src/base/memory/memory_pressure_monitor_win.cc - cobalt - Git at Google

 // Copyright 2015 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 "base/memory/memory_pressure_monitor_win.h"

 #include <windows.h>

 #include "base/single_thread_task_runner.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "base/time/time.h"
 #include "starboard/types.h"

 namespace base {
 namespace win {

 namespace {

 static const DWORDLONG kMBBytes = 1024 * 1024;

 }  // namespace

 // The following constants have been lifted from similar values in the ChromeOS
 // memory pressure monitor. The values were determined experimentally to ensure
 // sufficient responsiveness of the memory pressure subsystem, and minimal
 // overhead.
 const int MemoryPressureMonitor::kPollingIntervalMs = 5000;
 const int MemoryPressureMonitor::kModeratePressureCooldownMs = 10000;
 const int MemoryPressureMonitor::kModeratePressureCooldownCycles =
     kModeratePressureCooldownMs / kPollingIntervalMs;

 // TODO(chrisha): Explore the following constants further with an experiment.

 // A system is considered 'high memory' if it has more than 1.5GB of system
 // memory available for use by the memory manager (not reserved for hardware
 // and drivers). This is a fuzzy version of the ~2GB discussed below.
 const int MemoryPressureMonitor::kLargeMemoryThresholdMb = 1536;

 // These are the default thresholds used for systems with < ~2GB of physical
 // memory. Such systems have been observed to always maintain ~100MB of
 // available memory, paging until that is the case. To try to avoid paging a
 // threshold slightly above this is chosen. The moderate threshold is slightly
 // less grounded in reality and chosen as 2.5x critical.
 const int MemoryPressureMonitor::kSmallMemoryDefaultModerateThresholdMb = 500;
 const int MemoryPressureMonitor::kSmallMemoryDefaultCriticalThresholdMb = 200;

 // These are the default thresholds used for systems with >= ~2GB of physical
 // memory. Such systems have been observed to always maintain ~300MB of
 // available memory, paging until that is the case.
 const int MemoryPressureMonitor::kLargeMemoryDefaultModerateThresholdMb = 1000;
 const int MemoryPressureMonitor::kLargeMemoryDefaultCriticalThresholdMb = 400;

 MemoryPressureMonitor::MemoryPressureMonitor()
     : moderate_threshold_mb_(0),
       critical_threshold_mb_(0),
       current_memory_pressure_level_(
           MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE),
       moderate_pressure_repeat_count_(0),
       dispatch_callback_(
           base::Bind(&MemoryPressureListener::NotifyMemoryPressure)),
       weak_ptr_factory_(this) {
   InferThresholds();
   StartObserving();
 }

 MemoryPressureMonitor::MemoryPressureMonitor(int moderate_threshold_mb,
                                              int critical_threshold_mb)
     : moderate_threshold_mb_(moderate_threshold_mb),
       critical_threshold_mb_(critical_threshold_mb),
       current_memory_pressure_level_(
           MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE),
       moderate_pressure_repeat_count_(0),
       dispatch_callback_(
           base::Bind(&MemoryPressureListener::NotifyMemoryPressure)),
       weak_ptr_factory_(this) {
   DCHECK_GE(moderate_threshold_mb_, critical_threshold_mb_);
   DCHECK_LE(0, critical_threshold_mb_);
   StartObserving();
 }

 MemoryPressureMonitor::~MemoryPressureMonitor() {
   StopObserving();
 }

 void MemoryPressureMonitor::CheckMemoryPressureSoon() {
   DCHECK(thread_checker_.CalledOnValidThread());

   ThreadTaskRunnerHandle::Get()->PostTask(
       FROM_HERE, Bind(&MemoryPressureMonitor::CheckMemoryPressure,
                       weak_ptr_factory_.GetWeakPtr()));
 }

