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iwd/src/device.c

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/*
*
* Wireless daemon for Linux
*
* Copyright (C) 2013-2016 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
#include <stdio.h>
#include <errno.h>
#include <time.h>
#include <linux/if_ether.h>
#include <ell/ell.h>
#include "src/iwd.h"
#include "src/common.h"
#include "src/util.h"
#include "src/ie.h"
#include "src/handshake.h"
#include "src/wiphy.h"
#include "src/scan.h"
#include "src/netdev.h"
#include "src/dbus.h"
#include "src/network.h"
#include "src/device.h"
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#include "src/watchlist.h"
struct device_watchlist_item {
uint32_t id;
device_watch_func_t added;
device_watch_func_t removed;
void *userdata;
device_destroy_func_t destroy;
};
struct autoconnect_entry {
uint16_t rank;
struct network *network;
struct scan_bss *bss;
};
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struct device {
uint32_t index;
enum device_state state;
struct l_queue *bss_list;
struct l_queue *old_bss_list;
struct l_dbus_message *scan_pending;
struct l_hashmap *networks;
struct l_queue *networks_sorted;
struct scan_bss *connected_bss;
struct network *connected_network;
struct l_queue *autoconnect_list;
struct l_dbus_message *connect_pending;
struct l_dbus_message *disconnect_pending;
uint32_t netdev_watch_id;
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struct watchlist state_watches;
struct timespec roam_min_time;
struct l_timeout *roam_trigger_timeout;
uint32_t roam_scan_id;
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struct wiphy *wiphy;
struct netdev *netdev;
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bool scanning : 1;
bool autoconnect : 1;
bool preparing_roam : 1;
bool signal_low : 1;
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};
static struct watchlist device_watches;
static struct l_queue *device_list;
static void device_roam_timeout_rearm(struct device *device, int seconds);
uint32_t device_watch_add(device_watch_func_t func,
void *userdata, device_destroy_func_t destroy)
{
return watchlist_add(&device_watches, func, userdata, destroy);
}
bool device_watch_remove(uint32_t id)
{
return watchlist_remove(&device_watches, id);
}
void __iwd_device_foreach(iwd_device_foreach_func func, void *user_data)
{
const struct l_queue_entry *device_entry;
for (device_entry = l_queue_get_entries(device_list); device_entry;
device_entry = device_entry->next) {
struct device *device = device_entry->data;
func(device, user_data);
}
}
static const char *iwd_network_get_path(struct device *device,
const char *ssid,
enum security security)
{
static char path[256];
unsigned int pos, i;
pos = snprintf(path, sizeof(path), "%s/", device_get_path(device));
for (i = 0; ssid[i] && pos < sizeof(path); i++)
pos += snprintf(path + pos, sizeof(path) - pos, "%02x",
ssid[i]);
snprintf(path + pos, sizeof(path) - pos, "_%s",
security_to_str(security));
return path;
}
static const char *device_state_to_string(enum device_state state)
{
switch (state) {
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case DEVICE_STATE_OFF:
return "off";
case DEVICE_STATE_DISCONNECTED:
return "disconnected";
case DEVICE_STATE_AUTOCONNECT:
return "autoconnect";
case DEVICE_STATE_CONNECTING:
return "connecting";
case DEVICE_STATE_CONNECTED:
return "connected";
case DEVICE_STATE_DISCONNECTING:
return "disconnecting";
case DEVICE_STATE_ROAMING:
return "roaming";
}
return "invalid";
}
static void device_autoconnect_next(struct device *device)
{
struct autoconnect_entry *entry;
int r;
while ((entry = l_queue_pop_head(device->autoconnect_list))) {
l_debug("Considering autoconnecting to BSS '%s' with SSID: %s,"
" freq: %u, rank: %u, strength: %i",
util_address_to_string(entry->bss->addr),
network_get_ssid(entry->network),
entry->bss->frequency, entry->rank,
entry->bss->signal_strength);
/* TODO: Blacklist the network from auto-connect */
r = network_autoconnect(entry->network, entry->bss);
l_free(entry);
if (!r)
return;
}
}
static void bss_free(void *data)
{
struct scan_bss *bss = data;
const char *addr;
addr = util_address_to_string(bss->addr);
l_debug("Freeing BSS %s", addr);
scan_bss_free(bss);
}
static void network_free(void *data)
{
struct network *network = data;
network_remove(network, -ESHUTDOWN);
}
static int autoconnect_rank_compare(const void *a, const void *b, void *user)
{
const struct autoconnect_entry *new_ae = a;
const struct autoconnect_entry *ae = b;
return ae->rank - new_ae->rank;
}
static bool process_network(const void *key, void *data, void *user_data)
{
struct network *network = data;
struct device *device = user_data;
if (!network_bss_list_isempty(network)) {
/* Build the network list ordered by rank */
network_rank_update(network);
l_queue_insert(device->networks_sorted, network,
network_rank_compare, NULL);
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 void process_bss(struct device *device, struct scan_bss *bss,
struct timespec *timestamp)
{
struct network *network;
struct ie_rsn_info info;
int r;
enum security security;
const char *path;
double rankmod;
struct autoconnect_entry *entry;
char ssid[33];
l_debug("Found BSS '%s' with SSID: %s, freq: %u, rank: %u, "
"strength: %i",
util_address_to_string(bss->addr),
util_ssid_to_utf8(bss->ssid_len, bss->ssid),
bss->frequency, bss->rank, bss->signal_strength);
if (!util_ssid_is_utf8(bss->ssid_len, bss->ssid)) {
l_warn("Ignoring BSS with non-UTF8 SSID");
return;
}
memcpy(ssid, bss->ssid, bss->ssid_len);
ssid[bss->ssid_len] = '\0';
memset(&info, 0, sizeof(info));
r = scan_bss_get_rsn_info(bss, &info);
if (r < 0) {
if (r != -ENOENT)
return;
