metrics/metrics_daemon.cc - platform/system/core - Git at Google

 // Copyright (c) 2010 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 "metrics_daemon.h"

 #include <dbus/dbus-glib-lowlevel.h>

 #include <base/logging.h>

 #include "counter.h"

 using base::Time;
 using base::TimeDelta;
 using base::TimeTicks;

 #define SAFE_MESSAGE(e) (e.message ? e.message : "unknown error")
 #define DBUS_IFACE_CRASH_REPORTER "org.chromium.CrashReporter"
 #define DBUS_IFACE_FLIMFLAM_MANAGER "org.chromium.flimflam.Manager"
 #define DBUS_IFACE_POWER_MANAGER "org.chromium.PowerManager"
 #define DBUS_IFACE_SESSION_MANAGER "org.chromium.SessionManagerInterface"

 // File to aggregate daily usage before sending to UMA.
 // TODO(petkov): This file should probably live in a user-specific stateful
 // location, e.g., /home/chronos/user.
 static const char kDailyUseRecordFile[] = "/var/log/metrics/daily-usage";
 static const char kUserCrashIntervalRecordFile[] =
     "/var/log/metrics/user-crash-interval";

 static const int kSecondsPerMinute = 60;
 static const int kMinutesPerHour = 60;
 static const int kHoursPerDay = 24;
 static const int kMinutesPerDay = kHoursPerDay * kMinutesPerHour;
 static const int kSecondsPerDay = kSecondsPerMinute * kMinutesPerDay;
 static const int kDaysPerWeek = 7;
 static const int kSecondsPerWeek = kSecondsPerDay * kDaysPerWeek;

 // The daily use monitor is scheduled to a 1-minute interval after
 // initial user activity and then it's exponentially backed off to
 // 10-minute intervals. Although not required, the back off is
 // implemented because the histogram buckets are spaced exponentially
 // anyway and to avoid too frequent metrics daemon process wake-ups
 // and file I/O.
 static const int kUseMonitorIntervalInit = 1 * kSecondsPerMinute;
 static const int kUseMonitorIntervalMax = 10 * kSecondsPerMinute;

 // static metrics parameters.
 const char MetricsDaemon::kMetricDailyUseTimeName[] =
     "Logging.DailyUseTime";
 const int MetricsDaemon::kMetricDailyUseTimeMin = 1;
 const int MetricsDaemon::kMetricDailyUseTimeMax = kMinutesPerDay;
 const int MetricsDaemon::kMetricDailyUseTimeBuckets = 50;

 const char MetricsDaemon::kMetricTimeToNetworkDropName[] =
     "Network.TimeToDrop";
 const int MetricsDaemon::kMetricTimeToNetworkDropMin = 1;
 const int MetricsDaemon::kMetricTimeToNetworkDropMax =
     8 /* hours */ * kMinutesPerHour * kSecondsPerMinute;
 const int MetricsDaemon::kMetricTimeToNetworkDropBuckets = 50;

 const char MetricsDaemon::kMetricUserCrashIntervalName[] =
     "Logging.UserCrashInterval";
 const int MetricsDaemon::kMetricUserCrashIntervalMin = 1;
 const int MetricsDaemon::kMetricUserCrashIntervalMax = 4 * kSecondsPerWeek;
 const int MetricsDaemon::kMetricUserCrashIntervalBuckets = 50;

 // static
 const char* MetricsDaemon::kDBusMatches_[] = {
   "type='signal',"
   "interface='" DBUS_IFACE_CRASH_REPORTER "',"
   "path='/',"
   "member='UserCrash'",

   "type='signal',"
   "sender='org.chromium.flimflam',"
   "interface='" DBUS_IFACE_FLIMFLAM_MANAGER "',"
   "path='/',"
   "member='StateChanged'",

   "type='signal',"
   "interface='" DBUS_IFACE_POWER_MANAGER "',"
   "path='/'",

   "type='signal',"
   "sender='org.chromium.SessionManager',"
   "interface='" DBUS_IFACE_SESSION_MANAGER "',"
   "path='/org/chromium/SessionManager',"
   "member='SessionStateChanged'",
 };

 // static
 const char* MetricsDaemon::kNetworkStates_[] = {
 #define STATE(name, capname) #name,
 #include "network_states.h"
 };

 // static
 const char* MetricsDaemon::kPowerStates_[] = {
 #define STATE(name, capname) #name,
 #include "power_states.h"
 };

