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iwd/src/station.c
2024-11-07 19:11:59 +01:00

5855 lines
153 KiB
C

/*
*
* Wireless daemon for Linux
*
* Copyright (C) 2018-2019 Intel Corporation. All rights reserved.
*
* 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, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#define _GNU_SOURCE
#include <stdio.h>
#include <errno.h>
#include <time.h>
#include <sys/time.h>
#include <limits.h>
#include <linux/if_ether.h>
#include <ell/ell.h>
#include "ell/useful.h"
#include "src/util.h"
#include "src/iwd.h"
#include "src/module.h"
#include "src/common.h"
#include "src/watchlist.h"
#include "src/scan.h"
#include "src/netdev.h"
#include "src/dbus.h"
#include "src/wiphy.h"
#include "src/network.h"
#include "src/knownnetworks.h"
#include "src/ie.h"
#include "src/handshake.h"
#include "src/station.h"
#include "src/blacklist.h"
#include "src/mpdu.h"
#include "src/erp.h"
#include "src/netconfig.h"
#include "src/anqp.h"
#include "src/anqputil.h"
#include "src/diagnostic.h"
#include "src/frame-xchg.h"
#include "src/sysfs.h"
#include "src/band.h"
#include "src/ft.h"
#include "src/eap.h"
#include "src/eap-tls-common.h"
#include "src/storage.h"
#define STATION_RECENT_NETWORK_LIMIT 5
#define STATION_RECENT_FREQS_LIMIT 5
static struct l_queue *station_list;
static uint32_t netdev_watch;
static uint32_t mfp_setting;
static uint32_t roam_retry_interval;
static bool anqp_disabled;
static bool supports_arp_evict_nocarrier;
static bool supports_ndisc_evict_nocarrier;
static bool supports_drop_gratuitous_arp;
static bool supports_drop_unsolicited_na;
static bool supports_ipv4_drop_unicast_in_l2_multicast;
static bool supports_ipv6_drop_unicast_in_l2_multicast;
static struct watchlist event_watches;
static uint32_t known_networks_watch;
static uint32_t allowed_bands;
struct station {
enum station_state state;
struct watchlist state_watches;
struct scan_bss *connected_bss;
struct network *connected_network;
struct scan_bss *connect_pending_bss;
struct network *connect_pending_network;
struct l_queue *autoconnect_list;
struct l_queue *bss_list;
struct l_queue *hidden_bss_list_sorted;
struct l_hashmap *networks;
struct l_queue *networks_sorted;
struct l_dbus_message *connect_pending;
struct l_dbus_message *hidden_pending;
struct l_dbus_message *disconnect_pending;
struct l_dbus_message *scan_pending;
struct l_dbus_message *get_station_pending;
struct signal_agent *signal_agent;
uint32_t dbus_scan_id;
uint32_t quick_scan_id;
uint32_t hidden_network_scan_id;
struct l_queue *owe_hidden_scan_ids;
/* Roaming related members */
struct l_timeout *roam_trigger_timeout;
uint32_t roam_scan_id;
uint8_t preauth_bssid[6];
struct wiphy *wiphy;
struct netdev *netdev;
struct l_queue *anqp_pending;
struct netconfig *netconfig;
/* Set of frequencies to scan first when attempting a roam */
struct scan_freq_set *roam_freqs;
struct l_queue *roam_bss_list;
/* Frequencies split into subsets by priority */
struct scan_freq_set *scan_freqs_order[3];
unsigned int dbus_scan_subset_idx;
uint32_t wiphy_watch;
struct wiphy_radio_work_item ft_work;
uint64_t last_roam_scan;
struct l_queue *affinities;
unsigned int affinity_watch;
char *affinity_client;
bool preparing_roam : 1;
bool roam_scan_full : 1;
bool signal_low : 1;
bool ap_directed_roaming : 1;
bool scanning : 1;
bool autoconnect : 1;
bool autoconnect_can_start : 1;
bool netconfig_after_roam : 1;
};
struct anqp_entry {
struct station *station;
struct network *network;
uint32_t pending;
};
/*
* Used as entries for the roam list since holding scan_bss pointers directly
* from station->bss_list is not 100% safe due to the possibility of the
* hardware scanning and overwriting station->bss_list.
*/
struct roam_bss {
uint8_t addr[6];
uint16_t rank;
int32_t signal_strength;
bool ft_failed: 1;
};
static struct roam_bss *roam_bss_from_scan_bss(const struct scan_bss *bss,
uint16_t rank)
{
struct roam_bss *rbss = l_new(struct roam_bss, 1);
memcpy(rbss->addr, bss->addr, 6);
rbss->rank = rank;
rbss->signal_strength = bss->signal_strength;
rbss->ft_failed = false;
return rbss;
}
static int roam_bss_rank_compare(const void *a, const void *b, void *user_data)
{
const struct roam_bss *new_bss = a, *bss = b;
if (bss->rank == new_bss->rank)
return (bss->signal_strength >
new_bss->signal_strength) ? 1 : -1;
return (bss->rank > new_bss->rank) ? 1 : -1;
}
struct wiphy *station_get_wiphy(struct station *station)
{
return station->wiphy;
}
struct netdev *station_get_netdev(struct station *station)
{
return station->netdev;
}
struct network *station_get_connected_network(struct station *station)
{
return station->connected_network;
}
bool station_is_busy(struct station *station)
{
return station->state != STATION_STATE_DISCONNECTED &&
station->state != STATION_STATE_AUTOCONNECT_FULL &&
station->state != STATION_STATE_AUTOCONNECT_QUICK;
}
static bool station_is_autoconnecting(struct station *station)
{
return station->state == STATION_STATE_AUTOCONNECT_FULL ||
station->state == STATION_STATE_AUTOCONNECT_QUICK;
}
static bool station_is_roaming(struct station *station)
{
return station->state == STATION_STATE_ROAMING ||
station->state == STATION_STATE_FT_ROAMING ||
station->state == STATION_STATE_FW_ROAMING;
}
static bool station_debug_event(struct station *station, const char *name)
{
struct l_dbus_message *signal;
if (!iwd_is_developer_mode())
return true;
l_debug("StationDebug.Event(%s)", name);
signal = l_dbus_message_new_signal(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_DEBUG_INTERFACE, "Event");
l_dbus_message_set_arguments(signal, "sav", name, 0);
return l_dbus_send(dbus_get_bus(), signal) != 0;
}
static void station_property_set_scanning(struct station *station,
bool scanning)
{
if (station->scanning == scanning)
return;
station->scanning = scanning;
l_dbus_property_changed(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "Scanning");
}
static void station_enter_state(struct station *station,
enum station_state state);
static void network_add_foreach(struct network *network, void *user_data)
{
struct station *station = user_data;
l_queue_insert(station->autoconnect_list, network,
network_rank_compare, NULL);
}
static int station_autoconnect_next(struct station *station)
{
struct network *network;
int r;
if (!station->autoconnect_list)
return -ENOENT;
while ((network = l_queue_pop_head(station->autoconnect_list))) {
const char *ssid = network_get_ssid(network);
struct scan_bss *bss = network_bss_select(network, false);
l_debug("autoconnect: Trying SSID: %s", ssid);
if (!bss) {
l_debug("autoconnect: No suitable BSSes found");
continue;
}
l_debug("autoconnect: '%s' freq: %u, rank: %u, strength: %i",
util_address_to_string(bss->addr),
bss->frequency, bss->rank,
bss->signal_strength);
r = network_autoconnect(network, bss);
if (!r) {
if (station->quick_scan_id) {
scan_cancel(netdev_get_wdev_id(station->netdev),
station->quick_scan_id);
station->quick_scan_id = 0;
station_property_set_scanning(station, false);
}
return 0;
}
l_debug("autoconnect: network_autoconnect: %s (%d)",
strerror(-r), r);
}
return -ENOENT;
}
static void station_autoconnect_start(struct station *station)
{
if (!station->autoconnect_can_start)
return;
if (!station_is_autoconnecting(station))
return;
if (!l_queue_isempty(station->anqp_pending))
return;
if (!l_queue_isempty(station->owe_hidden_scan_ids))
return;
if (L_WARN_ON(station->autoconnect_list))
l_queue_destroy(station->autoconnect_list, NULL);
l_debug("");
station->autoconnect_list = l_queue_new();
station_network_foreach(station, network_add_foreach, station);
station_autoconnect_next(station);
station->autoconnect_can_start = false;
}
static void bss_free(void *data)
{
struct scan_bss *bss = data;
scan_bss_free(bss);
}
static void network_free(void *data)
{
struct network *network = data;
network_remove(network, -ESHUTDOWN);
}
struct process_network_data {
struct station *station;
const struct scan_freq_set *freqs;
};
static bool process_network(const void *key, void *data, void *user_data)
{
struct network *network = data;
struct process_network_data *process_data = user_data;
struct station *station = process_data->station;
if (!network_bss_list_isempty(network)) {
bool connected = network == station->connected_network;
/* Build the network list ordered by rank */
network_rank_update(network, connected);
l_queue_insert(station->networks_sorted, network,
network_rank_compare, NULL);
network_update_known_frequencies(network);
return false;
}
/* Drop networks that have no more BSSs in range */
l_debug("No remaining BSSs for SSID: %s -- Removing network",
network_get_ssid(network));
network_remove(network, -ERANGE);
return true;
}
static const char *iwd_network_get_path(struct station *station,
const char *ssid,
enum security security)
{
static char path[256];
unsigned int pos, i;
pos = snprintf(path, sizeof(path), "%s/",
netdev_get_path(station->netdev));
for (i = 0; ssid[i] && pos < sizeof(path); i++)
pos += snprintf(path + pos, sizeof(path) - pos, "%02hhx",
ssid[i]);
snprintf(path + pos, sizeof(path) - pos, "_%s",
security_to_str(security));
return path;
}
struct network *station_network_find(struct station *station, const char *ssid,
enum security security)
{
const char *path = iwd_network_get_path(station, ssid, security);
return l_hashmap_lookup(station->networks, path);
}
static int bss_signal_strength_compare(const void *a, const void *b, void *user)
{
const struct scan_bss *new_bss = a;
const struct scan_bss *bss = b;
return (bss->signal_strength > new_bss->signal_strength) ? 1 : -1;
}
static void station_print_scan_bss(const struct scan_bss *bss)
{
uint32_t kbps100 = DIV_ROUND_CLOSEST(bss->data_rate, 100000);
char optional[64] = {0};
char *ptr = optional;
if (bss->have_snr)
ptr += sprintf(ptr, ", snr: %d", bss->snr);
if (bss->have_utilization)
ptr += sprintf(ptr, ", load: %u/255", bss->utilization);
l_debug("Processing BSS '%s' with SSID: %s, freq: %u, rank: %u, "
"strength: %i, data_rate: %u.%u%s",
util_address_to_string(bss->addr),
util_ssid_to_utf8(bss->ssid_len, bss->ssid),
bss->frequency, bss->rank, bss->signal_strength,
kbps100 / 10, kbps100 % 10,
optional);
}
static const char *station_get_bss_path(struct station *station,
struct scan_bss *bss)
{
enum security security;
char ssid[33];
const char *network_path;
memcpy(ssid, bss->ssid, bss->ssid_len);
ssid[bss->ssid_len] = '\0';
if (scan_bss_get_security(bss, &security) < 0)
return NULL;
network_path = iwd_network_get_path(station, ssid, security);
if (!network_path)
return NULL;
return __network_path_append_bss(network_path, bss);
}
static bool match_bss_path(const void *data, const void *user_data)
{
const char *path1 = data;
const char *path2 = user_data;
return !strcmp(path1, path2);
}
static bool station_unregister_bss(struct station *station,
struct scan_bss *bss)
{
const char *path = station_get_bss_path(station, bss);
if (L_WARN_ON(!path))
return false;
l_queue_remove_if(station->affinities, match_bss_path, path);
return l_dbus_unregister_object(dbus_get_bus(), path);
}
static bool station_register_bss(struct network *network, struct scan_bss *bss)
{
struct scan_bss *old;
const char *path = __network_path_append_bss(network_get_path(network),
bss);
if (L_WARN_ON(!path))
return false;
/*
* If we find this path in the object tree update the data to the new
* scan_bss pointer, as this one will be freed soon.
*/
old = l_dbus_object_get_data(dbus_get_bus(), path, IWD_BSS_INTERFACE);
if (old)
return l_dbus_object_set_data(dbus_get_bus(), path,
IWD_BSS_INTERFACE, bss);
if (!l_dbus_object_add_interface(dbus_get_bus(), path,
IWD_BSS_INTERFACE, bss))
return false;
if (!l_dbus_object_add_interface(dbus_get_bus(), path,
L_DBUS_INTERFACE_PROPERTIES, bss))
return false;
return true;
}
/*
* Returns the network object the BSS was added to or NULL if ignored.
*/
static struct network *station_add_seen_bss(struct station *station,
struct scan_bss *bss)
{
struct network *network;
enum security security;
const char *path;
char ssid[SSID_MAX_SIZE + 1];
station_print_scan_bss(bss);
if (util_ssid_is_hidden(bss->ssid_len, bss->ssid)) {
l_debug("BSS has hidden SSID");
l_queue_insert(station->hidden_bss_list_sorted, bss,
bss_signal_strength_compare, NULL);
return NULL;
}
memcpy(ssid, bss->ssid, bss->ssid_len);
ssid[bss->ssid_len] = '\0';
if (!(bss->capability & IE_BSS_CAP_ESS)) {
l_debug("Ignoring non-ESS BSS \"%s\"", ssid);
return NULL;
}
if (scan_bss_get_security(bss, &security) < 0)
return NULL;
/* Hidden OWE transition network */
if (security == SECURITY_NONE && bss->rsne && bss->owe_trans) {
struct ie_owe_transition_info *info = bss->owe_trans;
/*
* WiFi Alliance OWE Specification v1.1 - Section 2.2.1:
*
* "2. An OWE AP shall use two different SSIDs, one for OWE
* and one for Open"
*
* "4. The OWE BSS shall include the OWE Transition Mode element
* in all Beacon and Probe Response frames to encapsulate
* the BSSID and SSID of the Open BSS"
*
* Meaning the hidden SSID should not match the SSID in the
* hidden network's OWE IE. Might as well restrict BSSID as well
* to be safe.
*
* In addition this SSID must be a valid utf8 string otherwise
* we could not look up the network. Note that this is not true
* for the open BSS IE, it can be non-utf8.
*/
if (!util_ssid_is_utf8(info->ssid_len, info->ssid))
return NULL;
if (!memcmp(info->ssid, bss->ssid, bss->ssid_len))
return NULL;
if (!memcmp(info->bssid, bss->addr, 6))
return NULL;
memcpy(ssid, info->ssid, info->ssid_len);
ssid[info->ssid_len] = '\0';
l_debug("Found hidden OWE network, using %s for network lookup",
ssid);
}
path = iwd_network_get_path(station, ssid, security);
network = l_hashmap_lookup(station->networks, path);
if (!network) {
network = network_create(station, ssid, security);
if (!network_register(network, path)) {
network_remove(network, -EINVAL);
return NULL;
}
l_hashmap_insert(station->networks,
network_get_path(network), network);
l_debug("Added new Network \"%s\" security %s",
network_get_ssid(network), security_to_str(security));
}
network_bss_add(network, bss);
station_register_bss(network, bss);
return network;
}
static bool bss_match(const void *a, const void *b)
{
const struct scan_bss *bss_a = a;
const struct scan_bss *bss_b = b;
if (memcmp(bss_a->addr, bss_b->addr, sizeof(bss_a->addr)))
return false;
if (bss_a->ssid_len != bss_b->ssid_len)
return false;
return !memcmp(bss_a->ssid, bss_b->ssid, bss_a->ssid_len);
}
struct bss_expiration_data {
struct scan_bss *connected_bss;
uint64_t now;
const struct scan_freq_set *freqs;
struct station *station;
};
#define SCAN_RESULT_BSS_RETENTION_TIME (30 * 1000000)
static bool bss_free_if_expired(void *data, void *user_data)
{
struct scan_bss *bss = data;
struct bss_expiration_data *expiration_data = user_data;
if (bss == expiration_data->connected_bss)
/* Do not expire the currently connected BSS. */
return false;
/* Keep any BSSes that are not on the frequency list */
if (!scan_freq_set_contains(expiration_data->freqs, bss->frequency))
return false;
if (l_time_before(expiration_data->now,
bss->time_stamp + SCAN_RESULT_BSS_RETENTION_TIME))
return false;
station_unregister_bss(expiration_data->station, bss);
scan_bss_free(bss);
return true;
}
static void station_bss_list_remove_expired_bsses(struct station *station,
const struct scan_freq_set *freqs)
{
struct bss_expiration_data data = {
.now = l_time_now(),
.connected_bss = station->connected_bss,
.freqs = freqs,
.station = station,
};
l_queue_foreach_remove(station->bss_list, bss_free_if_expired, &data);
}
struct nai_search {
struct network *network;
const char **realms;
};
static bool match_nai_realms(const struct network_info *info, void *user_data)
{
struct nai_search *search = user_data;
if (!network_info_match_nai_realm(info, search->realms))
return false;
network_set_info(search->network, (struct network_info *) info);
return true;
}
static bool match_pending(const void *a, const void *b)
{
const struct anqp_entry *entry = a;
return entry->pending != 0;
}
static void remove_anqp(void *data)
{
struct anqp_entry *entry = data;
if (entry->pending)
anqp_cancel(entry->pending);
l_free(entry);
}
static bool anqp_entry_foreach(void *data, void *user_data)
{
struct anqp_entry *e = data;
WATCHLIST_NOTIFY(&event_watches, station_event_watch_func_t,
STATION_EVENT_ANQP_FINISHED, e->network);
remove_anqp(e);
return true;
}
static void station_anqp_response_cb(enum anqp_result result,
const void *anqp, size_t anqp_len,
void *user_data)
{
struct anqp_entry *entry = user_data;
struct station *station = entry->station;
struct network *network = entry->network;
struct anqp_iter iter;
uint16_t id;
uint16_t len;
const void *data;
char **realms = NULL;
struct nai_search search;
l_debug("");
if (result != ANQP_SUCCESS) {
/* TODO: try next BSS */
goto request_done;
}
anqp_iter_init(&iter, anqp, anqp_len);
while (anqp_iter_next(&iter, &id, &len, &data)) {
switch (id) {
case ANQP_NAI_REALM:
if (realms)
break;
realms = anqp_parse_nai_realms(data, len);
if (!realms)
goto request_done;
break;
default:
continue;
}
}
if (!realms)
goto request_done;
search.network = network;
search.realms = (const char **)realms;
known_networks_foreach(match_nai_realms, &search);
l_strv_free(realms);
request_done:
entry->pending = 0;
/* Return if there are other pending requests */
if (l_queue_find(station->anqp_pending, match_pending, NULL))
return;
/* Notify all watchers now that every ANQP request has finished */
l_queue_foreach_remove(station->anqp_pending, anqp_entry_foreach, NULL);
station_autoconnect_start(station);
}
static bool station_start_anqp(struct station *station, struct network *network,
struct scan_bss *bss)
{
uint8_t anqp[256];
uint8_t *ptr = anqp;
struct anqp_entry *entry;
if (!bss->hs20_capable)
return false;
/* Network already has ANQP data/HESSID */
if (network_get_info(network))
return false;
if (anqp_disabled) {
l_debug("Not querying AP for ANQP data (disabled)");
return false;
}
entry = l_new(struct anqp_entry, 1);
entry->station = station;
entry->network = network;
l_put_le16(ANQP_QUERY_LIST, ptr);
ptr += 2;
l_put_le16(2, ptr);
ptr += 2;
l_put_le16(ANQP_NAI_REALM, ptr);
ptr += 2;
l_put_le16(ANQP_VENDOR_SPECIFIC, ptr);
ptr += 2;
/* vendor length */
l_put_le16(7, ptr);
ptr += 2;
*ptr++ = 0x50;
*ptr++ = 0x6f;
*ptr++ = 0x9a;
*ptr++ = 0x11; /* HS20 ANQP Element type */
*ptr++ = ANQP_HS20_QUERY_LIST;
*ptr++ = 0; /* reserved */
*ptr++ = ANQP_HS20_OSU_PROVIDERS_NAI_LIST;
/*
* TODO: Additional roaming consortiums can be queried if indicated
* by the roaming consortium IE. The IE contains up to the first 3, and
* these are checked in hs20_find_settings_file.
