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NetworkManager/src/core/devices/nm-device-wireguard.c

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/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
* Copyright (C) 2018 Javier Arteaga <jarteaga@jbeta.is>
*/
#include "src/core/nm-default-daemon.h"
#include "nm-device-wireguard.h"
#include <linux/rtnetlink.h>
#include <linux/fib_rules.h>
#include "nm-setting-wireguard.h"
#include "libnm-core-aux-intern/nm-libnm-core-utils.h"
#include "nm-l3-config-data.h"
#include "libnm-core-intern/nm-core-internal.h"
#include "libnm-glib-aux/nm-secret-utils.h"
#include "nm-device-private.h"
#include "libnm-platform/nm-platform.h"
#include "libnm-platform/nmp-object.h"
#include "libnm-platform/nmp-route-manager.h"
#include "nm-device-factory.h"
#include "nm-active-connection.h"
#include "nm-act-request.h"
#include "dns/nm-dns-manager.h"
#define _NMLOG_DEVICE_TYPE NMDeviceWireGuard
#include "nm-device-logging.h"
/*****************************************************************************/
/* TODO: activate profile with peer preshared-key-flags=2. On first activation, the secret is
* requested (good). Enter it and connect. Reactivate the profile, now there is no password
* prompt, as the secret is cached (good??). */
/* TODO: unlike for other VPNs, we don't inject a direct route to the peers. That means,
* you might get a routing scenario where the peer (VPN server) is reachable via the VPN.
* How we handle adding routes to external gateway for other peers, has severe issues
* as well. We may use policy-routing like wg-quick does. See also discussions at
* https://www.wireguard.com/netns/#improving-the-classic-solutions */
/* TODO: honor the TTL of DNS to determine when to retry resolving endpoints. */
/* TODO: when we get multiple IP addresses when resolving a peer endpoint. We currently
* just take the first from GAI. We should only accept AAAA/IPv6 if we also have a suitable
* IPv6 address. The problem is, that we have to recheck that when IP addressing on other
* interfaces changes. This makes it almost too cumbersome to implement. */
/*****************************************************************************/
G_STATIC_ASSERT(NM_WIREGUARD_PUBLIC_KEY_LEN == NMP_WIREGUARD_PUBLIC_KEY_LEN);
G_STATIC_ASSERT(NM_WIREGUARD_SYMMETRIC_KEY_LEN == NMP_WIREGUARD_SYMMETRIC_KEY_LEN);
/*****************************************************************************/
#define LINK_CONFIG_RATE_LIMIT_NSEC (50 * NM_UTILS_NSEC_PER_MSEC)
/* a special @next_try_at_nsec timestamp indicating that we should try again as soon as possible. */
#define NEXT_TRY_AT_NSEC_ASAP ((gint64) G_MAXINT64)
/* a special @next_try_at_nsec timestamp that is
* - positive (indicating resolve-checks are enabled)
* - already in the past (we use the absolute timestamp of 1nsec for that). */
#define NEXT_TRY_AT_NSEC_PAST ((gint64) 1)
/* like %NEXT_TRY_AT_NSEC_ASAP, but used for indicating to retry ASAP for a @retry_in_msec value.
* That is a relative time duration, contrary to @next_try_at_nsec which is an absolute
* timestamp. */
#define RETRY_IN_MSEC_ASAP ((gint64) G_MAXINT64)
#define RETRY_IN_MSEC_MAX ((gint64) (30 * 60 * 1000))
typedef enum {
LINK_CONFIG_MODE_FULL,
LINK_CONFIG_MODE_REAPPLY,
LINK_CONFIG_MODE_ASSUME,
LINK_CONFIG_MODE_ENDPOINTS,
} LinkConfigMode;
typedef struct {
GCancellable *cancellable;
NMSockAddrUnion sockaddr;
/* the timestamp (in nm_utils_get_monotonic_timestamp_nsec() scale) when we want
* to retry resolving the endpoint (again).
*
* It may be set to %NEXT_TRY_AT_NSEC_ASAP to indicate to re-resolve as soon as possible.
*
* A @sockaddr is either fixed or it has
* - @cancellable set to indicate an ongoing request
* - @next_try_at_nsec set to a positive value, indicating when
* we ought to retry. */
gint64 next_try_at_nsec;
guint resolv_fail_count;
} PeerEndpointResolveData;
typedef struct {
NMWireGuardPeer *peer;
NMDeviceWireGuard *self;
CList lst_peers;
PeerEndpointResolveData ep_resolv;
/* dirty flag used during _peers_update_all(). */
bool dirty_update_all : 1;
} PeerData;
NM_GOBJECT_PROPERTIES_DEFINE(NMDeviceWireGuard, PROP_PUBLIC_KEY, PROP_LISTEN_PORT, PROP_FWMARK, );
typedef struct {
NMDnsManager *dns_manager;
NMPlatformLnkWireGuard lnk_curr;
NMActRequestGetSecretsCallId *secrets_call_id;
CList lst_peers_head;
GHashTable *peers;
/* counts the numbers of peers that are currently resolving. */
guint peers_resolving_cnt;
gint64 resolve_next_try_at;
gint64 link_config_last_at;
guint resolve_next_try_id;
guint link_config_delayed_id;
guint32 auto_default_route_fwmark;
guint32 auto_default_route_priority;
bool auto_default_route_enabled_4 : 1;
bool auto_default_route_enabled_6 : 1;
bool auto_default_route_initialized : 1;
bool auto_default_route_refresh : 1;
bool auto_default_route_priority_initialized : 1;
} NMDeviceWireGuardPrivate;
struct _NMDeviceWireGuard {
NMDevice parent;
NMDeviceWireGuardPrivate _priv;
};
struct _NMDeviceWireGuardClass {
NMDeviceClass parent;
};
G_DEFINE_TYPE(NMDeviceWireGuard, nm_device_wireguard, NM_TYPE_DEVICE)
#define NM_DEVICE_WIREGUARD_GET_PRIVATE(self) \
_NM_GET_PRIVATE(self, NMDeviceWireGuard, NM_IS_DEVICE_WIREGUARD, NMDevice)
/*****************************************************************************/
static void _peers_resolve_start(NMDeviceWireGuard *self, PeerData *peer_data);
static void _peers_resolve_retry_reschedule(NMDeviceWireGuard *self, gint64 new_next_try_at_nsec);
static gboolean link_config_delayed_resolver_cb(gpointer user_data);
static gboolean link_config_delayed_ratelimit_cb(gpointer user_data);
/*****************************************************************************/
static NM_UTILS_LOOKUP_STR_DEFINE(_link_config_mode_to_string,
LinkConfigMode,
NM_UTILS_LOOKUP_DEFAULT_NM_ASSERT(NULL),
NM_UTILS_LOOKUP_ITEM(LINK_CONFIG_MODE_FULL, "full"),
NM_UTILS_LOOKUP_ITEM(LINK_CONFIG_MODE_REAPPLY, "reapply"),
NM_UTILS_LOOKUP_ITEM(LINK_CONFIG_MODE_ASSUME, "assume"),
NM_UTILS_LOOKUP_ITEM(LINK_CONFIG_MODE_ENDPOINTS, "endpoints"), );
/*****************************************************************************/
static void
_auto_default_route_get_enabled(NMSettingWireGuard *s_wg,
NMConnection *connection,
gboolean *out_enabled_v4,
gboolean *out_enabled_v6)
{
NMTernary enabled_v4;
NMTernary enabled_v6;
enabled_v4 = nm_setting_wireguard_get_ip4_auto_default_route(s_wg);
enabled_v6 = nm_setting_wireguard_get_ip6_auto_default_route(s_wg);
if (enabled_v4 == NM_TERNARY_DEFAULT) {
if (nm_setting_ip_config_get_never_default(
nm_connection_get_setting_ip_config(connection, AF_INET)))
enabled_v4 = FALSE;
}
if (enabled_v6 == NM_TERNARY_DEFAULT) {
if (nm_setting_ip_config_get_never_default(
nm_connection_get_setting_ip_config(connection, AF_INET6)))
enabled_v6 = FALSE;
}
if (enabled_v4 == NM_TERNARY_DEFAULT || enabled_v6 == NM_TERNARY_DEFAULT) {
guint i, n_peers;
n_peers = nm_setting_wireguard_get_peers_len(s_wg);
for (i = 0; i < n_peers; i++) {
NMWireGuardPeer *peer = nm_setting_wireguard_get_peer(s_wg, i);
guint n_aips;
guint j;
n_aips = nm_wireguard_peer_get_allowed_ips_len(peer);
for (j = 0; j < n_aips; j++) {
const char *aip;
gboolean valid;
int prefix;
int addr_family;
aip = nm_wireguard_peer_get_allowed_ip(peer, j, &valid);
if (!valid)
continue;
if (!nm_utils_parse_inaddr_prefix_bin(AF_UNSPEC, aip, &addr_family, NULL, &prefix))
continue;
if (prefix != 0)
continue;
if (addr_family == AF_INET) {
if (enabled_v4 == NM_TERNARY_DEFAULT) {
enabled_v4 = TRUE;
if (enabled_v6 != NM_TERNARY_DEFAULT)
goto done;
}
} else {
if (enabled_v6 == NM_TERNARY_DEFAULT) {
enabled_v6 = TRUE;
if (enabled_v4 != NM_TERNARY_DEFAULT)
goto done;
}
}
}
}
done:;
}
*out_enabled_v4 = (enabled_v4 == TRUE);
*out_enabled_v6 = (enabled_v6 == TRUE);
}
#define AUTO_RANDOM_RANGE 500u
static guint32
_auto_default_route_get_auto_fwmark(const char *uuid)
{
guint64 rnd_seed;
/* we use the generated number as fwmark but also as routing table for
* the default-route.
