_PUBLIC_ struct tsocket_address *socket_get_local_addr(struct socket_context *sock, TALLOC_CTX *mem_ctx)
{
struct socket_address *a;
struct tsocket_address *r;
a = socket_get_my_addr(sock, mem_ctx);
if (a == NULL) {
return NULL;
}
r = socket_address_to_tsocket_address(mem_ctx, a);
talloc_free(a);
return r;
}
static struct socket_address *gensec_socket_get_my_addr(struct socket_context *sock, TALLOC_CTX *mem_ctx)
{
struct gensec_socket *gensec = talloc_get_type(sock->private_data, struct gensec_socket);
return socket_get_my_addr(gensec->socket, mem_ctx);
}
/**
basic testing of udp routines
*/
static bool test_udp(struct torture_context *tctx)
{
struct socket_context *sock1, *sock2;
NTSTATUS status;
struct socket_address *srv_addr, *from_addr, *localhost;
size_t size = 100 + (random() % 100);
DATA_BLOB blob, blob2;
size_t sent, nread;
TALLOC_CTX *mem_ctx = tctx;
struct interface *ifaces;
load_interfaces(tctx, lp_interfaces(tctx->lp_ctx), &ifaces);
status = socket_create("ip", SOCKET_TYPE_DGRAM, &sock1, 0);
torture_assert_ntstatus_ok(tctx, status, "creating DGRAM IP socket 1");
talloc_steal(mem_ctx, sock1);
status = socket_create("ip", SOCKET_TYPE_DGRAM, &sock2, 0);
torture_assert_ntstatus_ok(tctx, status, "creating DGRAM IP socket 1");
talloc_steal(mem_ctx, sock2);
localhost = socket_address_from_strings(sock1, sock1->backend_name,
iface_best_ip(ifaces, "127.0.0.1"), 0);
torture_assert(tctx, localhost, "Localhost not found");
status = socket_listen(sock1, localhost, 0, 0);
torture_assert_ntstatus_ok(tctx, status, "listen on socket 1");
srv_addr = socket_get_my_addr(sock1, mem_ctx);
torture_assert(tctx, srv_addr != NULL &&
strcmp(srv_addr->addr, iface_best_ip(ifaces, "127.0.0.1")) == 0,
talloc_asprintf(tctx,
"Expected server address of %s but got %s",
iface_best_ip(ifaces, "127.0.0.1"), srv_addr ? srv_addr->addr : NULL));
torture_comment(tctx, "server port is %d\n", srv_addr->port);
blob = data_blob_talloc(mem_ctx, NULL, size);
blob2 = data_blob_talloc(mem_ctx, NULL, size);
generate_random_buffer(blob.data, blob.length);
sent = size;
status = socket_sendto(sock2, &blob, &sent, srv_addr);
torture_assert_ntstatus_ok(tctx, status, "sendto() on socket 2");
status = socket_recvfrom(sock1, blob2.data, size, &nread,
sock1, &from_addr);
torture_assert_ntstatus_ok(tctx, status, "recvfrom() on socket 1");
torture_assert_str_equal(tctx, from_addr->addr, srv_addr->addr,
"different address");
torture_assert_int_equal(tctx, nread, size, "Unexpected recvfrom size");
torture_assert_mem_equal(tctx, blob2.data, blob.data, size,
"Bad data in recvfrom");
generate_random_buffer(blob.data, blob.length);
status = socket_sendto(sock1, &blob, &sent, from_addr);
torture_assert_ntstatus_ok(tctx, status, "sendto() on socket 1");
status = socket_recvfrom(sock2, blob2.data, size, &nread,
sock2, &from_addr);
torture_assert_ntstatus_ok(tctx, status, "recvfrom() on socket 2");
torture_assert_str_equal(tctx, from_addr->addr, srv_addr->addr,
"Unexpected recvfrom addr");
torture_assert_int_equal(tctx, nread, size, "Unexpected recvfrom size");
torture_assert_int_equal(tctx, from_addr->port, srv_addr->port,
"Unexpected recvfrom port");
torture_assert_mem_equal(tctx, blob2.data, blob.data, size,
"Bad data in recvfrom");
talloc_free(sock1);
talloc_free(sock2);
return true;
}
/*
basic testing of tcp routines
*/
static bool test_tcp(struct torture_context *tctx)
{
struct socket_context *sock1, *sock2, *sock3;
NTSTATUS status;
struct socket_address *srv_addr, *from_addr, *localhost;
size_t size = 100 + (random() % 100);
DATA_BLOB blob, blob2;
size_t sent, nread;
TALLOC_CTX *mem_ctx = tctx;
struct tevent_context *ev = tctx->ev;
struct interface *ifaces;
