core-lightning/lightningd/subd.c

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#include "config.h"
#include <ccan/closefrom/closefrom.h>
#include <ccan/err/err.h>
#include <ccan/io/fdpass/fdpass.h>
#include <ccan/mem/mem.h>
#include <ccan/noerr/noerr.h>
#include <ccan/tal/path/path.h>
#include <ccan/tal/str/str.h>
#include <common/memleak.h>
#include <common/peer_status_wiregen.h>
#include <common/status_wiregen.h>
#include <common/version.h>
#include <db/exec.h>
#include <errno.h>
#include <fcntl.h>
#include <lightningd/lightningd.h>
#include <lightningd/log_status.h>
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#include <lightningd/peer_fd.h>
#include <lightningd/subd.h>
#include <sys/socket.h>
#include <sys/wait.h>
#include <wire/wire_io.h>
void maybe_subd_child(struct lightningd *ld, int childpid, int wstatus)
{
struct subd *sd;
list_for_each(&ld->subds, sd, list) {
if (sd->pid == childpid)
sd->wstatus = tal_dup(sd, int, &wstatus);
}
}
/* Carefully move fd *@from to @to: on success *from set to to */
static bool move_fd(int *from, int to)
{
assert(*from >= 0);
/* dup2 with same arguments may be a no-op, but
* the later close would make the fd invalid.
* Handle this edge case.
*/
if (*from == to)
return true;
if (dup2(*from, to) == -1)
return false;
/* dup2 does not duplicate flags, copy it here.
* This should be benign; the only POSIX-defined
* flag is FD_CLOEXEC, and we only use it rarely.
*/
if (fcntl(to, F_SETFD, fcntl(*from, F_GETFD)) < 0)
return false;
close(*from);
*from = to;
return true;
}
/* Returns index of fds which is == this fd, or -1 */
static int fd_used(int **fds, size_t num_fds, int fd)
{
for (size_t i = 0; i < num_fds; i++) {
if (*fds[i] == fd)
return i;
}
return -1;
}
/* Move an series of fd pointers into 0, 1, ... */
static bool shuffle_fds(int **fds, size_t num_fds)
{
/* If we need to move an fd out the way, this is a good place to start
* looking */
size_t next_free_fd = num_fds;
for (size_t i = 0; i < num_fds; i++) {
int in_the_way;
/* Already in the right place? Great! */
if (*fds[i] == i)
continue;
/* Is something we care about in the way? */
in_the_way = fd_used(fds + i, num_fds - i, i);
if (in_the_way != -1) {
/* Find a high-numbered unused fd. */
while (fd_used(fds + i, num_fds - i, next_free_fd) != -1)
next_free_fd++;
/* Trick: in_the_way is offset by i! */
if (!move_fd(fds[i + in_the_way], next_free_fd))
return false;
next_free_fd++;
}
/* Now there should be nothing in the way. */
assert(fd_used(fds, num_fds, i) == -1);
if (!move_fd(fds[i], i))
return false;
}
return true;
}
struct subd_req {
struct list_node list;
/* Callback for a reply. */
int type;
void (*replycb)(struct subd *, const u8 *, const int *, void *);
void *replycb_data;
size_t num_reply_fds;
/* If non-NULL, this is here to disable replycb */
void *disabler;
};
static void destroy_subd_req(struct subd_req *sr)
{
list_del(&sr->list);
/* Don't disable once we're freed! */
if (sr->disabler)
tal_free(sr->disabler);
}
/* Called when the callback is disabled because caller was freed. */
static void ignore_reply(struct subd *sd, const u8 *msg UNUSED, const int *fds,
void *arg UNUSED)
{
size_t i;
log_debug(sd->log, "IGNORING REPLY");
for (i = 0; i < tal_count(fds); i++)
close(fds[i]);
}
static void disable_cb(void *disabler UNUSED, struct subd_req *sr)
{
sr->replycb = ignore_reply;
sr->disabler = NULL;
}
