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bind/lib/isc/netmgr/tlsdns.c
Ondřej Surý b432d5d3bc Gracefully handle uv_read_start() failures 
Under specific rare timing circumstances the uv_read_start() could
fail with UV_EINVAL when the connection is reset between the connect (or
accept) and the uv_read_start() call on the nmworker loop.  Handle such
situation gracefully by propagating the errors from uv_read_start() into
upper layers, so the socket can be internally closed().
2022-06-14 11:33:02 +02:00

2231 lines
54 KiB
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/*
* Copyright (C) Internet Systems Consortium, Inc. ("ISC")
*
* SPDX-License-Identifier: MPL-2.0
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, you can obtain one at https://mozilla.org/MPL/2.0/.
*
* See the COPYRIGHT file distributed with this work for additional
* information regarding copyright ownership.
*/
#include <libgen.h>
#include <unistd.h>
#include <isc/atomic.h>
#include <isc/barrier.h>
#include <isc/buffer.h>
#include <isc/condition.h>
#include <isc/errno.h>
#include <isc/log.h>
#include <isc/magic.h>
#include <isc/mem.h>
#include <isc/netmgr.h>
#include <isc/quota.h>
#include <isc/random.h>
#include <isc/refcount.h>
#include <isc/region.h>
#include <isc/result.h>
#include <isc/sockaddr.h>
#include <isc/stdtime.h>
#include <isc/thread.h>
#include <isc/util.h>
#include <isc/uv.h>
#include "netmgr-int.h"
#include "openssl_shim.h"
static atomic_uint_fast32_t last_tlsdnsquota_log = 0;
static void
tls_error(isc_nmsocket_t *sock, isc_result_t result);
static isc_result_t
tlsdns_connect_direct(isc_nmsocket_t *sock, isc__nm_uvreq_t *req);
static void
tlsdns_close_direct(isc_nmsocket_t *sock);
static isc_result_t
tlsdns_send_direct(isc_nmsocket_t *sock, isc__nm_uvreq_t *req);
static void
tlsdns_connect_cb(uv_connect_t *uvreq, int status);
static void
tlsdns_connection_cb(uv_stream_t *server, int status);
static void
tlsdns_close_cb(uv_handle_t *uvhandle);
static isc_result_t
accept_connection(isc_nmsocket_t *ssock, isc_quota_t *quota);
static void
quota_accept_cb(isc_quota_t *quota, void *sock0);
static void
stop_tlsdns_parent(isc_nmsocket_t *sock);
static void
stop_tlsdns_child(isc_nmsocket_t *sock);
static void
async_tlsdns_cycle(isc_nmsocket_t *sock) __attribute__((unused));
static isc_result_t
tls_cycle(isc_nmsocket_t *sock);
static void
call_pending_send_callbacks(isc_nmsocket_t *sock, const isc_result_t result);
static void
tlsdns_keep_client_tls_session(isc_nmsocket_t *sock);
static void
tlsdns_set_tls_shutdown(isc_tls_t *tls) {
(void)SSL_set_shutdown(tls, SSL_SENT_SHUTDOWN);
}
static bool
peer_verification_has_failed(isc_nmsocket_t *sock) {
if (sock->tls.tls != NULL && sock->tls.state == TLS_STATE_HANDSHAKE &&
SSL_get_verify_result(sock->tls.tls) != X509_V_OK)
{
return (true);
}
return (false);
}
static bool
can_log_tlsdns_quota(void) {
isc_stdtime_t now, last;
isc_stdtime_get(&now);
last = atomic_exchange_relaxed(&last_tlsdnsquota_log, now);
if (now != last) {
return (true);
}
return (false);
}
static isc_result_t
tlsdns_connect_direct(isc_nmsocket_t *sock, isc__nm_uvreq_t *req) {
isc__networker_t *worker = NULL;
isc_result_t result = ISC_R_UNSET;
int r;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(VALID_UVREQ(req));
REQUIRE(isc__nm_in_netthread());
REQUIRE(sock->tid == isc_nm_tid());
worker = &sock->mgr->workers[sock->tid];
atomic_store(&sock->connecting, true);
/* 2 minute timeout */
result = isc__nm_socket_connectiontimeout(sock->fd, 120 * 1000);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
r = uv_tcp_init(&worker->loop, &sock->uv_handle.tcp);
UV_RUNTIME_CHECK(uv_tcp_init, r);
uv_handle_set_data(&sock->uv_handle.handle, sock);
r = uv_timer_init(&worker->loop, &sock->read_timer);
UV_RUNTIME_CHECK(uv_timer_init, r);
uv_handle_set_data((uv_handle_t *)&sock->read_timer, sock);
if (isc__nm_closing(sock)) {
result = ISC_R_SHUTTINGDOWN;
goto error;
}
r = uv_tcp_open(&sock->uv_handle.tcp, sock->fd);
if (r != 0) {
isc__nm_closesocket(sock->fd);
isc__nm_incstats(sock, STATID_OPENFAIL);
goto done;
}
isc__nm_incstats(sock, STATID_OPEN);
if (req->local.length != 0) {
r = uv_tcp_bind(&sock->uv_handle.tcp, &req->local.type.sa, 0);
/*
* In case of shared socket UV_EINVAL will be returned and needs
* to be ignored
*/
if (r != 0 && r != UV_EINVAL) {
isc__nm_incstats(sock, STATID_BINDFAIL);
goto done;
}
}
isc__nm_set_network_buffers(sock->mgr, &sock->uv_handle.handle);
uv_handle_set_data(&req->uv_req.handle, req);
r = uv_tcp_connect(&req->uv_req.connect, &sock->uv_handle.tcp,
&req->peer.type.sa, tlsdns_connect_cb);
if (r != 0) {
isc__nm_incstats(sock, STATID_CONNECTFAIL);
goto done;
}
isc__nm_incstats(sock, STATID_CONNECT);
uv_handle_set_data((uv_handle_t *)&sock->read_timer,
&req->uv_req.connect);
isc__nmsocket_timer_start(sock);
atomic_store(&sock->connected, true);
done:
result = isc_uverr2result(r);
error:
LOCK(&sock->lock);
sock->result = result;
SIGNAL(&sock->cond);
if (!atomic_load(&sock->active)) {
WAIT(&sock->scond, &sock->lock);
}
INSIST(atomic_load(&sock->active));
UNLOCK(&sock->lock);
return (result);
}
void
isc__nm_async_tlsdnsconnect(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsconnect_t *ievent =
(isc__netievent_tlsdnsconnect_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
isc__nm_uvreq_t *req = ievent->req;
isc_result_t result = ISC_R_SUCCESS;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(sock->parent == NULL);
REQUIRE(sock->tid == isc_nm_tid());
result = tlsdns_connect_direct(sock, req);
if (result != ISC_R_SUCCESS) {
INSIST(atomic_compare_exchange_strong(&sock->connecting,
&(bool){ true }, false));
isc__nmsocket_clearcb(sock);
isc__nm_connectcb(sock, req, result, true);
atomic_store(&sock->active, false);
isc__nm_tlsdns_close(sock);
}
/*
* The sock is now attached to the handle.
