net/disk_cache/mem_entry_impl.cc - chromium/src - Git at Google

 // Copyright (c) 2011 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/mem_entry_impl.h"

 #include "base/logging.h"
 #include "base/stringprintf.h"
 #include "net/base/io_buffer.h"
 #include "net/base/net_errors.h"
 #include "net/disk_cache/mem_backend_impl.h"
 #include "net/disk_cache/net_log_parameters.h"

 using base::Time;

 namespace {

 const int kSparseData = 1;

 // Maximum size of a sparse entry is 2 to the power of this number.
 const int kMaxSparseEntryBits = 12;

 // Sparse entry has maximum size of 4KB.
 const int kMaxSparseEntrySize = 1 << kMaxSparseEntryBits;

 // Convert global offset to child index.
 inline int ToChildIndex(int64 offset) {
   return static_cast<int>(offset >> kMaxSparseEntryBits);
 }

 // Convert global offset to offset in child entry.
 inline int ToChildOffset(int64 offset) {
   return static_cast<int>(offset & (kMaxSparseEntrySize - 1));
 }

 // Returns a name for a child entry given the base_name of the parent and the
 // child_id.  This name is only used for logging purposes.
 // If the entry is called entry_name, child entries will be named something
 // like Range_entry_name:YYY where YYY is the number of the particular child.
 std::string GenerateChildName(const std::string& base_name, int child_id) {
   return base::StringPrintf("Range_%s:%i", base_name.c_str(), child_id);
 }

 }  // namespace

 namespace disk_cache {

 MemEntryImpl::MemEntryImpl(MemBackendImpl* backend) {
   doomed_ = false;
   backend_ = backend;
   ref_count_ = 0;
   parent_ = NULL;
   child_id_ = 0;
   child_first_pos_ = 0;
   next_ = NULL;
   prev_ = NULL;
   for (int i = 0; i < NUM_STREAMS; i++)
     data_size_[i] = 0;
 }

 // ------------------------------------------------------------------------

 bool MemEntryImpl::CreateEntry(const std::string& key, net::NetLog* net_log) {
   net_log_ = net::BoundNetLog::Make(net_log,
                                     net::NetLog::SOURCE_MEMORY_CACHE_ENTRY);
   net_log_.BeginEvent(
       net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL,
       make_scoped_refptr(new EntryCreationParameters(key, true)));
   key_ = key;
   Time current = Time::Now();
   last_modified_ = current;
   last_used_ = current;
   Open();
   backend_->ModifyStorageSize(0, static_cast<int32>(key.size()));
   return true;
 }

 void MemEntryImpl::InternalDoom() {
   net_log_.AddEvent(net::NetLog::TYPE_ENTRY_DOOM, NULL);
   doomed_ = true;
   if (!ref_count_) {
     if (type() == kParentEntry) {
       // If this is a parent entry, we need to doom all the child entries.
       if (children_.get()) {
         EntryMap children;
         children.swap(*children_);
         for (EntryMap::iterator i = children.begin();
              i != children.end(); ++i) {
           // Since a pointer to this object is also saved in the map, avoid
           // dooming it.
           if (i->second != this)
             i->second->Doom();
         }
         DCHECK(children_->empty());
       }
     } else {
       // If this is a child entry, detach it from the parent.
       parent_->DetachChild(child_id_);
     }
     delete this;
   }
 }

 void MemEntryImpl::Open() {
   // Only a parent entry can be opened.
   // TODO(hclam): make sure it's correct to not apply the concept of ref
   // counting to child entry.
   DCHECK(type() == kParentEntry);
   ref_count_++;
   DCHECK_GE(ref_count_, 0);
   DCHECK(!doomed_);
 }

 bool MemEntryImpl::InUse() {
   if (type() == kParentEntry) {
     return ref_count_ > 0;
   } else {
     // A child entry is always not in use. The consequence is that a child entry
     // can always be evicted while the associated parent entry is currently in
     // used (i.e. opened).
     return false;
   }
 }

 // ------------------------------------------------------------------------

 void MemEntryImpl::Doom() {
   if (doomed_)
     return;
   if (type() == kParentEntry) {
     // Perform internal doom from the backend if this is a parent entry.
     backend_->InternalDoomEntry(this);
   } else {
     // Manually detach from the backend and perform internal doom.
     backend_->RemoveFromRankingList(this);
     InternalDoom();
   }
 }

 void MemEntryImpl::Close() {
   // Only a parent entry can be closed.
   DCHECK(type() == kParentEntry);
   ref_count_--;
   DCHECK_GE(ref_count_, 0);
   if (!ref_count_ && doomed_)
     InternalDoom();
 }

 std::string MemEntryImpl::GetKey() const {
   // A child entry doesn't have key so this method should not be called.
   DCHECK(type() == kParentEntry);
   return key_;
 }