static struct subd_req *add_req(const tal_t *ctx,
struct subd *sd, int type, size_t num_fds_in,
void (*replycb)(struct subd *, const u8 *, const int *,
void *),
void *replycb_data)
{
struct subd_req *sr = tal(sd, struct subd_req);
sr->type = type;
sr->replycb = replycb;
sr->replycb_data = replycb_data;
sr->num_reply_fds = num_fds_in;
/* We don't allocate sr off ctx, because we still have to handle the
* case where ctx is freed between request and reply. Hence this
* trick. */
if (ctx) {
sr->disabler = notleak(tal(ctx, char));
tal_add_destructor2(sr->disabler, disable_cb, sr);
} else
sr->disabler = NULL;
assert(strends(sd->msgname(sr->type + SUBD_REPLY_OFFSET), "_REPLY"));
/* Keep in FIFO order: we sent in order, so replies will be too. */
list_add_tail(&sd->reqs, &sr->list);
tal_add_destructor(sr, destroy_subd_req);
return sr;
}
/* Caller must free. */
static struct subd_req *get_req(struct subd *sd, int reply_type)
{
struct subd_req *sr;
list_for_each(&sd->reqs, sr, list) {
if (sr->type + SUBD_REPLY_OFFSET == reply_type)
return sr;
/* If it's a fail, and that's a valid type. */
if (sr->type + SUBD_REPLYFAIL_OFFSET == reply_type
&& strends(sd->msgname(reply_type), "_REPLYFAIL")) {
sr->num_reply_fds = 0;
return sr;
}
}
return NULL;
}
static void close_taken_fds(va_list *ap)
{
int *fd;
while ((fd = va_arg(*ap, int *)) != NULL) {
if (taken(fd) && *fd >= 0) {
close(*fd);
*fd = -1;
}
}
}
/* We use sockets, not pipes, because fds are bidir. */
static int subd(const char *path, const char *name,
const char *debug_subdaemon,
int *msgfd,
bool io_logging,
va_list *ap)
{
int childmsg[2], execfail[2];
pid_t childpid;
int err, *fd;
if (socketpair(AF_LOCAL, SOCK_STREAM, 0, childmsg) != 0)
goto fail;
if (pipe(execfail) != 0)
goto close_msgfd_fail;
if (fcntl(execfail[1], F_SETFD, fcntl(execfail[1], F_GETFD)
| FD_CLOEXEC) < 0)
goto close_execfail_fail;
childpid = fork();
if (childpid < 0)
goto close_execfail_fail;
if (childpid == 0) {
size_t num_args;
char *args[] = { NULL, NULL, NULL, NULL };
int **fds = tal_arr(tmpctx, int *, 3);
int stdoutfd = STDOUT_FILENO, stderrfd = STDERR_FILENO;
close(childmsg[0]);
close(execfail[0]);
/* msg = STDIN (0) */
fds[0] = &childmsg[1];
/* These are untouched */
fds[1] = &stdoutfd;
fds[2] = &stderrfd;
while ((fd = va_arg(*ap, int *)) != NULL) {
assert(*fd != -1);
tal_arr_expand(&fds, fd);
}
/* Finally, the fd to report exec errors on */
tal_arr_expand(&fds, &execfail[1]);
if (!shuffle_fds(fds, tal_count(fds)))
goto child_errno_fail;
/* Make (fairly!) sure all other fds are closed. */
closefrom(tal_count(fds));
num_args = 0;
args[num_args++] = tal_strdup(NULL, path);
if (io_logging)
args[num_args++] = "--log-io";
#if DEVELOPER
if (debug_subdaemon && strends(name, debug_subdaemon))
args[num_args++] = "--debugger";
#endif
execv(args[0], args);
child_errno_fail:
err = errno;
/* Gcc's warn-unused-result fail. */
if (write(execfail[1], &err, sizeof(err))) {
;
}
exit(127);
}
close(childmsg[1]);
close(execfail[1]);
if (ap)
close_taken_fds(ap);
/* Child will close this without writing on successful exec. */
if (read(execfail[0], &err, sizeof(err)) == sizeof(err)) {
close(execfail[0]);
waitpid(childpid, NULL, 0);
errno = err;
return -1;
}
close(execfail[0]);
*msgfd = childmsg[0];
return childpid;
close_execfail_fail:
close_noerr(execfail[0]);
close_noerr(execfail[1]);
close_msgfd_fail:
close_noerr(childmsg[0]);
close_noerr(childmsg[1]);
