src/net/disk_cache/memory/mem_backend_impl.cc - cobalt - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/disk_cache/memory/mem_backend_impl.h"

 #include <algorithm>
 #include <functional>
 #include <memory>
 #include <utility>

 #include "base/logging.h"
 #include "base/sys_info.h"
 #include "base/task/post_task.h"
 #include "base/threading/sequenced_task_runner_handle.h"
 #include "base/trace_event/memory_usage_estimator.h"
 #include "base/trace_event/process_memory_dump.h"
 #include "net/base/net_errors.h"
 #include "net/disk_cache/cache_util.h"
 #include "net/disk_cache/memory/mem_entry_impl.h"

 using base::Time;

 namespace disk_cache {

 namespace {

 const int kDefaultInMemoryCacheSize = 10 * 1024 * 1024;
 const int kDefaultEvictionSize = kDefaultInMemoryCacheSize / 10;

 bool CheckLRUListOrder(const base::LinkedList<MemEntryImpl>& lru_list) {
   // TODO(gavinp): Check MemBackendImpl::current_size_ here as well.
   base::Time previous_last_use_time;
   for (base::LinkNode<MemEntryImpl>* node = lru_list.head();
        node != lru_list.end(); node = node->next()) {
     if (node->value()->GetLastUsed() < previous_last_use_time)
       return false;
     previous_last_use_time = node->value()->GetLastUsed();
   }
   return true;
 }

 // Returns the next entry after |node| in |lru_list| that's not a child
 // of |node|.  This is useful when dooming, since dooming a parent entry
 // will also doom its children.
 base::LinkNode<MemEntryImpl>* NextSkippingChildren(
     const base::LinkedList<MemEntryImpl>& lru_list,
     base::LinkNode<MemEntryImpl>* node) {
   MemEntryImpl* cur = node->value();
   do {
     node = node->next();
   } while (node != lru_list.end() && node->value()->parent() == cur);
   return node;
 }

 }  // namespace

 MemBackendImpl::MemBackendImpl(net::NetLog* net_log)
     : max_size_(0),
       current_size_(0),
       net_log_(net_log),
       memory_pressure_listener_(
           base::BindRepeating(&MemBackendImpl::OnMemoryPressure,
                               base::Unretained(this))),
       weak_factory_(this) {}

 MemBackendImpl::~MemBackendImpl() {
   DCHECK(CheckLRUListOrder(lru_list_));
   while (!entries_.empty())
     entries_.begin()->second->Doom();

   if (!post_cleanup_callback_.is_null())
     base::SequencedTaskRunnerHandle::Get()->PostTask(
         FROM_HERE, std::move(post_cleanup_callback_));
 }

 // static
 std::unique_ptr<MemBackendImpl> MemBackendImpl::CreateBackend(
     int64_t max_bytes,
     net::NetLog* net_log) {
   std::unique_ptr<MemBackendImpl> cache(
       std::make_unique<MemBackendImpl>(net_log));
   if (cache->SetMaxSize(max_bytes) && cache->Init())
     return cache;

   LOG(ERROR) << "Unable to create cache";
   return nullptr;
 }

 bool MemBackendImpl::Init() {
   if (max_size_)
     return true;

   int64_t total_memory = base::SysInfo::AmountOfPhysicalMemory();

   if (total_memory <= 0) {
     max_size_ = kDefaultInMemoryCacheSize;
     return true;
   }

   // We want to use up to 2% of the computer's memory, with a limit of 50 MB,
   // reached on system with more than 2.5 GB of RAM.
   total_memory = total_memory * 2 / 100;
   if (total_memory > kDefaultInMemoryCacheSize * 5)
     max_size_ = kDefaultInMemoryCacheSize * 5;
   else
     max_size_ = static_cast<int32_t>(total_memory);

   return true;
 }

 bool MemBackendImpl::SetMaxSize(int64_t max_bytes) {
   if (max_bytes < 0 || max_bytes > std::numeric_limits<int>::max())
     return false;