*
* We pick a number
*
* - based on the connection's UUID (as stable seed).
* - larger than 51820u (arbitrarily)
* - one out of AUTO_RANDOM_RANGE
*/
rnd_seed = c_siphash_hash(NM_HASH_SEED_16(0xb9,
0x39,
0x8e,
0xed,
0x15,
0xb3,
0xd1,
0xc4,
0x5f,
0x45,
0x00,
0x4f,
0xec,
0xc2,
0x2b,
0x7e),
(const guint8 *) uuid,
uuid ? strlen(uuid) + 1u : 0u);
return 51820u + (rnd_seed % AUTO_RANDOM_RANGE);
}
#define PRIO_WIDTH 2u
static guint32
_auto_default_route_get_auto_priority(const char *uuid)
{
const guint32 RANGE_TOP = 32766u - 1000u;
guint64 rnd_seed;
/* we pick a priority for the routing rules as follows:
*
* - use the connection's UUID as stable seed for the "random" number.
* - have it smaller than RANGE_TOP (32766u - 1000u), where 32766u is the priority of the default
* rules
* - we add 2 rules (PRIO_WIDTH). Hence only pick even priorities.
* - pick one out of AUTO_RANDOM_RANGE. */
rnd_seed = c_siphash_hash(NM_HASH_SEED_16(0x99,
0x22,
0x4d,
0x7c,
0x37,
0xda,
0x8e,
0x7b,
0x2f,
0x55,
0x16,
0x7b,
0x75,
0xda,
0x42,
0xdc),
(const guint8 *) uuid,
uuid ? strlen(uuid) + 1u : 0u);
return RANGE_TOP - (((rnd_seed % (PRIO_WIDTH * AUTO_RANDOM_RANGE)) / PRIO_WIDTH) * PRIO_WIDTH);
}
static void
_auto_default_route_init(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
NMConnection *connection;
gboolean enabled_v4 = FALSE;
gboolean enabled_v6 = FALSE;
gboolean refreshing_only;
guint32 new_fwmark = 0;
guint32 old_fwmark;
char sbuf1[100];
if (G_LIKELY(priv->auto_default_route_initialized && !priv->auto_default_route_refresh))
return;
refreshing_only = priv->auto_default_route_initialized && priv->auto_default_route_refresh;
old_fwmark = priv->auto_default_route_fwmark;
connection = nm_device_get_applied_connection(NM_DEVICE(self));
if (connection) {
NMSettingWireGuard *s_wg;
s_wg = _nm_connection_get_setting(connection, NM_TYPE_SETTING_WIREGUARD);
new_fwmark = nm_setting_wireguard_get_fwmark(s_wg);
_auto_default_route_get_enabled(s_wg, connection, &enabled_v4, &enabled_v6);
}
if ((enabled_v4 || enabled_v6) && new_fwmark == 0u) {
if (refreshing_only)
new_fwmark = old_fwmark;
else
new_fwmark = _auto_default_route_get_auto_fwmark(nm_connection_get_uuid(connection));
}
priv->auto_default_route_refresh = FALSE;
priv->auto_default_route_fwmark = new_fwmark;
priv->auto_default_route_enabled_4 = enabled_v4;
priv->auto_default_route_enabled_6 = enabled_v6;
priv->auto_default_route_initialized = TRUE;
if (connection) {
_LOGT(LOGD_DEVICE,
"auto-default-route is %s for IPv4 and %s for IPv6%s",
priv->auto_default_route_enabled_4 ? "enabled" : "disabled",
priv->auto_default_route_enabled_6 ? "enabled" : "disabled",
priv->auto_default_route_enabled_4 || priv->auto_default_route_enabled_6
? nm_sprintf_buf(sbuf1, " (fwmark 0x%x)", priv->auto_default_route_fwmark)
: "");
}
}
static GPtrArray *
get_extra_rules(NMDevice *device)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(device);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
gs_unref_ptrarray GPtrArray *extra_rules = NULL;
guint32 priority = 0;
int is_ipv4;
NMConnection *connection;
_auto_default_route_init(self);
connection = nm_device_get_applied_connection(device);
if (!connection)
return NULL;
for (is_ipv4 = 0; is_ipv4 < 2; is_ipv4++) {
NMSettingIPConfig *s_ip;
int addr_family = is_ipv4 ? AF_INET : AF_INET6;
guint32 table_main;
guint32 fwmark;
if (is_ipv4) {
if (!priv->auto_default_route_enabled_4)
continue;
} else {
if (!priv->auto_default_route_enabled_6)
continue;
}
if (!extra_rules) {
if (priv->auto_default_route_priority_initialized)
priority = priv->auto_default_route_priority;
else {
priority =
_auto_default_route_get_auto_priority(nm_connection_get_uuid(connection));
priv->auto_default_route_priority = priority;
priv->auto_default_route_priority_initialized = TRUE;
}
extra_rules = g_ptr_array_new_with_free_func((GDestroyNotify) nmp_object_unref);
}
s_ip = nm_connection_get_setting_ip_config(connection, addr_family);
table_main = nm_setting_ip_config_get_route_table(s_ip);
if (table_main == 0)
table_main = RT_TABLE_MAIN;
fwmark = priv->auto_default_route_fwmark;
G_STATIC_ASSERT_EXPR(PRIO_WIDTH == 2);
g_ptr_array_add(extra_rules,
nmp_object_new(NMP_OBJECT_TYPE_ROUTING_RULE,
&((const NMPlatformRoutingRule){
.priority = priority,
.addr_family = addr_family,
.action = FR_ACT_TO_TBL,
.table = table_main,
.suppress_prefixlen_inverse = ~((guint32) 0u),
})));
g_ptr_array_add(extra_rules,
nmp_object_new(NMP_OBJECT_TYPE_ROUTING_RULE,
&((const NMPlatformRoutingRule){
.priority = priority + 1u,
.addr_family = addr_family,
.action = FR_ACT_TO_TBL,
.table = fwmark,
.flags = FIB_RULE_INVERT,
.fwmark = fwmark,
.fwmask = 0xFFFFFFFFu,
})));
}
return g_steal_pointer(&extra_rules);
}
static guint32
coerce_route_table(NMDevice *device, int addr_family, guint32 route_table, gboolean is_user_config)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(device);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
gboolean auto_default_route_enabled;
if (route_table != 0u)
return route_table;
_auto_default_route_init(self);
auto_default_route_enabled = (addr_family == AF_INET) ? priv->auto_default_route_enabled_4
: priv->auto_default_route_enabled_6;
if (auto_default_route_enabled) {
/* we need to enable full-sync mode of all routing tables. */
_LOGT(LOGD_DEVICE,
"coerce ipv%c.route-table setting to \"main\" (table 254) as we enable "
"auto-default-route handling",
nm_utils_addr_family_to_char(addr_family));
return RT_TABLE_MAIN;
}
return 0;
}
/*****************************************************************************/
static gboolean
_peer_data_equal(gconstpointer ptr_a, gconstpointer ptr_b)
{
const PeerData *peer_data_a = ptr_a;
const PeerData *peer_data_b = ptr_b;
return nm_streq(nm_wireguard_peer_get_public_key(peer_data_a->peer),
nm_wireguard_peer_get_public_key(peer_data_b->peer));
}
static guint
_peer_data_hash(gconstpointer ptr)
{
const PeerData *peer_data = ptr;
return nm_hash_str(nm_wireguard_peer_get_public_key(peer_data->peer));
}
static PeerData *
_peers_find(NMDeviceWireGuardPrivate *priv, NMWireGuardPeer *peer)
{
nm_assert(peer);
G_STATIC_ASSERT_EXPR(G_STRUCT_OFFSET(PeerData, peer) == 0);
return g_hash_table_lookup(priv->peers, &peer);
}
static guint
_peers_resolving_cnt(NMDeviceWireGuardPrivate *priv)
{
nm_assert(priv);
#if NM_MORE_ASSERTS > 3
{
PeerData *peer_data;
guint cnt = 0;
c_list_for_each_entry (peer_data, &priv->lst_peers_head, lst_peers) {
if (peer_data->ep_resolv.cancellable)
cnt++;
}
nm_assert(cnt == priv->peers_resolving_cnt);
}
#endif
return priv->peers_resolving_cnt;
}
static void
_peers_resolving_cnt_decrement(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
nm_assert(priv);
nm_assert(priv->peers_resolving_cnt > 0);
priv->peers_resolving_cnt--;
nm_assert(_peers_resolving_cnt(priv) == priv->peers_resolving_cnt);
if (priv->peers_resolving_cnt == 0) {
if (nm_device_get_state(NM_DEVICE(self)) == NM_DEVICE_STATE_CONFIG) {
_LOGT(LOGD_DEVICE,
"activation delayed to resolve DNS names of peers: completed, proceed now");
nm_device_activate_schedule_stage2_device_config(NM_DEVICE(self), FALSE);
}
}
}
static void
_peers_remove(NMDeviceWireGuard *self, PeerData *peer_data)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
nm_assert(peer_data);
nm_assert(g_hash_table_lookup(priv->peers, peer_data) == peer_data);
if (!g_hash_table_remove(priv->peers, peer_data))
nm_assert_not_reached();
c_list_unlink_stale(&peer_data->lst_peers);
nm_wireguard_peer_unref(peer_data->peer);
if (nm_clear_g_cancellable(&peer_data->ep_resolv.cancellable))
_peers_resolving_cnt_decrement(self);
g_slice_free(PeerData, peer_data);
if (c_list_is_empty(&priv->lst_peers_head)) {
nm_clear_g_source(&priv->resolve_next_try_id);
nm_clear_g_source(&priv->link_config_delayed_id);
}
nm_assert(_peers_resolving_cnt(priv) == priv->peers_resolving_cnt);
}
static PeerData *
_peers_add(NMDeviceWireGuard *self, NMWireGuardPeer *peer)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
PeerData *peer_data;