status = socket_create("ip", SOCKET_TYPE_STREAM, &sock1, 0);
torture_assert_ntstatus_ok(tctx, status, "creating IP stream socket 1");
talloc_steal(mem_ctx, sock1);
status = socket_create("ip", SOCKET_TYPE_STREAM, &sock2, 0);
torture_assert_ntstatus_ok(tctx, status, "creating IP stream socket 1");
talloc_steal(mem_ctx, sock2);
load_interfaces(tctx, lp_interfaces(tctx->lp_ctx), &ifaces);
localhost = socket_address_from_strings(sock1, sock1->backend_name,
iface_best_ip(ifaces, "127.0.0.1"), 0);
torture_assert(tctx, localhost, "Localhost not found");
status = socket_listen(sock1, localhost, 0, 0);
torture_assert_ntstatus_ok(tctx, status, "listen on socket 1");
srv_addr = socket_get_my_addr(sock1, mem_ctx);
torture_assert(tctx, srv_addr && srv_addr->addr,
"Unexpected socket_get_my_addr NULL\n");
torture_assert_str_equal(tctx, srv_addr->addr, iface_best_ip(ifaces, "127.0.0.1"),
"Unexpected server address");
torture_comment(tctx, "server port is %d\n", srv_addr->port);
status = socket_connect_ev(sock2, NULL, srv_addr, 0, ev);
torture_assert_ntstatus_ok(tctx, status, "connect() on socket 2");
status = socket_accept(sock1, &sock3);
torture_assert_ntstatus_ok(tctx, status, "accept() on socket 1");
talloc_steal(mem_ctx, sock3);
talloc_free(sock1);
blob = data_blob_talloc(mem_ctx, NULL, size);
blob2 = data_blob_talloc(mem_ctx, NULL, size);
generate_random_buffer(blob.data, blob.length);
sent = size;
status = socket_send(sock2, &blob, &sent);
torture_assert_ntstatus_ok(tctx, status, "send() on socket 2");
status = socket_recv(sock3, blob2.data, size, &nread);
torture_assert_ntstatus_ok(tctx, status, "recv() on socket 3");
from_addr = socket_get_peer_addr(sock3, mem_ctx);
torture_assert(tctx, from_addr && from_addr->addr,
"Unexpected recvfrom addr NULL");
torture_assert_str_equal(tctx, from_addr->addr, srv_addr->addr,
"Unexpected recvfrom addr");
torture_assert_int_equal(tctx, nread, size, "Unexpected recvfrom size");
torture_assert_mem_equal(tctx, blob2.data, blob.data, size,
"Bad data in recv");
return true;
}
/*
send a mailslot request
*/
NTSTATUS dgram_mailslot_send(struct nbt_dgram_socket *dgmsock,
enum dgram_msg_type msg_type,
const char *mailslot_name,
struct nbt_name *dest_name,
struct socket_address *dest,
struct nbt_name *src_name,
DATA_BLOB *request)
{
TALLOC_CTX *tmp_ctx = talloc_new(dgmsock);
struct nbt_dgram_packet packet;
struct dgram_message *msg;
struct dgram_smb_packet *smb;
struct smb_trans_body *trans;
struct socket_address *src;
NTSTATUS status;
if (dest->port == 0) {
return NT_STATUS_INVALID_PARAMETER;
}
ZERO_STRUCT(packet);
packet.msg_type = msg_type;
packet.flags = DGRAM_FLAG_FIRST | DGRAM_NODE_NBDD;
packet.dgram_id = generate_random() % UINT16_MAX;
src = socket_get_my_addr(dgmsock->sock, tmp_ctx);
if (!src) {
return NT_STATUS_NO_MEMORY;
}
packet.src_addr = src->addr;
packet.src_port = src->port;
msg = &packet.data.msg;
/* this length calculation is very crude - it should be based on gensize
calls */
msg->length = 138 + strlen(mailslot_name) + request->length;
msg->offset = 0;
msg->source_name = *src_name;
msg->dest_name = *dest_name;
msg->dgram_body_type = DGRAM_SMB;
smb = &msg->body.smb;
smb->smb_command = SMB_TRANSACTION;
trans = &smb->body.trans;
trans->total_data_count = request->length;
trans->timeout = 1000;
trans->data_count = request->length;
trans->data_offset = 70 + strlen(mailslot_name);
trans->opcode = 1; /* write mail slot */
trans->priority = 1;
trans->_class = 2;
trans->mailslot_name = mailslot_name;
trans->data = *request;
status = nbt_dgram_send(dgmsock, &packet, dest);
talloc_free(tmp_ctx);
return status;
}
/*
called when a listening socket becomes readable.
