naiveproxy/net/base/network_change_notifier.cc

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2018-02-02 13:49:39 +03:00
// Copyright (c) 2012 The Chromium 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 "net/base/network_change_notifier.h"
#include <limits>
#include <unordered_set>
#include "base/macros.h"
#include "base/metrics/histogram_macros.h"
#include "base/strings/string_util.h"
#include "base/synchronization/lock.h"
#include "base/threading/thread_checker.h"
#include "build/build_config.h"
#include "net/base/network_change_notifier_factory.h"
#include "net/base/network_interfaces.h"
#include "net/base/url_util.h"
#include "net/dns/dns_config_service.h"
#include "net/url_request/url_request.h"
#include "url/gurl.h"
#if defined(OS_ANDROID)
#include "base/metrics/sparse_histogram.h"
#include "base/strings/string_number_conversions.h"
#include "net/android/network_library.h"
#endif
#if defined(OS_WIN)
#include "net/base/network_change_notifier_win.h"
#elif defined(OS_LINUX) && !defined(OS_CHROMEOS)
#include "net/base/network_change_notifier_linux.h"
#elif defined(OS_MACOSX)
#include "net/base/network_change_notifier_mac.h"
#endif
namespace net {
namespace {
// The actual singleton notifier. The class contract forbids usage of the API
// in ways that would require us to place locks around access to this object.
// (The prohibition on global non-POD objects makes it tricky to do such a thing
// anyway.)
NetworkChangeNotifier* g_network_change_notifier = NULL;
// Class factory singleton.
NetworkChangeNotifierFactory* g_network_change_notifier_factory = NULL;
class MockNetworkChangeNotifier : public NetworkChangeNotifier {
public:
ConnectionType GetCurrentConnectionType() const override {
return CONNECTION_UNKNOWN;
}
};
} // namespace
// static
bool NetworkChangeNotifier::test_notifications_only_ = false;
// static
const NetworkChangeNotifier::NetworkHandle
NetworkChangeNotifier::kInvalidNetworkHandle = -1;
// The main observer class that records UMAs for network events.
class NetworkChangeNotifier::HistogramWatcher : public ConnectionTypeObserver,
public IPAddressObserver,
public DNSObserver,
public NetworkChangeObserver {
public:
HistogramWatcher()
: last_ip_address_change_(base::TimeTicks::Now()),
last_connection_change_(base::TimeTicks::Now()),
last_dns_change_(base::TimeTicks::Now()),
last_network_change_(base::TimeTicks::Now()),
last_connection_type_(CONNECTION_UNKNOWN),
offline_packets_received_(0),
bytes_read_since_last_connection_change_(0),
peak_kbps_since_last_connection_change_(0) {}
// Registers our three Observer implementations. This is called from the
// network thread so that our Observer implementations are also called
// from the network thread. This avoids multi-threaded race conditions
// because the only other interface, |NotifyDataReceived| is also
// only called from the network thread.
void Init() {
DCHECK(thread_checker_.CalledOnValidThread());
DCHECK(g_network_change_notifier);
AddConnectionTypeObserver(this);
AddIPAddressObserver(this);
AddDNSObserver(this);
AddNetworkChangeObserver(this);
}
~HistogramWatcher() override {
DCHECK(thread_checker_.CalledOnValidThread());
DCHECK(g_network_change_notifier);
RemoveConnectionTypeObserver(this);
RemoveIPAddressObserver(this);
RemoveDNSObserver(this);
RemoveNetworkChangeObserver(this);
}
// IPAddressObserver implementation.
void OnIPAddressChanged() override {
DCHECK(thread_checker_.CalledOnValidThread());
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.IPAddressChange",
SinceLast(&last_ip_address_change_));
UMA_HISTOGRAM_MEDIUM_TIMES(
"NCN.ConnectionTypeChangeToIPAddressChange",
last_ip_address_change_ - last_connection_change_);
}
// ConnectionTypeObserver implementation.