nm_assert(peer);
nm_assert(nm_wireguard_peer_is_sealed(peer));
nm_assert(!_peers_find(priv, peer));
peer_data = g_slice_new(PeerData);
*peer_data = (PeerData){
.self = self,
.peer = nm_wireguard_peer_ref(peer),
.ep_resolv =
{
.sockaddr = NM_SOCK_ADDR_UNION_INIT_UNSPEC,
},
};
c_list_link_tail(&priv->lst_peers_head, &peer_data->lst_peers);
if (!nm_g_hash_table_add(priv->peers, peer_data))
nm_assert_not_reached();
return peer_data;
}
static gboolean
_peers_resolve_retry_timeout(gpointer user_data)
{
NMDeviceWireGuard *self = user_data;
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
PeerData *peer_data;
gint64 now;
gint64 next;
priv->resolve_next_try_id = 0;
_LOGT(LOGD_DEVICE, "wireguard-peers: rechecking peer endpoints...");
now = nm_utils_get_monotonic_timestamp_nsec();
next = G_MAXINT64;
c_list_for_each_entry (peer_data, &priv->lst_peers_head, lst_peers) {
if (peer_data->ep_resolv.next_try_at_nsec <= 0)
continue;
if (peer_data->ep_resolv.cancellable) {
/* we are currently resolving a name. We don't need the global
* watchdog to guard this peer. No need to adjust @next for
* this one, when the currently ongoing resolving completes, we
* may reschedule. Skip. */
continue;
}
if (peer_data->ep_resolv.next_try_at_nsec == NEXT_TRY_AT_NSEC_ASAP
|| now >= peer_data->ep_resolv.next_try_at_nsec) {
_peers_resolve_start(self, peer_data);
/* same here. Now we are resolving. We don't need the global
* watchdog. Skip w.r.t. finding @next. */
continue;
}
if (next > peer_data->ep_resolv.next_try_at_nsec)
next = peer_data->ep_resolv.next_try_at_nsec;
}
if (next < G_MAXINT64)
_peers_resolve_retry_reschedule(self, next);
return G_SOURCE_REMOVE;
}
static void
_peers_resolve_retry_reschedule(NMDeviceWireGuard *self, gint64 new_next_try_at_nsec)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
guint32 interval_ms;
gint64 now;
nm_assert(new_next_try_at_nsec > 0);
nm_assert(new_next_try_at_nsec != NEXT_TRY_AT_NSEC_ASAP);
if (priv->resolve_next_try_id && priv->resolve_next_try_at <= new_next_try_at_nsec) {
/* we already have an earlier timeout scheduled (possibly for
* another peer that expires sooner). Don't reschedule now.
* Even if the scheduled timeout expires too early, we will
* compute the right next-timeout and reschedule then. */
return;
}
now = nm_utils_get_monotonic_timestamp_nsec();
/* schedule at most one day ahead. No problem if we expire earlier
* than expected. Also, rate-limit to 500 msec. */
interval_ms = NM_CLAMP((new_next_try_at_nsec - now) / NM_UTILS_NSEC_PER_MSEC,
(gint64) 500,
(gint64) (24 * 60 * 60 * 1000));
_LOGT(LOGD_DEVICE,
"wireguard-peers: schedule rechecking peer endpoints in %u msec",
interval_ms);
nm_clear_g_source(&priv->resolve_next_try_id);
priv->resolve_next_try_at = new_next_try_at_nsec;
priv->resolve_next_try_id = g_timeout_add(interval_ms, _peers_resolve_retry_timeout, self);
}
static void
_peers_resolve_retry_reschedule_for_peer(NMDeviceWireGuard *self,
PeerData *peer_data,
gint64 retry_in_msec)
{
nm_assert(retry_in_msec >= 0);
if (retry_in_msec == RETRY_IN_MSEC_ASAP) {
_peers_resolve_start(self, peer_data);
return;
}
peer_data->ep_resolv.next_try_at_nsec =
nm_utils_get_monotonic_timestamp_nsec() + (retry_in_msec * NM_UTILS_NSEC_PER_MSEC);
_peers_resolve_retry_reschedule(self, peer_data->ep_resolv.next_try_at_nsec);
}
static gint64
_peers_retry_in_msec(PeerData *peer_data, gboolean after_failure)
{
if (peer_data->ep_resolv.next_try_at_nsec == NEXT_TRY_AT_NSEC_ASAP) {
peer_data->ep_resolv.resolv_fail_count = 0;
return RETRY_IN_MSEC_ASAP;
}
if (after_failure) {
if (peer_data->ep_resolv.resolv_fail_count < G_MAXUINT)
peer_data->ep_resolv.resolv_fail_count++;
} else
peer_data->ep_resolv.resolv_fail_count = 0;
if (!after_failure)
return RETRY_IN_MSEC_MAX;
if (peer_data->ep_resolv.resolv_fail_count > 20)
return RETRY_IN_MSEC_MAX;
/* double the retry-time, starting with one second. */
return NM_MIN(RETRY_IN_MSEC_MAX, (1u << peer_data->ep_resolv.resolv_fail_count) * 500);
}
static void
_peers_resolve_cb(GObject *source_object, GAsyncResult *res, gpointer user_data)
{
NMDeviceWireGuard *self;
NMDeviceWireGuardPrivate *priv;
PeerData *peer_data;
gs_free_error GError *resolv_error = NULL;
GList *list;
gboolean changed;
NMSockAddrUnion sockaddr;
gint64 retry_in_msec;
char s_sockaddr[100];
char s_retry[100];
list = g_resolver_lookup_by_name_finish(G_RESOLVER(source_object), res, &resolv_error);
if (nm_utils_error_is_cancelled(resolv_error))
return;
peer_data = user_data;
self = peer_data->self;
priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
if (nm_clear_g_object(&peer_data->ep_resolv.cancellable))
_peers_resolving_cnt_decrement(self);
nm_assert((!resolv_error) != (!list));
nm_assert(_peers_resolving_cnt(priv) == priv->peers_resolving_cnt);
#define _retry_in_msec_to_string(retry_in_msec, s_retry) \
({ \
gint64 _retry_in_msec = (retry_in_msec); \
\
_retry_in_msec == RETRY_IN_MSEC_ASAP \
? "right away" \
: nm_sprintf_buf(s_retry, "in %" G_GINT64_FORMAT " msec", _retry_in_msec); \
})
if (resolv_error
&& !g_error_matches(resolv_error, G_RESOLVER_ERROR, G_RESOLVER_ERROR_NOT_FOUND)) {
retry_in_msec = _peers_retry_in_msec(peer_data, TRUE);
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: failure to resolve endpoint \"%s\": %s (retry %s)",
nm_wireguard_peer_get_public_key(peer_data->peer),
nm_wireguard_peer_get_endpoint(peer_data->peer),
resolv_error->message,
_retry_in_msec_to_string(retry_in_msec, s_retry));
_peers_resolve_retry_reschedule_for_peer(self, peer_data, retry_in_msec);
return;
}
sockaddr = (NMSockAddrUnion) NM_SOCK_ADDR_UNION_INIT_UNSPEC;
changed = FALSE;
if (!resolv_error) {
GList *iter;
for (iter = list; iter; iter = iter->next) {
GInetAddress *a = iter->data;
NMSockAddrUnion sockaddr_tmp;
NMSockAddrUnion *s;
s = sockaddr.sa.sa_family == AF_UNSPEC ? &sockaddr : &sockaddr_tmp;
switch (g_inet_address_get_family(a)) {
case G_SOCKET_FAMILY_IPV4:
nm_assert(g_inet_address_get_native_size(a) == sizeof(struct in_addr));
s->in = (struct sockaddr_in){
.sin_family = AF_INET,
.sin_port = htons(nm_sock_addr_endpoint_get_port(
_nm_wireguard_peer_get_endpoint(peer_data->peer))),
};
memcpy(&s->in.sin_addr, g_inet_address_to_bytes(a), sizeof(struct in_addr));
break;
case G_SOCKET_FAMILY_IPV6:
nm_assert(g_inet_address_get_native_size(a) == sizeof(struct in6_addr));
s->in6 = (struct sockaddr_in6){
.sin6_family = AF_INET6,
.sin6_port = htons(nm_sock_addr_endpoint_get_port(
_nm_wireguard_peer_get_endpoint(peer_data->peer))),
.sin6_scope_id = 0,
.sin6_flowinfo = 0,
};
memcpy(&s->in6.sin6_addr, g_inet_address_to_bytes(a), sizeof(struct in6_addr));
break;
default:
continue;
}
changed = TRUE;
if (peer_data->ep_resolv.sockaddr.sa.sa_family == AF_UNSPEC)
break;
if (nm_sock_addr_union_cmp(&peer_data->ep_resolv.sockaddr, &sockaddr) == 0) {
changed = FALSE;
break;
}
}
g_list_free_full(list, g_object_unref);
}
if (sockaddr.sa.sa_family == AF_UNSPEC) {
/* we failed to resolve the name. There is no need to reset the previous
* sockaddr. Either it was already AF_UNSPEC, or we had a good name
* from resolving before. In that case, we don't want to throw away
* a possibly good IP address, since WireGuard supports automatic roaming
* anyway. Either the IP address is still good (and we would wrongly
* reject it), or it isn't -- in which case it does not hurt much. */
} else if (changed)
peer_data->ep_resolv.sockaddr = sockaddr;
if (resolv_error || peer_data->ep_resolv.sockaddr.sa.sa_family == AF_UNSPEC) {
/* while it technically did not fail, something is probably odd. Retry frequently to
* resolve the name, like we would do for normal failures. */
retry_in_msec = _peers_retry_in_msec(peer_data, TRUE);
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: no %sresults for endpoint \"%s\" (retry %s)",
nm_wireguard_peer_get_public_key(peer_data->peer),
resolv_error ? "" : "suitable ",
nm_wireguard_peer_get_endpoint(peer_data->peer),
_retry_in_msec_to_string(retry_in_msec, s_retry));
} else {
retry_in_msec = _peers_retry_in_msec(peer_data, FALSE);