*/
static void standard_accept_connection(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
struct socket_context *sock,
void (*new_conn)(struct tevent_context *,
struct loadparm_context *, struct socket_context *,
struct server_id , void *),
void *private_data)
{
NTSTATUS status;
struct socket_context *sock2;
pid_t pid;
struct socket_address *c, *s;
struct standard_child_state *state;
struct tevent_fd *fde = NULL;
struct tevent_signal *se = NULL;
state = setup_standard_child_pipe(ev, NULL);
if (state == NULL) {
return;
}
/* accept an incoming connection. */
status = socket_accept(sock, &sock2);
if (!NT_STATUS_IS_OK(status)) {
DEBUG(0,("standard_accept_connection: accept: %s\n",
nt_errstr(status)));
/* this looks strange, but is correct. We need to throttle things until
the system clears enough resources to handle this new socket */
sleep(1);
close(state->to_parent_fd);
state->to_parent_fd = -1;
TALLOC_FREE(state);
return;
}
pid = fork();
if (pid != 0) {
close(state->to_parent_fd);
state->to_parent_fd = -1;
if (pid > 0) {
state->pid = pid;
} else {
TALLOC_FREE(state);
}
/* parent or error code ... */
talloc_free(sock2);
/* go back to the event loop */
return;
}
/* this leaves state->to_parent_fd open */
TALLOC_FREE(state);
pid = getpid();
/* This is now the child code. We need a completely new event_context to work with */
if (tevent_re_initialise(ev) != 0) {
smb_panic("Failed to re-initialise tevent after fork");
}
/* this will free all the listening sockets and all state that
is not associated with this new connection */
talloc_free(sock);
/* we don't care if the dup fails, as its only a select()
speed optimisation */
socket_dup(sock2);
/* tdb needs special fork handling */
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");
}
fde = tevent_add_fd(ev, ev, child_pipe[0], TEVENT_FD_READ,
standard_pipe_handler, NULL);
if (fde == NULL) {
smb_panic("Failed to add fd handler after fork");
}
if (child_pipe[1] != -1) {
close(child_pipe[1]);
child_pipe[1] = -1;
}
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");
}
/* setup the process title */
c = socket_get_peer_addr(sock2, ev);
s = socket_get_my_addr(sock2, ev);
if (s && c) {
setproctitle("conn c[%s:%u] s[%s:%u] server_id[%d]",
c->addr, c->port, s->addr, s->port, (int)pid);
}
talloc_free(c);
talloc_free(s);
/* setup this new connection. Cluster ID is PID based for this process model */
new_conn(ev, lp_ctx, sock2, cluster_id(pid, 0), private_data);
/* we can't return to the top level here, as that event context is gone,
so we now process events in the new event context until there are no
more to process */
tevent_loop_wait(ev);
talloc_free(ev);
exit(0);
}
/*
handle fd recv events on a KDC socket
*/
static void kdc_recv_handler(struct kdc_socket *kdc_socket)
{
NTSTATUS status;
TALLOC_CTX *tmp_ctx = talloc_new(kdc_socket);
DATA_BLOB blob;
struct kdc_reply *rep;
DATA_BLOB reply;
size_t nread, dsize;
struct socket_address *src;
struct socket_address *my_addr;
int ret;
status = socket_pending(kdc_socket->sock, &dsize);
if (!NT_STATUS_IS_OK(status)) {
talloc_free(tmp_ctx);
return;
}
blob = data_blob_talloc(tmp_ctx, NULL, dsize);
if (blob.data == NULL) {
/* hope this is a temporary low memory condition */