security = scan_get_security(bss->capability, NULL);
} else
security = scan_get_security(bss->capability, &info);
path = iwd_network_get_path(device, ssid, security);
network = l_hashmap_lookup(device->networks, path);
if (!network) {
network = network_create(device, ssid, security);
if (!network_register(network, path)) {
network_remove(network, -EINVAL);
return;
}
l_hashmap_insert(device->networks,
network_get_path(network), network);
l_debug("Added new Network \"%s\" security %s",
network_get_ssid(network), security_to_str(security));
}
if (network_bss_list_isempty(network))
network_seen(network, timestamp);
network_bss_add(network, bss);
if (device->state != DEVICE_STATE_AUTOCONNECT)
return;
/* See if network is autoconnectable (is a known network) */
if (!network_rankmod(network, &rankmod))
return;
entry = l_new(struct autoconnect_entry, 1);
entry->network = network;
entry->bss = bss;
entry->rank = bss->rank * rankmod;
l_queue_insert(device->autoconnect_list, entry,
autoconnect_rank_compare, NULL);
}
static bool bss_match(const void *a, const void *b)
{
const struct scan_bss *bss_a = a;
const struct scan_bss *bss_b = b;
return !memcmp(bss_a->addr, bss_b->addr, sizeof(bss_a->addr));
}
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/*
* Used when scan results were obtained; either from passive scan running
* inside device.c or active scans running in other state machines, e.g. wsc.c
*/
void device_set_scan_results(struct device *device, struct l_queue *bss_list)
{
struct network *network;
const struct l_queue_entry *bss_entry;
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
device->old_bss_list = device->bss_list;
device->bss_list = bss_list;
while ((network = l_queue_pop_head(device->networks_sorted)))
network_bss_list_clear(network);
l_queue_destroy(device->autoconnect_list, l_free);
device->autoconnect_list = l_queue_new();
for (bss_entry = l_queue_get_entries(bss_list); bss_entry;
bss_entry = bss_entry->next) {
struct scan_bss *bss = bss_entry->data;
process_bss(device, bss, &now);
}
if (device->connected_bss) {
struct scan_bss *bss;
bss = l_queue_find(device->bss_list, bss_match,
device->connected_bss);
if (!bss) {
l_warn("Connected BSS not in scan results!");
l_queue_push_tail(device->bss_list,
device->connected_bss);
network_bss_add(device->connected_network,
device->connected_bss);
l_queue_remove(device->old_bss_list,
device->connected_bss);
} else
device->connected_bss = bss;
}
l_hashmap_foreach_remove(device->networks, process_network, device);
l_queue_destroy(device->old_bss_list, bss_free);
device->old_bss_list = NULL;
if (device->state == DEVICE_STATE_AUTOCONNECT)
device_autoconnect_next(device);
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}
static bool new_scan_results(uint32_t wiphy_id, uint32_t ifindex, int err,
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struct l_queue *bss_list, void *userdata)
{
struct device *device = userdata;
struct l_dbus *dbus = dbus_get_bus();
device->scanning = false;
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Scanning");
if (err)
return false;
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device_set_scan_results(device, bss_list);
return true;
}
struct network *device_get_connected_network(struct device *device)
{
return device->connected_network;
}
const char *device_get_path(struct device *device)
{
static char path[26];
snprintf(path, sizeof(path), "%s/%u", wiphy_get_path(device->wiphy),
device->index);
return path;
}
bool device_is_busy(struct device *device)
{
if (device->state != DEVICE_STATE_DISCONNECTED &&
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device->state != DEVICE_STATE_AUTOCONNECT &&
device->state != DEVICE_STATE_OFF)
return true;
return false;
}
struct wiphy *device_get_wiphy(struct device *device)
{
return device->wiphy;
}
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struct netdev *device_get_netdev(struct device *device)
{
return device->netdev;
}
uint32_t device_get_ifindex(struct device *device)
{
return device->index;
}
const uint8_t *device_get_address(struct device *device)
{
return netdev_get_address(device->netdev);
}
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enum device_state device_get_state(struct device *device)
{
return device->state;
}
static void periodic_scan_trigger(int err, void *user_data)
{
struct device *device = user_data;
struct l_dbus *dbus = dbus_get_bus();
device->scanning = true;
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Scanning");
}
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uint32_t device_add_state_watch(struct device *device,
device_state_watch_func_t func,
void *user_data,
device_destroy_func_t destroy)
{
return watchlist_add(&device->state_watches, func, user_data, destroy);
}
bool device_remove_state_watch(struct device *device, uint32_t id)
{
return watchlist_remove(&device->state_watches, id);
}
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struct network *device_network_find(struct device *device, const char *ssid,
enum security security)
{
const char *path = iwd_network_get_path(device, ssid, security);
return l_hashmap_lookup(device->networks, path);
}
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static void device_enter_state(struct device *device, enum device_state state)
{
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struct l_dbus *dbus = dbus_get_bus();
bool disconnected;
l_debug("Old State: %s, new state: %s",
device_state_to_string(device->state),
device_state_to_string(state));
switch (state) {
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case DEVICE_STATE_OFF:
scan_periodic_stop(device->index);
break;
case DEVICE_STATE_AUTOCONNECT:
scan_periodic_start(device->index, periodic_scan_trigger,
