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samba-mirror/source4/samba/process_prefork.c
Joseph Sutton 6386306671 s4:samba: Add missing newline to logging message
Signed-off-by: Joseph Sutton <josephsutton@catalyst.net.nz>
Reviewed-by: Andrew Bartlett <abartlet@samba.org>
2023-08-08 04:39:38 +00:00

920 lines
24 KiB
C

/*
Unix SMB/CIFS implementation.
process model: prefork (n client connections per process)
Copyright (C) Andrew Tridgell 1992-2005
Copyright (C) James J Myers 2003 <myersjj@samba.org>
Copyright (C) Stefan (metze) Metzmacher 2004
Copyright (C) Andrew Bartlett 2008 <abartlet@samba.org>
Copyright (C) David Disseldorp 2008 <ddiss@sgi.com>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program 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 General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/*
* The pre-fork process model distributes the server workload amongst several
* designated worker threads (e.g. 'prefork-worker-ldap-0',
* 'prefork-worker-ldap-1', etc). The number of worker threads is controlled
* by the 'prefork children' conf setting. The worker threads are controlled
* by a prefork master process (e.g. 'prefork-master-ldap'). The prefork master
* doesn't handle the server workload (i.e. processing messages) itself, but is
* responsible for restarting workers if they exit unexpectedly. The top-level
* samba process is responsible for restarting the master process if it exits.
*/
#include "includes.h"
#include <unistd.h>
#include "lib/events/events.h"
#include "lib/messaging/messaging.h"
#include "lib/socket/socket.h"
#include "samba/process_model.h"
#include "cluster/cluster.h"
#include "param/param.h"
#include "ldb_wrap.h"
#include "lib/util/tfork.h"
#include "lib/messaging/irpc.h"
#include "lib/util/util_process.h"
#include "server_util.h"
#define min(a, b) (((a) < (b)) ? (a) : (b))
NTSTATUS process_model_prefork_init(void);
static void prefork_new_task(
struct tevent_context *ev,
struct loadparm_context *lp_ctx,
const char *service_name,
struct task_server *(*new_task_fn)(struct tevent_context *,
struct loadparm_context *lp_ctx,
struct server_id,
void *,
void *),
void *private_data,
const struct service_details *service_details,
int from_parent_fd);
static void prefork_fork_worker(struct task_server *task,
struct tevent_context *ev,
struct tevent_context *ev2,
struct loadparm_context *lp_ctx,
const struct service_details *service_details,
const char *service_name,
int control_pipe[2],
unsigned restart_delay,
struct process_details *pd);
static void prefork_child_pipe_handler(struct tevent_context *ev,
struct tevent_fd *fde,
uint16_t flags,
void *private_data);
static void setup_handlers(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
int from_parent_fd);
/*
* State needed to restart the master process or a worker process if they
* terminate early.
*/
struct master_restart_context {
struct task_server *(*new_task_fn)(struct tevent_context *,
struct loadparm_context *lp_ctx,
struct server_id,
void *,
void *);
void *private_data;
};
struct worker_restart_context {
unsigned int instance;
struct task_server *task;
struct tevent_context *ev2;
int control_pipe[2];
};
struct restart_context {
struct loadparm_context *lp_ctx;
struct tfork *t;
int from_parent_fd;
const struct service_details *service_details;
const char *service_name;
unsigned restart_delay;
struct master_restart_context *master;
struct worker_restart_context *worker;
};
static void sighup_signal_handler(struct tevent_context *ev,
struct tevent_signal *se,
int signum, int count, void *siginfo,
void *private_data)
{
reopen_logs_internal();
}
static void sigterm_signal_handler(struct tevent_context *ev,
struct tevent_signal *se,
int signum, int count, void *siginfo,
void *private_data)
{
#ifdef HAVE_GETPGRP
if (getpgrp() == getpid()) {
/*
* We're the process group leader, send
* SIGTERM to our process group.
