/* -*- mode: C; c-file-style: "gnu"; indent-tabs-mode: nil; -*- */
/* GIO - GLib Input, Output and Streaming Library
*
* Copyright (C) 2008 Red Hat, Inc.
* Copyright (C) 2018 Igalia S.L.
*
* SPDX-License-Identifier: LGPL-2.1-or-later
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General
* Public License along with this library; if not, see .
*/
#include "config.h"
#include
#include "glibintl.h"
#include
#include
#include "glib/glib-private.h"
#include "gthreadedresolver.h"
#include "gnetworkingprivate.h"
#include "gcancellable.h"
#include "ginetaddress.h"
#include "ginetsocketaddress.h"
#include "gtask.h"
#include "gsocketaddress.h"
#include "gsrvtarget.h"
/*
* GThreadedResolver is a threaded wrapper around the system libc’s
* `getaddrinfo()`.
*
* It has to be threaded, as `getaddrinfo()` is synchronous. libc does provide
* `getaddrinfo_a()` as an asynchronous version of `getaddrinfo()`, but it does
* not integrate with a poll loop. It requires use of sigevent to notify of
* completion of an asynchronous operation. That either emits a signal, or calls
* a callback function in a newly spawned thread.
*
* A signal (`SIGEV_SIGNAL`) can’t be used for completion as (aside from being
* another expensive round trip into the kernel) GLib cannot pick a `SIG*`
* number which is guaranteed to not be in use elsewhere in the process. Various
* other things could be interfering with signal dispositions, such as gdb or
* other libraries in the process. Using a `signalfd()`
* [cannot improve this situation](https://ldpreload.com/blog/signalfd-is-useless).
*
* A callback function in a newly spawned thread (`SIGEV_THREAD`) could be used,
* but that is very expensive. Internally, glibc currently also just implements
* `getaddrinfo_a()`
* [using its own thread pool](https://github.com/bminor/glibc/blob/master/resolv/gai_misc.c),
* and then
* [spawns an additional thread for each completion callback](https://github.com/bminor/glibc/blob/master/resolv/gai_notify.c).
* That is very expensive.
*
* No other appropriate sigevent callback types
* [currently exist](https://sourceware.org/bugzilla/show_bug.cgi?id=30287), and
* [others agree that sigevent is not great](http://davmac.org/davpage/linux/async-io.html#posixaio).
*
* Hence, #GThreadedResolver calls the normal synchronous `getaddrinfo()` in its
* own thread pool. Previously, #GThreadedResolver used the thread pool which is
* internal to #GTask by calling g_task_run_in_thread(). That lead to exhaustion
* of the #GTask thread pool in some situations, though, as DNS lookups are
* quite frequent leaf operations in some use cases. Now, #GThreadedResolver
* uses its own private thread pool.
*
* This is similar to what
* [libasyncns](http://git.0pointer.net/libasyncns.git/tree/libasyncns/asyncns.h)
* and other multi-threaded users of `getaddrinfo()` do.
*/
struct _GThreadedResolver
{
GResolver parent_instance;
GThreadPool *thread_pool; /* (owned) */
};
G_DEFINE_TYPE (GThreadedResolver, g_threaded_resolver, G_TYPE_RESOLVER)
static void run_task_in_thread_pool_async (GThreadedResolver *self,
GTask *task);
static void run_task_in_thread_pool_sync (GThreadedResolver *self,
GTask *task);
static void threaded_resolver_worker_cb (gpointer task_data,
gpointer user_data);
static void
g_threaded_resolver_init (GThreadedResolver *self)
{
self->thread_pool = g_thread_pool_new_full (threaded_resolver_worker_cb,
self,
(GDestroyNotify) g_object_unref,
20,
FALSE,
NULL);
}
static void
g_threaded_resolver_finalize (GObject *object)
{
GThreadedResolver *self = G_THREADED_RESOLVER (object);
g_thread_pool_free (self->thread_pool, TRUE, FALSE);
self->thread_pool = NULL;
G_OBJECT_CLASS (g_threaded_resolver_parent_class)->finalize (object);
}
static GResolverError
g_resolver_error_from_addrinfo_error (gint err)
{
switch (err)
{
case EAI_FAIL:
#if defined(EAI_NODATA) && (EAI_NODATA != EAI_NONAME)
case EAI_NODATA:
#endif
case EAI_NONAME:
return G_RESOLVER_ERROR_NOT_FOUND;
case EAI_AGAIN:
return G_RESOLVER_ERROR_TEMPORARY_FAILURE;
default:
return G_RESOLVER_ERROR_INTERNAL;
}
}
typedef struct {
enum {
LOOKUP_BY_NAME,
LOOKUP_BY_ADDRESS,
LOOKUP_RECORDS,
} lookup_type;
union {
struct {
char *hostname;
int address_family;
} lookup_by_name;
struct {
GInetAddress *address; /* (owned) */
} lookup_by_address;
struct {
char *rrname;
GResolverRecordType record_type;
} lookup_records;
};
GCond cond; /* used for signalling completion of the task when running it sync */
GMutex lock;
GSource *timeout_source; /* (nullable) (owned) */
GSource *cancellable_source; /* (nullable) (owned) */
/* This enum indicates that a particular code path has claimed the
* task and is shortly about to call g_task_return_*() on it.
* This must be accessed with GThreadedResolver.lock held. */
enum
{
NOT_YET,
COMPLETED, /* libc lookup call has completed successfully or errored */
TIMED_OUT,
CANCELLED,
} will_return;
/* Whether the thread pool thread executing this lookup has finished executing
* it and g_task_return_*() has been called on it already.