fail:
if (ap)
close_taken_fds(ap);
return -1;
}
static struct io_plan *sd_msg_read(struct io_conn *conn, struct subd *sd);
static void mark_freed(struct subd *unused UNUSED, bool *freed)
{
*freed = true;
}
static struct io_plan *sd_msg_reply(struct io_conn *conn, struct subd *sd,
struct subd_req *sr)
{
int type = fromwire_peektype(sd->msg_in);
bool freed = false;
int *fds_in;
log_debug(sd->log, "REPLY %s with %zu fds",
sd->msgname(type), tal_count(sd->fds_in));
/* Callback could free sd! Make sure destroy_subd() won't free conn */
sd->conn = NULL;
/* We want to free the msg_in, unless they tal_steal() it. */
tal_steal(tmpctx, sd->msg_in);
/* And we need to free sr after this too. */
tal_steal(tmpctx, sr);
/* In case they free sd, don't deref. */
list_del_init(&sr->list);
/* Free this array after, too. */
fds_in = tal_steal(tmpctx, sd->fds_in);
sd->fds_in = NULL;
/* Find out if they freed it. */
tal_add_destructor2(sd, mark_freed, &freed);
sr->replycb(sd, sd->msg_in, fds_in, sr->replycb_data);
if (freed)
return io_close(conn);
tal_del_destructor2(sd, mark_freed, &freed);
/* Restore conn ptr. */
sd->conn = conn;
return io_read_wire(conn, sd, &sd->msg_in, sd_msg_read, sd);
}
static struct io_plan *read_fds(struct io_conn *conn, struct subd *sd)
{
if (sd->num_fds_in_read == tal_count(sd->fds_in)) {
size_t i;
/* Don't trust subd to set it blocking. */
for (i = 0; i < tal_count(sd->fds_in); i++)
io_fd_block(sd->fds_in[i], true);
return sd_msg_read(conn, sd);
}
return io_recv_fd(conn, &sd->fds_in[sd->num_fds_in_read++],
read_fds, sd);
}
static struct io_plan *sd_collect_fds(struct io_conn *conn, struct subd *sd,
size_t num_fds)
{
assert(!sd->fds_in);
sd->fds_in = tal_arr(sd, int, num_fds);
sd->num_fds_in_read = 0;
return read_fds(conn, sd);
}
static void subdaemon_malformed_msg(struct subd *sd, const u8 *msg)
{
log_broken(sd->log, "%i: malformed message '%.s'",
fromwire_peektype(msg),
tal_hex(msg, msg));
#if DEVELOPER
if (sd->ld->dev_subdaemon_fail)
exit(1);
#endif
}
static bool log_status_fail(struct subd *sd, const u8 *msg)
{
const char *name = NULL;
enum status_failreason failreason;
char *desc;
if (!fromwire_status_fail(msg, msg, &failreason, &desc))
return false;
/* No 'default:' here so gcc gives warning if a new type added */
switch (failreason) {
case STATUS_FAIL_MASTER_IO:
name = "STATUS_FAIL_MASTER_IO";
break;
case STATUS_FAIL_HSM_IO:
name = "STATUS_FAIL_HSM_IO";
break;
case STATUS_FAIL_GOSSIP_IO:
name = "STATUS_FAIL_GOSSIP_IO";
break;
case STATUS_FAIL_INTERNAL_ERROR:
name = "STATUS_FAIL_INTERNAL_ERROR";
break;
}
/* fromwire_status_fail() guarantees it's one of those... */
assert(name);
log_broken(sd->log, "%s: %s", name, desc);
#if DEVELOPER
if (sd->ld->dev_subdaemon_fail)
exit(1);
#endif
return true;
}
static bool handle_peer_error(struct subd *sd, const u8 *msg, int fds[1])
{
void *channel = sd->channel;
struct channel_id channel_id;
char *desc;
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struct peer_fd *peer_fd;
u8 *err_for_them;
bool warning;
if (!fromwire_status_peer_error(msg, msg,
&channel_id, &desc, &warning,
&err_for_them))
return false;
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peer_fd = new_peer_fd_arr(msg, fds);
/* Don't free sd; we may be about to free channel. */
sd->channel = NULL;
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sd->errcb(channel, peer_fd, &channel_id, desc, warning, err_for_them);