void OnConnectionTypeChanged(ConnectionType type) override {
DCHECK(thread_checker_.CalledOnValidThread());
base::TimeTicks now = base::TimeTicks::Now();
int32_t kilobytes_read = bytes_read_since_last_connection_change_ / 1000;
base::TimeDelta state_duration = SinceLast(&last_connection_change_);
if (bytes_read_since_last_connection_change_) {
switch (last_connection_type_) {
case CONNECTION_UNKNOWN:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOnUnknown",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOnUnknown",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_ETHERNET:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOnEthernet",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOnEthernet",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_WIFI:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOnWifi",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOnWifi",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_2G:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOn2G",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOn2G",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_3G:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOn3G",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOn3G",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_4G:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOn4G",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOn4G",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_NONE:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOnNone",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOnNone",
fastest_RTT_since_last_connection_change_);
break;
case CONNECTION_BLUETOOTH:
UMA_HISTOGRAM_TIMES("NCN.CM.FirstReadOnBluetooth",
first_byte_after_connection_change_);
UMA_HISTOGRAM_TIMES("NCN.CM.FastestRTTOnBluetooth",
fastest_RTT_since_last_connection_change_);
}
}
if (peak_kbps_since_last_connection_change_) {
switch (last_connection_type_) {
case CONNECTION_UNKNOWN:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOnUnknown",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_ETHERNET:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOnEthernet",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_WIFI:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOnWifi",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_2G:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOn2G",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_3G:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOn3G",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_4G:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOn4G",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_NONE:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOnNone",
peak_kbps_since_last_connection_change_);
break;
case CONNECTION_BLUETOOTH:
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.PeakKbpsOnBluetooth",
peak_kbps_since_last_connection_change_);
break;
}
}
switch (last_connection_type_) {
case CONNECTION_UNKNOWN:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOnUnknown", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOnUnknown", kilobytes_read);
break;
case CONNECTION_ETHERNET:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOnEthernet", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOnEthernet",
kilobytes_read);
break;
case CONNECTION_WIFI:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOnWifi", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOnWifi", kilobytes_read);
break;
case CONNECTION_2G:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOn2G", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOn2G", kilobytes_read);
break;
case CONNECTION_3G:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOn3G", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOn3G", kilobytes_read);
break;
case CONNECTION_4G:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOn4G", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOn4G", kilobytes_read);
break;
case CONNECTION_NONE:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOnNone", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOnNone", kilobytes_read);
break;
case CONNECTION_BLUETOOTH:
UMA_HISTOGRAM_LONG_TIMES("NCN.CM.TimeOnBluetooth", state_duration);
UMA_HISTOGRAM_COUNTS_1M("NCN.CM.KBTransferedOnBluetooth",
kilobytes_read);
break;
}
if (type != CONNECTION_NONE) {
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.OnlineChange", state_duration);
if (offline_packets_received_) {
if ((now - last_offline_packet_received_) <
base::TimeDelta::FromSeconds(5)) {
// We can compare this sum with the sum of NCN.OfflineDataRecv.
UMA_HISTOGRAM_COUNTS_10000(
"NCN.OfflineDataRecvAny5sBeforeOnline",
offline_packets_received_);
}
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.OfflineDataRecvUntilOnline",
now - last_offline_packet_received_);
}
} else {
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.OfflineChange", state_duration);
}
LogOperatorCodeHistogram(type);
UMA_HISTOGRAM_MEDIUM_TIMES(
"NCN.IPAddressChangeToConnectionTypeChange",
now - last_ip_address_change_);
offline_packets_received_ = 0;
bytes_read_since_last_connection_change_ = 0;
peak_kbps_since_last_connection_change_ = 0;
last_connection_type_ = type;
polling_interval_ = base::TimeDelta::FromSeconds(1);
}
// DNSObserver implementation.
void OnDNSChanged() override {
DCHECK(thread_checker_.CalledOnValidThread());
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.DNSConfigChange",
SinceLast(&last_dns_change_));
}
// NetworkChangeObserver implementation.
void OnNetworkChanged(ConnectionType type) override {
DCHECK(thread_checker_.CalledOnValidThread());
if (type != CONNECTION_NONE) {
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.NetworkOnlineChange",
SinceLast(&last_network_change_));
} else {
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.NetworkOfflineChange",
SinceLast(&last_network_change_));
}
}
// Record histogram data whenever we receive a packet. Should only be called
// from the network thread.
void NotifyDataReceived(const URLRequest& request, int bytes_read) {
DCHECK(thread_checker_.CalledOnValidThread());
if (IsLocalhost(request.url().host()) ||
!request.url().SchemeIsHTTPOrHTTPS()) {
return;
}
base::TimeTicks now = base::TimeTicks::Now();
base::TimeDelta request_duration = now - request.creation_time();
if (bytes_read_since_last_connection_change_ == 0) {
first_byte_after_connection_change_ = now - last_connection_change_;
fastest_RTT_since_last_connection_change_ = request_duration;
}
bytes_read_since_last_connection_change_ += bytes_read;
if (request_duration < fastest_RTT_since_last_connection_change_)
fastest_RTT_since_last_connection_change_ = request_duration;
// Ignore tiny transfers which will not produce accurate rates.