 MemoryPressureListener::MemoryPressureLevel
 MemoryPressureMonitor::GetCurrentPressureLevel() {
   return current_memory_pressure_level_;
 }

 void MemoryPressureMonitor::InferThresholds() {
   // Default to a 'high' memory situation, which uses more conservative
   // thresholds.
   bool high_memory = true;
   MEMORYSTATUSEX mem_status = {};
   if (GetSystemMemoryStatus(&mem_status)) {
     static const DWORDLONG kLargeMemoryThresholdBytes =
         static_cast<DWORDLONG>(kLargeMemoryThresholdMb) * kMBBytes;
     high_memory = mem_status.ullTotalPhys >= kLargeMemoryThresholdBytes;
   }

   if (high_memory) {
     moderate_threshold_mb_ = kLargeMemoryDefaultModerateThresholdMb;
     critical_threshold_mb_ = kLargeMemoryDefaultCriticalThresholdMb;
   } else {
     moderate_threshold_mb_ = kSmallMemoryDefaultModerateThresholdMb;
     critical_threshold_mb_ = kSmallMemoryDefaultCriticalThresholdMb;
   }
 }

 void MemoryPressureMonitor::StartObserving() {
   DCHECK(thread_checker_.CalledOnValidThread());

   timer_.Start(FROM_HERE,
                TimeDelta::FromMilliseconds(kPollingIntervalMs),
                Bind(&MemoryPressureMonitor::
                         CheckMemoryPressureAndRecordStatistics,
                     weak_ptr_factory_.GetWeakPtr()));
 }

 void MemoryPressureMonitor::StopObserving() {
   DCHECK(thread_checker_.CalledOnValidThread());

   // If StartObserving failed, StopObserving will still get called.
   timer_.Stop();
   weak_ptr_factory_.InvalidateWeakPtrs();
 }

 void MemoryPressureMonitor::CheckMemoryPressure() {
   DCHECK(thread_checker_.CalledOnValidThread());

   // Get the previous pressure level and update the current one.
   MemoryPressureLevel old_pressure = current_memory_pressure_level_;
   current_memory_pressure_level_ = CalculateCurrentPressureLevel();

   // |notify| will be set to true if MemoryPressureListeners need to be
   // notified of a memory pressure level state change.
   bool notify = false;
   switch (current_memory_pressure_level_) {
     case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE:
       break;

     case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE:
       if (old_pressure != current_memory_pressure_level_) {
         // This is a new transition to moderate pressure so notify.
         moderate_pressure_repeat_count_ = 0;
         notify = true;
       } else {
         // Already in moderate pressure, only notify if sustained over the
         // cooldown period.
         if (++moderate_pressure_repeat_count_ ==
                 kModeratePressureCooldownCycles) {
           moderate_pressure_repeat_count_ = 0;
           notify = true;
         }
       }
       break;

     case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL:
       // Always notify of critical pressure levels.
       notify = true;
       break;
   }

   if (!notify)
     return;

   // Emit a notification of the current memory pressure level. This can only
   // happen for moderate and critical pressure levels.
   DCHECK_NE(MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE,
             current_memory_pressure_level_);
   dispatch_callback_.Run(current_memory_pressure_level_);
 }

 void MemoryPressureMonitor::CheckMemoryPressureAndRecordStatistics() {
   DCHECK(thread_checker_.CalledOnValidThread());

   CheckMemoryPressure();

   RecordMemoryPressure(current_memory_pressure_level_, 1);
 }

 MemoryPressureListener::MemoryPressureLevel
 MemoryPressureMonitor::CalculateCurrentPressureLevel() {
   MEMORYSTATUSEX mem_status = {};
   if (!GetSystemMemoryStatus(&mem_status))
     return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE;

   // How much system memory is actively available for use right now, in MBs.
   int phys_free = static_cast<int>(mem_status.ullAvailPhys / kMBBytes);

   // TODO(chrisha): This should eventually care about address space pressure,
   // but the browser process (where this is running) effectively never runs out
   // of address space. Renderers occasionally do, but it does them no good to
   // have the browser process monitor address space pressure. Long term,
   // renderers should run their own address space pressure monitors and act
   // accordingly, with the browser making cross-process decisions based on
   // system memory pressure.

   // Determine if the physical memory is under critical memory pressure.
   if (phys_free <= critical_threshold_mb_)
     return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL;

   // Determine if the physical memory is under moderate memory pressure.
   if (phys_free <= moderate_threshold_mb_)
     return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE;

   // No memory pressure was detected.
   return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE;
 }

 bool MemoryPressureMonitor::GetSystemMemoryStatus(
     MEMORYSTATUSEX* mem_status) {
   DCHECK(mem_status != nullptr);
   mem_status->dwLength = sizeof(*mem_status);
   if (!::GlobalMemoryStatusEx(mem_status))
     return false;
   return true;
 }

 void MemoryPressureMonitor::SetDispatchCallback(
     const DispatchCallback& callback) {
   dispatch_callback_ = callback;
 }