 Time MemEntryImpl::GetLastUsed() const {
   return last_used_;
 }

 Time MemEntryImpl::GetLastModified() const {
   return last_modified_;
 }

 int32 MemEntryImpl::GetDataSize(int index) const {
   if (index < 0 || index >= NUM_STREAMS)
     return 0;
   return data_size_[index];
 }

 int MemEntryImpl::ReadData(int index, int offset, net::IOBuffer* buf,
     int buf_len, net::CompletionCallback* completion_callback) {
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.BeginEvent(
         net::NetLog::TYPE_ENTRY_READ_DATA,
         make_scoped_refptr(
             new ReadWriteDataParameters(index, offset, buf_len, false)));
   }

   int result = InternalReadData(index, offset, buf, buf_len);

   if (net_log_.IsLoggingAllEvents()) {
     net_log_.EndEvent(
         net::NetLog::TYPE_ENTRY_READ_DATA,
         make_scoped_refptr(new ReadWriteCompleteParameters(result)));
   }
   return result;
 }

 int MemEntryImpl::WriteData(int index, int offset, net::IOBuffer* buf,
     int buf_len, net::CompletionCallback* completion_callback, bool truncate) {
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.BeginEvent(
         net::NetLog::TYPE_ENTRY_WRITE_DATA,
         make_scoped_refptr(
             new ReadWriteDataParameters(index, offset, buf_len, truncate)));
   }

   int result = InternalWriteData(index, offset, buf, buf_len, truncate);

   if (net_log_.IsLoggingAllEvents()) {
     net_log_.EndEvent(
         net::NetLog::TYPE_ENTRY_WRITE_DATA,
         make_scoped_refptr(new ReadWriteCompleteParameters(result)));
   }
   return result;
 }

 int MemEntryImpl::ReadSparseData(int64 offset, net::IOBuffer* buf, int buf_len,
                                  net::CompletionCallback* completion_callback) {
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.BeginEvent(
         net::NetLog::TYPE_SPARSE_READ,
         make_scoped_refptr(
             new SparseOperationParameters(offset, buf_len)));
   }
   int result = InternalReadSparseData(offset, buf, buf_len);
   if (net_log_.IsLoggingAllEvents())
     net_log_.EndEvent(net::NetLog::TYPE_SPARSE_READ, NULL);
   return result;
 }

 int MemEntryImpl::WriteSparseData(int64 offset, net::IOBuffer* buf, int buf_len,
     net::CompletionCallback* completion_callback) {
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.BeginEvent(net::NetLog::TYPE_SPARSE_WRITE,
         make_scoped_refptr(
             new SparseOperationParameters(offset, buf_len)));
   }
   int result = InternalWriteSparseData(offset, buf, buf_len);
   if (net_log_.IsLoggingAllEvents())
     net_log_.EndEvent(net::NetLog::TYPE_SPARSE_WRITE, NULL);
   return result;
 }

 int MemEntryImpl::GetAvailableRange(int64 offset, int len, int64* start,
                                     CompletionCallback* callback) {
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.BeginEvent(
         net::NetLog::TYPE_SPARSE_GET_RANGE,
         make_scoped_refptr(
             new SparseOperationParameters(offset, len)));
   }
   int result = GetAvailableRange(offset, len, start);
   if (net_log_.IsLoggingAllEvents()) {
     net_log_.EndEvent(
         net::NetLog::TYPE_SPARSE_GET_RANGE,
         make_scoped_refptr(
             new GetAvailableRangeResultParameters(*start, result)));
   }
   return result;
 }

 bool MemEntryImpl::CouldBeSparse() const {
   DCHECK_EQ(kParentEntry, type());
   return (children_.get() != NULL);
 }

 int MemEntryImpl::ReadyForSparseIO(
     net::CompletionCallback* completion_callback) {
   return net::OK;
 }

 // ------------------------------------------------------------------------

 MemEntryImpl::~MemEntryImpl() {
   for (int i = 0; i < NUM_STREAMS; i++)
     backend_->ModifyStorageSize(data_size_[i], 0);
   backend_->ModifyStorageSize(static_cast<int32>(key_.size()), 0);
   net_log_.EndEvent(net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL, NULL);
 }

 int MemEntryImpl::InternalReadData(int index, int offset, net::IOBuffer* buf,
                                    int buf_len) {
   DCHECK(type() == kParentEntry || index == kSparseData);

   if (index < 0 || index >= NUM_STREAMS)
     return net::ERR_INVALID_ARGUMENT;

   int entry_size = GetDataSize(index);
   if (offset >= entry_size || offset < 0 || !buf_len)
     return 0;

   if (buf_len < 0)
     return net::ERR_INVALID_ARGUMENT;

   if (offset + buf_len > entry_size)
     buf_len = entry_size - offset;

   UpdateRank(false);

   memcpy(buf->data(), &(data_[index])[offset], buf_len);
   return buf_len;
 }

 int MemEntryImpl::InternalWriteData(int index, int offset, net::IOBuffer* buf,
                                     int buf_len, bool truncate) {
   DCHECK(type() == kParentEntry || index == kSparseData);

   if (index < 0 || index >= NUM_STREAMS)
     return net::ERR_INVALID_ARGUMENT;

   if (offset < 0 || buf_len < 0)
     return net::ERR_INVALID_ARGUMENT;

   int max_file_size = backend_->MaxFileSize();

