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chromium / chromiumos / platform / shill / 4dc04c49b872fe2703ed3241613ba4ccca944ece / . / metrics.cc
blob: d9e183e7a912c254befb89a37cf41a9f25edb314 [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/metrics.h"
#include <base/strings/string_util.h>
#include <base/strings/stringprintf.h>
#include <chromeos/dbus/service_constants.h>
#include <metrics/bootstat.h>
#include "shill/ieee80211.h"
#include "shill/link_monitor.h"
#include "shill/logging.h"
#include "shill/wifi_service.h"
using std::string;
using std::shared_ptr;
namespace shill {
static const char kMetricPrefix[] = "Network.Shill";
// static
// Our disconnect enumeration values are 0 (System Disconnect) and
// 1 (User Disconnect), see histograms.xml, but Chrome needs a minimum
// enum value of 1 and the minimum number of buckets needs to be 3 (see
// histogram.h). Instead of remapping System Disconnect to 1 and
// User Disconnect to 2, we can just leave the enumerated values as-is
// because Chrome implicitly creates a [0-1) bucket for us. Using Min=1,
// Max=2 and NumBuckets=3 gives us the following three buckets:
// [0-1), [1-2), [2-INT_MAX). We end up with an extra bucket [2-INT_MAX)
// that we can safely ignore.
const char Metrics::kMetricDisconnectSuffix[] = "Disconnect";
const int Metrics::kMetricDisconnectMax = 2;
const int Metrics::kMetricDisconnectMin = 1;
const int Metrics::kMetricDisconnectNumBuckets = 3;
const char Metrics::kMetricSignalAtDisconnectSuffix[] = "SignalAtDisconnect";
const int Metrics::kMetricSignalAtDisconnectMin = 0;
const int Metrics::kMetricSignalAtDisconnectMax = 200;
const int Metrics::kMetricSignalAtDisconnectNumBuckets = 40;
const char Metrics::kMetricNetworkApModeSuffix[] = "ApMode";
const char Metrics::kMetricNetworkChannelSuffix[] = "Channel";
const int Metrics::kMetricNetworkChannelMax = Metrics::kWiFiChannelMax;
const char Metrics::kMetricNetworkEapInnerProtocolSuffix[] = "EapInnerProtocol";
const int Metrics::kMetricNetworkEapInnerProtocolMax =
Metrics::kEapInnerProtocolMax;
const char Metrics::kMetricNetworkEapOuterProtocolSuffix[] = "EapOuterProtocol";
const int Metrics::kMetricNetworkEapOuterProtocolMax =
Metrics::kEapOuterProtocolMax;
const char Metrics::kMetricNetworkPhyModeSuffix[] = "PhyMode";
const int Metrics::kMetricNetworkPhyModeMax = Metrics::kWiFiNetworkPhyModeMax;
const char Metrics::kMetricNetworkSecuritySuffix[] = "Security";
const int Metrics::kMetricNetworkSecurityMax = Metrics::kWiFiSecurityMax;
const char Metrics::kMetricNetworkServiceErrors[] =
"Network.Shill.ServiceErrors";
const int Metrics::kMetricNetworkServiceErrorsMax = Service::kFailureMax;
const char Metrics::kMetricNetworkSignalStrengthSuffix[] = "SignalStrength";
const int Metrics::kMetricNetworkSignalStrengthMax = 200;
const int Metrics::kMetricNetworkSignalStrengthMin = 0;
const int Metrics::kMetricNetworkSignalStrengthNumBuckets = 40;
const char Metrics::kMetricTimeOnlineSecondsSuffix[] = "TimeOnline";
const int Metrics::kMetricTimeOnlineSecondsMax = 8 * 60 * 60; // 8 hours
const int Metrics::kMetricTimeOnlineSecondsMin = 1;
const char Metrics::kMetricTimeToConnectMillisecondsSuffix[] = "TimeToConnect";
const int Metrics::kMetricTimeToConnectMillisecondsMax =
60 * 1000; // 60 seconds
const int Metrics::kMetricTimeToConnectMillisecondsMin = 1;
const int Metrics::kMetricTimeToConnectMillisecondsNumBuckets = 60;
const char Metrics::kMetricTimeToScanAndConnectMillisecondsSuffix[] =
"TimeToScanAndConnect";
const char Metrics::kMetricTimeToDropSeconds[] = "Network.Shill.TimeToDrop";;
const int Metrics::kMetricTimeToDropSecondsMax = 8 * 60 * 60; // 8 hours
const int Metrics::kMetricTimeToDropSecondsMin = 1;
const char Metrics::kMetricTimeToDisableMillisecondsSuffix[] = "TimeToDisable";
const int Metrics::kMetricTimeToDisableMillisecondsMax =
60 * 1000; // 60 seconds
const int Metrics::kMetricTimeToDisableMillisecondsMin = 1;
const int Metrics::kMetricTimeToDisableMillisecondsNumBuckets = 60;
const char Metrics::kMetricTimeToEnableMillisecondsSuffix[] = "TimeToEnable";
const int Metrics::kMetricTimeToEnableMillisecondsMax =
60 * 1000; // 60 seconds
const int Metrics::kMetricTimeToEnableMillisecondsMin = 1;
const int Metrics::kMetricTimeToEnableMillisecondsNumBuckets = 60;
const char Metrics::kMetricTimeToInitializeMillisecondsSuffix[] =
"TimeToInitialize";
const int Metrics::kMetricTimeToInitializeMillisecondsMax =
30 * 1000; // 30 seconds
const int Metrics::kMetricTimeToInitializeMillisecondsMin = 1;
const int Metrics::kMetricTimeToInitializeMillisecondsNumBuckets = 30;
const char Metrics::kMetricTimeResumeToReadyMillisecondsSuffix[] =
"TimeResumeToReady";
const char Metrics::kMetricTimeToConfigMillisecondsSuffix[] = "TimeToConfig";
const char Metrics::kMetricTimeToJoinMillisecondsSuffix[] = "TimeToJoin";
const char Metrics::kMetricTimeToOnlineMillisecondsSuffix[] = "TimeToOnline";
const char Metrics::kMetricTimeToPortalMillisecondsSuffix[] = "TimeToPortal";
const char Metrics::kMetricTimeToScanMillisecondsSuffix[] = "TimeToScan";
const int Metrics::kMetricTimeToScanMillisecondsMax = 180 * 1000; // 3 minutes
const int Metrics::kMetricTimeToScanMillisecondsMin = 1;
const int Metrics::kMetricTimeToScanMillisecondsNumBuckets = 90;