*/
DBG_NOTICE("SIGTERM: killing children\n");
kill(-getpgrp(), SIGTERM);
}
#endif
DBG_NOTICE("Exiting pid %d on SIGTERM\n", getpid());
TALLOC_FREE(ev);
exit(127);
}
/*
called when the process model is selected
*/
static void prefork_model_init(void)
{
}
static void prefork_reload_after_fork(void)
{
NTSTATUS status;
ldb_wrap_fork_hook();
/* Must be done after a fork() to reset messaging contexts. */
status = imessaging_reinit_all();
if (!NT_STATUS_IS_OK(status)) {
smb_panic("Failed to re-initialise imessaging after fork");
}
force_check_log_size();
}
/*
* clean up any messaging associated with the old process.
*
*/
static void irpc_cleanup(
struct loadparm_context *lp_ctx,
struct tevent_context *ev,
pid_t pid)
{
TALLOC_CTX *mem_ctx = talloc_new(NULL);
struct imessaging_context *msg_ctx = NULL;
NTSTATUS status = NT_STATUS_OK;
if (mem_ctx == NULL) {
DBG_ERR("OOM cleaning up irpc\n");
return;
}
msg_ctx = imessaging_client_init(mem_ctx, lp_ctx, ev);
if (msg_ctx == NULL) {
DBG_ERR("Unable to create imessaging_context\n");
TALLOC_FREE(mem_ctx);
return;
}
status = imessaging_process_cleanup(msg_ctx, pid);
if (!NT_STATUS_IS_OK(status)) {
DBG_ERR("imessaging_process_cleanup returned (%s)\n",
nt_errstr(status));
TALLOC_FREE(mem_ctx);
return;
}
TALLOC_FREE(mem_ctx);
}
/*
* handle EOF on the parent-to-all-children pipe in the child, i.e.
* the parent has died and its end of the pipe has been closed.
* The child handles this by exiting as well.
*/
static void prefork_pipe_handler(struct tevent_context *event_ctx,
struct tevent_fd *fde, uint16_t flags,
void *private_data)
{
struct loadparm_context *lp_ctx = NULL;
pid_t pid;
/*
* free the fde which removes the event and stops it firing again
*/
TALLOC_FREE(fde);
/*
* Clean up any irpc end points this process had.
*/
pid = getpid();
lp_ctx = talloc_get_type_abort(private_data, struct loadparm_context);
irpc_cleanup(lp_ctx, event_ctx, pid);
DBG_NOTICE("Child %d exiting\n", getpid());
TALLOC_FREE(event_ctx);
exit(0);
}
/*
* Called by the top-level samba process to create a new prefork master process
*/
static void prefork_fork_master(
struct tevent_context *ev,
struct loadparm_context *lp_ctx,
const char *service_name,
struct task_server *(*new_task_fn)(struct tevent_context *,
struct loadparm_context *lp_ctx,
struct server_id,
void *,
void *),
void *private_data,
const struct service_details *service_details,
unsigned restart_delay,
int from_parent_fd)
{
pid_t pid;
struct tfork* t = NULL;
int i, num_children;
struct tevent_context *ev2;
struct task_server *task = NULL;
struct process_details pd = initial_process_details;
struct samba_tevent_trace_state *samba_tevent_trace_state = NULL;
int control_pipe[2];
t = tfork_create();
if (t == NULL) {
smb_panic("failure in tfork\n");
}
DBG_NOTICE("Forking [%s] pre-fork master process\n", service_name);
pid = tfork_child_pid(t);
if (pid != 0) {
struct tevent_fd *fde = NULL;
int fd = tfork_event_fd(t);
struct restart_context *rc = NULL;
/* Register a pipe handler that gets called when the prefork
* master process terminates.