 }  // namespace win
 }  // namespace base
	// Copyright 2015 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 "base/memory/memory_pressure_monitor_win.h"

	#include <windows.h>

	#include "base/single_thread_task_runner.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "base/time/time.h"
	#include "starboard/types.h"

	namespace base {
	namespace win {

	namespace {

	static const DWORDLONG kMBBytes = 1024 * 1024;

	} // namespace

	// The following constants have been lifted from similar values in the ChromeOS
	// memory pressure monitor. The values were determined experimentally to ensure
	// sufficient responsiveness of the memory pressure subsystem, and minimal
	// overhead.
	const int MemoryPressureMonitor::kPollingIntervalMs = 5000;
	const int MemoryPressureMonitor::kModeratePressureCooldownMs = 10000;
	const int MemoryPressureMonitor::kModeratePressureCooldownCycles =
	kModeratePressureCooldownMs / kPollingIntervalMs;

	// TODO(chrisha): Explore the following constants further with an experiment.

	// A system is considered 'high memory' if it has more than 1.5GB of system
	// memory available for use by the memory manager (not reserved for hardware
	// and drivers). This is a fuzzy version of the ~2GB discussed below.
	const int MemoryPressureMonitor::kLargeMemoryThresholdMb = 1536;

	// These are the default thresholds used for systems with < ~2GB of physical
	// memory. Such systems have been observed to always maintain ~100MB of
	// available memory, paging until that is the case. To try to avoid paging a
	// threshold slightly above this is chosen. The moderate threshold is slightly
	// less grounded in reality and chosen as 2.5x critical.
	const int MemoryPressureMonitor::kSmallMemoryDefaultModerateThresholdMb = 500;
	const int MemoryPressureMonitor::kSmallMemoryDefaultCriticalThresholdMb = 200;

	// These are the default thresholds used for systems with >= ~2GB of physical
	// memory. Such systems have been observed to always maintain ~300MB of
	// available memory, paging until that is the case.
	const int MemoryPressureMonitor::kLargeMemoryDefaultModerateThresholdMb = 1000;
	const int MemoryPressureMonitor::kLargeMemoryDefaultCriticalThresholdMb = 400;

	MemoryPressureMonitor::MemoryPressureMonitor()
	: moderate_threshold_mb_(0),
	critical_threshold_mb_(0),
	current_memory_pressure_level_(
	MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE),
	moderate_pressure_repeat_count_(0),
	dispatch_callback_(
	base::Bind(&MemoryPressureListener::NotifyMemoryPressure)),
	weak_ptr_factory_(this) {
	InferThresholds();
	StartObserving();
	}

	MemoryPressureMonitor::MemoryPressureMonitor(int moderate_threshold_mb,
	int critical_threshold_mb)
	: moderate_threshold_mb_(moderate_threshold_mb),
	critical_threshold_mb_(critical_threshold_mb),
	current_memory_pressure_level_(
	MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE),
	moderate_pressure_repeat_count_(0),
	dispatch_callback_(
	base::Bind(&MemoryPressureListener::NotifyMemoryPressure)),
	weak_ptr_factory_(this) {
	DCHECK_GE(moderate_threshold_mb_, critical_threshold_mb_);
	DCHECK_LE(0, critical_threshold_mb_);
	StartObserving();
	}

	MemoryPressureMonitor::~MemoryPressureMonitor() {
	StopObserving();
	}

	void MemoryPressureMonitor::CheckMemoryPressureSoon() {
	DCHECK(thread_checker_.CalledOnValidThread());

	ThreadTaskRunnerHandle::Get()->PostTask(
	FROM_HERE, Bind(&MemoryPressureMonitor::CheckMemoryPressure,
	weak_ptr_factory_.GetWeakPtr()));
	}