*/
entry->pending = anqp_request(netdev_get_wdev_id(station->netdev),
netdev_get_address(station->netdev), bss, anqp,
ptr - anqp, station_anqp_response_cb,
entry, NULL);
if (!entry->pending) {
l_free(entry);
return false;
}
l_queue_push_head(station->anqp_pending, entry);
WATCHLIST_NOTIFY(&event_watches, station_event_watch_func_t,
STATION_EVENT_ANQP_STARTED, network);
return true;
}
static bool network_has_open_pair(struct network *network, struct scan_bss *owe)
{
const struct l_queue_entry *entry;
struct ie_owe_transition_info *owe_info = owe->owe_trans;
for (entry = network_bss_list_get_entries(network); entry;
entry = entry->next) {
struct scan_bss *open = entry->data;
struct ie_owe_transition_info *open_info = open->owe_trans;
/* AP does not advertise owe transition */
if (!open_info)
continue;
/*
* Check if this is an Open/Hidden pair:
*
* Open SSID equals the SSID in OWE IE
* Open BSSID equals the BSSID in OWE IE
*
* OWE SSID equals the SSID in Open IE
* OWE BSSID equals the BSSID in Open IE
*/
if (open->ssid_len == owe_info->ssid_len &&
open_info->ssid_len == owe->ssid_len &&
!memcmp(open->ssid, owe_info->ssid,
open->ssid_len) &&
!memcmp(open_info->ssid, owe->ssid,
owe->ssid_len) &&
!memcmp(open->addr, owe_info->bssid, 6) &&
!memcmp(open_info->bssid, owe->addr, 6))
return true;
}
return false;
}
static bool station_owe_transition_results(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct network *network = userdata;
struct station *station = network_get_station(network);
struct scan_bss *bss;
station_property_set_scanning(station, false);
if (err)
goto done;
while ((bss = l_queue_pop_head(bss_list))) {
/*
* Don't handle the open BSS, hidden BSS, BSS with no OWE
* Transition IE, or an IE with a non-utf8 SSID
*/
if (!bss->rsne || !bss->owe_trans ||
util_ssid_is_hidden(bss->ssid_len, bss->ssid) ||
!util_ssid_is_utf8(bss->owe_trans->ssid_len,
bss->owe_trans->ssid))
goto free;
/* Check if we have an open BSS that matches */
if (!network_has_open_pair(network, bss))
goto free;
l_debug("Adding OWE transition network "MAC" to %s",
MAC_STR(bss->addr), network_get_ssid(network));
l_queue_push_tail(station->bss_list, bss);
network_bss_add(network, bss);
station_register_bss(network, bss);
continue;
free:
scan_bss_free(bss);
}
network_update_known_frequencies(network);
l_queue_destroy(bss_list, NULL);
done:
l_queue_pop_head(station->owe_hidden_scan_ids);
WATCHLIST_NOTIFY(&event_watches, station_event_watch_func_t,
STATION_EVENT_OWE_HIDDEN_FINISHED, network);
station_autoconnect_start(station);
return err == 0;
}
static void station_owe_transition_triggered(int err, void *user_data)
{
struct network *network = user_data;
struct station *station = network_get_station(network);
if (err < 0) {
l_debug("OWE transition scan trigger failed: %i", err);
l_queue_pop_head(station->owe_hidden_scan_ids);
WATCHLIST_NOTIFY(&event_watches, station_event_watch_func_t,
STATION_EVENT_OWE_HIDDEN_FINISHED, network);
return;
}
l_debug("OWE transition scan triggered");
station_property_set_scanning(station, true);
}
static void foreach_add_owe_scan(struct network *network, void *data)
{
struct station *station = data;
const struct l_queue_entry *entry;
struct l_queue *list = NULL;
uint32_t id;
if (network_get_security(network) != SECURITY_NONE)
return;
for (entry = network_bss_list_get_entries(network); entry;
entry = entry->next) {
struct scan_bss *open = entry->data;
if (!open->owe_trans)
continue;
/* only want the open networks with WFA OWE IE */
if (open->rsne)
continue;
/* BSS already in network object */
if (network_bss_find_by_addr(network, open->owe_trans->bssid))
continue;
if (!list)
list = l_queue_new();
l_queue_push_tail(list, open);
}
if (!list)
return;
id = scan_owe_hidden(netdev_get_wdev_id(station->netdev), list,
station_owe_transition_triggered,
station_owe_transition_results, network, NULL);
l_queue_destroy(list, NULL);
if (!id)
return;
if (!station->owe_hidden_scan_ids)
station->owe_hidden_scan_ids = l_queue_new();
l_queue_push_tail(station->owe_hidden_scan_ids, L_UINT_TO_PTR(id));
WATCHLIST_NOTIFY(&event_watches, station_event_watch_func_t,
STATION_EVENT_OWE_HIDDEN_STARTED, network);
}
static void station_process_owe_transition_networks(struct station *station)
{
station_network_foreach(station, foreach_add_owe_scan, station);
}
static bool bss_free_if_ssid_not_utf8(void *data, void *user_data)
{
struct scan_bss *bss = data;
if (util_ssid_is_hidden(bss->ssid_len, bss->ssid))
return false;
if (util_ssid_is_utf8(bss->ssid_len, bss->ssid))
return false;
l_debug("Dropping scan_bss '%s', with non-utf8 SSID",
util_address_to_string(bss->addr));
bss_free(bss);
return true;
}
/*
* Used when scan results were obtained; either from scan running
* inside station module or scans running in other state machines, e.g. wsc
*/
void station_set_scan_results(struct station *station,
struct l_queue *new_bss_list,
const struct scan_freq_set *freqs,
bool trigger_autoconnect)
{
const struct l_queue_entry *bss_entry;
struct network *network;
struct process_network_data data;
l_queue_foreach_remove(new_bss_list, bss_free_if_ssid_not_utf8, NULL);
while ((network = l_queue_pop_head(station->networks_sorted)))
network_bss_list_clear(network);
l_queue_clear(station->hidden_bss_list_sorted, NULL);
l_queue_destroy(station->autoconnect_list, NULL);
station->autoconnect_list = NULL;
station_bss_list_remove_expired_bsses(station, freqs);
for (bss_entry = l_queue_get_entries(station->bss_list); bss_entry;
bss_entry = bss_entry->next) {
struct scan_bss *old_bss = bss_entry->data;
struct scan_bss *new_bss;
new_bss = l_queue_find(new_bss_list, bss_match, old_bss);
if (new_bss) {
if (old_bss == station->connected_bss)
station->connected_bss = new_bss;
scan_bss_free(old_bss);
continue;
}
if (old_bss == station->connected_bss) {
l_warn("Connected BSS not in scan results");
station->connected_bss->rank = 0;
}
l_queue_push_tail(new_bss_list, old_bss);
}
l_queue_destroy(station->bss_list, NULL);
for (bss_entry = l_queue_get_entries(new_bss_list); bss_entry;
bss_entry = bss_entry->next) {
struct scan_bss *bss = bss_entry->data;
struct network *network = station_add_seen_bss(station, bss);
if (!network)
continue;
/* Cached BSS entry, this should have been processed already */
if (!scan_freq_set_contains(freqs, bss->frequency))
continue;
station_register_bss(network, bss);
station_start_anqp(station, network, bss);
}
station->bss_list = new_bss_list;
data.station = station;
data.freqs = freqs;
l_hashmap_foreach_remove(station->networks, process_network, &data);
station->autoconnect_can_start = trigger_autoconnect;
station_autoconnect_start(station);
}
static void station_reconnect(struct station *station);
static void station_handshake_event(struct handshake_state *hs,
enum handshake_event event,
void *user_data, ...)
{
struct station *station = user_data;
struct network *network = station->connected_network;
va_list args;
va_start(args, user_data);
switch (event) {
case HANDSHAKE_EVENT_STARTED:
l_debug("Handshaking");
station_debug_event(station, "handshake-started");
break;
case HANDSHAKE_EVENT_SETTING_KEYS:
l_debug("Setting keys");
/* If we got here, then our settings work. Update if needed */
network_sync_settings(network);
break;
case HANDSHAKE_EVENT_FAILED:
netdev_handshake_failed(hs, va_arg(args, int));
break;
case HANDSHAKE_EVENT_REKEY_FAILED:
l_warn("Unable to securely rekey on this hw/kernel...");
station_reconnect(station);
break;
case HANDSHAKE_EVENT_TRANSITION_DISABLE:
{
const uint8_t *td = va_arg(args, const uint8_t *);
size_t len = va_arg(args, size_t);
network_set_transition_disable(network, td, len);
break;
}
case HANDSHAKE_EVENT_COMPLETE:
case HANDSHAKE_EVENT_SETTING_KEYS_FAILED:
case HANDSHAKE_EVENT_EAP_NOTIFY:
case HANDSHAKE_EVENT_P2P_IP_REQUEST:
case HANDSHAKE_EVENT_REKEY_COMPLETE:
/*
* currently we don't care about any other events. The
* netdev_connect_cb will notify us when the connection is
* complete.
*/
break;
}
va_end(args);
}
static int station_build_handshake_rsn(struct handshake_state *hs,
struct wiphy *wiphy,
struct network *network,
struct scan_bss *bss)
{
const struct l_settings *settings = iwd_get_config();
enum security security = network_get_security(network);
bool add_mde = false;
struct erp_cache_entry *erp_cache = NULL;
struct ie_rsn_info bss_info;
uint8_t rsne_buf[256];
struct ie_rsn_info info;
uint8_t *ap_ie;
bool disable_ocv;
enum band_freq band;
memset(&info, 0, sizeof(info));
if (!band_freq_to_channel(bss->frequency, &band))
goto not_supported;
memset(&bss_info, 0, sizeof(bss_info));
scan_bss_get_rsn_info(bss, &bss_info);
if (bss_info.akm_suites & (IE_RSN_AKM_SUITE_FILS_SHA256 |
IE_RSN_AKM_SUITE_FILS_SHA384))
hs->support_fils = true;
/*
* If this network 8021x we might have a set of cached EAP keys. If so
* wiphy may select FILS if supported by the AP.
*/
if (security == SECURITY_8021X && hs->support_fils)
erp_cache = network_get_erp_cache(network);
info.akm_suites = wiphy_select_akm(wiphy, bss, security,
&bss_info, erp_cache != NULL);
/*
* Special case for OWE. With OWE we still need to build up the
* handshake object with AKM/cipher info since OWE does the full 4-way
* handshake. But if this is a non-OWE open network, we can skip this.
*/
if (security == SECURITY_NONE &&
!(info.akm_suites & IE_RSN_AKM_SUITE_OWE))
goto open_network;
if (!info.akm_suites)
goto not_supported;
info.pairwise_ciphers = wiphy_select_cipher(wiphy,
bss_info.pairwise_ciphers);
info.group_cipher = wiphy_select_cipher(wiphy,
bss_info.group_cipher);
if (!info.pairwise_ciphers || !info.group_cipher)
goto not_supported;
/* Management frame protection is explicitly off for OSEN */
if (info.akm_suites & IE_RSN_AKM_SUITE_OSEN) {
info.group_management_cipher =
IE_RSN_CIPHER_SUITE_NO_GROUP_TRAFFIC;
goto build_ie;
}
switch (mfp_setting) {
case 0:
if (band != BAND_FREQ_6_GHZ)
break;
l_error("MFP turned off by [General].ManagementFrameProtection,"
" 6GHz frequencies are disabled");
goto not_supported;
case 1:
info.group_management_cipher =
wiphy_select_cipher(wiphy,
bss_info.group_management_cipher);
info.mfpc = info.group_management_cipher != 0;
if (band != BAND_FREQ_6_GHZ)
break;
if (!info.mfpc)
goto not_supported;
/*
* 802.11ax Section 12.12.2
* The STA shall use management frame protection
* (MFPR=1) when using RSN.
*/
info.mfpr = true;
break;
case 2:
info.group_management_cipher =
wiphy_select_cipher(wiphy,
bss_info.group_management_cipher);
/*
* MFP required on our side, but AP doesn't support MFP
* or cipher mismatch
*/
if (info.group_management_cipher == 0)
goto not_supported;
info.mfpc = true;
info.mfpr = true;
break;
}
if (bss_info.mfpr && !info.mfpc)
goto not_supported;
build_ie:
if (!l_settings_get_bool(settings, "General", "DisableOCV",
&disable_ocv))
disable_ocv = false;
/*
* Obviously do not enable OCV if explicitly disabled or no AP support.
*
* Not obviously hostapd rejects OCV support if MFPC is not enabled.
* This is not really specified by the spec, but we have to work around
* this limitation.
*
* Another limitation is full mac cards. With limited testing it was
* seen that they do not include the OCI in the 4-way handshake yet
* still advertise the capability. Because of this OCV is disabled if
* any offload features are detected (since IWD prefers to use offload).
*
* TODO: For now OCV is disabled if the network is FT capable. This is
* being done until support in the kernel is added to
* automatically include the OCI element for the association
* request.
*/
info.ocvc = !disable_ocv && bss_info.ocvc && info.mfpc &&
!wiphy_can_offload(wiphy) &&
!IE_AKM_IS_FT(info.akm_suites);
/*
* IEEE 802.11-2020 9.4.2.24.4 states extended key IDs can only be used
* with CCMP/GCMP cipher suites. We also only enable support if the AP
* also indicates support.
*/
if (wiphy_supports_ext_key_id(wiphy) && bss_info.extended_key_id &&
IE_CIPHER_IS_GCMP_CCMP(info.pairwise_ciphers))
info.extended_key_id = true;
/* RSN takes priority */
if (bss->rsne) {
ap_ie = bss->rsne;
ie_build_rsne(&info, rsne_buf);
} else if (bss->wpa) {
ap_ie = bss->wpa;
ie_build_wpa(&info, rsne_buf);
} else if (bss->osen) {
ap_ie = bss->osen;
ie_build_osen(&info, rsne_buf);
} else
goto not_supported;
if (!handshake_state_set_authenticator_ie(hs, ap_ie))
goto not_supported;
if (!handshake_state_set_supplicant_ie(hs, rsne_buf))
goto not_supported;
if (IE_AKM_IS_FT(info.akm_suites))
add_mde = true;
/*
* If FILS was chosen, the ERP cache has been verified to exist. Take
* a reference now so it remains valid (in case of expiration) until
* FILS starts.
*/
if (IE_AKM_IS_FILS(hs->akm_suite))
hs->erp_cache = erp_cache;
else if (erp_cache)
erp_cache_put(erp_cache);
open_network:
if (security == SECURITY_NONE)
/* Perform FT association if available */
add_mde = bss->mde_present;
if (add_mde) {
uint8_t mde[5];
/* The MDE advertised by the BSS must be passed verbatim */
mde[0] = IE_TYPE_MOBILITY_DOMAIN;
mde[1] = 3;
memcpy(mde + 2, bss->mde, 3);
handshake_state_set_mde(hs, mde);
}
return 0;
not_supported:
if (erp_cache)
erp_cache_put(erp_cache);
return -ENOTSUP;
}
static struct handshake_state *station_handshake_setup(struct station *station,
struct network *network,
struct scan_bss *bss)
{
struct wiphy *wiphy = station->wiphy;
const struct network_info *info = network_get_info(network);
struct handshake_state *hs;
const struct iovec *vendor_ies;
size_t iov_elems = 0;
struct ie_fils_ip_addr_request_info fils_ip_req;
hs = netdev_handshake_state_new(station->netdev);
handshake_state_set_event_func(hs, station_handshake_event, station);
if (station_build_handshake_rsn(hs, wiphy, network, bss) < 0)
goto not_supported;
handshake_state_set_authenticator_rsnxe(hs, bss->rsnxe);
if (network_handshake_setup(network, bss, hs) < 0)
goto not_supported;
vendor_ies = network_info_get_extra_ies(info, bss, &iov_elems);
handshake_state_set_vendor_ies(hs, vendor_ies, iov_elems);
/*
* It can't hurt to try the FILS IP Address Assignment independent of
* which auth-proto is actually used.
*/
if (station->netconfig && netconfig_get_fils_ip_req(station->netconfig,
&fils_ip_req)) {
hs->fils_ip_req_ie = l_malloc(32);
ie_build_fils_ip_addr_request(&fils_ip_req, hs->fils_ip_req_ie);
}
return hs;
not_supported:
handshake_state_free(hs);
return NULL;
}
static bool new_scan_results(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
station_property_set_scanning(station, false);
if (err)
return false;
station_set_scan_results(station, bss_list, freqs, false);
station_process_owe_transition_networks(station);
station->autoconnect_can_start = true;
station_autoconnect_start(station);
return true;
}
static void periodic_scan_trigger(int err, void *user_data)
{
struct station *station = user_data;
station_property_set_scanning(station, true);
}
static void periodic_scan_stop(struct station *station)
{
uint64_t id = netdev_get_wdev_id(station->netdev);
if (scan_periodic_stop(id))
station_property_set_scanning(station, false);
}
static bool station_needs_hidden_network_scan(struct station *station)
{
if (!known_networks_has_hidden())
return false;
if (station_is_autoconnecting(station))
return true;
return !l_queue_isempty(station->hidden_bss_list_sorted);
}
static struct scan_freq_set *station_get_allowed_freqs(struct station *station)
{
const struct scan_freq_set *supported =
wiphy_get_supported_freqs(station->wiphy);
struct scan_freq_set *allowed = scan_freq_set_clone(supported,
allowed_bands);
if (scan_freq_set_isempty(allowed)) {
scan_freq_set_free(allowed);
allowed = NULL;
}
return allowed;
}
static uint32_t station_scan_trigger(struct station *station,
struct scan_freq_set *freqs,
scan_trigger_func_t triggered,
scan_notify_func_t notify,
scan_destroy_func_t destroy)
{
uint64_t id = netdev_get_wdev_id(station->netdev);
struct scan_parameters params;
memset(&params, 0, sizeof(params));
params.flush = true;
params.freqs = freqs;
if (wiphy_can_randomize_mac_addr(station->wiphy) ||
station->connected_bss ||
station_needs_hidden_network_scan(station)) {
/* If we're connected, HW cannot randomize our MAC */
if (!station->connected_bss)
params.randomize_mac_addr_hint = true;
return scan_active_full(id, &params, triggered, notify,
station, destroy);
}
return scan_passive_full(id, &params, triggered, notify,
station, destroy);
}
static bool station_quick_scan_results(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
station_property_set_scanning(station, false);
if (err)
goto done;
station_set_scan_results(station, bss_list, freqs, false);
station_process_owe_transition_networks(station);
station->autoconnect_can_start = true;
station_autoconnect_start(station);
done:
if (station->state == STATION_STATE_AUTOCONNECT_QUICK)
/*
* If we're still in AUTOCONNECT_QUICK state, then autoconnect
* failed to find any candidates. Transition to AUTOCONNECT_FULL
*/
station_enter_state(station, STATION_STATE_AUTOCONNECT_FULL);
return err == 0;
}
static void station_quick_scan_triggered(int err, void *user_data)
{
struct station *station = user_data;
if (err < 0) {
l_debug("Quick scan trigger failed: %i", err);
station_enter_state(station, STATION_STATE_AUTOCONNECT_FULL);
return;
}
l_debug("Quick scan triggered for %s",
netdev_get_name(station->netdev));
station_property_set_scanning(station, true);
}
static void station_quick_scan_destroy(void *userdata)
{
struct station *station = userdata;
station->quick_scan_id = 0;
}
static int station_quick_scan_trigger(struct station *station)
{
_auto_(scan_freq_set_free) struct scan_freq_set *known_freq_set = NULL;
_auto_(scan_freq_set_free) struct scan_freq_set *allowed = NULL;
bool known_6ghz;
if (wiphy_regdom_is_updating(station->wiphy)) {
l_debug("regdom is updating, delaying quick scan");
return -EAGAIN;
}
known_freq_set = known_networks_get_recent_frequencies(
STATION_RECENT_NETWORK_LIMIT,
STATION_RECENT_FREQS_LIMIT);
if (!known_freq_set)
return -ENODATA;
known_6ghz = scan_freq_set_get_bands(known_freq_set) & BAND_FREQ_6_GHZ;
/*
* This means IWD has previously connected to a 6GHz AP before, but now
* the regulatory domain disallows 6GHz likely caused by a reboot, the
* firmware going down, or a regulatory update. The only way to
* re-enable 6GHz is to get enough beacons via scanning for the firmware
* to set the regulatory domain. A quick scan is very unlikely to do
* this since its so limited, so return an error which will fall back to
* full autoconnect.