* This must be accessed with GThreadedResolver.lock held. */
gboolean has_returned;
} LookupData;
static LookupData *
lookup_data_new_by_name (const char *hostname,
int address_family)
{
LookupData *data = g_new0 (LookupData, 1);
data->lookup_type = LOOKUP_BY_NAME;
g_cond_init (&data->cond);
g_mutex_init (&data->lock);
data->lookup_by_name.hostname = g_strdup (hostname);
data->lookup_by_name.address_family = address_family;
return g_steal_pointer (&data);
}
static LookupData *
lookup_data_new_by_address (GInetAddress *address)
{
LookupData *data = g_new0 (LookupData, 1);
data->lookup_type = LOOKUP_BY_ADDRESS;
g_cond_init (&data->cond);
g_mutex_init (&data->lock);
data->lookup_by_address.address = g_object_ref (address);
return g_steal_pointer (&data);
}
static LookupData *
lookup_data_new_records (const gchar *rrname,
GResolverRecordType record_type)
{
LookupData *data = g_new0 (LookupData, 1);
data->lookup_type = LOOKUP_RECORDS;
g_cond_init (&data->cond);
g_mutex_init (&data->lock);
data->lookup_records.rrname = g_strdup (rrname);
data->lookup_records.record_type = record_type;
return g_steal_pointer (&data);
}
static void
lookup_data_free (LookupData *data)
{
switch (data->lookup_type) {
case LOOKUP_BY_NAME:
g_free (data->lookup_by_name.hostname);
break;
case LOOKUP_BY_ADDRESS:
g_clear_object (&data->lookup_by_address.address);
break;
case LOOKUP_RECORDS:
g_free (data->lookup_records.rrname);
break;
default:
g_assert_not_reached ();
}
if (data->timeout_source != NULL)
{
g_source_destroy (data->timeout_source);
g_clear_pointer (&data->timeout_source, g_source_unref);
}
if (data->cancellable_source != NULL)
{
g_source_destroy (data->cancellable_source);
g_clear_pointer (&data->cancellable_source, g_source_unref);
}
g_mutex_clear (&data->lock);
g_cond_clear (&data->cond);
g_free (data);
}
static GList *
do_lookup_by_name (const gchar *hostname,
int address_family,
GCancellable *cancellable,
GError **error)
{
struct addrinfo *res = NULL;
GList *addresses;
gint retval;
struct addrinfo addrinfo_hints = { 0 };
#ifdef AI_ADDRCONFIG
addrinfo_hints.ai_flags = AI_ADDRCONFIG;
#endif
/* socktype and protocol don't actually matter, they just get copied into the
* returned addrinfo structures (and then we ignore them). But if
* we leave them unset, we'll get back duplicate answers.
*/
addrinfo_hints.ai_socktype = SOCK_STREAM;
addrinfo_hints.ai_protocol = IPPROTO_TCP;
addrinfo_hints.ai_family = address_family;
retval = getaddrinfo (hostname, NULL, &addrinfo_hints, &res);
if (retval == 0)
{
struct addrinfo *ai;
GSocketAddress *sockaddr;
GInetAddress *addr;
addresses = NULL;
for (ai = res; ai; ai = ai->ai_next)
{
sockaddr = g_socket_address_new_from_native (ai->ai_addr, ai->ai_addrlen);
if (!sockaddr)
continue;
if (!G_IS_INET_SOCKET_ADDRESS (sockaddr))
{
g_clear_object (&sockaddr);
continue;
}
addr = g_object_ref (g_inet_socket_address_get_address ((GInetSocketAddress *)sockaddr));
addresses = g_list_prepend (addresses, addr);
g_object_unref (sockaddr);
}
g_clear_pointer (&res, freeaddrinfo);
if (addresses != NULL)
{
addresses = g_list_reverse (addresses);
return g_steal_pointer (&addresses);
}
else
{
/* All addresses failed to be converted to GSocketAddresses. */
g_set_error (error,
G_RESOLVER_ERROR,
G_RESOLVER_ERROR_NOT_FOUND,
_("Error resolving “%s”: %s"),
hostname,
_("No valid addresses were found"));
return NULL;
}
}
else
{
#ifdef G_OS_WIN32
gchar *error_message = g_win32_error_message (WSAGetLastError ());
#else
gchar *error_message = g_locale_to_utf8 (gai_strerror (retval), -1, NULL, NULL, NULL);
if (error_message == NULL)
error_message = g_strdup ("[Invalid UTF-8]");
#endif
g_clear_pointer (&res, freeaddrinfo);
g_set_error (error,
G_RESOLVER_ERROR,
g_resolver_error_from_addrinfo_error (retval),
_("Error resolving “%s”: %s"),
hostname, error_message);
g_free (error_message);
return NULL;
}
}
static GList *
lookup_by_name (GResolver *resolver,
const gchar *hostname,
GCancellable *cancellable,
GError **error)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
GTask *task;
GList *addresses;
LookupData *data;
data = lookup_data_new_by_name (hostname, AF_UNSPEC);
task = g_task_new (resolver, cancellable, NULL, NULL);
g_task_set_source_tag (task, lookup_by_name);
g_task_set_name (task, "[gio] resolver lookup");
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_sync (self, task);
addresses = g_task_propagate_pointer (task, error);
g_object_unref (task);
return addresses;
}
static int
flags_to_family (GResolverNameLookupFlags flags)
{
int address_family = AF_UNSPEC;
if (flags & G_RESOLVER_NAME_LOOKUP_FLAGS_IPV4_ONLY)
address_family = AF_INET;
if (flags & G_RESOLVER_NAME_LOOKUP_FLAGS_IPV6_ONLY)
{
address_family = AF_INET6;
/* You can only filter by one family at a time */
g_return_val_if_fail (!(flags & G_RESOLVER_NAME_LOOKUP_FLAGS_IPV4_ONLY), address_family);
}
return address_family;
}
static GList *
lookup_by_name_with_flags (GResolver *resolver,
const gchar *hostname,
GResolverNameLookupFlags flags,
GCancellable *cancellable,
GError **error)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
GTask *task;
GList *addresses;
LookupData *data;