*/
isc__nmsocket_detach(&sock);
}
static void
tlsdns_connect_cb(uv_connect_t *uvreq, int status) {
isc_result_t result;
isc__nm_uvreq_t *req = NULL;
isc_nmsocket_t *sock = uv_handle_get_data((uv_handle_t *)uvreq->handle);
struct sockaddr_storage ss;
int r;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
req = uv_handle_get_data((uv_handle_t *)uvreq);
REQUIRE(VALID_UVREQ(req));
REQUIRE(VALID_NMHANDLE(req->handle));
if (atomic_load(&sock->timedout)) {
result = ISC_R_TIMEDOUT;
goto error;
}
if (isc__nm_closing(sock)) {
/* Network manager shutting down */
result = ISC_R_SHUTTINGDOWN;
goto error;
} else if (isc__nmsocket_closing(sock)) {
/* Connection canceled */
result = ISC_R_CANCELED;
goto error;
} else if (status == UV_ETIMEDOUT) {
/* Timeout status code here indicates hard error */
result = ISC_R_TIMEDOUT;
goto error;
} else if (status != 0) {
result = isc_uverr2result(status);
goto error;
}
isc__nm_incstats(sock, STATID_CONNECT);
r = uv_tcp_getpeername(&sock->uv_handle.tcp, (struct sockaddr *)&ss,
&(int){ sizeof(ss) });
if (r != 0) {
result = isc_uverr2result(r);
goto error;
}
sock->tls.state = TLS_STATE_NONE;
sock->tls.tls = isc_tls_create(sock->tls.ctx);
RUNTIME_CHECK(sock->tls.tls != NULL);
/*
*
*/
r = BIO_new_bio_pair(&sock->tls.ssl_wbio, ISC_NETMGR_TCP_RECVBUF_SIZE,
&sock->tls.app_rbio, ISC_NETMGR_TCP_RECVBUF_SIZE);
RUNTIME_CHECK(r == 1);
r = BIO_new_bio_pair(&sock->tls.ssl_rbio, ISC_NETMGR_TCP_RECVBUF_SIZE,
&sock->tls.app_wbio, ISC_NETMGR_TCP_RECVBUF_SIZE);
RUNTIME_CHECK(r == 1);
#if HAVE_SSL_SET0_RBIO && HAVE_SSL_SET0_WBIO
/*
* Note that if the rbio and wbio are the same then
* SSL_set0_rbio() and SSL_set0_wbio() each take ownership of
* one reference. Therefore it may be necessary to increment the
* number of references available using BIO_up_ref(3) before
* calling the set0 functions.
*/
SSL_set0_rbio(sock->tls.tls, sock->tls.ssl_rbio);
SSL_set0_wbio(sock->tls.tls, sock->tls.ssl_wbio);
#else
SSL_set_bio(sock->tls.tls, sock->tls.ssl_rbio, sock->tls.ssl_wbio);
#endif
result = isc_sockaddr_fromsockaddr(&sock->peer, (struct sockaddr *)&ss);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
if (sock->tls.client_sess_cache != NULL) {
isc_tlsctx_client_session_cache_reuse_sockaddr(
sock->tls.client_sess_cache, &sock->peer,
sock->tls.tls);
}
SSL_set_connect_state(sock->tls.tls);
/* Setting pending req */
sock->tls.pending_req = req;
result = isc__nm_process_sock_buffer(sock);
if (result != ISC_R_SUCCESS) {
sock->tls.pending_req = NULL;
goto error;
}
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
sock->tls.pending_req = NULL;
goto error;
}
return;
error:
isc__nm_failed_connect_cb(sock, req, result, false);
}
void
isc_nm_tlsdnsconnect(isc_nm_t *mgr, isc_sockaddr_t *local, isc_sockaddr_t *peer,
isc_nm_cb_t cb, void *cbarg, unsigned int timeout,
isc_tlsctx_t *sslctx,
isc_tlsctx_client_session_cache_t *client_sess_cache) {
isc_result_t result = ISC_R_SUCCESS;
isc_nmsocket_t *sock = NULL;
isc__netievent_tlsdnsconnect_t *ievent = NULL;
isc__nm_uvreq_t *req = NULL;
sa_family_t sa_family;
REQUIRE(VALID_NM(mgr));
REQUIRE(local != NULL);
REQUIRE(peer != NULL);
REQUIRE(sslctx != NULL);
sa_family = peer->type.sa.sa_family;
sock = isc_mem_get(mgr->mctx, sizeof(*sock));
isc__nmsocket_init(sock, mgr, isc_nm_tlsdnssocket, local);
sock->connect_timeout = timeout;
sock->result = ISC_R_UNSET;
isc_tlsctx_attach(sslctx, &sock->tls.ctx);
atomic_init(&sock->client, true);
atomic_init(&sock->connecting, true);
req = isc__nm_uvreq_get(mgr, sock);
req->cb.connect = cb;
req->cbarg = cbarg;
req->peer = *peer;
req->local = *local;
req->handle = isc__nmhandle_get(sock, &req->peer, &sock->iface);
if (client_sess_cache != NULL) {
INSIST(isc_tlsctx_client_session_cache_getctx(
client_sess_cache) == sslctx);
isc_tlsctx_client_session_cache_attach(
client_sess_cache, &sock->tls.client_sess_cache);
}
result = isc__nm_socket(sa_family, SOCK_STREAM, 0, &sock->fd);
if (result != ISC_R_SUCCESS) {
goto failure;
}
if (isc__nm_closing(sock)) {
result = ISC_R_SHUTTINGDOWN;
goto failure;
}
(void)isc__nm_socket_min_mtu(sock->fd, sa_family);
(void)isc__nm_socket_tcp_maxseg(sock->fd, NM_MAXSEG);
/* 2 minute timeout */
result = isc__nm_socket_connectiontimeout(sock->fd, 120 * 1000);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
ievent = isc__nm_get_netievent_tlsdnsconnect(mgr, sock, req);
if (isc__nm_in_netthread()) {
atomic_store(&sock->active, true);
sock->tid = isc_nm_tid();
isc__nm_async_tlsdnsconnect(&mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
isc__nm_put_netievent_tlsdnsconnect(mgr, ievent);
} else {
atomic_init(&sock->active, false);
sock->tid = isc_random_uniform(mgr->nworkers);
isc__nm_enqueue_ievent(&mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
LOCK(&sock->lock);
while (sock->result == ISC_R_UNSET) {
WAIT(&sock->cond, &sock->lock);
}
atomic_store(&sock->active, true);
BROADCAST(&sock->scond);
UNLOCK(&sock->lock);
return;
failure:
if (isc__nm_in_netthread()) {
sock->tid = isc_nm_tid();
}
INSIST(atomic_compare_exchange_strong(&sock->connecting,
&(bool){ true }, false));
isc__nmsocket_clearcb(sock);
isc__nm_connectcb(sock, req, result, true);
atomic_store(&sock->closed, true);
isc__nmsocket_detach(&sock);
}
static uv_os_sock_t
isc__nm_tlsdns_lb_socket(isc_nm_t *mgr, sa_family_t sa_family) {
isc_result_t result;
uv_os_sock_t sock;
result = isc__nm_socket(sa_family, SOCK_STREAM, 0, &sock);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
(void)isc__nm_socket_incoming_cpu(sock);
(void)isc__nm_socket_v6only(sock, sa_family);
/* FIXME: set mss */
result = isc__nm_socket_reuse(sock);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
if (mgr->load_balance_sockets) {
result = isc__nm_socket_reuse_lb(sock);
RUNTIME_CHECK(result == ISC_R_SUCCESS);
}
return (sock);
}
static void
start_tlsdns_child(isc_nm_t *mgr, isc_sockaddr_t *iface, isc_nmsocket_t *sock,
uv_os_sock_t fd, int tid) {
isc__netievent_tlsdnslisten_t *ievent = NULL;
isc_nmsocket_t *csock = &sock->children[tid];
isc__nmsocket_init(csock, mgr, isc_nm_tlsdnssocket, iface);
csock->parent = sock;
csock->accept_cb = sock->accept_cb;
csock->accept_cbarg = sock->accept_cbarg;
csock->recv_cb = sock->recv_cb;
csock->recv_cbarg = sock->recv_cbarg;
csock->backlog = sock->backlog;
csock->tid = tid;
isc_tlsctx_attach(sock->tls.ctx, &csock->tls.ctx);
/*
* We don't attach to quota, just assign - to avoid
* increasing quota unnecessarily.