 // static
 const char* MetricsDaemon::kSessionStates_[] = {
 #define STATE(name, capname) #name,
 #include "session_states.h"
 };

 MetricsDaemon::MetricsDaemon()
     : network_state_(kUnknownNetworkState),
       power_state_(kUnknownPowerState),
       session_state_(kUnknownSessionState),
       user_active_(false),
       usemon_interval_(0),
       usemon_source_(NULL) {}

 MetricsDaemon::~MetricsDaemon() {}

 void MetricsDaemon::Run(bool run_as_daemon) {
   if (!run_as_daemon || daemon(0, 0) == 0) {
     Loop();
   }
 }

 void MetricsDaemon::Init(bool testing, MetricsLibraryInterface* metrics_lib) {
   testing_ = testing;
   DCHECK(metrics_lib != NULL);
   metrics_lib_ = metrics_lib;
   daily_use_.reset(new chromeos_metrics::TaggedCounter());
   daily_use_->Init(kDailyUseRecordFile, &DailyUseReporter, this);
   user_crash_interval_.reset(new chromeos_metrics::TaggedCounter());
   user_crash_interval_->Init(kUserCrashIntervalRecordFile,
                              &UserCrashIntervalReporter, this);

   // Don't setup D-Bus and GLib in test mode.
   if (testing)
     return;

   g_thread_init(NULL);
   g_type_init();
   dbus_g_thread_init();

   DBusError error;
   dbus_error_init(&error);

   DBusConnection* connection = dbus_bus_get(DBUS_BUS_SYSTEM, &error);
   LOG_IF(FATAL, dbus_error_is_set(&error)) <<
       "No D-Bus connection: " << SAFE_MESSAGE(error);

   dbus_connection_setup_with_g_main(connection, NULL);

   // Registers D-Bus matches for the signals we would like to catch.
   for (unsigned int m = 0; m < arraysize(kDBusMatches_); m++) {
     const char* match = kDBusMatches_[m];
     DLOG(INFO) << "adding dbus match: " << match;
     dbus_bus_add_match(connection, match, &error);
     LOG_IF(FATAL, dbus_error_is_set(&error)) <<
         "unable to add a match: " << SAFE_MESSAGE(error);
   }

   // Adds the D-Bus filter routine to be called back whenever one of
   // the registered D-Bus matches is successful. The daemon is not
   // activated for D-Bus messages that don't match.
   CHECK(dbus_connection_add_filter(connection, MessageFilter, this, NULL));
 }

 void MetricsDaemon::Loop() {
   GMainLoop* loop = g_main_loop_new(NULL, false);
   g_main_loop_run(loop);
 }

 // static
 DBusHandlerResult MetricsDaemon::MessageFilter(DBusConnection* connection,
                                                DBusMessage* message,
                                                void* user_data) {
   Time now = Time::Now();
   TimeTicks ticks = TimeTicks::Now();
   DLOG(INFO) << "message intercepted @ " << now.ToInternalValue();

   int message_type = dbus_message_get_type(message);
   if (message_type != DBUS_MESSAGE_TYPE_SIGNAL) {
     DLOG(WARNING) << "unexpected message type " << message_type;
     return DBUS_HANDLER_RESULT_NOT_YET_HANDLED;
   }

   // Signal messages always have interfaces.
   const char* interface = dbus_message_get_interface(message);
   CHECK(interface != NULL);

   MetricsDaemon* daemon = static_cast<MetricsDaemon*>(user_data);

   DBusMessageIter iter;
   dbus_message_iter_init(message, &iter);
   if (strcmp(interface, DBUS_IFACE_CRASH_REPORTER) == 0) {
     CHECK(strcmp(dbus_message_get_member(message),
                  "UserCrash") == 0);
     daemon->ProcessUserCrash();
   } else if (strcmp(interface, DBUS_IFACE_FLIMFLAM_MANAGER) == 0) {
     CHECK(strcmp(dbus_message_get_member(message),
                  "StateChanged") == 0);