data = lookup_data_new_by_name (hostname, flags_to_family (flags));
task = g_task_new (resolver, cancellable, NULL, NULL);
g_task_set_source_tag (task, lookup_by_name_with_flags);
g_task_set_name (task, "[gio] resolver lookup");
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_sync (self, task);
addresses = g_task_propagate_pointer (task, error);
g_object_unref (task);
return addresses;
}
static void
lookup_by_name_with_flags_async (GResolver *resolver,
const gchar *hostname,
GResolverNameLookupFlags flags,
GCancellable *cancellable,
GAsyncReadyCallback callback,
gpointer user_data)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
GTask *task;
LookupData *data;
data = lookup_data_new_by_name (hostname, flags_to_family (flags));
task = g_task_new (resolver, cancellable, callback, user_data);
g_debug ("%s: starting new lookup for %s with GTask %p, LookupData %p",
G_STRFUNC, hostname, task, data);
g_task_set_source_tag (task, lookup_by_name_with_flags_async);
g_task_set_name (task, "[gio] resolver lookup");
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_async (self, task);
g_object_unref (task);
}
static void
lookup_by_name_async (GResolver *resolver,
const gchar *hostname,
GCancellable *cancellable,
GAsyncReadyCallback callback,
gpointer user_data)
{
lookup_by_name_with_flags_async (resolver,
hostname,
G_RESOLVER_NAME_LOOKUP_FLAGS_DEFAULT,
cancellable,
callback,
user_data);
}
static GList *
lookup_by_name_finish (GResolver *resolver,
GAsyncResult *result,
GError **error)
{
g_return_val_if_fail (g_task_is_valid (result, resolver), NULL);
return g_task_propagate_pointer (G_TASK (result), error);
}
static GList *
lookup_by_name_with_flags_finish (GResolver *resolver,
GAsyncResult *result,
GError **error)
{
g_return_val_if_fail (g_task_is_valid (result, resolver), NULL);
return g_task_propagate_pointer (G_TASK (result), error);
}
static gchar *
do_lookup_by_address (GInetAddress *address,
GCancellable *cancellable,
GError **error)
{
struct sockaddr_storage sockaddr_address;
gsize sockaddr_address_size;
GSocketAddress *gsockaddr;
gchar name[NI_MAXHOST];
gint retval;
gsockaddr = g_inet_socket_address_new (address, 0);
g_socket_address_to_native (gsockaddr, (struct sockaddr *)&sockaddr_address,
sizeof (sockaddr_address), NULL);
sockaddr_address_size = g_socket_address_get_native_size (gsockaddr);
g_object_unref (gsockaddr);
retval = getnameinfo ((struct sockaddr *) &sockaddr_address, sockaddr_address_size,
name, sizeof (name), NULL, 0, NI_NAMEREQD);
if (retval == 0)
return g_strdup (name);
else
{
gchar *phys;
#ifdef G_OS_WIN32
gchar *error_message = g_win32_error_message (WSAGetLastError ());
#else
gchar *error_message = g_locale_to_utf8 (gai_strerror (retval), -1, NULL, NULL, NULL);
if (error_message == NULL)
error_message = g_strdup ("[Invalid UTF-8]");
#endif
phys = g_inet_address_to_string (address);
g_set_error (error,
G_RESOLVER_ERROR,
g_resolver_error_from_addrinfo_error (retval),
_("Error reverse-resolving “%s”: %s"),
phys ? phys : "(unknown)",
error_message);
g_free (phys);
g_free (error_message);
return NULL;
}
}
static gchar *
lookup_by_address (GResolver *resolver,
GInetAddress *address,
GCancellable *cancellable,
GError **error)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
LookupData *data = NULL;
GTask *task;
gchar *name;
data = lookup_data_new_by_address (address);
task = g_task_new (resolver, cancellable, NULL, NULL);
g_task_set_source_tag (task, lookup_by_address);
g_task_set_name (task, "[gio] resolver lookup");
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_sync (self, task);
name = g_task_propagate_pointer (task, error);
g_object_unref (task);
return name;
}
static void
lookup_by_address_async (GResolver *resolver,
GInetAddress *address,
GCancellable *cancellable,
GAsyncReadyCallback callback,
gpointer user_data)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
LookupData *data = NULL;
GTask *task;
data = lookup_data_new_by_address (address);
task = g_task_new (resolver, cancellable, callback, user_data);
g_task_set_source_tag (task, lookup_by_address_async);
g_task_set_name (task, "[gio] resolver lookup");
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_async (self, task);
g_object_unref (task);
}
static gchar *
lookup_by_address_finish (GResolver *resolver,
GAsyncResult *result,
GError **error)
{
g_return_val_if_fail (g_task_is_valid (result, resolver), NULL);
return g_task_propagate_pointer (G_TASK (result), error);
}
#if defined(G_OS_UNIX)
#if defined __BIONIC__ && !defined BIND_4_COMPAT
/* Copy from bionic/libc/private/arpa_nameser_compat.h
* and bionic/libc/private/arpa_nameser.h */
typedef struct {
unsigned id :16; /* query identification number */
#if BYTE_ORDER == BIG_ENDIAN
/* fields in third byte */
unsigned qr: 1; /* response flag */
unsigned opcode: 4; /* purpose of message */
unsigned aa: 1; /* authoritative answer */
unsigned tc: 1; /* truncated message */
unsigned rd: 1; /* recursion desired */
/* fields in fourth byte */
unsigned ra: 1; /* recursion available */
unsigned unused :1; /* unused bits (MBZ as of 4.9.3a3) */
unsigned ad: 1; /* authentic data from named */
unsigned cd: 1; /* checking disabled by resolver */