return true;
}
static bool handle_set_billboard(struct subd *sd, const u8 *msg)
{
bool perm;
char *happenings;
if (!fromwire_status_peer_billboard(msg, msg, &perm, &happenings))
return false;
sd->billboardcb(sd->channel, perm, happenings);
return true;
}
static bool handle_version(struct subd *sd, const u8 *msg)
{
char *ver;
if (!fromwire_status_version(msg, msg, &ver))
return false;
if (!streq(ver, version())) {
log_broken(sd->log, "version '%s' not '%s': restarting",
ver, version());
sd->ld->try_reexec = true;
/* Return us to toplevel lightningd.c */
log_debug(sd->ld->log, "io_break: %s", __func__);
io_break(sd->ld);
return false;
}
sd->rcvd_version = true;
/* In case there are outgoing msgs, we can send now. */
msg_wake(sd->outq);
return true;
}
static struct io_plan *sd_msg_read(struct io_conn *conn, struct subd *sd)
{
int type = fromwire_peektype(sd->msg_in);
struct subd_req *sr;
struct db *db = sd->ld->wallet->db;
struct io_plan *plan;
unsigned int i;
bool freed = false;
/* Everything we do, we wrap in a database transaction */
db_begin_transaction(db);
if (type == -1)
goto malformed;
/* First, check for replies. */
sr = get_req(sd, type);
if (sr) {
if (sr->num_reply_fds && sd->fds_in == NULL) {
plan = sd_collect_fds(conn, sd, sr->num_reply_fds);
goto out;
}
assert(sr->num_reply_fds == tal_count(sd->fds_in));
plan = sd_msg_reply(conn, sd, sr);
goto out;
}
/* If not stolen, we'll free this later. */
tal_steal(tmpctx, sd->msg_in);
/* We handle status messages ourselves. */
switch ((enum status_wire)type) {
case WIRE_STATUS_LOG:
case WIRE_STATUS_IO:
if (!log_status_msg(sd->log, sd->node_id, sd->msg_in))
goto malformed;
goto next;
case WIRE_STATUS_FAIL:
if (!log_status_fail(sd, sd->msg_in))
goto malformed;
goto close;
case WIRE_STATUS_PEER_CONNECTION_LOST:
if (!sd->channel)
goto malformed;
log_info(sd->log, "Peer connection lost");
goto close;
case WIRE_STATUS_PEER_BILLBOARD:
if (!sd->channel)
goto malformed;
if (!handle_set_billboard(sd, sd->msg_in))
goto malformed;
goto next;
case WIRE_STATUS_VERSION:
if (!handle_version(sd, sd->msg_in))
goto close;
goto next;
}
if (sd->channel) {
switch ((enum peer_status_wire)type) {
case WIRE_STATUS_PEER_ERROR:
/* We expect 1 fd after this */
if (!sd->fds_in) {
/* Don't free msg_in: we go around again. */
tal_steal(sd, sd->msg_in);
plan = sd_collect_fds(conn, sd, 1);
goto out;
}
if (!handle_peer_error(sd, sd->msg_in, sd->fds_in))
goto malformed;
goto close;
}
}
/* Might free sd (if returns negative); save/restore sd->conn */
sd->conn = NULL;
tal_add_destructor2(sd, mark_freed, &freed);
i = sd->msgcb(sd, sd->msg_in, sd->fds_in);
if (freed)
goto close;
tal_del_destructor2(sd, mark_freed, &freed);
sd->conn = conn;
if (i != 0) {
/* Don't ask for fds twice! */
assert(!sd->fds_in);
/* Don't free msg_in: we go around again. */
tal_steal(sd, sd->msg_in);
plan = sd_collect_fds(conn, sd, i);
goto out;
}
next:
sd->msg_in = NULL;
sd->fds_in = tal_free(sd->fds_in);
plan = io_read_wire(conn, sd, &sd->msg_in, sd_msg_read, sd);
goto out;
malformed:
subdaemon_malformed_msg(sd, sd->msg_in);
close:
plan = io_close(conn);
out:
db_commit_transaction(db);
return plan;
}
static void destroy_subd(struct subd *sd)
{
int status;
bool fail_if_subd_fails;
fail_if_subd_fails = IFDEV(sd->ld->dev_subdaemon_fail, false);
list_del_from(&sd->ld->subds, &sd->list);
/* lightningd may have already done waitpid() */
