blob: e7450a8bab66750e815a890ccc4bfc6ebbea0250 [file] [log] [blame]
// Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "shill/wifi_endpoint.h"
#include <base/logging.h>
#include <base/stl_util.h>
#include <base/stringprintf.h>
#include <base/string_number_conversions.h>
#include <base/string_util.h>
#include <chromeos/dbus/service_constants.h>
#include "shill/ieee80211.h"
#include "shill/proxy_factory.h"
#include "shill/scope_logger.h"
#include "shill/supplicant_bss_proxy_interface.h"
#include "shill/wifi.h"
#include "shill/wifi_endpoint.h"
#include "shill/wpa_supplicant.h"
using std::map;
using std::set;
using std::string;
using std::vector;
namespace shill {
WiFiEndpoint::WiFiEndpoint(ProxyFactory *proxy_factory,
const WiFiRefPtr &device,
const string &rpc_id,
const map<string, ::DBus::Variant> &properties)
: frequency_(0),
proxy_factory_(proxy_factory),
device_(device),
rpc_id_(rpc_id) {
// XXX will segfault on missing properties
ssid_ =
properties.find(wpa_supplicant::kBSSPropertySSID)->second.
operator std::vector<uint8_t>();
bssid_ =
properties.find(wpa_supplicant::kBSSPropertyBSSID)->second.
operator std::vector<uint8_t>();
signal_strength_ =
properties.find(wpa_supplicant::kBSSPropertySignal)->second.
reader().get_int16();
map<string, ::DBus::Variant>::const_iterator it =
properties.find(wpa_supplicant::kBSSPropertyFrequency);
if (it != properties.end())
frequency_ = it->second.reader().get_uint16();
physical_mode_ = DeterminePhyMode(properties, frequency_);
network_mode_ = ParseMode(
properties.find(wpa_supplicant::kBSSPropertyMode)->second);
security_mode_ = ParseSecurity(properties);
if (network_mode_.empty()) {
// XXX log error?
}
ssid_string_ = string(ssid_.begin(), ssid_.end());
WiFi::SanitizeSSID(&ssid_string_);
ssid_hex_ = base::HexEncode(&(*ssid_.begin()), ssid_.size());
bssid_string_ = StringPrintf("%02x:%02x:%02x:%02x:%02x:%02x",
bssid_[0], bssid_[1], bssid_[2],
bssid_[3], bssid_[4], bssid_[5]);
bssid_hex_ = base::HexEncode(&(*bssid_.begin()), bssid_.size());
}
WiFiEndpoint::~WiFiEndpoint() {}
void WiFiEndpoint::Start() {
supplicant_bss_proxy_.reset(
proxy_factory_->CreateSupplicantBSSProxy(
this, rpc_id_, wpa_supplicant::kDBusAddr));
}
void WiFiEndpoint::PropertiesChanged(
const map<string, ::DBus::Variant> &properties) {
LOG(INFO) << __func__;
map<string, ::DBus::Variant>::const_iterator properties_it =
properties.find(wpa_supplicant::kBSSPropertySignal);
if (properties_it != properties.end()) {
signal_strength_ = properties_it->second.reader().get_int16();
SLOG(WiFi, 2) << "WiFiEndpoint " << bssid_string_ << " signal is now "
<< signal_strength_;
device_->NotifyEndpointChanged(*this);
}
}
// static
uint32_t WiFiEndpoint::ModeStringToUint(const std::string &mode_string) {
if (mode_string == flimflam::kModeManaged)
return wpa_supplicant::kNetworkModeInfrastructureInt;
else if (mode_string == flimflam::kModeAdhoc)
return wpa_supplicant::kNetworkModeAdHocInt;
else
NOTIMPLEMENTED() << "Shill dos not support " << mode_string
<< " mode at this time.";
return 0;
}
const vector<uint8_t> &WiFiEndpoint::ssid() const {
return ssid_;
}