new_scan_results, device);
break;
case DEVICE_STATE_DISCONNECTED:
scan_periodic_stop(device->index);
break;
case DEVICE_STATE_CONNECTED:
scan_periodic_stop(device->index);
break;
case DEVICE_STATE_CONNECTING:
break;
case DEVICE_STATE_DISCONNECTING:
break;
case DEVICE_STATE_ROAMING:
break;
}
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disconnected = device->state <= DEVICE_STATE_AUTOCONNECT;
if ((disconnected && state > DEVICE_STATE_AUTOCONNECT) ||
(!disconnected && state != device->state))
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "State");
device->state = state;
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WATCHLIST_NOTIFY(&device->state_watches,
device_state_watch_func_t, state);
}
static void device_reset_connection_state(struct device *device)
{
struct network *network = device->connected_network;
struct l_dbus *dbus = dbus_get_bus();
if (!network)
return;
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if (device->state == DEVICE_STATE_CONNECTED ||
device->state == DEVICE_STATE_ROAMING)
network_disconnected(network);
l_timeout_remove(device->roam_trigger_timeout);
device->roam_trigger_timeout = NULL;
device->preparing_roam = false;
device->signal_low = false;
device->roam_min_time.tv_sec = 0;
if (device->roam_scan_id)
scan_cancel(device->index, device->roam_scan_id);
device->connected_bss = NULL;
device->connected_network = NULL;
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "ConnectedNetwork");
l_dbus_property_changed(dbus, network_get_path(network),
IWD_NETWORK_INTERFACE, "Connected");
}
static void device_disassociated(struct device *device)
{
l_debug("%d", device->index);
device_reset_connection_state(device);
device_enter_state(device, DEVICE_STATE_DISCONNECTED);
if (device->autoconnect)
device_enter_state(device, DEVICE_STATE_AUTOCONNECT);
}
static void device_lost_beacon(struct device *device)
{
l_debug("%d", device->index);
if (device->connect_pending)
dbus_pending_reply(&device->connect_pending,
dbus_error_failed(device->connect_pending));
device_disassociated(device);
}
static void device_disconnect_by_ap(struct device *device)
{
l_debug("%d", device->index);
if (device->connect_pending) {
struct network *network = device->connected_network;
dbus_pending_reply(&device->connect_pending,
dbus_error_failed(device->connect_pending));
network_connect_failed(network);
}
device_disassociated(device);
}
static enum ie_rsn_akm_suite device_select_akm_suite(struct network *network,
struct scan_bss *bss,
struct ie_rsn_info *info)
{
enum security security = network_get_security(network);
/*
* If FT is available, use FT authentication to keep the door open
* for fast transitions. Otherwise use SHA256 version if present.
*/
if (security == SECURITY_8021X) {
if ((info->akm_suites & IE_RSN_AKM_SUITE_FT_OVER_8021X) &&
bss->rsne && bss->mde_present)
return IE_RSN_AKM_SUITE_FT_OVER_8021X;
if (info->akm_suites & IE_RSN_AKM_SUITE_8021X_SHA256)
return IE_RSN_AKM_SUITE_8021X_SHA256;
if (info->akm_suites & IE_RSN_AKM_SUITE_8021X)
return IE_RSN_AKM_SUITE_8021X;
} else if (security == SECURITY_PSK) {
if ((info->akm_suites & IE_RSN_AKM_SUITE_FT_USING_PSK) &&
bss->rsne && bss->mde_present)
return IE_RSN_AKM_SUITE_FT_USING_PSK;
if (info->akm_suites & IE_RSN_AKM_SUITE_PSK_SHA256)
return IE_RSN_AKM_SUITE_PSK_SHA256;
if (info->akm_suites & IE_RSN_AKM_SUITE_PSK)
return IE_RSN_AKM_SUITE_PSK;
}
return 0;
}
static struct handshake_state *device_handshake_setup(struct device *device,
struct network *network,
struct scan_bss *bss)
{
enum security security = network_get_security(network);
struct wiphy *wiphy = device->wiphy;
struct handshake_state *hs;
bool add_mde = false;
hs = handshake_state_new(netdev_get_ifindex(device->netdev));
if (security == SECURITY_PSK || security == SECURITY_8021X) {
const struct l_settings *settings = iwd_get_config();
struct ie_rsn_info bss_info;
uint8_t rsne_buf[256];
struct ie_rsn_info info;
const char *ssid;
uint32_t mfp_setting;
memset(&info, 0, sizeof(info));
memset(&bss_info, 0, sizeof(bss_info));
scan_bss_get_rsn_info(bss, &bss_info);
info.akm_suites = device_select_akm_suite(network, bss,
&bss_info);
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;
if (!l_settings_get_uint(settings, "General",
"ManagementFrameProtection", &mfp_setting))
mfp_setting = 1;
if (mfp_setting > 2) {
l_error("Invalid MFP value, using default of 1");
mfp_setting = 1;
}
switch (mfp_setting) {
case 0:
break;
case 1:
info.group_management_cipher =
wiphy_select_cipher(wiphy,
bss_info.group_management_cipher);
info.mfpc = info.group_management_cipher != 0;
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;
ssid = network_get_ssid(network);
handshake_state_set_ssid(hs, (void *) ssid, strlen(ssid));
/* RSN takes priority */
if (bss->rsne) {
ie_build_rsne(&info, rsne_buf);
handshake_state_set_ap_rsn(hs, bss->rsne);
handshake_state_set_own_rsn(hs, rsne_buf);
} else {
ie_build_wpa(&info, rsne_buf);
handshake_state_set_ap_wpa(hs, bss->wpa);
handshake_state_set_own_wpa(hs, rsne_buf);
}
if (security == SECURITY_PSK)
handshake_state_set_pmk(hs, network_get_psk(network));
else
handshake_state_set_8021x_config(hs,
network_get_settings(network));
if (info.akm_suites & (IE_RSN_AKM_SUITE_FT_OVER_8021X |
IE_RSN_AKM_SUITE_FT_USING_PSK |
IE_RSN_AKM_SUITE_FT_OVER_SAE_SHA256))
add_mde = true;
}
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 hs;
not_supported:
handshake_state_free(hs);
return NULL;
}
static void device_roam_failed(struct device *device)
{
/*
* 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. Otherwise (we'd already started negotiating with the
* transition target, preparing_roam is false, state is roaming) we
* are now disconnected.