   // offset of buf_len could be negative numbers.
   if (offset > max_file_size || buf_len > max_file_size ||
       offset + buf_len > max_file_size) {
     return net::ERR_FAILED;
   }

   // Read the size at this point.
   int entry_size = GetDataSize(index);

   PrepareTarget(index, offset, buf_len);

   if (entry_size < offset + buf_len) {
     backend_->ModifyStorageSize(entry_size, offset + buf_len);
     data_size_[index] = offset + buf_len;
   } else if (truncate) {
     if (entry_size > offset + buf_len) {
       backend_->ModifyStorageSize(entry_size, offset + buf_len);
       data_size_[index] = offset + buf_len;
     }
   }

   UpdateRank(true);

   if (!buf_len)
     return 0;

   memcpy(&(data_[index])[offset], buf->data(), buf_len);
   return buf_len;
 }

 int MemEntryImpl::InternalReadSparseData(int64 offset, net::IOBuffer* buf,
                                          int buf_len) {
   DCHECK(type() == kParentEntry);

   if (!InitSparseInfo())
     return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

   if (offset < 0 || buf_len < 0)
     return net::ERR_INVALID_ARGUMENT;

   // We will keep using this buffer and adjust the offset in this buffer.
   scoped_refptr<net::DrainableIOBuffer> io_buf(
       new net::DrainableIOBuffer(buf, buf_len));

   // Iterate until we have read enough.
   while (io_buf->BytesRemaining()) {
     MemEntryImpl* child = OpenChild(offset + io_buf->BytesConsumed(), false);

     // No child present for that offset.
     if (!child)
       break;

     // We then need to prepare the child offset and len.
     int child_offset = ToChildOffset(offset + io_buf->BytesConsumed());

     // If we are trying to read from a position that the child entry has no data
     // we should stop.
     if (child_offset < child->child_first_pos_)
       break;
     if (net_log_.IsLoggingAllEvents()) {
       net_log_.BeginEvent(
           net::NetLog::TYPE_SPARSE_READ_CHILD_DATA,
           make_scoped_refptr(new SparseReadWriteParameters(
               child->net_log().source(),
               io_buf->BytesRemaining())));
     }
     int ret = child->ReadData(kSparseData, child_offset, io_buf,
                               io_buf->BytesRemaining(), NULL);
     if (net_log_.IsLoggingAllEvents()) {
       net_log_.EndEventWithNetErrorCode(
           net::NetLog::TYPE_SPARSE_READ_CHILD_DATA, ret);
     }

     // If we encounter an error in one entry, return immediately.
     if (ret < 0)
       return ret;
     else if (ret == 0)
       break;

     // Increment the counter by number of bytes read in the child entry.
     io_buf->DidConsume(ret);
   }

   UpdateRank(false);

   return io_buf->BytesConsumed();
 }

 int MemEntryImpl::InternalWriteSparseData(int64 offset, net::IOBuffer* buf,
                                           int buf_len) {
   DCHECK(type() == kParentEntry);

   if (!InitSparseInfo())
     return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

   if (offset < 0 || buf_len < 0)
     return net::ERR_INVALID_ARGUMENT;

   scoped_refptr<net::DrainableIOBuffer> io_buf(
       new net::DrainableIOBuffer(buf, buf_len));

   // This loop walks through child entries continuously starting from |offset|
   // and writes blocks of data (of maximum size kMaxSparseEntrySize) into each
   // child entry until all |buf_len| bytes are written. The write operation can
   // start in the middle of an entry.
   while (io_buf->BytesRemaining()) {
     MemEntryImpl* child = OpenChild(offset + io_buf->BytesConsumed(), true);
     int child_offset = ToChildOffset(offset + io_buf->BytesConsumed());

     // Find the right amount to write, this evaluates the remaining bytes to
     // write and remaining capacity of this child entry.
     int write_len = std::min(static_cast<int>(io_buf->BytesRemaining()),
                              kMaxSparseEntrySize - child_offset);

     // Keep a record of the last byte position (exclusive) in the child.
     int data_size = child->GetDataSize(kSparseData);

     if (net_log_.IsLoggingAllEvents()) {
       net_log_.BeginEvent(
           net::NetLog::TYPE_SPARSE_WRITE_CHILD_DATA,
           make_scoped_refptr(new SparseReadWriteParameters(
               child->net_log().source(),
               write_len)));
     }

     // Always writes to the child entry. This operation may overwrite data
     // previously written.
     // TODO(hclam): if there is data in the entry and this write is not
     // continuous we may want to discard this write.
     int ret = child->WriteData(kSparseData, child_offset, io_buf, write_len,
                                NULL, true);
     if (net_log_.IsLoggingAllEvents()) {
       net_log_.EndEventWithNetErrorCode(
           net::NetLog::TYPE_SPARSE_WRITE_CHILD_DATA, ret);
     }
     if (ret < 0)
       return ret;
     else if (ret == 0)
       break;