*/
if (wiphy_band_is_disabled(station->wiphy, BAND_FREQ_6_GHZ) == 1 &&
wiphy_country_is_unknown(station->wiphy) &&
known_6ghz)
return -ENOTSUP;
allowed = station_get_allowed_freqs(station);
if (L_WARN_ON(!allowed))
return -ENOTSUP;
scan_freq_set_constrain(known_freq_set, allowed);
if (scan_freq_set_isempty(known_freq_set))
return -ENOTSUP;
station->quick_scan_id = station_scan_trigger(station,
known_freq_set,
station_quick_scan_triggered,
station_quick_scan_results,
station_quick_scan_destroy);
if (!station->quick_scan_id)
return -EIO;
return 0;
}
static const char *station_state_to_string(enum station_state state)
{
switch (state) {
case STATION_STATE_DISCONNECTED:
return "disconnected";
case STATION_STATE_AUTOCONNECT_QUICK:
return "autoconnect_quick";
case STATION_STATE_AUTOCONNECT_FULL:
return "autoconnect_full";
case STATION_STATE_CONNECTING:
return "connecting";
case STATION_STATE_CONNECTING_AUTO:
return "connecting (auto)";
case STATION_STATE_CONNECTED:
return "connected";
case STATION_STATE_DISCONNECTING:
return "disconnecting";
case STATION_STATE_ROAMING:
return "roaming";
case STATION_STATE_FT_ROAMING:
return "ft-roaming";
case STATION_STATE_FW_ROAMING:
return "fw-roaming";
case STATION_STATE_NETCONFIG:
return "connecting (netconfig)";
}
return "invalid";
}
static void station_set_evict_nocarrier(struct station *station, bool value)
{
char *v = value ? "1" : "0";
if (supports_arp_evict_nocarrier)
sysfs_write_ipv4_setting(netdev_get_name(station->netdev),
"arp_evict_nocarrier", v);
if (supports_ndisc_evict_nocarrier)
sysfs_write_ipv6_setting(netdev_get_name(station->netdev),
"ndisc_evict_nocarrier", v);
}
/*
* Handles dropping ARP (IPv4) and neighbor advertisements (IPv6) settings.
*/
static void station_set_drop_neighbor_discovery(struct station *station,
bool value)
{
char *v = value ? "1" : "0";
if (supports_drop_gratuitous_arp)
sysfs_write_ipv4_setting(netdev_get_name(station->netdev),
"drop_gratuitous_arp", v);
if (supports_drop_unsolicited_na)
sysfs_write_ipv6_setting(netdev_get_name(station->netdev),
"drop_unsolicited_na", v);
}
static void station_set_drop_unicast_l2_multicast(struct station *station,
bool value)
{
char *v = value ? "1" : "0";
if (supports_ipv4_drop_unicast_in_l2_multicast)
sysfs_write_ipv4_setting(netdev_get_name(station->netdev),
"drop_unicast_in_l2_multicast", v);
if (supports_ipv6_drop_unicast_in_l2_multicast)
sysfs_write_ipv6_setting(netdev_get_name(station->netdev),
"drop_unicast_in_l2_multicast", v);
}
static void station_signal_agent_notify(struct station *station);
static void station_enter_state(struct station *station,
enum station_state state)
{
uint64_t id = netdev_get_wdev_id(station->netdev);
struct l_dbus *dbus = dbus_get_bus();
bool disconnected;
int ret;
iwd_notice(IWD_NOTICE_STATE, "old: %s, new: %s",
station_state_to_string(station->state),
station_state_to_string(state));
station_debug_event(station, station_state_to_string(state));
disconnected = !station_is_busy(station);
if ((disconnected && state > STATION_STATE_AUTOCONNECT_FULL) ||
(!disconnected && state != station->state))
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "State");
station->state = state;
switch (state) {
case STATION_STATE_AUTOCONNECT_QUICK:
ret = station_quick_scan_trigger(station);
if (ret == 0 || ret == -EAGAIN)
break;
station->state = STATION_STATE_AUTOCONNECT_FULL;
/* Fall through */
case STATION_STATE_AUTOCONNECT_FULL:
scan_periodic_start(id, periodic_scan_trigger,
new_scan_results, station);
break;
case STATION_STATE_CONNECTING:
case STATION_STATE_CONNECTING_AUTO:
/* Refresh the ordered network list */
network_rank_update(station->connected_network, true);
l_queue_remove(station->networks_sorted,
station->connected_network);
l_queue_insert(station->networks_sorted,
station->connected_network,
network_rank_compare, NULL);
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "ConnectedNetwork");
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "ConnectedAccessPoint");
l_dbus_property_changed(dbus,
network_get_path(station->connected_network),
IWD_NETWORK_INTERFACE, "Connected");
if (station->signal_agent)
station_signal_agent_notify(station);
periodic_scan_stop(station);
break;
case STATION_STATE_CONNECTED:
l_dbus_object_add_interface(dbus,
netdev_get_path(station->netdev),
IWD_STATION_DIAGNOSTIC_INTERFACE,
station);
periodic_scan_stop(station);
station_set_evict_nocarrier(station, true);
/*
* Hotspot Specification 2.0 - Section 6.5
*
* " - Shall drop all received {gratuitous ARP, unsolicited
* Neighbor Advertisement} messages when the Proxy ARP field
* is set to 1 in the Extended Capabilities element of the
* serving AP.
*
* - When the serving AP transmits frames containing an HS2.0
* Indication element in which the value of the DGAF Disable
* bit subfield is set to 0, the mobile device should
* discard all received unicast IP packets that were
* decrypted using the GTK"
*/
if (station->connected_bss->proxy_arp)
station_set_drop_neighbor_discovery(station, true);
if (station->connected_bss->hs20_dgaf_disable)
station_set_drop_unicast_l2_multicast(station, true);
break;
case STATION_STATE_DISCONNECTED:
periodic_scan_stop(station);
station_set_evict_nocarrier(station, true);
station_set_drop_neighbor_discovery(station, false);
station_set_drop_unicast_l2_multicast(station, false);
if (station->affinity_watch) {
l_dbus_remove_watch(dbus_get_bus(),
station->affinity_watch);
station->affinity_watch = 0;
}
break;
case STATION_STATE_DISCONNECTING:
case STATION_STATE_NETCONFIG:
break;
case STATION_STATE_ROAMING:
case STATION_STATE_FT_ROAMING:
case STATION_STATE_FW_ROAMING:
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "ConnectedAccessPoint");
if (station->affinity_watch) {
l_dbus_remove_watch(dbus_get_bus(),
station->affinity_watch);
station->affinity_watch = 0;
}
station_set_evict_nocarrier(station, false);
break;
}
WATCHLIST_NOTIFY(&station->state_watches,
station_state_watch_func_t, station->state);
}
enum station_state station_get_state(struct station *station)
{
return station->state;
}
uint32_t station_add_state_watch(struct station *station,
station_state_watch_func_t func,
void *user_data,
station_destroy_func_t destroy)
{
return watchlist_add(&station->state_watches, func, user_data, destroy);
}
bool station_remove_state_watch(struct station *station, uint32_t id)
{
return watchlist_remove(&station->state_watches, id);
}
uint32_t station_add_event_watch(station_event_watch_func_t func,
void *user_data,
station_destroy_func_t destroy)
{
return watchlist_add(&event_watches, func, user_data, destroy);
}
void station_remove_event_watch(uint32_t id)
{
watchlist_remove(&event_watches, id);
}
bool station_set_autoconnect(struct station *station, bool autoconnect)
{
if (station->autoconnect == autoconnect)
return true;
station->autoconnect = autoconnect;
if (station->state == STATION_STATE_DISCONNECTED && autoconnect)
station_enter_state(station, STATION_STATE_AUTOCONNECT_QUICK);
if (station_is_autoconnecting(station) && !autoconnect)
station_enter_state(station, STATION_STATE_DISCONNECTED);
if (iwd_is_developer_mode())
l_dbus_property_changed(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_DEBUG_INTERFACE, "AutoConnect");
return true;
}
bool station_get_autoconnect(struct station *station)
{
return station->autoconnect;
}
static void station_roam_state_clear(struct station *station)
{
l_debug("%u", netdev_get_ifindex(station->netdev));
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
station->preparing_roam = false;
station->roam_scan_full = false;
station->signal_low = false;
station->netconfig_after_roam = false;
station->last_roam_scan = 0;
if (station->roam_scan_id)
scan_cancel(netdev_get_wdev_id(station->netdev),
station->roam_scan_id);
if (station->roam_freqs) {
scan_freq_set_free(station->roam_freqs);
station->roam_freqs = NULL;
}
l_queue_clear(station->roam_bss_list, l_free);
ft_clear_authentications(netdev_get_ifindex(station->netdev));
if (station->ft_work.id)
wiphy_radio_work_done(station->wiphy, station->ft_work.id);
}
static void station_reset_connection_state(struct station *station)
{
struct network *network = station->connected_network;
struct l_dbus *dbus = dbus_get_bus();
l_debug("%u", netdev_get_ifindex(station->netdev));
if (!network)
return;
station_roam_state_clear(station);
if (station->netconfig)
netconfig_reset(station->netconfig);
/* Refresh the ordered network list */
network_rank_update(station->connected_network, false);
l_queue_remove(station->networks_sorted, station->connected_network);
l_queue_insert(station->networks_sorted, station->connected_network,
network_rank_compare, NULL);
station->connected_bss = NULL;
station->connected_network = NULL;
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "ConnectedNetwork");
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "ConnectedAccessPoint");
l_dbus_property_changed(dbus, network_get_path(network),
IWD_NETWORK_INTERFACE, "Connected");
l_dbus_object_remove_interface(dbus, netdev_get_path(station->netdev),
IWD_STATION_DIAGNOSTIC_INTERFACE);
/*
* Perform this step last since calling network_disconnected() might
* result in the removal of the network (for example if provisioning
* a new hidden network fails with an incorrect password).
*/
if (station->state == STATION_STATE_CONNECTED ||
station->state == STATION_STATE_CONNECTING ||
station->state == STATION_STATE_CONNECTING_AUTO ||
station->state == STATION_STATE_NETCONFIG ||
station_is_roaming(station))
network_disconnected(network);
}
static void station_disassociated(struct station *station)
{
l_debug("%u", netdev_get_ifindex(station->netdev));
station_reset_connection_state(station);
station_enter_state(station, STATION_STATE_DISCONNECTED);
if (station->autoconnect)
station_enter_state(station, STATION_STATE_AUTOCONNECT_QUICK);
}
static void station_roam_timeout_rearm(struct station *station, int seconds);
static int station_roam_scan(struct station *station,
struct scan_freq_set *freq_set);
static bool is_freq_band_supported(struct station *station, uint32_t freq,
enum band_freq band)
{
const struct band_freq_attrs *attr;
if (!(band & wiphy_get_supported_bands(station->wiphy)))
return false;
/* Skip if frequency is not supported or disabled */
attr = wiphy_get_frequency_info(station->wiphy, freq);
if (!attr || attr->disabled)
return false;
return true;
}
/*
* Some Cisco APs report all operating class values as 0 in the Neighbor
* Report Responses. Historically we could be very sure what band the
* channel was associated with since there was no overlap between 2.4
* and 5GHz. With the addition of 6GHz this becomes more difficult as
* the 6GHz channel range overlaps both 2.4 and 5ghz.
*
* To cover all 3 bands, calculate a frequency for each and see what sticks.
*/
static void station_parse_zero_oper_class(struct station *station,
struct ie_neighbor_report_info *info,
struct scan_freq_set *freq_set)
{
uint32_t freq_2g;
uint32_t freq_5g;
uint32_t freq_6g;
freq_2g = band_channel_to_freq(info->channel_num, BAND_FREQ_2_4_GHZ);
freq_5g = band_channel_to_freq(info->channel_num, BAND_FREQ_5_GHZ);
freq_6g = band_channel_to_freq(info->channel_num, BAND_FREQ_6_GHZ);
if (!freq_2g && !freq_5g && !freq_6g) {
l_debug("Ignored: 0 oper class with an unusual "
"channel number %u", info->channel_num);
return;
}
if (freq_2g && is_freq_band_supported(station, freq_2g,
BAND_FREQ_2_4_GHZ)) {
l_debug("adding frequency %u from invalid oper class", freq_2g);
scan_freq_set_add(freq_set, freq_2g);
}
if (freq_5g && is_freq_band_supported(station, freq_5g,
BAND_FREQ_5_GHZ)) {
l_debug("adding frequency %u from invalid oper class", freq_5g);
scan_freq_set_add(freq_set, freq_5g);
}
if (freq_6g && is_freq_band_supported(station, freq_6g,
BAND_FREQ_6_GHZ)) {
l_debug("adding frequency %u from invalid oper class", freq_6g);
scan_freq_set_add(freq_set, freq_6g);
}
}
static void station_add_neighbor_report_freqs(struct station *station,
struct ie_neighbor_report_info *info,
struct scan_freq_set *freq_set)
{
enum band_freq band;
uint32_t freq;
const uint8_t *country = station->connected_bss->cc_present ?
station->connected_bss->cc : NULL;
if (info->oper_class == 0) {
station_parse_zero_oper_class(station, info, freq_set);
return;
} else {
band = band_oper_class_to_band(country, info->oper_class);
if (!band) {
l_debug("Ignored: unsupported oper class");
return;
}
}
freq = band_channel_to_freq(info->channel_num, band);
if (!freq) {
l_debug("Ignored: unsupported channel");
return;
}
/* Skip if the band/frequency is not supported */
if (!is_freq_band_supported(station, freq, band))
return;
scan_freq_set_add(freq_set, freq);
}
static void parse_neighbor_report(struct station *station,
const uint8_t *reports,
size_t reports_len,
struct scan_freq_set **set)
{
struct ie_tlv_iter iter;
struct scan_freq_set *freq_set_md, *freq_set_no_md;
uint32_t current_freq = station->connected_bss->frequency;
struct handshake_state *hs = netdev_get_handshake(station->netdev);
freq_set_md = scan_freq_set_new();
freq_set_no_md = scan_freq_set_new();
ie_tlv_iter_init(&iter, reports, reports_len);
/* First see if any of the reports contain the MD bit set */
while (ie_tlv_iter_next(&iter)) {
struct ie_neighbor_report_info info;
if (ie_tlv_iter_get_tag(&iter) != IE_TYPE_NEIGHBOR_REPORT)
continue;
if (ie_parse_neighbor_report(&iter, &info) < 0)
continue;
l_debug("Neighbor report received for %s: ch %i "
"(oper class %i), %s",
util_address_to_string(info.addr),
(int) info.channel_num, (int) info.oper_class,
info.md ? "MD set" : "MD not set");
if (!memcmp(info.addr,
station->connected_bss->addr, ETH_ALEN)) {
/*
* If this report is for the current AP, don't add
* it to any of the lists yet. We will need to scan
* its channel because it may still be the best ranked
* or the only visible AP.
*/
continue;
}
station_add_neighbor_report_freqs(station, &info,
info.md && hs->mde ?
freq_set_md : freq_set_no_md);
}
/*
* If there are neighbor reports with the MD bit set then the bit
* is probably valid so scan only the frequencies of the neighbors
* with that bit set, which will allow us to use Fast Transition.
* Some APs, such as those based on hostapd do not set the MD bit
* even if the neighbor is within the MD.
*
* In any case we only select the frequencies here and will check
* the IEs in the scan results as the authoritative information
* on whether we can use Fast Transition, and rank BSSes based on
* that.
*
* TODO: possibly save the neighbors from outside the MD and if
* none of the ones in the MD end up working, try a non-FT
* transition to those neighbors. We should be using a
* blacklisting mechanism (for both initial connection and
* transitions) so that cound_md would not count the
* BSSes already used and when it goes down to 0 we'd
* automatically fall back to the non-FT candidates and then to
* full scan.