// Ignore zero duration transfers which might cause divide by zero.
if (bytes_read > 10000 &&
request_duration > base::TimeDelta::FromMilliseconds(1) &&
request.creation_time() > last_connection_change_) {
int32_t kbps = static_cast<int32_t>(bytes_read * 8 /
request_duration.InMilliseconds());
if (kbps > peak_kbps_since_last_connection_change_)
peak_kbps_since_last_connection_change_ = kbps;
}
if (last_connection_type_ != CONNECTION_NONE)
return;
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.OfflineDataRecv",
now - last_connection_change_);
offline_packets_received_++;
last_offline_packet_received_ = now;
if ((now - last_polled_connection_) > polling_interval_) {
polling_interval_ *= 2;
last_polled_connection_ = now;
last_polled_connection_type_ = GetConnectionType();
}
if (last_polled_connection_type_ == CONNECTION_NONE) {
UMA_HISTOGRAM_MEDIUM_TIMES("NCN.PollingOfflineDataRecv",
now - last_connection_change_);
}
}
private:
static base::TimeDelta SinceLast(base::TimeTicks *last_time) {
base::TimeTicks current_time = base::TimeTicks::Now();
base::TimeDelta delta = current_time - *last_time;
*last_time = current_time;
return delta;
}
base::TimeTicks last_ip_address_change_;
base::TimeTicks last_connection_change_;
base::TimeTicks last_dns_change_;
base::TimeTicks last_network_change_;
base::TimeTicks last_offline_packet_received_;
base::TimeTicks last_polled_connection_;
// |polling_interval_| is initialized by |OnConnectionTypeChanged| on our
// first transition to offline and on subsequent transitions. Once offline,
// |polling_interval_| doubles as offline data is received and we poll
// with |GetConnectionType| to verify the connection
// state.
base::TimeDelta polling_interval_;
// |last_connection_type_| is the last value passed to
// |OnConnectionTypeChanged|.
ConnectionType last_connection_type_;
// |last_polled_connection_type_| is last result from calling
// |GetConnectionType| in |NotifyDataReceived|.
ConnectionType last_polled_connection_type_;
// Count of how many times NotifyDataReceived() has been called while the
// NetworkChangeNotifier thought network connection was offline.
int32_t offline_packets_received_;
// Number of bytes of network data received since last connectivity change.
int32_t bytes_read_since_last_connection_change_;
// Fastest round-trip-time (RTT) since last connectivity change. RTT measured
// from URLRequest creation until first byte received.
base::TimeDelta fastest_RTT_since_last_connection_change_;
// Time between connectivity change and first network data byte received.
base::TimeDelta first_byte_after_connection_change_;
// Rough measurement of peak KB/s witnessed since last connectivity change.
// The accuracy is decreased by ignoring these factors:
// 1) Multiple URLRequests can occur concurrently.
// 2) NotifyDataReceived() may be called repeatedly for one URLRequest.
// 3) The transfer time includes at least one RTT while no bytes are read.
// Erring on the conservative side is hopefully offset by taking the maximum.
int32_t peak_kbps_since_last_connection_change_;
base::ThreadChecker thread_checker_;
DISALLOW_COPY_AND_ASSIGN(HistogramWatcher);
};
// NetworkState is thread safe.
class NetworkChangeNotifier::NetworkState {
public:
NetworkState() = default;
~NetworkState() = default;
void GetDnsConfig(DnsConfig* config) const {
base::AutoLock lock(lock_);
*config = dns_config_;
}
void SetDnsConfig(const DnsConfig& dns_config) {
base::AutoLock lock(lock_);
dns_config_ = dns_config;
}
private:
mutable base::Lock lock_;
DnsConfig dns_config_;
};
NetworkChangeNotifier::NetworkChangeCalculatorParams::
NetworkChangeCalculatorParams() = default;
// Calculates NetworkChange signal from IPAddress and ConnectionType signals.
class NetworkChangeNotifier::NetworkChangeCalculator
: public ConnectionTypeObserver,
public IPAddressObserver {
public:
explicit NetworkChangeCalculator(const NetworkChangeCalculatorParams& params)
: params_(params),
have_announced_(false),
last_announced_connection_type_(CONNECTION_NONE),
pending_connection_type_(CONNECTION_NONE) {}
void Init() {
DCHECK(thread_checker_.CalledOnValidThread());
DCHECK(g_network_change_notifier);
AddConnectionTypeObserver(this);
AddIPAddressObserver(this);
}
~NetworkChangeCalculator() override {
DCHECK(thread_checker_.CalledOnValidThread());
DCHECK(g_network_change_notifier);
RemoveConnectionTypeObserver(this);
RemoveIPAddressObserver(this);
}
// NetworkChangeNotifier::IPAddressObserver implementation.
void OnIPAddressChanged() override {
DCHECK(thread_checker_.CalledOnValidThread());
base::TimeDelta delay = last_announced_connection_type_ == CONNECTION_NONE
? params_.ip_address_offline_delay_ : params_.ip_address_online_delay_;
// Cancels any previous timer.
timer_.Start(FROM_HERE, delay, this, &NetworkChangeCalculator::Notify);
}
// NetworkChangeNotifier::ConnectionTypeObserver implementation.