     // Keep a record of the first byte position in the child if the write was
     // not aligned nor continuous. This is to enable witting to the middle
     // of an entry and still keep track of data off the aligned edge.
     if (data_size != child_offset)
       child->child_first_pos_ = child_offset;

     // Adjust the offset in the IO buffer.
     io_buf->DidConsume(ret);
   }

   UpdateRank(true);

   return io_buf->BytesConsumed();
 }

 int MemEntryImpl::GetAvailableRange(int64 offset, int len, int64* start) {
   DCHECK(type() == kParentEntry);
   DCHECK(start);

   if (!InitSparseInfo())
     return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

   if (offset < 0 || len < 0 || !start)
     return net::ERR_INVALID_ARGUMENT;

   MemEntryImpl* current_child = NULL;

   // Find the first child and record the number of empty bytes.
   int empty = FindNextChild(offset, len, &current_child);
   if (current_child) {
     *start = offset + empty;
     len -= empty;

     // Counts the number of continuous bytes.
     int continuous = 0;

     // This loop scan for continuous bytes.
     while (len && current_child) {
       // Number of bytes available in this child.
       int data_size = current_child->GetDataSize(kSparseData) -
                       ToChildOffset(*start + continuous);
       if (data_size > len)
         data_size = len;

       // We have found more continuous bytes so increment the count. Also
       // decrement the length we should scan.
       continuous += data_size;
       len -= data_size;

       // If the next child is discontinuous, break the loop.
       if (FindNextChild(*start + continuous, len, &current_child))
         break;
     }
     return continuous;
   }
   *start = offset;
   return 0;
 }

 void MemEntryImpl::PrepareTarget(int index, int offset, int buf_len) {
   int entry_size = GetDataSize(index);

   if (entry_size >= offset + buf_len)
     return;  // Not growing the stored data.

   if (static_cast<int>(data_[index].size()) < offset + buf_len)
     data_[index].resize(offset + buf_len);

   if (offset <= entry_size)
     return;  // There is no "hole" on the stored data.

   // Cleanup the hole not written by the user. The point is to avoid returning
   // random stuff later on.
   memset(&(data_[index])[entry_size], 0, offset - entry_size);
 }

 void MemEntryImpl::UpdateRank(bool modified) {
   Time current = Time::Now();
   last_used_ = current;

   if (modified)
     last_modified_ = current;

   if (!doomed_)
     backend_->UpdateRank(this);
 }

 bool MemEntryImpl::InitSparseInfo() {
   DCHECK(type() == kParentEntry);

   if (!children_.get()) {
     // If we already have some data in sparse stream but we are being
     // initialized as a sparse entry, we should fail.
     if (GetDataSize(kSparseData))
       return false;
     children_.reset(new EntryMap());

     // The parent entry stores data for the first block, so save this object to
     // index 0.
     (*children_)[0] = this;
   }
   return true;
 }

 bool MemEntryImpl::InitChildEntry(MemEntryImpl* parent, int child_id,
                                   net::NetLog* net_log) {
   DCHECK(!parent_);
   DCHECK(!child_id_);

   net_log_ = net::BoundNetLog::Make(net_log,
                                     net::NetLog::SOURCE_MEMORY_CACHE_ENTRY);
   net_log_.BeginEvent(
       net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL,
       make_scoped_refptr(new EntryCreationParameters(
           GenerateChildName(parent->key(), child_id_),
           true)));

   parent_ = parent;
   child_id_ = child_id;
   Time current = Time::Now();
   last_modified_ = current;
   last_used_ = current;
   // Insert this to the backend's ranking list.
   backend_->InsertIntoRankingList(this);
   return true;
 }

 MemEntryImpl* MemEntryImpl::OpenChild(int64 offset, bool create) {
   DCHECK(type() == kParentEntry);
   int index = ToChildIndex(offset);
   EntryMap::iterator i = children_->find(index);
   if (i != children_->end()) {
     return i->second;
   } else if (create) {
     MemEntryImpl* child = new MemEntryImpl(backend_);
     child->InitChildEntry(this, index, net_log_.net_log());
     (*children_)[index] = child;
     return child;
   }
   return NULL;
 }

 int MemEntryImpl::FindNextChild(int64 offset, int len, MemEntryImpl** child) {
   DCHECK(child);
   *child = NULL;
   int scanned_len = 0;

   // This loop tries to find the first existing child.
   while (scanned_len < len) {
     // This points to the current offset in the child.
     int current_child_offset = ToChildOffset(offset + scanned_len);
     MemEntryImpl* current_child = OpenChild(offset + scanned_len, false);
     if (current_child) {
       int child_first_pos = current_child->child_first_pos_;

       // This points to the first byte that we should be reading from, we need
       // to take care of the filled region and the current offset in the child.
       int first_pos =  std::max(current_child_offset, child_first_pos);

       // If the first byte position we should read from doesn't exceed the
       // filled region, we have found the first child.
       if (first_pos < current_child->GetDataSize(kSparseData)) {
          *child = current_child;