*/
csock->pquota = sock->pquota;
isc_quota_cb_init(&csock->quotacb, quota_accept_cb, csock);
if (mgr->load_balance_sockets) {
UNUSED(fd);
csock->fd = isc__nm_tlsdns_lb_socket(mgr,
iface->type.sa.sa_family);
} else {
csock->fd = dup(fd);
}
REQUIRE(csock->fd >= 0);
ievent = isc__nm_get_netievent_tlsdnslisten(mgr, csock);
isc__nm_maybe_enqueue_ievent(&mgr->workers[tid],
(isc__netievent_t *)ievent);
}
static void
enqueue_stoplistening(isc_nmsocket_t *sock) {
isc__netievent_tlsdnsstop_t *ievent =
isc__nm_get_netievent_tlsdnsstop(sock->mgr, sock);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
isc_result_t
isc_nm_listentlsdns(isc_nm_t *mgr, uint32_t workers, isc_sockaddr_t *iface,
isc_nm_recv_cb_t recv_cb, void *recv_cbarg,
isc_nm_accept_cb_t accept_cb, void *accept_cbarg,
int backlog, isc_quota_t *quota, isc_tlsctx_t *sslctx,
isc_nmsocket_t **sockp) {
isc_result_t result = ISC_R_SUCCESS;
isc_nmsocket_t *sock = NULL;
size_t children_size = 0;
uv_os_sock_t fd = -1;
REQUIRE(VALID_NM(mgr));
sock = isc_mem_get(mgr->mctx, sizeof(*sock));
isc__nmsocket_init(sock, mgr, isc_nm_tlsdnslistener, iface);
atomic_init(&sock->rchildren, 0);
sock->nchildren = (workers == ISC_NM_LISTEN_ALL)
? (uint32_t)mgr->nworkers
: workers;
children_size = sock->nchildren * sizeof(sock->children[0]);
sock->children = isc_mem_get(mgr->mctx, children_size);
memset(sock->children, 0, children_size);
sock->result = ISC_R_UNSET;
sock->accept_cb = accept_cb;
sock->accept_cbarg = accept_cbarg;
sock->recv_cb = recv_cb;
sock->recv_cbarg = recv_cbarg;
sock->backlog = backlog;
sock->pquota = quota;
isc_tlsctx_attach(sslctx, &sock->tls.ctx);
sock->tid = 0;
sock->fd = -1;
if (!mgr->load_balance_sockets) {
fd = isc__nm_tlsdns_lb_socket(mgr, iface->type.sa.sa_family);
}
isc_barrier_init(&sock->startlistening, sock->nchildren);
for (size_t i = 0; i < sock->nchildren; i++) {
if ((int)i == isc_nm_tid()) {
continue;
}
start_tlsdns_child(mgr, iface, sock, fd, i);
}
if (isc__nm_in_netthread()) {
start_tlsdns_child(mgr, iface, sock, fd, isc_nm_tid());
}
if (!mgr->load_balance_sockets) {
isc__nm_closesocket(fd);
}
LOCK(&sock->lock);
while (atomic_load(&sock->rchildren) != sock->nchildren) {
WAIT(&sock->cond, &sock->lock);
}
result = sock->result;
atomic_store(&sock->active, true);
UNLOCK(&sock->lock);
INSIST(result != ISC_R_UNSET);
if (result == ISC_R_SUCCESS) {
REQUIRE(atomic_load(&sock->rchildren) == sock->nchildren);
*sockp = sock;
} else {
atomic_store(&sock->active, false);
enqueue_stoplistening(sock);
isc_nmsocket_close(&sock);
}
return (result);
}
void
isc__nm_async_tlsdnslisten(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnslisten_t *ievent =
(isc__netievent_tlsdnslisten_t *)ev0;
sa_family_t sa_family;
int r;
int flags = 0;
isc_nmsocket_t *sock = NULL;
isc_result_t result = ISC_R_UNSET;
isc_nm_t *mgr;
REQUIRE(VALID_NMSOCK(ievent->sock));
REQUIRE(ievent->sock->tid == isc_nm_tid());
REQUIRE(VALID_NMSOCK(ievent->sock->parent));
sock = ievent->sock;
sa_family = sock->iface.type.sa.sa_family;
mgr = sock->mgr;
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(sock->parent != NULL);
REQUIRE(sock->tid == isc_nm_tid());
(void)isc__nm_socket_min_mtu(sock->fd, sa_family);
(void)isc__nm_socket_tcp_maxseg(sock->fd, NM_MAXSEG);
r = uv_tcp_init(&worker->loop, &sock->uv_handle.tcp);
UV_RUNTIME_CHECK(uv_tcp_init, r);
uv_handle_set_data(&sock->uv_handle.handle, sock);
/* This keeps the socket alive after everything else is gone */
isc__nmsocket_attach(sock, &(isc_nmsocket_t *){ NULL });
r = uv_timer_init(&worker->loop, &sock->read_timer);
UV_RUNTIME_CHECK(uv_timer_init, r);
uv_handle_set_data((uv_handle_t *)&sock->read_timer, sock);
LOCK(&sock->parent->lock);
r = uv_tcp_open(&sock->uv_handle.tcp, sock->fd);
if (r < 0) {
isc__nm_closesocket(sock->fd);
isc__nm_incstats(sock, STATID_OPENFAIL);
goto done;
}
isc__nm_incstats(sock, STATID_OPEN);
if (sa_family == AF_INET6) {
flags = UV_TCP_IPV6ONLY;
}
if (mgr->load_balance_sockets) {
r = isc__nm_tcp_freebind(&sock->uv_handle.tcp,
&sock->iface.type.sa, flags);
if (r < 0) {
isc__nm_incstats(sock, STATID_BINDFAIL);
goto done;
}
} else {
if (sock->parent->fd == -1) {
r = isc__nm_tcp_freebind(&sock->uv_handle.tcp,
&sock->iface.type.sa, flags);
if (r < 0) {
isc__nm_incstats(sock, STATID_BINDFAIL);
goto done;
}
sock->parent->uv_handle.tcp.flags =
sock->uv_handle.tcp.flags;
sock->parent->fd = sock->fd;
} else {
/* The socket is already bound, just copy the flags */
sock->uv_handle.tcp.flags =
sock->parent->uv_handle.tcp.flags;
}
}
isc__nm_set_network_buffers(sock->mgr, &sock->uv_handle.handle);
/*
* The callback will run in the same thread uv_listen() was
* called from, so a race with tlsdns_connection_cb() isn't
* possible.