const int Metrics::kTimerHistogramMillisecondsMax = 45 * 1000;
const int Metrics::kTimerHistogramMillisecondsMin = 1;
const int Metrics::kTimerHistogramNumBuckets = 50;
const char Metrics::kMetricPortalAttemptsSuffix[] = "PortalAttempts";
const int Metrics::kMetricPortalAttemptsMax =
PortalDetector::kMaxRequestAttempts;
const int Metrics::kMetricPortalAttemptsMin = 1;
const int Metrics::kMetricPortalAttemptsNumBuckets =
Metrics::kMetricPortalAttemptsMax;
const char Metrics::kMetricPortalAttemptsToOnlineSuffix[] =
"PortalAttemptsToOnline";
const int Metrics::kMetricPortalAttemptsToOnlineMax = 100;
const int Metrics::kMetricPortalAttemptsToOnlineMin = 1;
const int Metrics::kMetricPortalAttemptsToOnlineNumBuckets = 10;
const char Metrics::kMetricPortalResultSuffix[] = "PortalResult";
const char Metrics::kMetricFrequenciesConnectedEver[] =
"Network.Shill.WiFi.FrequenciesConnectedEver";
const int Metrics::kMetricFrequenciesConnectedMax = 50;
const int Metrics::kMetricFrequenciesConnectedMin = 1;
const int Metrics::kMetricFrequenciesConnectedNumBuckets = 50;
const char Metrics::kMetricScanResult[] =
"Network.Shill.WiFi.ScanResult";
const char Metrics::kMetricWiFiScanTimeInEbusyMilliseconds[] =
"Network.Shill.WiFi.ScanTimeInEbusy";
const char Metrics::kMetricTerminationActionTimeOnTerminate[] =
"Network.Shill.TerminationActionTime.OnTerminate";
const char Metrics::kMetricTerminationActionResultOnTerminate[] =
"Network.Shill.TerminationActionResult.OnTerminate";
const char Metrics::kMetricTerminationActionTimeOnSuspend[] =
"Network.Shill.TerminationActionTime.OnSuspend";
const char Metrics::kMetricTerminationActionResultOnSuspend[] =
"Network.Shill.TerminationActionResult.OnSuspend";
const int Metrics::kMetricTerminationActionTimeMillisecondsMax = 10000;
const int Metrics::kMetricTerminationActionTimeMillisecondsMin = 1;
// static
const char Metrics::kMetricServiceFixupEntriesSuffix[] = "ServiceFixupEntries";
// static
const uint16 Metrics::kWiFiBandwidth5MHz = 5;
const uint16 Metrics::kWiFiBandwidth20MHz = 20;
const uint16 Metrics::kWiFiFrequency2412 = 2412;
const uint16 Metrics::kWiFiFrequency2472 = 2472;
const uint16 Metrics::kWiFiFrequency2484 = 2484;
const uint16 Metrics::kWiFiFrequency5170 = 5170;
const uint16 Metrics::kWiFiFrequency5180 = 5180;
const uint16 Metrics::kWiFiFrequency5230 = 5230;
const uint16 Metrics::kWiFiFrequency5240 = 5240;
const uint16 Metrics::kWiFiFrequency5320 = 5320;
const uint16 Metrics::kWiFiFrequency5500 = 5500;
const uint16 Metrics::kWiFiFrequency5700 = 5700;
const uint16 Metrics::kWiFiFrequency5745 = 5745;
const uint16 Metrics::kWiFiFrequency5825 = 5825;
// static
const char Metrics::kMetricPowerManagerKey[] = "metrics";
// static
const char Metrics::kMetricLinkMonitorFailureSuffix[] = "LinkMonitorFailure";
const char Metrics::kMetricLinkMonitorResponseTimeSampleSuffix[] =
"LinkMonitorResponseTimeSample";
const int Metrics::kMetricLinkMonitorResponseTimeSampleMin = 0;
const int Metrics::kMetricLinkMonitorResponseTimeSampleMax =
LinkMonitor::kDefaultTestPeriodMilliseconds;
const int Metrics::kMetricLinkMonitorResponseTimeSampleNumBuckets = 50;
const char Metrics::kMetricLinkMonitorSecondsToFailureSuffix[] =
"LinkMonitorSecondsToFailure";
const int Metrics::kMetricLinkMonitorSecondsToFailureMin = 0;
const int Metrics::kMetricLinkMonitorSecondsToFailureMax = 7200;
const int Metrics::kMetricLinkMonitorSecondsToFailureNumBuckets = 50;
const char Metrics::kMetricLinkMonitorBroadcastErrorsAtFailureSuffix[] =
"LinkMonitorBroadcastErrorsAtFailure";
const char Metrics::kMetricLinkMonitorUnicastErrorsAtFailureSuffix[] =
"LinkMonitorUnicastErrorsAtFailure";
const int Metrics::kMetricLinkMonitorErrorCountMin = 0;
const int Metrics::kMetricLinkMonitorErrorCountMax =
LinkMonitor::kFailureThreshold;
const int Metrics::kMetricLinkMonitorErrorCountNumBuckets =
LinkMonitor::kFailureThreshold + 1;
// static
const char Metrics::kMetricLinkClientDisconnectReason[] =
"Network.Shill.WiFi.ClientDisconnectReason";
const char Metrics::kMetricLinkApDisconnectReason[] =
"Network.Shill.WiFi.ApDisconnectReason";
const char Metrics::kMetricLinkClientDisconnectType[] =
"Network.Shill.WiFi.ClientDisconnectType";
const char Metrics::kMetricLinkApDisconnectType[] =
"Network.Shill.WiFi.ApDisconnectType";
// static
const char Metrics::kMetricCellular3GPPRegistrationDelayedDrop[] =
"Network.Shill.Cellular.3GPPRegistrationDelayedDrop";
const char Metrics::kMetricCellularAutoConnectTries[] =
"Network.Shill.Cellular.AutoConnectTries";
const int Metrics::kMetricCellularAutoConnectTriesMax = 20;
const int Metrics::kMetricCellularAutoConnectTriesMin = 1;
const int Metrics::kMetricCellularAutoConnectTriesNumBuckets = 20;
const char Metrics::kMetricCellularAutoConnectTotalTime[] =
"Network.Shill.Cellular.AutoConnectTotalTime";
const int Metrics::kMetricCellularAutoConnectTotalTimeMax =
60 * 1000; // 60 seconds
const int Metrics::kMetricCellularAutoConnectTotalTimeMin = 0;
const int Metrics::kMetricCellularAutoConnectTotalTimeNumBuckets = 60;
const char Metrics::kMetricCellularDrop[] =
"Network.Shill.Cellular.Drop";
// The format of FailureReason is different to other metrics because this
// name is prepended to the error message before the entire string is sent
// via SendUserActionToUMA.