*/
if (!scan_freq_set_isempty(freq_set_md)) {
scan_freq_set_add(freq_set_md, current_freq);
*set = freq_set_md;
scan_freq_set_free(freq_set_no_md);
} else if (!scan_freq_set_isempty(freq_set_no_md)) {
scan_freq_set_add(freq_set_no_md, current_freq);
*set = freq_set_no_md;
scan_freq_set_free(freq_set_md);
} else {
scan_freq_set_free(freq_set_no_md);
scan_freq_set_free(freq_set_md);
*set = NULL;
}
}
static void station_early_neighbor_report_cb(struct netdev *netdev, int err,
const uint8_t *reports,
size_t reports_len,
void *user_data)
{
struct station *station = user_data;
if (err == -ENODEV)
return;
l_debug("ifindex: %u, error: %d(%s)",
netdev_get_ifindex(station->netdev),
err, err < 0 ? strerror(-err) : "");
if (!reports || err)
return;
parse_neighbor_report(station, reports, reports_len,
&station->roam_freqs);
}
static bool station_can_fast_transition(struct station *station,
struct handshake_state *hs,
struct scan_bss *bss)
{
uint16_t mdid;
if (!hs->mde)
return false;
if (ie_parse_mobility_domain_from_data(hs->mde, hs->mde[1] + 2,
&mdid, NULL, NULL) < 0)
return false;
if (!(bss->mde_present && l_get_le16(bss->mde) == mdid))
return false;
if (hs->supplicant_ie != NULL) {
struct ie_rsn_info rsn_info;
if (!IE_AKM_IS_FT(hs->akm_suite))
return false;
if (scan_bss_get_rsn_info(bss, &rsn_info) < 0)
return false;
if (!IE_AKM_IS_FT(rsn_info.akm_suites))
return false;
}
/*
* FT-over-Air in its current form relies on CMD_REMAIN_ON_CHANNEL. Some
* drivers do not support this so only allow over-DS if this is the case
*/
if (!(hs->mde[4] & 1) &&
!wiphy_supports_cmd_offchannel(station->wiphy)) {
l_debug("FT-over-Air needs offchannel, using reassociation");
return false;
}
return true;
}
static void station_disconnect_on_error_cb(struct netdev *netdev, bool success,
void *user_data)
{
struct station *station = user_data;
bool continue_autoconnect;
station_enter_state(station, STATION_STATE_DISCONNECTED);
continue_autoconnect = station->state == STATION_STATE_CONNECTING_AUTO;
if (continue_autoconnect) {
if (station_autoconnect_next(station) < 0) {
l_debug("Nothing left on autoconnect list");
station_enter_state(station,
STATION_STATE_AUTOCONNECT_FULL);
}
return;
}
if (station->autoconnect)
station_enter_state(station, STATION_STATE_AUTOCONNECT_QUICK);
}
static void station_netconfig_event_handler(enum netconfig_event event,
void *user_data)
{
struct station *station = user_data;
switch (event) {
case NETCONFIG_EVENT_CONNECTED:
station_enter_state(station, STATION_STATE_CONNECTED);
break;
case NETCONFIG_EVENT_FAILED:
if (station->connect_pending) {
struct l_dbus_message *reply = dbus_error_failed(
station->connect_pending);
dbus_pending_reply(&station->connect_pending, reply);
}
if (station->state == STATION_STATE_NETCONFIG)
network_connect_failed(station->connected_network,
false);
netdev_disconnect(station->netdev,
station_disconnect_on_error_cb,
station);
station_reset_connection_state(station);
station_enter_state(station, STATION_STATE_DISCONNECTING);
break;
default:
l_error("station: Unsupported netconfig event: %d.", event);
break;
}
}
static bool netconfig_after_roam(struct station *station)
{
const struct network *network = station_get_connected_network(station);
/* Netconfig was reset which frees all settings, reload now */
if (!netconfig_load_settings(station->netconfig,
network_get_settings(network)))
return false;
if (!netconfig_configure(station->netconfig,
station_netconfig_event_handler,
station))
return false;
station_enter_state(station, STATION_STATE_NETCONFIG);
return true;
}
static void station_roamed(struct station *station)
{
station->roam_scan_full = false;
/*
* Schedule another roaming attempt in case the signal continues to
* remain low. A subsequent high signal notification will cancel it.
*/
if (station->signal_low)
station_roam_timeout_rearm(station, roam_retry_interval);
if (station->netconfig)
netconfig_reconfigure(station->netconfig,
!supports_arp_evict_nocarrier);
if (station->roam_freqs) {
scan_freq_set_free(station->roam_freqs);
station->roam_freqs = NULL;
}
if (station->connected_bss->cap_rm_neighbor_report) {
if (netdev_neighbor_report_req(station->netdev,
station_early_neighbor_report_cb) < 0)
l_warn("Could not request neighbor report");
}
l_queue_clear(station->roam_bss_list, l_free);
/* Re-enable netconfig if it never finished on the last BSS */
if (station->netconfig_after_roam) {
station->netconfig_after_roam = false;
L_WARN_ON(!netconfig_after_roam(station));
} else
station_enter_state(station, STATION_STATE_CONNECTED);
}
static void station_roam_retry(struct station *station)
{
/*
* If we're still connected to the old BSS, only clear preparing_roam
* and reattempt in 60 seconds if signal level is still low at that
* time.
*/
station->preparing_roam = false;
station->roam_scan_full = false;
station->ap_directed_roaming = false;
if (station->signal_low)
station_roam_timeout_rearm(station, roam_retry_interval);
}
static void station_roam_failed(struct station *station)
{
l_debug("%u", netdev_get_ifindex(station->netdev));
l_queue_clear(station->roam_bss_list, l_free);
/*
* If we attempted a reassociation or a fast transition, and ended up
* here then we are now disconnected.
*/
if (station_is_roaming(station)) {
station_disassociated(station);
return;
}
/* Re-enable netconfig if needed, even on a failed roam */
if (station->netconfig_after_roam) {
station->netconfig_after_roam = false;
L_WARN_ON(!netconfig_after_roam(station));
}
/*
* We were told by the AP to roam, but failed. Try ourselves or
* wait for the AP to tell us to roam again
*/
if (station->ap_directed_roaming)
goto delayed_retry;
/*
* If we tried a limited scan, failed and the signal is still low,
* repeat with a full scan right away
*/
if (station->signal_low && !station->roam_scan_full) {
/*
* Since we're re-using roam_scan_id, explicitly cancel
* the scan here, so that the destroy callback is not called
* after the return of this function
*/
scan_cancel(netdev_get_wdev_id(station->netdev),
station->roam_scan_id);
if (!station_roam_scan(station, NULL))
return;
}
delayed_retry:
station_roam_retry(station);
}
static void station_reassociate_cb(struct netdev *netdev,
enum netdev_result result,
void *event_data,
void *user_data)
{
struct station *station = user_data;
l_debug("%u, result: %d", netdev_get_ifindex(station->netdev), result);
if (station->state != STATION_STATE_ROAMING &&
station->state != STATION_STATE_FT_ROAMING)
return;
if (result == NETDEV_RESULT_OK)
station_roamed(station);
else
station_roam_failed(station);
}
static void station_netdev_event(struct netdev *netdev, enum netdev_event event,
void *event_data, void *user_data);
static int station_transition_reassociate(struct station *station,
struct scan_bss *bss,
struct handshake_state *new_hs)
{
int ret;
ret = netdev_reassociate(station->netdev, bss, station->connected_bss,
new_hs, station_netdev_event,
station_reassociate_cb, station);
if (ret < 0)
return ret;
l_debug("");
station->connected_bss = bss;
station->preparing_roam = false;
station_enter_state(station, STATION_STATE_ROAMING);
return 0;
}
static bool bss_match_bssid(const void *a, const void *b)
{
const struct scan_bss *bss = a;
const uint8_t *bssid = b;
return !memcmp(bss->addr, bssid, sizeof(bss->addr));
}
static void station_preauthenticate_cb(struct netdev *netdev,
enum netdev_result result,
const uint8_t *pmk, void *user_data)
{
struct station *station = user_data;
struct network *connected = station->connected_network;
struct scan_bss *bss;
struct handshake_state *new_hs;
l_debug("%u, result: %d", netdev_get_ifindex(station->netdev), result);
if (!station->preparing_roam || result == NETDEV_RESULT_ABORTED)
return;
bss = network_bss_find_by_addr(station->connected_network,
station->preauth_bssid);
if (!bss) {
l_error("Roam target BSS not found");
station_roam_failed(station);
return;
}
new_hs = station_handshake_setup(station, connected, bss);
if (!new_hs) {
l_error("station_handshake_setup failed");
station_roam_failed(station);
return;
}
if (result == NETDEV_RESULT_OK) {
uint8_t pmkid[16];
uint8_t rsne_buf[300];
struct ie_rsn_info rsn_info;
handshake_state_set_pmk(new_hs, pmk, 32);
handshake_state_set_authenticator_address(new_hs,
station->preauth_bssid);
handshake_state_set_supplicant_address(new_hs,
netdev_get_address(station->netdev));
/*
* Rebuild the RSNE to include the negotiated PMKID. Note
* supplicant_ie can't be a WPA IE here, including because
* the WPA IE doesn't have a capabilities field and
* target_rsne->preauthentication would have been false in
* station_transition_start.
*/
ie_parse_rsne_from_data(new_hs->supplicant_ie,
new_hs->supplicant_ie[1] + 2,
&rsn_info);
/*
* IEEE 802.11 Section 12.7.1.3:
*
* "When the PMKID is calculated for the PMKSA as part of
* preauthentication, the AKM has not yet been negotiated.
* In this case, the HMAC-SHA-1 based derivation is used for
* the PMKID calculation."
*/
handshake_state_get_pmkid(new_hs, pmkid, L_CHECKSUM_SHA1);
rsn_info.num_pmkids = 1;
rsn_info.pmkids = pmkid;
ie_build_rsne(&rsn_info, rsne_buf);
handshake_state_set_supplicant_ie(new_hs, rsne_buf);
}
if (station_transition_reassociate(station, bss, new_hs) < 0) {
handshake_state_free(new_hs);
station_roam_failed(station);
}
}
static void station_transition_start(struct station *station);
static bool station_ft_work_ready(struct wiphy_radio_work_item *item)
{
struct station *station = l_container_of(item, struct station, ft_work);
_auto_(l_free) struct roam_bss *rbss = l_queue_pop_head(
station->roam_bss_list);
struct scan_bss *bss;
int ret;
/* Very unlikely, but the BSS could have gone away */
bss = network_bss_find_by_addr(station->connected_network, rbss->addr);
if (!bss)
goto try_next;
ret = ft_handshake_setup(netdev_get_ifindex(station->netdev),
bss->addr);
switch (ret) {
case MMPDU_STATUS_CODE_INVALID_PMKID:
/*
* Re-insert removing FT from the ranking (scan_bss does not
* take into account FT, so we can use that rank directly).
* If the BSS is still the best reassociation will be used,
* otherwise we'll try more FT candidates that are better ranked
*/
rbss->rank = bss->rank;
rbss->ft_failed = true;
l_debug("Re-inserting BSS "MAC" using reassociation, rank: %u",
MAC_STR(rbss->addr), rbss->rank);
l_queue_insert(station->roam_bss_list, rbss,
roam_bss_rank_compare, NULL);
station_debug_event(station, "ft-fallback-to-reassoc");
iwd_notice(IWD_NOTICE_FT_ROAM_FAILED, "status: %d",
MMPDU_STATUS_CODE_INVALID_PMKID);
station_transition_start(station);
l_steal_ptr(rbss);
break;
case -ENOENT:
station_debug_event(station, "ft-roam-failed");
iwd_notice(IWD_NOTICE_FT_ROAM_FAILED,
"status: authentication timeout");
try_next:
station_transition_start(station);
break;
case 0:
ret = netdev_ft_reassociate(station->netdev, bss,
station->connected_bss,
station_netdev_event,
station_reassociate_cb, station);
if (ret < 0)
goto disassociate;
station->connected_bss = bss;
station->preparing_roam = false;
station_enter_state(station, STATION_STATE_FT_ROAMING);
break;
case -EINVAL:
/*
* Likely an impossible situation, but since ft_handshake_setup
* rederived the handshake keys we can't do anything but
* disconnect.
*/
disassociate:
station_disassociated(station);
break;
default:
if (ret > 0) {
iwd_notice(IWD_NOTICE_FT_ROAM_FAILED, "status: %d", ret);
goto try_next;
}
station_roam_failed(station);
break;
}
return true;
}
static const struct wiphy_radio_work_item_ops ft_work_ops = {
.do_work = station_ft_work_ready,
};
static bool station_fast_transition(struct station *station,
struct scan_bss *bss)
{
struct handshake_state *hs = netdev_get_handshake(station->netdev);
struct network *connected = station->connected_network;
const struct network_info *info = network_get_info(connected);
const struct iovec *vendor_ies;
size_t iov_elems = 0;
/* Rebuild handshake RSN for target AP */
if (station_build_handshake_rsn(hs, station->wiphy,
station->connected_network, bss) < 0)
return false;
/* Reset the vendor_ies in case they're different */
vendor_ies = network_info_get_extra_ies(info, bss, &iov_elems);
handshake_state_set_vendor_ies(hs, vendor_ies, iov_elems);
if (station->roam_trigger_timeout) {
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
}
/* Both ft_action/ft_authenticate will gate the associate work item */
if ((hs->mde[4] & 1)) {
ft_action(netdev_get_ifindex(station->netdev),
station->connected_bss->frequency, bss);
goto done;
}
station_debug_event(station, "ft-authenticating");
if (station->connected_bss->frequency == bss->frequency) {
ft_authenticate_onchannel(netdev_get_ifindex(station->netdev),
bss);
goto done;
}
ft_authenticate(netdev_get_ifindex(station->netdev), bss);
done:
if (station->ft_work.id)
wiphy_radio_work_reschedule(station->wiphy, &station->ft_work);
else
wiphy_radio_work_insert(station->wiphy, &station->ft_work,
WIPHY_WORK_PRIORITY_CONNECT,
&ft_work_ops);
return true;
}
static bool station_try_next_transition(struct station *station,
struct scan_bss *bss,
bool no_ft)
{
struct handshake_state *hs = netdev_get_handshake(station->netdev);
struct network *connected = station->connected_network;
enum security security = network_get_security(connected);
struct handshake_state *new_hs;
struct ie_rsn_info cur_rsne, target_rsne;
iwd_notice(IWD_NOTICE_ROAM_INFO, "bss: "MAC", signal: %d, load: %d/255",
MAC_STR(bss->addr),
bss->signal_strength / 100,
bss->utilization);
/* Reset AP roam flag, at this point the roaming behaves the same */
station->ap_directed_roaming = false;
/* Can we use Fast Transition? */
if (station_can_fast_transition(station, hs, bss) && !no_ft)
return station_fast_transition(station, bss);
/* Non-FT transition */
/*
* FT not available, we can try preauthentication if available.
* 802.11-2012 section 11.5.9.2:
* "A STA shall not use preauthentication within the same mobility
* domain if AKM suite type 00-0F-AC:3 or 00-0F-AC:4 is used in
* the current association."
*/
if (security == SECURITY_8021X &&
scan_bss_get_rsn_info(station->connected_bss,
&cur_rsne) >= 0 &&
scan_bss_get_rsn_info(bss, &target_rsne) >= 0 &&
cur_rsne.preauthentication &&
target_rsne.preauthentication) {
/*
* Both the current and the target AP support
* pre-authentication and we're using 8021x authentication so
* attempt to pre-authenticate and reassociate afterwards.
* If the pre-authentication fails or times out we simply
* won't supply any PMKID when reassociating.
* Remain in the preparing_roam state.
*/
memcpy(station->preauth_bssid, bss->addr, ETH_ALEN);
if (netdev_preauthenticate(station->netdev, bss,
station_preauthenticate_cb,
station) >= 0)
return true;
}
new_hs = station_handshake_setup(station, connected, bss);
if (!new_hs) {
l_error("station_handshake_setup failed in reassociation");
return false;
}
if (station_transition_reassociate(station, bss, new_hs) < 0) {
handshake_state_free(new_hs);
return false;
}
return true;
}
static void station_transition_start(struct station *station)
{
struct roam_bss *rbss;
bool roaming = false;
bool connected = (station->state == STATION_STATE_CONNECTED);
/*
* For each failed attempt pop the BSS leaving the head of the queue
* with the current roam candidate.
*/
while ((rbss = l_queue_peek_head(station->roam_bss_list))) {
struct scan_bss *bss = network_bss_find_by_addr(
station->connected_network, rbss->addr);
if (L_WARN_ON(!bss))
continue;
roaming = station_try_next_transition(station, bss,
rbss->ft_failed);
if (roaming)
break;
l_queue_pop_head(station->roam_bss_list);
l_free(rbss);
}
if (!roaming) {
station_roam_failed(station);
return;
}
/*
* Netconfig could potentially be running and not completed yet. We
* still should roam in this case but need to restart netconfig once the
* roam is finished.
*/
if (station->netconfig && !connected) {
netconfig_reset(station->netconfig);
station->netconfig_after_roam = true;
}
}
static void station_roam_scan_triggered(int err, void *user_data)
{
struct station *station = user_data;
if (err) {
station_roam_failed(station);
return;
}
station_debug_event(station, "roam-scan-triggered");
iwd_notice(IWD_NOTICE_ROAM_SCAN);
/*
* Do not update the Scanning property as we won't be updating the
* list of networks.
*/
}
static void station_update_roam_bss(struct station *station,
struct scan_bss *bss)
{
struct network *network = station->connected_network;
struct scan_bss *old =
l_queue_remove_if(station->bss_list, bss_match, bss);
network_bss_update(network, bss);
station_register_bss(network, bss);
l_queue_push_tail(station->bss_list, bss);
if (old)
scan_bss_free(old);
}
static bool station_roam_scan_notify(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
struct network *network = station->connected_network;
struct handshake_state *hs = netdev_get_handshake(station->netdev);
struct scan_bss *current_bss = station->connected_bss;
struct scan_bss *bss;
double cur_bss_rank = 0.0;
static const double RANK_FT_FACTOR = 1.3;
uint16_t mdid;
enum security orig_security, security;
if (err) {
station_roam_failed(station);
return false;
}
/*
* Do not call station_set_scan_results because this may have been
* a partial scan. We could at most update the current networks' BSS
* list in its station->networks entry.
*/
orig_security = network_get_security(network);
if (hs->mde)
ie_parse_mobility_domain_from_data(hs->mde, hs->mde[1] + 2,
&mdid, NULL, NULL);
/*
* Find the current BSS rank, use the updated result if it exists. If
* this is an AP roam keep the current rank as zero to force the roam
* to occur.
*/
bss = l_queue_find(bss_list, bss_match_bssid, current_bss->addr);
if (bss && !station->ap_directed_roaming) {
cur_bss_rank = bss->rank;
if (hs->mde && bss->mde_present && l_get_le16(bss->mde) == mdid)
cur_bss_rank *= RANK_FT_FACTOR;
}
/*
* BSSes in the bss_list come already ranked with their initial
* association preference rank value. We only need to add preference
* for BSSes that are within the FT Mobility Domain so as to favor
* Fast Roaming, if it is supported.
*/
l_debug("Current BSS '%s' with SSID: %s",
util_address_to_string(current_bss->addr),
util_ssid_to_utf8(current_bss->ssid_len, current_bss->ssid));
/*
* Reverse now so the known frequency list gets updated in the correct
* order (via network_bss_update).
*/
l_queue_reverse(bss_list);
while ((bss = l_queue_pop_head(bss_list))) {
double rank;
struct roam_bss *rbss;
station_print_scan_bss(bss);
/* Skip the BSS we are connected to */
if (!memcmp(bss->addr, station->connected_bss->addr, 6))
goto next;
/* Skip result if it is not part of the ESS */
if (bss->ssid_len != hs->ssid_len ||
memcmp(bss->ssid, hs->ssid, hs->ssid_len))
goto next;
if (scan_bss_get_security(bss, &security) < 0)
goto next;
if (security != orig_security)
goto next;
if (network_can_connect_bss(network, bss) < 0)
goto next;
if (blacklist_contains_bss(bss->addr))
goto next;
rank = bss->rank;
if (hs->mde && bss->mde_present && l_get_le16(bss->mde) == mdid)
rank *= RANK_FT_FACTOR;
if (rank <= cur_bss_rank)
goto next;
/*
* We need to update/add any potential roam candidate so
* station/network know it exists.