*/
r = uv_listen((uv_stream_t *)&sock->uv_handle.tcp, sock->backlog,
tlsdns_connection_cb);
if (r != 0) {
isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL,
ISC_LOGMODULE_NETMGR, ISC_LOG_ERROR,
"uv_listen failed: %s",
isc_result_totext(isc_uverr2result(r)));
isc__nm_incstats(sock, STATID_BINDFAIL);
goto done;
}
atomic_store(&sock->listening, true);
done:
result = isc_uverr2result(r);
if (result != ISC_R_SUCCESS) {
sock->pquota = NULL;
}
atomic_fetch_add(&sock->parent->rchildren, 1);
if (sock->parent->result == ISC_R_UNSET) {
sock->parent->result = result;
}
SIGNAL(&sock->parent->cond);
UNLOCK(&sock->parent->lock);
isc_barrier_wait(&sock->parent->startlistening);
}
static void
tlsdns_connection_cb(uv_stream_t *server, int status) {
isc_nmsocket_t *ssock = uv_handle_get_data((uv_handle_t *)server);
isc_result_t result;
isc_quota_t *quota = NULL;
if (status != 0) {
result = isc_uverr2result(status);
goto done;
}
REQUIRE(VALID_NMSOCK(ssock));
REQUIRE(ssock->tid == isc_nm_tid());
if (isc__nmsocket_closing(ssock)) {
result = ISC_R_CANCELED;
goto done;
}
if (ssock->pquota != NULL) {
result = isc_quota_attach_cb(ssock->pquota, &quota,
&ssock->quotacb);
if (result == ISC_R_QUOTA) {
isc__nm_incstats(ssock, STATID_ACCEPTFAIL);
goto done;
}
}
result = accept_connection(ssock, quota);
done:
isc__nm_accept_connection_log(result, can_log_tlsdns_quota());
}
void
isc__nm_tlsdns_stoplistening(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnslistener);
if (!atomic_compare_exchange_strong(&sock->closing, &(bool){ false },
true)) {
UNREACHABLE();
}
if (!isc__nm_in_netthread()) {
enqueue_stoplistening(sock);
} else {
stop_tlsdns_parent(sock);
}
}
static void
tls_shutdown(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
isc__netievent_tlsdnsshutdown_t *ievent =
isc__nm_get_netievent_tlsdnsshutdown(sock->mgr, sock);
isc__nm_maybe_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
void
isc__nm_async_tlsdnsshutdown(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsshutdown_t *ievent =
(isc__netievent_tlsdnsshutdown_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
int rv;
int err;
isc_result_t result;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(ievent->sock));
if (sock->tls.state != TLS_STATE_IO) {
/* Nothing to do */
return;
}
rv = SSL_shutdown(sock->tls.tls);
if (rv == 1) {
sock->tls.state = TLS_STATE_NONE;
/* FIXME: continue closing the socket */
return;
}
if (rv == 0) {
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
tls_error(sock, result);
return;
}
/* Reschedule closing the socket */
tls_shutdown(sock);
return;
}
err = SSL_get_error(sock->tls.tls, rv);
switch (err) {
case SSL_ERROR_WANT_READ:
case SSL_ERROR_WANT_WRITE:
case SSL_ERROR_WANT_X509_LOOKUP:
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
tls_error(sock, result);
return;
}
/* Reschedule closing the socket */
tls_shutdown(sock);
return;
case 0:
UNREACHABLE();
case SSL_ERROR_ZERO_RETURN:
tls_error(sock, ISC_R_EOF);
break;
default:
tls_error(sock, ISC_R_TLSERROR);
}
return;
}
void
isc__nm_async_tlsdnsstop(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsstop_t *ievent =
(isc__netievent_tlsdnsstop_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
if (sock->parent != NULL) {
stop_tlsdns_child(sock);
return;
}
stop_tlsdns_parent(sock);
}
void
isc__nm_tlsdns_failed_read_cb(isc_nmsocket_t *sock, isc_result_t result,
bool async) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(result != ISC_R_SUCCESS);
isc__nmsocket_timer_stop(sock);
isc__nm_stop_reading(sock);
if (sock->tls.pending_req != NULL) {
isc_result_t failure_result = ISC_R_CANCELED;
isc__nm_uvreq_t *req = sock->tls.pending_req;
sock->tls.pending_req = NULL;
if (peer_verification_has_failed(sock)) {
failure_result = ISC_R_TLSBADPEERCERT;
}
isc__nm_failed_connect_cb(sock, req, failure_result, async);
}
if (!sock->recv_read) {
goto destroy;
}
sock->recv_read = false;
if (sock->recv_cb != NULL) {
isc__nm_uvreq_t *req = isc__nm_get_read_req(sock, NULL);
isc__nmsocket_clearcb(sock);
isc__nm_readcb(sock, req, result);
}
destroy:
call_pending_send_callbacks(sock, result);
isc__nmsocket_prep_destroy(sock);
/*
* We need to detach from quota after the read callback function
* had a chance to be executed.
*/
if (sock->quota != NULL) {
isc_quota_detach(&sock->quota);
}
}
void
isc__nm_tlsdns_read(isc_nmhandle_t *handle, isc_nm_recv_cb_t cb, void *cbarg) {
REQUIRE(VALID_NMHANDLE(handle));
REQUIRE(VALID_NMSOCK(handle->sock));
isc_nmsocket_t *sock = handle->sock;
isc__netievent_tlsdnsread_t *ievent = NULL;
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(sock->statichandle == handle);
sock->recv_cb = cb;
sock->recv_cbarg = cbarg;
sock->recv_read = true;
if (sock->read_timeout == 0) {
sock->read_timeout =
(atomic_load(&sock->keepalive)
? atomic_load(&sock->mgr->keepalive)
: atomic_load(&sock->mgr->idle));
}
ievent = isc__nm_get_netievent_tlsdnsread(sock->mgr, sock);
/*
* This MUST be done asynchronously, no matter which thread
* we're in. The callback function for isc_nm_read() often calls
* isc_nm_read() again; if we tried to do that synchronously
* we'd clash in processbuffer() and grow the stack
* indefinitely.
*/
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
return;
}
void
isc__nm_async_tlsdnsread(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsread_t *ievent =
(isc__netievent_tlsdnsread_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
isc_result_t result = ISC_R_SUCCESS;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
if (isc__nmsocket_closing(sock)) {
atomic_store(&sock->reading, true);
isc__nm_failed_read_cb(sock, ISC_R_CANCELED, false);
return;
}
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
isc__nm_failed_read_cb(sock, result, false);
}
}
/*
* Process a single packet from the incoming buffer.
*
* Return ISC_R_SUCCESS and attach 'handlep' to a handle if something
* was processed; return ISC_R_NOMORE if there isn't a full message
* to be processed.
*
* The caller will need to unreference the handle.
*/
isc_result_t
isc__nm_tlsdns_processbuffer(isc_nmsocket_t *sock) {
size_t len;
isc__nm_uvreq_t *req = NULL;
isc_nmhandle_t *handle = NULL;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
if (isc__nmsocket_closing(sock)) {
return (ISC_R_CANCELED);
}
/*
* If we don't even have the length yet, we can't do
* anything.
*/
if (sock->buf_len < 2) {
return (ISC_R_NOMORE);
}
/*
* Process the first packet from the buffer, leaving
* the rest (if any) for later.
*/
len = ntohs(*(uint16_t *)sock->buf);
if (len > sock->buf_len - 2) {
return (ISC_R_NOMORE);
}
if (sock->recv_cb == NULL) {
/*
* recv_cb has been cleared - there is
* nothing to do
*/
return (ISC_R_CANCELED);
} else if (sock->statichandle == NULL &&
sock->tls.state == TLS_STATE_IO &&
atomic_load(&sock->connected) &&
!atomic_load(&sock->connecting))
{
/*
* It seems that some unexpected data (a DNS message) has
* arrived while we are wrapping up.
*/
return (ISC_R_CANCELED);
}
req = isc__nm_get_read_req(sock, NULL);
REQUIRE(VALID_UVREQ(req));
/*
* We need to launch isc__nm_resume_processing() after the buffer
* has been consumed, thus we must delay detaching the handle.
*/
isc_nmhandle_attach(req->handle, &handle);
/*
* The callback will be called synchronously because the
* result is ISC_R_SUCCESS, so we don't need to have
* the buffer on the heap
*/
req->uvbuf.base = (char *)sock->buf + 2;
req->uvbuf.len = len;
/*
* If isc__nm_tlsdns_read() was called, it will be satisfied by
* single DNS message in the next call.
*/
sock->recv_read = false;
/*
* An assertion failure here means that there's an erroneous
* extra nmhandle detach happening in the callback and
* isc__nm_resume_processing() is called while we're
* processing the buffer.
*/
REQUIRE(sock->processing == false);
sock->processing = true;
isc__nm_readcb(sock, req, ISC_R_SUCCESS);
sock->processing = false;
len += 2;
sock->buf_len -= len;
if (sock->buf_len > 0) {
memmove(sock->buf, sock->buf + len, sock->buf_len);
}
isc_nmhandle_detach(&handle);
if (isc__nmsocket_closing(sock)) {
tlsdns_set_tls_shutdown(sock->tls.tls);
tlsdns_keep_client_tls_session(sock);
}
return (ISC_R_SUCCESS);
}
static isc_result_t
tls_cycle_input(isc_nmsocket_t *sock) {
isc_result_t result = ISC_R_SUCCESS;
int err = 0;
int rv = 1;
if (sock->tls.state == TLS_STATE_IO) {
size_t len;
for (;;) {
(void)SSL_peek(sock->tls.tls, &(char){ '\0' }, 0);
int pending = SSL_pending(sock->tls.tls);
if (pending > (int)ISC_NETMGR_TCP_RECVBUF_SIZE) {
pending = (int)ISC_NETMGR_TCP_RECVBUF_SIZE;
}
if ((sock->buf_len + pending) > sock->buf_size) {
isc__nm_alloc_dnsbuf(sock,
sock->buf_len + pending);
}
len = 0;
rv = SSL_read_ex(sock->tls.tls,
sock->buf + sock->buf_len,
sock->buf_size - sock->buf_len, &len);
if (rv != 1) {
/*
* Process what's in the buffer so far
*/
result = isc__nm_process_sock_buffer(sock);
if (result != ISC_R_SUCCESS) {
goto failure;
}
/*
* FIXME: Should we call
* isc__nm_failed_read_cb()?