unsigned rcode :4; /* response code */
#endif
#if BYTE_ORDER == LITTLE_ENDIAN || BYTE_ORDER == PDP_ENDIAN
/* fields in third byte */
unsigned rd :1; /* recursion desired */
unsigned tc :1; /* truncated message */
unsigned aa :1; /* authoritative answer */
unsigned opcode :4; /* purpose of message */
unsigned qr :1; /* response flag */
/* fields in fourth byte */
unsigned rcode :4; /* response code */
unsigned cd: 1; /* checking disabled by resolver */
unsigned ad: 1; /* authentic data from named */
unsigned unused :1; /* unused bits (MBZ as of 4.9.3a3) */
unsigned ra :1; /* recursion available */
#endif
/* remaining bytes */
unsigned qdcount :16; /* number of question entries */
unsigned ancount :16; /* number of answer entries */
unsigned nscount :16; /* number of authority entries */
unsigned arcount :16; /* number of resource entries */
} HEADER;
#define NS_INT32SZ 4 /* #/bytes of data in a uint32_t */
#define NS_INT16SZ 2 /* #/bytes of data in a uint16_t */
#define NS_GET16(s, cp) do { \
const u_char *t_cp = (const u_char *)(cp); \
(s) = ((uint16_t)t_cp[0] << 8) \
| ((uint16_t)t_cp[1]) \
; \
(cp) += NS_INT16SZ; \
} while (/*CONSTCOND*/0)
#define NS_GET32(l, cp) do { \
const u_char *t_cp = (const u_char *)(cp); \
(l) = ((uint32_t)t_cp[0] << 24) \
| ((uint32_t)t_cp[1] << 16) \
| ((uint32_t)t_cp[2] << 8) \
| ((uint32_t)t_cp[3]) \
; \
(cp) += NS_INT32SZ; \
} while (/*CONSTCOND*/0)
#define GETSHORT NS_GET16
#define GETLONG NS_GET32
#define C_IN 1
/* From bionic/libc/private/resolv_private.h */
int dn_expand(const u_char *, const u_char *, const u_char *, char *, int);
#define dn_skipname __dn_skipname
int dn_skipname(const u_char *, const u_char *);
/* From bionic/libc/private/arpa_nameser_compat.h */
#define T_MX ns_t_mx
#define T_TXT ns_t_txt
#define T_SOA ns_t_soa
#define T_NS ns_t_ns
/* From bionic/libc/private/arpa_nameser.h */
typedef enum __ns_type {
ns_t_invalid = 0, /* Cookie. */
ns_t_a = 1, /* Host address. */
ns_t_ns = 2, /* Authoritative server. */
ns_t_md = 3, /* Mail destination. */
ns_t_mf = 4, /* Mail forwarder. */
ns_t_cname = 5, /* Canonical name. */
ns_t_soa = 6, /* Start of authority zone. */
ns_t_mb = 7, /* Mailbox domain name. */
ns_t_mg = 8, /* Mail group member. */
ns_t_mr = 9, /* Mail rename name. */
ns_t_null = 10, /* Null resource record. */
ns_t_wks = 11, /* Well known service. */
ns_t_ptr = 12, /* Domain name pointer. */
ns_t_hinfo = 13, /* Host information. */
ns_t_minfo = 14, /* Mailbox information. */
ns_t_mx = 15, /* Mail routing information. */
ns_t_txt = 16, /* Text strings. */
ns_t_rp = 17, /* Responsible person. */
ns_t_afsdb = 18, /* AFS cell database. */
ns_t_x25 = 19, /* X_25 calling address. */
ns_t_isdn = 20, /* ISDN calling address. */
ns_t_rt = 21, /* Router. */
ns_t_nsap = 22, /* NSAP address. */
ns_t_nsap_ptr = 23, /* Reverse NSAP lookup (deprecated). */
ns_t_sig = 24, /* Security signature. */
ns_t_key = 25, /* Security key. */
ns_t_px = 26, /* X.400 mail mapping. */
ns_t_gpos = 27, /* Geographical position (withdrawn). */
ns_t_aaaa = 28, /* Ip6 Address. */
ns_t_loc = 29, /* Location Information. */
ns_t_nxt = 30, /* Next domain (security). */
ns_t_eid = 31, /* Endpoint identifier. */
ns_t_nimloc = 32, /* Nimrod Locator. */
ns_t_srv = 33, /* Server Selection. */
ns_t_atma = 34, /* ATM Address */
ns_t_naptr = 35, /* Naming Authority PoinTeR */
ns_t_kx = 36, /* Key Exchange */
ns_t_cert = 37, /* Certification record */
ns_t_a6 = 38, /* IPv6 address (deprecates AAAA) */
ns_t_dname = 39, /* Non-terminal DNAME (for IPv6) */
ns_t_sink = 40, /* Kitchen sink (experimental) */
ns_t_opt = 41, /* EDNS0 option (meta-RR) */
ns_t_apl = 42, /* Address prefix list (RFC 3123) */
ns_t_tkey = 249, /* Transaction key */
ns_t_tsig = 250, /* Transaction signature. */
ns_t_ixfr = 251, /* Incremental zone transfer. */
ns_t_axfr = 252, /* Transfer zone of authority. */
ns_t_mailb = 253, /* Transfer mailbox records. */
ns_t_maila = 254, /* Transfer mail agent records. */
ns_t_any = 255, /* Wildcard match. */
ns_t_zxfr = 256, /* BIND-specific, nonstandard. */
ns_t_max = 65536
} ns_type;
#endif /* __BIONIC__ */
/* Wrapper around dn_expand() which does associated length checks and returns
* errors as #GError. */
static gboolean
expand_name (const gchar *rrname,
const guint8 *answer,
const guint8 *end,
const guint8 **p,
gchar *namebuf,
gsize namebuf_len,
GError **error)
{
int expand_result;
expand_result = dn_expand (answer, end, *p, namebuf, namebuf_len);
if (expand_result < 0 || end - *p < expand_result)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), rrname);
return FALSE;
}
*p += expand_result;
return TRUE;
}
static GVariant *
parse_res_srv (const guint8 *answer,
const guint8 *end,
const guint8 **p,
GError **error)
{
gchar namebuf[1024];
guint16 priority, weight, port;
if (end - *p < 6)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), "SRV");
return NULL;
}
GETSHORT (priority, *p);
GETSHORT (weight, *p);
GETSHORT (port, *p);
/* RFC 2782 says (on page 4) that “Unless and until permitted by future
* standards action, name compression is not to be used for this field.”, so
* technically we shouldn’t be expanding names here for SRV records.