void OnConnectionTypeChanged(ConnectionType type) override {
DCHECK(thread_checker_.CalledOnValidThread());
pending_connection_type_ = type;
base::TimeDelta delay = last_announced_connection_type_ == CONNECTION_NONE
? params_.connection_type_offline_delay_
: params_.connection_type_online_delay_;
// Cancels any previous timer.
timer_.Start(FROM_HERE, delay, this, &NetworkChangeCalculator::Notify);
}
private:
void Notify() {
DCHECK(thread_checker_.CalledOnValidThread());
// Don't bother signaling about dead connections.
if (have_announced_ &&
(last_announced_connection_type_ == CONNECTION_NONE) &&
(pending_connection_type_ == CONNECTION_NONE)) {
return;
}
have_announced_ = true;
last_announced_connection_type_ = pending_connection_type_;
// Immediately before sending out an online signal, send out an offline
// signal to perform any destructive actions before constructive actions.
if (pending_connection_type_ != CONNECTION_NONE)
NetworkChangeNotifier::NotifyObserversOfNetworkChange(CONNECTION_NONE);
NetworkChangeNotifier::NotifyObserversOfNetworkChange(
pending_connection_type_);
}
const NetworkChangeCalculatorParams params_;
// Indicates if NotifyObserversOfNetworkChange has been called yet.
bool have_announced_;
// Last value passed to NotifyObserversOfNetworkChange.
ConnectionType last_announced_connection_type_;
// Value to pass to NotifyObserversOfNetworkChange when Notify is called.
ConnectionType pending_connection_type_;
// Used to delay notifications so duplicates can be combined.
base::OneShotTimer timer_;
base::ThreadChecker thread_checker_;
DISALLOW_COPY_AND_ASSIGN(NetworkChangeCalculator);
};
NetworkChangeNotifier::~NetworkChangeNotifier() {
network_change_calculator_.reset();
DCHECK_EQ(this, g_network_change_notifier);
g_network_change_notifier = NULL;
}
// static
void NetworkChangeNotifier::SetFactory(
NetworkChangeNotifierFactory* factory) {
CHECK(!g_network_change_notifier_factory);
g_network_change_notifier_factory = factory;
}
// static
NetworkChangeNotifier* NetworkChangeNotifier::Create() {
if (g_network_change_notifier_factory)
return g_network_change_notifier_factory->CreateInstance();
#if defined(OS_WIN)
NetworkChangeNotifierWin* network_change_notifier =
new NetworkChangeNotifierWin();
network_change_notifier->WatchForAddressChange();
return network_change_notifier;
#elif defined(OS_CHROMEOS) || defined(OS_ANDROID)
// ChromeOS and Android builds MUST use their own class factory.
#if !defined(OS_CHROMEOS)
// TODO(oshima): ash_shell do not have access to chromeos'es
// notifier yet. Re-enable this when chromeos'es notifier moved to
// chromeos root directory. crbug.com/119298.
CHECK(false);
#endif
return NULL;
#elif defined(OS_LINUX)
return new NetworkChangeNotifierLinux(std::unordered_set<std::string>());
#elif defined(OS_MACOSX)
return new NetworkChangeNotifierMac();
#else
NOTIMPLEMENTED();
return NULL;
#endif
}
// static
bool NetworkChangeNotifier::HasNetworkChangeNotifier() {
return g_network_change_notifier != nullptr;
}
// static
NetworkChangeNotifier::ConnectionType
NetworkChangeNotifier::GetConnectionType() {
return g_network_change_notifier ?
g_network_change_notifier->GetCurrentConnectionType() :
CONNECTION_UNKNOWN;
}
// static
NetworkChangeNotifier::ConnectionSubtype
NetworkChangeNotifier::GetConnectionSubtype() {
return g_network_change_notifier
? g_network_change_notifier->GetCurrentConnectionSubtype()
: SUBTYPE_UNKNOWN;
}
// static
void NetworkChangeNotifier::GetMaxBandwidthAndConnectionType(
double* max_bandwidth_mbps,
ConnectionType* connection_type) {
if (!g_network_change_notifier) {
*connection_type = CONNECTION_UNKNOWN;
*max_bandwidth_mbps =
GetMaxBandwidthMbpsForConnectionSubtype(SUBTYPE_UNKNOWN);
return;
}
g_network_change_notifier->GetCurrentMaxBandwidthAndConnectionType(
max_bandwidth_mbps, connection_type);
}
// static
double NetworkChangeNotifier::GetMaxBandwidthMbpsForConnectionSubtype(
ConnectionSubtype subtype) {
switch (subtype) {
case SUBTYPE_GSM:
return 0.01;
case SUBTYPE_IDEN:
return 0.064;
case SUBTYPE_CDMA:
return 0.115;