          // We need to advance the scanned length.
          scanned_len += first_pos - current_child_offset;
          break;
       }
     }
     scanned_len += kMaxSparseEntrySize - current_child_offset;
   }
   return scanned_len;
 }

 void MemEntryImpl::DetachChild(int child_id) {
   children_->erase(child_id);
 }

 }  // namespace disk_cache
	// Copyright (c) 2011 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/mem_entry_impl.h"

	#include "base/logging.h"
	#include "base/stringprintf.h"
	#include "net/base/io_buffer.h"
	#include "net/base/net_errors.h"
	#include "net/disk_cache/mem_backend_impl.h"
	#include "net/disk_cache/net_log_parameters.h"

	using base::Time;

	namespace {

	const int kSparseData = 1;

	// Maximum size of a sparse entry is 2 to the power of this number.
	const int kMaxSparseEntryBits = 12;

	// Sparse entry has maximum size of 4KB.
	const int kMaxSparseEntrySize = 1 << kMaxSparseEntryBits;

	// Convert global offset to child index.
	inline int ToChildIndex(int64 offset) {
	return static_cast<int>(offset >> kMaxSparseEntryBits);
	}

	// Convert global offset to offset in child entry.
	inline int ToChildOffset(int64 offset) {
	return static_cast<int>(offset & (kMaxSparseEntrySize - 1));
	}

	// Returns a name for a child entry given the base_name of the parent and the
	// child_id. This name is only used for logging purposes.
	// If the entry is called entry_name, child entries will be named something
	// like Range_entry_name:YYY where YYY is the number of the particular child.
	std::string GenerateChildName(const std::string& base_name, int child_id) {
	return base::StringPrintf("Range_%s:%i", base_name.c_str(), child_id);
	}

	} // namespace

	namespace disk_cache {

	MemEntryImpl::MemEntryImpl(MemBackendImpl* backend) {
	doomed_ = false;
	backend_ = backend;
	ref_count_ = 0;
	parent_ = NULL;
	child_id_ = 0;
	child_first_pos_ = 0;
	next_ = NULL;
	prev_ = NULL;
	for (int i = 0; i < NUM_STREAMS; i++)
	data_size_[i] = 0;
	}

	// ------------------------------------------------------------------------

	bool MemEntryImpl::CreateEntry(const std::string& key, net::NetLog* net_log) {
	net_log_ = net::BoundNetLog::Make(net_log,
	net::NetLog::SOURCE_MEMORY_CACHE_ENTRY);
	net_log_.BeginEvent(
	net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL,
	make_scoped_refptr(new EntryCreationParameters(key, true)));
	key_ = key;
	Time current = Time::Now();
	last_modified_ = current;
	last_used_ = current;
	Open();
	backend_->ModifyStorageSize(0, static_cast<int32>(key.size()));
	return true;
	}

	void MemEntryImpl::InternalDoom() {
	net_log_.AddEvent(net::NetLog::TYPE_ENTRY_DOOM, NULL);
	doomed_ = true;
	if (!ref_count_) {
	if (type() == kParentEntry) {
	// If this is a parent entry, we need to doom all the child entries.
	if (children_.get()) {
	EntryMap children;
	children.swap(*children_);
	for (EntryMap::iterator i = children.begin();
	i != children.end(); ++i) {
	// Since a pointer to this object is also saved in the map, avoid
	// dooming it.
	if (i->second != this)
	i->second->Doom();
	}
	DCHECK(children_->empty());
	}
	} else {
	// If this is a child entry, detach it from the parent.
	parent_->DetachChild(child_id_);
	}
	delete this;
	}
	}

	void MemEntryImpl::Open() {
	// Only a parent entry can be opened.
	// TODO(hclam): make sure it's correct to not apply the concept of ref
	// counting to child entry.
	DCHECK(type() == kParentEntry);
	ref_count_++;
	DCHECK_GE(ref_count_, 0);
	DCHECK(!doomed_);
	}

	bool MemEntryImpl::InUse() {
	if (type() == kParentEntry) {
	return ref_count_ > 0;
	} else {
	// A child entry is always not in use. The consequence is that a child entry
	// can always be evicted while the associated parent entry is currently in
	// used (i.e. opened).
	return false;
	}
	}

	// ------------------------------------------------------------------------

	void MemEntryImpl::Doom() {
	if (doomed_)
	return;
	if (type() == kParentEntry) {
	// Perform internal doom from the backend if this is a parent entry.
	backend_->InternalDoomEntry(this);
	} else {
	// Manually detach from the backend and perform internal doom.
	backend_->RemoveFromRankingList(this);
	InternalDoom();
	}
	}

	void MemEntryImpl::Close() {
	// Only a parent entry can be closed.
	DCHECK(type() == kParentEntry);
	ref_count_--;
	DCHECK_GE(ref_count_, 0);
	if (!ref_count_ && doomed_)
	InternalDoom();
	}

	std::string MemEntryImpl::GetKey() const {
	// A child entry doesn't have key so this method should not be called.
	DCHECK(type() == kParentEntry);
	return key_;
	}