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: endpoint \"%s\" resolved to %s (retry %s)",
nm_wireguard_peer_get_public_key(peer_data->peer),
nm_wireguard_peer_get_endpoint(peer_data->peer),
nm_sock_addr_union_to_string(&peer_data->ep_resolv.sockaddr,
s_sockaddr,
sizeof(s_sockaddr)),
_retry_in_msec_to_string(retry_in_msec, s_retry));
}
_peers_resolve_retry_reschedule_for_peer(self, peer_data, retry_in_msec);
if (changed) {
/* schedule the job in the background, to give multiple resolve events time
* to complete. */
nm_clear_g_source(&priv->link_config_delayed_id);
priv->link_config_delayed_id = g_idle_add_full(G_PRIORITY_DEFAULT_IDLE + 1,
link_config_delayed_resolver_cb,
self,
NULL);
}
}
static void
_peers_resolve_start(NMDeviceWireGuard *self, PeerData *peer_data)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
gs_unref_object GResolver *resolver = NULL;
const char *host;
resolver = g_resolver_get_default();
nm_assert(!peer_data->ep_resolv.cancellable);
peer_data->ep_resolv.cancellable = g_cancellable_new();
priv->peers_resolving_cnt++;
/* set a special next-try timestamp. It is positive, and indicates
* that we are in the process of trying.
* This timestamp however already lies in the past, but that is correct,
* because we are currently in the process of trying. We will determine
* a next-try timestamp once the try completes. */
peer_data->ep_resolv.next_try_at_nsec = NEXT_TRY_AT_NSEC_PAST;
host = nm_sock_addr_endpoint_get_host(_nm_wireguard_peer_get_endpoint(peer_data->peer));
g_resolver_lookup_by_name_async(resolver,
host,
peer_data->ep_resolv.cancellable,
_peers_resolve_cb,
peer_data);
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: resolving name \"%s\" for endpoint \"%s\"...",
nm_wireguard_peer_get_public_key(peer_data->peer),
host,
nm_wireguard_peer_get_endpoint(peer_data->peer));
nm_assert(_peers_resolving_cnt(priv) == priv->peers_resolving_cnt);
}
static void
_peers_resolve_reresolve_all(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
PeerData *peer_data;
c_list_for_each_entry (peer_data, &priv->lst_peers_head, lst_peers) {
if (peer_data->ep_resolv.cancellable) {
/* remember to retry when the currently ongoing request completes. */
peer_data->ep_resolv.next_try_at_nsec = NEXT_TRY_AT_NSEC_ASAP;
} else if (peer_data->ep_resolv.next_try_at_nsec <= 0) {
/* this peer does not require resolving the name. Skip it. */
} else {
/* we have a next-try scheduled. Restart right away. */
peer_data->ep_resolv.resolv_fail_count = 0;
_peers_resolve_start(self, peer_data);
}
}
}
static gboolean
_peers_update(NMDeviceWireGuard *self,
PeerData *peer_data,
NMWireGuardPeer *peer,
gboolean force_update)
{
nm_auto_unref_wgpeer NMWireGuardPeer *old_peer = NULL;
NMSockAddrEndpoint *old_endpoint;
NMSockAddrEndpoint *endpoint;
gboolean endpoint_changed = FALSE;
gboolean changed;
NMSockAddrUnion sockaddr;
gboolean sockaddr_fixed;
char sockaddr_sbuf[100];
nm_assert(peer);
nm_assert(nm_wireguard_peer_is_sealed(peer));
if (peer == peer_data->peer && !force_update)
return FALSE;
changed = (nm_wireguard_peer_cmp(peer, peer_data->peer, NM_SETTING_COMPARE_FLAG_EXACT) != 0);
old_peer = peer_data->peer;
peer_data->peer = nm_wireguard_peer_ref(peer);
old_endpoint = old_peer ? _nm_wireguard_peer_get_endpoint(old_peer) : NULL;
endpoint = peer ? _nm_wireguard_peer_get_endpoint(peer) : NULL;
endpoint_changed = (endpoint != old_endpoint
&& (!old_endpoint || !endpoint
|| !nm_streq(nm_sock_addr_endpoint_get_endpoint(old_endpoint),
nm_sock_addr_endpoint_get_endpoint(endpoint))));
if (!force_update && !endpoint_changed) {
/* nothing to do. */
return changed;
}
sockaddr = (NMSockAddrUnion) NM_SOCK_ADDR_UNION_INIT_UNSPEC;
sockaddr_fixed = TRUE;
if (endpoint && nm_sock_addr_endpoint_get_host(endpoint)) {
if (!nm_sock_addr_endpoint_get_fixed_sockaddr(endpoint, &sockaddr)) {
/* we have an endpoint, but it's not a static IP address. We need to resolve
* the names. */
sockaddr_fixed = FALSE;
}
}
if (nm_sock_addr_union_cmp(&peer_data->ep_resolv.sockaddr, &sockaddr) != 0)
changed = TRUE;
if (nm_clear_g_cancellable(&peer_data->ep_resolv.cancellable))
_peers_resolving_cnt_decrement(self);
peer_data->ep_resolv = (PeerEndpointResolveData){
.sockaddr = sockaddr,
.resolv_fail_count = 0,
.cancellable = NULL,
.next_try_at_nsec = 0,
};
if (!endpoint) {
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: no endpoint configured",
nm_wireguard_peer_get_public_key(peer_data->peer));
} else if (!nm_sock_addr_endpoint_get_host(endpoint)) {
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: invalid endpoint \"%s\"",
nm_wireguard_peer_get_public_key(peer_data->peer),
nm_sock_addr_endpoint_get_endpoint(endpoint));
} else if (sockaddr_fixed) {
_LOGT(LOGD_DEVICE,
"wireguard-peer[%s]: fixed endpoint \"%s\" (%s)",
nm_wireguard_peer_get_public_key(peer_data->peer),
nm_sock_addr_endpoint_get_endpoint(endpoint),
nm_sock_addr_union_to_string(&peer_data->ep_resolv.sockaddr,
sockaddr_sbuf,
sizeof(sockaddr_sbuf)));
} else
_peers_resolve_start(self, peer_data);
return changed;
}
static void
_peers_remove_all(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
PeerData *peer_data;
while ((peer_data = c_list_first_entry(&priv->lst_peers_head, PeerData, lst_peers)))
_peers_remove(self, peer_data);
}
static void
_peers_update_all(NMDeviceWireGuard *self, NMSettingWireGuard *s_wg, gboolean *out_peers_removed)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
PeerData *peer_data_safe;
PeerData *peer_data;
guint i, n;
gboolean peers_removed = FALSE;
c_list_for_each_entry (peer_data, &priv->lst_peers_head, lst_peers)
peer_data->dirty_update_all = TRUE;
n = nm_setting_wireguard_get_peers_len(s_wg);
for (i = 0; i < n; i++) {
NMWireGuardPeer *peer = nm_setting_wireguard_get_peer(s_wg, i);
gboolean added = FALSE;
peer_data = _peers_find(priv, peer);
if (!peer_data) {
peer_data = _peers_add(self, peer);
added = TRUE;
}
_peers_update(self, peer_data, peer, added);
peer_data->dirty_update_all = FALSE;
}
c_list_for_each_entry_safe (peer_data, peer_data_safe, &priv->lst_peers_head, lst_peers) {
if (peer_data->dirty_update_all) {
_peers_remove(self, peer_data);
peers_removed = TRUE;
}
}
NM_SET_OUT(out_peers_removed, peers_removed);
}
static void
_peers_get_platform_list(NMDeviceWireGuardPrivate *priv,
LinkConfigMode config_mode,
NMPWireGuardPeer **out_peers,
NMPlatformWireGuardChangePeerFlags **out_peer_flags,
guint *out_len,
GArray **out_allowed_ips_data)
{
gs_free NMPWireGuardPeer *plpeers = NULL;
gs_free NMPlatformWireGuardChangePeerFlags *plpeer_flags = NULL;
gs_unref_array GArray *allowed_ips = NULL;
PeerData *peer_data;
guint i_good;
guint n_aip;
guint i_aip;
guint len;
guint i;
nm_assert(out_peers && !*out_peers);
nm_assert(out_peer_flags && !*out_peer_flags);
nm_assert(out_len && *out_len == 0);
nm_assert(out_allowed_ips_data && !*out_allowed_ips_data);
len = g_hash_table_size(priv->peers);
nm_assert(len == c_list_length(&priv->lst_peers_head));
if (len == 0)
return;
plpeers = g_new0(NMPWireGuardPeer, len);
plpeer_flags = g_new0(NMPlatformWireGuardChangePeerFlags, len);
i_good = 0;
c_list_for_each_entry (peer_data, &priv->lst_peers_head, lst_peers) {
NMPlatformWireGuardChangePeerFlags *plf = &plpeer_flags[i_good];
NMPWireGuardPeer *plp = &plpeers[i_good];
NMSettingSecretFlags psk_secret_flags;
if (!nm_utils_base64secret_decode(nm_wireguard_peer_get_public_key(peer_data->peer),
sizeof(plp->public_key),
plp->public_key))
continue;
*plf = NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_NONE;
plp->persistent_keepalive_interval =
nm_wireguard_peer_get_persistent_keepalive(peer_data->peer);
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL, LINK_CONFIG_MODE_REAPPLY))
*plf |= NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_HAS_KEEPALIVE_INTERVAL;
/* if the peer has an endpoint but it is not yet resolved (not ready),
* we still configure it and leave the endpoint unspecified. Later,
* when we can resolve the endpoint, we will update. */