case SUBTYPE_1XRTT:
return 0.153;
case SUBTYPE_GPRS:
return 0.237;
case SUBTYPE_EDGE:
return 0.384;
case SUBTYPE_UMTS:
return 2.0;
case SUBTYPE_EVDO_REV_0:
return 2.46;
case SUBTYPE_EVDO_REV_A:
return 3.1;
case SUBTYPE_HSPA:
return 3.6;
case SUBTYPE_EVDO_REV_B:
return 14.7;
case SUBTYPE_HSDPA:
return 14.3;
case SUBTYPE_HSUPA:
return 14.4;
case SUBTYPE_EHRPD:
return 21.0;
case SUBTYPE_HSPAP:
return 42.0;
case SUBTYPE_LTE:
return 100.0;
case SUBTYPE_LTE_ADVANCED:
return 100.0;
case SUBTYPE_BLUETOOTH_1_2:
return 1.0;
case SUBTYPE_BLUETOOTH_2_1:
return 3.0;
case SUBTYPE_BLUETOOTH_3_0:
return 24.0;
case SUBTYPE_BLUETOOTH_4_0:
return 1.0;
case SUBTYPE_ETHERNET:
return 10.0;
case SUBTYPE_FAST_ETHERNET:
return 100.0;
case SUBTYPE_GIGABIT_ETHERNET:
return 1000.0;
case SUBTYPE_10_GIGABIT_ETHERNET:
return 10000.0;
case SUBTYPE_WIFI_B:
return 11.0;
case SUBTYPE_WIFI_G:
return 54.0;
case SUBTYPE_WIFI_N:
return 600.0;
case SUBTYPE_WIFI_AC:
return 1300.0;
case SUBTYPE_WIFI_AD:
return 7000.0;
case SUBTYPE_UNKNOWN:
return std::numeric_limits<double>::infinity();
case SUBTYPE_NONE:
return 0.0;
case SUBTYPE_OTHER:
return std::numeric_limits<double>::infinity();
}
NOTREACHED();
return std::numeric_limits<double>::infinity();
}
// static
bool NetworkChangeNotifier::AreNetworkHandlesSupported() {
if (g_network_change_notifier) {
return g_network_change_notifier->AreNetworkHandlesCurrentlySupported();
}
return false;
}
// static
void NetworkChangeNotifier::GetConnectedNetworks(NetworkList* network_list) {
DCHECK(AreNetworkHandlesSupported());
if (g_network_change_notifier) {
g_network_change_notifier->GetCurrentConnectedNetworks(network_list);
} else {
network_list->clear();
}
}
// static
NetworkChangeNotifier::ConnectionType
NetworkChangeNotifier::GetNetworkConnectionType(NetworkHandle network) {
DCHECK(AreNetworkHandlesSupported());
return g_network_change_notifier
? g_network_change_notifier->GetCurrentNetworkConnectionType(
network)
: CONNECTION_UNKNOWN;
}
// static
NetworkChangeNotifier::NetworkHandle
NetworkChangeNotifier::GetDefaultNetwork() {
DCHECK(AreNetworkHandlesSupported());
return g_network_change_notifier
? g_network_change_notifier->GetCurrentDefaultNetwork()
: kInvalidNetworkHandle;
}
// static
void NetworkChangeNotifier::GetDnsConfig(DnsConfig* config) {
if (!g_network_change_notifier) {
*config = DnsConfig();
} else {
g_network_change_notifier->network_state_->GetDnsConfig(config);
}
}
// static
const char* NetworkChangeNotifier::ConnectionTypeToString(
ConnectionType type) {
static const char* const kConnectionTypeNames[] = {
"CONNECTION_UNKNOWN",
"CONNECTION_ETHERNET",
"CONNECTION_WIFI",
"CONNECTION_2G",
"CONNECTION_3G",
"CONNECTION_4G",
"CONNECTION_NONE",
"CONNECTION_BLUETOOTH"
};
static_assert(arraysize(kConnectionTypeNames) ==
NetworkChangeNotifier::CONNECTION_LAST + 1,
"ConnectionType name count should match");
if (type < CONNECTION_UNKNOWN || type > CONNECTION_LAST) {
NOTREACHED();
return "CONNECTION_INVALID";
}
return kConnectionTypeNames[type];
}
// static
void NetworkChangeNotifier::NotifyDataReceived(const URLRequest& request,
int bytes_read) {
if (!g_network_change_notifier ||
!g_network_change_notifier->histogram_watcher_) {
return;
}
g_network_change_notifier->histogram_watcher_->NotifyDataReceived(request,
bytes_read);
}
// static
void NetworkChangeNotifier::InitHistogramWatcher() {
if (!g_network_change_notifier)
return;
g_network_change_notifier->histogram_watcher_.reset(new HistogramWatcher());
g_network_change_notifier->histogram_watcher_->Init();
}
// static
void NetworkChangeNotifier::ShutdownHistogramWatcher() {
if (!g_network_change_notifier)
return;
g_network_change_notifier->histogram_watcher_.reset();
}
// static
void NetworkChangeNotifier::FinalizingMetricsLogRecord() {
if (!g_network_change_notifier)
return;
g_network_change_notifier->OnFinalizingMetricsLogRecord();
}
// static
void NetworkChangeNotifier::LogOperatorCodeHistogram(ConnectionType type) {
#if defined(OS_ANDROID)
// On a connection type change to cellular, log the network operator MCC/MNC.