*/
break;
}
INSIST((size_t)pending == len);
sock->buf_len += len;
result = isc__nm_process_sock_buffer(sock);
if (result != ISC_R_SUCCESS) {
goto failure;
}
}
} else if (!SSL_is_init_finished(sock->tls.tls)) {
if (SSL_is_server(sock->tls.tls)) {
rv = SSL_accept(sock->tls.tls);
} else {
rv = SSL_connect(sock->tls.tls);
}
} else {
rv = 1;
}
if (rv <= 0) {
err = SSL_get_error(sock->tls.tls, rv);
}
switch (err) {
case SSL_ERROR_WANT_READ:
if (sock->tls.state == TLS_STATE_NONE &&
!SSL_is_init_finished(sock->tls.tls)) {
sock->tls.state = TLS_STATE_HANDSHAKE;
result = isc__nm_process_sock_buffer(sock);
if (result != ISC_R_SUCCESS) {
goto failure;
}
}
/* else continue reading */
break;
case SSL_ERROR_WANT_WRITE:
async_tlsdns_cycle(sock);
break;
case SSL_ERROR_WANT_X509_LOOKUP:
/* Continue reading/writing */
break;
case 0:
/* Everything is ok, continue */
break;
case SSL_ERROR_ZERO_RETURN:
return (ISC_R_EOF);
default:
return (ISC_R_TLSERROR);
}
/* Stop state after handshake */
if (sock->tls.state == TLS_STATE_HANDSHAKE &&
SSL_is_init_finished(sock->tls.tls))
{
const unsigned char *alpn = NULL;
unsigned int alpnlen = 0;
isc__nmsocket_log_tls_session_reuse(sock, sock->tls.tls);
isc_tls_get_selected_alpn(sock->tls.tls, &alpn, &alpnlen);
if (alpn != NULL && alpnlen == ISC_TLS_DOT_PROTO_ALPN_ID_LEN &&
memcmp(ISC_TLS_DOT_PROTO_ALPN_ID, alpn,
ISC_TLS_DOT_PROTO_ALPN_ID_LEN) == 0)
{
sock->tls.alpn_negotiated = true;
}
sock->tls.state = TLS_STATE_IO;
if (SSL_is_server(sock->tls.tls)) {
REQUIRE(sock->recv_handle != NULL);
result = sock->accept_cb(sock->recv_handle,
ISC_R_SUCCESS,
sock->accept_cbarg);
if (result != ISC_R_SUCCESS) {
isc_nmhandle_detach(&sock->recv_handle);
goto failure;
}
} else {
isc__nm_uvreq_t *req = sock->tls.pending_req;
sock->tls.pending_req = NULL;
isc__nmsocket_timer_stop(sock);
uv_handle_set_data((uv_handle_t *)&sock->read_timer,
sock);
INSIST(atomic_compare_exchange_strong(
&sock->connecting, &(bool){ true }, false));
isc__nm_connectcb(sock, req, ISC_R_SUCCESS, true);
}
async_tlsdns_cycle(sock);
}
failure:
return (result);
}
static void
tls_error(isc_nmsocket_t *sock, isc_result_t result) {
switch (sock->tls.state) {
case TLS_STATE_HANDSHAKE:
case TLS_STATE_IO:
if (atomic_load(&sock->connecting)) {
isc__nm_uvreq_t *req = sock->tls.pending_req;
sock->tls.pending_req = NULL;
isc__nm_failed_connect_cb(sock, req, result, false);
} else {
isc__nm_tlsdns_failed_read_cb(sock, result, false);
}
break;
case TLS_STATE_ERROR:
return;
default:
break;
}
sock->tls.state = TLS_STATE_ERROR;
sock->tls.pending_error = result;
isc__nmsocket_shutdown(sock);
}
static void
call_pending_send_callbacks(isc_nmsocket_t *sock, const isc_result_t result) {
isc__nm_uvreq_t *cbreq = ISC_LIST_HEAD(sock->tls.sendreqs);
while (cbreq != NULL) {
isc__nm_uvreq_t *next = ISC_LIST_NEXT(cbreq, link);
ISC_LIST_UNLINK(sock->tls.sendreqs, cbreq, link);
INSIST(sock == cbreq->handle->sock);
isc__nm_sendcb(sock, cbreq, result, false);
cbreq = next;
}
}
static void
free_senddata(isc_nmsocket_t *sock, const isc_result_t result) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tls.senddata.base != NULL);
REQUIRE(sock->tls.senddata.length > 0);
isc_mem_put(sock->mgr->mctx, sock->tls.senddata.base,
sock->tls.senddata.length);
sock->tls.senddata.base = NULL;
sock->tls.senddata.length = 0;
call_pending_send_callbacks(sock, result);
}
static void
tls_write_cb(uv_write_t *req, int status) {
isc_result_t result = status != 0 ? isc_uverr2result(status)
: ISC_R_SUCCESS;
isc__nm_uvreq_t *uvreq = (isc__nm_uvreq_t *)req->data;
isc_nmsocket_t *sock = uvreq->sock;
isc_nm_timer_stop(uvreq->timer);
isc_nm_timer_detach(&uvreq->timer);
free_senddata(sock, result);
isc__nm_uvreq_put(&uvreq, sock);
if (status != 0) {
tls_error(sock, result);
return;
}
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
tls_error(sock, result);
return;
}
}
static isc_result_t
tls_cycle_output(isc_nmsocket_t *sock) {
isc_result_t result = ISC_R_SUCCESS;
int pending;
while ((pending = BIO_pending(sock->tls.app_rbio)) > 0) {
isc__nm_uvreq_t *req = NULL;
size_t bytes;
int rv;
int r;
if (sock->tls.senddata.base != NULL ||
sock->tls.senddata.length > 0) {
break;
}
if (pending > (int)ISC_NETMGR_TCP_RECVBUF_SIZE) {
pending = (int)ISC_NETMGR_TCP_RECVBUF_SIZE;
}
sock->tls.senddata.base = isc_mem_get(sock->mgr->mctx, pending);
sock->tls.senddata.length = pending;
/* It's a bit misnomer here, but it does the right thing */
req = isc__nm_get_read_req(sock, NULL);
req->uvbuf.base = (char *)sock->tls.senddata.base;
req->uvbuf.len = sock->tls.senddata.length;
rv = BIO_read_ex(sock->tls.app_rbio, req->uvbuf.base,
req->uvbuf.len, &bytes);
RUNTIME_CHECK(rv == 1);
INSIST((size_t)pending == bytes);
r = uv_try_write(&sock->uv_handle.stream, &req->uvbuf, 1);
if (r == pending) {
/* Wrote everything, restart */
isc__nm_uvreq_put(&req, sock);
free_senddata(sock, ISC_R_SUCCESS);
continue;
}
if (r > 0) {
/* Partial write, send rest asynchronously */
memmove(req->uvbuf.base, req->uvbuf.base + r,
req->uvbuf.len - r);
req->uvbuf.len = req->uvbuf.len - r;
} else if (r == UV_ENOSYS || r == UV_EAGAIN) {
/* uv_try_write is not supported, send
* asynchronously */
} else {
result = isc_uverr2result(r);
isc__nm_uvreq_put(&req, sock);
free_senddata(sock, result);
break;
}
r = uv_write(&req->uv_req.write, &sock->uv_handle.stream,
&req->uvbuf, 1, tls_write_cb);
if (r < 0) {
result = isc_uverr2result(r);
isc__nm_uvreq_put(&req, sock);
free_senddata(sock, result);
break;
}
isc_nm_timer_create(req->handle, isc__nmsocket_writetimeout_cb,
req, &req->timer);
if (sock->write_timeout > 0) {
isc_nm_timer_start(req->timer, sock->write_timeout);
}
break;
}
return (result);
}
static isc_result_t
tls_pop_error(isc_nmsocket_t *sock) {
isc_result_t result;
if (sock->tls.state != TLS_STATE_ERROR) {
return (ISC_R_SUCCESS);
}
if (sock->tls.pending_error == ISC_R_SUCCESS) {
return (ISC_R_TLSERROR);
}
result = sock->tls.pending_error;
sock->tls.pending_error = ISC_R_SUCCESS;
return (result);
}
static isc_result_t
tls_cycle(isc_nmsocket_t *sock) {
isc_result_t result;
if (isc__nmsocket_closing(sock)) {