   // Zero size means use the default.
   if (!max_bytes)
     return true;

   max_size_ = max_bytes;
   return true;
 }

 int MemBackendImpl::MaxFileSize() const {
   return max_size_ / 8;
 }

 void MemBackendImpl::OnEntryInserted(MemEntryImpl* entry) {
   lru_list_.Append(entry);
 }

 void MemBackendImpl::OnEntryUpdated(MemEntryImpl* entry) {
   DCHECK(CheckLRUListOrder(lru_list_));
   // LinkedList<>::RemoveFromList() removes |entry| from |lru_list_|.
   entry->RemoveFromList();
   lru_list_.Append(entry);
 }

 void MemBackendImpl::OnEntryDoomed(MemEntryImpl* entry) {
   DCHECK(CheckLRUListOrder(lru_list_));
   if (entry->type() == MemEntryImpl::PARENT_ENTRY)
     entries_.erase(entry->key());
   // LinkedList<>::RemoveFromList() removes |entry| from |lru_list_|.
   entry->RemoveFromList();
 }

 void MemBackendImpl::ModifyStorageSize(int32_t delta) {
   current_size_ += delta;
   if (delta > 0)
     EvictIfNeeded();
 }

 bool MemBackendImpl::HasExceededStorageSize() const {
   return current_size_ > max_size_;
 }

 void MemBackendImpl::SetPostCleanupCallback(base::OnceClosure cb) {
   DCHECK(post_cleanup_callback_.is_null());
   post_cleanup_callback_ = std::move(cb);
 }

 net::CacheType MemBackendImpl::GetCacheType() const {
   return net::MEMORY_CACHE;
 }

 int32_t MemBackendImpl::GetEntryCount() const {
   return static_cast<int32_t>(entries_.size());
 }

 net::Error MemBackendImpl::OpenEntry(const std::string& key,
                                      net::RequestPriority request_priority,
                                      Entry** entry,
                                      CompletionOnceCallback callback) {
   auto it = entries_.find(key);
   if (it == entries_.end())
     return net::ERR_FAILED;

   it->second->Open();

   *entry = it->second;
   return net::OK;
 }

 net::Error MemBackendImpl::CreateEntry(const std::string& key,
                                        net::RequestPriority request_priority,
                                        Entry** entry,
                                        CompletionOnceCallback callback) {
   std::pair<EntryMap::iterator, bool> create_result =
       entries_.insert(EntryMap::value_type(key, nullptr));
   const bool did_insert = create_result.second;
   if (!did_insert)
     return net::ERR_FAILED;

   MemEntryImpl* cache_entry =
       new MemEntryImpl(weak_factory_.GetWeakPtr(), key, net_log_);
   create_result.first->second = cache_entry;
   *entry = cache_entry;
   return net::OK;
 }

 net::Error MemBackendImpl::DoomEntry(const std::string& key,
                                      net::RequestPriority priority,
                                      CompletionOnceCallback callback) {
   auto it = entries_.find(key);
   if (it == entries_.end())
     return net::ERR_FAILED;

   it->second->Doom();
   return net::OK;
 }

 net::Error MemBackendImpl::DoomAllEntries(CompletionOnceCallback callback) {
   return DoomEntriesBetween(Time(), Time(), std::move(callback));
 }

 net::Error MemBackendImpl::DoomEntriesBetween(Time initial_time,
                                               Time end_time,
                                               CompletionOnceCallback callback) {
   if (end_time.is_null())
     end_time = Time::Max();
   DCHECK_GE(end_time, initial_time);

   base::LinkNode<MemEntryImpl>* node = lru_list_.head();
   while (node != lru_list_.end() && node->value()->GetLastUsed() < initial_time)
     node = node->next();
   while (node != lru_list_.end() && node->value()->GetLastUsed() < end_time) {
     MemEntryImpl* to_doom = node->value();
     node = NextSkippingChildren(lru_list_, node);
     to_doom->Doom();
   }

   return net::OK;
 }

 net::Error MemBackendImpl::DoomEntriesSince(Time initial_time,
                                             CompletionOnceCallback callback) {
   return DoomEntriesBetween(initial_time, Time::Max(), std::move(callback));
 }

 int64_t MemBackendImpl::CalculateSizeOfAllEntries(
     Int64CompletionOnceCallback callback) {
   return current_size_;
 }

 int64_t MemBackendImpl::CalculateSizeOfEntriesBetween(
     base::Time initial_time,
     base::Time end_time,
     Int64CompletionOnceCallback callback) {
   if (end_time.is_null())
     end_time = Time::Max();
   DCHECK_GE(end_time, initial_time);