*/
station_update_roam_bss(station, bss);
rbss = roam_bss_from_scan_bss(bss, rank);
l_queue_insert(station->roam_bss_list, rbss,
roam_bss_rank_compare, NULL);
continue;
next:
scan_bss_free(bss);
}
l_queue_destroy(bss_list, NULL);
/* See if we have anywhere to roam to */
if (l_queue_isempty(station->roam_bss_list)) {
station_debug_event(station, "no-roam-candidates");
goto fail;
}
station_transition_start(station);
return true;
fail:
station_roam_failed(station);
return true;
}
static void station_roam_scan_destroy(void *userdata)
{
struct station *station = userdata;
station->roam_scan_id = 0;
}
static int station_roam_scan(struct station *station,
struct scan_freq_set *freq_set)
{
struct scan_parameters params = { .freqs = freq_set, .flush = true };
_auto_(scan_freq_set_free) struct scan_freq_set *allowed =
station_get_allowed_freqs(station);
if (L_WARN_ON(!allowed))
return -ENOTSUP;
l_debug("ifindex: %u", netdev_get_ifindex(station->netdev));
if (station->connected_network) {
const char *ssid = network_get_ssid(station->connected_network);
/* Use direct probe request */
params.ssid = (const uint8_t *)ssid;
params.ssid_len = strlen(ssid);
}
if (!freq_set) {
station->roam_scan_full = true;
params.freqs = allowed;
} else
scan_freq_set_constrain(freq_set, allowed);
if (L_WARN_ON(scan_freq_set_isempty(params.freqs)))
return -ENOTSUP;
station->last_roam_scan = l_time_now();
station->roam_scan_id =
scan_active_full(netdev_get_wdev_id(station->netdev), &params,
station_roam_scan_triggered,
station_roam_scan_notify, station,
station_roam_scan_destroy);
if (!station->roam_scan_id)
return -EIO;
return 0;
}
static int station_roam_scan_known_freqs(struct station *station)
{
const struct network_info *info = network_get_info(
station->connected_network);
struct scan_freq_set *freqs = network_info_get_roam_frequencies(info,
station->connected_bss->frequency,
STATION_RECENT_FREQS_LIMIT);
int r = -ENODATA;
if (!freqs)
return r;
if (!wiphy_constrain_freq_set(station->wiphy, freqs))
goto free_set;
r = station_roam_scan(station, freqs);
free_set:
scan_freq_set_free(freqs);
return r;
}
static void station_neighbor_report_cb(struct netdev *netdev, int err,
const uint8_t *reports,
size_t reports_len, void *user_data)
{
struct station *station = user_data;
struct scan_freq_set *freq_set;
int r;
if (err == -ENODEV)
return;
l_debug("ifindex: %u, error: %d(%s)",
netdev_get_ifindex(station->netdev),
err, err < 0 ? strerror(-err) : "");
/*
* Check if we're still attempting to roam -- if dbus Disconnect
* had been called in the meantime we just abort the attempt.
*/
if (!station->preparing_roam || err == -ENODEV)
return;
if (!reports || err) {
r = station_roam_scan_known_freqs(station);
if (r == -ENODATA)
l_debug("no neighbor report results or known freqs");
if (r < 0)
station_roam_failed(station);
return;
}
parse_neighbor_report(station, reports, reports_len, &freq_set);
r = station_roam_scan(station, freq_set);
if (freq_set)
scan_freq_set_free(freq_set);
if (r < 0)
station_roam_failed(station);
}
static void station_start_roam(struct station *station)
{
int r;
station->preparing_roam = true;
/*
* If current BSS supports Neighbor Reports, narrow the scan down
* to channels occupied by known neighbors in the ESS. If no neighbor
* report was obtained upon connection, request one now. This isn't
* 100% reliable as the neighbor lists are not required to be
* complete or current. It is likely still better than doing a
* full scan. 10.11.10.1: "A neighbor report may not be exhaustive
* either by choice, or due to the fact that there may be neighbor
* APs not known to the AP."
*/
if (station->roam_freqs) {
if (station_roam_scan(station, station->roam_freqs) == 0) {
l_debug("Using cached neighbor report for roam");
return;
}
} else if (station->connected_bss->cap_rm_neighbor_report) {
if (netdev_neighbor_report_req(station->netdev,
station_neighbor_report_cb) == 0) {
l_debug("Requesting neighbor report for roam");
return;
}
}
r = station_roam_scan_known_freqs(station);
if (r == -ENODATA)
l_debug("No neighbor report or known frequencies, roam failed");
if (r < 0)
station_roam_failed(station);
}
static bool station_cannot_roam(struct station *station)
{
const struct l_settings *config = iwd_get_config();
bool disabled;
/*
* Disable roaming with hardware that can roam automatically. Note this
* is now required for recent kernels which have CQM event support on
* this type of hardware (e.g. brcmfmac).
*/
if (wiphy_supports_firmware_roam(station->wiphy))
return true;
if (!l_settings_get_bool(config, "Scan", "DisableRoamingScan",
&disabled))
disabled = false;
return disabled || station->preparing_roam ||
station->state == STATION_STATE_ROAMING ||
station->state == STATION_STATE_FT_ROAMING ||
station->ft_work.id;
}
static void station_roam_trigger_cb(struct l_timeout *timeout, void *user_data)
{
struct station *station = user_data;
l_debug("%u", netdev_get_ifindex(station->netdev));
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
if (station_cannot_roam(station))
return;
station_start_roam(station);
}
static void station_roam_timeout_rearm(struct station *station, int seconds)
{
uint64_t remaining;
if (!station->roam_trigger_timeout)
goto new_timeout;
/* If we can't get the remaining time just create a new timer */
if (L_WARN_ON(!l_timeout_remaining(station->roam_trigger_timeout,
&remaining))) {
l_timeout_remove(station->roam_trigger_timeout);
goto new_timeout;
}
/* Our current timeout is less than the rearm, keep current */
if (l_time_before(remaining, seconds * L_USEC_PER_SEC)) {
l_debug("Keeping current roam timeout of %" PRIx64 " seconds",
l_time_to_secs(remaining));
return;
}
l_debug("Rescheduling roam timeout from %" PRIx64" to %d seconds",
l_time_to_secs(remaining), seconds);
l_timeout_modify(station->roam_trigger_timeout, seconds);
return;
new_timeout:
l_debug("Arming new roam timer for %d seconds", seconds);
station->roam_trigger_timeout =
l_timeout_create(seconds, station_roam_trigger_cb,
station, NULL);
}
#define WNM_REQUEST_MODE_PREFERRED_CANDIDATE_LIST (1 << 0)
#define WNM_REQUEST_MODE_DISASSOCIATION_IMMINENT (1 << 2)
#define WNM_REQUEST_MODE_TERMINATION_IMMINENT (1 << 3)
#define WNM_REQUEST_MODE_ESS_DISASSOCIATION_IMMINENT (1 << 4)
static void station_ap_directed_roam(struct station *station,
const struct mmpdu_header *hdr,
const void *body, size_t body_len)
{
uint32_t pos = 0;
uint8_t req_mode;
uint16_t dtimer;
uint8_t valid_interval;
l_debug("ifindex: %u", netdev_get_ifindex(station->netdev));
if (station_cannot_roam(station))
return;
if (station->state != STATION_STATE_CONNECTED) {
l_debug("roam: unexpected AP directed roam -- ignore");
return;
}
/*
* Sanitize the frame to check that it is from our current AP.
*
* 802.11-2020 Section 9.3.3.1 about Address2:
* "If the STA is an AP with dot11MultiBSSDImplemented set to false,
* then this address is the BSSID."
*
* Address3:
* "If the STA is an AP or PCP, the Address 3 field is the same as the
* Address 2 field."
*
* For now check that Address2 & Address3 is the same as the connected
* BSS address.
*/
if (memcmp(hdr->address_2, station->connected_bss, ETH_ALEN) ||
memcmp(hdr->address_2, hdr->address_3, ETH_ALEN)) {
l_debug("roam: AP directed roam not from our AP -- ignore");
return;
}
if (body_len < 7)
goto format_error;
/*
* First two bytes are checked by the frame watch (WNM category and
* WNM action). The third is the dialog token which is not relevant
* because we did not send a BSS transition query -- so skip these
* first three bytes.
*/
pos += 3;
req_mode = l_get_u8(body + pos);
pos++;
/*
* TODO: Disassociation timer and validity interval are currently not
* used since the BSS transition request is being handled immediately.
*/
dtimer = l_get_le16(body + pos);
pos += 2;
valid_interval = l_get_u8(body + pos);
pos++;
l_debug("roam: BSS transition received from AP: " MAC", "
"Disassociation Time: %u, "
"Validity interval: %u, Address3: " MAC,
MAC_STR(hdr->address_2),
dtimer, valid_interval,
MAC_STR(hdr->address_3));
/*
* The ap_directed_roaming flag forces IWD to roam if there are any
* candidates, even if they are worse than the current BSS. This isn't
* always a good idea since we may be associated to the best BSS. Where
* this does matter is if the AP indicates its going down or will be
* disassociating us. If either of these bits are set, set the
* ap_directed_roaming flag. Otherwise still try roaming but don't
* treat it any different than a normal roam.
*/
if (req_mode & (WNM_REQUEST_MODE_DISASSOCIATION_IMMINENT |
WNM_REQUEST_MODE_TERMINATION_IMMINENT |
WNM_REQUEST_MODE_ESS_DISASSOCIATION_IMMINENT))
station->ap_directed_roaming = true;
if (req_mode & WNM_REQUEST_MODE_TERMINATION_IMMINENT) {
if (pos + 12 > body_len)
goto format_error;
pos += 12;
}
if (req_mode & WNM_REQUEST_MODE_ESS_DISASSOCIATION_IMMINENT) {
uint8_t url_len;
if (pos + 1 > body_len)
goto format_error;
url_len = l_get_u8(body + pos);
pos++;
if (pos + url_len > body_len)
goto format_error;
pos += url_len;
}
station->preparing_roam = true;
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
if (req_mode & WNM_REQUEST_MODE_PREFERRED_CANDIDATE_LIST) {
l_debug("roam: AP sent a preferred candidate list");
station_neighbor_report_cb(station->netdev, 0, body + pos,
body_len - pos, station);
} else {
l_debug("roam: AP did not include a preferred candidate list");
if (station_roam_scan(station, NULL) < 0)
station_roam_failed(station);
}
return;
format_error:
l_debug("bad AP roam frame formatting");
}
static void station_low_rssi(struct station *station)
{
if (station->signal_low)
return;
station->signal_low = true;
if (station_cannot_roam(station))
return;
/* Set a 5-second initial timeout */
station_roam_timeout_rearm(station, 5);
}
static void station_ok_rssi(struct station *station)
{
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
station->signal_low = false;
}
static void station_event_roamed(struct station *station, struct scan_bss *new)
{
struct scan_bss *stale;
network_bss_update(station->connected_network, new);
station_register_bss(station->connected_network, new);
/* Remove new BSS if it exists in past scan results */
stale = l_queue_remove_if(station->bss_list, bss_match, new);
if (stale)
scan_bss_free(stale);
station->connected_bss = new;
l_queue_insert(station->bss_list, new, scan_bss_rank_compare, NULL);
station_roamed(station);
}
static void station_event_channel_switched(struct station *station,
const uint32_t freq)
{
struct network *network = station->connected_network;
station->connected_bss->frequency = freq;
network_bss_update(network, station->connected_bss);
}
static bool station_try_next_bss(struct station *station)
{
struct scan_bss *next;
int ret;
next = network_bss_select(station->connected_network, false);
if (!next)
return false;
ret = __station_connect_network(station, station->connected_network,
next, station->state);
if (ret < 0)
return false;
l_debug("Attempting to connect to next BSS "MAC, MAC_STR(next->addr));
return true;
}
static bool station_retry_owe_default_group(struct station *station)
{
/*
* Shouldn't ever get here with classic open networks so its safe to
* assume if the security is none this is an OWE network.
*/
if (network_get_security(station->connected_network) != SECURITY_NONE)
return false;
/* If we already forced group 19, allow the BSS to be blacklisted */
if (network_get_force_default_ecc_group(station->connected_network))
return false;
l_warn("Failed to connect to OWE BSS "MAC" possibly because the AP is "
"incorrectly deriving the PTK, this AP should be fixed. "
"Retrying with group 19 as a workaround",
MAC_STR(station->connected_bss->addr));
network_set_force_default_ecc_group(station->connected_network);
return true;
}
static bool station_retry_with_reason(struct station *station,
uint16_t reason_code)
{
iwd_notice(IWD_NOTICE_CONNECT_FAILED, "reason: %u", reason_code);
/*
* We don't want to cause a retry and blacklist if the password was
* incorrect. Otherwise we would just continue to fail.
*
* Other reason codes can be added here if its decided we want to
* fail in those cases.
*/
switch (reason_code) {
case MMPDU_REASON_CODE_PREV_AUTH_NOT_VALID:
if (station_retry_owe_default_group(station))
goto try_next;
/* fall through */
case MMPDU_REASON_CODE_IEEE8021X_FAILED:
return false;
default:
break;
}
blacklist_add_bss(station->connected_bss->addr);
try_next:
return station_try_next_bss(station);
}
/* A bit more concise for trying to fit these into 80 characters */
#define IS_TEMPORARY_STATUS(code) \
((code) == MMPDU_STATUS_CODE_DENIED_UNSUFFICIENT_BANDWIDTH || \
(code) == MMPDU_STATUS_CODE_DENIED_POOR_CHAN_CONDITIONS || \
(code) == MMPDU_STATUS_CODE_REJECTED_WITH_SUGG_BSS_TRANS || \
(code) == MMPDU_STATUS_CODE_DENIED_NO_MORE_STAS)
static bool station_retry_with_status(struct station *station,
uint16_t status_code)
{
/*
* Certain Auth/Assoc failures should not cause a timeout blacklist.
* In these cases we want to only temporarily blacklist the BSS until
* the connection is complete.
*
* TODO: The WITH_SUGG_BSS_TRANS case should also include a neighbor
* report IE in the frame. This would allow us to target a
* specific BSS on our next attempt. There is currently no way to
* obtain that IE, but this should be done in the future.
*/
if (IS_TEMPORARY_STATUS(status_code))
network_blacklist_add(station->connected_network,
station->connected_bss);
else
blacklist_add_bss(station->connected_bss->addr);
iwd_notice(IWD_NOTICE_CONNECT_FAILED, "status: %u", status_code);
return station_try_next_bss(station);
}
static void station_connect_ok(struct station *station)
{
struct handshake_state *hs = netdev_get_handshake(station->netdev);
l_debug("");
if (station->connect_pending) {
struct l_dbus_message *reply =
l_dbus_message_new_method_return(
station->connect_pending);
dbus_pending_reply(&station->connect_pending, reply);
}
/*
* Get a neighbor report now so future roams can avoid waiting for
* a report at that time
*/
if (station->connected_bss->cap_rm_neighbor_report) {
if (netdev_neighbor_report_req(station->netdev,
station_early_neighbor_report_cb) < 0)
l_warn("Could not request neighbor report");
}
network_connected(station->connected_network);
if (station->netconfig) {
if (hs->fils_ip_req_ie && hs->fils_ip_resp_ie) {
struct ie_fils_ip_addr_response_info info;
struct ie_tlv_iter iter;
int r;
ie_tlv_iter_init(&iter, hs->fils_ip_resp_ie,
hs->fils_ip_resp_ie[1] + 2);
if (!L_WARN_ON(unlikely(!ie_tlv_iter_next(&iter))))
r = ie_parse_fils_ip_addr_response(&iter,
&info);
else
r = -ENOMSG;
if (r != 0)
l_debug("Error parsing the FILS IP Address "
"Assignment response: %s (%i)",
strerror(-r), -r);
else if (info.response_pending &&
info.response_timeout)
l_debug("FILS IP Address Assignment response "
"is pending (unsupported)");
else if (info.response_pending)
l_debug("FILS IP Address Assignment failed");
else {
l_debug("FILS IP Address Assignment response "
"OK");
netconfig_handle_fils_ip_resp(
station->netconfig,
&info);
}
}
if (L_WARN_ON(!netconfig_configure(station->netconfig,
station_netconfig_event_handler,
station)))
return;
station_enter_state(station, STATION_STATE_NETCONFIG);
} else
station_enter_state(station, STATION_STATE_CONNECTED);
}
static void station_connect_cb(struct netdev *netdev, enum netdev_result result,
void *event_data, void *user_data)
{
struct station *station = user_data;
bool continue_autoconnect;
uint16_t reason = MMPDU_REASON_CODE_UNSPECIFIED;
l_debug("%u, result: %d", netdev_get_ifindex(station->netdev), result);
switch (result) {
case NETDEV_RESULT_OK:
blacklist_remove_bss(station->connected_bss->addr);
station_connect_ok(station);
return;
case NETDEV_RESULT_DISCONNECTED:
reason = l_get_u16(event_data);
iwd_notice(IWD_NOTICE_DISCONNECT_INFO, "reason: %u", reason);
/* Disconnected while connecting */
network_blacklist_add(station->connected_network,
station->connected_bss);
if (station_try_next_bss(station))
return;
break;
case NETDEV_RESULT_HANDSHAKE_FAILED:
reason = l_get_u16(event_data);
/* reason code in this case */
if (station_retry_with_reason(station, reason))
return;
break;
case NETDEV_RESULT_AUTHENTICATION_FAILED:
case NETDEV_RESULT_ASSOCIATION_FAILED:
/* status code in this case */
if (station_retry_with_status(station, l_get_u16(event_data)))
return;
break;
default:
break;
}
if (station->connect_pending) {
struct l_dbus_message *reply;
if (result == NETDEV_RESULT_ABORTED)
reply = dbus_error_aborted(station->connect_pending);
else
reply = dbus_error_failed(station->connect_pending);
dbus_pending_reply(&station->connect_pending, reply);
}
if (result == NETDEV_RESULT_ABORTED)
return;
continue_autoconnect = station->state == STATION_STATE_CONNECTING_AUTO;
if (station->state == STATION_STATE_CONNECTING) {
/*
* Either a handshake failure (generated internally) or a 4-way
* handshake timeout should trigger the PSK to be asked for
* again. Set during_eapol accordingly.
*/
bool during_eapol = result == NETDEV_RESULT_HANDSHAKE_FAILED ||
reason == MMPDU_REASON_CODE_4WAY_HANDSHAKE_TIMEOUT;
network_connect_failed(station->connected_network,
during_eapol);
}
station_reset_connection_state(station);
station_enter_state(station, STATION_STATE_DISCONNECTED);
if (continue_autoconnect) {
if (station_autoconnect_next(station) < 0) {
l_debug("Nothing left on autoconnect list");
station_enter_state(station,
STATION_STATE_AUTOCONNECT_FULL);
}
return;
}
if (station->autoconnect)
station_enter_state(station, STATION_STATE_AUTOCONNECT_QUICK);
}
static void station_disconnect_event(struct station *station, void *event_data)
{
l_debug("%u", netdev_get_ifindex(station->netdev));
/*
* If we're connecting, AP deauthenticated us, most likely because
* we provided the wrong password or otherwise failed authentication
* during the handshaking phase. Connection failures should be handled
* within station_connect_cb/station_reassociate_cb apart from netconfig
* and FW roams.
*/
switch (station->state) {
case STATION_STATE_CONNECTED:
case STATION_STATE_FW_ROAMING:
case STATION_STATE_NETCONFIG:
iwd_notice(IWD_NOTICE_DISCONNECT_INFO, "reason: %u",
l_get_u16(event_data));
station_disassociated(station);
return;
default:
break;
}
l_warn("Unexpected disconnect event");
}
#define STATION_PKT_LOSS_THRESHOLD 10
#define LOSS_ROAM_RATE_LIMIT 2
static void station_packets_lost(struct station *station, uint32_t num_pkts)
{
uint64_t elapsed;
l_debug("Packets lost event: %u", num_pkts);
if (num_pkts < STATION_PKT_LOSS_THRESHOLD)
return;
if (station_cannot_roam(station))
return;
station_debug_event(station, "packet-loss-roam");
elapsed = l_time_diff(station->last_roam_scan, l_time_now());
/*
* If we just issued a roam scan, delay the roam to avoid constant
* scanning.
