freebsd-skq/contrib/ntp/libntp/ntp_worker.c
delphij a3a54e251a MFV r298691:
ntp 4.2.8p7.

Security:	CVE-2016-1547, CVE-2016-1548, CVE-2016-1549, CVE-2016-1550
Security:	CVE-2016-1551, CVE-2016-2516, CVE-2016-2517, CVE-2016-2518
Security:	CVE-2016-2519
Security:	FreeBSD-SA-16:16.ntp
With hat:	so
2016-04-27 07:46:38 +00:00

369 lines
7.2 KiB
C

/*
* ntp_worker.c
*/
#include <config.h>
#include "ntp_workimpl.h"
#ifdef WORKER
#include <stdio.h>
#include <ctype.h>
#include <signal.h>
#include "iosignal.h"
#include "ntp_stdlib.h"
#include "ntp_malloc.h"
#include "ntp_syslog.h"
#include "ntpd.h"
#include "ntp_io.h"
#include "ntp_assert.h"
#include "ntp_unixtime.h"
#include "intreswork.h"
#define CHILD_MAX_IDLE (3 * 60) /* seconds, idle worker limit */
blocking_child ** blocking_children;
size_t blocking_children_alloc;
int worker_per_query; /* boolean */
int intres_req_pending;
volatile u_int blocking_child_ready_seen;
volatile u_int blocking_child_ready_done;
#ifndef HAVE_IO_COMPLETION_PORT
/*
* pipe_socketpair()
*
* Provides an AF_UNIX socketpair on systems which have them, otherwise
* pair of unidirectional pipes.
*/
int
pipe_socketpair(
int caller_fds[2],
int * is_pipe
)
{
int rc;
int fds[2];
int called_pipe;
#ifdef HAVE_SOCKETPAIR
rc = socketpair(AF_UNIX, SOCK_STREAM, 0, &fds[0]);
#else
rc = -1;
#endif
if (-1 == rc) {
rc = pipe(&fds[0]);
called_pipe = TRUE;
} else {
called_pipe = FALSE;
}
if (-1 == rc)
return rc;
caller_fds[0] = fds[0];
caller_fds[1] = fds[1];
if (is_pipe != NULL)
*is_pipe = called_pipe;
return 0;
}
/*
* close_all_except()
*
* Close all file descriptors except the given keep_fd.
*/
void
close_all_except(
int keep_fd
)
{
int fd;
for (fd = 0; fd < keep_fd; fd++)
close(fd);
close_all_beyond(keep_fd);
}
/*
* close_all_beyond()
*
* Close all file descriptors after the given keep_fd, which is the
* highest fd to keep open.
*/
void
close_all_beyond(
int keep_fd
)
{
# ifdef HAVE_CLOSEFROM
closefrom(keep_fd + 1);
# elif defined(F_CLOSEM)
/*
* From 'Writing Reliable AIX Daemons,' SG24-4946-00,
* by Eric Agar (saves us from doing 32767 system
* calls)
*/
if (fcntl(keep_fd + 1, F_CLOSEM, 0) == -1)
msyslog(LOG_ERR, "F_CLOSEM(%d): %m", keep_fd + 1);
# else /* !HAVE_CLOSEFROM && !F_CLOSEM follows */
int fd;
int max_fd;
max_fd = GETDTABLESIZE();
for (fd = keep_fd + 1; fd < max_fd; fd++)
close(fd);
# endif /* !HAVE_CLOSEFROM && !F_CLOSEM */
}
#endif /* HAVE_IO_COMPLETION_PORT */
u_int
available_blocking_child_slot(void)
{
const size_t each = sizeof(blocking_children[0]);
u_int slot;
size_t prev_alloc;
size_t new_alloc;
size_t prev_octets;
size_t octets;
for (slot = 0; slot < blocking_children_alloc; slot++) {
if (NULL == blocking_children[slot])
return slot;
if (blocking_children[slot]->reusable) {
blocking_children[slot]->reusable = FALSE;
return slot;
}
}
prev_alloc = blocking_children_alloc;
prev_octets = prev_alloc * each;
new_alloc = blocking_children_alloc + 4;
octets = new_alloc * each;
blocking_children = erealloc_zero(blocking_children, octets,
prev_octets);
blocking_children_alloc = new_alloc;
/* assume we'll never have enough workers to overflow u_int */
return (u_int)prev_alloc;
}
int
queue_blocking_request(
blocking_work_req rtype,
void * req,
size_t reqsize,
blocking_work_callback done_func,
void * context
)
{
static u_int intres_slot = UINT_MAX;
u_int child_slot;
blocking_child * c;
blocking_pipe_header req_hdr;
req_hdr.octets = sizeof(req_hdr) + reqsize;
req_hdr.magic_sig = BLOCKING_REQ_MAGIC;
req_hdr.rtype = rtype;
req_hdr.done_func = done_func;
req_hdr.context = context;
child_slot = UINT_MAX;
if (worker_per_query || UINT_MAX == intres_slot ||