     char* state_name;
     dbus_message_iter_get_basic(&iter, &state_name);
     daemon->NetStateChanged(state_name, ticks);
   } else if (strcmp(interface, DBUS_IFACE_POWER_MANAGER) == 0) {
     const char* member = dbus_message_get_member(message);
     if (strcmp(member, "ScreenIsLocked") == 0) {
       daemon->SetUserActiveState(false, now);
     } else if (strcmp(member, "ScreenIsUnlocked") == 0) {
       daemon->SetUserActiveState(true, now);
     } else if (strcmp(member, "PowerStateChanged") == 0) {
       char* state_name;
       dbus_message_iter_get_basic(&iter, &state_name);
       daemon->PowerStateChanged(state_name, now);
     }
   } else if (strcmp(interface, DBUS_IFACE_SESSION_MANAGER) == 0) {
     CHECK(strcmp(dbus_message_get_member(message),
                  "SessionStateChanged") == 0);

     char* state_name;
     dbus_message_iter_get_basic(&iter, &state_name);
     daemon->SessionStateChanged(state_name, now);
   } else {
     DLOG(WARNING) << "unexpected interface: " << interface;
     return DBUS_HANDLER_RESULT_NOT_YET_HANDLED;
   }

   return DBUS_HANDLER_RESULT_HANDLED;
 }

 void MetricsDaemon::NetStateChanged(const char* state_name, TimeTicks ticks) {
   DLOG(INFO) << "network state: " << state_name;

   NetworkState state = LookupNetworkState(state_name);

   // Logs the time in seconds between the network going online to
   // going offline (or, more precisely, going not online) in order to
   // measure the mean time to network dropping. Going offline as part
   // of suspend-to-RAM is not logged as network drop -- the assumption
   // is that the message for suspend-to-RAM comes before the network
   // offline message which seems to and should be the case.
   if (state != kNetworkStateOnline &&
       network_state_ == kNetworkStateOnline &&
       power_state_ != kPowerStateMem) {
     TimeDelta since_online = ticks - network_state_last_;
     int online_time = static_cast<int>(since_online.InSeconds());
     SendMetric(kMetricTimeToNetworkDropName, online_time,
                kMetricTimeToNetworkDropMin,
                kMetricTimeToNetworkDropMax,
                kMetricTimeToNetworkDropBuckets);
   }

   network_state_ = state;
   network_state_last_ = ticks;
 }

 MetricsDaemon::NetworkState
 MetricsDaemon::LookupNetworkState(const char* state_name) {
   for (int i = 0; i < kNumberNetworkStates; i++) {
     if (strcmp(state_name, kNetworkStates_[i]) == 0) {
       return static_cast<NetworkState>(i);
     }
   }
   DLOG(WARNING) << "unknown network connection state: " << state_name;
   return kUnknownNetworkState;
 }

 void MetricsDaemon::PowerStateChanged(const char* state_name, Time now) {
   DLOG(INFO) << "power state: " << state_name;
   power_state_ = LookupPowerState(state_name);

   if (power_state_ != kPowerStateOn)
     SetUserActiveState(false, now);
 }

 MetricsDaemon::PowerState
 MetricsDaemon::LookupPowerState(const char* state_name) {
   for (int i = 0; i < kNumberPowerStates; i++) {
     if (strcmp(state_name, kPowerStates_[i]) == 0) {
       return static_cast<PowerState>(i);
     }
   }
   DLOG(WARNING) << "unknown power state: " << state_name;
   return kUnknownPowerState;
 }

 void MetricsDaemon::SessionStateChanged(const char* state_name, Time now) {
   DLOG(INFO) << "user session state: " << state_name;
   session_state_ = LookupSessionState(state_name);
   SetUserActiveState(session_state_ == kSessionStateStarted, now);
 }

 MetricsDaemon::SessionState
 MetricsDaemon::LookupSessionState(const char* state_name) {
   for (int i = 0; i < kNumberSessionStates; i++) {
     if (strcmp(state_name, kSessionStates_[i]) == 0) {
       return static_cast<SessionState>(i);
     }
   }
   DLOG(WARNING) << "unknown user session state: " << state_name;
   return kUnknownSessionState;
 }

 void MetricsDaemon::SetUserActiveState(bool active, Time now) {
   DLOG(INFO) << "user: " << (active ? "active" : "inactive");

   // Calculates the seconds of active use since the last update and
   // the day since Epoch, and logs the usage data.  Guards against the
   // time jumping back and forth due to the user changing it by
   // discarding the new use time.
   int seconds = 0;
   if (user_active_ && now > user_active_last_) {
     TimeDelta since_active = now - user_active_last_;
     if (since_active < TimeDelta::FromSeconds(
             kUseMonitorIntervalMax + kSecondsPerMinute)) {
       seconds = static_cast<int>(since_active.InSeconds());
     }
   }
   TimeDelta since_epoch = now - Time();
   int day = since_epoch.InDays();
   daily_use_->Update(day, seconds);
   user_crash_interval_->Update(0, seconds);