*/
rc = talloc_zero(ev, struct restart_context);
if (rc == NULL) {
smb_panic("OOM allocating restart context\n");
}
rc->t = t;
rc->lp_ctx = lp_ctx;
rc->service_name = service_name;
rc->service_details = service_details;
rc->from_parent_fd = from_parent_fd;
rc->restart_delay = restart_delay;
rc->master = talloc_zero(rc, struct master_restart_context);
if (rc->master == NULL) {
smb_panic("OOM allocating master restart context\n");
}
rc->master->new_task_fn = new_task_fn;
rc->master->private_data = private_data;
fde = tevent_add_fd(
ev, ev, fd, TEVENT_FD_READ, prefork_child_pipe_handler, rc);
if (fde == NULL) {
smb_panic("Failed to add child pipe handler, "
"after fork");
}
tevent_fd_set_auto_close(fde);
return;
}
pid = getpid();
process_set_title("%s[master]", "task[%s] pre-fork master", service_name);
/*
* this will free all the listening sockets and all state that
* is not associated with this new connection
*/
if (tevent_re_initialise(ev) != 0) {
smb_panic("Failed to re-initialise tevent after fork");
}
prefork_reload_after_fork();
setup_handlers(ev, lp_ctx, from_parent_fd);
if (service_details->inhibit_pre_fork) {
task = new_task_fn(
ev, lp_ctx, cluster_id(pid, 0), private_data, NULL);
/*
* The task does not support pre-fork
*/
if (task != NULL && service_details->post_fork != NULL) {
service_details->post_fork(task, &pd);
}
if (task != NULL && service_details->before_loop != NULL) {
service_details->before_loop(task);
}
tevent_loop_wait(ev);
TALLOC_FREE(ev);
exit(0);
}
/*
* This is now the child code. We need a completely new event_context
* to work with
*/
ev2 = s4_event_context_init(NULL);
samba_tevent_trace_state = create_samba_tevent_trace_state(ev2);
if (samba_tevent_trace_state == NULL) {
TALLOC_FREE(ev);
TALLOC_FREE(ev2);
exit(127);
}
tevent_set_trace_callback(ev2,
samba_tevent_trace_callback,
samba_tevent_trace_state);
/* setup this new connection: process will bind to it's sockets etc
*
* While we can use ev for the child, which has been re-initialised
* above we must run the new task under ev2 otherwise the children would
* be listening on the sockets. Also we don't want the top level
* process accepting and handling requests, it's responsible for
* monitoring and controlling the child work processes.
*/
task = new_task_fn(ev2, lp_ctx, cluster_id(pid, 0), private_data, NULL);
if (task == NULL) {
TALLOC_FREE(ev);
TALLOC_FREE(ev2);
exit(127);
}
/*
* Register an irpc name that can be used by the samba-tool processes
* command
*/
{
struct talloc_ctx *ctx = talloc_new(NULL);
char *name = NULL;
if (ctx == NULL) {
DBG_ERR("Out of memory\n");
exit(127);
}
name = talloc_asprintf(ctx, "prefork-master-%s", service_name);
irpc_add_name(task->msg_ctx, name);
TALLOC_FREE(ctx);
}
{
int default_children;
default_children = lpcfg_prefork_children(lp_ctx);
num_children = lpcfg_parm_int(lp_ctx, NULL, "prefork children",
service_name, default_children);
}
if (num_children == 0) {
DBG_WARNING("Number of pre-fork children for %s is zero, "
"NO worker processes will be started for %s\n",
service_name, service_name);
}
DBG_NOTICE("Forking %d %s worker processes\n",
num_children, service_name);
/*
* the prefork master creates its own control pipe, so the prefork
* workers can detect if the master exits (in which case an EOF gets
* written). (Whereas from_parent_fd is the control pipe from the
* top-level process that the prefork master listens on)
*/
{
int ret;
ret = pipe(control_pipe);
if (ret != 0) {
smb_panic("Unable to create worker control pipe\n");
}
smb_set_close_on_exec(control_pipe[0]);
smb_set_close_on_exec(control_pipe[1]);
}
/*
* Note, we call this before the first
* prefork_fork_worker() in order to have
* a stable order of:
* task_init(master) -> before_loop(master)
* -> post_fork(worker) -> before_loop(worker)
*
* Otherwise we would have different behaviors
* between the first prefork_fork_worker() loop
* and restarting of died workers
*/
if (task != NULL && service_details->before_loop != NULL) {
struct task_server *task_copy = NULL;
/*
* We need to use ev as parent in order to
* keep everything alive during the loop
*/
task_copy = talloc(ev, struct task_server);
if (task_copy == NULL) {
TALLOC_FREE(ev);
TALLOC_FREE(ev2);
exit(127);
}
*task_copy = *task;
/*
* In order to allow the before_loop() hook
* to register messages or event handlers,
* we need to fix up task->event_ctx
* and create a new task->msg_ctx
*/
task_copy->event_ctx = ev;
task_copy->msg_ctx = imessaging_init(task_copy,
task_copy->lp_ctx,
task_copy->server_id,
task_copy->event_ctx);
if (task_copy->msg_ctx == NULL) {
TALLOC_FREE(ev);
TALLOC_FREE(ev2);
exit(127);
}
service_details->before_loop(task_copy);
}
/*
* We are now free to spawn some worker processes
*/
for (i=0; i < num_children; i++) {
prefork_fork_worker(task,
ev,
ev2,
lp_ctx,
service_details,
service_name,
control_pipe,
0,
&pd);
pd.instances++;
}
/*
* Make sure the messaging context
* used by the workers is no longer
* active on ev2, otherwise we
* would have memory leaks, because
* we queue incoming messages
* and never process them via ev2.