// Log zero in other cases.
unsigned mcc_mnc = 0;
if (NetworkChangeNotifier::IsConnectionCellular(type)) {
// Log zero if not perfectly converted.
if (!base::StringToUint(android::GetTelephonyNetworkOperator(), &mcc_mnc)) {
mcc_mnc = 0;
}
}
UMA_HISTOGRAM_SPARSE_SLOWLY("NCN.NetworkOperatorMCCMNC", mcc_mnc);
#endif
}
#if defined(OS_LINUX)
// static
const internal::AddressTrackerLinux*
NetworkChangeNotifier::GetAddressTracker() {
return g_network_change_notifier ?
g_network_change_notifier->GetAddressTrackerInternal() : NULL;
}
#endif
// static
bool NetworkChangeNotifier::IsOffline() {
return GetConnectionType() == CONNECTION_NONE;
}
// static
bool NetworkChangeNotifier::IsConnectionCellular(ConnectionType type) {
bool is_cellular = false;
switch (type) {
case CONNECTION_2G:
case CONNECTION_3G:
case CONNECTION_4G:
is_cellular = true;
break;
case CONNECTION_UNKNOWN:
case CONNECTION_ETHERNET:
case CONNECTION_WIFI:
case CONNECTION_NONE:
case CONNECTION_BLUETOOTH:
is_cellular = false;
break;
}
return is_cellular;
}
// static
NetworkChangeNotifier::ConnectionType
NetworkChangeNotifier::ConnectionTypeFromInterfaces() {
NetworkInterfaceList interfaces;
if (!GetNetworkList(&interfaces, EXCLUDE_HOST_SCOPE_VIRTUAL_INTERFACES))
return CONNECTION_UNKNOWN;
return ConnectionTypeFromInterfaceList(interfaces);
}
// static
NetworkChangeNotifier::ConnectionType
NetworkChangeNotifier::ConnectionTypeFromInterfaceList(
const NetworkInterfaceList& interfaces) {
bool first = true;
ConnectionType result = CONNECTION_NONE;
for (size_t i = 0; i < interfaces.size(); ++i) {
#if defined(OS_WIN)
if (interfaces[i].friendly_name == "Teredo Tunneling Pseudo-Interface")
continue;
#endif
#if defined(OS_MACOSX)
// Ignore tunnel and airdrop interfaces.
if (base::StartsWith(interfaces[i].friendly_name, "utun",
base::CompareCase::SENSITIVE) ||
base::StartsWith(interfaces[i].friendly_name, "awdl",
base::CompareCase::SENSITIVE)) {
continue;
}
#endif
// Remove VMware network interfaces as they're internal and should not be
// used to determine the network connection type.
if (base::ToLowerASCII(interfaces[i].friendly_name).find("vmnet") !=
std::string::npos) {
continue;
}
if (first) {
first = false;
result = interfaces[i].type;
} else if (result != interfaces[i].type) {
return CONNECTION_UNKNOWN;
}
}
return result;
}
// static
NetworkChangeNotifier* NetworkChangeNotifier::CreateMock() {
return new MockNetworkChangeNotifier();
}
void NetworkChangeNotifier::AddIPAddressObserver(IPAddressObserver* observer) {
if (g_network_change_notifier)
g_network_change_notifier->ip_address_observer_list_->AddObserver(observer);
}
void NetworkChangeNotifier::AddConnectionTypeObserver(
ConnectionTypeObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->connection_type_observer_list_->AddObserver(
observer);
}
}
void NetworkChangeNotifier::AddDNSObserver(DNSObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->resolver_state_observer_list_->AddObserver(
observer);
}
}
void NetworkChangeNotifier::AddNetworkChangeObserver(
NetworkChangeObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->network_change_observer_list_->AddObserver(
observer);
}
}
void NetworkChangeNotifier::AddMaxBandwidthObserver(
MaxBandwidthObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->max_bandwidth_observer_list_->AddObserver(
observer);
}
}
void NetworkChangeNotifier::AddNetworkObserver(NetworkObserver* observer) {
DCHECK(AreNetworkHandlesSupported());
if (g_network_change_notifier) {
g_network_change_notifier->network_observer_list_->AddObserver(observer);
}
}
void NetworkChangeNotifier::RemoveIPAddressObserver(
IPAddressObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->ip_address_observer_list_->RemoveObserver(
observer);
}
}
void NetworkChangeNotifier::RemoveConnectionTypeObserver(
ConnectionTypeObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->connection_type_observer_list_->RemoveObserver(