   // Schedules a use monitor on inactive->active transitions and
   // unschedules it on active->inactive transitions.
   if (!user_active_ && active)
     ScheduleUseMonitor(kUseMonitorIntervalInit, /* backoff */ false);
   else if (user_active_ && !active)
     UnscheduleUseMonitor();

   // Remembers the current active state and the time of the last
   // activity update.
   user_active_ = active;
   user_active_last_ = now;
 }

 void MetricsDaemon::ProcessUserCrash() {
   // Counts the active use time up to now.
   SetUserActiveState(user_active_, Time::Now());

   // Reports the active use time since the last crash and resets it.
   user_crash_interval_->Flush();
 }

 // static
 gboolean MetricsDaemon::UseMonitorStatic(gpointer data) {
   return static_cast<MetricsDaemon*>(data)->UseMonitor() ? TRUE : FALSE;
 }

 bool MetricsDaemon::UseMonitor() {
   SetUserActiveState(user_active_, Time::Now());

   // If a new monitor source/instance is scheduled, returns false to
   // tell GLib to destroy this monitor source/instance. Returns true
   // otherwise to keep calling back this monitor.
   return !ScheduleUseMonitor(usemon_interval_ * 2, /* backoff */ true);
 }

 bool MetricsDaemon::ScheduleUseMonitor(int interval, bool backoff)
 {
   if (testing_)
     return false;

   // Caps the interval -- the bigger the interval, the more active use
   // time will be potentially dropped on system shutdown.
   if (interval > kUseMonitorIntervalMax)
     interval = kUseMonitorIntervalMax;

   if (backoff) {
     // Back-off mode is used by the use monitor to reschedule itself
     // with exponential back-off in time. This mode doesn't create a
     // new timeout source if the new interval is the same as the old
     // one. Also, if a new timeout source is created, the old one is
     // not destroyed explicitly here -- it will be destroyed by GLib
     // when the monitor returns FALSE (see UseMonitor and
     // UseMonitorStatic).
     if (interval == usemon_interval_)
       return false;
   } else {
     UnscheduleUseMonitor();
   }

   // Schedules a new use monitor for |interval| seconds from now.
   DLOG(INFO) << "scheduling use monitor in " << interval << " seconds";
   usemon_source_ = g_timeout_source_new_seconds(interval);
   g_source_set_callback(usemon_source_, UseMonitorStatic, this,
                         NULL); // No destroy notification.
   g_source_attach(usemon_source_,
                   NULL); // Default context.
   usemon_interval_ = interval;
   return true;
 }

 void MetricsDaemon::UnscheduleUseMonitor() {
   // If there's a use monitor scheduled already, destroys it.
   if (usemon_source_ == NULL)
     return;

   DLOG(INFO) << "destroying use monitor";
   g_source_destroy(usemon_source_);
   usemon_source_ = NULL;
   usemon_interval_ = 0;
 }

 // static
 void MetricsDaemon::DailyUseReporter(void* handle, int tag, int count) {
   if (count <= 0)
     return;

   MetricsDaemon* daemon = static_cast<MetricsDaemon*>(handle);
   int minutes = (count + kSecondsPerMinute / 2) / kSecondsPerMinute;
   daemon->SendMetric(kMetricDailyUseTimeName, minutes,
                      kMetricDailyUseTimeMin,
                      kMetricDailyUseTimeMax,
                      kMetricDailyUseTimeBuckets);
 }

 // static
 void MetricsDaemon::UserCrashIntervalReporter(void* handle,
                                               int tag, int count) {
   MetricsDaemon* daemon = static_cast<MetricsDaemon*>(handle);
   daemon->SendMetric(kMetricUserCrashIntervalName, count,
                      kMetricUserCrashIntervalMin,
                      kMetricUserCrashIntervalMax,
                      kMetricUserCrashIntervalBuckets);
 }

 void MetricsDaemon::SendMetric(const std::string& name, int sample,
                                int min, int max, int nbuckets) {
   DLOG(INFO) << "received metric: " << name << " " << sample << " "
              << min << " " << max << " " << nbuckets;
   metrics_lib_->SendToUMA(name, sample, min, max, nbuckets);
 }
	// Copyright (c) 2010 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 "metrics_daemon.h"