*/
imessaging_dgm_unref_ev(ev2);
/* Don't listen on the sockets we just gave to the children */
tevent_loop_wait(ev);
imessaging_dgm_unref_ev(ev);
TALLOC_FREE(ev);
/* We need to keep ev2 until we're finished for the messaging to work */
TALLOC_FREE(ev2);
exit(0);
}
static void prefork_restart_fn(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv,
void *private_data);
/*
* Restarts a child process if it exits unexpectedly
*/
static bool prefork_restart(struct tevent_context *ev,
struct restart_context *rc)
{
struct tevent_timer *te = NULL;
if (rc->restart_delay > 0) {
DBG_ERR("Restarting [%s] pre-fork %s in (%d) seconds\n",
rc->service_name,
(rc->master == NULL) ? "worker" : "master",
rc->restart_delay);
}
/*
* Always use an async timer event. If
* rc->restart_delay is zero this is the
* same as an immediate event and will be
* called immediately we go back into the
* event loop.
*/
te = tevent_add_timer(ev,
ev,
tevent_timeval_current_ofs(rc->restart_delay, 0),
prefork_restart_fn,
rc);
if (te == NULL) {
DBG_ERR("tevent_add_timer fail [%s] pre-fork event %s\n",
rc->service_name,
(rc->master == NULL) ? "worker" : "master");
/* Caller needs to free rc. */
return false;
}
/* Caller must not free rc - it's in use. */
return true;
}
static void prefork_restart_fn(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv,
void *private_data)
{
unsigned max_backoff = 0;
unsigned backoff = 0;
unsigned default_value = 0;
struct restart_context *rc = talloc_get_type(private_data,
struct restart_context);
unsigned restart_delay = rc->restart_delay;
TALLOC_FREE(te);
/*
* If the child process is constantly exiting, then restarting it can
* consume a lot of resources. In which case, we want to backoff a bit
* before respawning it
*/
default_value = lpcfg_prefork_backoff_increment(rc->lp_ctx);
backoff = lpcfg_parm_int(rc->lp_ctx,
NULL,
"prefork backoff increment",
rc->service_name,
default_value);
default_value = lpcfg_prefork_maximum_backoff(rc->lp_ctx);
max_backoff = lpcfg_parm_int(rc->lp_ctx,
NULL,
"prefork maximum backoff",
rc->service_name,
default_value);
restart_delay += backoff;
restart_delay = min(restart_delay, max_backoff);
if (rc->master != NULL) {
DBG_ERR("Restarting [%s] pre-fork master\n", rc->service_name);
prefork_fork_master(ev,
rc->lp_ctx,
rc->service_name,
rc->master->new_task_fn,
rc->master->private_data,
rc->service_details,
restart_delay,
rc->from_parent_fd);
} else if (rc->worker != NULL) {
struct process_details pd = initial_process_details;
DBG_ERR("Restarting [%s] pre-fork worker(%d)\n",
rc->service_name,
rc->worker->instance);
pd.instances = rc->worker->instance;
prefork_fork_worker(rc->worker->task,
ev,
rc->worker->ev2,
rc->lp_ctx,
rc->service_details,
rc->service_name,
rc->worker->control_pipe,
restart_delay,
&pd);
}
/* tfork allocates tfork structures with malloc */
tfork_destroy(&rc->t);
free(rc->t);
TALLOC_FREE(rc);
}
/*
handle EOF on the child pipe in the parent, so we know when a
process terminates without using SIGCHLD or waiting on all possible pids.
We need to ensure we do not ignore SIGCHLD because we need it to
work to get a valid error code from samba_runcmd_*().