   int size = 0;
   base::LinkNode<MemEntryImpl>* node = lru_list_.head();
   while (node != lru_list_.end() && node->value()->GetLastUsed() < initial_time)
     node = node->next();
   while (node != lru_list_.end() && node->value()->GetLastUsed() < end_time) {
     MemEntryImpl* entry = node->value();
     size += entry->GetStorageSize();
     node = node->next();
   }
   return size;
 }

 class MemBackendImpl::MemIterator final : public Backend::Iterator {
  public:
   explicit MemIterator(base::WeakPtr<MemBackendImpl> backend)
       : backend_(backend) {}

   net::Error OpenNextEntry(Entry** next_entry,
                            CompletionOnceCallback callback) override {
     if (!backend_)
       return net::ERR_FAILED;

     if (!backend_keys_) {
       backend_keys_ = std::make_unique<Strings>(backend_->entries_.size());
       for (const auto& iter : backend_->entries_)
         backend_keys_->push_back(iter.first);
       current_ = backend_keys_->begin();
     } else {
       current_++;
     }

     while (true) {
       if (current_ == backend_keys_->end()) {
         *next_entry = nullptr;
         backend_keys_.reset();
         return net::ERR_FAILED;
       }

       const auto& entry_iter = backend_->entries_.find(*current_);
       if (entry_iter == backend_->entries_.end()) {
         // The key is no longer in the cache, move on to the next key.
         current_++;
         continue;
       }

       entry_iter->second->Open();
       *next_entry = entry_iter->second;
       return net::OK;
     }
   }

  private:
   using Strings = std::vector<std::string>;

   base::WeakPtr<MemBackendImpl> backend_;
   std::unique_ptr<Strings> backend_keys_;
   Strings::iterator current_;
 };

 std::unique_ptr<Backend::Iterator> MemBackendImpl::CreateIterator() {
   return std::unique_ptr<Backend::Iterator>(
       new MemIterator(weak_factory_.GetWeakPtr()));
 }

 void MemBackendImpl::OnExternalCacheHit(const std::string& key) {
   auto it = entries_.find(key);
   if (it != entries_.end())
     it->second->UpdateStateOnUse(MemEntryImpl::ENTRY_WAS_NOT_MODIFIED);
 }

 size_t MemBackendImpl::DumpMemoryStats(
     base::trace_event::ProcessMemoryDump* pmd,
     const std::string& parent_absolute_name) const {
   base::trace_event::MemoryAllocatorDump* dump =
       pmd->CreateAllocatorDump(parent_absolute_name + "/memory_backend");

   // Entries in lru_list_ will be counted by EMU but not in entries_ since
   // they're pointers.
   size_t size = base::trace_event::EstimateMemoryUsage(lru_list_) +
                 base::trace_event::EstimateMemoryUsage(entries_);
   dump->AddScalar(base::trace_event::MemoryAllocatorDump::kNameSize,
                   base::trace_event::MemoryAllocatorDump::kUnitsBytes, size);
   dump->AddScalar("mem_backend_size",
                   base::trace_event::MemoryAllocatorDump::kUnitsBytes,
                   current_size_);
   dump->AddScalar("mem_backend_max_size",
                   base::trace_event::MemoryAllocatorDump::kUnitsBytes,
                   max_size_);
   return size;
 }

 void MemBackendImpl::EvictIfNeeded() {
   if (current_size_ <= max_size_)
     return;
   int target_size = std::max(0, max_size_ - kDefaultEvictionSize);
   EvictTill(target_size);
 }

 void MemBackendImpl::EvictTill(int target_size) {
   base::LinkNode<MemEntryImpl>* entry = lru_list_.head();
   while (current_size_ > target_size && entry != lru_list_.end()) {
     MemEntryImpl* to_doom = entry->value();
     entry = NextSkippingChildren(lru_list_, entry);

     if (!to_doom->InUse())
       to_doom->Doom();
   }
 }

 void MemBackendImpl::OnMemoryPressure(
     base::MemoryPressureListener::MemoryPressureLevel memory_pressure_level) {
   switch (memory_pressure_level) {
     case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE:
       // Not supposed to get this here, but if there is no problem, there is
       // no problem...
       break;
     case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE:
       EvictTill(max_size_ / 2);
       break;
     case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL:
       EvictTill(max_size_ / 10);
       break;
   }
 }