	Time MemEntryImpl::GetLastUsed() const {
	return last_used_;
	}

	Time MemEntryImpl::GetLastModified() const {
	return last_modified_;
	}

	int32 MemEntryImpl::GetDataSize(int index) const {
	if (index < 0 \|\| index >= NUM_STREAMS)
	return 0;
	return data_size_[index];
	}

	int MemEntryImpl::ReadData(int index, int offset, net::IOBuffer* buf,
	int buf_len, net::CompletionCallback* completion_callback) {
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_ENTRY_READ_DATA,
	make_scoped_refptr(
	new ReadWriteDataParameters(index, offset, buf_len, false)));
	}

	int result = InternalReadData(index, offset, buf, buf_len);

	if (net_log_.IsLoggingAllEvents()) {
	net_log_.EndEvent(
	net::NetLog::TYPE_ENTRY_READ_DATA,
	make_scoped_refptr(new ReadWriteCompleteParameters(result)));
	}
	return result;
	}

	int MemEntryImpl::WriteData(int index, int offset, net::IOBuffer* buf,
	int buf_len, net::CompletionCallback* completion_callback, bool truncate) {
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_ENTRY_WRITE_DATA,
	make_scoped_refptr(
	new ReadWriteDataParameters(index, offset, buf_len, truncate)));
	}

	int result = InternalWriteData(index, offset, buf, buf_len, truncate);

	if (net_log_.IsLoggingAllEvents()) {
	net_log_.EndEvent(
	net::NetLog::TYPE_ENTRY_WRITE_DATA,
	make_scoped_refptr(new ReadWriteCompleteParameters(result)));
	}
	return result;
	}

	int MemEntryImpl::ReadSparseData(int64 offset, net::IOBuffer* buf, int buf_len,
	net::CompletionCallback* completion_callback) {
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_SPARSE_READ,
	make_scoped_refptr(
	new SparseOperationParameters(offset, buf_len)));
	}
	int result = InternalReadSparseData(offset, buf, buf_len);
	if (net_log_.IsLoggingAllEvents())
	net_log_.EndEvent(net::NetLog::TYPE_SPARSE_READ, NULL);
	return result;
	}

	int MemEntryImpl::WriteSparseData(int64 offset, net::IOBuffer* buf, int buf_len,
	net::CompletionCallback* completion_callback) {
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(net::NetLog::TYPE_SPARSE_WRITE,
	make_scoped_refptr(
	new SparseOperationParameters(offset, buf_len)));
	}
	int result = InternalWriteSparseData(offset, buf, buf_len);
	if (net_log_.IsLoggingAllEvents())
	net_log_.EndEvent(net::NetLog::TYPE_SPARSE_WRITE, NULL);
	return result;
	}

	int MemEntryImpl::GetAvailableRange(int64 offset, int len, int64* start,
	CompletionCallback* callback) {
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_SPARSE_GET_RANGE,
	make_scoped_refptr(
	new SparseOperationParameters(offset, len)));
	}
	int result = GetAvailableRange(offset, len, start);
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.EndEvent(
	net::NetLog::TYPE_SPARSE_GET_RANGE,
	make_scoped_refptr(
	new GetAvailableRangeResultParameters(*start, result)));
	}
	return result;
	}

	bool MemEntryImpl::CouldBeSparse() const {
	DCHECK_EQ(kParentEntry, type());
	return (children_.get() != NULL);
	}

	int MemEntryImpl::ReadyForSparseIO(
	net::CompletionCallback* completion_callback) {
	return net::OK;
	}

	// ------------------------------------------------------------------------

	MemEntryImpl::~MemEntryImpl() {
	for (int i = 0; i < NUM_STREAMS; i++)
	backend_->ModifyStorageSize(data_size_[i], 0);
	backend_->ModifyStorageSize(static_cast<int32>(key_.size()), 0);
	net_log_.EndEvent(net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL, NULL);
	}

	int MemEntryImpl::InternalReadData(int index, int offset, net::IOBuffer* buf,
	int buf_len) {
	DCHECK(type() == kParentEntry \|\| index == kSparseData);

	if (index < 0 \|\| index >= NUM_STREAMS)
	return net::ERR_INVALID_ARGUMENT;

	int entry_size = GetDataSize(index);
	if (offset >= entry_size \|\| offset < 0 \|\| !buf_len)
	return 0;

	if (buf_len < 0)
	return net::ERR_INVALID_ARGUMENT;

	if (offset + buf_len > entry_size)
	buf_len = entry_size - offset;

	UpdateRank(false);

	memcpy(buf->data(), &(data_[index])[offset], buf_len);
	return buf_len;
	}

	int MemEntryImpl::InternalWriteData(int index, int offset, net::IOBuffer* buf,
	int buf_len, bool truncate) {
	DCHECK(type() == kParentEntry \|\| index == kSparseData);

	if (index < 0 \|\| index >= NUM_STREAMS)
	return net::ERR_INVALID_ARGUMENT;

	if (offset < 0 \|\| buf_len < 0)
	return net::ERR_INVALID_ARGUMENT;

	int max_file_size = backend_->MaxFileSize();

	// offset of buf_len could be negative numbers.
	if (offset > max_file_size \|\| buf_len > max_file_size \|\|
	offset + buf_len > max_file_size) {
	return net::ERR_FAILED;
	}