talloc_free(tmp_ctx);
return;
}
status = socket_recvfrom(kdc_socket->sock, blob.data, blob.length, &nread,
tmp_ctx, &src);
if (!NT_STATUS_IS_OK(status)) {
talloc_free(tmp_ctx);
return;
}
blob.length = nread;
DEBUG(10,("Received krb5 UDP packet of length %lu from %s:%u\n",
(long)blob.length, src->addr, (uint16_t)src->port));
my_addr = socket_get_my_addr(kdc_socket->sock, tmp_ctx);
if (!my_addr) {
talloc_free(tmp_ctx);
return;
}
/* Call krb5 */
ret = kdc_socket->process(kdc_socket->kdc,
tmp_ctx,
&blob,
&reply,
src, my_addr,
1 /* Datagram */);
if (!ret) {
talloc_free(tmp_ctx);
return;
}
/* queue a pending reply */
rep = talloc(kdc_socket, struct kdc_reply);
if (rep == NULL) {
talloc_free(tmp_ctx);
return;
}
rep->dest = talloc_steal(rep, src);
rep->packet = reply;
talloc_steal(rep, reply.data);
if (rep->packet.data == NULL) {
talloc_free(rep);
talloc_free(tmp_ctx);
return;
}
DLIST_ADD_END(kdc_socket->send_queue, rep, struct kdc_reply *);
EVENT_FD_WRITEABLE(kdc_socket->fde);
talloc_free(tmp_ctx);
}
/*
called when a listening socket becomes readable.
*/
static void standard_accept_connection(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
struct socket_context *sock,
void (*new_conn)(struct tevent_context *,
struct loadparm_context *, struct socket_context *,
struct server_id , void *),
void *private_data)
{
NTSTATUS status;
struct socket_context *sock2;
pid_t pid;
struct tevent_context *ev2;
struct socket_address *c, *s;
/* accept an incoming connection. */
status = socket_accept(sock, &sock2);
if (!NT_STATUS_IS_OK(status)) {
DEBUG(0,("standard_accept_connection: accept: %s\n",
nt_errstr(status)));
/* this looks strange, but is correct. We need to throttle things until
the system clears enough resources to handle this new socket */
sleep(1);
return;
}
pid = fork();
if (pid != 0) {
/* parent or error code ... */
talloc_free(sock2);
/* go back to the event loop */
return;
}
pid = getpid();
/* This is now the child code. We need a completely new event_context to work with */
ev2 = s4_event_context_init(NULL);
/* the service has given us a private pointer that
encapsulates the context it needs for this new connection -
everything else will be freed */
talloc_steal(ev2, private_data);
talloc_steal(private_data, sock2);
/* this will free all the listening sockets and all state that
is not associated with this new connection */
talloc_free(sock);
talloc_free(ev);
/* we don't care if the dup fails, as its only a select()
speed optimisation */
socket_dup(sock2);
/* tdb needs special fork handling */
if (tdb_reopen_all(1) == -1) {
DEBUG(0,("standard_accept_connection: tdb_reopen_all failed.\n"));
}
/* Ensure that the forked children do not expose identical random streams */
set_need_random_reseed();
/* setup the process title */
c = socket_get_peer_addr(sock2, ev2);
s = socket_get_my_addr(sock2, ev2);
if (s && c) {
setproctitle("conn c[%s:%u] s[%s:%u] server_id[%d]",
c->addr, c->port, s->addr, s->port, pid);
}
talloc_free(c);
talloc_free(s);
/* setup this new connection. Cluster ID is PID based for this process modal */
new_conn(ev2, lp_ctx, sock2, cluster_id(pid, 0), private_data);
/* we can't return to the top level here, as that event context is gone,