 }  // namespace disk_cache
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/disk_cache/memory/mem_backend_impl.h"

	#include <algorithm>
	#include <functional>
	#include <memory>
	#include <utility>

	#include "base/logging.h"
	#include "base/sys_info.h"
	#include "base/task/post_task.h"
	#include "base/threading/sequenced_task_runner_handle.h"
	#include "base/trace_event/memory_usage_estimator.h"
	#include "base/trace_event/process_memory_dump.h"
	#include "net/base/net_errors.h"
	#include "net/disk_cache/cache_util.h"
	#include "net/disk_cache/memory/mem_entry_impl.h"

	using base::Time;

	namespace disk_cache {

	namespace {

	const int kDefaultInMemoryCacheSize = 10 * 1024 * 1024;
	const int kDefaultEvictionSize = kDefaultInMemoryCacheSize / 10;

	bool CheckLRUListOrder(const base::LinkedList<MemEntryImpl>& lru_list) {
	// TODO(gavinp): Check MemBackendImpl::current_size_ here as well.
	base::Time previous_last_use_time;
	for (base::LinkNode<MemEntryImpl>* node = lru_list.head();
	node != lru_list.end(); node = node->next()) {
	if (node->value()->GetLastUsed() < previous_last_use_time)
	return false;
	previous_last_use_time = node->value()->GetLastUsed();
	}
	return true;
	}

	// Returns the next entry after \|node\| in \|lru_list\| that's not a child
	// of \|node\|. This is useful when dooming, since dooming a parent entry
	// will also doom its children.
	base::LinkNode<MemEntryImpl>* NextSkippingChildren(
	const base::LinkedList<MemEntryImpl>& lru_list,
	base::LinkNode<MemEntryImpl>* node) {
	MemEntryImpl* cur = node->value();
	do {
	node = node->next();
	} while (node != lru_list.end() && node->value()->parent() == cur);
	return node;
	}

	} // namespace

	MemBackendImpl::MemBackendImpl(net::NetLog* net_log)
	: max_size_(0),
	current_size_(0),
	net_log_(net_log),
	memory_pressure_listener_(
	base::BindRepeating(&MemBackendImpl::OnMemoryPressure,
	base::Unretained(this))),
	weak_factory_(this) {}

	MemBackendImpl::~MemBackendImpl() {
	DCHECK(CheckLRUListOrder(lru_list_));
	while (!entries_.empty())
	entries_.begin()->second->Doom();

	if (!post_cleanup_callback_.is_null())
	base::SequencedTaskRunnerHandle::Get()->PostTask(
	FROM_HERE, std::move(post_cleanup_callback_));
	}

	// static
	std::unique_ptr<MemBackendImpl> MemBackendImpl::CreateBackend(
	int64_t max_bytes,
	net::NetLog* net_log) {
	std::unique_ptr<MemBackendImpl> cache(
	std::make_unique<MemBackendImpl>(net_log));
	if (cache->SetMaxSize(max_bytes) && cache->Init())
	return cache;

	LOG(ERROR) << "Unable to create cache";
	return nullptr;
	}

	bool MemBackendImpl::Init() {
	if (max_size_)
	return true;

	int64_t total_memory = base::SysInfo::AmountOfPhysicalMemory();

	if (total_memory <= 0) {
	max_size_ = kDefaultInMemoryCacheSize;
	return true;
	}

	// We want to use up to 2% of the computer's memory, with a limit of 50 MB,
	// reached on system with more than 2.5 GB of RAM.
	total_memory = total_memory * 2 / 100;
	if (total_memory > kDefaultInMemoryCacheSize * 5)
	max_size_ = kDefaultInMemoryCacheSize * 5;
	else
	max_size_ = static_cast<int32_t>(total_memory);

	return true;
	}

	bool MemBackendImpl::SetMaxSize(int64_t max_bytes) {
	if (max_bytes < 0 \|\| max_bytes > std::numeric_limits<int>::max())
	return false;