	// Read the size at this point.
	int entry_size = GetDataSize(index);

	PrepareTarget(index, offset, buf_len);

	if (entry_size < offset + buf_len) {
	backend_->ModifyStorageSize(entry_size, offset + buf_len);
	data_size_[index] = offset + buf_len;
	} else if (truncate) {
	if (entry_size > offset + buf_len) {
	backend_->ModifyStorageSize(entry_size, offset + buf_len);
	data_size_[index] = offset + buf_len;
	}
	}

	UpdateRank(true);

	if (!buf_len)
	return 0;

	memcpy(&(data_[index])[offset], buf->data(), buf_len);
	return buf_len;
	}

	int MemEntryImpl::InternalReadSparseData(int64 offset, net::IOBuffer* buf,
	int buf_len) {
	DCHECK(type() == kParentEntry);

	if (!InitSparseInfo())
	return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

	if (offset < 0 \|\| buf_len < 0)
	return net::ERR_INVALID_ARGUMENT;

	// We will keep using this buffer and adjust the offset in this buffer.
	scoped_refptr<net::DrainableIOBuffer> io_buf(
	new net::DrainableIOBuffer(buf, buf_len));

	// Iterate until we have read enough.
	while (io_buf->BytesRemaining()) {
	MemEntryImpl* child = OpenChild(offset + io_buf->BytesConsumed(), false);

	// No child present for that offset.
	if (!child)
	break;

	// We then need to prepare the child offset and len.
	int child_offset = ToChildOffset(offset + io_buf->BytesConsumed());

	// If we are trying to read from a position that the child entry has no data
	// we should stop.
	if (child_offset < child->child_first_pos_)
	break;
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_SPARSE_READ_CHILD_DATA,
	make_scoped_refptr(new SparseReadWriteParameters(
	child->net_log().source(),
	io_buf->BytesRemaining())));
	}
	int ret = child->ReadData(kSparseData, child_offset, io_buf,
	io_buf->BytesRemaining(), NULL);
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.EndEventWithNetErrorCode(
	net::NetLog::TYPE_SPARSE_READ_CHILD_DATA, ret);
	}

	// If we encounter an error in one entry, return immediately.
	if (ret < 0)
	return ret;
	else if (ret == 0)
	break;

	// Increment the counter by number of bytes read in the child entry.
	io_buf->DidConsume(ret);
	}

	UpdateRank(false);

	return io_buf->BytesConsumed();
	}

	int MemEntryImpl::InternalWriteSparseData(int64 offset, net::IOBuffer* buf,
	int buf_len) {
	DCHECK(type() == kParentEntry);

	if (!InitSparseInfo())
	return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

	if (offset < 0 \|\| buf_len < 0)
	return net::ERR_INVALID_ARGUMENT;

	scoped_refptr<net::DrainableIOBuffer> io_buf(
	new net::DrainableIOBuffer(buf, buf_len));

	// This loop walks through child entries continuously starting from \|offset\|
	// and writes blocks of data (of maximum size kMaxSparseEntrySize) into each
	// child entry until all \|buf_len\| bytes are written. The write operation can
	// start in the middle of an entry.
	while (io_buf->BytesRemaining()) {
	MemEntryImpl* child = OpenChild(offset + io_buf->BytesConsumed(), true);
	int child_offset = ToChildOffset(offset + io_buf->BytesConsumed());

	// Find the right amount to write, this evaluates the remaining bytes to
	// write and remaining capacity of this child entry.
	int write_len = std::min(static_cast<int>(io_buf->BytesRemaining()),
	kMaxSparseEntrySize - child_offset);

	// Keep a record of the last byte position (exclusive) in the child.
	int data_size = child->GetDataSize(kSparseData);

	if (net_log_.IsLoggingAllEvents()) {
	net_log_.BeginEvent(
	net::NetLog::TYPE_SPARSE_WRITE_CHILD_DATA,
	make_scoped_refptr(new SparseReadWriteParameters(
	child->net_log().source(),
	write_len)));
	}

	// Always writes to the child entry. This operation may overwrite data
	// previously written.
	// TODO(hclam): if there is data in the entry and this write is not
	// continuous we may want to discard this write.
	int ret = child->WriteData(kSparseData, child_offset, io_buf, write_len,
	NULL, true);
	if (net_log_.IsLoggingAllEvents()) {
	net_log_.EndEventWithNetErrorCode(
	net::NetLog::TYPE_SPARSE_WRITE_CHILD_DATA, ret);
	}
	if (ret < 0)
	return ret;
	else if (ret == 0)
	break;

	// Keep a record of the first byte position in the child if the write was
	// not aligned nor continuous. This is to enable witting to the middle
	// of an entry and still keep track of data off the aligned edge.
	if (data_size != child_offset)
	child->child_first_pos_ = child_offset;