observer);
}
}
void NetworkChangeNotifier::RemoveDNSObserver(DNSObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->resolver_state_observer_list_->RemoveObserver(
observer);
}
}
void NetworkChangeNotifier::RemoveNetworkChangeObserver(
NetworkChangeObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->network_change_observer_list_->RemoveObserver(
observer);
}
}
void NetworkChangeNotifier::RemoveMaxBandwidthObserver(
MaxBandwidthObserver* observer) {
if (g_network_change_notifier) {
g_network_change_notifier->max_bandwidth_observer_list_->RemoveObserver(
observer);
}
}
void NetworkChangeNotifier::RemoveNetworkObserver(NetworkObserver* observer) {
DCHECK(AreNetworkHandlesSupported());
if (g_network_change_notifier) {
g_network_change_notifier->network_observer_list_->RemoveObserver(observer);
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfIPAddressChangeForTests() {
if (g_network_change_notifier)
g_network_change_notifier->NotifyObserversOfIPAddressChangeImpl();
}
// static
void NetworkChangeNotifier::NotifyObserversOfConnectionTypeChangeForTests(
ConnectionType type) {
if (g_network_change_notifier)
g_network_change_notifier->NotifyObserversOfConnectionTypeChangeImpl(type);
}
// static
void NetworkChangeNotifier::NotifyObserversOfDNSChangeForTests() {
if (g_network_change_notifier)
g_network_change_notifier->NotifyObserversOfDNSChangeImpl();
}
// static
void NetworkChangeNotifier::NotifyObserversOfNetworkChangeForTests(
ConnectionType type) {
if (g_network_change_notifier)
g_network_change_notifier->NotifyObserversOfNetworkChangeImpl(type);
}
// static
void NetworkChangeNotifier::NotifyObserversOfInitialDNSConfigReadForTests() {
if (g_network_change_notifier)
g_network_change_notifier->NotifyObserversOfInitialDNSConfigReadImpl();
}
// static
void NetworkChangeNotifier::NotifyObserversOfMaxBandwidthChangeForTests(
double max_bandwidth_mbps,
ConnectionType type) {
if (g_network_change_notifier) {
g_network_change_notifier->NotifyObserversOfMaxBandwidthChangeImpl(
max_bandwidth_mbps, type);
}
}
// static
void NetworkChangeNotifier::SetTestNotificationsOnly(bool test_only) {
DCHECK(!g_network_change_notifier);
NetworkChangeNotifier::test_notifications_only_ = test_only;
}
NetworkChangeNotifier::NetworkChangeNotifier(
const NetworkChangeCalculatorParams& params
/*= NetworkChangeCalculatorParams()*/)
: ip_address_observer_list_(
new base::ObserverListThreadSafe<IPAddressObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
connection_type_observer_list_(
new base::ObserverListThreadSafe<ConnectionTypeObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
resolver_state_observer_list_(
new base::ObserverListThreadSafe<DNSObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
network_change_observer_list_(
new base::ObserverListThreadSafe<NetworkChangeObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
max_bandwidth_observer_list_(
new base::ObserverListThreadSafe<MaxBandwidthObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
network_observer_list_(new base::ObserverListThreadSafe<NetworkObserver>(
base::ObserverListPolicy::EXISTING_ONLY)),
network_state_(new NetworkState()),
network_change_calculator_(new NetworkChangeCalculator(params)) {
DCHECK(!g_network_change_notifier);
g_network_change_notifier = this;
network_change_calculator_->Init();
}
#if defined(OS_LINUX)
const internal::AddressTrackerLinux*
NetworkChangeNotifier::GetAddressTrackerInternal() const {
return NULL;
}
#endif
NetworkChangeNotifier::ConnectionSubtype
NetworkChangeNotifier::GetCurrentConnectionSubtype() const {
return SUBTYPE_UNKNOWN;
}
void NetworkChangeNotifier::GetCurrentMaxBandwidthAndConnectionType(
double* max_bandwidth_mbps,
ConnectionType* connection_type) const {
// This default implementation conforms to the NetInfo V3 specification but
// should be overridden to provide specific bandwidth data based on the
// platform.