plp->endpoint = peer_data->ep_resolv.sockaddr;
if (plp->endpoint.sa.sa_family == AF_UNSPEC) {
/* we don't actually ever clear endpoints, if we don't have better information. */
} else
*plf |= NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_HAS_ENDPOINT;
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL, LINK_CONFIG_MODE_REAPPLY)) {
psk_secret_flags = nm_wireguard_peer_get_preshared_key_flags(peer_data->peer);
if (!NM_FLAGS_HAS(psk_secret_flags, NM_SETTING_SECRET_FLAG_NOT_REQUIRED)) {
if (!nm_utils_base64secret_decode(
nm_wireguard_peer_get_preshared_key(peer_data->peer),
sizeof(plp->preshared_key),
plp->preshared_key)
&& config_mode == LINK_CONFIG_MODE_FULL)
goto skip;
}
*plf |= NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_HAS_PRESHARED_KEY;
}
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL, LINK_CONFIG_MODE_REAPPLY)
&& ((n_aip = nm_wireguard_peer_get_allowed_ips_len(peer_data->peer)) > 0)) {
if (!allowed_ips)
allowed_ips = g_array_new(FALSE, FALSE, sizeof(NMPWireGuardAllowedIP));
*plf |= NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_HAS_ALLOWEDIPS
| NM_PLATFORM_WIREGUARD_CHANGE_PEER_FLAG_REPLACE_ALLOWEDIPS;
plp->_construct_idx_start = allowed_ips->len;
for (i_aip = 0; i_aip < n_aip; i_aip++) {
const char *aip;
NMIPAddr addrbin = {};
int addr_family;
gboolean valid;
int prefix;
aip = nm_wireguard_peer_get_allowed_ip(peer_data->peer, i_aip, &valid);
if (!valid
|| !nm_utils_parse_inaddr_prefix_bin(AF_UNSPEC,
aip,
&addr_family,
&addrbin,
&prefix)) {
/* the address is really not expected to be invalid, because then
* the connection would not verify. Anyway, silently skip it. */
continue;
}
if (prefix == -1)
prefix = addr_family == AF_INET ? 32 : 128;
g_array_append_val(allowed_ips,
((NMPWireGuardAllowedIP){
.family = addr_family,
.mask = prefix,
.addr = addrbin,
}));
}
plp->_construct_idx_end = allowed_ips->len;
}
i_good++;
continue;
skip:
memset(plp, 0, sizeof(*plp));
}
if (i_good == 0)
return;
for (i = 0; i < i_good; i++) {
NMPWireGuardPeer *plp = &plpeers[i];
guint l;
if (plp->_construct_idx_end == 0) {
nm_assert(plp->_construct_idx_start == 0);
plp->allowed_ips = NULL;
plp->allowed_ips_len = 0;
} else {
nm_assert(plp->_construct_idx_start < plp->_construct_idx_end);
l = plp->_construct_idx_end - plp->_construct_idx_start;
plp->allowed_ips =
&g_array_index(allowed_ips, NMPWireGuardAllowedIP, plp->_construct_idx_start);
plp->allowed_ips_len = l;
}
}
*out_peers = g_steal_pointer(&plpeers);
*out_peer_flags = g_steal_pointer(&plpeer_flags);
*out_len = i_good;
*out_allowed_ips_data = g_steal_pointer(&allowed_ips);
}
/*****************************************************************************/
static void
update_properties(NMDevice *device)
{
NMDeviceWireGuard *self;
NMDeviceWireGuardPrivate *priv;
const NMPlatformLink *plink;
const NMPlatformLnkWireGuard *props = NULL;
int ifindex;
g_return_if_fail(NM_IS_DEVICE_WIREGUARD(device));
self = NM_DEVICE_WIREGUARD(device);
priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
ifindex = nm_device_get_ifindex(device);
props = nm_platform_link_get_lnk_wireguard(nm_device_get_platform(device), ifindex, &plink);
if (!props) {
_LOGW(LOGD_PLATFORM, "could not get wireguard properties");
return;
}
g_object_freeze_notify(G_OBJECT(device));
#define CHECK_PROPERTY_CHANGED(field, prop) \
G_STMT_START \
{ \
if (priv->lnk_curr.field != props->field) { \
priv->lnk_curr.field = props->field; \
_notify(self, prop); \
} \
} \
G_STMT_END
#define CHECK_PROPERTY_CHANGED_ARRAY(field, prop) \
G_STMT_START \
{ \
if (memcmp(&priv->lnk_curr.field, &props->field, sizeof(priv->lnk_curr.field)) != 0) { \
memcpy(&priv->lnk_curr.field, &props->field, sizeof(priv->lnk_curr.field)); \
_notify(self, prop); \
} \
} \
G_STMT_END
CHECK_PROPERTY_CHANGED_ARRAY(public_key, PROP_PUBLIC_KEY);
CHECK_PROPERTY_CHANGED(listen_port, PROP_LISTEN_PORT);
CHECK_PROPERTY_CHANGED(fwmark, PROP_FWMARK);
g_object_thaw_notify(G_OBJECT(device));
}
static void
link_changed(NMDevice *device, const NMPlatformLink *pllink)
{
NM_DEVICE_CLASS(nm_device_wireguard_parent_class)->link_changed(device, pllink);
update_properties(device);
}
static NMDeviceCapabilities
get_generic_capabilities(NMDevice *dev)
{
return NM_DEVICE_CAP_IS_SOFTWARE;
}
/*****************************************************************************/
static gboolean
create_and_realize(NMDevice *device,
NMConnection *connection,
NMDevice *parent,
const NMPlatformLink **out_plink,
GError **error)
{
const char *iface = nm_device_get_iface(device);
int r;
g_return_val_if_fail(iface, FALSE);
r = nm_platform_link_wireguard_add(nm_device_get_platform(device), iface, out_plink);
if (r < 0) {
g_set_error(error,
NM_DEVICE_ERROR,
NM_DEVICE_ERROR_CREATION_FAILED,
"Failed to create WireGuard interface '%s' for '%s': %s",
iface,
nm_connection_get_id(connection),
nm_strerror(r));
return FALSE;
}
return TRUE;
}
/*****************************************************************************/
static void
_secrets_cancel(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
if (priv->secrets_call_id)
nm_act_request_cancel_secrets(NULL, priv->secrets_call_id);
nm_assert(!priv->secrets_call_id);
}
static void
_secrets_cb(NMActRequest *req,
NMActRequestGetSecretsCallId *call_id,
NMSettingsConnection *connection,
GError *error,
gpointer user_data)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(user_data);
NMDevice *device = NM_DEVICE(self);
NMDeviceWireGuardPrivate *priv;
g_return_if_fail(NM_IS_DEVICE_WIREGUARD(self));
g_return_if_fail(NM_IS_ACT_REQUEST(req));
priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
g_return_if_fail(priv->secrets_call_id == call_id);
priv->secrets_call_id = NULL;
if (g_error_matches(error, G_IO_ERROR, G_IO_ERROR_CANCELLED))
return;
g_return_if_fail(req == nm_device_get_act_request(device));
g_return_if_fail(nm_device_get_state(device) == NM_DEVICE_STATE_NEED_AUTH);
g_return_if_fail(nm_act_request_get_settings_connection(req) == connection);
if (error) {
_LOGW(LOGD_ETHER, "%s", error->message);
nm_device_state_changed(device, NM_DEVICE_STATE_FAILED, NM_DEVICE_STATE_REASON_NO_SECRETS);
return;
}
nm_device_activate_schedule_stage1_device_prepare(device, FALSE);
}
static void
_secrets_get_secrets(NMDeviceWireGuard *self,
const char *setting_name,
NMSecretAgentGetSecretsFlags flags,
const char *const *hints)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
NMActRequest *req;
_secrets_cancel(self);
req = nm_device_get_act_request(NM_DEVICE(self));
g_return_if_fail(NM_IS_ACT_REQUEST(req));
priv->secrets_call_id =
nm_act_request_get_secrets(req, TRUE, setting_name, flags, hints, _secrets_cb, self);
g_return_if_fail(priv->secrets_call_id);
}
static NMActStageReturn
_secrets_handle_auth_or_fail(NMDeviceWireGuard *self, NMActRequest *req, gboolean new_secrets)
{
NMConnection *applied_connection;
const char *setting_name;
gs_unref_ptrarray GPtrArray *hints = NULL;
if (!nm_device_auth_retries_try_next(NM_DEVICE(self)))
return NM_ACT_STAGE_RETURN_FAILURE;
nm_device_state_changed(NM_DEVICE(self),
NM_DEVICE_STATE_NEED_AUTH,
NM_DEVICE_STATE_REASON_NONE);
nm_active_connection_clear_secrets(NM_ACTIVE_CONNECTION(req));
applied_connection = nm_act_request_get_applied_connection(req);
setting_name = nm_connection_need_secrets(applied_connection, &hints);
if (!setting_name) {
_LOGI(LOGD_DEVICE, "Cleared secrets, but setting didn't need any secrets.");
return NM_ACT_STAGE_RETURN_FAILURE;
}
if (hints)
g_ptr_array_add(hints, NULL);
_secrets_get_secrets(self,
setting_name,
NM_SECRET_AGENT_GET_SECRETS_FLAG_ALLOW_INTERACTION
| (new_secrets ? NM_SECRET_AGENT_GET_SECRETS_FLAG_REQUEST_NEW : 0),
(hints ? (const char *const *) hints->pdata : NULL));
return NM_ACT_STAGE_RETURN_POSTPONE;
}
/*****************************************************************************/
static void
_dns_config_changed(NMDnsManager *dns_manager, NMDeviceWireGuard *self)
{
/* when the DNS configuration changes, we re-resolve the peer addresses.