	MemoryPressureListener::MemoryPressureLevel
	MemoryPressureMonitor::GetCurrentPressureLevel() {
	return current_memory_pressure_level_;
	}

	void MemoryPressureMonitor::InferThresholds() {
	// Default to a 'high' memory situation, which uses more conservative
	// thresholds.
	bool high_memory = true;
	MEMORYSTATUSEX mem_status = {};
	if (GetSystemMemoryStatus(&mem_status)) {
	static const DWORDLONG kLargeMemoryThresholdBytes =
	static_cast<DWORDLONG>(kLargeMemoryThresholdMb) * kMBBytes;
	high_memory = mem_status.ullTotalPhys >= kLargeMemoryThresholdBytes;
	}

	if (high_memory) {
	moderate_threshold_mb_ = kLargeMemoryDefaultModerateThresholdMb;
	critical_threshold_mb_ = kLargeMemoryDefaultCriticalThresholdMb;
	} else {
	moderate_threshold_mb_ = kSmallMemoryDefaultModerateThresholdMb;
	critical_threshold_mb_ = kSmallMemoryDefaultCriticalThresholdMb;
	}
	}

	void MemoryPressureMonitor::StartObserving() {
	DCHECK(thread_checker_.CalledOnValidThread());

	timer_.Start(FROM_HERE,
	TimeDelta::FromMilliseconds(kPollingIntervalMs),
	Bind(&MemoryPressureMonitor::
	CheckMemoryPressureAndRecordStatistics,
	weak_ptr_factory_.GetWeakPtr()));
	}

	void MemoryPressureMonitor::StopObserving() {
	DCHECK(thread_checker_.CalledOnValidThread());

	// If StartObserving failed, StopObserving will still get called.
	timer_.Stop();
	weak_ptr_factory_.InvalidateWeakPtrs();
	}

	void MemoryPressureMonitor::CheckMemoryPressure() {
	DCHECK(thread_checker_.CalledOnValidThread());

	// Get the previous pressure level and update the current one.
	MemoryPressureLevel old_pressure = current_memory_pressure_level_;
	current_memory_pressure_level_ = CalculateCurrentPressureLevel();

	// \|notify\| will be set to true if MemoryPressureListeners need to be
	// notified of a memory pressure level state change.
	bool notify = false;
	switch (current_memory_pressure_level_) {
	case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE:
	break;

	case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE:
	if (old_pressure != current_memory_pressure_level_) {
	// This is a new transition to moderate pressure so notify.
	moderate_pressure_repeat_count_ = 0;
	notify = true;
	} else {
	// Already in moderate pressure, only notify if sustained over the
	// cooldown period.
	if (++moderate_pressure_repeat_count_ ==
	kModeratePressureCooldownCycles) {
	moderate_pressure_repeat_count_ = 0;
	notify = true;
	}
	}
	break;

	case MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL:
	// Always notify of critical pressure levels.
	notify = true;
	break;
	}

	if (!notify)
	return;

	// Emit a notification of the current memory pressure level. This can only
	// happen for moderate and critical pressure levels.
	DCHECK_NE(MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE,
	current_memory_pressure_level_);
	dispatch_callback_.Run(current_memory_pressure_level_);
	}

	void MemoryPressureMonitor::CheckMemoryPressureAndRecordStatistics() {
	DCHECK(thread_checker_.CalledOnValidThread());

	CheckMemoryPressure();

	RecordMemoryPressure(current_memory_pressure_level_, 1);
	}

	MemoryPressureListener::MemoryPressureLevel
	MemoryPressureMonitor::CalculateCurrentPressureLevel() {
	MEMORYSTATUSEX mem_status = {};
	if (!GetSystemMemoryStatus(&mem_status))
	return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE;

	// How much system memory is actively available for use right now, in MBs.
	int phys_free = static_cast<int>(mem_status.ullAvailPhys / kMBBytes);

	// TODO(chrisha): This should eventually care about address space pressure,
	// but the browser process (where this is running) effectively never runs out
	// of address space. Renderers occasionally do, but it does them no good to
	// have the browser process monitor address space pressure. Long term,
	// renderers should run their own address space pressure monitors and act
	// accordingly, with the browser making cross-process decisions based on
	// system memory pressure.

	// Determine if the physical memory is under critical memory pressure.
	if (phys_free <= critical_threshold_mb_)
	return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL;

	// Determine if the physical memory is under moderate memory pressure.
	if (phys_free <= moderate_threshold_mb_)
	return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE;

	// No memory pressure was detected.
	return MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE;
	}

	bool MemoryPressureMonitor::GetSystemMemoryStatus(
	MEMORYSTATUSEX* mem_status) {
	DCHECK(mem_status != nullptr);
	mem_status->dwLength = sizeof(*mem_status);
	if (!::GlobalMemoryStatusEx(mem_status))
	return false;
	return true;
	}

	void MemoryPressureMonitor::SetDispatchCallback(
	const DispatchCallback& callback) {
	dispatch_callback_ = callback;
	}

	} // namespace win
	} // namespace base