const string &WiFiEndpoint::ssid_string() const {
return ssid_string_;
}
const string &WiFiEndpoint::ssid_hex() const {
return ssid_hex_;
}
const string &WiFiEndpoint::bssid_string() const {
return bssid_string_;
}
const string &WiFiEndpoint::bssid_hex() const {
return bssid_hex_;
}
int16_t WiFiEndpoint::signal_strength() const {
return signal_strength_;
}
uint16 WiFiEndpoint::frequency() const {
return frequency_;
}
uint16 WiFiEndpoint::physical_mode() const {
return physical_mode_;
}
const string &WiFiEndpoint::network_mode() const {
return network_mode_;
}
const string &WiFiEndpoint::security_mode() const {
return security_mode_;
}
// static
WiFiEndpoint *WiFiEndpoint::MakeOpenEndpoint(ProxyFactory *proxy_factory,
const WiFiRefPtr &wifi,
const string &ssid,
const string &bssid,
uint16 frequency,
int16 signal_dbm) {
map <string, ::DBus::Variant> args;
::DBus::MessageIter writer;
writer = args[wpa_supplicant::kBSSPropertySSID].writer();
writer << vector<uint8_t>(ssid.begin(), ssid.end());
string bssid_nosep;
RemoveChars(bssid, ":", &bssid_nosep);
vector<uint8_t> bssid_bytes;
base::HexStringToBytes(bssid_nosep, &bssid_bytes);
writer = args[wpa_supplicant::kBSSPropertyBSSID].writer();
writer << bssid_bytes;
args[wpa_supplicant::kBSSPropertySignal].writer().append_int16(signal_dbm);
args[wpa_supplicant::kBSSPropertyFrequency].writer().append_uint16(frequency);
args[wpa_supplicant::kBSSPropertyMode].writer().append_string(
wpa_supplicant::kNetworkModeInfrastructure);
// We indicate this is an open BSS by leaving out all security properties.
return new WiFiEndpoint(
proxy_factory, wifi, bssid, args); // |bssid| fakes an RPC ID
}
// static
const char *WiFiEndpoint::ParseMode(const string &mode_string) {
if (mode_string == wpa_supplicant::kNetworkModeInfrastructure) {
return flimflam::kModeManaged;
} else if (mode_string == wpa_supplicant::kNetworkModeAdHoc) {
return flimflam::kModeAdhoc;
} else if (mode_string == wpa_supplicant::kNetworkModeAccessPoint) {
NOTREACHED() << "Shill does not support AP mode at this time.";
return NULL;
} else {
NOTREACHED() << "Unknown WiFi endpoint mode!";
return NULL;
}
}
// static
const char *WiFiEndpoint::ParseSecurity(
const map<string, ::DBus::Variant> &properties) {
set<KeyManagement> rsn_key_management_methods;
if (ContainsKey(properties, wpa_supplicant::kPropertyRSN)) {
// TODO(quiche): check type before casting
const map<string, ::DBus::Variant> rsn_properties(
properties.find(wpa_supplicant::kPropertyRSN)->second.
operator map<string, ::DBus::Variant>());
ParseKeyManagementMethods(rsn_properties, &rsn_key_management_methods);
}
set<KeyManagement> wpa_key_management_methods;
if (ContainsKey(properties, wpa_supplicant::kPropertyWPA)) {
// TODO(quiche): check type before casting
const map<string, ::DBus::Variant> rsn_properties(
properties.find(wpa_supplicant::kPropertyWPA)->second.
operator map<string, ::DBus::Variant>());
ParseKeyManagementMethods(rsn_properties, &wpa_key_management_methods);
}
bool wep_privacy = false;
if (ContainsKey(properties, wpa_supplicant::kPropertyPrivacy)) {
wep_privacy = properties.find(wpa_supplicant::kPropertyPrivacy)->second.
