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// Copyright (c) 2006-2008 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.
// Windows Timer Primer
//
// A good article: http://www.ddj.com/windows/184416651
// A good mozilla bug: http://bugzilla.mozilla.org/show_bug.cgi?id=363258
//
// The default windows timer, GetSystemTimeAsFileTime is not very precise.
// It is only good to ~15.5ms.
//
// QueryPerformanceCounter is the logical choice for a high-precision timer.
// However, it is known to be buggy on some hardware. Specifically, it can
// sometimes "jump". On laptops, QPC can also be very expensive to call.
// It's 3-4x slower than timeGetTime() on desktops, but can be 10x slower
// on laptops. A unittest exists which will show the relative cost of various
// timers on any system.
//
// The next logical choice is timeGetTime(). timeGetTime has a precision of
// 1ms, but only if you call APIs (timeBeginPeriod()) which affect all other
// applications on the system. By default, precision is only 15.5ms.
// Unfortunately, we don't want to call timeBeginPeriod because we don't
// want to affect other applications. Further, on mobile platforms, use of
// faster multimedia timers can hurt battery life. See the intel
// article about this here:
// http://softwarecommunity.intel.com/articles/eng/1086.htm
//
// To work around all this, we're going to generally use timeGetTime(). We
// will only increase the system-wide timer if we're not running on battery
// power. Using timeBeginPeriod(1) is a requirement in order to make our
// message loop waits have the same resolution that our time measurements
// do. Otherwise, WaitForSingleObject(..., 1) will no less than 15ms when
// there is nothing else to waken the Wait.
#include "base/time.h"
#pragma comment(lib, "winmm.lib")
#include <windows.h>
#include <mmsystem.h>
#include "base/basictypes.h"
#include "base/lock.h"
#include "base/logging.h"
#include "base/cpu.h"
#include "base/singleton.h"
#include "base/system_monitor.h"
using base::Time;
using base::TimeDelta;
using base::TimeTicks;
namespace {
// From MSDN, FILETIME "Contains a 64-bit value representing the number of
// 100-nanosecond intervals since January 1, 1601 (UTC)."
int64 FileTimeToMicroseconds(const FILETIME& ft) {
// Need to bit_cast to fix alignment, then divide by 10 to convert
// 100-nanoseconds to milliseconds. This only works on little-endian
// machines.
return bit_cast<int64, FILETIME>(ft) / 10;
}
void MicrosecondsToFileTime(int64 us, FILETIME* ft) {
DCHECK(us >= 0) << "Time is less than 0, negative values are not "
"representable in FILETIME";
// Multiply by 10 to convert milliseconds to 100-nanoseconds. Bit_cast will
// handle alignment problems. This only works on little-endian machines.
*ft = bit_cast<FILETIME, int64>(us * 10);
}
int64 CurrentWallclockMicroseconds() {
FILETIME ft;
::GetSystemTimeAsFileTime(&ft);
return FileTimeToMicroseconds(ft);
}
// Time between resampling the un-granular clock for this API. 60 seconds.
const int kMaxMillisecondsToAvoidDrift = 60 * Time::kMillisecondsPerSecond;
int64 initial_time = 0;
TimeTicks initial_ticks;
void InitializeClock() {
initial_ticks = TimeTicks::Now();
initial_time = CurrentWallclockMicroseconds();
}
class HighResolutionTimerManager : public base::SystemMonitor::PowerObserver {
public:
~HighResolutionTimerManager() {
StopMonitoring();
UseHiResClock(false);
}
void Enable() {
StopMonitoring();
UseHiResClock(true);
}
void StartMonitoring() {
if (is_monitoring_)
return;
is_monitoring_ = true;
base::SystemMonitor* system = base::SystemMonitor::Get();
DCHECK(system);
system->AddObserver(this);
UseHiResClock(!system->BatteryPower());
}
void StopMonitoring() {
if (!is_monitoring_)
return;
is_monitoring_ = false;
base::SystemMonitor* monitor = base::SystemMonitor::Get();
if (monitor)
monitor->RemoveObserver(this);
}
// Interfaces for monitoring Power changes.
void OnPowerStateChange(base::SystemMonitor* system) {
UseHiResClock(!system->BatteryPower());
}
void OnSuspend(base::SystemMonitor* system) {}
void OnResume(base::SystemMonitor* system) {}
private:
HighResolutionTimerManager()
: is_monitoring_(false),
hi_res_clock_enabled_(false) {
}
friend struct DefaultSingletonTraits<HighResolutionTimerManager>;
// Enable or disable the faster multimedia timer.
void UseHiResClock(bool enabled) {
if (enabled == hi_res_clock_enabled_)
return;
if (enabled)
timeBeginPeriod(1);
else
timeEndPeriod(1);
hi_res_clock_enabled_ = enabled;
}
bool is_monitoring_;
bool hi_res_clock_enabled_;
DISALLOW_COPY_AND_ASSIGN(HighResolutionTimerManager);
};
} // namespace
// Time -----------------------------------------------------------------------
// The internal representation of Time uses FILETIME, whose epoch is 1601-01-01
// 00:00:00 UTC. ((1970-1601)*365+89)*24*60*60*1000*1000, where 89 is the
// number of leap year days between 1601 and 1970: (1970-1601)/4 excluding
// 1700, 1800, and 1900.