so we now process events in the new event context until there are no
more to process */
event_loop_wait(ev2);
talloc_free(ev2);
exit(0);
}
/*
initialise a server_context from a open socket and register a event handler
for reading from that socket
*/
static void ldapsrv_accept(struct stream_connection *c,
struct auth_session_info *session_info)
{
struct ldapsrv_service *ldapsrv_service =
talloc_get_type(c->private_data, struct ldapsrv_service);
struct ldapsrv_connection *conn;
struct cli_credentials *server_credentials;
struct socket_address *socket_address;
NTSTATUS status;
int port;
conn = talloc_zero(c, struct ldapsrv_connection);
if (!conn) {
stream_terminate_connection(c, "ldapsrv_accept: out of memory");
return;
}
conn->packet = NULL;
conn->connection = c;
conn->service = ldapsrv_service;
conn->sockets.raw = c->socket;
conn->lp_ctx = ldapsrv_service->task->lp_ctx;
c->private_data = conn;
socket_address = socket_get_my_addr(c->socket, conn);
if (!socket_address) {
ldapsrv_terminate_connection(conn, "ldapsrv_accept: failed to obtain local socket address!");
return;
}
port = socket_address->port;
talloc_free(socket_address);
if (port == 636) {
struct socket_context *tls_socket = tls_init_server(ldapsrv_service->tls_params, c->socket,
c->event.fde, NULL);
if (!tls_socket) {
ldapsrv_terminate_connection(conn, "ldapsrv_accept: tls_init_server() failed");
return;
}
talloc_steal(c, tls_socket);
c->socket = tls_socket;
conn->sockets.tls = tls_socket;
} else if (port == 3268) /* Global catalog */ {
conn->global_catalog = true;
}
conn->packet = packet_init(conn);
if (conn->packet == NULL) {
ldapsrv_terminate_connection(conn, "out of memory");
return;
}
packet_set_private(conn->packet, conn);
packet_set_socket(conn->packet, c->socket);
packet_set_callback(conn->packet, ldapsrv_decode);
packet_set_full_request(conn->packet, ldap_full_packet);
packet_set_error_handler(conn->packet, ldapsrv_error_handler);
packet_set_event_context(conn->packet, c->event.ctx);
packet_set_fde(conn->packet, c->event.fde);
packet_set_serialise(conn->packet);
if (conn->sockets.tls) {
packet_set_unreliable_select(conn->packet);
}
/* Ensure we don't get packets until the database is ready below */
packet_recv_disable(conn->packet);
server_credentials = cli_credentials_init(conn);
if (!server_credentials) {
stream_terminate_connection(c, "Failed to init server credentials\n");
return;
}
cli_credentials_set_conf(server_credentials, conn->lp_ctx);
status = cli_credentials_set_machine_account(server_credentials, conn->lp_ctx);
if (!NT_STATUS_IS_OK(status)) {
stream_terminate_connection(c, talloc_asprintf(conn, "Failed to obtain server credentials, perhaps a standalone server?: %s\n", nt_errstr(status)));
return;
}
conn->server_credentials = server_credentials;
conn->session_info = talloc_move(conn, &session_info);
if (!NT_STATUS_IS_OK(ldapsrv_backend_Init(conn))) {
ldapsrv_terminate_connection(conn, "backend Init failed");
return;
}
/* load limits from the conf partition */
ldapsrv_load_limits(conn); /* should we fail on error ? */
/* register the server */
irpc_add_name(c->msg_ctx, "ldap_server");
/* set connections limits */
conn->limits.ite = event_add_timed(c->event.ctx, conn,