*/
if (LOSS_ROAM_RATE_LIMIT > l_time_to_secs(elapsed)) {
l_debug("Too many roam attempts in %u second timeframe, "
"delaying roam", LOSS_ROAM_RATE_LIMIT);
station_roam_timeout_rearm(station, LOSS_ROAM_RATE_LIMIT);
return;
}
if (station->roam_trigger_timeout) {
l_debug("canceling roam timer to roam immediately");
l_timeout_remove(station->roam_trigger_timeout);
station->roam_trigger_timeout = NULL;
}
station_start_roam(station);
}
static void station_beacon_lost(struct station *station)
{
l_debug("Beacon lost event");
if (station_cannot_roam(station))
return;
station_debug_event(station, "beacon-loss-roam");
station_roam_timeout_rearm(station, LOSS_ROAM_RATE_LIMIT);
}
static void station_event_roaming(struct station *station)
{
if (station->netconfig && station->state != STATION_STATE_CONNECTED) {
netconfig_reset(station->netconfig);
station->netconfig_after_roam = true;
}
station_enter_state(station, STATION_STATE_FW_ROAMING);
}
static void station_ecc_group_retry(struct station *station)
{
struct network *network = station_get_connected_network(station);
if (L_WARN_ON(!network))
return;
station_debug_event(station, "ecc-group-rejected");
network_set_force_default_ecc_group(network);
}
static void station_netdev_event(struct netdev *netdev, enum netdev_event event,
void *event_data, void *user_data)
{
struct station *station = user_data;
switch (event) {
case NETDEV_EVENT_AUTHENTICATING:
station_debug_event(station, "authenticating");
break;
case NETDEV_EVENT_ASSOCIATING:
station_debug_event(station, "associating");
break;
case NETDEV_EVENT_DISCONNECT_BY_AP:
case NETDEV_EVENT_DISCONNECT_BY_SME:
station_disconnect_event(station, event_data);
break;
case NETDEV_EVENT_RSSI_THRESHOLD_LOW:
station_low_rssi(station);
break;
case NETDEV_EVENT_RSSI_THRESHOLD_HIGH:
station_ok_rssi(station);
break;
case NETDEV_EVENT_RSSI_LEVEL_NOTIFY:
if (station->signal_agent)
station_signal_agent_notify(station);
break;
case NETDEV_EVENT_ROAMING:
station_event_roaming(station);
break;
case NETDEV_EVENT_ROAMED:
station_event_roamed(station, (struct scan_bss *) event_data);
break;
case NETDEV_EVENT_CHANNEL_SWITCHED:
station_event_channel_switched(station, l_get_u32(event_data));
break;
case NETDEV_EVENT_PACKET_LOSS_NOTIFY:
station_packets_lost(station, l_get_u32(event_data));
break;
case NETDEV_EVENT_BEACON_LOSS_NOTIFY:
station_beacon_lost(station);
break;
case NETDEV_EVENT_ECC_GROUP_RETRY:
station_ecc_group_retry(station);
break;
}
}
int __station_connect_network(struct station *station, struct network *network,
struct scan_bss *bss, enum station_state state)
{
struct handshake_state *hs;
int r;
if (station->netconfig && !netconfig_load_settings(
station->netconfig,
network_get_settings(network)))
return -EINVAL;
hs = station_handshake_setup(station, network, bss);
if (!hs)
return -ENOTSUP;
r = netdev_connect(station->netdev, bss, hs,
station_netdev_event,
station_connect_cb, station);
if (r < 0) {
handshake_state_free(hs);
return r;
}
iwd_notice(IWD_NOTICE_CONNECT_INFO, "ssid: %s, bss: "MAC", "
"signal: %d, load: %d/255",
network_get_ssid(network),
MAC_STR(bss->addr),
bss->signal_strength / 100,
bss->utilization);
station->connected_bss = bss;
station->connected_network = network;
if (station->state != state)
station_enter_state(station, state);
return 0;
}
static void station_disconnect_onconnect_cb(struct netdev *netdev, bool success,
void *user_data)
{
struct station *station = user_data;
int err;
station_enter_state(station, STATION_STATE_DISCONNECTED);
err = __station_connect_network(station,
station->connect_pending_network,
station->connect_pending_bss,
STATION_STATE_CONNECTING);
station->connect_pending_network = NULL;
station->connect_pending_bss = NULL;
if (err < 0) {
dbus_pending_reply(&station->connect_pending,
dbus_error_from_errno(err,
station->connect_pending));
return;
}
}
static void station_disconnect_onconnect(struct station *station,
struct network *network,
struct scan_bss *bss,
struct l_dbus_message *message)
{
if (netdev_disconnect(station->netdev, station_disconnect_onconnect_cb,
station) < 0) {
l_dbus_send(dbus_get_bus(),
dbus_error_from_errno(-EIO, message));
return;
}
station_reset_connection_state(station);
station_enter_state(station, STATION_STATE_DISCONNECTING);
station->connect_pending_network = network;
station->connect_pending_bss = bss;
station->connect_pending = l_dbus_message_ref(message);
}
void station_connect_network(struct station *station, struct network *network,
struct scan_bss *bss,
struct l_dbus_message *message)
{
struct l_dbus *dbus = dbus_get_bus();
int err;
/*
* If a hidden scan is not completed, station_is_busy would not
* indicate anything is going on so we need to cancel the scan and
* fail the connection now.
*/
if (station->hidden_network_scan_id) {
scan_cancel(netdev_get_wdev_id(station->netdev),
station->hidden_network_scan_id);
dbus_pending_reply(&station->hidden_pending,
dbus_error_failed(station->hidden_pending));
}
if (station->quick_scan_id) {
scan_cancel(netdev_get_wdev_id(station->netdev),
station->quick_scan_id);
station->quick_scan_id = 0;
station_property_set_scanning(station, false);
}
if (station_is_busy(station)) {
station_disconnect_onconnect(station, network, bss, message);
return;
}
err = __station_connect_network(station, network, bss,
STATION_STATE_CONNECTING);
if (err < 0)
goto error;
station->connect_pending = l_dbus_message_ref(message);
station_set_autoconnect(station, true);
return;
error:
l_dbus_send(dbus, dbus_error_from_errno(err, message));
}
static void station_hidden_network_scan_triggered(int err, void *user_data)
{
struct station *station = user_data;
l_debug("");
if (!err)
return;
dbus_pending_reply(&station->hidden_pending,
dbus_error_failed(station->hidden_pending));
}
static bool station_hidden_network_scan_results(int err,
struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
struct network *network_psk;
struct network *network_open;
const char *ssid;
uint8_t ssid_len;
struct l_dbus_message *msg;
struct l_dbus_message *error;
struct scan_bss *bss;
l_debug("");
msg = station->hidden_pending;
station->hidden_pending = NULL;
/* Zero this now so station_connect_network knows the scan is done */
station->hidden_network_scan_id = 0;
if (err) {
dbus_pending_reply(&msg, dbus_error_failed(msg));
return false;
}
if (!l_dbus_message_get_arguments(msg, "s", &ssid)) {
dbus_pending_reply(&msg, dbus_error_invalid_args(msg));
return false;
}
ssid_len = strlen(ssid);
while ((bss = l_queue_pop_head(bss_list))) {
if (bss->ssid_len != ssid_len ||
memcmp(bss->ssid, ssid, ssid_len))
goto next;
if (bss->owe_trans)
goto next;
/*
* Override time_stamp so that this entry is removed on
* the next scan
*/
bss->time_stamp = 0;
if (station_add_seen_bss(station, bss)) {
l_queue_push_tail(station->bss_list, bss);
continue;
}
next:
scan_bss_free(bss);
}
l_queue_destroy(bss_list, NULL);
network_psk = station_network_find(station, ssid, SECURITY_PSK);
network_open = station_network_find(station, ssid, SECURITY_NONE);
if (!network_psk && !network_open) {
dbus_pending_reply(&msg, dbus_error_not_found(msg));
return true;
}
if (network_psk && network_open) {
station_hide_network(station, network_psk);
station_hide_network(station, network_open);
dbus_pending_reply(&msg, dbus_error_service_set_overlap(msg));
return true;
}
network_update_known_frequencies(network_psk ?: network_open);
error = network_connect_new_hidden_network(network_psk ?: network_open,
msg);
if (error)
dbus_pending_reply(&msg, error);
else
l_dbus_message_unref(msg);
return true;
}
static void station_hidden_network_scan_destroy(void *userdata)
{
struct station *station = userdata;
station->hidden_network_scan_id = 0;
}
static struct l_dbus_message *station_dbus_connect_hidden_network(
struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
uint64_t id = netdev_get_wdev_id(station->netdev);
struct scan_parameters params = {
.flush = true,
.randomize_mac_addr_hint = false,
};
const char *ssid;
struct network *network;
_auto_(scan_freq_set_free) struct scan_freq_set *allowed = NULL;
l_debug("");
if (station->hidden_pending)
return dbus_error_busy(message);
if (!l_dbus_message_get_arguments(message, "s", &ssid))
return dbus_error_invalid_args(message);
if (strlen(ssid) > SSID_MAX_SIZE)
return dbus_error_invalid_args(message);
if (known_networks_find(ssid, SECURITY_PSK) ||
known_networks_find(ssid, SECURITY_NONE))
return dbus_error_already_provisioned(message);
network = station_network_find(station, ssid, SECURITY_PSK);
if (!network)
network = station_network_find(station, ssid, SECURITY_NONE);
/*
* This checks for a corner case where the hidden network was already
* found and is in our scan results, but the initial connection failed.
* For example, the password was given incorrectly. In this case the
* entry will also be found on the hidden bss list.
*/
if (network) {
const struct l_queue_entry *entry =
l_queue_get_entries(station->hidden_bss_list_sorted);
struct scan_bss *target = network_bss_select(network, true);
/* Treat OWE transition networks special */
if (target->owe_trans)
goto not_hidden;
for (; entry; entry = entry->next) {
struct scan_bss *bss = entry->data;
if (!scan_bss_addr_eq(target, bss))
continue;
/* We can skip the scan and try to connect right away */
return network_connect_new_hidden_network(network,
message);
}
not_hidden:
return dbus_error_not_hidden(message);
}
allowed = station_get_allowed_freqs(station);
if (L_WARN_ON(!allowed))
return dbus_error_not_supported(message);
params.freqs = allowed;
params.ssid = (const uint8_t *)ssid;
params.ssid_len = strlen(ssid);
/* HW cannot randomize our MAC if connected */
if (!station->connected_bss)
params.randomize_mac_addr_hint = true;
station->hidden_network_scan_id = scan_active_full(id, &params,
station_hidden_network_scan_triggered,
station_hidden_network_scan_results,
station, station_hidden_network_scan_destroy);
if (!station->hidden_network_scan_id)
return dbus_error_failed(message);
station->hidden_pending = l_dbus_message_ref(message);
return NULL;
}
static void station_disconnect_reconnect_cb(struct netdev *netdev, bool success,
void *user_data)
{
struct station *station = user_data;
if (__station_connect_network(station, station->connected_network,
station->connected_bss,
STATION_STATE_ROAMING) < 0)
station_disassociated(station);
}
static void station_reconnect(struct station *station)
{
/*
* Rather than doing 4 or so state changes, lets just go into
* roaming for the duration of this reconnect.
*/
station_enter_state(station, STATION_STATE_ROAMING);
netdev_disconnect(station->netdev, station_disconnect_reconnect_cb,
station);
}
static void station_disconnect_cb(struct netdev *netdev, bool success,
void *user_data)
{
struct station *station = user_data;
l_debug("%u, success: %d",
netdev_get_ifindex(station->netdev), success);
if (station->disconnect_pending) {
struct l_dbus_message *reply;
if (success) {
reply = l_dbus_message_new_method_return(
station->disconnect_pending);
l_dbus_message_set_arguments(reply, "");
} else
reply = dbus_error_failed(station->disconnect_pending);
dbus_pending_reply(&station->disconnect_pending, reply);
}
station_enter_state(station, STATION_STATE_DISCONNECTED);
if (station->autoconnect)
station_enter_state(station, STATION_STATE_AUTOCONNECT_QUICK);
}
int station_disconnect(struct station *station)
{
if (station->state == STATION_STATE_DISCONNECTING)
return -EBUSY;
if (!station->connected_bss)
return -ENOTCONN;
/*
* If the disconnect somehow fails we won't know if we're still
* connected so we may as well indicate now that we're no longer
* connected.
*/
station_reset_connection_state(station);
station_enter_state(station, STATION_STATE_DISCONNECTING);
if (netdev_disconnect(station->netdev,
station_disconnect_cb, station) < 0)
return -EIO;
return 0;
}
static struct l_dbus_message *station_dbus_disconnect(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
int result;
l_debug("");
/*
* Disconnect was triggered by the user, don't autoconnect. Wait for
* the user's explicit instructions to scan and connect to the network
*/
station_set_autoconnect(station, false);
if (station->hidden_network_scan_id) {
scan_cancel(netdev_get_wdev_id(station->netdev),
station->hidden_network_scan_id);
dbus_pending_reply(&station->hidden_pending,
dbus_error_aborted(station->hidden_pending));
return l_dbus_message_new_method_return(message);
}
if (!station_is_busy(station))
return l_dbus_message_new_method_return(message);
result = station_disconnect(station);
if (result < 0)
return dbus_error_from_errno(result, message);
station->disconnect_pending = l_dbus_message_ref(message);
return NULL;
}
static struct l_dbus_message *station_dbus_get_networks(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply =
l_dbus_message_new_method_return(message);
struct l_dbus_message_builder *builder =
l_dbus_message_builder_new(reply);
struct l_queue *sorted = station->networks_sorted;
const struct l_queue_entry *entry;
l_dbus_message_builder_enter_array(builder, "(on)");
for (entry = l_queue_get_entries(sorted); entry; entry = entry->next) {
const struct network *network = entry->data;
int16_t signal_strength = network_get_signal_strength(network);
l_dbus_message_builder_enter_struct(builder, "on");
l_dbus_message_builder_append_basic(builder, 'o',
network_get_path(network));
l_dbus_message_builder_append_basic(builder, 'n',
&signal_strength);
l_dbus_message_builder_leave_struct(builder);
}
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_finalize(builder);
l_dbus_message_builder_destroy(builder);
return reply;
}
static struct l_dbus_message *station_dbus_get_hidden_access_points(
struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply =
l_dbus_message_new_method_return(message);
struct l_dbus_message_builder *builder =
l_dbus_message_builder_new(reply);
const struct l_queue_entry *entry;
l_dbus_message_builder_enter_array(builder, "(sns)");
for (entry = l_queue_get_entries(station->hidden_bss_list_sorted);
entry; entry = entry->next) {
struct scan_bss *bss = entry->data;
int16_t signal_strength = bss->signal_strength;
enum security security;
if (scan_bss_get_security(bss, &security) < 0)
continue;
l_dbus_message_builder_enter_struct(builder, "sns");
l_dbus_message_builder_append_basic(builder, 's',
util_address_to_string(bss->addr));
l_dbus_message_builder_append_basic(builder, 'n',
&signal_strength);
l_dbus_message_builder_append_basic(builder, 's',
security_to_str(security));
l_dbus_message_builder_leave_struct(builder);
}
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_finalize(builder);
l_dbus_message_builder_destroy(builder);
return reply;
}
static void station_dbus_scan_done(struct station *station,
bool try_autoconnect)
{
station->dbus_scan_id = 0;
station_property_set_scanning(station, false);
station_process_owe_transition_networks(station);
if (try_autoconnect) {
station->autoconnect_can_start = true;
station_autoconnect_start(station);
}
}
static void station_dbus_scan_triggered(int err, void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply;
l_debug("station_scan_triggered: %i", err);
if (err < 0) {
if (station->scan_pending) {
reply = dbus_error_from_errno(err,
station->scan_pending);
dbus_pending_reply(&station->scan_pending, reply);
}
station_dbus_scan_done(station, true);
return;
}
l_debug("Scan triggered for %s subset %i",
netdev_get_name(station->netdev),
station->dbus_scan_subset_idx);
if (station->scan_pending) {
reply = l_dbus_message_new_method_return(station->scan_pending);
l_dbus_message_set_arguments(reply, "");
dbus_pending_reply(&station->scan_pending, reply);
}
station_property_set_scanning(station, true);
}
static bool station_dbus_scan_subset(struct station *station);
static bool station_dbus_scan_results(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
unsigned int next_idx = station->dbus_scan_subset_idx + 1;
bool last_subset;
if (err) {
station_dbus_scan_done(station, true);
return false;
}
last_subset = next_idx >= L_ARRAY_SIZE(station->scan_freqs_order) ||
station->scan_freqs_order[next_idx] == NULL;
station->dbus_scan_subset_idx = next_idx;
station_set_scan_results(station, bss_list, freqs, false);
if (last_subset || !station_dbus_scan_subset(station))
station_dbus_scan_done(station, true);
return true;
}
static bool station_dbus_scan_subset(struct station *station)
{
unsigned int idx = station->dbus_scan_subset_idx;
station->dbus_scan_id = station_scan_trigger(station,
station->scan_freqs_order[idx],
station_dbus_scan_triggered,
station_dbus_scan_results,
NULL);
return station->dbus_scan_id != 0;
}
static struct l_dbus_message *station_dbus_scan(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
l_debug("Scan called from DBus");
if (station->dbus_scan_id)
return dbus_error_busy(message);
if (L_IN_SET(station->state, STATION_STATE_CONNECTING,
STATION_STATE_CONNECTING_AUTO,
STATION_STATE_NETCONFIG) ||
station_is_roaming(station))
return dbus_error_busy(message);
station->dbus_scan_subset_idx = 0;
if (!station_dbus_scan_subset(station))
return dbus_error_failed(message);
station->scan_pending = l_dbus_message_ref(message);
return NULL;
}
struct signal_agent {
char *owner;
char *path;
unsigned int disconnect_watch;
};
static void station_signal_agent_notify(struct station *station)
{
struct signal_agent *agent = station->signal_agent;
struct netdev *netdev = station->netdev;
const char *device_path = netdev_get_path(netdev);
uint8_t level = netdev_get_rssi_level_idx(netdev);
struct l_dbus_message *msg;
msg = l_dbus_message_new_method_call(dbus_get_bus(),
agent->owner, agent->path,
IWD_SIGNAL_AGENT_INTERFACE,
"Changed");
l_dbus_message_set_arguments(msg, "oy", device_path, level);
l_dbus_message_set_no_reply(msg, true);
l_dbus_send(dbus_get_bus(), msg);
}
static void station_signal_agent_release(struct signal_agent *agent,
const char *device_path)
{
struct l_dbus_message *msg;
msg = l_dbus_message_new_method_call(dbus_get_bus(),
agent->owner, agent->path,
IWD_SIGNAL_AGENT_INTERFACE,
"Release");
l_dbus_message_set_arguments(msg, "o", device_path);
l_dbus_message_set_no_reply(msg, true);
l_dbus_send(dbus_get_bus(), msg);
}
static void signal_agent_free(void *data)
{
struct signal_agent *agent = data;
l_free(agent->owner);