return (ISC_R_CANCELED);
}
result = tls_pop_error(sock);
if (result != ISC_R_SUCCESS) {
goto done;
}
if (sock->tls.cycle) {
return (ISC_R_SUCCESS);
}
sock->tls.cycle = true;
result = tls_cycle_input(sock);
if (result != ISC_R_SUCCESS) {
goto done;
}
result = tls_cycle_output(sock);
if (result != ISC_R_SUCCESS) {
goto done;
}
done:
sock->tls.cycle = false;
return (result);
}
static void
async_tlsdns_cycle(isc_nmsocket_t *sock) {
isc__netievent_tlsdnscycle_t *ievent = NULL;
REQUIRE(VALID_NMSOCK(sock));
/* Socket was closed midflight by isc__nm_tlsdns_shutdown() */
if (isc__nmsocket_closing(sock)) {
return;
}
ievent = isc__nm_get_netievent_tlsdnscycle(sock->mgr, sock);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
void
isc__nm_async_tlsdnscycle(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnscycle_t *ievent =
(isc__netievent_tlsdnscycle_t *)ev0;
isc_result_t result;
isc_nmsocket_t *sock;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(ievent->sock));
REQUIRE(ievent->sock->tid == isc_nm_tid());
sock = ievent->sock;
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
tls_error(sock, result);
}
}
void
isc__nm_tlsdns_read_cb(uv_stream_t *stream, ssize_t nread,
const uv_buf_t *buf) {
isc_nmsocket_t *sock = uv_handle_get_data((uv_handle_t *)stream);
size_t len;
isc_result_t result;
int rv;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(atomic_load(&sock->reading));
REQUIRE(buf != NULL);
if (isc__nmsocket_closing(sock)) {
isc__nm_failed_read_cb(sock, ISC_R_CANCELED, true);
goto free;
}
if (nread < 0) {
if (nread != UV_EOF) {
isc__nm_incstats(sock, STATID_RECVFAIL);
}
isc__nm_failed_read_cb(sock, isc_uverr2result(nread), true);
goto free;
}
if (!atomic_load(&sock->client)) {
sock->read_timeout = atomic_load(&sock->mgr->idle);
}
/*
* The input has to be fed into BIO
*/
rv = BIO_write_ex(sock->tls.app_wbio, buf->base, (size_t)nread, &len);
if (rv <= 0 || (size_t)nread != len) {
isc__nm_failed_read_cb(sock, ISC_R_TLSERROR, true);
goto free;
}
result = tls_cycle(sock);
if (result != ISC_R_SUCCESS) {
isc__nm_failed_read_cb(sock, result, true);
}
free:
async_tlsdns_cycle(sock);
if (nread < 0) {
/*
* The buffer may be a null buffer on error.
*/
if (buf->base == NULL && buf->len == 0) {
return;
}
}
isc__nm_free_uvbuf(sock, buf);
}
static void
quota_accept_cb(isc_quota_t *quota, void *sock0) {
isc_nmsocket_t *sock = (isc_nmsocket_t *)sock0;
REQUIRE(VALID_NMSOCK(sock));
/*
* Create a tlsdnsaccept event and pass it using the async
* channel.
*/
isc__netievent_tlsdnsaccept_t *ievent =
isc__nm_get_netievent_tlsdnsaccept(sock->mgr, sock, quota);
isc__nm_maybe_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
/*
* This is called after we get a quota_accept_cb() callback.
*/
void
isc__nm_async_tlsdnsaccept(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsaccept_t *ievent =
(isc__netievent_tlsdnsaccept_t *)ev0;
isc_result_t result;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(ievent->sock));
REQUIRE(ievent->sock->tid == isc_nm_tid());
result = accept_connection(ievent->sock, ievent->quota);
isc__nm_accept_connection_log(result, can_log_tlsdns_quota());
}
static isc_result_t
accept_connection(isc_nmsocket_t *ssock, isc_quota_t *quota) {
isc_nmsocket_t *csock = NULL;
isc__networker_t *worker = NULL;
int r;
isc_result_t result;
struct sockaddr_storage peer_ss;
struct sockaddr_storage local_ss;
isc_sockaddr_t local;
isc_nmhandle_t *handle = NULL;
REQUIRE(VALID_NMSOCK(ssock));
REQUIRE(ssock->tid == isc_nm_tid());
if (isc__nmsocket_closing(ssock)) {
if (quota != NULL) {
isc_quota_detach(&quota);
}
return (ISC_R_CANCELED);
}
REQUIRE(ssock->accept_cb != NULL);
csock = isc_mem_get(ssock->mgr->mctx, sizeof(isc_nmsocket_t));
isc__nmsocket_init(csock, ssock->mgr, isc_nm_tlsdnssocket,
&ssock->iface);
csock->tid = ssock->tid;
isc__nmsocket_attach(ssock, &csock->server);
csock->accept_cb = ssock->accept_cb;
csock->accept_cbarg = ssock->accept_cbarg;
csock->recv_cb = ssock->recv_cb;
csock->recv_cbarg = ssock->recv_cbarg;
csock->quota = quota;
atomic_init(&csock->accepting, true);
worker = &csock->mgr->workers[csock->tid];
r = uv_tcp_init(&worker->loop, &csock->uv_handle.tcp);
UV_RUNTIME_CHECK(uv_tcp_init, r);
uv_handle_set_data(&csock->uv_handle.handle, csock);
r = uv_timer_init(&worker->loop, &csock->read_timer);
UV_RUNTIME_CHECK(uv_timer_init, r);
uv_handle_set_data((uv_handle_t *)&csock->read_timer, csock);
r = uv_accept(&ssock->uv_handle.stream, &csock->uv_handle.stream);
if (r != 0) {
result = isc_uverr2result(r);
goto failure;
}
r = uv_tcp_getpeername(&csock->uv_handle.tcp,
(struct sockaddr *)&peer_ss,
&(int){ sizeof(peer_ss) });
if (r != 0) {
result = isc_uverr2result(r);
goto failure;
}
result = isc_sockaddr_fromsockaddr(&csock->peer,
(struct sockaddr *)&peer_ss);
if (result != ISC_R_SUCCESS) {
goto failure;
}
r = uv_tcp_getsockname(&csock->uv_handle.tcp,
(struct sockaddr *)&local_ss,
&(int){ sizeof(local_ss) });
if (r != 0) {
result = isc_uverr2result(r);
goto failure;
}
result = isc_sockaddr_fromsockaddr(&local,
(struct sockaddr *)&local_ss);
if (result != ISC_R_SUCCESS) {
goto failure;
}
/*
* The handle will be either detached on acceptcb failure or in
* the readcb.
*/
handle = isc__nmhandle_get(csock, NULL, &local);
result = ssock->accept_cb(handle, ISC_R_SUCCESS, ssock->accept_cbarg);
if (result != ISC_R_SUCCESS) {
isc_nmhandle_detach(&handle);
goto failure;
}
csock->tls.state = TLS_STATE_NONE;
csock->tls.tls = isc_tls_create(ssock->tls.ctx);
RUNTIME_CHECK(csock->tls.tls != NULL);
r = BIO_new_bio_pair(&csock->tls.ssl_wbio, ISC_NETMGR_TCP_RECVBUF_SIZE,
&csock->tls.app_rbio, ISC_NETMGR_TCP_RECVBUF_SIZE);
RUNTIME_CHECK(r == 1);
r = BIO_new_bio_pair(&csock->tls.ssl_rbio, ISC_NETMGR_TCP_RECVBUF_SIZE,
&csock->tls.app_wbio, ISC_NETMGR_TCP_RECVBUF_SIZE);
RUNTIME_CHECK(r == 1);
#if HAVE_SSL_SET0_RBIO && HAVE_SSL_SET0_WBIO
/*
* Note that if the rbio and wbio are the same then
* SSL_set0_rbio() and SSL_set0_wbio() each take ownership of
* one reference. Therefore it may be necessary to increment the
* number of references available using BIO_up_ref(3) before
* calling the set0 functions.