*/
static void prefork_child_pipe_handler(struct tevent_context *ev,
struct tevent_fd *fde,
uint16_t flags,
void *private_data)
{
struct restart_context *rc = NULL;
int status = 0;
pid_t pid = 0;
bool rc_inuse = false;
/* free the fde which removes the event and stops it firing again */
TALLOC_FREE(fde);
/* the child has closed the pipe, assume its dead */
rc = talloc_get_type_abort(private_data, struct restart_context);
pid = tfork_child_pid(rc->t);
errno = 0;
irpc_cleanup(rc->lp_ctx, ev, pid);
status = tfork_status(&rc->t, false);
if (status == -1) {
DBG_ERR("Parent %d, Child %d terminated, "
"unable to get status code from tfork\n",
getpid(), pid);
rc_inuse = prefork_restart(ev, rc);
} else if (WIFEXITED(status)) {
status = WEXITSTATUS(status);
DBG_ERR("Parent %d, Child %d exited with status %d\n",
getpid(), pid, status);
if (status != 0) {
rc_inuse = prefork_restart(ev, rc);
}
} else if (WIFSIGNALED(status)) {
status = WTERMSIG(status);
DBG_ERR("Parent %d, Child %d terminated with signal %d\n",
getpid(), pid, status);
if (status == SIGABRT || status == SIGBUS || status == SIGFPE ||
status == SIGILL || status == SIGSYS || status == SIGSEGV ||
status == SIGKILL) {
rc_inuse = prefork_restart(ev, rc);
}
}
if (!rc_inuse) {
/* tfork allocates tfork structures with malloc */
tfork_destroy(&rc->t);
free(rc->t);
TALLOC_FREE(rc);
}
return;
}
/*
called when a listening socket becomes readable.
*/
static void prefork_accept_connection(
struct tevent_context *ev,
struct loadparm_context *lp_ctx,
struct socket_context *listen_socket,
void (*new_conn)(struct tevent_context *,
struct loadparm_context *,
struct socket_context *,
struct server_id,
void *,
void *),
void *private_data,
void *process_context)
{
NTSTATUS status;
struct socket_context *connected_socket;
pid_t pid = getpid();
/* accept an incoming connection. */
status = socket_accept(listen_socket, &connected_socket);
if (!NT_STATUS_IS_OK(status)) {
/*
* For prefork we can ignore STATUS_MORE_ENTRIES, as once a
* connection becomes available all waiting processes are
* woken, but only one gets work to process.
* AKA the thundering herd.
* In the short term this should not be an issue as the number
* of workers should be a small multiple of the number of cpus
* In the longer term socket_accept needs to implement a
* mutex/semaphore (like apache does) to serialise the accepts
*/
if (!NT_STATUS_EQUAL(status, STATUS_MORE_ENTRIES)) {
DBG_ERR("Worker process (%d), error in accept [%s]\n",
getpid(), nt_errstr(status));
}
return;
}
talloc_steal(private_data, connected_socket);
new_conn(ev, lp_ctx, connected_socket,
cluster_id(pid, socket_get_fd(connected_socket)),
private_data, process_context);
}
static void setup_handlers(
struct tevent_context *ev,
struct loadparm_context *lp_ctx,
int from_parent_fd)
{
struct tevent_fd *fde = NULL;
struct tevent_signal *se = NULL;
fde = tevent_add_fd(ev, ev, from_parent_fd, TEVENT_FD_READ,
prefork_pipe_handler, lp_ctx);
if (fde == NULL) {
smb_panic("Failed to add fd handler after fork");
}
se = tevent_add_signal(ev,
ev,
SIGHUP,
0,
sighup_signal_handler,
NULL);
if (se == NULL) {
smb_panic("Failed to add SIGHUP handler after fork");
}
se = tevent_add_signal(ev,
ev,
SIGTERM,
0,
sigterm_signal_handler,
NULL);
if (se == NULL) {
smb_panic("Failed to add SIGTERM handler after fork");
}
}
/*
* Called by the prefork master to create a new prefork worker process
*/
static void prefork_fork_worker(struct task_server *task,
struct tevent_context *ev,
struct tevent_context *ev2,
struct loadparm_context *lp_ctx,
const struct service_details *service_details,
const char *service_name,
int control_pipe[2],
unsigned restart_delay,
struct process_details *pd)
{
struct tfork *w = NULL;