	// Adjust the offset in the IO buffer.
	io_buf->DidConsume(ret);
	}

	UpdateRank(true);

	return io_buf->BytesConsumed();
	}

	int MemEntryImpl::GetAvailableRange(int64 offset, int len, int64* start) {
	DCHECK(type() == kParentEntry);
	DCHECK(start);

	if (!InitSparseInfo())
	return net::ERR_CACHE_OPERATION_NOT_SUPPORTED;

	if (offset < 0 \|\| len < 0 \|\| !start)
	return net::ERR_INVALID_ARGUMENT;

	MemEntryImpl* current_child = NULL;

	// Find the first child and record the number of empty bytes.
	int empty = FindNextChild(offset, len, &current_child);
	if (current_child) {
	*start = offset + empty;
	len -= empty;

	// Counts the number of continuous bytes.
	int continuous = 0;

	// This loop scan for continuous bytes.
	while (len && current_child) {
	// Number of bytes available in this child.
	int data_size = current_child->GetDataSize(kSparseData) -
	ToChildOffset(*start + continuous);
	if (data_size > len)
	data_size = len;

	// We have found more continuous bytes so increment the count. Also
	// decrement the length we should scan.
	continuous += data_size;
	len -= data_size;

	// If the next child is discontinuous, break the loop.
	if (FindNextChild(*start + continuous, len, &current_child))
	break;
	}
	return continuous;
	}
	*start = offset;
	return 0;
	}

	void MemEntryImpl::PrepareTarget(int index, int offset, int buf_len) {
	int entry_size = GetDataSize(index);

	if (entry_size >= offset + buf_len)
	return; // Not growing the stored data.

	if (static_cast<int>(data_[index].size()) < offset + buf_len)
	data_[index].resize(offset + buf_len);

	if (offset <= entry_size)
	return; // There is no "hole" on the stored data.

	// Cleanup the hole not written by the user. The point is to avoid returning
	// random stuff later on.
	memset(&(data_[index])[entry_size], 0, offset - entry_size);
	}

	void MemEntryImpl::UpdateRank(bool modified) {
	Time current = Time::Now();
	last_used_ = current;

	if (modified)
	last_modified_ = current;

	if (!doomed_)
	backend_->UpdateRank(this);
	}

	bool MemEntryImpl::InitSparseInfo() {
	DCHECK(type() == kParentEntry);

	if (!children_.get()) {
	// If we already have some data in sparse stream but we are being
	// initialized as a sparse entry, we should fail.
	if (GetDataSize(kSparseData))
	return false;
	children_.reset(new EntryMap());

	// The parent entry stores data for the first block, so save this object to
	// index 0.
	(*children_)[0] = this;
	}
	return true;
	}

	bool MemEntryImpl::InitChildEntry(MemEntryImpl* parent, int child_id,
	net::NetLog* net_log) {
	DCHECK(!parent_);
	DCHECK(!child_id_);

	net_log_ = net::BoundNetLog::Make(net_log,
	net::NetLog::SOURCE_MEMORY_CACHE_ENTRY);
	net_log_.BeginEvent(
	net::NetLog::TYPE_DISK_CACHE_MEM_ENTRY_IMPL,
	make_scoped_refptr(new EntryCreationParameters(
	GenerateChildName(parent->key(), child_id_),
	true)));

	parent_ = parent;
	child_id_ = child_id;
	Time current = Time::Now();
	last_modified_ = current;
	last_used_ = current;
	// Insert this to the backend's ranking list.
	backend_->InsertIntoRankingList(this);
	return true;
	}

	MemEntryImpl* MemEntryImpl::OpenChild(int64 offset, bool create) {
	DCHECK(type() == kParentEntry);
	int index = ToChildIndex(offset);
	EntryMap::iterator i = children_->find(index);
	if (i != children_->end()) {
	return i->second;
	} else if (create) {
	MemEntryImpl* child = new MemEntryImpl(backend_);
	child->InitChildEntry(this, index, net_log_.net_log());
	(*children_)[index] = child;
	return child;
	}
	return NULL;
	}

	int MemEntryImpl::FindNextChild(int64 offset, int len, MemEntryImpl** child) {
	DCHECK(child);
	*child = NULL;
	int scanned_len = 0;

	// This loop tries to find the first existing child.
	while (scanned_len < len) {
	// This points to the current offset in the child.
	int current_child_offset = ToChildOffset(offset + scanned_len);
	MemEntryImpl* current_child = OpenChild(offset + scanned_len, false);
	if (current_child) {
	int child_first_pos = current_child->child_first_pos_;

	// This points to the first byte that we should be reading from, we need
	// to take care of the filled region and the current offset in the child.
	int first_pos = std::max(current_child_offset, child_first_pos);

	// If the first byte position we should read from doesn't exceed the
	// filled region, we have found the first child.
	if (first_pos < current_child->GetDataSize(kSparseData)) {
	*child = current_child;

	// We need to advance the scanned length.
	scanned_len += first_pos - current_child_offset;
	break;
	}
	}
	scanned_len += kMaxSparseEntrySize - current_child_offset;
	}
	return scanned_len;
	}

	void MemEntryImpl::DetachChild(int child_id) {
	children_->erase(child_id);
	}

	} // namespace disk_cache