*/
l_debug("%d", device->index);
device->preparing_roam = false;
if (device->state == DEVICE_STATE_ROAMING)
device_disassociated(device);
else if (device->signal_low)
device_roam_timeout_rearm(device, 60);
}
static void device_reassociate_cb(struct netdev *netdev,
enum netdev_result result,
void *user_data)
{
struct device *device = user_data;
l_debug("%d, result: %d", device->index, result);
if (device->state != DEVICE_STATE_ROAMING)
return;
if (result == NETDEV_RESULT_OK) {
/*
* New signal high/low notification should occur on the next
* beacon from new AP.
*/
device->signal_low = false;
device->roam_min_time.tv_sec = 0;
device_enter_state(device, DEVICE_STATE_CONNECTED);
} else
device_roam_failed(device);
}
static void device_fast_transition_cb(struct netdev *netdev,
enum netdev_result result,
void *user_data)
{
struct device *device = user_data;
l_debug("%d, result: %d", device->index, result);
if (device->state != DEVICE_STATE_ROAMING)
return;
if (result == NETDEV_RESULT_OK) {
/*
* New signal high/low notification should occur on the next
* beacon from new AP.
*/
device->signal_low = false;
device->roam_min_time.tv_sec = 0;
device_enter_state(device, DEVICE_STATE_CONNECTED);
} else
device_roam_failed(device);
}
static void device_transition_start(struct device *device, struct scan_bss *bss)
{
struct handshake_state *hs = netdev_get_handshake(device->netdev);
uint16_t mdid;
struct handshake_state *new_hs;
l_debug("%d, target %s", device->index,
util_address_to_string(bss->addr));
if (hs->mde)
ie_parse_mobility_domain_from_data(hs->mde, hs->mde[1] + 2,
&mdid, NULL, NULL);
/* Can we use Fast Transition? */
if (hs->mde && bss->mde_present && l_get_le16(bss->mde) == mdid) {
/*
* There's no need to regenerate the RSNE because neither
* the AKM nor cipher suite can change:
*
* 12.5.2: "If the FTO selects a pairwise cipher suite in
* the RSNE that is different from the ones used in the
* Initial mobility domain association, then the AP shall
* reject the Authentication Request with status code 19
* (i.e., Invalid Pairwise Cipher)."
*/
if (netdev_fast_transition(device->netdev, bss,
device_fast_transition_cb) < 0) {
device_roam_failed(device);
return;
}
device->connected_bss = bss;
device->preparing_roam = false;
device_enter_state(device, DEVICE_STATE_ROAMING);
return;
}
/* Non-FT transition */
new_hs = device_handshake_setup(device, device->connected_network, bss);
if (!new_hs) {
l_error("device_handshake_setup failed in reassociation");
device_roam_failed(device);
return;
}
if (netdev_reassociate(device->netdev, bss, new_hs,
device_reassociate_cb) < 0) {
handshake_state_free(new_hs);
device_roam_failed(device);
return;
}
device->connected_bss = bss;
device->preparing_roam = false;
device_enter_state(device, DEVICE_STATE_ROAMING);
}
static void device_roam_scan_triggered(int err, void *user_data)
{
struct device *device = user_data;
if (err) {
device_roam_failed(device);
return;
}
/*
* Do not update the Scanning property as we won't be updating the
* list of networks.
*/
}
static bool device_roam_scan_notify(uint32_t wiphy_id, uint32_t ifindex,
int err, struct l_queue *bss_list,
void *userdata)
{
struct device *device = userdata;
struct network *network = device->connected_network;
struct handshake_state *hs = netdev_get_handshake(device->netdev);
struct scan_bss *bss;
struct scan_bss *best_bss = NULL;
double best_bss_rank = 0.0;
static const double RANK_FT_FACTOR = 1.3;
uint16_t mdid;
enum security orig_security, security;
struct timespec now;
bool seen = false;
if (err) {
device_roam_failed(device);
return false;
}
/*
* Do not call device_set_scan_results because this may have been
* a partial scan. We could at most update the current networks' BSS
* list in its device->networks entry.
*/
network = device->connected_network;
orig_security = network_get_security(network);
if (hs->mde)
ie_parse_mobility_domain_from_data(hs->mde, hs->mde[1] + 2,
&mdid, NULL, NULL);
/*
* 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.