if (sd->wstatus != NULL) {
status = *sd->wstatus;
} else {
switch (waitpid(sd->pid, &status, WNOHANG)) {
case 0:
/* If it's an essential daemon, don't kill: we want the
* exit status */
if (!sd->must_not_exit) {
log_debug(sd->log,
"Status closed, but not exited. Killing");
kill(sd->pid, SIGKILL);
}
waitpid(sd->pid, &status, 0);
fail_if_subd_fails = false;
break;
case -1:
log_broken(sd->log, "Status closed, but waitpid %i says %s",
sd->pid, strerror(errno));
status = -1;
break;
}
}
if (fail_if_subd_fails && WIFSIGNALED(status)) {
log_broken(sd->log, "Subdaemon %s killed with signal %i",
sd->name, WTERMSIG(status));
exit(1);
}
/* In case we're freed manually, such as channel_fail_permanent */
if (sd->conn)
sd->conn = tal_free(sd->conn);
/* Peer still attached? */
if (sd->channel) {
/* Don't loop back when we fail it. */
void *channel = sd->channel;
struct db *db = sd->ld->wallet->db;
bool outer_transaction;
/* Clear any transient messages in billboard */
sd->billboardcb(channel, false, NULL);
sd->channel = NULL;
/* We can be freed both inside msg handling, or spontaneously. */
outer_transaction = db_in_transaction(db);
if (!outer_transaction)
db_begin_transaction(db);
if (sd->errcb)
sd->errcb(channel, NULL, NULL,
tal_fmt(sd, "Owning subdaemon %s died (%i)",
sd->name, status),
false, NULL);
if (!outer_transaction)
db_commit_transaction(db);
}
if (sd->must_not_exit) {
if (WIFEXITED(status))
errx(1, "%s failed (exit status %i), exiting.",
sd->name, WEXITSTATUS(status));
errx(1, "%s failed (signal %u), exiting.",
sd->name, WTERMSIG(status));
}
}
static struct io_plan *msg_send_next(struct io_conn *conn, struct subd *sd)
{
const u8 *msg;
int fd;
/* Don't send if we haven't read version! */
if (!sd->rcvd_version)
return msg_queue_wait(conn, sd->outq, msg_send_next, sd);
/* Nothing to do? Wait for msg_enqueue. */
msg = msg_dequeue(sd->outq);
if (!msg)
return msg_queue_wait(conn, sd->outq, msg_send_next, sd);
fd = msg_extract_fd(sd->outq, msg);
if (fd >= 0) {
tal_free(msg);
return io_send_fd(conn, fd, true, msg_send_next, sd);
}
return io_write_wire(conn, take(msg), msg_send_next, sd);
}
static struct io_plan *msg_setup(struct io_conn *conn, struct subd *sd)
{
return io_duplex(conn,
io_read_wire(conn, sd, &sd->msg_in, sd_msg_read, sd),
msg_send_next(conn, sd));
}
static struct subd *new_subd(const tal_t *ctx,
struct lightningd *ld,
const char *name,
void *channel,
const struct node_id *node_id,
struct log *base_log,
bool talks_to_peer,
const char *(*msgname)(int msgtype),
unsigned int (*msgcb)(struct subd *,
const u8 *, const int *fds),
void (*errcb)(void *channel,
2022-01-11 02:13:59 +01:00
struct peer_fd *peer_fd,
const struct channel_id *channel_id,
const char *desc,
bool warning,
const u8 *err_for_them),
void (*billboardcb)(void *channel,
bool perm,
const char *happenings),
va_list *ap)
{
struct subd *sd = tal(ctx, struct subd);
int msg_fd;
const char *debug_subd = NULL;
const char *shortname;
assert(name != NULL);
/* This part of the name is a bit redundant for logging */
if (strstarts(name, "lightning_"))
shortname = name + strlen("lightning_");
else
shortname = name;
if (base_log) {
sd->log = new_log(sd, ld->log_book, node_id,
"%s-%s", shortname, log_prefix(base_log));
} else {
sd->log = new_log(sd, ld->log_book, node_id, "%s", shortname);
}
#if DEVELOPER
debug_subd = ld->dev_debug_subprocess;
#endif /* DEVELOPER */