l_free(agent->path);
l_dbus_remove_watch(dbus_get_bus(), agent->disconnect_watch);
l_free(agent);
}
static void signal_agent_disconnect(struct l_dbus *dbus, void *user_data)
{
struct station *station = user_data;
l_debug("signal_agent %s disconnected", station->signal_agent->owner);
l_idle_oneshot(signal_agent_free, station->signal_agent, NULL);
station->signal_agent = NULL;
netdev_set_rssi_report_levels(station->netdev, NULL, 0);
}
static struct l_dbus_message *station_dbus_signal_agent_register(
struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
const char *path, *sender;
struct l_dbus_message *reply;
struct l_dbus_message_iter level_iter;
int8_t levels[16];
int err;
int16_t val;
size_t count = 0;
if (station->signal_agent)
return dbus_error_already_exists(message);
l_debug("signal agent register called");
if (!l_dbus_message_get_arguments(message, "oan", &path, &level_iter))
return dbus_error_invalid_args(message);
while (l_dbus_message_iter_next_entry(&level_iter, &val)) {
if (count >= L_ARRAY_SIZE(levels) || val > 127 || val < -127)
return dbus_error_invalid_args(message);
levels[count++] = val;
}
if (count < 1)
return dbus_error_invalid_args(message);
err = netdev_set_rssi_report_levels(station->netdev, levels, count);
if (err == -ENOTSUP)
return dbus_error_not_supported(message);
else if (err < 0)
return dbus_error_failed(message);
sender = l_dbus_message_get_sender(message);
station->signal_agent = l_new(struct signal_agent, 1);
station->signal_agent->owner = l_strdup(sender);
station->signal_agent->path = l_strdup(path);
station->signal_agent->disconnect_watch =
l_dbus_add_disconnect_watch(dbus, sender,
signal_agent_disconnect,
station, NULL);
l_debug("agent %s path %s", sender, path);
reply = l_dbus_message_new_method_return(message);
l_dbus_send(dbus, reply);
if (station->connected_network)
station_signal_agent_notify(station);
return NULL;
}
static struct l_dbus_message *station_dbus_signal_agent_unregister(
struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
const char *path, *sender;
if (!station->signal_agent)
return dbus_error_failed(message);
l_debug("signal agent unregister");
if (!l_dbus_message_get_arguments(message, "o", &path))
return dbus_error_invalid_args(message);
if (strcmp(station->signal_agent->path, path))
return dbus_error_not_found(message);
sender = l_dbus_message_get_sender(message);
if (strcmp(station->signal_agent->owner, sender))
return dbus_error_not_found(message);
signal_agent_free(station->signal_agent);
station->signal_agent = NULL;
netdev_set_rssi_report_levels(station->netdev, NULL, 0);
return l_dbus_message_new_method_return(message);
}
static bool station_property_get_connected_network(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
if (!station->connected_network)
return false;
l_dbus_message_builder_append_basic(builder, 'o',
network_get_path(station->connected_network));
return true;
}
static bool station_property_get_connected_ap(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
if (!station->connected_network)
return false;
l_dbus_message_builder_append_basic(builder, 'o',
network_bss_get_path(station->connected_network,
station->connected_bss));
return true;
}
static bool station_property_get_scanning(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
bool scanning = station->scanning;
l_dbus_message_builder_append_basic(builder, 'b', &scanning);
return true;
}
static bool station_property_get_state(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
const char *statestr = "invalid";
switch (station->state) {
case STATION_STATE_AUTOCONNECT_QUICK:
case STATION_STATE_AUTOCONNECT_FULL:
case STATION_STATE_DISCONNECTED:
statestr = "disconnected";
break;
case STATION_STATE_CONNECTING:
case STATION_STATE_CONNECTING_AUTO:
case STATION_STATE_NETCONFIG:
statestr = "connecting";
break;
case STATION_STATE_CONNECTED:
statestr = "connected";
break;
case STATION_STATE_DISCONNECTING:
statestr = "disconnecting";
break;
case STATION_STATE_ROAMING:
case STATION_STATE_FT_ROAMING:
case STATION_STATE_FW_ROAMING:
/*
* Stay in a connecting state if roaming before netconfig
* has finished
*/
if (station->netconfig_after_roam)
statestr = "connecting";
else
statestr = "roaming";
break;
}
l_dbus_message_builder_append_basic(builder, 's', statestr);
return true;
}
static bool station_property_get_affinities(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
const struct l_queue_entry *e;
if (!station->connected_network)
return false;
l_dbus_message_builder_enter_array(builder, "o");
for (e = l_queue_get_entries(station->affinities); e; e = e->next) {
const char *path = e->data;
l_dbus_message_builder_append_basic(builder, 'o', path);
}
l_dbus_message_builder_leave_array(builder);
return true;
}
static void station_affinity_disconnected_cb(struct l_dbus *dbus,
void *user_data)
{
struct station *station = user_data;
l_dbus_remove_watch(dbus_get_bus(), station->affinity_watch);
l_debug("client that set affinity has disconnected");
/* The client who set the affinity disconnected, raise the threshold */
netdev_raise_signal_threshold(station->netdev);
}
static void station_affinity_watch_destroy(void *user_data)
{
struct station *station = user_data;
bool empty = l_queue_length(station->affinities) == 0;
station->affinity_watch = 0;
l_free(station->affinity_client);
station->affinity_client = NULL;
l_queue_clear(station->affinities, l_free);
if (!empty)
l_dbus_property_changed(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "Affinities");
}
static struct l_dbus_message *station_property_set_affinities(
struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_iter *new_value,
l_dbus_property_complete_cb_t complete,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message_iter array;
const char *sender = l_dbus_message_get_sender(message);
char *old_path = l_queue_peek_head(station->affinities);
const char *new_path = NULL;
struct scan_bss *new_bss = NULL;
struct scan_bss *old_bss = NULL;
bool lower_threshold = false;
if (!station->connected_network)
return dbus_error_not_connected(message);
if (wiphy_supports_firmware_roam(station->wiphy))
return dbus_error_not_supported(message);
if (station->affinity_watch &&
strcmp(station->affinity_client, sender)) {
l_warn("Only one client may manage Affinities property");
return dbus_error_permission_denied(message);
}
if (!l_dbus_message_iter_get_variant(new_value, "ao", &array))
return dbus_error_invalid_args(message);
/* Get first entry, there should be only one */
l_dbus_message_iter_next_entry(&array, &new_path);
if (l_dbus_message_iter_next_entry(&array, &new_path))
return dbus_error_invalid_args(message);
old_path = l_queue_peek_head(station->affinities);
if (old_path)
old_bss = l_dbus_object_get_data(dbus_get_bus(),
old_path, IWD_BSS_INTERFACE);
if (new_path)
new_bss = l_dbus_object_get_data(dbus,
new_path, IWD_BSS_INTERFACE);
/* Either the same path, or both arrays are empty */
if (old_bss == new_bss) {
complete(dbus, message, NULL);
return NULL;
}
/*
* TODO: For now only allow the affinities array to contain a single
* value, the connected BSS path. Any other values will be
* rejected. This could change in the future.
*/
if (new_bss && new_bss != station->connected_bss)
return dbus_error_invalid_args(message);
l_queue_clear(station->affinities, l_free);
/*
* Adding a new BSS, create a watch for this DBus client so if it
* disconnects we can clear the affinities list
*/
if (new_path) {
l_queue_push_head(station->affinities, l_strdup(new_path));
lower_threshold = true;
if (!station->affinity_watch) {
station->affinity_client = l_strdup(sender);
station->affinity_watch = l_dbus_add_disconnect_watch(
dbus, sender,
station_affinity_disconnected_cb,
station,
station_affinity_watch_destroy);
}
/* The list was cleared, remove the watch */
} else if (station->affinity_watch)
l_dbus_remove_watch(dbus, station->affinity_watch);
/*
* If affinity was set to the current BSS, lower the roam threshold. If
* the connected BSS was not in the list raise the signal threshold.
* The threshold may already be raised, in which case netdev will detect
* this and do nothing.
*/
if (lower_threshold)
netdev_lower_signal_threshold(station->netdev);
else
netdev_raise_signal_threshold(station->netdev);
complete(dbus, message, NULL);
l_dbus_property_changed(dbus, netdev_get_path(station->netdev),
IWD_STATION_INTERFACE, "Affinities");
return NULL;
}
void station_foreach(station_foreach_func_t func, void *user_data)
{
const struct l_queue_entry *entry;
for (entry = l_queue_get_entries(station_list); entry;
entry = entry->next) {
struct station *station = entry->data;
func(station, user_data);
}
}
struct station *station_find(uint32_t ifindex)
{
const struct l_queue_entry *entry;
for (entry = l_queue_get_entries(station_list); entry;
entry = entry->next) {
struct station *station = entry->data;
if (netdev_get_ifindex(station->netdev) == ifindex)
return station;
}
return NULL;
}
struct network_foreach_data {
station_network_foreach_func_t func;
void *user_data;
};
static void network_foreach(const void *key, void *value, void *user_data)
{
struct network_foreach_data *data = user_data;
struct network *network = value;
data->func(network, data->user_data);
}
void station_network_foreach(struct station *station,
station_network_foreach_func_t func,
void *user_data)
{
struct network_foreach_data data = {
.func = func,
.user_data = user_data,
};
l_hashmap_foreach(station->networks, network_foreach, &data);
}
struct l_queue *station_get_bss_list(struct station *station)
{
return station->bss_list;
}
struct scan_bss *station_get_connected_bss(struct station *station)
{
return station->connected_bss;
}
int station_hide_network(struct station *station, struct network *network)
{
const char *path = network_get_path(network);
struct scan_bss *bss;
l_debug("%s", path);
if (station->connected_network == network)
return -EBUSY;
if (!l_hashmap_lookup(station->networks, path))
return -ENOENT;
l_queue_remove(station->networks_sorted, network);
l_hashmap_remove(station->networks, path);
while ((bss = network_bss_list_pop(network))) {
memset(bss->ssid, 0, bss->ssid_len);
l_queue_remove_if(station->hidden_bss_list_sorted,
bss_match_bssid, bss->addr);
l_queue_insert(station->hidden_bss_list_sorted, bss,
bss_signal_strength_compare, NULL);
}
network_remove(network, -ESRCH);
return 0;
}
static void station_add_2_4ghz_freq(uint32_t freq, void *user_data)
{
struct scan_freq_set *set = user_data;
/* exclude social channels added in initial scan request */
if (freq < 3000 && freq != 2412 && freq != 2437 && freq != 2462)
scan_freq_set_add(set, freq);
}
static void station_fill_scan_freq_subsets(struct station *station)
{
const struct scan_freq_set *supported =
wiphy_get_supported_freqs(station->wiphy);
unsigned int subset_idx = 0;
/*
* Scan the 2.4GHz "social channels" first, 5GHz second, if supported,
* all other 2.4GHz channels last. To be refined as needed.
*/
if (allowed_bands & BAND_FREQ_2_4_GHZ) {
station->scan_freqs_order[subset_idx] = scan_freq_set_new();
scan_freq_set_add(station->scan_freqs_order[subset_idx], 2412);
scan_freq_set_add(station->scan_freqs_order[subset_idx], 2437);
scan_freq_set_add(station->scan_freqs_order[subset_idx], 2462);
subset_idx++;
}
/*
* TODO: It may might sense to split up 5 and 6ghz into separate subsets
* since the channel set is so large.
*/
if (allowed_bands & (BAND_FREQ_5_GHZ | BAND_FREQ_6_GHZ)) {
uint32_t mask = allowed_bands &
(BAND_FREQ_5_GHZ | BAND_FREQ_6_GHZ);
struct scan_freq_set *set = scan_freq_set_clone(supported,
mask);
/* 5/6ghz didn't add any frequencies */
if (scan_freq_set_isempty(set)) {
scan_freq_set_free(set);
} else
station->scan_freqs_order[subset_idx++] = set;
}
/* Add remaining 2.4ghz channels to subset */
if (allowed_bands & BAND_FREQ_2_4_GHZ) {
station->scan_freqs_order[subset_idx] = scan_freq_set_new();
scan_freq_set_foreach(supported, station_add_2_4ghz_freq,
station->scan_freqs_order[subset_idx]);
}
/*
* This has the unintended consequence of allowing DBus scans to
* scan the entire spectrum rather than cause IWD to be completely
* non-functional. Rather than prevent DBus scans from working at all
* print a warning here.
*/
if (station->scan_freqs_order[0] == NULL)
l_warn("All supported bands were disabled by user! IWD will not"
" function as expected");
}
static void station_wiphy_watch(struct wiphy *wiphy,
enum wiphy_state_watch_event event,
void *user_data)
{
struct station *station = user_data;
int ret;
if (event != WIPHY_STATE_WATCH_EVENT_REGDOM_DONE)
return;
/*
* The only state that requires special handling is for
* quick scans since the previous quick scan was delayed until
* the regulatory domain updated. Try again in case 6GHz is now
* unlocked (unlikely), or advance to full autoconnect. Just in
* case this update came during a quick scan, ignore it.
*/
if (station->state != STATION_STATE_AUTOCONNECT_QUICK ||
station->quick_scan_id)
return;
ret = station_quick_scan_trigger(station);
if (!ret)
return;
L_WARN_ON(ret == -EAGAIN);
station_enter_state(station, STATION_STATE_AUTOCONNECT_FULL);
}
static struct station *station_create(struct netdev *netdev)
{
struct station *station;
struct l_dbus *dbus = dbus_get_bus();
bool autoconnect = true;
station = l_new(struct station, 1);
watchlist_init(&station->state_watches, NULL);
station->bss_list = l_queue_new();
station->hidden_bss_list_sorted = l_queue_new();
station->networks = l_hashmap_new();
l_hashmap_set_hash_function(station->networks, l_str_hash);
l_hashmap_set_compare_function(station->networks,
(l_hashmap_compare_func_t) strcmp);
station->networks_sorted = l_queue_new();
station->wiphy = netdev_get_wiphy(netdev);
station->netdev = netdev;
station->wiphy_watch = wiphy_state_watch_add(station->wiphy,
station_wiphy_watch,
station, NULL);
l_queue_push_head(station_list, station);
l_dbus_object_add_interface(dbus, netdev_get_path(netdev),
IWD_STATION_INTERFACE, station);
if (netconfig_enabled())
station->netconfig = netconfig_new(netdev_get_ifindex(netdev));
station->anqp_pending = l_queue_new();
station_fill_scan_freq_subsets(station);
if (iwd_is_developer_mode()) {
l_dbus_object_add_interface(dbus,
netdev_get_path(station->netdev),
IWD_STATION_DEBUG_INTERFACE,
station);
autoconnect = false;
}
station_set_autoconnect(station, autoconnect);
station->roam_bss_list = l_queue_new();
station->affinities = l_queue_new();
return station;
}
static void station_free(struct station *station)
{
l_debug("");
if (!l_queue_remove(station_list, station))
return;
l_dbus_object_remove_interface(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_DIAGNOSTIC_INTERFACE);
if (iwd_is_developer_mode())
l_dbus_object_remove_interface(dbus_get_bus(),
netdev_get_path(station->netdev),
IWD_STATION_DEBUG_INTERFACE);
if (station->netconfig) {
netconfig_destroy(station->netconfig);
station->netconfig = NULL;
}
periodic_scan_stop(station);
if (station->signal_agent) {
station_signal_agent_release(station->signal_agent,
netdev_get_path(station->netdev));
signal_agent_free(station->signal_agent);
}
if (station->connect_pending)
dbus_pending_reply(&station->connect_pending,
dbus_error_aborted(station->connect_pending));
if (station->hidden_pending)
dbus_pending_reply(&station->hidden_pending,
dbus_error_aborted(station->hidden_pending));
if (station->disconnect_pending)
dbus_pending_reply(&station->disconnect_pending,
dbus_error_aborted(station->disconnect_pending));
if (station->scan_pending)
dbus_pending_reply(&station->scan_pending,
dbus_error_aborted(station->scan_pending));
if (station->dbus_scan_id)
scan_cancel(netdev_get_wdev_id(station->netdev),
station->dbus_scan_id);
if (station->quick_scan_id)
scan_cancel(netdev_get_wdev_id(station->netdev),
station->quick_scan_id);
if (station->hidden_network_scan_id)
scan_cancel(netdev_get_wdev_id(station->netdev),
station->hidden_network_scan_id);
if (station->owe_hidden_scan_ids) {
void *ptr;
while ((ptr = l_queue_pop_head(station->owe_hidden_scan_ids)))
scan_cancel(netdev_get_wdev_id(station->netdev),
L_PTR_TO_UINT(ptr));
l_queue_destroy(station->owe_hidden_scan_ids, NULL);
}
station_roam_state_clear(station);
l_queue_destroy(station->networks_sorted, NULL);
l_hashmap_destroy(station->networks, network_free);
l_queue_destroy(station->bss_list, bss_free);
l_queue_destroy(station->hidden_bss_list_sorted, NULL);
l_queue_destroy(station->autoconnect_list, NULL);
watchlist_destroy(&station->state_watches);
l_queue_destroy(station->anqp_pending, remove_anqp);
scan_freq_set_free(station->scan_freqs_order[0]);
scan_freq_set_free(station->scan_freqs_order[1]);
if (station->scan_freqs_order[2])
scan_freq_set_free(station->scan_freqs_order[2]);
wiphy_state_watch_remove(station->wiphy, station->wiphy_watch);
l_queue_destroy(station->roam_bss_list, l_free);
if (station->affinity_watch)
l_dbus_remove_watch(dbus_get_bus(), station->affinity_watch);
l_queue_destroy(station->affinities, l_free);
l_free(station);
}
static void station_setup_interface(struct l_dbus_interface *interface)
{
l_dbus_interface_method(interface, "ConnectHiddenNetwork", 0,
station_dbus_connect_hidden_network,
"", "s", "name");
l_dbus_interface_method(interface, "Disconnect", 0,
station_dbus_disconnect, "", "");
l_dbus_interface_method(interface, "GetOrderedNetworks", 0,
station_dbus_get_networks, "a(on)", "",
"networks");
l_dbus_interface_method(interface, "GetHiddenAccessPoints", 0,
station_dbus_get_hidden_access_points,
"a(sns)", "",
"accesspoints");
l_dbus_interface_method(interface, "Scan", 0,
station_dbus_scan, "", "");
l_dbus_interface_method(interface, "RegisterSignalLevelAgent", 0,
station_dbus_signal_agent_register,
"", "oan", "path", "levels");
l_dbus_interface_method(interface, "UnregisterSignalLevelAgent", 0,
station_dbus_signal_agent_unregister,
"", "o", "path");
l_dbus_interface_property(interface, "ConnectedNetwork", 0, "o",
station_property_get_connected_network,
NULL);
l_dbus_interface_property(interface, "ConnectedAccessPoint", 0, "o",
station_property_get_connected_ap,
NULL);
l_dbus_interface_property(interface, "Scanning", 0, "b",
station_property_get_scanning, NULL);
l_dbus_interface_property(interface, "State", 0, "s",
station_property_get_state, NULL);
l_dbus_interface_property(interface, "Affinities", 0, "ao",