*connection_type = GetCurrentConnectionType();
*max_bandwidth_mbps =
*connection_type == CONNECTION_NONE
? GetMaxBandwidthMbpsForConnectionSubtype(SUBTYPE_NONE)
: GetMaxBandwidthMbpsForConnectionSubtype(SUBTYPE_UNKNOWN);
}
bool NetworkChangeNotifier::AreNetworkHandlesCurrentlySupported() const {
return false;
}
void NetworkChangeNotifier::GetCurrentConnectedNetworks(
NetworkList* network_list) const {
network_list->clear();
}
NetworkChangeNotifier::ConnectionType
NetworkChangeNotifier::GetCurrentNetworkConnectionType(
NetworkHandle network) const {
return CONNECTION_UNKNOWN;
}
NetworkChangeNotifier::NetworkHandle
NetworkChangeNotifier::GetCurrentDefaultNetwork() const {
return kInvalidNetworkHandle;
}
// static
void NetworkChangeNotifier::NotifyObserversOfIPAddressChange() {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfIPAddressChangeImpl();
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfConnectionTypeChange() {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfConnectionTypeChangeImpl(
GetConnectionType());
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfNetworkChange(
ConnectionType type) {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfNetworkChangeImpl(type);
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfMaxBandwidthChange(
double max_bandwidth_mbps,
ConnectionType type) {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfMaxBandwidthChangeImpl(
max_bandwidth_mbps, type);
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfDNSChange() {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfDNSChangeImpl();
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfInitialDNSConfigRead() {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfInitialDNSConfigReadImpl();
}
}
// static
void NetworkChangeNotifier::NotifyObserversOfSpecificNetworkChange(
NetworkChangeType type,
NetworkHandle network) {
if (g_network_change_notifier &&
!NetworkChangeNotifier::test_notifications_only_) {
g_network_change_notifier->NotifyObserversOfSpecificNetworkChangeImpl(
type, network);
}
}
// static
void NetworkChangeNotifier::SetDnsConfig(const DnsConfig& config) {
if (!g_network_change_notifier)
return;
g_network_change_notifier->network_state_->SetDnsConfig(config);
NotifyObserversOfDNSChange();
}
// static
void NetworkChangeNotifier::SetInitialDnsConfig(const DnsConfig& config) {
if (!g_network_change_notifier)
return;
#if DCHECK_IS_ON()
// Verify we've never received a valid DnsConfig previously.
DnsConfig old_config;
g_network_change_notifier->network_state_->GetDnsConfig(&old_config);
DCHECK(!old_config.IsValid());
#endif
g_network_change_notifier->network_state_->SetDnsConfig(config);
NotifyObserversOfInitialDNSConfigRead();
}
void NetworkChangeNotifier::NotifyObserversOfIPAddressChangeImpl() {
ip_address_observer_list_->Notify(FROM_HERE,
&IPAddressObserver::OnIPAddressChanged);
}
void NetworkChangeNotifier::NotifyObserversOfConnectionTypeChangeImpl(
ConnectionType type) {
connection_type_observer_list_->Notify(
FROM_HERE, &ConnectionTypeObserver::OnConnectionTypeChanged, type);
}
void NetworkChangeNotifier::NotifyObserversOfNetworkChangeImpl(
ConnectionType type) {
network_change_observer_list_->Notify(
FROM_HERE, &NetworkChangeObserver::OnNetworkChanged, type);
}
void NetworkChangeNotifier::NotifyObserversOfDNSChangeImpl() {
resolver_state_observer_list_->Notify(FROM_HERE, &DNSObserver::OnDNSChanged);
}
void NetworkChangeNotifier::NotifyObserversOfInitialDNSConfigReadImpl() {
resolver_state_observer_list_->Notify(FROM_HERE,
&DNSObserver::OnInitialDNSConfigRead);
}
void NetworkChangeNotifier::NotifyObserversOfMaxBandwidthChangeImpl(
double max_bandwidth_mbps,
ConnectionType type) {
max_bandwidth_observer_list_->Notify(
FROM_HERE, &MaxBandwidthObserver::OnMaxBandwidthChanged,
max_bandwidth_mbps, type);
}
void NetworkChangeNotifier::NotifyObserversOfSpecificNetworkChangeImpl(
NetworkChangeType type,
NetworkHandle network) {
switch (type) {
case CONNECTED:
network_observer_list_->Notify(
FROM_HERE, &NetworkObserver::OnNetworkConnected, network);
break;
case DISCONNECTED:
network_observer_list_->Notify(
FROM_HERE, &NetworkObserver::OnNetworkDisconnected, network);
break;
case SOON_TO_DISCONNECT:
network_observer_list_->Notify(
FROM_HERE, &NetworkObserver::OnNetworkSoonToDisconnect, network);
break;
case MADE_DEFAULT:
network_observer_list_->Notify(
FROM_HERE, &NetworkObserver::OnNetworkMadeDefault, network);
break;
}
}
NetworkChangeNotifier::DisableForTest::DisableForTest()
: network_change_notifier_(g_network_change_notifier) {
DCHECK(g_network_change_notifier);
g_network_change_notifier = NULL;
}
NetworkChangeNotifier::DisableForTest::~DisableForTest() {
DCHECK(!g_network_change_notifier);
g_network_change_notifier = network_change_notifier_;
}
void NetworkChangeNotifier::DNSObserver::OnInitialDNSConfigRead() {
}
} // namespace net