*
* However, other DNS resolvers (such as systemd[1]) do, and it seems in
* keeping with the principle of being liberal in what you accept and strict
* in what you emit. It also seems harmless.
*
* An earlier version of the RFC, RFC 2052 (now obsolete) specified that name
* compression *was* to be used for SRV targets[2].
*
* See discussion on https://gitlab.gnome.org/GNOME/glib/-/issues/2622.
*
* [1]: https://github.com/yuwata/systemd/blob/2d23cc3c07c49722ce93170737b3efd2692a2d08/src/resolve/resolved-dns-packet.c#L1674
* [2]: https://datatracker.ietf.org/doc/html/rfc2052#page-3
*/
if (!expand_name ("SRV", answer, end, p, namebuf, sizeof (namebuf), error))
return NULL;
return g_variant_new ("(qqqs)",
priority,
weight,
port,
namebuf);
}
static GVariant *
parse_res_soa (const guint8 *answer,
const guint8 *end,
const guint8 **p,
GError **error)
{
gchar mnamebuf[1024];
gchar rnamebuf[1024];
guint32 serial, refresh, retry, expire, ttl;
if (!expand_name ("SOA", answer, end, p, mnamebuf, sizeof (mnamebuf), error))
return NULL;
if (!expand_name ("SOA", answer, end, p, rnamebuf, sizeof (rnamebuf), error))
return NULL;
if (end - *p < 20)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), "SOA");
return NULL;
}
GETLONG (serial, *p);
GETLONG (refresh, *p);
GETLONG (retry, *p);
GETLONG (expire, *p);
GETLONG (ttl, *p);
return g_variant_new ("(ssuuuuu)",
mnamebuf,
rnamebuf,
serial,
refresh,
retry,
expire,
ttl);
}
static GVariant *
parse_res_ns (const guint8 *answer,
const guint8 *end,
const guint8 **p,
GError **error)
{
gchar namebuf[1024];
if (!expand_name ("NS", answer, end, p, namebuf, sizeof (namebuf), error))
return NULL;
return g_variant_new ("(s)", namebuf);
}
static GVariant *
parse_res_mx (const guint8 *answer,
const guint8 *end,
const guint8 **p,
GError **error)
{
gchar namebuf[1024];
guint16 preference;
if (end - *p < 2)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), "MX");
return NULL;
}
GETSHORT (preference, *p);
if (!expand_name ("MX", answer, end, p, namebuf, sizeof (namebuf), error))
return NULL;
return g_variant_new ("(qs)",
preference,
namebuf);
}
static GVariant *
parse_res_txt (const guint8 *answer,
const guint8 *end,
const guint8 **p,
GError **error)
{
GVariant *record;
GPtrArray *array;
const guint8 *at = *p;
gsize len;
if (end - *p == 0)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), "TXT");
return NULL;
}
array = g_ptr_array_new_with_free_func (g_free);
while (at < end)
{
len = *(at++);
if (len > (gsize) (end - at))
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the placeholder is a DNS record type, such as ‘MX’ or ‘SRV’ */
_("Error parsing DNS %s record: malformed DNS packet"), "TXT");
g_ptr_array_free (array, TRUE);
return NULL;
}
g_ptr_array_add (array, g_strndup ((gchar *)at, len));
at += len;
}
*p = at;
record = g_variant_new ("(@as)",
g_variant_new_strv ((const gchar **)array->pdata, array->len));
g_ptr_array_free (array, TRUE);
return record;
}
gint
g_resolver_record_type_to_rrtype (GResolverRecordType type)
{
switch (type)
{
case G_RESOLVER_RECORD_SRV:
return T_SRV;
case G_RESOLVER_RECORD_TXT:
return T_TXT;
case G_RESOLVER_RECORD_SOA:
return T_SOA;
case G_RESOLVER_RECORD_NS:
return T_NS;
case G_RESOLVER_RECORD_MX:
return T_MX;
}
g_return_val_if_reached (-1);
}
GList *
g_resolver_records_from_res_query (const gchar *rrname,
gint rrtype,
const guint8 *answer,
gssize len,
gint herr,
GError **error)
{
uint16_t count;
gchar namebuf[1024];
const guint8 *end, *p;
guint16 type, qclass, rdlength;
const HEADER *header;
GList *records;
GVariant *record;
gsize len_unsigned;
GError *parsing_error = NULL;
if (len <= 0)
{
if (len == 0 || herr == HOST_NOT_FOUND || herr == NO_DATA)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_NOT_FOUND,
_("No DNS record of the requested type for “%s”"), rrname);
}
else if (herr == TRY_AGAIN)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_TEMPORARY_FAILURE,
_("Temporarily unable to resolve “%s”"), rrname);
}
else
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
_("Error resolving “%s”"), rrname);
}
return NULL;
}
/* We know len ≥ 0 now. */
len_unsigned = (gsize) len;
if (len_unsigned < sizeof (HEADER))
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the first placeholder is a domain name, the
* second is an error message */
_("Error resolving “%s”: %s"), rrname, _("Malformed DNS packet"));
return NULL;
}
records = NULL;
header = (HEADER *)answer;
p = answer + sizeof (HEADER);
end = answer + len_unsigned;
/* Skip query */
count = ntohs (header->qdcount);
while (count-- && p < end)
{
int expand_result;
expand_result = dn_expand (answer, end, p, namebuf, sizeof (namebuf));
if (expand_result < 0 || end - p < expand_result + 4)
{
/* Not possible to recover parsing as the length of the rest of the
* record is unknown or is too short. */
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the first placeholder is a domain name, the
* second is an error message */
_("Error resolving “%s”: %s"), rrname, _("Malformed DNS packet"));
return NULL;
}
p += expand_result;
p += 4; /* skip TYPE and CLASS */
/* To silence gcc warnings */
namebuf[0] = namebuf[1];
}
/* Read answers */
count = ntohs (header->ancount);
while (count-- && p < end)
{
int expand_result;
expand_result = dn_expand (answer, end, p, namebuf, sizeof (namebuf));
if (expand_result < 0 || end - p < expand_result + 10)
{
/* Not possible to recover parsing as the length of the rest of the
* record is unknown or is too short. */