reader().get_bool();
}
if (ContainsKey(rsn_key_management_methods, kKeyManagement802_1x) ||
ContainsKey(wpa_key_management_methods, kKeyManagement802_1x)) {
return flimflam::kSecurity8021x;
} else if (ContainsKey(rsn_key_management_methods, kKeyManagementPSK)) {
return flimflam::kSecurityRsn;
} else if (ContainsKey(wpa_key_management_methods, kKeyManagementPSK)) {
return flimflam::kSecurityWpa;
} else if (wep_privacy) {
return flimflam::kSecurityWep;
} else {
return flimflam::kSecurityNone;
}
}
// static
void WiFiEndpoint::ParseKeyManagementMethods(
const map<string, ::DBus::Variant> &security_method_properties,
set<KeyManagement> *key_management_methods) {
if (!ContainsKey(security_method_properties,
wpa_supplicant::kSecurityMethodPropertyKeyManagement)) {
return;
}
// TODO(quiche): check type before cast
const vector<string> key_management_vec =
security_method_properties.
find(wpa_supplicant::kSecurityMethodPropertyKeyManagement)->second.
operator vector<string>();
for (vector<string>::const_iterator it = key_management_vec.begin();
it != key_management_vec.end();
++it) {
if (EndsWith(*it, wpa_supplicant::kKeyManagementMethodSuffixEAP, true)) {
key_management_methods->insert(kKeyManagement802_1x);
} else if (
EndsWith(*it, wpa_supplicant::kKeyManagementMethodSuffixPSK, true)) {
key_management_methods->insert(kKeyManagementPSK);
}
}
}
// static
Metrics::WiFiNetworkPhyMode WiFiEndpoint::DeterminePhyMode(
const map<string, ::DBus::Variant> &properties, uint16 frequency) {
uint32_t max_rate = 0;
map<string, ::DBus::Variant>::const_iterator it =
properties.find(wpa_supplicant::kBSSPropertyRates);
if (it != properties.end()) {
vector<uint32_t> rates = it->second.operator vector<uint32_t>();
if (rates.size() > 0)
max_rate = rates[0]; // Rates are sorted in descending order
}
Metrics::WiFiNetworkPhyMode phy_mode = Metrics::kWiFiNetworkPhyModeUndef;
it = properties.find(wpa_supplicant::kBSSPropertyIEs);
if (it != properties.end()) {
phy_mode = ParseIEsForPhyMode(it->second.operator vector<uint8_t>());
if (phy_mode != Metrics::kWiFiNetworkPhyModeUndef)
return phy_mode;
}
if (frequency < 3000) {
// 2.4GHz legacy, check for tx rate for 11b-only
// (note 22M is valid)
if (max_rate < 24000000)
phy_mode = Metrics::kWiFiNetworkPhyMode11b;
else
phy_mode = Metrics::kWiFiNetworkPhyMode11g;
} else {
phy_mode = Metrics::kWiFiNetworkPhyMode11a;
}
return phy_mode;
}
// static
Metrics::WiFiNetworkPhyMode WiFiEndpoint::ParseIEsForPhyMode(
const vector<uint8_t> &ies) {
// Format of an information element:
// 1 1 3 1 - 252
// +------+--------+------------+----------------+
// | Type | Length | OUI | Data |
// +------+--------+------------+----------------+
Metrics::WiFiNetworkPhyMode phy_mode = Metrics::kWiFiNetworkPhyModeUndef;
vector<uint8_t>::const_iterator it;
for (it = ies.begin();
it + 1 < ies.end(); // +1 to ensure Length field is in valid memory
it += 2 + *(it + 1)) {
if (*it == IEEE_80211::kElemIdErp) {
phy_mode = Metrics::kWiFiNetworkPhyMode11g;
continue; // NB: Continue to check for HT
}
if (*it == IEEE_80211::kElemIdHTCap || *it == IEEE_80211::kElemIdHTInfo) {
phy_mode = Metrics::kWiFiNetworkPhyMode11n;
break;
}
}
return phy_mode;
}
} // namespace shill