	#include <dbus/dbus-glib-lowlevel.h>

	#include <base/logging.h>

	#include "counter.h"

	using base::Time;
	using base::TimeDelta;
	using base::TimeTicks;

	#define SAFE_MESSAGE(e) (e.message ? e.message : "unknown error")
	#define DBUS_IFACE_CRASH_REPORTER "org.chromium.CrashReporter"
	#define DBUS_IFACE_FLIMFLAM_MANAGER "org.chromium.flimflam.Manager"
	#define DBUS_IFACE_POWER_MANAGER "org.chromium.PowerManager"
	#define DBUS_IFACE_SESSION_MANAGER "org.chromium.SessionManagerInterface"

	// File to aggregate daily usage before sending to UMA.
	// TODO(petkov): This file should probably live in a user-specific stateful
	// location, e.g., /home/chronos/user.
	static const char kDailyUseRecordFile[] = "/var/log/metrics/daily-usage";
	static const char kUserCrashIntervalRecordFile[] =
	"/var/log/metrics/user-crash-interval";

	static const int kSecondsPerMinute = 60;
	static const int kMinutesPerHour = 60;
	static const int kHoursPerDay = 24;
	static const int kMinutesPerDay = kHoursPerDay * kMinutesPerHour;
	static const int kSecondsPerDay = kSecondsPerMinute * kMinutesPerDay;
	static const int kDaysPerWeek = 7;
	static const int kSecondsPerWeek = kSecondsPerDay * kDaysPerWeek;

	// The daily use monitor is scheduled to a 1-minute interval after
	// initial user activity and then it's exponentially backed off to
	// 10-minute intervals. Although not required, the back off is
	// implemented because the histogram buckets are spaced exponentially
	// anyway and to avoid too frequent metrics daemon process wake-ups
	// and file I/O.
	static const int kUseMonitorIntervalInit = 1 * kSecondsPerMinute;
	static const int kUseMonitorIntervalMax = 10 * kSecondsPerMinute;

	// static metrics parameters.
	const char MetricsDaemon::kMetricDailyUseTimeName[] =
	"Logging.DailyUseTime";
	const int MetricsDaemon::kMetricDailyUseTimeMin = 1;
	const int MetricsDaemon::kMetricDailyUseTimeMax = kMinutesPerDay;
	const int MetricsDaemon::kMetricDailyUseTimeBuckets = 50;

	const char MetricsDaemon::kMetricTimeToNetworkDropName[] =
	"Network.TimeToDrop";
	const int MetricsDaemon::kMetricTimeToNetworkDropMin = 1;
	const int MetricsDaemon::kMetricTimeToNetworkDropMax =
	8 /* hours / kMinutesPerHour * kSecondsPerMinute;
	const int MetricsDaemon::kMetricTimeToNetworkDropBuckets = 50;

	const char MetricsDaemon::kMetricUserCrashIntervalName[] =
	"Logging.UserCrashInterval";
	const int MetricsDaemon::kMetricUserCrashIntervalMin = 1;
	const int MetricsDaemon::kMetricUserCrashIntervalMax = 4 * kSecondsPerWeek;
	const int MetricsDaemon::kMetricUserCrashIntervalBuckets = 50;

	// static
	const char* MetricsDaemon::kDBusMatches_[] = {
	"type='signal',"
	"interface='" DBUS_IFACE_CRASH_REPORTER "',"
	"path='/',"
	"member='UserCrash'",

	"type='signal',"
	"sender='org.chromium.flimflam',"
	"interface='" DBUS_IFACE_FLIMFLAM_MANAGER "',"
	"path='/',"
	"member='StateChanged'",

	"type='signal',"
	"interface='" DBUS_IFACE_POWER_MANAGER "',"
	"path='/'",

	"type='signal',"
	"sender='org.chromium.SessionManager',"
	"interface='" DBUS_IFACE_SESSION_MANAGER "',"
	"path='/org/chromium/SessionManager',"
	"member='SessionStateChanged'",
	};

	// static
	const char* MetricsDaemon::kNetworkStates_[] = {
	#define STATE(name, capname) #name,
	#include "network_states.h"
	};

	// static
	const char* MetricsDaemon::kPowerStates_[] = {
	#define STATE(name, capname) #name,
	#include "power_states.h"
	};