g_set_error (&parsing_error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the first placeholder is a domain name, the
* second is an error message */
_("Error resolving “%s”: %s"), rrname, _("Malformed DNS packet"));
break;
}
p += expand_result;
GETSHORT (type, p);
GETSHORT (qclass, p);
p += 4; /* ignore the ttl (type=long) value */
GETSHORT (rdlength, p);
if (end - p < rdlength)
{
g_set_error (&parsing_error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
/* Translators: the first placeholder is a domain name, the
* second is an error message */
_("Error resolving “%s”: %s"), rrname, _("Malformed DNS packet"));
break;
}
if (type != rrtype || qclass != C_IN)
{
p += rdlength;
continue;
}
switch (rrtype)
{
case T_SRV:
record = parse_res_srv (answer, p + rdlength, &p, &parsing_error);
break;
case T_MX:
record = parse_res_mx (answer, p + rdlength, &p, &parsing_error);
break;
case T_SOA:
record = parse_res_soa (answer, p + rdlength, &p, &parsing_error);
break;
case T_NS:
record = parse_res_ns (answer, p + rdlength, &p, &parsing_error);
break;
case T_TXT:
record = parse_res_txt (answer, p + rdlength, &p, &parsing_error);
break;
default:
g_debug ("Unrecognised DNS record type %u", rrtype);
record = NULL;
break;
}
if (record != NULL)
records = g_list_prepend (records, record);
if (parsing_error != NULL)
break;
}
if (parsing_error != NULL)
{
g_propagate_prefixed_error (error, parsing_error, _("Failed to parse DNS response for “%s”: "), rrname);
g_list_free_full (records, (GDestroyNotify)g_variant_unref);
return NULL;
}
else if (records == NULL)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_NOT_FOUND,
_("No DNS record of the requested type for “%s”"), rrname);
return NULL;
}
else
return records;
}
#elif defined(G_OS_WIN32)
static GVariant *
parse_dns_srv (DNS_RECORD *rec)
{
return g_variant_new ("(qqqs)",
(guint16)rec->Data.SRV.wPriority,
(guint16)rec->Data.SRV.wWeight,
(guint16)rec->Data.SRV.wPort,
rec->Data.SRV.pNameTarget);
}
static GVariant *
parse_dns_soa (DNS_RECORD *rec)
{
return g_variant_new ("(ssuuuuu)",
rec->Data.SOA.pNamePrimaryServer,
rec->Data.SOA.pNameAdministrator,
(guint32)rec->Data.SOA.dwSerialNo,
(guint32)rec->Data.SOA.dwRefresh,
(guint32)rec->Data.SOA.dwRetry,
(guint32)rec->Data.SOA.dwExpire,
(guint32)rec->Data.SOA.dwDefaultTtl);
}
static GVariant *
parse_dns_ns (DNS_RECORD *rec)
{
return g_variant_new ("(s)", rec->Data.NS.pNameHost);
}
static GVariant *
parse_dns_mx (DNS_RECORD *rec)
{
return g_variant_new ("(qs)",
(guint16)rec->Data.MX.wPreference,
rec->Data.MX.pNameExchange);
}
static GVariant *
parse_dns_txt (DNS_RECORD *rec)
{
GVariant *record;
GPtrArray *array;
DWORD i;
array = g_ptr_array_new ();
for (i = 0; i < rec->Data.TXT.dwStringCount; i++)
g_ptr_array_add (array, rec->Data.TXT.pStringArray[i]);
record = g_variant_new ("(@as)",
g_variant_new_strv ((const gchar **)array->pdata, array->len));
g_ptr_array_free (array, TRUE);
return record;
}
static WORD
g_resolver_record_type_to_dnstype (GResolverRecordType type)
{
switch (type)
{
case G_RESOLVER_RECORD_SRV:
return DNS_TYPE_SRV;
case G_RESOLVER_RECORD_TXT:
return DNS_TYPE_TEXT;
case G_RESOLVER_RECORD_SOA:
return DNS_TYPE_SOA;
case G_RESOLVER_RECORD_NS:
return DNS_TYPE_NS;
case G_RESOLVER_RECORD_MX:
return DNS_TYPE_MX;
}
g_return_val_if_reached (-1);
}
static GList *
g_resolver_records_from_DnsQuery (const gchar *rrname,
WORD dnstype,
DNS_STATUS status,
DNS_RECORD *results,
GError **error)
{
DNS_RECORD *rec;
gpointer record;
GList *records;
if (status != ERROR_SUCCESS)
{
if (status == DNS_ERROR_RCODE_NAME_ERROR)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_NOT_FOUND,
_("No DNS record of the requested type for “%s”"), rrname);
}
else if (status == DNS_ERROR_RCODE_SERVER_FAILURE)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_TEMPORARY_FAILURE,
_("Temporarily unable to resolve “%s”"), rrname);
}
else
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
_("Error resolving “%s”"), rrname);
}
return NULL;
}
records = NULL;
for (rec = results; rec; rec = rec->pNext)
{
if (rec->wType != dnstype)
continue;
switch (dnstype)
{
case DNS_TYPE_SRV:
record = parse_dns_srv (rec);
break;
case DNS_TYPE_SOA:
record = parse_dns_soa (rec);
break;
case DNS_TYPE_NS:
record = parse_dns_ns (rec);
break;
case DNS_TYPE_MX:
record = parse_dns_mx (rec);
break;
case DNS_TYPE_TEXT:
record = parse_dns_txt (rec);
break;
default:
g_warn_if_reached ();
record = NULL;
break;
}
if (record != NULL)
records = g_list_prepend (records, g_variant_ref_sink (record));
}
if (records == NULL)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_NOT_FOUND,
_("No DNS record of the requested type for “%s”"), rrname);
return NULL;
}
else
return records;
}
#endif
static void
free_records (GList *records)
{
g_list_free_full (records, (GDestroyNotify) g_variant_unref);
}
#if defined(G_OS_UNIX)
#ifdef __BIONIC__
#ifndef C_IN
#define C_IN 1
#endif
int res_query(const char *, int, int, u_char *, int);
#endif
#endif
static GList *
do_lookup_records (const gchar *rrname,
GResolverRecordType record_type,
GCancellable *cancellable,
GError **error)
{
GList *records;
#if defined(G_OS_UNIX)
gint len = 512;
gint herr;
GByteArray *answer;
gint rrtype;
#ifdef HAVE_RES_NQUERY
/* Load the resolver state. This is done once per worker thread, and the
* #GResolver::reload signal is ignored (since we always reload). This could
* be improved by having an explicit worker thread pool, with each thread
* containing some state which is initialised at thread creation time and
* updated in response to #GResolver::reload.