const char *path = subdaemon_path(tmpctx, ld, name);
sd->pid = subd(path, name, debug_subd,
&msg_fd,
/* We only turn on subdaemon io logging if we're going
* to print it: too stressful otherwise! */
log_print_level(sd->log, node_id) < LOG_DBG,
ap);
if (sd->pid == (pid_t)-1) {
log_unusual(ld->log, "subd %s failed: %s",
name, strerror(errno));
return tal_free(sd);
}
sd->ld = ld;
sd->name = shortname;
sd->must_not_exit = false;
sd->talks_to_peer = talks_to_peer;
sd->msgname = msgname;
assert(msgname);
sd->msgcb = msgcb;
assert(msgcb);
sd->errcb = errcb;
sd->billboardcb = billboardcb;
sd->fds_in = NULL;
sd->outq = msg_queue_new(sd, true);
sd->wstatus = NULL;
list_add(&ld->subds, &sd->list);
tal_add_destructor(sd, destroy_subd);
list_head_init(&sd->reqs);
sd->channel = channel;
sd->rcvd_version = false;
sd->node_id = tal_dup_or_null(sd, struct node_id, node_id);
/* conn actually owns daemon: we die when it does. */
sd->conn = io_new_conn(ld, msg_fd, msg_setup, sd);
tal_steal(sd->conn, sd);
log_peer_debug(sd->log, node_id, "pid %u, msgfd %i", sd->pid, msg_fd);
/* Clear any old transient message. */
if (billboardcb)
billboardcb(sd->channel, false, NULL);
return sd;
}
struct subd *new_global_subd(struct lightningd *ld,
const char *name,
const char *(*msgname)(int msgtype),
unsigned int (*msgcb)(struct subd *, const u8 *,
const int *fds),
...)
{
va_list ap;
struct subd *sd;
va_start(ap, msgcb);
sd = new_subd(ld, ld, name, NULL, NULL, NULL, false,
msgname, msgcb, NULL, NULL, &ap);
va_end(ap);
sd->must_not_exit = true;
return sd;
}
struct subd *new_channel_subd_(const tal_t *ctx,
struct lightningd *ld,
const char *name,
void *channel,
const struct node_id *node_id,
struct log *base_log,
bool talks_to_peer,
const char *(*msgname)(int msgtype),
unsigned int (*msgcb)(struct subd *, const u8 *,
const int *fds),
void (*errcb)(void *channel,
2022-01-11 02:13:59 +01:00
struct peer_fd *peer_fd,
const struct channel_id *channel_id,
const char *desc,
bool warning,
const u8 *err_for_them),
void (*billboardcb)(void *channel, bool perm,
const char *happenings),
...)
{
va_list ap;
struct subd *sd;
va_start(ap, billboardcb);
sd = new_subd(ctx, ld, name, channel, node_id, base_log,
talks_to_peer, msgname, msgcb, errcb, billboardcb, &ap);
va_end(ap);
return sd;
}
void subd_send_msg(struct subd *sd, const u8 *msg_out)
{
u16 type = fromwire_peektype(msg_out);
/* FIXME: We should use unique upper bits for each daemon, then
* have generate-wire.py add them, just assert here. */
if (strstarts(sd->msgname(type), "INVALID"))
fatal("Sending %s an invalid message %s", sd->name, tal_hex(tmpctx, msg_out));
msg_enqueue(sd->outq, msg_out);
}
void subd_send_fd(struct subd *sd, int fd)
{
msg_enqueue_fd(sd->outq, fd);
}
struct subd_req *subd_req_(const tal_t *ctx,
struct subd *sd,
const u8 *msg_out,
int fd_out, size_t num_fds_in,
void (*replycb)(struct subd *, const u8 *, const int *, void *),
void *replycb_data)
{
/* Grab type now in case msg_out is taken() */
int type = fromwire_peektype(msg_out);
subd_send_msg(sd, msg_out);
if (fd_out >= 0)
subd_send_fd(sd, fd_out);
return add_req(ctx, sd, type, num_fds_in, replycb, replycb_data);
}
/* SIGALRM terminates by default: we just want it to interrupt waitpid(),
* which is implied by "handling" it. */
static void discard_alarm(int sig UNNEEDED)
{
}
struct subd *subd_shutdown(struct subd *sd, unsigned int seconds)
{
struct sigaction sa, old;