*/
while ((bss = l_queue_pop_head(bss_list))) {
double rank;
struct ie_rsn_info info;
int r;
/* 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;
memset(&info, 0, sizeof(info));
r = scan_bss_get_rsn_info(bss, &info);
if (r < 0) {
if (r != -ENOENT)
goto next;
security = scan_get_security(bss->capability, NULL);
} else
security = scan_get_security(bss->capability, &info);
if (security != orig_security)
goto next;
seen = true;
if (!wiphy_can_connect(device->wiphy, bss))
goto next;
rank = bss->rank;
if (hs->mde && bss->mde_present && l_get_le16(bss->mde) == mdid)
rank *= RANK_FT_FACTOR;
if (rank > best_bss_rank) {
if (best_bss)
scan_bss_free(best_bss);
best_bss = bss;
best_bss_rank = rank;
continue;
}
next:
scan_bss_free(bss);
}
l_queue_destroy(bss_list, NULL);
if (!seen)
goto fail_free_bss;
clock_gettime(CLOCK_REALTIME, &now);
network_seen(network, &now);
/* See if we have anywhere to roam to */
if (!best_bss || bss_match(best_bss, device->connected_bss))
goto fail_free_bss;
bss = network_bss_find_by_addr(network, best_bss->addr);
if (bss) {
scan_bss_free(best_bss);
best_bss = bss;
} else {
network_bss_add(network, best_bss);
l_queue_push_tail(device->bss_list, best_bss);
}
device_transition_start(device, best_bss);
return true;
fail_free_bss:
if (best_bss)
scan_bss_free(best_bss);
device_roam_failed(device);
return true;
}
static void device_roam_scan_destroy(void *userdata)
{
struct device *device = userdata;
device->roam_scan_id = 0;
}
static void device_roam_scan(struct device *device,
struct scan_freq_set *freq_set)
{
struct scan_parameters params = { .freqs = freq_set, .flush = true };
/* Use an active scan to save time */
device->roam_scan_id = scan_active_full(device->index, &params,
device_roam_scan_triggered,
device_roam_scan_notify, device,
device_roam_scan_destroy);
if (!device->roam_scan_id)
device_roam_failed(device);
}
static void device_neighbor_report_cb(struct netdev *netdev, int err,
const uint8_t *reports,
size_t reports_len, void *user_data)
{
struct device *device = user_data;
struct ie_tlv_iter iter;
int count_md = 0, count_no_md = 0;
struct scan_freq_set *freq_set_md, *freq_set_no_md;
uint32_t current_freq = 0;
struct handshake_state *hs = netdev_get_handshake(device->netdev);
/*
* Check if we're still attempting to roam -- if dbus Disconnect
* had been called in the meantime we just abort the attempt.
*/
if (!device->preparing_roam || err == -ENODEV)
return;
if (!reports || err) {
/* Have to do a full scan */
device_roam_scan(device, NULL);
return;
}
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;
enum scan_band band;
uint32_t freq;
const uint8_t *cc = NULL;
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 (device->connected_bss->cc_present)
cc = device->connected_bss->cc;
band = scan_oper_class_to_band(cc, info.oper_class);
if (!band) {
l_debug("Ignored: unsupported oper class");
continue;
}
freq = scan_channel_to_freq(info.channel_num, band);
if (!freq) {
l_debug("Ignored: unsupported channel");
continue;
}
if (!memcmp(info.addr, device->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.
*/
current_freq = freq;
continue;
}
/* Add the frequency to one of the lists */
if (info.md && hs->mde) {
scan_freq_set_add(freq_set_md, freq);
count_md += 1;
} else {
scan_freq_set_add(freq_set_no_md, freq);
count_no_md += 1;
}
}
if (!current_freq)
current_freq = device->connected_bss->frequency;
/*
* 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 (count_md) {
scan_freq_set_add(freq_set_md, current_freq);
device_roam_scan(device, freq_set_md);
} else if (count_no_md) {
scan_freq_set_add(freq_set_no_md, current_freq);
device_roam_scan(device, freq_set_no_md);
} else
device_roam_scan(device, NULL);
scan_freq_set_free(freq_set_md);
scan_freq_set_free(freq_set_no_md);
}
static void device_roam_trigger_cb(struct l_timeout *timeout, void *user_data)
{
struct device *device = user_data;
l_debug("%d", device->index);
l_timeout_remove(device->roam_trigger_timeout);
device->roam_trigger_timeout = NULL;
device->preparing_roam = true;
/*
* If current BSS supports Neighbor Reports, narrow the scan down
* to channels occupied by known neighbors in the ESS. 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 (device->connected_bss->cap_rm_neighbor_report)
if (netdev_neighbor_report_req(device->netdev,
device_neighbor_report_cb) == 0)
return;
/* Otherwise do a full scan for target BSS candidates */
device_roam_scan(device, NULL);
}
static void device_roam_timeout_rearm(struct device *device, int seconds)
{
struct timespec now, min_timeout;
clock_gettime(CLOCK_MONOTONIC, &now);
min_timeout = now;
min_timeout.tv_sec += seconds;
if (device->roam_min_time.tv_sec < min_timeout.tv_sec ||
(device->roam_min_time.tv_sec == min_timeout.tv_sec &&
device->roam_min_time.tv_nsec < min_timeout.tv_nsec))
device->roam_min_time = min_timeout;
seconds = device->roam_min_time.tv_sec - now.tv_sec +
(device->roam_min_time.tv_nsec > now.tv_nsec ? 1 : 0);
device->roam_trigger_timeout =
l_timeout_create(seconds, device_roam_trigger_cb, device, NULL);
}
static void device_connect_cb(struct netdev *netdev, enum netdev_result result,
void *user_data)
{
struct device *device = user_data;
2016-08-04 17:39:41 +02:00
l_debug("%d, result: %d", device->index, result);
if (device->connect_pending) {
struct l_dbus_message *reply;