*
* What we have currently is not particularly worse than using res_query() in
* worker threads, since it would transparently call res_init() for each new
* worker thread. (Although the workers would get reused by the
* #GThreadPool.)
*
* FreeBSD requires the state to be zero-filled before calling res_ninit(). */
struct __res_state res = { 0, };
if (res_ninit (&res) != 0)
{
g_set_error (error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_INTERNAL,
_("Error resolving “%s”"), rrname);
return NULL;
}
#endif
rrtype = g_resolver_record_type_to_rrtype (record_type);
answer = g_byte_array_new ();
for (;;)
{
g_byte_array_set_size (answer, len * 2);
#if defined(HAVE_RES_NQUERY)
len = res_nquery (&res, rrname, C_IN, rrtype, answer->data, answer->len);
#else
len = res_query (rrname, C_IN, rrtype, answer->data, answer->len);
#endif
/* If answer fit in the buffer then we're done */
if (len < 0 || len < (gint)answer->len)
break;
/*
* On overflow some res_query's return the length needed, others
* return the full length entered. This code works in either case.
*/
}
herr = h_errno;
records = g_resolver_records_from_res_query (rrname, rrtype, answer->data, len, herr, error);
g_byte_array_free (answer, TRUE);
#ifdef HAVE_RES_NQUERY
#if defined(HAVE_RES_NDESTROY)
res_ndestroy (&res);
#elif defined(HAVE_RES_NCLOSE)
res_nclose (&res);
#elif defined(HAVE_RES_NINIT)
#error "Your platform has res_ninit() but not res_nclose() or res_ndestroy(). Please file a bug at https://gitlab.gnome.org/GNOME/glib/issues/new"
#endif
#endif /* HAVE_RES_NQUERY */
#else
DNS_STATUS status;
DNS_RECORD *results = NULL;
WORD dnstype;
dnstype = g_resolver_record_type_to_dnstype (record_type);
status = DnsQuery_A (rrname, dnstype, DNS_QUERY_STANDARD, NULL, &results, NULL);
records = g_resolver_records_from_DnsQuery (rrname, dnstype, status, results, error);
if (results != NULL)
DnsRecordListFree (results, DnsFreeRecordList);
#endif
return g_steal_pointer (&records);
}
static GList *
lookup_records (GResolver *resolver,
const gchar *rrname,
GResolverRecordType record_type,
GCancellable *cancellable,
GError **error)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
GTask *task;
GList *records;
LookupData *data = NULL;
task = g_task_new (resolver, cancellable, NULL, NULL);
g_task_set_source_tag (task, lookup_records);
g_task_set_name (task, "[gio] resolver lookup records");
data = lookup_data_new_records (rrname, record_type);
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_sync (self, task);
records = g_task_propagate_pointer (task, error);
g_object_unref (task);
return records;
}
static void
lookup_records_async (GResolver *resolver,
const char *rrname,
GResolverRecordType record_type,
GCancellable *cancellable,
GAsyncReadyCallback callback,
gpointer user_data)
{
GThreadedResolver *self = G_THREADED_RESOLVER (resolver);
GTask *task;
LookupData *data = NULL;
task = g_task_new (resolver, cancellable, callback, user_data);
g_task_set_source_tag (task, lookup_records_async);
g_task_set_name (task, "[gio] resolver lookup records");
data = lookup_data_new_records (rrname, record_type);
g_task_set_task_data (task, g_steal_pointer (&data), (GDestroyNotify) lookup_data_free);
run_task_in_thread_pool_async (self, task);
g_object_unref (task);
}
static GList *
lookup_records_finish (GResolver *resolver,
GAsyncResult *result,
GError **error)
{
g_return_val_if_fail (g_task_is_valid (result, resolver), NULL);
return g_task_propagate_pointer (G_TASK (result), error);
}
/* Will be called in the GLib worker thread, so must lock all accesses to shared
* data. */
static gboolean
timeout_cb (gpointer user_data)
{
GTask *task = G_TASK (user_data);
LookupData *data = g_task_get_task_data (task);
gboolean should_return;
g_mutex_lock (&data->lock);
should_return = g_atomic_int_compare_and_exchange (&data->will_return, NOT_YET, TIMED_OUT);
g_clear_pointer (&data->timeout_source, g_source_unref);
g_mutex_unlock (&data->lock);
if (should_return)
g_task_return_new_error (task, G_IO_ERROR, G_IO_ERROR_TIMED_OUT,
_("Socket I/O timed out"));
/* Signal completion of the task. */
g_mutex_lock (&data->lock);
data->has_returned = TRUE;
g_cond_broadcast (&data->cond);
g_mutex_unlock (&data->lock);
return G_SOURCE_REMOVE;
}
/* Will be called in the GLib worker thread, so must lock all accesses to shared
* data. */
static gboolean
cancelled_cb (GCancellable *cancellable,
gpointer user_data)
{
GTask *task = G_TASK (user_data);
LookupData *data = g_task_get_task_data (task);
gboolean should_return;
g_mutex_lock (&data->lock);
g_assert (g_cancellable_is_cancelled (cancellable));
should_return = g_atomic_int_compare_and_exchange (&data->will_return, NOT_YET, CANCELLED);
g_clear_pointer (&data->cancellable_source, g_source_unref);
g_mutex_unlock (&data->lock);
if (should_return)