blocking_children[intres_slot]->reusable)
child_slot = available_blocking_child_slot();
if (!worker_per_query) {
if (UINT_MAX == intres_slot)
intres_slot = child_slot;
else
child_slot = intres_slot;
if (0 == intres_req_pending)
intres_timeout_req(0);
}
intres_req_pending++;
INSIST(UINT_MAX != child_slot);
c = blocking_children[child_slot];
if (NULL == c) {
c = emalloc_zero(sizeof(*c));
#ifdef WORK_FORK
c->req_read_pipe = -1;
c->req_write_pipe = -1;
#endif
#ifdef WORK_PIPE
c->resp_read_pipe = -1;
c->resp_write_pipe = -1;
#endif
blocking_children[child_slot] = c;
}
req_hdr.child_idx = child_slot;
return send_blocking_req_internal(c, &req_hdr, req);
}
int queue_blocking_response(
blocking_child * c,
blocking_pipe_header * resp,
size_t respsize,
const blocking_pipe_header * req
)
{
resp->octets = respsize;
resp->magic_sig = BLOCKING_RESP_MAGIC;
resp->rtype = req->rtype;
resp->context = req->context;
resp->done_func = req->done_func;
return send_blocking_resp_internal(c, resp);
}
void
process_blocking_resp(
blocking_child * c
)
{
blocking_pipe_header * resp;
void * data;
/*
* On Windows send_blocking_resp_internal() may signal the
* blocking_response_ready event multiple times while we're
* processing a response, so always consume all available
* responses before returning to test the event again.
*/
#ifdef WORK_THREAD
do {
#endif
resp = receive_blocking_resp_internal(c);
if (NULL != resp) {
DEBUG_REQUIRE(BLOCKING_RESP_MAGIC ==
resp->magic_sig);
data = (char *)resp + sizeof(*resp);
intres_req_pending--;
(*resp->done_func)(resp->rtype, resp->context,
resp->octets - sizeof(*resp),
data);
free(resp);
}
#ifdef WORK_THREAD
} while (NULL != resp);
#endif
if (!worker_per_query && 0 == intres_req_pending)
intres_timeout_req(CHILD_MAX_IDLE);
else if (worker_per_query)
req_child_exit(c);
}
void
harvest_blocking_responses(void)
{
size_t idx;
blocking_child* cp;
u_int scseen, scdone;
scseen = blocking_child_ready_seen;
scdone = blocking_child_ready_done;
if (scdone != scseen) {
blocking_child_ready_done = scseen;
for (idx = 0; idx < blocking_children_alloc; idx++) {
cp = blocking_children[idx];
if (NULL == cp)
continue;
scseen = cp->resp_ready_seen;
scdone = cp->resp_ready_done;
if (scdone != scseen) {
cp->resp_ready_done = scseen;
process_blocking_resp(cp);
}
}
}
}
/*
* blocking_child_common runs as a forked child or a thread
*/
int
blocking_child_common(
blocking_child *c
)
{
int say_bye;
blocking_pipe_header *req;
say_bye = FALSE;
while (!say_bye) {
req = receive_blocking_req_internal(c);
if (NULL == req) {
say_bye = TRUE;
continue;
}
DEBUG_REQUIRE(BLOCKING_REQ_MAGIC == req->magic_sig);
switch (req->rtype) {
case BLOCKING_GETADDRINFO:
if (blocking_getaddrinfo(c, req))
say_bye = TRUE;
break;
case BLOCKING_GETNAMEINFO:
if (blocking_getnameinfo(c, req))
say_bye = TRUE;
break;
default:
msyslog(LOG_ERR, "unknown req %d to blocking worker", req->rtype);
say_bye = TRUE;
}
free(req);
}
return 0;
}
/*
* worker_idle_timer_fired()
*
* The parent starts this timer when the last pending response has been
* received from the child, making it idle, and clears the timer when a
* request is dispatched to the child. Once the timer expires, the
* child is sent packing.
*
* This is called when worker_idle_timer is nonzero and less than or
* equal to current_time.
*/
void
worker_idle_timer_fired(void)
{
u_int idx;
blocking_child * c;
DEBUG_REQUIRE(0 == intres_req_pending);
intres_timeout_req(0);
for (idx = 0; idx < blocking_children_alloc; idx++) {
c = blocking_children[idx];
if (NULL == c)
continue;
req_child_exit(c);
}
}
#else /* !WORKER follows */
int ntp_worker_nonempty_compilation_unit;
#endif