	// static
	const char* MetricsDaemon::kSessionStates_[] = {
	#define STATE(name, capname) #name,
	#include "session_states.h"
	};

	MetricsDaemon::MetricsDaemon()
	: network_state_(kUnknownNetworkState),
	power_state_(kUnknownPowerState),
	session_state_(kUnknownSessionState),
	user_active_(false),
	usemon_interval_(0),
	usemon_source_(NULL) {}

	MetricsDaemon::~MetricsDaemon() {}

	void MetricsDaemon::Run(bool run_as_daemon) {
	if (!run_as_daemon \|\| daemon(0, 0) == 0) {
	Loop();
	}
	}

	void MetricsDaemon::Init(bool testing, MetricsLibraryInterface* metrics_lib) {
	testing_ = testing;
	DCHECK(metrics_lib != NULL);
	metrics_lib_ = metrics_lib;
	daily_use_.reset(new chromeos_metrics::TaggedCounter());
	daily_use_->Init(kDailyUseRecordFile, &DailyUseReporter, this);
	user_crash_interval_.reset(new chromeos_metrics::TaggedCounter());
	user_crash_interval_->Init(kUserCrashIntervalRecordFile,
	&UserCrashIntervalReporter, this);

	// Don't setup D-Bus and GLib in test mode.
	if (testing)
	return;

	g_thread_init(NULL);
	g_type_init();
	dbus_g_thread_init();

	DBusError error;
	dbus_error_init(&error);

	DBusConnection* connection = dbus_bus_get(DBUS_BUS_SYSTEM, &error);
	LOG_IF(FATAL, dbus_error_is_set(&error)) <<
	"No D-Bus connection: " << SAFE_MESSAGE(error);

	dbus_connection_setup_with_g_main(connection, NULL);

	// Registers D-Bus matches for the signals we would like to catch.
	for (unsigned int m = 0; m < arraysize(kDBusMatches_); m++) {
	const char* match = kDBusMatches_[m];
	DLOG(INFO) << "adding dbus match: " << match;
	dbus_bus_add_match(connection, match, &error);
	LOG_IF(FATAL, dbus_error_is_set(&error)) <<
	"unable to add a match: " << SAFE_MESSAGE(error);
	}

	// Adds the D-Bus filter routine to be called back whenever one of
	// the registered D-Bus matches is successful. The daemon is not
	// activated for D-Bus messages that don't match.
	CHECK(dbus_connection_add_filter(connection, MessageFilter, this, NULL));
	}

	void MetricsDaemon::Loop() {
	GMainLoop* loop = g_main_loop_new(NULL, false);
	g_main_loop_run(loop);
	}

	// static
	DBusHandlerResult MetricsDaemon::MessageFilter(DBusConnection* connection,
	DBusMessage* message,
	void* user_data) {
	Time now = Time::Now();
	TimeTicks ticks = TimeTicks::Now();
	DLOG(INFO) << "message intercepted @ " << now.ToInternalValue();

	int message_type = dbus_message_get_type(message);
	if (message_type != DBUS_MESSAGE_TYPE_SIGNAL) {
	DLOG(WARNING) << "unexpected message type " << message_type;
	return DBUS_HANDLER_RESULT_NOT_YET_HANDLED;
	}

	// Signal messages always have interfaces.
	const char* interface = dbus_message_get_interface(message);
	CHECK(interface != NULL);

	MetricsDaemon* daemon = static_cast<MetricsDaemon*>(user_data);

	DBusMessageIter iter;
	dbus_message_iter_init(message, &iter);
	if (strcmp(interface, DBUS_IFACE_CRASH_REPORTER) == 0) {
	CHECK(strcmp(dbus_message_get_member(message),
	"UserCrash") == 0);
	daemon->ProcessUserCrash();
	} else if (strcmp(interface, DBUS_IFACE_FLIMFLAM_MANAGER) == 0) {
	CHECK(strcmp(dbus_message_get_member(message),
	"StateChanged") == 0);