switch (result) {
case NETDEV_RESULT_ABORTED:
reply = dbus_error_aborted(device->connect_pending);
break;
case NETDEV_RESULT_OK:
reply = l_dbus_message_new_method_return(
device->connect_pending);
l_dbus_message_set_arguments(reply, "");
break;
default:
reply = dbus_error_failed(device->connect_pending);
break;
}
dbus_pending_reply(&device->connect_pending, reply);
}
2016-06-16 17:53:26 +02:00
if (result != NETDEV_RESULT_OK) {
if (result != NETDEV_RESULT_ABORTED) {
network_connect_failed(device->connected_network);
device_disassociated(device);
}
return;
2016-06-16 17:53:26 +02:00
}
network_connected(device->connected_network);
device_enter_state(device, DEVICE_STATE_CONNECTED);
device->autoconnect = true;
}
static void device_netdev_event(struct netdev *netdev, enum netdev_event event,
void *user_data)
{
struct device *device = user_data;
struct network *network = device->connected_network;
switch (event) {
case NETDEV_EVENT_AUTHENTICATING:
l_debug("Authenticating");
break;
case NETDEV_EVENT_ASSOCIATING:
l_debug("Associating");
break;
case NETDEV_EVENT_4WAY_HANDSHAKE:
l_debug("Handshaking");
break;
case NETDEV_EVENT_SETTING_KEYS:
l_debug("Setting keys");
/* If we got here, then our PSK works. Save if required */
network_sync_psk(network);
break;
case NETDEV_EVENT_LOST_BEACON:
device_lost_beacon(device);
break;
case NETDEV_EVENT_DISCONNECT_BY_AP:
device_disconnect_by_ap(device);
break;
case NETDEV_EVENT_DISCONNECT_BY_SME:
device_disassociated(device);
break;
case NETDEV_EVENT_RSSI_THRESHOLD_LOW:
if (device->signal_low)
break;
device->signal_low = true;
if (device->preparing_roam ||
device->state == DEVICE_STATE_ROAMING)
break;
/* Set a 5-second initial timeout */
device_roam_timeout_rearm(device, 5);
break;
case NETDEV_EVENT_RSSI_THRESHOLD_HIGH:
l_timeout_remove(device->roam_trigger_timeout);
device->roam_trigger_timeout = NULL;
device->signal_low = false;
break;
};
}
bool device_set_autoconnect(struct device *device, bool autoconnect)
{
if (device->autoconnect == autoconnect)
return true;
device->autoconnect = autoconnect;
if (device->state == DEVICE_STATE_DISCONNECTED && autoconnect)
device_enter_state(device, DEVICE_STATE_AUTOCONNECT);
if (device->state == DEVICE_STATE_AUTOCONNECT && !autoconnect)
device_enter_state(device, DEVICE_STATE_DISCONNECTED);
return true;
}
void device_connect_network(struct device *device, struct network *network,
struct scan_bss *bss,
struct l_dbus_message *message)
{
struct l_dbus *dbus = dbus_get_bus();
struct handshake_state *hs;
hs = device_handshake_setup(device, network, bss);
if (!hs) {
if (message)
l_dbus_send(dbus, dbus_error_not_supported(message));
return;
}
if (netdev_connect(device->netdev, bss, hs, device_netdev_event,
device_connect_cb, device) < 0) {
handshake_state_free(hs);
if (message)
l_dbus_send(dbus, dbus_error_failed(message));
return;
}
device->connect_pending = l_dbus_message_ref(message);
device->connected_bss = bss;
device->connected_network = network;
device_enter_state(device, DEVICE_STATE_CONNECTING);
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "ConnectedNetwork");
l_dbus_property_changed(dbus, network_get_path(network),
IWD_NETWORK_INTERFACE, "Connected");
}
static void device_scan_triggered(int err, void *user_data)
{
struct device *device = user_data;
struct l_dbus_message *reply;
struct l_dbus *dbus = dbus_get_bus();
l_debug("device_scan_triggered: %i", err);
if (err < 0) {
dbus_pending_reply(&device->scan_pending,
dbus_error_failed(device->scan_pending));
return;
}
l_debug("Scan triggered for %s", netdev_get_name(device->netdev));
device->scanning = true;
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Scanning");
reply = l_dbus_message_new_method_return(device->scan_pending);
l_dbus_message_set_arguments(reply, "");
dbus_pending_reply(&device->scan_pending, reply);
}
static struct l_dbus_message *device_scan(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct device *device = user_data;
l_debug("Scan called from DBus");
if (device->scan_pending)
return dbus_error_busy(message);
device->scan_pending = l_dbus_message_ref(message);
if (!scan_passive(device->index, device_scan_triggered,
new_scan_results, device, NULL))
return dbus_error_failed(message);
return NULL;
}
static void device_disconnect_cb(struct netdev *netdev, bool success,
void *user_data)
{
struct device *device = user_data;
2016-08-04 17:39:41 +02:00
l_debug("%d, success: %d", device->index, success);
2016-08-04 18:37:23 +02:00
if (device->disconnect_pending) {
struct l_dbus_message *reply;
2016-08-04 18:37:23 +02:00
if (success) {
reply = l_dbus_message_new_method_return(
device->disconnect_pending);
l_dbus_message_set_arguments(reply, "");
} else
reply = dbus_error_failed(device->disconnect_pending);
2016-08-04 18:37:23 +02:00
dbus_pending_reply(&device->disconnect_pending, reply);
2016-08-04 18:37:23 +02:00
}
device_enter_state(device, DEVICE_STATE_DISCONNECTED);
if (device->autoconnect)
device_enter_state(device, DEVICE_STATE_AUTOCONNECT);
}
int device_disconnect(struct device *device)
{
if (device->state == DEVICE_STATE_DISCONNECTING)
return -EBUSY;
if (!device->connected_bss)
return -ENOTCONN;
if (netdev_disconnect(device->netdev, device_disconnect_cb, device) < 0)
return -EIO;
/*
* 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.