*/
SSL_set0_rbio(csock->tls.tls, csock->tls.ssl_rbio);
SSL_set0_wbio(csock->tls.tls, csock->tls.ssl_wbio);
#else
SSL_set_bio(csock->tls.tls, csock->tls.ssl_rbio, csock->tls.ssl_wbio);
#endif
SSL_set_accept_state(csock->tls.tls);
/* FIXME: Set SSL_MODE_RELEASE_BUFFERS */
atomic_store(&csock->accepting, false);
isc__nm_incstats(csock, STATID_ACCEPT);
csock->read_timeout = atomic_load(&csock->mgr->init);
csock->closehandle_cb = isc__nm_resume_processing;
/*
* We need to keep the handle alive until we fail to read or
* connection is closed by the other side, it will be detached
* via prep_destroy()->tlsdns_close_direct().
*/
isc_nmhandle_attach(handle, &csock->recv_handle);
/*
* The initial timer has been set, update the read timeout for
* the next reads.
*/
csock->read_timeout = (atomic_load(&csock->keepalive)
? atomic_load(&csock->mgr->keepalive)
: atomic_load(&csock->mgr->idle));
isc_nmhandle_detach(&handle);
result = isc__nm_process_sock_buffer(csock);
if (result != ISC_R_SUCCESS) {
goto failure;
}
/*
* sock is now attached to the handle.
*/
isc__nmsocket_detach(&csock);
return (ISC_R_SUCCESS);
failure:
atomic_store(&csock->active, false);
isc__nm_failed_accept_cb(csock, result);
isc__nmsocket_prep_destroy(csock);
isc__nmsocket_detach(&csock);
return (result);
}
void
isc__nm_tlsdns_send(isc_nmhandle_t *handle, isc_region_t *region,
isc_nm_cb_t cb, void *cbarg) {
isc__netievent_tlsdnssend_t *ievent = NULL;
isc__nm_uvreq_t *uvreq = NULL;
isc_nmsocket_t *sock = NULL;
REQUIRE(VALID_NMHANDLE(handle));
sock = handle->sock;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnssocket);
uvreq = isc__nm_uvreq_get(sock->mgr, sock);
*(uint16_t *)uvreq->tcplen = htons(region->length);
uvreq->uvbuf.base = (char *)region->base;
uvreq->uvbuf.len = region->length;
isc_nmhandle_attach(handle, &uvreq->handle);
uvreq->cb.send = cb;
uvreq->cbarg = cbarg;
ievent = isc__nm_get_netievent_tlsdnssend(sock->mgr, sock, uvreq);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
return;
}
/*
* Handle 'tcpsend' async event - send a packet on the socket
*/
void
isc__nm_async_tlsdnssend(isc__networker_t *worker, isc__netievent_t *ev0) {
isc_result_t result;
isc__netievent_tlsdnssend_t *ievent =
(isc__netievent_tlsdnssend_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
isc__nm_uvreq_t *uvreq = ievent->req;
UNUSED(worker);
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(sock->tid == isc_nm_tid());
if (sock->write_timeout == 0) {
sock->write_timeout =
(atomic_load(&sock->keepalive)
? atomic_load(&sock->mgr->keepalive)
: atomic_load(&sock->mgr->idle));
}
result = tlsdns_send_direct(sock, uvreq);
if (result != ISC_R_SUCCESS) {
isc__nm_incstats(sock, STATID_SENDFAIL);
isc__nm_failed_send_cb(sock, uvreq, result);
}
}
static void
tlsdns_send_enqueue(isc_nmsocket_t *sock, isc__nm_uvreq_t *req) {
isc__netievent_tlsdnssend_t *ievent =
isc__nm_get_netievent_tlsdnssend(sock->mgr, sock, req);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
static isc_result_t
tlsdns_send_direct(isc_nmsocket_t *sock, isc__nm_uvreq_t *req) {
isc_result_t result;
int err = 0;
int rv;
size_t bytes = 0;
size_t sendlen;
isc__networker_t *worker = NULL;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(VALID_UVREQ(req));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(sock->type == isc_nm_tlsdnssocket);
result = tls_pop_error(sock);
if (result != ISC_R_SUCCESS) {
return (result);
}
if (isc__nmsocket_closing(sock)) {
return (ISC_R_CANCELED);
}
/* Writes won't succeed until handshake end */
if (!SSL_is_init_finished(sock->tls.tls)) {
goto requeue;
}
/*
* There's no SSL_writev(), so we need to use a local buffer to
* assemble the whole message
*/
worker = &sock->mgr->workers[sock->tid];
sendlen = req->uvbuf.len + sizeof(uint16_t);
memmove(worker->sendbuf, req->tcplen, sizeof(uint16_t));
memmove(worker->sendbuf + sizeof(uint16_t), req->uvbuf.base,
req->uvbuf.len);
rv = SSL_write_ex(sock->tls.tls, worker->sendbuf, sendlen, &bytes);
if (rv > 0) {
/* SSL_write_ex() doesn't do partial writes */
INSIST(sendlen == bytes);
ISC_LIST_APPEND(sock->tls.sendreqs, req, link);
async_tlsdns_cycle(sock);
return (ISC_R_SUCCESS);
}
/* Nothing was written, maybe enqueue? */
err = SSL_get_error(sock->tls.tls, rv);
switch (err) {
case SSL_ERROR_WANT_WRITE:
case SSL_ERROR_WANT_READ:
break;
case 0:
UNREACHABLE();
default:
return (ISC_R_TLSERROR);
}
result = tls_cycle(sock);
requeue:
tlsdns_send_enqueue(sock, req);
return (result);
}
static void
tlsdns_stop_cb(uv_handle_t *handle) {
isc_nmsocket_t *sock = uv_handle_get_data(handle);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(atomic_load(&sock->closing));
uv_handle_set_data(handle, NULL);
if (!atomic_compare_exchange_strong(&sock->closed, &(bool){ false },
true)) {
UNREACHABLE();
}
isc__nm_incstats(sock, STATID_CLOSE);
atomic_store(&sock->listening, false);
BIO_free_all(sock->tls.app_rbio);
BIO_free_all(sock->tls.app_wbio);
if (sock->tls.ctx != NULL) {
isc_tlsctx_free(&sock->tls.ctx);
}
isc__nmsocket_detach(&sock);
}
static void
tlsdns_close_sock(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(atomic_load(&sock->closing));
if (!atomic_compare_exchange_strong(&sock->closed, &(bool){ false },
true)) {
UNREACHABLE();
}
isc__nm_incstats(sock, STATID_CLOSE);
if (sock->server != NULL) {
isc__nmsocket_detach(&sock->server);
}
atomic_store(&sock->connected, false);
if (sock->tls.tls != NULL) {
/*
* Let's shutdown the TLS session properly so that the session
* will remain resumable, if required.