const char Metrics::kMetricCellularFailureReason[] =
"Network.Shill.Cellular.FailureReason: ";
const char Metrics::kMetricCellularOutOfCreditsReason[] =
"Network.Shill.Cellular.OutOfCreditsReason";
const char Metrics::kMetricCellularSignalStrengthBeforeDrop[] =
"Network.Shill.Cellular.SignalStrengthBeforeDrop";
const int Metrics::kMetricCellularSignalStrengthBeforeDropMax = 100;
const int Metrics::kMetricCellularSignalStrengthBeforeDropMin = 0;
const int Metrics::kMetricCellularSignalStrengthBeforeDropNumBuckets = 10;
// static
const char Metrics::kMetricCorruptedProfile[] =
"Network.Shill.CorruptedProfile";
// static
const char Metrics::kMetricVpnDriver[] =
"Network.Shill.Vpn.Driver";
const int Metrics::kMetricVpnDriverMax = Metrics::kVpnDriverMax;
const char Metrics::kMetricVpnRemoteAuthenticationType[] =
"Network.Shill.Vpn.RemoteAuthenticationType";
const int Metrics::kMetricVpnRemoteAuthenticationTypeMax =
Metrics::kVpnRemoteAuthenticationTypeMax;
const char Metrics::kMetricVpnUserAuthenticationType[] =
"Network.Shill.Vpn.UserAuthenticationType";
const int Metrics::kMetricVpnUserAuthenticationTypeMax =
Metrics::kVpnUserAuthenticationTypeMax;
// static
const char Metrics::kMetricDHCPOptionFailureDetected[] =
"Network.Shill.DHCPOptionFailureDetected";
const char Metrics::kMetricExpiredLeaseLengthSecondsSuffix[] =
"ExpiredLeaseLengthSeconds";
const int Metrics::kMetricExpiredLeaseLengthSecondsMax =
7 * 24 * 60 * 60; // 7 days
const int Metrics::kMetricExpiredLeaseLengthSecondsMin = 1;
const int Metrics::kMetricExpiredLeaseLengthSecondsNumBuckets =
Metrics::kMetricExpiredLeaseLengthSecondsMax;
// static
const char Metrics::kMetricWifiAutoConnectableServices[] =
"Network.Shill.WiFi.AutoConnectableServices";
const int Metrics::kMetricWifiAutoConnectableServicesMax = 50;
const int Metrics::kMetricWifiAutoConnectableServicesMin = 1;
const int Metrics::kMetricWifiAutoConnectableServicesNumBuckets = 10;
// static
const char Metrics::kMetricWifiAvailableBSSes[] =
"Network.Shill.WiFi.AvailableBSSesAtConnect";
const int Metrics::kMetricWifiAvailableBSSesMax = 50;
const int Metrics::kMetricWifiAvailableBSSesMin = 1;
const int Metrics::kMetricWifiAvailableBSSesNumBuckets = 10;
// Number of services associated with currently connected network.
const char Metrics::kMetricServicesOnSameNetwork[] =
"Network.Shill.ServicesOnSameNetwork";
const int Metrics::kMetricServicesOnSameNetworkMax = 20;
const int Metrics::kMetricServicesOnSameNetworkMin = 1;
const int Metrics::kMetricServicesOnSameNetworkNumBuckets = 10;
// static
const char Metrics::kMetricUserInitiatedEvents[] =
"Network.Shill.UserInitiatedEvents";
// static
const char Metrics::kMetricWifiTxBitrate[] =
"Network.Shill.WiFi.TransmitBitrateMbps";
const int Metrics::kMetricWifiTxBitrateMax = 7000;
const int Metrics::kMetricWifiTxBitrateMin = 1;
const int Metrics::kMetricWifiTxBitrateNumBuckets = 100;
// static
const char Metrics::kMetricWifiUserInitiatedConnectionResult[] =
"Network.Shill.WiFi.UserInitiatedConnectionResult";
// static
const char Metrics::kMetricFallbackDNSTestResultSuffix[] =
"FallbackDNSTestResult";
// static
const char Metrics::kMetricNetworkProblemDetectedSuffix[] =
"NetworkProblemDetected";
Metrics::Metrics(EventDispatcher *dispatcher)
: dispatcher_(dispatcher),
library_(&metrics_library_),
last_default_technology_(Technology::kUnknown),
was_online_(false),
time_online_timer_(new chromeos_metrics::Timer),
time_to_drop_timer_(new chromeos_metrics::Timer),
time_resume_to_ready_timer_(new chromeos_metrics::Timer),
time_termination_actions_timer(new chromeos_metrics::Timer),
collect_bootstats_(true) {
metrics_library_.Init();
chromeos_metrics::TimerReporter::set_metrics_lib(library_);
}
Metrics::~Metrics() {}
// static
Metrics::WiFiChannel Metrics::WiFiFrequencyToChannel(uint16 frequency) {
WiFiChannel channel = kWiFiChannelUndef;
if (kWiFiFrequency2412 <= frequency && frequency <= kWiFiFrequency2472) {
if (((frequency - kWiFiFrequency2412) % kWiFiBandwidth5MHz) == 0)
channel = static_cast<WiFiChannel>(
kWiFiChannel2412 +
(frequency - kWiFiFrequency2412) / kWiFiBandwidth5MHz);
} else if (frequency == kWiFiFrequency2484) {
channel = kWiFiChannel2484;
} else if (kWiFiFrequency5170 <= frequency &&
frequency <= kWiFiFrequency5230) {
if ((frequency % kWiFiBandwidth20MHz) == 0)
channel = static_cast<WiFiChannel>(
kWiFiChannel5180 +
(frequency - kWiFiFrequency5180) / kWiFiBandwidth20MHz);
if ((frequency % kWiFiBandwidth20MHz) == 10)
channel = static_cast<WiFiChannel>(
kWiFiChannel5170 +
(frequency - kWiFiFrequency5170) / kWiFiBandwidth20MHz);
} else if (kWiFiFrequency5240 <= frequency &&
frequency <= kWiFiFrequency5320) {
if (((frequency - kWiFiFrequency5180) % kWiFiBandwidth20MHz) == 0)
channel = static_cast<WiFiChannel>(
kWiFiChannel5180 +
(frequency - kWiFiFrequency5180) / kWiFiBandwidth20MHz);
} else if (kWiFiFrequency5500 <= frequency &&
frequency <= kWiFiFrequency5700) {
if (((frequency - kWiFiFrequency5500) % kWiFiBandwidth20MHz) == 0)
channel = static_cast<WiFiChannel>(
kWiFiChannel5500 +
(frequency - kWiFiFrequency5500) / kWiFiBandwidth20MHz);
} else if (kWiFiFrequency5745 <= frequency &&
frequency <= kWiFiFrequency5825) {
if (((frequency - kWiFiFrequency5745) % kWiFiBandwidth20MHz) == 0)
channel = static_cast<WiFiChannel>(
kWiFiChannel5745 +
(frequency - kWiFiFrequency5745) / kWiFiBandwidth20MHz);
}
CHECK(kWiFiChannelUndef <= channel && channel < kWiFiChannelMax);
if (channel == kWiFiChannelUndef)
LOG(WARNING) << "no mapping for frequency " << frequency;
else
SLOG(Metrics, 3) << "mapped frequency " << frequency