*/
device_reset_connection_state(device);
device_enter_state(device, DEVICE_STATE_DISCONNECTING);
return 0;
}
static struct l_dbus_message *device_dbus_disconnect(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct device *device = 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
*/
device_set_autoconnect(device, false);
result = device_disconnect(device);
if (result == -EBUSY)
return dbus_error_busy(message);
if (result == -ENOTCONN)
return dbus_error_not_connected(message);
if (result < 0)
return dbus_error_failed(message);
device->disconnect_pending = l_dbus_message_ref(message);
return NULL;
}
static struct l_dbus_message *device_get_networks(struct l_dbus *dbus,
struct l_dbus_message *message,
void *user_data)
{
struct device *device = user_data;
struct l_dbus_message *reply;
struct l_dbus_message_builder *builder;
const struct l_queue_entry *entry;
reply = l_dbus_message_new_method_return(message);
builder = l_dbus_message_builder_new(reply);
l_dbus_message_builder_enter_array(builder, "(osns)");
for (entry = l_queue_get_entries(device->networks_sorted); entry;
entry = entry->next) {
const struct network *network = entry->data;
enum security security = network_get_security(network);
int16_t signal_strength = network_get_signal_strength(network);
l_dbus_message_builder_enter_struct(builder, "osns");
l_dbus_message_builder_append_basic(builder, 'o',
network_get_path(network));
l_dbus_message_builder_append_basic(builder, 's',
network_get_ssid(network));
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 bool device_property_get_name(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
l_dbus_message_builder_append_basic(builder, 's',
netdev_get_name(device->netdev));
return true;
}
static bool device_property_get_address(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
const char *str;
str = util_address_to_string(netdev_get_address(device->netdev));
l_dbus_message_builder_append_basic(builder, 's', str);
return true;
}
static bool device_property_get_connected_network(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
if (!device->connected_network)
return false;
l_dbus_message_builder_append_basic(builder, 'o',
network_get_path(device->connected_network));
return true;
}
static bool device_property_get_powered(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
2016-06-25 20:42:19 +02:00
bool powered = device->state != DEVICE_STATE_OFF;
l_dbus_message_builder_append_basic(builder, 'b', &powered);
return true;
}
2016-07-12 04:13:52 +02:00
struct set_powered_cb_data {
struct device *device;
struct l_dbus *dbus;
struct l_dbus_message *message;
l_dbus_property_complete_cb_t complete;
};
static void set_powered_cb(struct netdev *netdev, int result, void *user_data)
{
struct set_powered_cb_data *cb_data = user_data;
struct l_dbus_message *reply = NULL;
if (result < 0)
reply = dbus_error_failed(cb_data->message);
cb_data->complete(cb_data->dbus, cb_data->message, reply);
}
static struct l_dbus_message *device_property_set_powered(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 device *device = user_data;
bool powered;
struct set_powered_cb_data *cb_data;
if (!l_dbus_message_iter_get_variant(new_value, "b", &powered))
return dbus_error_invalid_args(message);
if (powered == (device->state != DEVICE_STATE_OFF)) {
complete(dbus, message, NULL);
return NULL;
}
cb_data = l_new(struct set_powered_cb_data, 1);
cb_data->device = device;
cb_data->dbus = dbus;
cb_data->message = message;
cb_data->complete = complete;
netdev_set_powered(device->netdev, powered, set_powered_cb, cb_data,
l_free);
return NULL;
}
static bool device_property_get_scanning(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
2016-09-22 19:57:10 +02:00
bool scanning = device->scanning;
2016-09-22 19:57:10 +02:00
l_dbus_message_builder_append_basic(builder, 'b', &scanning);
return true;
}
2016-07-20 00:48:39 +02:00
static bool device_property_get_state(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
const char *statestr = "unknown";
switch (device->state) {
case DEVICE_STATE_CONNECTED:
statestr = "connected";
break;
case DEVICE_STATE_CONNECTING:
statestr = "connecting";
break;
case DEVICE_STATE_DISCONNECTING:
statestr = "disconnecting";
break;
case DEVICE_STATE_OFF:
case DEVICE_STATE_DISCONNECTED:
case DEVICE_STATE_AUTOCONNECT:
statestr = "disconnected";
break;
case DEVICE_STATE_ROAMING:
statestr = "roaming";
break;
2016-07-20 00:48:39 +02:00
}
l_dbus_message_builder_append_basic(builder, 's', statestr);
return true;
}
static bool device_property_get_adapter(struct l_dbus *dbus,
struct l_dbus_message *message,
struct l_dbus_message_builder *builder,
void *user_data)
{
struct device *device = user_data;
l_dbus_message_builder_append_basic(builder, 'o',
wiphy_get_path(device->wiphy));
return true;
}
static void setup_device_interface(struct l_dbus_interface *interface)
{
l_dbus_interface_method(interface, "Scan", 0,
device_scan, "", "");
l_dbus_interface_method(interface, "Disconnect", 0,
device_dbus_disconnect, "", "");
l_dbus_interface_method(interface, "GetOrderedNetworks", 0,
device_get_networks, "a(osns)", "",
"networks");
l_dbus_interface_property(interface, "Name", 0, "s",
device_property_get_name, NULL);
l_dbus_interface_property(interface, "Address", 0, "s",
device_property_get_address, NULL);
l_dbus_interface_property(interface, "ConnectedNetwork", 0, "o",
device_property_get_connected_network,
NULL);
l_dbus_interface_property(interface, "Powered", 0, "b",
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device_property_get_powered,