	char* state_name;
	dbus_message_iter_get_basic(&iter, &state_name);
	daemon->NetStateChanged(state_name, ticks);
	} else if (strcmp(interface, DBUS_IFACE_POWER_MANAGER) == 0) {
	const char* member = dbus_message_get_member(message);
	if (strcmp(member, "ScreenIsLocked") == 0) {
	daemon->SetUserActiveState(false, now);
	} else if (strcmp(member, "ScreenIsUnlocked") == 0) {
	daemon->SetUserActiveState(true, now);
	} else if (strcmp(member, "PowerStateChanged") == 0) {
	char* state_name;
	dbus_message_iter_get_basic(&iter, &state_name);
	daemon->PowerStateChanged(state_name, now);
	}
	} else if (strcmp(interface, DBUS_IFACE_SESSION_MANAGER) == 0) {
	CHECK(strcmp(dbus_message_get_member(message),
	"SessionStateChanged") == 0);

	char* state_name;
	dbus_message_iter_get_basic(&iter, &state_name);
	daemon->SessionStateChanged(state_name, now);
	} else {
	DLOG(WARNING) << "unexpected interface: " << interface;
	return DBUS_HANDLER_RESULT_NOT_YET_HANDLED;
	}

	return DBUS_HANDLER_RESULT_HANDLED;
	}

	void MetricsDaemon::NetStateChanged(const char* state_name, TimeTicks ticks) {
	DLOG(INFO) << "network state: " << state_name;

	NetworkState state = LookupNetworkState(state_name);

	// Logs the time in seconds between the network going online to
	// going offline (or, more precisely, going not online) in order to
	// measure the mean time to network dropping. Going offline as part
	// of suspend-to-RAM is not logged as network drop -- the assumption
	// is that the message for suspend-to-RAM comes before the network
	// offline message which seems to and should be the case.
	if (state != kNetworkStateOnline &&
	network_state_ == kNetworkStateOnline &&
	power_state_ != kPowerStateMem) {
	TimeDelta since_online = ticks - network_state_last_;
	int online_time = static_cast<int>(since_online.InSeconds());
	SendMetric(kMetricTimeToNetworkDropName, online_time,
	kMetricTimeToNetworkDropMin,
	kMetricTimeToNetworkDropMax,
	kMetricTimeToNetworkDropBuckets);
	}

	network_state_ = state;
	network_state_last_ = ticks;
	}

	MetricsDaemon::NetworkState
	MetricsDaemon::LookupNetworkState(const char* state_name) {
	for (int i = 0; i < kNumberNetworkStates; i++) {
	if (strcmp(state_name, kNetworkStates_[i]) == 0) {
	return static_cast<NetworkState>(i);
	}
	}
	DLOG(WARNING) << "unknown network connection state: " << state_name;
	return kUnknownNetworkState;
	}

	void MetricsDaemon::PowerStateChanged(const char* state_name, Time now) {
	DLOG(INFO) << "power state: " << state_name;
	power_state_ = LookupPowerState(state_name);

	if (power_state_ != kPowerStateOn)
	SetUserActiveState(false, now);
	}

	MetricsDaemon::PowerState
	MetricsDaemon::LookupPowerState(const char* state_name) {
	for (int i = 0; i < kNumberPowerStates; i++) {
	if (strcmp(state_name, kPowerStates_[i]) == 0) {
	return static_cast<PowerState>(i);
	}
	}
	DLOG(WARNING) << "unknown power state: " << state_name;
	return kUnknownPowerState;
	}

	void MetricsDaemon::SessionStateChanged(const char* state_name, Time now) {
	DLOG(INFO) << "user session state: " << state_name;
	session_state_ = LookupSessionState(state_name);
	SetUserActiveState(session_state_ == kSessionStateStarted, now);
	}

	MetricsDaemon::SessionState
	MetricsDaemon::LookupSessionState(const char* state_name) {
	for (int i = 0; i < kNumberSessionStates; i++) {
	if (strcmp(state_name, kSessionStates_[i]) == 0) {
	return static_cast<SessionState>(i);
	}
	}
	DLOG(WARNING) << "unknown user session state: " << state_name;
	return kUnknownSessionState;
	}

	void MetricsDaemon::SetUserActiveState(bool active, Time now) {
	DLOG(INFO) << "user: " << (active ? "active" : "inactive");

	// Calculates the seconds of active use since the last update and
	// the day since Epoch, and logs the usage data. Guards against the
	// time jumping back and forth due to the user changing it by
	// discarding the new use time.
	int seconds = 0;
	if (user_active_ && now > user_active_last_) {
	TimeDelta since_active = now - user_active_last_;
	if (since_active < TimeDelta::FromSeconds(
	kUseMonitorIntervalMax + kSecondsPerMinute)) {
	seconds = static_cast<int>(since_active.InSeconds());
	}
	}
	TimeDelta since_epoch = now - Time();
	int day = since_epoch.InDays();
	daily_use_->Update(day, seconds);
	user_crash_interval_->Update(0, seconds);