	// Zero size means use the default.
	if (!max_bytes)
	return true;

	max_size_ = max_bytes;
	return true;
	}

	int MemBackendImpl::MaxFileSize() const {
	return max_size_ / 8;
	}

	void MemBackendImpl::OnEntryInserted(MemEntryImpl* entry) {
	lru_list_.Append(entry);
	}

	void MemBackendImpl::OnEntryUpdated(MemEntryImpl* entry) {
	DCHECK(CheckLRUListOrder(lru_list_));
	// LinkedList<>::RemoveFromList() removes \|entry\| from \|lru_list_\|.
	entry->RemoveFromList();
	lru_list_.Append(entry);
	}

	void MemBackendImpl::OnEntryDoomed(MemEntryImpl* entry) {
	DCHECK(CheckLRUListOrder(lru_list_));
	if (entry->type() == MemEntryImpl::PARENT_ENTRY)
	entries_.erase(entry->key());
	// LinkedList<>::RemoveFromList() removes \|entry\| from \|lru_list_\|.
	entry->RemoveFromList();
	}

	void MemBackendImpl::ModifyStorageSize(int32_t delta) {
	current_size_ += delta;
	if (delta > 0)
	EvictIfNeeded();
	}

	bool MemBackendImpl::HasExceededStorageSize() const {
	return current_size_ > max_size_;
	}

	void MemBackendImpl::SetPostCleanupCallback(base::OnceClosure cb) {
	DCHECK(post_cleanup_callback_.is_null());
	post_cleanup_callback_ = std::move(cb);
	}

	net::CacheType MemBackendImpl::GetCacheType() const {
	return net::MEMORY_CACHE;
	}

	int32_t MemBackendImpl::GetEntryCount() const {
	return static_cast<int32_t>(entries_.size());
	}

	net::Error MemBackendImpl::OpenEntry(const std::string& key,
	net::RequestPriority request_priority,
	Entry** entry,
	CompletionOnceCallback callback) {
	auto it = entries_.find(key);
	if (it == entries_.end())
	return net::ERR_FAILED;

	it->second->Open();

	*entry = it->second;
	return net::OK;
	}

	net::Error MemBackendImpl::CreateEntry(const std::string& key,
	net::RequestPriority request_priority,
	Entry** entry,
	CompletionOnceCallback callback) {
	std::pair<EntryMap::iterator, bool> create_result =
	entries_.insert(EntryMap::value_type(key, nullptr));
	const bool did_insert = create_result.second;
	if (!did_insert)
	return net::ERR_FAILED;

	MemEntryImpl* cache_entry =
	new MemEntryImpl(weak_factory_.GetWeakPtr(), key, net_log_);
	create_result.first->second = cache_entry;
	*entry = cache_entry;
	return net::OK;
	}

	net::Error MemBackendImpl::DoomEntry(const std::string& key,
	net::RequestPriority priority,
	CompletionOnceCallback callback) {
	auto it = entries_.find(key);
	if (it == entries_.end())
	return net::ERR_FAILED;

	it->second->Doom();
	return net::OK;
	}

	net::Error MemBackendImpl::DoomAllEntries(CompletionOnceCallback callback) {
	return DoomEntriesBetween(Time(), Time(), std::move(callback));
	}

	net::Error MemBackendImpl::DoomEntriesBetween(Time initial_time,
	Time end_time,
	CompletionOnceCallback callback) {
	if (end_time.is_null())
	end_time = Time::Max();
	DCHECK_GE(end_time, initial_time);

	base::LinkNode<MemEntryImpl>* node = lru_list_.head();
	while (node != lru_list_.end() && node->value()->GetLastUsed() < initial_time)
	node = node->next();
	while (node != lru_list_.end() && node->value()->GetLastUsed() < end_time) {
	MemEntryImpl* to_doom = node->value();
	node = NextSkippingChildren(lru_list_, node);
	to_doom->Doom();
	}

	return net::OK;
	}

	net::Error MemBackendImpl::DoomEntriesSince(Time initial_time,
	CompletionOnceCallback callback) {
	return DoomEntriesBetween(initial_time, Time::Max(), std::move(callback));
	}

	int64_t MemBackendImpl::CalculateSizeOfAllEntries(
	Int64CompletionOnceCallback callback) {
	return current_size_;
	}

	int64_t MemBackendImpl::CalculateSizeOfEntriesBetween(
	base::Time initial_time,
	base::Time end_time,
	Int64CompletionOnceCallback callback) {
	if (end_time.is_null())
	end_time = Time::Max();
	DCHECK_GE(end_time, initial_time);