device_property_set_powered);
l_dbus_interface_property(interface, "Scanning", 0, "b",
device_property_get_scanning, NULL);
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l_dbus_interface_property(interface, "State", 0, "s",
device_property_get_state, NULL);
l_dbus_interface_property(interface, "Adapter", 0, "o",
device_property_get_adapter, NULL);
}
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static bool device_remove_network(const void *key, void *data, void *user_data)
{
struct network *network = data;
network_remove(network, -ESHUTDOWN);
return true;
}
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static void device_netdev_notify(struct netdev *netdev,
enum netdev_watch_event event,
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void *user_data)
{
struct device *device = user_data;
struct l_dbus *dbus = dbus_get_bus();
switch (event) {
case NETDEV_WATCH_EVENT_UP:
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device_enter_state(device, DEVICE_STATE_AUTOCONNECT);
WATCHLIST_NOTIFY(&device_watches, device_watch_func_t,
device, DEVICE_EVENT_INSERTED);
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l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Powered");
break;
case NETDEV_WATCH_EVENT_DOWN:
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device_enter_state(device, DEVICE_STATE_OFF);
if (device->scan_pending)
dbus_pending_reply(&device->scan_pending,
dbus_error_aborted(device->scan_pending));
if (device->connect_pending)
dbus_pending_reply(&device->connect_pending,
dbus_error_aborted(device->connect_pending));
device_reset_connection_state(device);
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l_hashmap_foreach_remove(device->networks,
device_remove_network, device);
l_queue_destroy(device->autoconnect_list, l_free);
device->autoconnect_list = l_queue_new();
l_queue_destroy(device->bss_list, bss_free);
device->bss_list = l_queue_new();
l_queue_destroy(device->networks_sorted, NULL);
device->networks_sorted = l_queue_new();
WATCHLIST_NOTIFY(&device_watches, device_watch_func_t,
device, DEVICE_EVENT_REMOVED);
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l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Powered");
break;
case NETDEV_WATCH_EVENT_NAME_CHANGE:
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Name");
break;
case NETDEV_WATCH_EVENT_ADDRESS_CHANGE:
l_dbus_property_changed(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, "Address");
break;
}
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}
struct device *device_create(struct wiphy *wiphy, struct netdev *netdev)
{
struct device *device;
struct l_dbus *dbus = dbus_get_bus();
uint32_t ifindex = netdev_get_ifindex(netdev);
device = l_new(struct device, 1);
device->bss_list = l_queue_new();
device->networks = l_hashmap_new();
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watchlist_init(&device->state_watches);
l_hashmap_set_hash_function(device->networks, l_str_hash);
l_hashmap_set_compare_function(device->networks,
(l_hashmap_compare_func_t) strcmp);
device->networks_sorted = l_queue_new();
device->index = ifindex;
device->wiphy = wiphy;
device->netdev = netdev;
device->autoconnect = true;
l_queue_push_head(device_list, device);
if (!l_dbus_object_add_interface(dbus, device_get_path(device),
IWD_DEVICE_INTERFACE, device))
l_info("Unable to register %s interface", IWD_DEVICE_INTERFACE);
if (!l_dbus_object_add_interface(dbus, device_get_path(device),
L_DBUS_INTERFACE_PROPERTIES, device))
l_info("Unable to register %s interface",
L_DBUS_INTERFACE_PROPERTIES);
scan_ifindex_add(device->index);
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device_netdev_notify(netdev, netdev_get_is_up(netdev) ?
NETDEV_WATCH_EVENT_UP :
NETDEV_WATCH_EVENT_DOWN,
device);
device->netdev_watch_id =
netdev_watch_add(netdev, device_netdev_notify, device);
return device;
}
static void device_free(void *user)
{
struct device *device = user;
struct l_dbus *dbus;
l_debug("");
if (device->scan_pending)
dbus_pending_reply(&device->scan_pending,
dbus_error_aborted(device->scan_pending));
if (device->connect_pending)
dbus_pending_reply(&device->connect_pending,
dbus_error_aborted(device->connect_pending));
if (device->state != DEVICE_STATE_OFF)
WATCHLIST_NOTIFY(&device_watches, device_watch_func_t,
device, DEVICE_EVENT_REMOVED);
watchlist_destroy(&device->state_watches);
dbus = dbus_get_bus();
l_dbus_unregister_object(dbus, device_get_path(device));
l_queue_destroy(device->networks_sorted, NULL);
l_hashmap_destroy(device->networks, network_free);
l_queue_destroy(device->bss_list, bss_free);
l_queue_destroy(device->old_bss_list, bss_free);
l_queue_destroy(device->autoconnect_list, l_free);
netdev_watch_remove(device->netdev, device->netdev_watch_id);
l_timeout_remove(device->roam_trigger_timeout);
scan_ifindex_remove(device->index);
l_free(device);
}
void device_remove(struct device *device)
{
if (!l_queue_remove(device_list, device))
return;
device_free(device);
}
bool device_init(void)
{
if (!l_dbus_register_interface(dbus_get_bus(),
IWD_DEVICE_INTERFACE,
setup_device_interface,
NULL, false))
return false;
watchlist_init(&device_watches);
device_list = l_queue_new();
return true;
}
bool device_exit(void)
{
if (!l_queue_isempty(device_list))
l_warn("device_list isn't empty!");
l_queue_destroy(device_list, device_free);
device_list = NULL;
watchlist_destroy(&device_watches);
l_dbus_unregister_interface(dbus_get_bus(), IWD_DEVICE_INTERFACE);
return true;
}