g_task_return_error_if_cancelled (task);
/* Signal completion of the task. */
g_mutex_lock (&data->lock);
data->has_returned = TRUE;
g_cond_broadcast (&data->cond);
g_mutex_unlock (&data->lock);
return G_SOURCE_REMOVE;
}
static void
run_task_in_thread_pool_async (GThreadedResolver *self,
GTask *task)
{
LookupData *data = g_task_get_task_data (task);
guint timeout_ms = g_resolver_get_timeout (G_RESOLVER (self));
GCancellable *cancellable = g_task_get_cancellable (task);
g_mutex_lock (&data->lock);
g_thread_pool_push (self->thread_pool, g_object_ref (task), NULL);
if (timeout_ms != 0)
{
data->timeout_source = g_timeout_source_new (timeout_ms);
g_source_set_static_name (data->timeout_source, "[gio] threaded resolver timeout");
g_source_set_callback (data->timeout_source, G_SOURCE_FUNC (timeout_cb), task, NULL);
g_source_attach (data->timeout_source, GLIB_PRIVATE_CALL (g_get_worker_context) ());
}
if (cancellable != NULL)
{
data->cancellable_source = g_cancellable_source_new (cancellable);
g_source_set_static_name (data->cancellable_source, "[gio] threaded resolver cancellable");
g_source_set_callback (data->cancellable_source, G_SOURCE_FUNC (cancelled_cb), task, NULL);
g_source_attach (data->cancellable_source, GLIB_PRIVATE_CALL (g_get_worker_context) ());
}
g_mutex_unlock (&data->lock);
}
static void
run_task_in_thread_pool_sync (GThreadedResolver *self,
GTask *task)
{
LookupData *data = g_task_get_task_data (task);
run_task_in_thread_pool_async (self, task);
g_mutex_lock (&data->lock);
while (!data->has_returned)
g_cond_wait (&data->cond, &data->lock);
g_mutex_unlock (&data->lock);
}
static void
threaded_resolver_worker_cb (gpointer task_data,
gpointer user_data)
{
GTask *task = G_TASK (g_steal_pointer (&task_data));
LookupData *data = g_task_get_task_data (task);
GCancellable *cancellable = g_task_get_cancellable (task);
GError *local_error = NULL;
gboolean should_return;
switch (data->lookup_type) {
case LOOKUP_BY_NAME:
{
GList *addresses = do_lookup_by_name (data->lookup_by_name.hostname,
data->lookup_by_name.address_family,
cancellable,
&local_error);
g_mutex_lock (&data->lock);
should_return = g_atomic_int_compare_and_exchange (&data->will_return, NOT_YET, COMPLETED);
g_mutex_unlock (&data->lock);
if (should_return)
{
if (addresses != NULL)
g_task_return_pointer (task, g_steal_pointer (&addresses), (GDestroyNotify) g_resolver_free_addresses);
else
g_task_return_error (task, g_steal_pointer (&local_error));
}
g_clear_pointer (&addresses, g_resolver_free_addresses);
}
break;
case LOOKUP_BY_ADDRESS:
{
gchar *name = do_lookup_by_address (data->lookup_by_address.address,
cancellable,
&local_error);
g_mutex_lock (&data->lock);
should_return = g_atomic_int_compare_and_exchange (&data->will_return, NOT_YET, COMPLETED);
g_mutex_unlock (&data->lock);
if (should_return)
{
if (name != NULL)
g_task_return_pointer (task, g_steal_pointer (&name), g_free);
else
g_task_return_error (task, g_steal_pointer (&local_error));
}
g_clear_pointer (&name, g_free);
}
break;
case LOOKUP_RECORDS:
{
GList *records = do_lookup_records (data->lookup_records.rrname,
data->lookup_records.record_type,
cancellable,
&local_error);
g_mutex_lock (&data->lock);
should_return = g_atomic_int_compare_and_exchange (&data->will_return, NOT_YET, COMPLETED);
g_mutex_unlock (&data->lock);
if (should_return)
{
if (records != NULL)
g_task_return_pointer (task, g_steal_pointer (&records), (GDestroyNotify) free_records);
else
g_task_return_error (task, g_steal_pointer (&local_error));
}
g_clear_pointer (&records, free_records);
}
break;
default:
g_assert_not_reached ();
}
/* Signal completion of a task. */
g_mutex_lock (&data->lock);
data->has_returned = TRUE;
g_cond_broadcast (&data->cond);
g_mutex_unlock (&data->lock);
g_object_unref (task);
}
static void
g_threaded_resolver_class_init (GThreadedResolverClass *threaded_class)
{
GObjectClass *object_class = G_OBJECT_CLASS (threaded_class);
GResolverClass *resolver_class = G_RESOLVER_CLASS (threaded_class);
object_class->finalize = g_threaded_resolver_finalize;
resolver_class->lookup_by_name = lookup_by_name;
resolver_class->lookup_by_name_async = lookup_by_name_async;
resolver_class->lookup_by_name_finish = lookup_by_name_finish;
resolver_class->lookup_by_name_with_flags = lookup_by_name_with_flags;
resolver_class->lookup_by_name_with_flags_async = lookup_by_name_with_flags_async;
resolver_class->lookup_by_name_with_flags_finish = lookup_by_name_with_flags_finish;
resolver_class->lookup_by_address = lookup_by_address;
resolver_class->lookup_by_address_async = lookup_by_address_async;
resolver_class->lookup_by_address_finish = lookup_by_address_finish;
resolver_class->lookup_records = lookup_records;
resolver_class->lookup_records_async = lookup_records_async;
resolver_class->lookup_records_finish = lookup_records_finish;
}