*/
tlsdns_set_tls_shutdown(sock->tls.tls);
tlsdns_keep_client_tls_session(sock);
isc_tls_free(&sock->tls.tls);
}
BIO_free_all(sock->tls.app_rbio);
BIO_free_all(sock->tls.app_wbio);
if (sock->tls.ctx != NULL) {
isc_tlsctx_free(&sock->tls.ctx);
}
isc__nmsocket_prep_destroy(sock);
}
static void
tlsdns_close_cb(uv_handle_t *handle) {
isc_nmsocket_t *sock = uv_handle_get_data(handle);
uv_handle_set_data(handle, NULL);
tlsdns_close_sock(sock);
}
static void
read_timer_close_cb(uv_handle_t *handle) {
isc_nmsocket_t *sock = uv_handle_get_data(handle);
uv_handle_set_data(handle, NULL);
REQUIRE(VALID_NMSOCK(sock));
if (sock->parent) {
uv_close(&sock->uv_handle.handle, tlsdns_stop_cb);
} else if (uv_is_closing(&sock->uv_handle.handle)) {
tlsdns_close_sock(sock);
} else {
uv_close(&sock->uv_handle.handle, tlsdns_close_cb);
}
}
static void
stop_tlsdns_child(isc_nmsocket_t *sock) {
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(sock->tid == isc_nm_tid());
if (!atomic_compare_exchange_strong(&sock->closing, &(bool){ false },
true)) {
return;
}
tlsdns_close_direct(sock);
atomic_fetch_sub(&sock->parent->rchildren, 1);
isc_barrier_wait(&sock->parent->stoplistening);
}
static void
stop_tlsdns_parent(isc_nmsocket_t *sock) {
isc_nmsocket_t *csock = NULL;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(sock->type == isc_nm_tlsdnslistener);
isc_barrier_init(&sock->stoplistening, sock->nchildren);
for (size_t i = 0; i < sock->nchildren; i++) {
csock = &sock->children[i];
REQUIRE(VALID_NMSOCK(csock));
if ((int)i == isc_nm_tid()) {
/*
* We need to schedule closing the other sockets first
*/
continue;
}
atomic_store(&csock->active, false);
enqueue_stoplistening(csock);
}
csock = &sock->children[isc_nm_tid()];
atomic_store(&csock->active, false);
stop_tlsdns_child(csock);
atomic_store(&sock->closed, true);
isc__nmsocket_prep_destroy(sock);
}
static void
tlsdns_close_direct(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(atomic_load(&sock->closing));
REQUIRE(sock->tls.pending_req == NULL);
if (sock->quota != NULL) {
isc_quota_detach(&sock->quota);
}
if (sock->recv_handle != NULL) {
isc_nmhandle_detach(&sock->recv_handle);
}
isc__nmsocket_timer_stop(sock);
isc__nm_stop_reading(sock);
uv_handle_set_data((uv_handle_t *)&sock->read_timer, sock);
uv_close((uv_handle_t *)&sock->read_timer, read_timer_close_cb);
}
void
isc__nm_tlsdns_close(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnssocket);
REQUIRE(!isc__nmsocket_active(sock));
if (!atomic_compare_exchange_strong(&sock->closing, &(bool){ false },
true)) {
return;
}
if (sock->tid == isc_nm_tid()) {
tlsdns_close_direct(sock);
} else {
/*
* We need to create an event and pass it using async
* channel
*/
isc__netievent_tlsdnsclose_t *ievent =
isc__nm_get_netievent_tlsdnsclose(sock->mgr, sock);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
}
void
isc__nm_async_tlsdnsclose(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnsclose_t *ievent =
(isc__netievent_tlsdnsclose_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
tlsdns_close_direct(sock);
}
static void
tlsdns_close_connect_cb(uv_handle_t *handle) {
isc_nmsocket_t *sock = uv_handle_get_data(handle);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(isc__nm_in_netthread());
REQUIRE(sock->tid == isc_nm_tid());
isc__nmsocket_prep_destroy(sock);
isc__nmsocket_detach(&sock);
}
void
isc__nm_tlsdns_shutdown(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
REQUIRE(sock->type == isc_nm_tlsdnssocket);
/*
* If the socket is active, mark it inactive and
* continue. If it isn't active, stop now.
*/
if (!isc__nmsocket_deactivate(sock)) {
return;
}
if (sock->tls.tls) {
/* Shutdown any active TLS connections */
tlsdns_set_tls_shutdown(sock->tls.tls);
}
if (atomic_load(&sock->accepting)) {
return;
}
/* TLS handshake hasn't been completed yet */
if (atomic_load(&sock->connecting)) {
isc_nmsocket_t *tsock = NULL;
/*
* TCP connection has been established, now waiting on
* TLS handshake to complete
*/
if (sock->tls.pending_req != NULL) {
isc_result_t result = ISC_R_CANCELED;
isc__nm_uvreq_t *req = sock->tls.pending_req;
sock->tls.pending_req = NULL;
if (peer_verification_has_failed(sock)) {
result = ISC_R_TLSBADPEERCERT;
}
isc__nm_failed_connect_cb(sock, req, result, false);
return;
}
/* The TCP connection hasn't been established yet */
isc__nmsocket_attach(sock, &tsock);
uv_close(&sock->uv_handle.handle, tlsdns_close_connect_cb);
return;
}
if (sock->statichandle != NULL) {
if (isc__nm_closing(sock)) {
isc__nm_failed_read_cb(sock, ISC_R_SHUTTINGDOWN, false);
} else {
isc__nm_failed_read_cb(sock, ISC_R_CANCELED, false);
}
return;
}
/*
* Otherwise, we just send the socket to abyss...
*/
if (sock->parent == NULL) {
isc__nmsocket_prep_destroy(sock);
}
}
void
isc__nm_tlsdns_cancelread(isc_nmhandle_t *handle) {
isc_nmsocket_t *sock = NULL;
isc__netievent_tlsdnscancel_t *ievent = NULL;
REQUIRE(VALID_NMHANDLE(handle));
sock = handle->sock;
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnssocket);
ievent = isc__nm_get_netievent_tlsdnscancel(sock->mgr, sock, handle);
isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid],
(isc__netievent_t *)ievent);
}
void
isc__nm_async_tlsdnscancel(isc__networker_t *worker, isc__netievent_t *ev0) {
isc__netievent_tlsdnscancel_t *ievent =
(isc__netievent_tlsdnscancel_t *)ev0;
isc_nmsocket_t *sock = ievent->sock;
UNUSED(worker);
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->tid == isc_nm_tid());
isc__nm_failed_read_cb(sock, ISC_R_EOF, false);
}
/* Zone transfers/updates over TLS are allowed only when "dot" ALPN
* was negotiated.
*
* Per the XoT spec, we must also check that the TLS version is >=
* 1.3. The check could be added here. However, we still need to
* support platforms where no cryptographic library with TLSv1.3
* support is available. As a result of this we cannot be too strict
* regarding the minimal TLS protocol version in order to make it
* possible to do encrypted zone transfers over TLSv1.2, as it would
* not be right to leave users on these platforms without means for
* encrypted zone transfers using BIND only.
*
* The ones requiring strict compatibility with the specification
* could disable TLSv1.2 in the configuration file.
*/
bool
isc__nm_tlsdns_xfr_allowed(isc_nmsocket_t *sock) {
REQUIRE(VALID_NMSOCK(sock));
REQUIRE(sock->type == isc_nm_tlsdnssocket);
return (sock->tls.alpn_negotiated);
}
const char *
isc__nm_tlsdns_verify_tls_peer_result_string(const isc_nmhandle_t *handle) {
isc_nmsocket_t *sock = NULL;
REQUIRE(VALID_NMHANDLE(handle));
REQUIRE(VALID_NMSOCK(handle->sock));
REQUIRE(handle->sock->type == isc_nm_tlsdnssocket);
sock = handle->sock;
if (sock->tls.tls == NULL) {
return (NULL);
}
return (isc_tls_verify_peer_result_string(sock->tls.tls));
}
void
isc__nm_async_tlsdns_set_tlsctx(isc_nmsocket_t *listener, isc_tlsctx_t *tlsctx,
const int tid) {
REQUIRE(tid >= 0);
isc_tlsctx_free(&listener->children[tid].tls.ctx);
isc_tlsctx_attach(tlsctx, &listener->children[tid].tls.ctx);
}
void
isc__nm_tlsdns_cleanup_data(isc_nmsocket_t *sock) {
if (sock->type == isc_nm_tlsdnslistener ||
sock->type == isc_nm_tlsdnssocket) {
if (sock->tls.client_sess_cache != NULL) {
INSIST(atomic_load(&sock->client));
INSIST(sock->type == isc_nm_tlsdnssocket);
isc_tlsctx_client_session_cache_detach(
&sock->tls.client_sess_cache);
}
if (sock->tls.ctx != NULL) {
INSIST(ISC_LIST_EMPTY(sock->tls.sendreqs));
isc_tlsctx_free(&sock->tls.ctx);
}
}
}
static void
tlsdns_keep_client_tls_session(isc_nmsocket_t *sock) {
/*
* Ensure that the isc_tls_t is being accessed from
* within the worker thread the socket is bound to.
*/
REQUIRE(sock->tid == isc_nm_tid());
if (sock->tls.client_sess_cache != NULL &&
sock->tls.client_session_saved == false)
{
INSIST(atomic_load(&sock->client));
isc_tlsctx_client_session_cache_keep_sockaddr(
sock->tls.client_sess_cache, &sock->peer,
sock->tls.tls);
sock->tls.client_session_saved = true;
}
}
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