timeval_current_ofs(conn->limits.initial_timeout, 0),
ldapsrv_conn_init_timeout, conn);
packet_recv_enable(conn->packet);
}
/*
initialise a server_context from a open socket and register a event handler
for reading from that socket
*/
static void ldapsrv_accept(struct stream_connection *c,
struct auth_session_info *session_info,
bool is_privileged)
{
struct ldapsrv_service *ldapsrv_service =
talloc_get_type(c->private_data, struct ldapsrv_service);
struct ldapsrv_connection *conn;
struct cli_credentials *server_credentials;
struct socket_address *socket_address;
NTSTATUS status;
int port;
int ret;
struct tevent_req *subreq;
struct timeval endtime;
conn = talloc_zero(c, struct ldapsrv_connection);
if (!conn) {
stream_terminate_connection(c, "ldapsrv_accept: out of memory");
return;
}
conn->is_privileged = is_privileged;
conn->sockets.send_queue = tevent_queue_create(conn, "ldapsev send queue");
if (conn->sockets.send_queue == NULL) {
stream_terminate_connection(c,
"ldapsrv_accept: tevent_queue_create failed");
return;
}
TALLOC_FREE(c->event.fde);
ret = tstream_bsd_existing_socket(conn,
socket_get_fd(c->socket),
&conn->sockets.raw);
if (ret == -1) {
stream_terminate_connection(c,
"ldapsrv_accept: out of memory");
return;
}
socket_set_flags(c->socket, SOCKET_FLAG_NOCLOSE);
conn->connection = c;
conn->service = ldapsrv_service;
conn->lp_ctx = ldapsrv_service->task->lp_ctx;
c->private_data = conn;
socket_address = socket_get_my_addr(c->socket, conn);
if (!socket_address) {
ldapsrv_terminate_connection(conn, "ldapsrv_accept: failed to obtain local socket address!");
return;
}
port = socket_address->port;
talloc_free(socket_address);
if (port == 3268 || port == 3269) /* Global catalog */ {
conn->global_catalog = true;
}
server_credentials = cli_credentials_init(conn);
if (!server_credentials) {
stream_terminate_connection(c, "Failed to init server credentials\n");
return;
}
cli_credentials_set_conf(server_credentials, conn->lp_ctx);
status = cli_credentials_set_machine_account(server_credentials, conn->lp_ctx);
if (!NT_STATUS_IS_OK(status)) {
stream_terminate_connection(c, talloc_asprintf(conn, "Failed to obtain server credentials, perhaps a standalone server?: %s\n", nt_errstr(status)));
return;
}
conn->server_credentials = server_credentials;
conn->session_info = session_info;
if (!NT_STATUS_IS_OK(ldapsrv_backend_Init(conn))) {
ldapsrv_terminate_connection(conn, "backend Init failed");
return;
}
/* load limits from the conf partition */
ldapsrv_load_limits(conn); /* should we fail on error ? */
/* register the server */
irpc_add_name(c->msg_ctx, "ldap_server");
conn->sockets.active = conn->sockets.raw;
if (port != 636 && port != 3269) {
ldapsrv_call_read_next(conn);
return;
}
endtime = timeval_current_ofs(conn->limits.conn_idle_time, 0);
subreq = tstream_tls_accept_send(conn,
conn->connection->event.ctx,
conn->sockets.raw,
conn->service->tls_params);
if (subreq == NULL) {
ldapsrv_terminate_connection(conn, "ldapsrv_accept: "
"no memory for tstream_tls_accept_send");
return;
}
tevent_req_set_endtime(subreq,
conn->connection->event.ctx,
endtime);
tevent_req_set_callback(subreq, ldapsrv_accept_tls_done, conn);
}
/*
called when a listening socket becomes readable.