*
* Possibly, we should also do that when the default-route changes, but it's
* hard to figure out when that happens. */
_peers_resolve_reresolve_all(self);
}
/*****************************************************************************/
static NMActStageReturn
link_config(NMDeviceWireGuard *self,
const char *reason,
LinkConfigMode config_mode,
NMDeviceStateReason *out_failure_reason)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
nm_auto_bzero_secret_ptr NMSecretPtr wg_lnk_clear_private_key = NM_SECRET_PTR_INIT();
NMSettingWireGuard *s_wg;
NMConnection *connection;
NMActStageReturn ret;
gs_unref_array GArray *allowed_ips_data = NULL;
NMPlatformLnkWireGuard wg_lnk;
gs_free NMPWireGuardPeer *plpeers = NULL;
gs_free NMPlatformWireGuardChangePeerFlags *plpeer_flags = NULL;
guint plpeers_len = 0;
const char *setting_name;
gboolean peers_removed;
NMPlatformWireGuardChangeFlags wg_change_flags;
int ifindex;
int r;
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_NONE);
connection = nm_device_get_applied_connection(NM_DEVICE(self));
s_wg = NM_SETTING_WIREGUARD(nm_connection_get_setting(connection, NM_TYPE_SETTING_WIREGUARD));
g_return_val_if_fail(s_wg, NM_ACT_STAGE_RETURN_FAILURE);
priv->link_config_last_at = nm_utils_get_monotonic_timestamp_nsec();
_LOGT(LOGD_DEVICE,
"wireguard link config (%s, %s)...",
reason,
_link_config_mode_to_string(config_mode));
_auto_default_route_init(self);
if (!priv->dns_manager) {
priv->dns_manager = g_object_ref(nm_dns_manager_get());
g_signal_connect(priv->dns_manager,
NM_DNS_MANAGER_CONFIG_CHANGED,
G_CALLBACK(_dns_config_changed),
self);
}
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL)
&& (setting_name = nm_connection_need_secrets(connection, NULL))) {
NMActRequest *req = nm_device_get_act_request(NM_DEVICE(self));
_LOGD(LOGD_DEVICE,
"Activation: connection '%s' has security, but secrets are required.",
nm_connection_get_id(connection));
ret = _secrets_handle_auth_or_fail(self, req, FALSE);
if (ret != NM_ACT_STAGE_RETURN_SUCCESS) {
if (ret != NM_ACT_STAGE_RETURN_POSTPONE) {
nm_assert(ret == NM_ACT_STAGE_RETURN_FAILURE);
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_NO_SECRETS);
}
return ret;
}
}
ifindex = nm_device_get_ip_ifindex(NM_DEVICE(self));
if (ifindex <= 0) {
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_CONFIG_FAILED);
return NM_ACT_STAGE_RETURN_FAILURE;
}
_peers_update_all(self, s_wg, &peers_removed);
wg_lnk = (NMPlatformLnkWireGuard){};
wg_change_flags = NM_PLATFORM_WIREGUARD_CHANGE_FLAG_NONE;
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL)
|| (NM_IN_SET(config_mode, LINK_CONFIG_MODE_REAPPLY) && peers_removed))
wg_change_flags |= NM_PLATFORM_WIREGUARD_CHANGE_FLAG_REPLACE_PEERS;
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL, LINK_CONFIG_MODE_REAPPLY)) {
wg_lnk.listen_port = nm_setting_wireguard_get_listen_port(s_wg);
wg_change_flags |= NM_PLATFORM_WIREGUARD_CHANGE_FLAG_HAS_LISTEN_PORT;
wg_lnk.fwmark = priv->auto_default_route_fwmark;
wg_change_flags |= NM_PLATFORM_WIREGUARD_CHANGE_FLAG_HAS_FWMARK;
if (nm_utils_base64secret_decode(nm_setting_wireguard_get_private_key(s_wg),
sizeof(wg_lnk.private_key),
wg_lnk.private_key)) {
wg_lnk_clear_private_key = NM_SECRET_PTR_ARRAY(wg_lnk.private_key);
wg_change_flags |= NM_PLATFORM_WIREGUARD_CHANGE_FLAG_HAS_PRIVATE_KEY;
} else {
if (NM_IN_SET(config_mode, LINK_CONFIG_MODE_FULL)) {
_LOGD(LOGD_DEVICE, "the provided private-key is invalid");
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_NO_SECRETS);
return NM_ACT_STAGE_RETURN_FAILURE;
}
}
}
_peers_get_platform_list(priv,
config_mode,
&plpeers,
&plpeer_flags,
&plpeers_len,
&allowed_ips_data);
r = nm_platform_link_wireguard_change(nm_device_get_platform(NM_DEVICE(self)),
ifindex,
&wg_lnk,
plpeers,
plpeer_flags,
plpeers_len,
wg_change_flags);
nm_explicit_bzero(plpeers, sizeof(plpeers[0]) * plpeers_len);
if (r < 0) {
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_CONFIG_FAILED);
return NM_ACT_STAGE_RETURN_FAILURE;
}
return NM_ACT_STAGE_RETURN_SUCCESS;
}
static void
link_config_delayed(NMDeviceWireGuard *self, const char *reason)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
gint64 now;
priv->link_config_delayed_id = 0;
if (priv->link_config_last_at != 0) {
now = nm_utils_get_monotonic_timestamp_nsec();
if (now < priv->link_config_last_at + LINK_CONFIG_RATE_LIMIT_NSEC) {
/* we ratelimit calls to link_config(), because we call this whenever a resolver
* completes. */
_LOGT(LOGD_DEVICE, "wireguard link config (%s) (postponed)", reason);
priv->link_config_delayed_id =
g_timeout_add(NM_MAX((priv->link_config_last_at + LINK_CONFIG_RATE_LIMIT_NSEC - now)
/ NM_UTILS_NSEC_PER_MSEC,
(gint64) 1),
link_config_delayed_ratelimit_cb,
self);
return;
}
}
link_config(self, reason, LINK_CONFIG_MODE_ENDPOINTS, NULL);
}
static gboolean
link_config_delayed_ratelimit_cb(gpointer user_data)
{
link_config_delayed(user_data, "after-ratelimiting");
return G_SOURCE_REMOVE;
}
static gboolean
link_config_delayed_resolver_cb(gpointer user_data)
{
link_config_delayed(user_data, "resolver-update");
return G_SOURCE_REMOVE;
}
static NMActStageReturn
act_stage2_config(NMDevice *device, NMDeviceStateReason *out_failure_reason)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(device);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
NMDeviceSysIfaceState sys_iface_state;
NMDeviceStateReason failure_reason;
NMActStageReturn ret;
sys_iface_state = nm_device_sys_iface_state_get(device);
if (sys_iface_state == NM_DEVICE_SYS_IFACE_STATE_EXTERNAL) {
NM_SET_OUT(out_failure_reason, NM_DEVICE_STATE_REASON_NONE);
return NM_ACT_STAGE_RETURN_SUCCESS;
}
ret =
link_config(NM_DEVICE_WIREGUARD(device),
"configure",
(sys_iface_state == NM_DEVICE_SYS_IFACE_STATE_ASSUME) ? LINK_CONFIG_MODE_ASSUME
: LINK_CONFIG_MODE_FULL,
&failure_reason);
if (ret == NM_ACT_STAGE_RETURN_FAILURE) {
if (sys_iface_state == NM_DEVICE_SYS_IFACE_STATE_ASSUME) {
/* this never fails. */
return NM_ACT_STAGE_RETURN_SUCCESS;
}
nm_device_state_changed(device, NM_DEVICE_STATE_FAILED, failure_reason);
NM_SET_OUT(out_failure_reason, failure_reason);
return NM_ACT_STAGE_RETURN_FAILURE;
}
nm_assert(NM_IN_SET(ret, NM_ACT_STAGE_RETURN_SUCCESS, NM_ACT_STAGE_RETURN_POSTPONE));
if (ret == NM_ACT_STAGE_RETURN_SUCCESS && _peers_resolving_cnt(priv) > 0u) {
_LOGT(LOGD_DEVICE,
"activation delayed to resolve DNS names of peers: resolving and waiting...");
return NM_ACT_STAGE_RETURN_POSTPONE;
}
return ret;
}
static const NML3ConfigData *
_get_dev2_ip_config(NMDeviceWireGuard *self, int addr_family)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
nm_auto_unref_l3cd_init NML3ConfigData *l3cd = NULL;
NMConnection *connection;
NMSettingWireGuard *s_wg;
guint n_peers;
guint i;
int ip_ifindex;
guint32 route_metric;
guint32 route_table_coerced;
gboolean auto_default_route_enabled;
_auto_default_route_init(self);
connection = nm_device_get_applied_connection(NM_DEVICE(self));
s_wg = NM_SETTING_WIREGUARD(nm_connection_get_setting(connection, NM_TYPE_SETTING_WIREGUARD));
/* Differences to `wg-quick`.