// static
const int64 Time::kTimeTToMicrosecondsOffset = GG_INT64_C(11644473600000000);
// static
Time Time::Now() {
if (initial_time == 0)
InitializeClock();
// We implement time using the high-resolution timers so that we can get
// timeouts which are smaller than 10-15ms. If we just used
// CurrentWallclockMicroseconds(), we'd have the less-granular timer.
//
// To make this work, we initialize the clock (initial_time) and the
// counter (initial_ctr). To compute the initial time, we can check
// the number of ticks that have elapsed, and compute the delta.
//
// To avoid any drift, we periodically resync the counters to the system
// clock.
while(true) {
TimeTicks ticks = TimeTicks::Now();
// Calculate the time elapsed since we started our timer
TimeDelta elapsed = ticks - initial_ticks;
// Check if enough time has elapsed that we need to resync the clock.
if (elapsed.InMilliseconds() > kMaxMillisecondsToAvoidDrift) {
InitializeClock();
continue;
}
return Time(elapsed + initial_time);
}
}
// static
Time Time::NowFromSystemTime() {
// Force resync.
InitializeClock();
return Time(initial_time);
}
// static
Time Time::FromFileTime(FILETIME ft) {
return Time(FileTimeToMicroseconds(ft));
}
FILETIME Time::ToFileTime() const {
FILETIME utc_ft;
MicrosecondsToFileTime(us_, &utc_ft);
return utc_ft;
}
// static
void Time::StartSystemMonitorObserver() {
Singleton<HighResolutionTimerManager>()->StartMonitoring();
}
// static
void Time::EnableHiResClockForTests() {
Singleton<HighResolutionTimerManager>()->Enable();
}
// static
Time Time::FromExploded(bool is_local, const Exploded& exploded) {
// Create the system struct representing our exploded time. It will either be
// in local time or UTC.
SYSTEMTIME st;
st.wYear = exploded.year;
st.wMonth = exploded.month;
st.wDayOfWeek = exploded.day_of_week;
st.wDay = exploded.day_of_month;
st.wHour = exploded.hour;
st.wMinute = exploded.minute;
st.wSecond = exploded.second;
st.wMilliseconds = exploded.millisecond;
// Convert to FILETIME.
FILETIME ft;
if (!SystemTimeToFileTime(&st, &ft)) {
NOTREACHED() << "Unable to convert time";
return Time(0);
}
// Ensure that it's in UTC.
if (is_local) {
FILETIME utc_ft;
LocalFileTimeToFileTime(&ft, &utc_ft);
return Time(FileTimeToMicroseconds(utc_ft));
}
return Time(FileTimeToMicroseconds(ft));
}
void Time::Explode(bool is_local, Exploded* exploded) const {
// FILETIME in UTC.
FILETIME utc_ft;
MicrosecondsToFileTime(us_, &utc_ft);
// FILETIME in local time if necessary.
BOOL success = TRUE;
FILETIME ft;
if (is_local)
success = FileTimeToLocalFileTime(&utc_ft, &ft);
else
ft = utc_ft;
// FILETIME in SYSTEMTIME (exploded).
SYSTEMTIME st;
if (!success || !FileTimeToSystemTime(&ft, &st)) {
NOTREACHED() << "Unable to convert time, don't know why";
ZeroMemory(exploded, sizeof(exploded));
return;
}
exploded->year = st.wYear;
exploded->month = st.wMonth;
exploded->day_of_week = st.wDayOfWeek;
exploded->day_of_month = st.wDay;
exploded->hour = st.wHour;
exploded->minute = st.wMinute;
exploded->second = st.wSecond;
exploded->millisecond = st.wMilliseconds;
}
// TimeTicks ------------------------------------------------------------------
namespace {
// We define a wrapper to adapt between the __stdcall and __cdecl call of the
// mock function, and to avoid a static constructor. Assigning an import to a
// function pointer directly would require setup code to fetch from the IAT.
DWORD timeGetTimeWrapper() {
return timeGetTime();
}
DWORD (*tick_function)(void) = &timeGetTimeWrapper;
// We use timeGetTime() to implement TimeTicks::Now(). This can be problematic
// because it returns the number of milliseconds since Windows has started,
// which will roll over the 32-bit value every ~49 days. We try to track
// rollover ourselves, which works if TimeTicks::Now() is called at least every
// 49 days.
class NowSingleton {
public:
NowSingleton()
: rollover_(TimeDelta::FromMilliseconds(0)),
last_seen_(0) {
}
~NowSingleton() {
}
TimeDelta Now() {
AutoLock locked(lock_);
// We should hold the lock while calling tick_function to make sure that
// we keep our last_seen_ stay correctly in sync.