<< " to enum bucket " << channel;
return channel;
}
// static
Metrics::WiFiSecurity Metrics::WiFiSecurityStringToEnum(
const string &security) {
if (security == kSecurityNone) {
return kWiFiSecurityNone;
} else if (security == kSecurityWep) {
return kWiFiSecurityWep;
} else if (security == kSecurityWpa) {
return kWiFiSecurityWpa;
} else if (security == kSecurityRsn) {
return kWiFiSecurityRsn;
} else if (security == kSecurity8021x) {
return kWiFiSecurity8021x;
} else if (security == kSecurityPsk) {
return kWiFiSecurityPsk;
} else {
return kWiFiSecurityUnknown;
}
}
// static
Metrics::WiFiApMode Metrics::WiFiApModeStringToEnum(const string &ap_mode) {
if (ap_mode == kModeManaged) {
return kWiFiApModeManaged;
} else if (ap_mode == kModeAdhoc) {
return kWiFiApModeAdHoc;
} else {
return kWiFiApModeUnknown;
}
}
// static
Metrics::EapOuterProtocol Metrics::EapOuterProtocolStringToEnum(
const string &outer) {
if (outer == kEapMethodPEAP) {
return kEapOuterProtocolPeap;
} else if (outer == kEapMethodTLS) {
return kEapOuterProtocolTls;
} else if (outer == kEapMethodTTLS) {
return kEapOuterProtocolTtls;
} else if (outer == kEapMethodLEAP) {
return kEapOuterProtocolLeap;
} else {
return kEapOuterProtocolUnknown;
}
}
// static
Metrics::EapInnerProtocol Metrics::EapInnerProtocolStringToEnum(
const string &inner) {
if (inner.empty()) {
return kEapInnerProtocolNone;
} else if (inner == kEapPhase2AuthPEAPMD5) {
return kEapInnerProtocolPeapMd5;
} else if (inner == kEapPhase2AuthPEAPMSCHAPV2) {
return kEapInnerProtocolPeapMschapv2;
} else if (inner == kEapPhase2AuthTTLSEAPMD5) {
return kEapInnerProtocolTtlsEapMd5;
} else if (inner == kEapPhase2AuthTTLSEAPMSCHAPV2) {
return kEapInnerProtocolTtlsEapMschapv2;
} else if (inner == kEapPhase2AuthTTLSMSCHAPV2) {
return kEapInnerProtocolTtlsMschapv2;
} else if (inner == kEapPhase2AuthTTLSMSCHAP) {
return kEapInnerProtocolTtlsMschap;
} else if (inner == kEapPhase2AuthTTLSPAP) {
return kEapInnerProtocolTtlsPap;
} else if (inner == kEapPhase2AuthTTLSCHAP) {
return kEapInnerProtocolTtlsChap;
} else {
return kEapInnerProtocolUnknown;
}
}
// static
Metrics::PortalResult Metrics::PortalDetectionResultToEnum(
const PortalDetector::Result &result) {
DCHECK(result.final);
PortalResult retval = kPortalResultUnknown;
// The only time we should end a successful portal detection is when we're
// in the Content phase. If we end with kStatusSuccess in any other phase,
// then this indicates that something bad has happened.
switch (result.phase) {
case PortalDetector::kPhaseDNS:
if (result.status == PortalDetector::kStatusFailure)
retval = kPortalResultDNSFailure;
else if (result.status == PortalDetector::kStatusTimeout)
retval = kPortalResultDNSTimeout;
else
LOG(DFATAL) << __func__ << ": Final result status " << result.status
<< " is not allowed in the DNS phase";
break;
case PortalDetector::kPhaseConnection:
if (result.status == PortalDetector::kStatusFailure)
retval = kPortalResultConnectionFailure;
else if (result.status == PortalDetector::kStatusTimeout)
retval = kPortalResultConnectionTimeout;
else
LOG(DFATAL) << __func__ << ": Final result status " << result.status
<< " is not allowed in the Connection phase";
break;
case PortalDetector::kPhaseHTTP:
if (result.status == PortalDetector::kStatusFailure)
retval = kPortalResultHTTPFailure;
else if (result.status == PortalDetector::kStatusTimeout)
retval = kPortalResultHTTPTimeout;
else
LOG(DFATAL) << __func__ << ": Final result status " << result.status
<< " is not allowed in the HTTP phase";
break;
case PortalDetector::kPhaseContent:
if (result.status == PortalDetector::kStatusSuccess)
retval = kPortalResultSuccess;
else if (result.status == PortalDetector::kStatusFailure)
retval = kPortalResultContentFailure;
else if (result.status == PortalDetector::kStatusTimeout)
retval = kPortalResultContentTimeout;
else
LOG(DFATAL) << __func__ << ": Final result status " << result.status
<< " is not allowed in the Content phase";
break;
case PortalDetector::kPhaseUnknown:
retval = kPortalResultUnknown;
break;
default:
LOG(DFATAL) << __func__ << ": Invalid phase " << result.phase;
break;
}
return retval;
}
void Metrics::Start() {
SLOG(Metrics, 2) << __func__;
}
void Metrics::Stop() {
SLOG(Metrics, 2) << __func__;
}
void Metrics::RegisterService(const Service &service) {
SLOG(Metrics, 2) << __func__;
LOG_IF(WARNING, ContainsKey(services_metrics_, &service))
<< "Repeatedly registering " << service.unique_name();
shared_ptr<ServiceMetrics> service_metrics(new ServiceMetrics());
services_metrics_[&service] = service_metrics;
InitializeCommonServiceMetrics(service);
}
void Metrics::DeregisterService(const Service &service) {
services_metrics_.erase(&service);
}
void Metrics::AddServiceStateTransitionTimer(
const Service &service,
const string &histogram_name,
Service::ConnectState start_state,
Service::ConnectState stop_state) {
SLOG(Metrics, 2) << __func__ << ": adding " << histogram_name << " for "
<< Service::ConnectStateToString(start_state) << " -> "
<< Service::ConnectStateToString(stop_state);
ServiceMetricsLookupMap::iterator it = services_metrics_.find(&service);
if (it == services_metrics_.end()) {
SLOG(Metrics, 1) << "service not found";
DCHECK(false);
return;
}
ServiceMetrics *service_metrics = it->second.get();
CHECK(start_state < stop_state);
chromeos_metrics::TimerReporter *timer =
new chromeos_metrics::TimerReporter(histogram_name,
kTimerHistogramMillisecondsMin,
kTimerHistogramMillisecondsMax,
kTimerHistogramNumBuckets);
service_metrics->timers.push_back(timer); // passes ownership.
