content/browser/renderer_data_memoizing_store.h - chromium/src - Git at Google

 // Copyright 2013 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.

 #ifndef CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_
 #define CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_

 #include <map>

 #include "base/bind.h"
 #include "base/synchronization/lock.h"
 #include "content/public/browser/browser_thread.h"
 #include "content/public/browser/render_process_host.h"
 #include "content/public/browser/render_process_host_observer.h"

 namespace content {

 // RendererDataMemoizingStore is a thread-safe container that retains reference
 // counted objects that are associated with one or more render processes.
 // Objects are identified by an int and only a single reference to a given
 // object is retained. RendererDataMemoizingStore watches for render process
 // termination and releases objects that are no longer associated with any
 // render process.
 //
 // TODO(jcampan): Rather than watching for render process termination, we should
 //                instead be listening to events such as resource cached/
 //                removed from cache, and remove the items when we know they
 //                are not used anymore.
 template <typename T>
 class RendererDataMemoizingStore : public RenderProcessHostObserver {
  public:
   RendererDataMemoizingStore() : next_item_id_(1) {
   }

   ~RendererDataMemoizingStore() {
     DCHECK_EQ(0U, id_to_item_.size()) << "Failed to outlive render processes";
   }

   // Store adds |item| to this collection, associates it with the given render
   // process id and returns an opaque identifier for it. If |item| is already
   // known, the same identifier will be returned.
   int Store(T* item, int process_id) {
     DCHECK(item);
     base::AutoLock auto_lock(lock_);

     int item_id;

     // Do we already know this item?
     typename ReverseItemMap::iterator item_iter = item_to_id_.find(item);
     if (item_iter == item_to_id_.end()) {
       item_id = next_item_id_++;
       // We use 0 as an invalid item_id value.  In the unlikely event that
       // next_item_id_ wraps around, we reset it to 1.
       if (next_item_id_ == 0)
         next_item_id_ = 1;
       id_to_item_[item_id] = item;
       item_to_id_[item] = item_id;
     } else {
       item_id = item_iter->second;
     }

     // Let's update process_id_to_item_id_.
     std::pair<IDMap::iterator, IDMap::iterator> process_ids =
         process_id_to_item_id_.equal_range(process_id);
     bool already_watching_process = (process_ids.first != process_ids.second);
     if (std::find_if(process_ids.first, process_ids.second,
                      MatchSecond<int>(item_id)) == process_ids.second) {
       process_id_to_item_id_.insert(std::make_pair(process_id, item_id));
     }

     // And item_id_to_process_id_.
     std::pair<IDMap::iterator, IDMap::iterator> item_ids =
         item_id_to_process_id_.equal_range(item_id);
     if (std::find_if(item_ids.first, item_ids.second,
                      MatchSecond<int>(process_id)) == item_ids.second) {
       item_id_to_process_id_.insert(std::make_pair(item_id, process_id));
     }

     // If we're not doing so already, keep an eye for the process host deletion.
     if (!already_watching_process) {
       if (BrowserThread::CurrentlyOn(BrowserThread::UI)) {
         StartObservingProcess(process_id);
       } else {
         BrowserThread::PostTask(
             BrowserThread::UI,
             FROM_HERE,
             base::Bind(&RendererDataMemoizingStore::StartObservingProcess,
                        base::Unretained(this),
                        process_id));
       }
     }

     DCHECK(item_id);
     return item_id;
   }

   // Retrieve fetches a previously Stored() item, identified by |item_id|.
   // If |item_id| is recognized, |item| will be updated and Retrieve() will
   // return true, it will otherwise return false.
   bool Retrieve(int item_id, scoped_refptr<T>* item) {
     base::AutoLock auto_lock(lock_);

     typename ItemMap::iterator iter = id_to_item_.find(item_id);
     if (iter == id_to_item_.end())
       return false;
     if (item)
       *item = iter->second;
     return true;
   }

  private:
   typedef std::multimap<int, int> IDMap;
   typedef std::map<int, scoped_refptr<T> > ItemMap;
   typedef std::map<T*, int, typename T::LessThan> ReverseItemMap;

   template <typename M>
   struct MatchSecond {
     explicit MatchSecond(const M& t) : value(t) {}

     template <typename Pair>
     bool operator()(const Pair& p) const {
       return (value == p.second);
     }

     M value;
   };

   void StartObservingProcess(int process_id) {
     DCHECK_CURRENTLY_ON(BrowserThread::UI);
     RenderProcessHost* host = RenderProcessHost::FromID(process_id);
     if (!host) {
       // We lost the race to observe the host before it was destroyed. Since
       // this function was called because we're managing objects tied to that
       // (now destroyed) RenderProcessHost, let's clean up.
       RemoveRenderProcessItems(process_id);
       return;
     }

     host->AddObserver(this);
   }

   // Remove the item specified by |item_id| from id_to_item_ and item_to_id_.
   // NOTE: the caller (RemoveRenderProcessItems) must hold lock_.
   void RemoveInternal(int item_id) {
     typename ItemMap::iterator item_iter = id_to_item_.find(item_id);
     DCHECK(item_iter != id_to_item_.end());

     typename ReverseItemMap::iterator id_iter =
         item_to_id_.find(item_iter->second.get());
     DCHECK(id_iter != item_to_id_.end());
     item_to_id_.erase(id_iter);

     id_to_item_.erase(item_iter);
   }

   void RenderProcessHostDestroyed(RenderProcessHost* host) override {
     DCHECK_CURRENTLY_ON(BrowserThread::UI);
     RemoveRenderProcessItems(host->GetID());
   }