*/
static void standard_accept_connection(struct tevent_context *ev,
struct loadparm_context *lp_ctx,
struct socket_context *sock,
void (*new_conn)(struct tevent_context *,
struct loadparm_context *, struct socket_context *,
struct server_id , void *),
void *private_data)
{
NTSTATUS status;
struct socket_context *sock2;
pid_t pid;
struct socket_address *c, *s;
/* accept an incoming connection. */
status = socket_accept(sock, &sock2);
if (!NT_STATUS_IS_OK(status)) {
DEBUG(0,("standard_accept_connection: accept: %s\n",
nt_errstr(status)));
/* this looks strange, but is correct. We need to throttle things until
the system clears enough resources to handle this new socket */
sleep(1);
return;
}
pid = fork();
if (pid != 0) {
/* parent or error code ... */
talloc_free(sock2);
/* go back to the event loop */
return;
}
pid = getpid();
/* This is now the child code. We need a completely new event_context to work with */
if (tevent_re_initialise(ev) != 0) {
smb_panic("Failed to re-initialise tevent after fork");
}
/* this will free all the listening sockets and all state that
is not associated with this new connection */
talloc_free(sock);
/* we don't care if the dup fails, as its only a select()
speed optimisation */
socket_dup(sock2);
/* tdb needs special fork handling */
ldb_wrap_fork_hook();
tevent_add_fd(ev, ev, child_pipe[0], TEVENT_FD_READ,
standard_pipe_handler, NULL);
close(child_pipe[1]);
/* Ensure that the forked children do not expose identical random streams */
set_need_random_reseed();
/* setup the process title */
c = socket_get_peer_addr(sock2, ev);
s = socket_get_my_addr(sock2, ev);
if (s && c) {
setproctitle("conn c[%s:%u] s[%s:%u] server_id[%d]",
c->addr, c->port, s->addr, s->port, (int)pid);
}
talloc_free(c);
talloc_free(s);
/* setup this new connection. Cluster ID is PID based for this process model */
new_conn(ev, lp_ctx, sock2, cluster_id(pid, 0), private_data);
/* we can't return to the top level here, as that event context is gone,
so we now process events in the new event context until there are no
more to process */
tevent_loop_wait(ev);
talloc_free(ev);
exit(0);
}
/*
called when we get a new connection
*/
static void kdc_tcp_accept(struct stream_connection *conn)
{
struct kdc_socket *kdc_socket = talloc_get_type(conn->private_data, struct kdc_socket);
struct kdc_tcp_connection *kdcconn;
struct socket_address *src_addr;
struct socket_address *my_addr;
int ret;
kdcconn = talloc_zero(conn, struct kdc_tcp_connection);
if (!kdcconn) {
stream_terminate_connection(conn, "kdc_tcp_accept: out of memory");
return;
}
kdcconn->conn = conn;
kdcconn->kdc_socket = kdc_socket;
conn->private_data = kdcconn;
src_addr = socket_get_peer_addr(kdcconn->conn->socket, kdcconn);
if (!src_addr) {
kdc_tcp_terminate_connection(kdcconn, "kdc_tcp_accept: out of memory");
return;
}
my_addr = socket_get_my_addr(kdcconn->conn->socket, kdcconn);
if (!my_addr) {
kdc_tcp_terminate_connection(kdcconn, "kdc_tcp_accept: out of memory");
return;
}
ret = tsocket_address_bsd_from_sockaddr(kdcconn,
src_addr->sockaddr,
src_addr->sockaddrlen,
&kdcconn->remote_address);
if (ret < 0) {
kdc_tcp_terminate_connection(kdcconn, "kdc_tcp_accept: out of memory");
return;
}
ret = tsocket_address_bsd_from_sockaddr(kdcconn,
my_addr->sockaddr,
my_addr->sockaddrlen,
&kdcconn->local_address);
if (ret < 0) {
kdc_tcp_terminate_connection(kdcconn, "kdc_tcp_accept: out of memory");
return;
}
TALLOC_FREE(src_addr);
TALLOC_FREE(my_addr);
kdcconn->packet = packet_init(kdcconn);
if (kdcconn->packet == NULL) {
kdc_tcp_terminate_connection(kdcconn, "kdc_tcp_accept: out of memory");
return;
}
packet_set_private(kdcconn->packet, kdcconn);
packet_set_socket(kdcconn->packet, conn->socket);
packet_set_callback(kdcconn->packet, kdc_tcp_recv);
packet_set_full_request(kdcconn->packet, packet_full_request_u32);
packet_set_error_handler(kdcconn->packet, kdc_tcp_recv_error);
packet_set_event_context(kdcconn->packet, conn->event.ctx);
packet_set_fde(kdcconn->packet, conn->event.fde);
packet_set_serialise(kdcconn->packet);
}