service_metrics->start_on_state[start_state].push_back(timer);
service_metrics->stop_on_state[stop_state].push_back(timer);
}
void Metrics::NotifyDefaultServiceChanged(const Service *service) {
base::TimeDelta elapsed_seconds;
Technology::Identifier technology = (service) ? service->technology() :
Technology::kUnknown;
if (technology != last_default_technology_) {
if (last_default_technology_ != Technology::kUnknown) {
string histogram = GetFullMetricName(kMetricTimeOnlineSecondsSuffix,
last_default_technology_);
time_online_timer_->GetElapsedTime(&elapsed_seconds);
SendToUMA(histogram,
elapsed_seconds.InSeconds(),
kMetricTimeOnlineSecondsMin,
kMetricTimeOnlineSecondsMax,
kTimerHistogramNumBuckets);
}
last_default_technology_ = technology;
time_online_timer_->Start();
}
// Ignore changes that are not online/offline transitions; e.g.
// switching between wired and wireless. TimeToDrop measures
// time online regardless of how we are connected.
if ((service == NULL && !was_online_) || (service != NULL && was_online_))
return;
if (service == NULL) {
time_to_drop_timer_->GetElapsedTime(&elapsed_seconds);
SendToUMA(kMetricTimeToDropSeconds,
elapsed_seconds.InSeconds(),
kMetricTimeToDropSecondsMin,
kMetricTimeToDropSecondsMax,
kTimerHistogramNumBuckets);
} else {
time_to_drop_timer_->Start();
}
was_online_ = (service != NULL);
}
void Metrics::NotifyServiceStateChanged(const Service &service,
Service::ConnectState new_state) {
ServiceMetricsLookupMap::iterator it = services_metrics_.find(&service);
if (it == services_metrics_.end()) {
SLOG(Metrics, 1) << "service not found";
DCHECK(false);
return;
}
ServiceMetrics *service_metrics = it->second.get();
UpdateServiceStateTransitionMetrics(service_metrics, new_state);
if (new_state == Service::kStateFailure)
SendServiceFailure(service);
if (collect_bootstats_) {
bootstat_log(base::StringPrintf("network-%s-%s",
Technology::NameFromIdentifier(
service.technology()).c_str(),
service.GetStateString().c_str()).c_str());
}
if (new_state != Service::kStateConnected)
return;
base::TimeDelta time_resume_to_ready;
time_resume_to_ready_timer_->GetElapsedTime(&time_resume_to_ready);
time_resume_to_ready_timer_->Reset();
service.SendPostReadyStateMetrics(time_resume_to_ready.InMilliseconds());
}
string Metrics::GetFullMetricName(const char *metric_suffix,
Technology::Identifier technology_id) {
string technology = Technology::NameFromIdentifier(technology_id);
technology[0] = base::ToUpperASCII(technology[0]);
return base::StringPrintf("%s.%s.%s", kMetricPrefix, technology.c_str(),
metric_suffix);
}
void Metrics::NotifyServiceDisconnect(const Service &service) {
Technology::Identifier technology = service.technology();
string histogram = GetFullMetricName(kMetricDisconnectSuffix, technology);
SendToUMA(histogram,
service.explicitly_disconnected(),
kMetricDisconnectMin,
kMetricDisconnectMax,
kMetricDisconnectNumBuckets);
}
void Metrics::NotifySignalAtDisconnect(const Service &service,
int16_t signal_strength) {
// Negate signal_strength (goes from dBm to -dBm) because the metrics don't
// seem to handle negative values well. Now everything's positive.