   // Removes all the items associated with the specified process from the store.
   void RemoveRenderProcessItems(int process_id) {
     base::AutoLock auto_lock(lock_);

     // We iterate through all the item ids for that process.
     std::pair<IDMap::iterator, IDMap::iterator> process_ids =
         process_id_to_item_id_.equal_range(process_id);
     for (IDMap::iterator ids_iter = process_ids.first;
          ids_iter != process_ids.second; ++ids_iter) {
       int item_id = ids_iter->second;
       // Find all the processes referring to this item id in
       // item_id_to_process_id_, then locate the process being removed within
       // that range.
       std::pair<IDMap::iterator, IDMap::iterator> item_ids =
           item_id_to_process_id_.equal_range(item_id);
       IDMap::iterator proc_iter = std::find_if(
           item_ids.first, item_ids.second, MatchSecond<int>(process_id));
       DCHECK(proc_iter != item_ids.second);

       // Before removing, determine if no other processes refer to the current
       // item id. If |proc_iter| (the current process) is the lower bound of
       // processes containing the current item id and if |next_proc_iter| is the
       // upper bound (the first process that does not), then only one process,
       // the one being removed, refers to the item id.
       IDMap::iterator next_proc_iter = proc_iter;
       ++next_proc_iter;
       bool last_process_for_item_id =
           (proc_iter == item_ids.first && next_proc_iter == item_ids.second);
       item_id_to_process_id_.erase(proc_iter);

       if (last_process_for_item_id) {
         // The current item id is not referenced by any other processes, so
         // remove it from id_to_item_ and item_to_id_.
         RemoveInternal(item_id);
       }
     }
     if (process_ids.first != process_ids.second)
       process_id_to_item_id_.erase(process_ids.first, process_ids.second);
   }

   IDMap process_id_to_item_id_;
   IDMap item_id_to_process_id_;
   ItemMap id_to_item_;
   ReverseItemMap item_to_id_;

   int next_item_id_;

   // This lock protects: process_id_to_item_id_, item_id_to_process_id_,
   //                     id_to_item_, and item_to_id_.
   base::Lock lock_;
 };

 }  // namespace content

 #endif  // CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_
	// Copyright 2013 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.

	#ifndef CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_
	#define CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_

	#include <map>

	#include "base/bind.h"
	#include "base/synchronization/lock.h"
	#include "content/public/browser/browser_thread.h"
	#include "content/public/browser/render_process_host.h"
	#include "content/public/browser/render_process_host_observer.h"

	namespace content {

	// RendererDataMemoizingStore is a thread-safe container that retains reference
	// counted objects that are associated with one or more render processes.
	// Objects are identified by an int and only a single reference to a given
	// object is retained. RendererDataMemoizingStore watches for render process
	// termination and releases objects that are no longer associated with any
	// render process.
	//
	// TODO(jcampan): Rather than watching for render process termination, we should
	// instead be listening to events such as resource cached/
	// removed from cache, and remove the items when we know they
	// are not used anymore.
	template <typename T>
	class RendererDataMemoizingStore : public RenderProcessHostObserver {
	public:
	RendererDataMemoizingStore() : next_item_id_(1) {
	}

	~RendererDataMemoizingStore() {
	DCHECK_EQ(0U, id_to_item_.size()) << "Failed to outlive render processes";
	}

	// Store adds \|item\| to this collection, associates it with the given render
	// process id and returns an opaque identifier for it. If \|item\| is already
	// known, the same identifier will be returned.
	int Store(T* item, int process_id) {
	DCHECK(item);
	base::AutoLock auto_lock(lock_);

	int item_id;

	// Do we already know this item?
	typename ReverseItemMap::iterator item_iter = item_to_id_.find(item);
	if (item_iter == item_to_id_.end()) {
	item_id = next_item_id_++;
	// We use 0 as an invalid item_id value. In the unlikely event that
	// next_item_id_ wraps around, we reset it to 1.
	if (next_item_id_ == 0)
	next_item_id_ = 1;
	id_to_item_[item_id] = item;
	item_to_id_[item] = item_id;
	} else {
	item_id = item_iter->second;
	}

	// Let's update process_id_to_item_id_.
	std::pair<IDMap::iterator, IDMap::iterator> process_ids =
	process_id_to_item_id_.equal_range(process_id);
	bool already_watching_process = (process_ids.first != process_ids.second);
	if (std::find_if(process_ids.first, process_ids.second,
	MatchSecond<int>(item_id)) == process_ids.second) {
	process_id_to_item_id_.insert(std::make_pair(process_id, item_id));
	}