station_property_get_affinities,
station_property_set_affinities);
}
static void station_destroy_interface(void *user_data)
{
struct station *station = user_data;
station_free(station);
}
static void station_get_diagnostic_cb(
const struct diagnostic_station_info *info,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply;
struct l_dbus_message_builder *builder;
struct handshake_state *hs = netdev_get_handshake(station->netdev);
uint16_t channel_num;
if (!info) {
reply = dbus_error_aborted(station->get_station_pending);
goto done;
}
channel_num = band_freq_to_channel(station->connected_bss->frequency,
NULL);
reply = l_dbus_message_new_method_return(station->get_station_pending);
builder = l_dbus_message_builder_new(reply);
l_dbus_message_builder_enter_array(builder, "{sv}");
dbus_append_dict_basic(builder, "ConnectedBss", 's',
util_address_to_string(info->addr));
dbus_append_dict_basic(builder, "Frequency", 'u',
&station->connected_bss->frequency);
if (channel_num != 0)
dbus_append_dict_basic(builder, "Channel", 'q', &channel_num);
dbus_append_dict_basic(builder, "Security", 's',
diagnostic_akm_suite_to_security(hs->akm_suite,
hs->wpa_ie));
if (hs->pairwise_cipher) {
const char *str;
if (hs->pairwise_cipher ==
IE_RSN_CIPHER_SUITE_USE_GROUP_CIPHER)
str = ie_rsn_cipher_suite_to_string(hs->group_cipher);
else
str = ie_rsn_cipher_suite_to_string(
hs->pairwise_cipher);
if (str)
dbus_append_dict_basic(builder, "PairwiseCipher",
's', str);
}
diagnostic_info_to_dict(info, builder);
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_finalize(builder);
l_dbus_message_builder_destroy(builder);
done:
dbus_pending_reply(&station->get_station_pending, reply);
}
static void station_get_diagnostic_destroy(void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply;
if (station->get_station_pending) {
reply = dbus_error_aborted(station->get_station_pending);
dbus_pending_reply(&station->get_station_pending, reply);
}
}
static struct l_dbus_message *station_get_diagnostics(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
int ret;
if (station->get_station_pending)
return dbus_error_busy(message);
ret = netdev_get_current_station(station->netdev,
station_get_diagnostic_cb, station,
station_get_diagnostic_destroy);
if (ret < 0)
return dbus_error_from_errno(ret, message);
station->get_station_pending = l_dbus_message_ref(message);
return NULL;
}
struct station_roam_data {
struct station *station;
struct l_dbus_message *pending;
uint8_t bssid[6];
};
static void station_force_roam_scan_triggered(int err, void *user_data)
{
struct station_roam_data *data = user_data;
struct station *station = data->station;
if (err)
station_roam_failed(station);
}
static bool station_force_roam_scan_notify(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *user_data)
{
struct station_roam_data *data = user_data;
struct station *station = data->station;
struct scan_bss *target;
struct l_dbus_message *reply;
if (err) {
reply = dbus_error_from_errno(err, data->pending);
goto reply;
}
target = l_queue_remove_if(bss_list, bss_match_bssid, data->bssid);
if (!target) {
reply = dbus_error_not_found(data->pending);
goto reply;
}
l_debug("Attempting forced roam to BSS "MAC, MAC_STR(target->addr));
/* The various roam routines expect this to be set from scanning */
station->preparing_roam = true;
l_queue_push_tail(station->roam_bss_list,
roam_bss_from_scan_bss(target, target->rank));
station_update_roam_bss(station, target);
station_transition_start(station);
reply = l_dbus_message_new_method_return(data->pending);
reply:
dbus_pending_reply(&data->pending, reply);
return false;
}
static void station_force_roam_scan_destroy(void *user_data)
{
struct station_roam_data *data = user_data;
data->station->roam_scan_id = 0;
if (data->pending)
l_dbus_message_unref(data->pending);
l_free(data);
}
static struct l_dbus_message *station_force_roam(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct scan_bss *target;
struct l_dbus_message_iter iter;
uint8_t *mac;
uint32_t mac_len;
struct scan_parameters params = { 0 };
struct scan_freq_set *freqs = NULL;
struct station_roam_data *data;
if (!l_dbus_message_get_arguments(message, "ay", &iter))
goto invalid_args;
if (!l_dbus_message_iter_get_fixed_array(&iter, &mac, &mac_len))
goto invalid_args;
if (mac_len != 6)
return dbus_error_invalid_args(message);
if (!station->connected_network)
return dbus_error_not_connected(message);
target = network_bss_find_by_addr(station->connected_network, mac);
if (!target)
goto full_scan;
if (target && target == station->connected_bss)
return dbus_error_already_exists(message);
if (station->connected_bss->ssid_len != target->ssid_len)
goto invalid_args;
if (memcmp(station->connected_bss->ssid, target->ssid,
target->ssid_len))
goto invalid_args;
/*
* Always scan before a roam to ensure the kernel has the BSS in its
* cache. If we already see the BSS only scan that frequency
*/
freqs = scan_freq_set_new();
scan_freq_set_add(freqs, target->frequency);
params.freqs = freqs;
full_scan:
params.flush = true;
data = l_new(struct station_roam_data, 1);
data->station = station;
data->pending = l_dbus_message_ref(message);
memcpy(data->bssid, mac, 6);
station->roam_scan_id = scan_active_full(
netdev_get_wdev_id(station->netdev),
&params,
station_force_roam_scan_triggered,
station_force_roam_scan_notify, data,
station_force_roam_scan_destroy);
if (freqs)
scan_freq_set_free(freqs);
if (!station->roam_scan_id) {
l_free(data);
return dbus_error_failed(message);
}
if (freqs)
l_debug("Scanning on %u for BSS "MAC, target->frequency,
MAC_STR(mac));
else
l_debug("Full scan for BSS "MAC, MAC_STR(mac));
return NULL;
invalid_args:
return dbus_error_invalid_args(message);
}
static struct network *station_find_network_from_bss(struct station *station,
struct scan_bss *bss)
{
enum security security;
char ssid[33];
memcpy(ssid, bss->ssid, bss->ssid_len);
ssid[bss->ssid_len] = '\0';
if (scan_bss_get_security(bss, &security) < 0)
return NULL;
return station_network_find(station, ssid, security);
}
static void station_setup_diagnostic_interface(
struct l_dbus_interface *interface)
{
l_dbus_interface_method(interface, "GetDiagnostics", 0,
station_get_diagnostics, "a{sv}", "",
"diagnostics");
}
static void station_destroy_diagnostic_interface(void *user_data)
{
}
static struct l_dbus_message *station_force_connect_bssid(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct l_queue *bss_list;
struct scan_bss *target;
struct network *network;
struct l_dbus_message_iter iter;
uint8_t *mac;
uint32_t mac_len;
if (!l_dbus_message_get_arguments(message, "ay", &iter))
goto invalid_args;
if (!l_dbus_message_iter_get_fixed_array(&iter, &mac, &mac_len))
goto invalid_args;
if (mac_len != 6)
return dbus_error_invalid_args(message);
bss_list = station_get_bss_list(station);
target = l_queue_find(bss_list, bss_match_bssid, mac);
if (!target)
return dbus_error_invalid_args(message);
if (util_ssid_is_hidden(target->ssid_len, target->ssid))
return dbus_error_not_found(message);
network = station_find_network_from_bss(station, target);
if (!network)
return dbus_error_invalid_args(message);
l_debug("Attempting forced connection to BSS "MAC, MAC_STR(mac));
return __network_connect(network, target, message);
invalid_args:
return dbus_error_invalid_args(message);
}
static void station_debug_scan_triggered(int err, void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply;
if (err < 0) {
if (station->scan_pending) {
reply = dbus_error_from_errno(err,
station->scan_pending);
dbus_pending_reply(&station->scan_pending, reply);
}
station_dbus_scan_done(station, false);
return;
}
l_debug("debug scan triggered for %s",
netdev_get_name(station->netdev));
if (station->scan_pending) {
reply = l_dbus_message_new_method_return(station->scan_pending);
l_dbus_message_set_arguments(reply, "");
dbus_pending_reply(&station->scan_pending, reply);
}
station_property_set_scanning(station, true);
}
static bool station_debug_scan_results(int err, struct l_queue *bss_list,
const struct scan_freq_set *freqs,
void *userdata)
{
struct station *station = userdata;
if (err) {
station_dbus_scan_done(station, false);
return false;
}
station_set_scan_results(station, bss_list, freqs, false);
station_dbus_scan_done(station, false);
return true;
}
static struct l_dbus_message *station_debug_scan(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message_iter iter;
uint16_t *freqs;
uint32_t freqs_len;
struct scan_freq_set *freq_set;
unsigned int i;
if (station->dbus_scan_id)
return dbus_error_busy(message);
if (L_IN_SET(station->state, STATION_STATE_CONNECTING,
STATION_STATE_CONNECTING_AUTO,
STATION_STATE_NETCONFIG) ||
station_is_roaming(station))
return dbus_error_busy(message);
if (!l_dbus_message_get_arguments(message, "aq", &iter))
goto invalid_args;
if (!l_dbus_message_iter_get_fixed_array(&iter, &freqs, &freqs_len))
goto invalid_args;
freq_set = scan_freq_set_new();
for (i = 0; i < freqs_len; i++) {
if (scan_freq_set_contains(freq_set, (uint32_t)freqs[i]))
continue;
if (!scan_freq_set_add(freq_set, (uint32_t)freqs[i])) {
scan_freq_set_free(freq_set);
goto invalid_args;
}
l_debug("added frequency %u", freqs[i]);
}
station->dbus_scan_id = station_scan_trigger(station, freq_set,
station_debug_scan_triggered,
station_debug_scan_results,
NULL);
scan_freq_set_free(freq_set);
if (!station->dbus_scan_id)
goto failed;
station->scan_pending = l_dbus_message_ref(message);
return NULL;
failed:
return dbus_error_failed(message);
invalid_args:
return dbus_error_invalid_args(message);
}
static bool station_property_get_autoconnect(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct station *station = user_data;
bool autoconnect;
autoconnect = station->autoconnect;
l_dbus_message_builder_append_basic(builder, 'b', &autoconnect);
return true;
}
static struct l_dbus_message *station_property_set_autoconnect(
struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_iter *new_value,
l_dbus_property_complete_cb_t complete,
void *user_data)
{
struct station *station = user_data;
bool autoconnect;
if (!l_dbus_message_iter_get_variant(new_value, "b", &autoconnect))
return dbus_error_invalid_args(message);
l_debug("Setting autoconnect %s", autoconnect ? "true" : "false");
station_set_autoconnect(station, autoconnect);
return l_dbus_message_new_method_return(message);
}
static void station_append_byte_array(struct l_dbus_message_builder *builder,
const char *name,
const uint8_t *bytes, size_t len)
{
size_t i;
l_dbus_message_builder_enter_dict(builder, "sv");
l_dbus_message_builder_append_basic(builder, 's', name);
l_dbus_message_builder_enter_variant(builder, "ay");
l_dbus_message_builder_enter_array(builder, "y");
for (i = 0; i < len; i++)
l_dbus_message_builder_append_basic(builder, 'y', &bytes[i]);
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_leave_variant(builder);
l_dbus_message_builder_leave_dict(builder);
}
static void station_append_bss_list(struct l_dbus_message_builder *builder,
const struct l_queue_entry *entry)
{
for (; entry; entry = entry->next) {
struct scan_bss *bss = entry->data;
int32_t rssi = bss->signal_strength / 100;
l_dbus_message_builder_enter_array(builder, "{sv}");
dbus_append_dict_basic(builder, "Frequency", 'u',
&bss->frequency);
dbus_append_dict_basic(builder, "RSSI", 'i',
&rssi);
dbus_append_dict_basic(builder, "Rank", 'q', &bss->rank);
dbus_append_dict_basic(builder, "Address", 's',
util_address_to_string(bss->addr));
station_append_byte_array(builder, "MDE", bss->mde, 3);
l_dbus_message_builder_leave_array(builder);
}
}
static struct l_dbus_message *station_debug_get_networks(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct station *station = user_data;
struct l_dbus_message *reply =
l_dbus_message_new_method_return(message);
struct l_dbus_message_builder *builder =
l_dbus_message_builder_new(reply);
const struct l_queue_entry *entry;
l_dbus_message_builder_enter_array(builder, "{oaa{sv}}");
if (l_queue_isempty(station->networks_sorted))
goto done;
for (entry = l_queue_get_entries(station->networks_sorted); entry;
entry = entry->next) {
const struct network *network = entry->data;
l_dbus_message_builder_enter_dict(builder, "oaa{sv}");
l_dbus_message_builder_append_basic(builder, 'o',
network_get_path(network));
l_dbus_message_builder_enter_array(builder, "a{sv}");
station_append_bss_list(builder,
network_bss_list_get_entries(network));
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_leave_dict(builder);
}
done:
l_dbus_message_builder_leave_array(builder);
l_dbus_message_builder_finalize(builder);
l_dbus_message_builder_destroy(builder);
return reply;
}
static void station_setup_debug_interface(
struct l_dbus_interface *interface)
{
l_dbus_interface_method(interface, "ConnectBssid", 0,
station_force_connect_bssid, "", "ay",
"mac");
l_dbus_interface_method(interface, "Roam", 0,
station_force_roam, "", "ay", "mac");
l_dbus_interface_method(interface, "Scan", 0,
station_debug_scan, "", "aq",
"frequencies");
l_dbus_interface_method(interface, "GetNetworks", 0,
station_debug_get_networks, "a{oaa{sv}}", "",
"networks");
l_dbus_interface_signal(interface, "Event", 0, "sav", "name", "data");
l_dbus_interface_property(interface, "AutoConnect", 0, "b",
station_property_get_autoconnect,
station_property_set_autoconnect);
}
static void ap_roam_frame_event(const struct mmpdu_header *hdr,
const void *body, size_t body_len,
int rssi, void *user_data)
{
uint32_t ifindex = L_PTR_TO_UINT(user_data);
struct station *station = station_find(ifindex);
if (!station)
return;
station_ap_directed_roam(station, hdr, body, body_len);
}
static void add_frame_watches(struct netdev *netdev)
{
static const uint8_t action_ap_roam_prefix[2] = { 0x0a, 0x07 };
/*
* register for AP roam transition watch
*/
frame_watch_add(netdev_get_wdev_id(netdev), 0, 0x00d0,
action_ap_roam_prefix, sizeof(action_ap_roam_prefix),
false, ap_roam_frame_event,
L_UINT_TO_PTR(netdev_get_ifindex(netdev)), NULL);
}
static void station_netdev_watch(struct netdev *netdev,
enum netdev_watch_event event, void *userdata)
{
switch (event) {
case NETDEV_WATCH_EVENT_NEW:
if (netdev_get_iftype(netdev) == NETDEV_IFTYPE_STATION) {
add_frame_watches(netdev);
if (netdev_get_is_up(netdev))
station_create(netdev);
}
break;
case NETDEV_WATCH_EVENT_UP:
if (netdev_get_iftype(netdev) == NETDEV_IFTYPE_STATION)
station_create(netdev);
break;
case NETDEV_WATCH_EVENT_DOWN:
case NETDEV_WATCH_EVENT_DEL:
l_dbus_object_remove_interface(dbus_get_bus(),
netdev_get_path(netdev),
IWD_STATION_INTERFACE);
break;
case NETDEV_WATCH_EVENT_IFTYPE_CHANGE:
if (netdev_get_iftype(netdev) == NETDEV_IFTYPE_STATION)
add_frame_watches(netdev);
break;
default:
break;
}
}
static void station_known_networks_changed(enum known_networks_event event,
const struct network_info *info,
void *user_data)
{
_auto_(l_free) char *network_id = NULL;
if (event != KNOWN_NETWORKS_EVENT_REMOVED)
return;
if (info->type != SECURITY_8021X)
return;
network_id = l_util_hexstring(info->ssid, strlen(info->ssid));
eap_tls_forget_peer(network_id);
}
static int station_init(void)
{
if (scan_get_band_rank_modifier(BAND_FREQ_2_4_GHZ))
allowed_bands |= BAND_FREQ_2_4_GHZ;
if (scan_get_band_rank_modifier(BAND_FREQ_5_GHZ))
allowed_bands |= BAND_FREQ_5_GHZ;
if (scan_get_band_rank_modifier(BAND_FREQ_6_GHZ))
allowed_bands |= BAND_FREQ_6_GHZ;
if (!(allowed_bands & (BAND_FREQ_2_4_GHZ | BAND_FREQ_5_GHZ))) {
l_error("At least 2.4GHz and 5GHz bands must be enabled for "
"IWD to start, check [Rank].BandModifier* setting");
return -ENOTSUP;
}
station_list = l_queue_new();
netdev_watch = netdev_watch_add(station_netdev_watch, NULL, NULL);
l_dbus_register_interface(dbus_get_bus(), IWD_STATION_INTERFACE,
station_setup_interface,
station_destroy_interface, false);
l_dbus_register_interface(dbus_get_bus(),
IWD_STATION_DIAGNOSTIC_INTERFACE,
station_setup_diagnostic_interface,
station_destroy_diagnostic_interface,
false);
if (iwd_is_developer_mode())
l_dbus_register_interface(dbus_get_bus(),
IWD_STATION_DEBUG_INTERFACE,
station_setup_debug_interface,
NULL,
false);
if (!l_settings_get_uint(iwd_get_config(), "General",
"ManagementFrameProtection",
&mfp_setting))
mfp_setting = 1;
if (mfp_setting > 2) {
l_error("Invalid [General].ManagementFrameProtection value: %d,"
" using default of 1", mfp_setting);
mfp_setting = 1;
}
if (!l_settings_get_uint(iwd_get_config(), "General",
"RoamRetryInterval",
&roam_retry_interval))
roam_retry_interval = 60;
if (roam_retry_interval > INT_MAX)
roam_retry_interval = INT_MAX;
if (!l_settings_get_bool(iwd_get_config(), "General", "DisableANQP",
&anqp_disabled))
anqp_disabled = true;
if (!netconfig_enabled())
l_info("station: Network configuration is disabled.");
supports_arp_evict_nocarrier = sysfs_supports_ipv4_setting("all",
"arp_evict_nocarrier");
supports_ndisc_evict_nocarrier = sysfs_supports_ipv6_setting("all",
"ndisc_evict_nocarrier");
supports_drop_gratuitous_arp = sysfs_supports_ipv4_setting("all",
"drop_gratuitous_arp");
supports_drop_unsolicited_na = sysfs_supports_ipv6_setting("all",
"drop_unsolicited_na");
supports_ipv4_drop_unicast_in_l2_multicast =
sysfs_supports_ipv4_setting("all",
"drop_unicast_in_l2_multicast");
supports_ipv6_drop_unicast_in_l2_multicast =
sysfs_supports_ipv6_setting("all",
"drop_unicast_in_l2_multicast");
watchlist_init(&event_watches, NULL);
eap_tls_set_session_cache_ops(storage_eap_tls_cache_load,
storage_eap_tls_cache_sync);
known_networks_watch = known_networks_watch_add(
station_known_networks_changed,
NULL, NULL);
return 0;
}
static void station_exit(void)
{
l_dbus_unregister_interface(dbus_get_bus(),
IWD_STATION_DIAGNOSTIC_INTERFACE);
if (iwd_is_developer_mode())
l_dbus_unregister_interface(dbus_get_bus(),
IWD_STATION_DEBUG_INTERFACE);
l_dbus_unregister_interface(dbus_get_bus(), IWD_STATION_INTERFACE);
netdev_watch_remove(netdev_watch);
l_queue_destroy(station_list, NULL);
station_list = NULL;
watchlist_destroy(&event_watches);
known_networks_watch_remove(known_networks_watch);
known_networks_watch = 0;
}
IWD_MODULE(station, station_init, station_exit)
IWD_MODULE_DEPENDS(station, known_networks)
IWD_MODULE_DEPENDS(station, netdev);
IWD_MODULE_DEPENDS(station, netconfig);
IWD_MODULE_DEPENDS(station, frame_xchg);
IWD_MODULE_DEPENDS(station, wiphy);