Technology::Identifier technology = service.technology();
string histogram = GetFullMetricName(kMetricSignalAtDisconnectSuffix,
technology);
SendToUMA(histogram,
-signal_strength,
kMetricSignalAtDisconnectMin,
kMetricSignalAtDisconnectMax,
kMetricSignalAtDisconnectNumBuckets);
}
void Metrics::NotifySuspendDone() {
time_resume_to_ready_timer_->Start();
}
void Metrics::NotifyTerminationActionsStarted(
TerminationActionReason /*reason*/) {
if (time_termination_actions_timer->HasStarted())
return;
time_termination_actions_timer->Start();
}
void Metrics::NotifyTerminationActionsCompleted(
TerminationActionReason reason, bool success) {
if (!time_termination_actions_timer->HasStarted())
return;
int result = success ? kTerminationActionResultSuccess :
kTerminationActionResultFailure;
base::TimeDelta elapsed_time;
time_termination_actions_timer->GetElapsedTime(&elapsed_time);
time_termination_actions_timer->Reset();
string time_metric, result_metric;
switch (reason) {
case kTerminationActionReasonSuspend:
time_metric = kMetricTerminationActionTimeOnSuspend;
result_metric = kMetricTerminationActionResultOnSuspend;
break;
case kTerminationActionReasonTerminate:
time_metric = kMetricTerminationActionTimeOnTerminate;
result_metric = kMetricTerminationActionResultOnTerminate;
break;
}
SendToUMA(time_metric,
elapsed_time.InMilliseconds(),
kMetricTerminationActionTimeMillisecondsMin,
kMetricTerminationActionTimeMillisecondsMax,
kTimerHistogramNumBuckets);
SendEnumToUMA(result_metric,
result,
kTerminationActionResultMax);
}
void Metrics::NotifyLinkMonitorFailure(
Technology::Identifier technology,
LinkMonitorFailure failure,
int seconds_to_failure,
int broadcast_error_count,
int unicast_error_count) {
string histogram = GetFullMetricName(kMetricLinkMonitorFailureSuffix,
technology);
SendEnumToUMA(histogram, failure, kLinkMonitorFailureMax);
if (failure == kLinkMonitorFailureThresholdReached) {
if (seconds_to_failure > kMetricLinkMonitorSecondsToFailureMax) {
seconds_to_failure = kMetricLinkMonitorSecondsToFailureMax;
}
histogram = GetFullMetricName(kMetricLinkMonitorSecondsToFailureSuffix,
technology);
SendToUMA(histogram,
seconds_to_failure,
kMetricLinkMonitorSecondsToFailureMin,
kMetricLinkMonitorSecondsToFailureMax,
kMetricLinkMonitorSecondsToFailureNumBuckets);
histogram = GetFullMetricName(
kMetricLinkMonitorBroadcastErrorsAtFailureSuffix, technology);
SendToUMA(histogram,
broadcast_error_count,
kMetricLinkMonitorErrorCountMin,
kMetricLinkMonitorErrorCountMax,
kMetricLinkMonitorErrorCountNumBuckets);
histogram = GetFullMetricName(
kMetricLinkMonitorUnicastErrorsAtFailureSuffix, technology);
SendToUMA(histogram,
unicast_error_count,
kMetricLinkMonitorErrorCountMin,
kMetricLinkMonitorErrorCountMax,
kMetricLinkMonitorErrorCountNumBuckets);
}
}
void Metrics::NotifyLinkMonitorResponseTimeSampleAdded(
Technology::Identifier technology,
int response_time_milliseconds) {
string histogram = GetFullMetricName(
kMetricLinkMonitorResponseTimeSampleSuffix, technology);
SendToUMA(histogram,
response_time_milliseconds,
kMetricLinkMonitorResponseTimeSampleMin,
kMetricLinkMonitorResponseTimeSampleMax,
kMetricLinkMonitorResponseTimeSampleNumBuckets);
}
void Metrics::Notify80211Disconnect(WiFiDisconnectByWhom by_whom,
IEEE_80211::WiFiReasonCode reason) {
string metric_disconnect_reason;
string metric_disconnect_type;
WiFiStatusType type;
if (by_whom == kDisconnectedByAp) {
metric_disconnect_reason = kMetricLinkApDisconnectReason;
metric_disconnect_type = kMetricLinkApDisconnectType;
type = kStatusCodeTypeByAp;
} else {
metric_disconnect_reason = kMetricLinkClientDisconnectReason;
metric_disconnect_type = kMetricLinkClientDisconnectType;
switch (reason) {
case IEEE_80211::kReasonCodeSenderHasLeft:
case IEEE_80211::kReasonCodeDisassociatedHasLeft:
type = kStatusCodeTypeByUser;
break;
case IEEE_80211::kReasonCodeInactivity:
type = kStatusCodeTypeConsideredDead;
break;
default:
type = kStatusCodeTypeByClient;
break;
}
}
SendEnumToUMA(metric_disconnect_reason, reason,
IEEE_80211::kStatusCodeMax);
SendEnumToUMA(metric_disconnect_type, type, kStatusCodeTypeMax);
}
void Metrics::RegisterDevice(int interface_index,
Technology::Identifier technology) {
SLOG(Metrics, 2) << __func__ << ": " << interface_index;
shared_ptr<DeviceMetrics> device_metrics(new DeviceMetrics);
devices_metrics_[interface_index] = device_metrics;
device_metrics->technology = technology;
string histogram = GetFullMetricName(
kMetricTimeToInitializeMillisecondsSuffix, technology);
device_metrics->initialization_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToInitializeMillisecondsMin,
kMetricTimeToInitializeMillisecondsMax,
kMetricTimeToInitializeMillisecondsNumBuckets));
device_metrics->initialization_timer->Start();
histogram = GetFullMetricName(kMetricTimeToEnableMillisecondsSuffix,
technology);
device_metrics->enable_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToEnableMillisecondsMin,
kMetricTimeToEnableMillisecondsMax,
kMetricTimeToEnableMillisecondsNumBuckets));
histogram = GetFullMetricName(kMetricTimeToDisableMillisecondsSuffix,
technology);
device_metrics->disable_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToDisableMillisecondsMin,
kMetricTimeToDisableMillisecondsMax,
kMetricTimeToDisableMillisecondsNumBuckets));
histogram = GetFullMetricName(kMetricTimeToScanMillisecondsSuffix,
technology);
device_metrics->scan_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToScanMillisecondsMin,
kMetricTimeToScanMillisecondsMax,
kMetricTimeToScanMillisecondsNumBuckets));
histogram = GetFullMetricName(kMetricTimeToConnectMillisecondsSuffix,
technology);
device_metrics->connect_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToConnectMillisecondsMin,
kMetricTimeToConnectMillisecondsMax,
kMetricTimeToConnectMillisecondsNumBuckets));
histogram = GetFullMetricName(kMetricTimeToScanAndConnectMillisecondsSuffix,
technology);
device_metrics->scan_connect_timer.reset(
new chromeos_metrics::TimerReporter(
histogram,
kMetricTimeToScanMillisecondsMin,
kMetricTimeToScanMillisecondsMax +
kMetricTimeToConnectMillisecondsMax,
kMetricTimeToScanMillisecondsNumBuckets +
kMetricTimeToConnectMillisecondsNumBuckets));
device_metrics->auto_connect_timer.reset(
new chromeos_metrics::TimerReporter(
kMetricCellularAutoConnectTotalTime,
kMetricCellularAutoConnectTotalTimeMin,
kMetricCellularAutoConnectTotalTimeMax,
kMetricCellularAutoConnectTotalTimeNumBuckets));
}
bool Metrics::IsDeviceRegistered(int interface_index,
Technology::Identifier technology) {
SLOG(Metrics, 2) << __func__ << ": interface index: " << interface_index
<< ", technology: " << technology;
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return false;
// Make sure the device technologies match.