*
* `wg-quick` supports the "Table" setting with 3 modes:
*
* a1) "off": this is what we do with "peer-routes" disabled.
*
* a2) an explicit routing table. This is our behavior with "peer-routes" on. In this case
* we honor the "ipv4.route-table" and "ipv6.route-table" settings. One difference is that
* `wg-quick` would resolve table names from /etc/iproute2/rt_tables. Our connection profiles
* only contain table numbers, so that conversion from name to table must have happened
* before already.
*
* a3) "auto" (the default). In this case, `wg-quick` would only add the route to the
* main table, if the AllowedIP range is not yet reachable on the link. With "peer-routes"
* enabled, we don't check for that and always add the routes to the main-table
* (with 'ipv4.route-table' and 'ipv6.route-table' set to zero or RT_TABLE_MAIN (254)).
*
* Also, in "auto" mode, `wg-quick` would add special handling for /0 routes and pick
* an empty table to configure policy routing to avoid routing loops. This handling
* of routing-loops via policy routing is not yet done, and requires a separate solution
* from constructing the peer-routes here.
*/
if (!nm_setting_wireguard_get_peer_routes(s_wg))
return NULL;
ip_ifindex = nm_device_get_ip_ifindex(NM_DEVICE(self));
if (ip_ifindex <= 0)
return NULL;
route_metric = nm_device_get_route_metric(NM_DEVICE(self), addr_family);
route_table_coerced =
nm_platform_route_table_coerce(nm_device_get_route_table(NM_DEVICE(self), addr_family));
auto_default_route_enabled = (addr_family == AF_INET) ? priv->auto_default_route_enabled_4
: priv->auto_default_route_enabled_6;
n_peers = nm_setting_wireguard_get_peers_len(s_wg);
for (i = 0; i < n_peers; i++) {
NMWireGuardPeer *peer = nm_setting_wireguard_get_peer(s_wg, i);
guint n_aips;
guint j;
n_aips = nm_wireguard_peer_get_allowed_ips_len(peer);
for (j = 0; j < n_aips; j++) {
NMPlatformIPXRoute rt;
NMIPAddr addrbin;
const char *aip;
gboolean valid;
int prefix;
guint32 rtable_coerced;
aip = nm_wireguard_peer_get_allowed_ip(peer, j, &valid);
if (!valid
|| !nm_utils_parse_inaddr_prefix_bin(addr_family, aip, NULL, &addrbin, &prefix))
continue;
if (prefix < 0)
prefix = (addr_family == AF_INET) ? 32 : 128;
if (prefix == 0) {
NMSettingIPConfig *s_ip;
s_ip = nm_connection_get_setting_ip_config(connection, addr_family);
if (nm_setting_ip_config_get_never_default(s_ip))
continue;
}
if (!l3cd) {
l3cd = nm_device_create_l3_config_data(NM_DEVICE(self), NM_IP_CONFIG_SOURCE_USER);
nm_l3_config_data_set_flags(l3cd,
NM_L3_CONFIG_DAT_FLAGS_IGNORE_MERGE_NO_DEFAULT_ROUTES);
}
nm_utils_ipx_address_clear_host_address(addr_family, &addrbin, NULL, prefix);
rtable_coerced = route_table_coerced;
if (prefix == 0 && auto_default_route_enabled) {
/* In auto-default-route mode, we place the default route in a table that
* has the same number as the fwmark. wg-quick does that too. If you don't
* like that, configure the rules and the default-route explicitly in the
* connection profile. */
rtable_coerced = nm_platform_route_table_coerce(priv->auto_default_route_fwmark);
}
if (addr_family == AF_INET) {
rt.r4 = (NMPlatformIP4Route){
.network = addrbin.addr4,
.plen = prefix,
.ifindex = ip_ifindex,
.rt_source = NM_IP_CONFIG_SOURCE_USER,
.table_coerced = rtable_coerced,
.metric = route_metric,
};
} else {
rt.r6 = (NMPlatformIP6Route){
.network = addrbin.addr6,
.plen = prefix,
.ifindex = ip_ifindex,
.rt_source = NM_IP_CONFIG_SOURCE_USER,
.table_coerced = rtable_coerced,
.metric = route_metric,
};
}
nm_l3_config_data_add_route(l3cd, addr_family, NULL, &rt.rx);
}
}
if (!l3cd)
return NULL;
return nm_l3_config_data_seal(g_steal_pointer(&l3cd));
}
static void
act_stage3_ip_config(NMDevice *device, int addr_family)
{
nm_auto_unref_l3cd const NML3ConfigData *l3cd = NULL;
l3cd = _get_dev2_ip_config(NM_DEVICE_WIREGUARD(device), addr_family);
nm_device_devip_set_state(device, addr_family, NM_DEVICE_IP_STATE_READY, l3cd);
}
static guint32
get_configured_mtu(NMDevice *device, NMDeviceMtuSource *out_source, gboolean *out_force)
{
/* When "MTU" for `wg-quick up` is unset, it calls `ip route get` for
* each configured endpoint, to determine the suitable MTU how to reach
* each endpoint.
* For `wg-quick` this works very well, because whenever the script runs it
* determines the best setting at that point in time. It's simply not concerned
* with what happens later (and it's not around anyway).
*
* NetworkManager sticks around, so the right MTU would need to be re-determined
* whenever anything relevant changes. Which basically means, to re-evaluate whenever
* something related to addresses or routing changes (which happens all the time).
*
* The correct MTU indeed depends on the MTU setting of other interfaces (or routes).
* But it's still odd, that activating/deactivating a seemingly unrelated interface
* would trigger an MTU change. It's odd to explain/document and odd to implemented
* -- despite this being the reality.
*
* For now, only support configuring an explicit MTU, or leave the setting untouched.
* The same limitation also applies to other "ip-tunnel" types, where we could use
* similar smarts for autodetecting the MTU.
*/
return nm_device_get_configured_mtu_from_connection(device,
NM_TYPE_SETTING_WIREGUARD,
out_source);
}
static void
_device_cleanup(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
_peers_remove_all(self);
_secrets_cancel(self);
priv->auto_default_route_initialized = FALSE;
priv->auto_default_route_priority_initialized = FALSE;
}
static void
device_state_changed(NMDevice *device,
NMDeviceState new_state,
NMDeviceState old_state,
NMDeviceStateReason reason)
{
if (new_state <= NM_DEVICE_STATE_ACTIVATED)
return;
_device_cleanup(NM_DEVICE_WIREGUARD(device));
}
/*****************************************************************************/
static gboolean
can_reapply_change(NMDevice *device,
const char *setting_name,
NMSetting *s_old,
NMSetting *s_new,
GHashTable *diffs,
GError **error)
{
if (nm_streq(setting_name, NM_SETTING_WIREGUARD_SETTING_NAME)) {
/* Most, but not all WireGuard settings can be reapplied. Whitelist.