DWORD now = tick_function();
if (now < last_seen_)
rollover_ += TimeDelta::FromMilliseconds(0x100000000I64); // ~49.7 days.
last_seen_ = now;
return TimeDelta::FromMilliseconds(now) + rollover_;
}
private:
Lock lock_; // To protected last_seen_ and rollover_.
TimeDelta rollover_; // Accumulation of time lost due to rollover.
DWORD last_seen_; // The last timeGetTime value we saw, to detect rollover.
DISALLOW_COPY_AND_ASSIGN(NowSingleton);
};
// Overview of time counters:
// (1) CPU cycle counter. (Retrieved via RDTSC)
// The CPU counter provides the highest resolution time stamp and is the least
// expensive to retrieve. However, the CPU counter is unreliable and should not
// be used in production. Its biggest issue is that it is per processor and it
// is not synchronized between processors. Also, on some computers, the counters
// will change frequency due to thermal and power changes, and stop in some
// states.
//
// (2) QueryPerformanceCounter (QPC). The QPC counter provides a high-
// resolution (100 nanoseconds) time stamp but is comparatively more expensive
// to retrieve. What QueryPerformanceCounter actually does is up to the HAL.
// (with some help from ACPI).
// According to http://blogs.msdn.com/oldnewthing/archive/2005/09/02/459952.aspx
// in the worst case, it gets the counter from the rollover interrupt on the
// programmable interrupt timer. In best cases, the HAL may conclude that the
// RDTSC counter runs at a constant frequency, then it uses that instead. On
// multiprocessor machines, it will try to verify the values returned from
// RDTSC on each processor are consistent with each other, and apply a handful
// of workarounds for known buggy hardware. In other words, QPC is supposed to
// give consistent result on a multiprocessor computer, but it is unreliable in
// reality due to bugs in BIOS or HAL on some, especially old computers.
// With recent updates on HAL and newer BIOS, QPC is getting more reliable but
// it should be used with caution.
//
// (3) System time. The system time provides a low-resolution (typically 10ms
// to 55 milliseconds) time stamp but is comparatively less expensive to
// retrieve and more reliable.
class HighResNowSingleton {
public:
HighResNowSingleton()
: ticks_per_microsecond_(0.0),
skew_(0) {
InitializeClock();
// On Athlon X2 CPUs (e.g. model 15) QueryPerformanceCounter is
// unreliable. Fallback to low-res clock.
base::CPU cpu;
if (cpu.vendor_name() == "AuthenticAMD" && cpu.family() == 15)
DisableHighResClock();
}
bool IsUsingHighResClock() {
return ticks_per_microsecond_ != 0.0;
}
void DisableHighResClock() {
ticks_per_microsecond_ = 0.0;
}
TimeDelta Now() {
// Our maximum tolerance for QPC drifting.
const int kMaxTimeDrift = 50 * Time::kMicrosecondsPerMillisecond;
if (IsUsingHighResClock()) {
int64 now = UnreliableNow();
// Verify that QPC does not seem to drift.
DCHECK(now - ReliableNow() - skew_ < kMaxTimeDrift);
return TimeDelta::FromMicroseconds(now);
}
// Just fallback to the slower clock.
return Singleton<NowSingleton>::get()->Now();
}
private:
// Synchronize the QPC clock with GetSystemTimeAsFileTime.
void InitializeClock() {
LARGE_INTEGER ticks_per_sec = {0};
if (!QueryPerformanceFrequency(&ticks_per_sec))
return; // Broken, we don't guarantee this function works.
ticks_per_microsecond_ = static_cast<float>(ticks_per_sec.QuadPart) /
static_cast<float>(Time::kMicrosecondsPerSecond);
skew_ = UnreliableNow() - ReliableNow();
}
// Get the number of microseconds since boot in a reliable fashion
int64 UnreliableNow() {
LARGE_INTEGER now;
QueryPerformanceCounter(&now);
return static_cast<int64>(now.QuadPart / ticks_per_microsecond_);
}
// Get the number of microseconds since boot in a reliable fashion
int64 ReliableNow() {
return Singleton<NowSingleton>::get()->Now().InMicroseconds();
}
// Cached clock frequency -> microseconds. This assumes that the clock
// frequency is faster than one microsecond (which is 1MHz, should be OK).
float ticks_per_microsecond_; // 0 indicates QPF failed and we're broken.
int64 skew_; // Skew between lo-res and hi-res clocks (for debugging).
DISALLOW_COPY_AND_ASSIGN(HighResNowSingleton);
};
} // namespace
// static
TimeTicks::TickFunctionType TimeTicks::SetMockTickFunction(
TickFunctionType ticker) {
TickFunctionType old = tick_function;
tick_function = ticker;
return old;
}
// static
TimeTicks TimeTicks::Now() {
return TimeTicks() + Singleton<NowSingleton>::get()->Now();
}
// static
TimeTicks TimeTicks::HighResNow() {
return TimeTicks() + Singleton<HighResNowSingleton>::get()->Now();
}
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