open_devnull_stdio(void)
{
int fd;
static const char *name = "/dev/__null__";
if (mknod(name, S_IFCHR | 0600, (1 << 8) | 3) == 0) {
fd = open(name, O_RDWR);
unlink(name);
if (fd >= 0) {
dup2(fd, 0);
dup2(fd, 1);
dup2(fd, 2);
if (fd > 2) {
close(fd);
}
return;
}
}
exit(1);
}
void add_service_keycodes(struct service *svc)
{
struct input_keychord *keychord;
int i, size;
if (svc->keycodes) {
/* add a new keychord to the list */
size = sizeof(*keychord) + svc->nkeycodes * sizeof(keychord->keycodes[0]);
keychords = realloc(keychords, keychords_length + size);
if (!keychords) {
ERROR("could not allocate keychords\n");
keychords_length = 0;
keychords_count = 0;
return;
}
keychord = (struct input_keychord *)((char *)keychords + keychords_length);
keychord->version = KEYCHORD_VERSION;
keychord->id = keychords_count + 1;
keychord->count = svc->nkeycodes;
svc->keychord_id = keychord->id;
for (i = 0; i < svc->nkeycodes; i++) {
keychord->keycodes[i] = svc->keycodes[i];
}
keychords_count++;
keychords_length += size;
}
}
int open_keychord()
{
int fd, ret;
service_for_each(add_service_keycodes);
/* nothing to do if no services require keychords */
if (!keychords)
return -1;
fd = open("/dev/keychord", O_RDWR);
if (fd < 0) {
ERROR("could not open /dev/keychord\n");
return fd;
}
fcntl(fd, F_SETFD, FD_CLOEXEC);
ret = write(fd, keychords, keychords_length);
if (ret != keychords_length) {
ERROR("could not configure /dev/keychord %d (%d)\n", ret, errno);
close(fd);
fd = -1;
}
free(keychords);
keychords = 0;
return fd;
}
void handle_keychord(int fd)
{
struct service *svc;
int ret;
__u16 id;
ret = read(fd, &id, sizeof(id));
if (ret != sizeof(id)) {
ERROR("could not read keychord id\n");
return;
}
svc = service_find_by_keychord(id);
if (svc) {
INFO("starting service %s from keychord\n", svc->name);
service_start(svc, NULL);
} else {
ERROR("service for keychord %d not found\n", id);
}
}
int main(int argc, char **argv)
{
int device_fd = -1;
int property_set_fd = -1;
int signal_recv_fd = -1;
int keychord_fd = -1;
int fd_count;
int s[2];
int fd;
struct sigaction act;
char tmp[PROP_VALUE_MAX];
struct pollfd ufds[4];
char *tmpdev;
char* debuggable;
act.sa_handler = sigchld_handler;
act.sa_flags = SA_NOCLDSTOP;
act.sa_mask = 0;
act.sa_restorer = NULL;
sigaction(SIGCHLD, &act, 0);
/* clear the umask */
umask(0);
/* Get the basic filesystem setup we need put
* together in the initramdisk on / and then we'll
* let the rc file figure out the rest.
*/
mkdir("/dev", 0755);
mkdir("/proc", 0755);
mkdir("/sys", 0755);
mount("tmpfs", "/dev", "tmpfs", 0, "mode=0755");
mkdir("/dev/pts", 0755);
mkdir("/dev/socket", 0755);
mount("devpts", "/dev/pts", "devpts", 0, NULL);
mount("proc", "/proc", "proc", 0, NULL);
mount("sysfs", "/sys", "sysfs", 0, NULL);
/* We must have some place other than / to create the
* device nodes for kmsg and null, otherwise we won't
* be able to remount / read-only later on.
* Now that tmpfs is mounted on /dev, we can actually
* talk to the outside world.