return (technology == device_metrics->technology);
}
void Metrics::DeregisterDevice(int interface_index) {
SLOG(Metrics, 2) << __func__ << ": interface index: " << interface_index;
devices_metrics_.erase(interface_index);
}
void Metrics::NotifyDeviceInitialized(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
if (!device_metrics->initialization_timer->Stop())
return;
device_metrics->initialization_timer->ReportMilliseconds();
}
void Metrics::NotifyDeviceEnableStarted(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->enable_timer->Start();
}
void Metrics::NotifyDeviceEnableFinished(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
if (!device_metrics->enable_timer->Stop())
return;
device_metrics->enable_timer->ReportMilliseconds();
}
void Metrics::NotifyDeviceDisableStarted(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->disable_timer->Start();
}
void Metrics::NotifyDeviceDisableFinished(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
if (!device_metrics->disable_timer->Stop())
return;
device_metrics->disable_timer->ReportMilliseconds();
}
void Metrics::NotifyDeviceScanStarted(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->scan_timer->Start();
device_metrics->scan_connect_timer->Start();
}
void Metrics::NotifyDeviceScanFinished(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
if (!device_metrics->scan_timer->Stop())
return;
// Don't send TimeToScan metrics if the elapsed time exceeds the max metrics
// value. Huge scan times usually mean something's gone awry; for cellular,
// for instance, this usually means that the modem is in an area without
// service and we're not interested in this scenario.
base::TimeDelta elapsed_time;
device_metrics->scan_timer->GetElapsedTime(&elapsed_time);
if (elapsed_time.InMilliseconds() <= kMetricTimeToScanMillisecondsMax)
device_metrics->scan_timer->ReportMilliseconds();
}
void Metrics::ResetScanTimer(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->scan_timer->Reset();
}
void Metrics::NotifyDeviceConnectStarted(int interface_index,
bool is_auto_connecting) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->connect_timer->Start();
if (is_auto_connecting) {
device_metrics->auto_connect_tries++;
if (device_metrics->auto_connect_tries == 1)
device_metrics->auto_connect_timer->Start();
} else {
AutoConnectMetricsReset(device_metrics);
}
}
void Metrics::NotifyDeviceConnectFinished(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
if (!device_metrics->connect_timer->Stop())
return;
device_metrics->connect_timer->ReportMilliseconds();
if (device_metrics->auto_connect_tries > 0) {
if (!device_metrics->auto_connect_timer->Stop())
return;
base::TimeDelta elapsed_time;
device_metrics->auto_connect_timer->GetElapsedTime(&elapsed_time);
if (elapsed_time.InMilliseconds() > kMetricCellularAutoConnectTotalTimeMax)
return;
device_metrics->auto_connect_timer->ReportMilliseconds();
SendToUMA(kMetricCellularAutoConnectTries,
device_metrics->auto_connect_tries,
kMetricCellularAutoConnectTriesMin,
kMetricCellularAutoConnectTriesMax,
kMetricCellularAutoConnectTriesNumBuckets);
AutoConnectMetricsReset(device_metrics);
}
if (!device_metrics->scan_connect_timer->Stop())
return;
device_metrics->scan_connect_timer->ReportMilliseconds();
}
void Metrics::ResetConnectTimer(int interface_index) {
DeviceMetrics *device_metrics = GetDeviceMetrics(interface_index);
if (device_metrics == NULL)
return;
device_metrics->connect_timer->Reset();
device_metrics->scan_connect_timer->Reset();
}
void Metrics::Notify3GPPRegistrationDelayedDropPosted() {
SendEnumToUMA(kMetricCellular3GPPRegistrationDelayedDrop,
kCellular3GPPRegistrationDelayedDropPosted,
kCellular3GPPRegistrationDelayedDropMax);
}
void Metrics::Notify3GPPRegistrationDelayedDropCanceled() {
SendEnumToUMA(kMetricCellular3GPPRegistrationDelayedDrop,
kCellular3GPPRegistrationDelayedDropCanceled,
kCellular3GPPRegistrationDelayedDropMax);
}
void Metrics::NotifyCellularDeviceDrop(const string &network_technology,
uint16 signal_strength) {
SLOG(Metrics, 2) << __func__ << ": " << network_technology
<< ", " << signal_strength;
CellularDropTechnology drop_technology = kCellularDropTechnologyUnknown;
if (network_technology == kNetworkTechnology1Xrtt) {
drop_technology = kCellularDropTechnology1Xrtt;
} else if (network_technology == kNetworkTechnologyEdge) {
drop_technology = kCellularDropTechnologyEdge;
} else if (network_technology == kNetworkTechnologyEvdo) {
drop_technology = kCellularDropTechnologyEvdo;
} else if (network_technology == kNetworkTechnologyGprs) {
drop_technology = kCellularDropTechnologyGprs;
} else if (network_technology == kNetworkTechnologyGsm) {
drop_technology = kCellularDropTechnologyGsm;
} else if (network_technology == kNetworkTechnologyHspa) {
drop_technology = kCellularDropTechnologyHspa;
} else if (network_technology == kNetworkTechnologyHspaPlus) {
drop_technology = kCellularDropTechnologyHspaPlus;
} else if (network_technology == kNetworkTechnologyLte) {
drop_technology = kCellularDropTechnologyLte;
} else if (network_technology == kNetworkTechnologyUmts) {
drop_technology = kCellularDropTechnologyUmts;
}
SendEnumToUMA(kMetricCellularDrop,
drop_technology,
kCellularDropTechnologyMax);
SendToUMA(kMetricCellularSignalStrengthBeforeDrop,
signal_strength,
kMetricCellularSignalStrengthBeforeDropMin,
kMetricCellularSignalStrengthBeforeDropMax,
kMetricCellularSignalStrengthBeforeDropNumBuckets);
}
void Metrics::NotifyCellularDeviceFailure(const Error &error) {
library_->SendUserActionToUMA(
kMetricCellularFailureReason + error.message());