pid_t pid;
w = tfork_create();
if (w == NULL) {
smb_panic("failure in tfork\n");
}
pid = tfork_child_pid(w);
if (pid != 0) {
struct tevent_fd *fde = NULL;
int fd = tfork_event_fd(w);
struct restart_context *rc = NULL;
/*
* we're the parent (prefork master), so store enough info to
* restart the worker/child if it exits unexpectedly
*/
rc = talloc_zero(ev, struct restart_context);
if (rc == NULL) {
smb_panic("OOM allocating restart context\n");
}
rc->t = w;
rc->lp_ctx = lp_ctx;
rc->service_name = service_name;
rc->service_details = service_details;
rc->restart_delay = restart_delay;
rc->master = NULL;
rc->worker = talloc_zero(rc, struct worker_restart_context);
if (rc->worker == NULL) {
smb_panic("OOM allocating master restart context\n");
}
rc->worker->ev2 = ev2;
rc->worker->instance = pd->instances;
rc->worker->task = task;
rc->worker->control_pipe[0] = control_pipe[0];
rc->worker->control_pipe[1] = control_pipe[1];
fde = tevent_add_fd(
ev, ev, fd, TEVENT_FD_READ, prefork_child_pipe_handler, rc);
if (fde == NULL) {
smb_panic("Failed to add child pipe handler, "
"after fork");
}
tevent_fd_set_auto_close(fde);
} else {
/*
* we're the child (prefork-worker). We never write to the
* control pipe, but listen on the read end in case our parent
* (the pre-fork master) exits
*/
close(control_pipe[1]);
setup_handlers(ev2, lp_ctx, control_pipe[0]);
/*
* tfork uses malloc
*/
free(w);
imessaging_dgm_unref_ev(ev);
TALLOC_FREE(ev);
process_set_title("%s(%d)",
"task[%s] pre-forked worker(%d)",
service_name,
pd->instances);
prefork_reload_after_fork();
if (service_details->post_fork != NULL) {
service_details->post_fork(task, pd);
}
{
struct talloc_ctx *ctx = talloc_new(NULL);
char *name = NULL;
if (ctx == NULL) {
smb_panic("OOM allocating talloc context\n");
}
name = talloc_asprintf(ctx,
"prefork-worker-%s-%d",
service_name,
pd->instances);
irpc_add_name(task->msg_ctx, name);
TALLOC_FREE(ctx);
}
if (service_details->before_loop != NULL) {
service_details->before_loop(task);
}
tevent_loop_wait(ev2);
imessaging_dgm_unref_ev(ev2);
talloc_free(ev2);
exit(0);
}
}
/*
* called to create a new server task
*/
static void prefork_new_task(
struct tevent_context *ev,
struct loadparm_context *lp_ctx,
const char *service_name,
struct task_server *(*new_task_fn)(struct tevent_context *,
struct loadparm_context *lp_ctx,
struct server_id , void *, void *),
void *private_data,
const struct service_details *service_details,
int from_parent_fd)
{
prefork_fork_master(ev,
lp_ctx,
service_name,
new_task_fn,
private_data,
service_details,
0,
from_parent_fd);
}
/*
* called when a task terminates
*/
static void prefork_terminate_task(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
const char *reason,
bool fatal,
void *process_context)
{
DBG_DEBUG("called with reason[%s]\n", reason);
TALLOC_FREE(ev);
if (fatal == true) {
exit(127);
} else {
exit(0);
}
}
/*
* called when a connection completes
*/
static void prefork_terminate_connection(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
const char *reason,
void *process_context)
{
}
/* called to set a title of a task or connection */
static void prefork_set_title(struct tevent_context *ev, const char *title)
{
}
static const struct model_ops prefork_ops = {
.name = "prefork",
.model_init = prefork_model_init,
.accept_connection = prefork_accept_connection,
.new_task = prefork_new_task,
.terminate_task = prefork_terminate_task,
.terminate_connection = prefork_terminate_connection,
.set_title = prefork_set_title,
};
/*
* initialise the prefork process model, registering ourselves with the
* process model subsystem
*/
NTSTATUS process_model_prefork_init(void)
{
return register_process_model(&prefork_ops);
}