	int size = 0;
	base::LinkNode<MemEntryImpl>* node = lru_list_.head();
	while (node != lru_list_.end() && node->value()->GetLastUsed() < initial_time)
	node = node->next();
	while (node != lru_list_.end() && node->value()->GetLastUsed() < end_time) {
	MemEntryImpl* entry = node->value();
	size += entry->GetStorageSize();
	node = node->next();
	}
	return size;
	}

	class MemBackendImpl::MemIterator final : public Backend::Iterator {
	public:
	explicit MemIterator(base::WeakPtr<MemBackendImpl> backend)
	: backend_(backend) {}

	net::Error OpenNextEntry(Entry** next_entry,
	CompletionOnceCallback callback) override {
	if (!backend_)
	return net::ERR_FAILED;

	if (!backend_keys_) {
	backend_keys_ = std::make_unique<Strings>(backend_->entries_.size());
	for (const auto& iter : backend_->entries_)
	backend_keys_->push_back(iter.first);
	current_ = backend_keys_->begin();
	} else {
	current_++;
	}

	while (true) {
	if (current_ == backend_keys_->end()) {
	*next_entry = nullptr;
	backend_keys_.reset();
	return net::ERR_FAILED;
	}

	const auto& entry_iter = backend_->entries_.find(*current_);
	if (entry_iter == backend_->entries_.end()) {
	// The key is no longer in the cache, move on to the next key.
	current_++;
	continue;
	}

	entry_iter->second->Open();
	*next_entry = entry_iter->second;
	return net::OK;
	}
	}

	private:
	using Strings = std::vector<std::string>;

	base::WeakPtr<MemBackendImpl> backend_;
	std::unique_ptr<Strings> backend_keys_;
	Strings::iterator current_;
	};

	std::unique_ptr<Backend::Iterator> MemBackendImpl::CreateIterator() {
	return std::unique_ptr<Backend::Iterator>(
	new MemIterator(weak_factory_.GetWeakPtr()));
	}

	void MemBackendImpl::OnExternalCacheHit(const std::string& key) {
	auto it = entries_.find(key);
	if (it != entries_.end())
	it->second->UpdateStateOnUse(MemEntryImpl::ENTRY_WAS_NOT_MODIFIED);
	}

	size_t MemBackendImpl::DumpMemoryStats(
	base::trace_event::ProcessMemoryDump* pmd,
	const std::string& parent_absolute_name) const {
	base::trace_event::MemoryAllocatorDump* dump =
	pmd->CreateAllocatorDump(parent_absolute_name + "/memory_backend");

	// Entries in lru_list_ will be counted by EMU but not in entries_ since
	// they're pointers.
	size_t size = base::trace_event::EstimateMemoryUsage(lru_list_) +
	base::trace_event::EstimateMemoryUsage(entries_);
	dump->AddScalar(base::trace_event::MemoryAllocatorDump::kNameSize,
	base::trace_event::MemoryAllocatorDump::kUnitsBytes, size);
	dump->AddScalar("mem_backend_size",
	base::trace_event::MemoryAllocatorDump::kUnitsBytes,
	current_size_);
	dump->AddScalar("mem_backend_max_size",
	base::trace_event::MemoryAllocatorDump::kUnitsBytes,
	max_size_);
	return size;
	}

	void MemBackendImpl::EvictIfNeeded() {
	if (current_size_ <= max_size_)
	return;
	int target_size = std::max(0, max_size_ - kDefaultEvictionSize);
	EvictTill(target_size);
	}

	void MemBackendImpl::EvictTill(int target_size) {
	base::LinkNode<MemEntryImpl>* entry = lru_list_.head();
	while (current_size_ > target_size && entry != lru_list_.end()) {
	MemEntryImpl* to_doom = entry->value();
	entry = NextSkippingChildren(lru_list_, entry);

	if (!to_doom->InUse())
	to_doom->Doom();
	}
	}

	void MemBackendImpl::OnMemoryPressure(
	base::MemoryPressureListener::MemoryPressureLevel memory_pressure_level) {
	switch (memory_pressure_level) {
	case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_NONE:
	// Not supposed to get this here, but if there is no problem, there is
	// no problem...
	break;
	case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_MODERATE:
	EvictTill(max_size_ / 2);
	break;
	case base::MemoryPressureListener::MEMORY_PRESSURE_LEVEL_CRITICAL:
	EvictTill(max_size_ / 10);
	break;
	}
	}

	} // namespace disk_cache