}
void Metrics::NotifyCellularOutOfCredits(
Metrics::CellularOutOfCreditsReason reason) {
SendEnumToUMA(kMetricCellularOutOfCreditsReason,
reason,
kCellularOutOfCreditsReasonMax);
}
void Metrics::NotifyCorruptedProfile() {
SendEnumToUMA(kMetricCorruptedProfile,
kCorruptedProfile,
kCorruptedProfileMax);
}
void Metrics::NotifyDHCPOptionFailure(const Service &service) {
int failure_technology = kDHCPOptionFailureTechnologyUnknown;
switch (service.technology()) {
case Technology::kCellular:
failure_technology = kDHCPOptionFailureTechnologyCellular;
break;
case Technology::kEthernet:
failure_technology = kDHCPOptionFailureTechnologyEthernet;
break;
case Technology::kEthernetEap:
failure_technology = kDHCPOptionFailureTechnologyEthernetEap;
break;
case Technology::kWifi:
failure_technology = kDHCPOptionFailureTechnologyWifi;
break;
case Technology::kWiMax:
failure_technology = kDHCPOptionFailureTechnologyWiMax;
break;
case Technology::kVPN:
failure_technology = kDHCPOptionFailureTechnologyVPN;
break;
default:
break;
}
SendEnumToUMA(kMetricDHCPOptionFailureDetected,
failure_technology,
kDHCPOptionFailureTechnologyMax);
}
void Metrics::NotifyWifiAutoConnectableServices(int num_services) {
SendToUMA(kMetricWifiAutoConnectableServices,
num_services,
kMetricWifiAutoConnectableServicesMin,
kMetricWifiAutoConnectableServicesMax,
kMetricWifiAutoConnectableServicesNumBuckets);
}
void Metrics::NotifyWifiAvailableBSSes(int num_bss) {
SendToUMA(kMetricWifiAvailableBSSes,
num_bss,
kMetricWifiAvailableBSSesMin,
kMetricWifiAvailableBSSesMax,
kMetricWifiAvailableBSSesNumBuckets);
}
void Metrics::NotifyServicesOnSameNetwork(int num_services) {
SendToUMA(kMetricServicesOnSameNetwork,
num_services,
kMetricServicesOnSameNetworkMin,
kMetricServicesOnSameNetworkMax,
kMetricServicesOnSameNetworkNumBuckets);
}
void Metrics::NotifyUserInitiatedEvent(int event) {
SendEnumToUMA(kMetricUserInitiatedEvents,
event,
kUserInitiatedEventMax);
}
void Metrics::NotifyWifiTxBitrate(int bitrate) {
SendToUMA(kMetricWifiTxBitrate,
bitrate,
kMetricWifiTxBitrateMin,
kMetricWifiTxBitrateMax,
kMetricWifiTxBitrateNumBuckets);
}
void Metrics::NotifyUserInitiatedConnectionResult(const string &name,
int result) {
SendEnumToUMA(name,
result,
kUserInitiatedConnectionResultMax);
}
void Metrics::NotifyFallbackDNSTestResult(Technology::Identifier technology_id,
int result) {
string histogram = GetFullMetricName(kMetricFallbackDNSTestResultSuffix,
technology_id);
SendEnumToUMA(histogram,
result,
kFallbackDNSTestResultMax);
}
void Metrics::NotifyNetworkProblemDetected(Technology::Identifier technology_id,
int reason) {
string histogram = GetFullMetricName(kMetricNetworkProblemDetectedSuffix,
technology_id);
SendEnumToUMA(histogram,
reason,
kNetworkProblemMax);
}
bool Metrics::SendEnumToUMA(const string &name, int sample, int max) {
SLOG(Metrics, 5)
<< "Sending enum " << name << " with value " << sample << ".";
return library_->SendEnumToUMA(name, sample, max);
}
bool Metrics::SendToUMA(const string &name, int sample, int min, int max,
int num_buckets) {
SLOG(Metrics, 5)
<< "Sending metric " << name << " with value " << sample << ".";
return library_->SendToUMA(name, sample, min, max, num_buckets);
}
void Metrics::InitializeCommonServiceMetrics(const Service &service) {
Technology::Identifier technology = service.technology();
string histogram = GetFullMetricName(kMetricTimeToConfigMillisecondsSuffix,
technology);
AddServiceStateTransitionTimer(
service,
histogram,
Service::kStateConfiguring,
Service::kStateConnected);
histogram = GetFullMetricName(kMetricTimeToPortalMillisecondsSuffix,
technology);
AddServiceStateTransitionTimer(
service,
histogram,
Service::kStateConnected,
Service::kStatePortal);
histogram = GetFullMetricName(kMetricTimeToOnlineMillisecondsSuffix,
technology);
AddServiceStateTransitionTimer(
service,
histogram,
Service::kStateConnected,
Service::kStateOnline);
}
void Metrics::UpdateServiceStateTransitionMetrics(
ServiceMetrics *service_metrics,
Service::ConnectState new_state) {
const char *state_string = Service::ConnectStateToString(new_state);
SLOG(Metrics, 5) << __func__ << ": new_state=" << state_string;
TimerReportersList &start_timers = service_metrics->start_on_state[new_state];
for (auto &start_timer : start_timers) {
SLOG(Metrics, 5) << "Starting timer for " << start_timer->histogram_name()
<< " due to new state " << state_string << ".";
start_timer->Start();
}
TimerReportersList &stop_timers = service_metrics->stop_on_state[new_state];
for (auto &stop_timer : stop_timers) {
SLOG(Metrics, 5) << "Stopping timer for " << stop_timer->histogram_name()
<< " due to new state " << state_string << ".";
if (stop_timer->Stop())
stop_timer->ReportMilliseconds();
}
}
void Metrics::SendServiceFailure(const Service &service) {
library_->SendEnumToUMA(kMetricNetworkServiceErrors,
service.failure(),
kMetricNetworkServiceErrorsMax);
}
Metrics::DeviceMetrics *Metrics::GetDeviceMetrics(int interface_index) const {
DeviceMetricsLookupMap::const_iterator it =
devices_metrics_.find(interface_index);
if (it == devices_metrics_.end()) {
SLOG(Metrics, 2) << __func__ << ": device " << interface_index
<< " not found";
return NULL;
}
return it->second.get();
}
void Metrics::AutoConnectMetricsReset(DeviceMetrics *device_metrics) {
device_metrics->auto_connect_tries = 0;
device_metrics->auto_connect_timer->Reset();
}
void Metrics::set_library(MetricsLibraryInterface *library) {
chromeos_metrics::TimerReporter::set_metrics_lib(library);
library_ = library;
}
} // namespace shill