log_debug(sd->log, "Shutting down");
tal_del_destructor(sd, destroy_subd);
/* This should make it exit; steal so it stays around. */
tal_steal(sd->ld, sd);
sd->conn = tal_free(sd->conn);
/* Set up alarm to wake us up if child doesn't exit. */
sa.sa_handler = discard_alarm;
sigemptyset(&sa.sa_mask);
sa.sa_flags = 0;
sigaction(SIGALRM, &sa, &old);
alarm(seconds);
if (waitpid(sd->pid, NULL, 0) > 0) {
alarm(0);
sigaction(SIGALRM, &old, NULL);
list_del_from(&sd->ld->subds, &sd->list);
return tal_free(sd);
}
sigaction(SIGALRM, &old, NULL);
/* Didn't die? This will kill it harder */
sd->must_not_exit = false;
destroy_subd(sd);
return tal_free(sd);
}
void subd_shutdown_remaining(struct lightningd *ld)
{
struct subd *subd;
/* We give them a second to finish exiting, before we kill
* them in destroy_subd() */
sleep(1);
while ((subd = list_top(&ld->subds, struct subd, list)) != NULL) {
/* Destructor removes from list */
io_close(subd->conn);
}
}
void subd_release_channel(struct subd *owner, const void *channel)
{
/* If owner is a per-peer-daemon, and not already freeing itself... */
if (owner->channel) {
assert(owner->channel == channel);
owner->channel = NULL;
tal_free(owner);
}
}
#if DEVELOPER
char *opt_subd_dev_disconnect(const char *optarg, struct lightningd *ld)
{
ld->dev_disconnect_fd = open(optarg, O_RDONLY);
if (ld->dev_disconnect_fd < 0)
return tal_fmt(ld, "Could not open --dev-disconnect=%s: %s",
optarg, strerror(errno));
return NULL;
}
/* If test specified that this disconnection should cause permanent failure */
bool dev_disconnect_permanent(struct lightningd *ld)
{
char permfail[strlen("PERMFAIL")];
int r;
if (ld->dev_disconnect_fd == -1)
return false;
r = read(ld->dev_disconnect_fd, permfail, sizeof(permfail));
if (r < 0)
fatal("Reading dev_disconnect file: %s", strerror(errno));
if (memeq(permfail, r, "permfail", strlen("permfail")))
return true;
/* Nope, restore. */
2018-01-09 08:13:35 +01:00
if (lseek(ld->dev_disconnect_fd, -r, SEEK_CUR) < 0) {
fatal("lseek failure");
}
return false;
}
#endif /* DEVELOPER */
/* Ugly helper to get full pathname of the current binary. */
const char *find_my_abspath(const tal_t *ctx, const char *argv0)
{
char *me;
/* A command containing / is run relative to the current directory,
* not searched through the path. The shell sets argv0 to the command
* run, though something else could set it to a arbitrary value and
* this logic would be wrong. */
if (strchr(argv0, PATH_SEP)) {
const char *path;
/* Absolute paths are easy. */
if (strstarts(argv0, PATH_SEP_STR))
path = argv0;
/* It contains a '/', it's relative to current dir. */
else
path = path_join(tmpctx, path_cwd(tmpctx), argv0);
me = path_canon(ctx, path);
if (!me || access(me, X_OK) != 0)
errx(1, "I cannot find myself at %s based on my name %s",
path, argv0);
} else {
/* No /, search path */
char **pathdirs;
const char *pathenv = getenv("PATH");
size_t i;
/* This replicates the standard shell path search algorithm */
if (!pathenv)
errx(1, "Cannot find myself: no $PATH set");
pathdirs = tal_strsplit(tmpctx, pathenv, ":", STR_NO_EMPTY);
me = NULL;
for (i = 0; pathdirs[i]; i++) {
/* This returns NULL if it doesn't exist. */
me = path_canon(ctx,
path_join(tmpctx, pathdirs[i], argv0));
if (me && access(me, X_OK) == 0)
break;
/* Nope, try again. */
me = tal_free(me);
}
if (!me)
errx(1, "Cannot find %s in $PATH", argv0);
}
return me;
}