	// Schedules a use monitor on inactive->active transitions and
	// unschedules it on active->inactive transitions.
	if (!user_active_ && active)
	ScheduleUseMonitor(kUseMonitorIntervalInit, /* backoff */ false);
	else if (user_active_ && !active)
	UnscheduleUseMonitor();

	// Remembers the current active state and the time of the last
	// activity update.
	user_active_ = active;
	user_active_last_ = now;
	}

	void MetricsDaemon::ProcessUserCrash() {
	// Counts the active use time up to now.
	SetUserActiveState(user_active_, Time::Now());

	// Reports the active use time since the last crash and resets it.
	user_crash_interval_->Flush();
	}

	// static
	gboolean MetricsDaemon::UseMonitorStatic(gpointer data) {
	return static_cast<MetricsDaemon*>(data)->UseMonitor() ? TRUE : FALSE;
	}

	bool MetricsDaemon::UseMonitor() {
	SetUserActiveState(user_active_, Time::Now());

	// If a new monitor source/instance is scheduled, returns false to
	// tell GLib to destroy this monitor source/instance. Returns true
	// otherwise to keep calling back this monitor.
	return !ScheduleUseMonitor(usemon_interval_ * 2, /* backoff */ true);
	}

	bool MetricsDaemon::ScheduleUseMonitor(int interval, bool backoff)
	{
	if (testing_)
	return false;

	// Caps the interval -- the bigger the interval, the more active use
	// time will be potentially dropped on system shutdown.
	if (interval > kUseMonitorIntervalMax)
	interval = kUseMonitorIntervalMax;

	if (backoff) {
	// Back-off mode is used by the use monitor to reschedule itself
	// with exponential back-off in time. This mode doesn't create a
	// new timeout source if the new interval is the same as the old
	// one. Also, if a new timeout source is created, the old one is
	// not destroyed explicitly here -- it will be destroyed by GLib
	// when the monitor returns FALSE (see UseMonitor and
	// UseMonitorStatic).
	if (interval == usemon_interval_)
	return false;
	} else {
	UnscheduleUseMonitor();
	}

	// Schedules a new use monitor for \|interval\| seconds from now.
	DLOG(INFO) << "scheduling use monitor in " << interval << " seconds";
	usemon_source_ = g_timeout_source_new_seconds(interval);
	g_source_set_callback(usemon_source_, UseMonitorStatic, this,
	NULL); // No destroy notification.
	g_source_attach(usemon_source_,
	NULL); // Default context.
	usemon_interval_ = interval;
	return true;
	}

	void MetricsDaemon::UnscheduleUseMonitor() {
	// If there's a use monitor scheduled already, destroys it.
	if (usemon_source_ == NULL)
	return;

	DLOG(INFO) << "destroying use monitor";
	g_source_destroy(usemon_source_);
	usemon_source_ = NULL;
	usemon_interval_ = 0;
	}

	// static
	void MetricsDaemon::DailyUseReporter(void* handle, int tag, int count) {
	if (count <= 0)
	return;

	MetricsDaemon* daemon = static_cast<MetricsDaemon*>(handle);
	int minutes = (count + kSecondsPerMinute / 2) / kSecondsPerMinute;
	daemon->SendMetric(kMetricDailyUseTimeName, minutes,
	kMetricDailyUseTimeMin,
	kMetricDailyUseTimeMax,
	kMetricDailyUseTimeBuckets);
	}

	// static
	void MetricsDaemon::UserCrashIntervalReporter(void* handle,
	int tag, int count) {
	MetricsDaemon* daemon = static_cast<MetricsDaemon*>(handle);
	daemon->SendMetric(kMetricUserCrashIntervalName, count,
	kMetricUserCrashIntervalMin,
	kMetricUserCrashIntervalMax,
	kMetricUserCrashIntervalBuckets);
	}

	void MetricsDaemon::SendMetric(const std::string& name, int sample,
	int min, int max, int nbuckets) {
	DLOG(INFO) << "received metric: " << name << " " << sample << " "
	<< min << " " << max << " " << nbuckets;
	metrics_lib_->SendToUMA(name, sample, min, max, nbuckets);
	}