*/
open_devnull_stdio();
log_init();
INFO("reading config file\n");
parse_config_file("/init.rc");
/* pull the kernel commandline and ramdisk properties file in */
qemu_init();
import_kernel_cmdline(0);
get_hardware_name();
snprintf(tmp, sizeof(tmp), "/init.%s.rc", hardware);
parse_config_file(tmp);
action_for_each_trigger("early-init", action_add_queue_tail);
drain_action_queue();
INFO("device init\n");
device_fd = device_init();
property_init();
// only listen for keychords if ro.debuggable is true
debuggable = property_get("ro.debuggable");
if (debuggable && !strcmp(debuggable, "1")) {
keychord_fd = open_keychord();
}
if (console[0]) {
snprintf(tmp, sizeof(tmp), "/dev/%s", console);
console_name = strdup(tmp);
}
fd = open(console_name, O_RDWR);
if (fd >= 0)
have_console = 1;
close(fd);
if( load_565rle_image(INIT_IMAGE_FILE) ) {
fd = open("/dev/tty0", O_WRONLY);
if (fd >= 0) {
const char *msg;
msg = "\n"
"\n"
"\n"
"\n"
"\n"
"\n"
"\n" // console is 40 cols x 30 lines
"\n"
"\n"
"\n"
"\n"
"\n"
"\n"
"\n"
" A N D R O I D ";
write(fd, msg, strlen(msg));
close(fd);
}
}
if (qemu[0])
import_kernel_cmdline(1);
if (!strcmp(bootmode,"factory"))
property_set("ro.factorytest", "1");
else if (!strcmp(bootmode,"factory2"))
property_set("ro.factorytest", "2");
else
property_set("ro.factorytest", "0");
property_set("ro.serialno", serialno[0] ? serialno : "");
property_set("ro.bootmode", bootmode[0] ? bootmode : "unknown");
property_set("ro.baseband", baseband[0] ? baseband : "unknown");
property_set("ro.carrier", carrier[0] ? carrier : "unknown");
property_set("ro.bootloader", bootloader[0] ? bootloader : "unknown");
property_set("ro.hardware", hardware);
snprintf(tmp, PROP_VALUE_MAX, "%d", revision);
property_set("ro.revision", tmp);
/* execute all the boot actions to get us started */
action_for_each_trigger("init", action_add_queue_tail);
drain_action_queue();
/* read any property files on system or data and
* fire up the property service. This must happen
* after the ro.foo properties are set above so
* that /data/local.prop cannot interfere with them.
*/
property_set_fd = start_property_service();
/* create a signalling mechanism for the sigchld handler */
if (socketpair(AF_UNIX, SOCK_STREAM, 0, s) == 0) {
signal_fd = s[0];
signal_recv_fd = s[1];
fcntl(s[0], F_SETFD, FD_CLOEXEC);
fcntl(s[0], F_SETFL, O_NONBLOCK);
fcntl(s[1], F_SETFD, FD_CLOEXEC);
fcntl(s[1], F_SETFL, O_NONBLOCK);
}
/* make sure we actually have all the pieces we need */
if ((device_fd < 0) ||
(property_set_fd < 0) ||
(signal_recv_fd < 0)) {
ERROR("init startup failure\n");
return 1;
}
/* execute all the boot actions to get us started */
action_for_each_trigger("early-boot", action_add_queue_tail);
action_for_each_trigger("boot", action_add_queue_tail);
drain_action_queue();
/* run all property triggers based on current state of the properties */
queue_all_property_triggers();
drain_action_queue();
/* enable property triggers */
property_triggers_enabled = 1;
ufds[0].fd = device_fd;
ufds[0].events = POLLIN;
ufds[1].fd = property_set_fd;
ufds[1].events = POLLIN;
ufds[2].fd = signal_recv_fd;
ufds[2].events = POLLIN;
fd_count = 3;
if (keychord_fd > 0) {
ufds[3].fd = keychord_fd;
ufds[3].events = POLLIN;
fd_count++;
} else {
ufds[3].events = 0;
ufds[3].revents = 0;
}
#if BOOTCHART
bootchart_count = bootchart_init();
if (bootchart_count < 0) {
ERROR("bootcharting init failure\n");
} else if (bootchart_count > 0) {
NOTICE("bootcharting started (period=%d ms)\n", bootchart_count*BOOTCHART_POLLING_MS);
} else {
NOTICE("bootcharting ignored\n");
}
#endif
for(;;) {
int nr, i, timeout = -1;
for (i = 0; i < fd_count; i++)
ufds[i].revents = 0;
drain_action_queue();
restart_processes();
if (process_needs_restart) {
timeout = (process_needs_restart - gettime()) * 1000;
if (timeout < 0)
timeout = 0;
}
#if BOOTCHART
if (bootchart_count > 0) {
if (timeout < 0 || timeout > BOOTCHART_POLLING_MS)
timeout = BOOTCHART_POLLING_MS;
if (bootchart_step() < 0 || --bootchart_count == 0) {
bootchart_finish();
bootchart_count = 0;
}
}
#endif
nr = poll(ufds, fd_count, timeout);
if (nr <= 0)
continue;
if (ufds[2].revents == POLLIN) {
/* we got a SIGCHLD - reap and restart as needed */
read(signal_recv_fd, tmp, sizeof(tmp));
while (!wait_for_one_process(0))
;
continue;
}
if (ufds[0].revents == POLLIN)
handle_device_fd(device_fd);
if (ufds[1].revents == POLLIN)
handle_property_set_fd(property_set_fd);
if (ufds[3].revents == POLLIN)
handle_keychord(keychord_fd);
}
return 0;
}