	// And item_id_to_process_id_.
	std::pair<IDMap::iterator, IDMap::iterator> item_ids =
	item_id_to_process_id_.equal_range(item_id);
	if (std::find_if(item_ids.first, item_ids.second,
	MatchSecond<int>(process_id)) == item_ids.second) {
	item_id_to_process_id_.insert(std::make_pair(item_id, process_id));
	}

	// If we're not doing so already, keep an eye for the process host deletion.
	if (!already_watching_process) {
	if (BrowserThread::CurrentlyOn(BrowserThread::UI)) {
	StartObservingProcess(process_id);
	} else {
	BrowserThread::PostTask(
	BrowserThread::UI,
	FROM_HERE,
	base::Bind(&RendererDataMemoizingStore::StartObservingProcess,
	base::Unretained(this),
	process_id));
	}
	}

	DCHECK(item_id);
	return item_id;
	}

	// Retrieve fetches a previously Stored() item, identified by \|item_id\|.
	// If \|item_id\| is recognized, \|item\| will be updated and Retrieve() will
	// return true, it will otherwise return false.
	bool Retrieve(int item_id, scoped_refptr<T>* item) {
	base::AutoLock auto_lock(lock_);

	typename ItemMap::iterator iter = id_to_item_.find(item_id);
	if (iter == id_to_item_.end())
	return false;
	if (item)
	*item = iter->second;
	return true;
	}

	private:
	typedef std::multimap<int, int> IDMap;
	typedef std::map<int, scoped_refptr<T> > ItemMap;
	typedef std::map<T*, int, typename T::LessThan> ReverseItemMap;

	template <typename M>
	struct MatchSecond {
	explicit MatchSecond(const M& t) : value(t) {}

	template <typename Pair>
	bool operator()(const Pair& p) const {
	return (value == p.second);
	}

	M value;
	};

	void StartObservingProcess(int process_id) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	RenderProcessHost* host = RenderProcessHost::FromID(process_id);
	if (!host) {
	// We lost the race to observe the host before it was destroyed. Since
	// this function was called because we're managing objects tied to that
	// (now destroyed) RenderProcessHost, let's clean up.
	RemoveRenderProcessItems(process_id);
	return;
	}

	host->AddObserver(this);
	}

	// Remove the item specified by \|item_id\| from id_to_item_ and item_to_id_.
	// NOTE: the caller (RemoveRenderProcessItems) must hold lock_.
	void RemoveInternal(int item_id) {
	typename ItemMap::iterator item_iter = id_to_item_.find(item_id);
	DCHECK(item_iter != id_to_item_.end());

	typename ReverseItemMap::iterator id_iter =
	item_to_id_.find(item_iter->second.get());
	DCHECK(id_iter != item_to_id_.end());
	item_to_id_.erase(id_iter);

	id_to_item_.erase(item_iter);
	}

	void RenderProcessHostDestroyed(RenderProcessHost* host) override {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	RemoveRenderProcessItems(host->GetID());
	}

	// Removes all the items associated with the specified process from the store.
	void RemoveRenderProcessItems(int process_id) {
	base::AutoLock auto_lock(lock_);

	// We iterate through all the item ids for that process.
	std::pair<IDMap::iterator, IDMap::iterator> process_ids =
	process_id_to_item_id_.equal_range(process_id);
	for (IDMap::iterator ids_iter = process_ids.first;
	ids_iter != process_ids.second; ++ids_iter) {
	int item_id = ids_iter->second;
	// Find all the processes referring to this item id in
	// item_id_to_process_id_, then locate the process being removed within
	// that range.
	std::pair<IDMap::iterator, IDMap::iterator> item_ids =
	item_id_to_process_id_.equal_range(item_id);
	IDMap::iterator proc_iter = std::find_if(
	item_ids.first, item_ids.second, MatchSecond<int>(process_id));
	DCHECK(proc_iter != item_ids.second);

	// Before removing, determine if no other processes refer to the current
	// item id. If \|proc_iter\| (the current process) is the lower bound of
	// processes containing the current item id and if \|next_proc_iter\| is the
	// upper bound (the first process that does not), then only one process,
	// the one being removed, refers to the item id.
	IDMap::iterator next_proc_iter = proc_iter;
	++next_proc_iter;
	bool last_process_for_item_id =
	(proc_iter == item_ids.first && next_proc_iter == item_ids.second);
	item_id_to_process_id_.erase(proc_iter);

	if (last_process_for_item_id) {
	// The current item id is not referenced by any other processes, so
	// remove it from id_to_item_ and item_to_id_.
	RemoveInternal(item_id);
	}
	}
	if (process_ids.first != process_ids.second)
	process_id_to_item_id_.erase(process_ids.first, process_ids.second);
	}

	IDMap process_id_to_item_id_;
	IDMap item_id_to_process_id_;
	ItemMap id_to_item_;
	ReverseItemMap item_to_id_;

	int next_item_id_;

	// This lock protects: process_id_to_item_id_, item_id_to_process_id_,
	// id_to_item_, and item_to_id_.
	base::Lock lock_;
	};

	} // namespace content

	#endif // CONTENT_BROWSER_RENDERER_DATA_MEMOIZING_STORE_H_