*
* MTU cannot be reapplied. */
return nm_device_hash_check_invalid_keys(diffs,
NM_SETTING_WIREGUARD_SETTING_NAME,
error,
NM_SETTING_WIREGUARD_FWMARK,
NM_SETTING_WIREGUARD_IP4_AUTO_DEFAULT_ROUTE,
NM_SETTING_WIREGUARD_IP6_AUTO_DEFAULT_ROUTE,
NM_SETTING_WIREGUARD_LISTEN_PORT,
NM_SETTING_WIREGUARD_PEERS,
NM_SETTING_WIREGUARD_PEER_ROUTES,
NM_SETTING_WIREGUARD_PRIVATE_KEY,
NM_SETTING_WIREGUARD_PRIVATE_KEY_FLAGS);
}
return NM_DEVICE_CLASS(nm_device_wireguard_parent_class)
->can_reapply_change(device, setting_name, s_old, s_new, diffs, error);
}
static void
reapply_connection(NMDevice *device, NMConnection *con_old, NMConnection *con_new)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(device);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
NMDeviceState state = nm_device_get_state(device);
NM_DEVICE_CLASS(nm_device_wireguard_parent_class)->reapply_connection(device, con_old, con_new);
if (state >= NM_DEVICE_STATE_CONFIG) {
priv->auto_default_route_refresh = TRUE;
link_config(NM_DEVICE_WIREGUARD(device), "reapply", LINK_CONFIG_MODE_REAPPLY, NULL);
}
if (state >= NM_DEVICE_STATE_IP_CONFIG) {
nm_auto_unref_l3cd const NML3ConfigData *l3cd_4 = NULL;
nm_auto_unref_l3cd const NML3ConfigData *l3cd_6 = NULL;
l3cd_4 = _get_dev2_ip_config(self, AF_INET);
l3cd_6 = _get_dev2_ip_config(self, AF_INET6);
nm_device_devip_set_state(device, AF_INET, NM_DEVICE_IP_STATE_READY, l3cd_4);
nm_device_devip_set_state(device, AF_INET6, NM_DEVICE_IP_STATE_READY, l3cd_6);
}
}
/*****************************************************************************/
static void
update_connection(NMDevice *device, NMConnection *connection)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(device);
NMSettingWireGuard *s_wg = _nm_connection_ensure_setting(connection, NM_TYPE_SETTING_WIREGUARD);
const NMPObject *obj_wg;
const NMPObjectLnkWireGuard *olnk_wg;
guint i;
g_object_set(s_wg,
NM_SETTING_WIREGUARD_FWMARK,
(guint) priv->lnk_curr.fwmark,
NM_SETTING_WIREGUARD_LISTEN_PORT,
(guint) priv->lnk_curr.listen_port,
NULL);
obj_wg = NMP_OBJECT_UP_CAST(nm_platform_link_get_lnk_wireguard(nm_device_get_platform(device),
nm_device_get_ip_ifindex(device),
NULL));
if (!obj_wg)
return;
olnk_wg = &obj_wg->_lnk_wireguard;
for (i = 0; i < olnk_wg->peers_len; i++) {
nm_auto_unref_wgpeer NMWireGuardPeer *peer = NULL;
const NMPWireGuardPeer *ppeer = &olnk_wg->peers[i];
peer = nm_wireguard_peer_new();
_nm_wireguard_peer_set_public_key_bin(peer, ppeer->public_key);
nm_setting_wireguard_append_peer(s_wg, peer);
}
}
/*****************************************************************************/
static void
get_property(GObject *object, guint prop_id, GValue *value, GParamSpec *pspec)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(object);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
switch (prop_id) {
case PROP_PUBLIC_KEY:
g_value_take_variant(
value,
nm_g_variant_new_ay(priv->lnk_curr.public_key, sizeof(priv->lnk_curr.public_key)));
break;
case PROP_LISTEN_PORT:
g_value_set_uint(value, priv->lnk_curr.listen_port);
break;
case PROP_FWMARK:
g_value_set_uint(value, priv->lnk_curr.fwmark);
break;
default:
G_OBJECT_WARN_INVALID_PROPERTY_ID(object, prop_id, pspec);
break;
}
}
/*****************************************************************************/
static void
nm_device_wireguard_init(NMDeviceWireGuard *self)
{
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
c_list_init(&priv->lst_peers_head);
priv->peers = g_hash_table_new(_peer_data_hash, _peer_data_equal);
}
static void
dispose(GObject *object)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(object);
_device_cleanup(self);
G_OBJECT_CLASS(nm_device_wireguard_parent_class)->dispose(object);
}
static void
finalize(GObject *object)
{
NMDeviceWireGuard *self = NM_DEVICE_WIREGUARD(object);
NMDeviceWireGuardPrivate *priv = NM_DEVICE_WIREGUARD_GET_PRIVATE(self);
nm_explicit_bzero(priv->lnk_curr.private_key, sizeof(priv->lnk_curr.private_key));
if (priv->dns_manager) {
g_signal_handlers_disconnect_by_func(priv->dns_manager, _dns_config_changed, self);
g_object_unref(priv->dns_manager);
}
g_hash_table_destroy(priv->peers);
G_OBJECT_CLASS(nm_device_wireguard_parent_class)->finalize(object);
}
static const NMDBusInterfaceInfoExtended interface_info_device_wireguard = {
.parent = NM_DEFINE_GDBUS_INTERFACE_INFO_INIT(
NM_DBUS_INTERFACE_DEVICE_WIREGUARD,
.properties = NM_DEFINE_GDBUS_PROPERTY_INFOS(
NM_DEFINE_DBUS_PROPERTY_INFO_EXTENDED_READABLE("PublicKey",
"ay",
NM_DEVICE_WIREGUARD_PUBLIC_KEY),
NM_DEFINE_DBUS_PROPERTY_INFO_EXTENDED_READABLE("ListenPort",
"q",
NM_DEVICE_WIREGUARD_LISTEN_PORT),
NM_DEFINE_DBUS_PROPERTY_INFO_EXTENDED_READABLE("FwMark",
"u",
NM_DEVICE_WIREGUARD_FWMARK), ), ),
};
static void
nm_device_wireguard_class_init(NMDeviceWireGuardClass *klass)
{
GObjectClass *object_class = G_OBJECT_CLASS(klass);
NMDBusObjectClass *dbus_object_class = NM_DBUS_OBJECT_CLASS(klass);
NMDeviceClass *device_class = NM_DEVICE_CLASS(klass);
object_class->get_property = get_property;
object_class->dispose = dispose;
object_class->finalize = finalize;
dbus_object_class->interface_infos = NM_DBUS_INTERFACE_INFOS(&interface_info_device_wireguard);
device_class->connection_type_supported = NM_SETTING_WIREGUARD_SETTING_NAME;
device_class->connection_type_check_compatible = NM_SETTING_WIREGUARD_SETTING_NAME;
device_class->link_types = NM_DEVICE_DEFINE_LINK_TYPES(NM_LINK_TYPE_WIREGUARD);
device_class->state_changed = device_state_changed;
device_class->create_and_realize = create_and_realize;
device_class->act_stage2_config = act_stage2_config;
device_class->act_stage2_config_also_for_external_or_assume = TRUE;
device_class->act_stage3_ip_config = act_stage3_ip_config;
device_class->get_generic_capabilities = get_generic_capabilities;
device_class->link_changed = link_changed;
device_class->update_connection = update_connection;
device_class->can_reapply_change = can_reapply_change;
device_class->reapply_connection = reapply_connection;
device_class->get_configured_mtu = get_configured_mtu;
device_class->get_extra_rules = get_extra_rules;
device_class->coerce_route_table = coerce_route_table;
obj_properties[PROP_PUBLIC_KEY] =
g_param_spec_variant(NM_DEVICE_WIREGUARD_PUBLIC_KEY,
"",
"",
G_VARIANT_TYPE("ay"),
NULL,
G_PARAM_READABLE | G_PARAM_STATIC_STRINGS);
obj_properties[PROP_LISTEN_PORT] = g_param_spec_uint(NM_DEVICE_WIREGUARD_LISTEN_PORT,
"",
"",
0,
G_MAXUINT16,
0,
G_PARAM_READABLE | G_PARAM_STATIC_STRINGS);
obj_properties[PROP_FWMARK] = g_param_spec_uint(NM_DEVICE_WIREGUARD_FWMARK,
"",
"",
0,
G_MAXUINT32,
0,
G_PARAM_READABLE | G_PARAM_STATIC_STRINGS);
g_object_class_install_properties(object_class, _PROPERTY_ENUMS_LAST, obj_properties);
}
/*************************************************************/
#define NM_TYPE_WIREGUARD_DEVICE_FACTORY (nm_wireguard_device_factory_get_type())
#define NM_WIREGUARD_DEVICE_FACTORY(obj) \
(G_TYPE_CHECK_INSTANCE_CAST((obj), NM_TYPE_WIREGUARD_DEVICE_FACTORY, NMWireGuardDeviceFactory))
static NMDevice *
create_device(NMDeviceFactory *factory,
const char *iface,
const NMPlatformLink *plink,
NMConnection *connection,
gboolean *out_ignore)
{
return g_object_new(NM_TYPE_DEVICE_WIREGUARD,
NM_DEVICE_IFACE,
iface,
NM_DEVICE_TYPE_DESC,
"WireGuard",
NM_DEVICE_DEVICE_TYPE,
NM_DEVICE_TYPE_WIREGUARD,
NM_DEVICE_LINK_TYPE,
NM_LINK_TYPE_WIREGUARD,
NULL);
}
NM_DEVICE_FACTORY_DEFINE_INTERNAL(
WIREGUARD,
WireGuard,
wireguard,
NM_DEVICE_FACTORY_DECLARE_LINK_TYPES(NM_LINK_TYPE_WIREGUARD)
NM_DEVICE_FACTORY_DECLARE_SETTING_TYPES(NM_SETTING_WIREGUARD_SETTING_NAME),
factory_class->create_device = create_device;)
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