net/proxy/multi_threaded_proxy_resolver.cc - platform/external/chromium - Git at Google

 // Copyright (c) 2010 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/proxy/multi_threaded_proxy_resolver.h"

 #include "base/message_loop.h"
 #include "base/string_util.h"
 #include "base/stringprintf.h"
 #include "base/threading/thread.h"
 #include "base/threading/thread_restrictions.h"
 #include "net/base/net_errors.h"
 #include "net/base/net_log.h"
 #include "net/proxy/proxy_info.h"

 // TODO(eroman): Have the MultiThreadedProxyResolver clear its PAC script
 //               data when SetPacScript fails. That will reclaim memory when
 //               testing bogus scripts.

 namespace net {

 namespace {

 class PurgeMemoryTask : public base::RefCountedThreadSafe<PurgeMemoryTask> {
  public:
   explicit PurgeMemoryTask(ProxyResolver* resolver) : resolver_(resolver) {}
   void PurgeMemory() { resolver_->PurgeMemory(); }
  private:
   friend class base::RefCountedThreadSafe<PurgeMemoryTask>;
   ~PurgeMemoryTask() {}
   ProxyResolver* resolver_;
 };

 }  // namespace

 // An "executor" is a job-runner for PAC requests. It encapsulates a worker
 // thread and a synchronous ProxyResolver (which will be operated on said
 // thread.)
 class MultiThreadedProxyResolver::Executor
     : public base::RefCountedThreadSafe<MultiThreadedProxyResolver::Executor > {
  public:
   // |coordinator| must remain valid throughout our lifetime. It is used to
   // signal when the executor is ready to receive work by calling
   // |coordinator->OnExecutorReady()|.
   // The constructor takes ownership of |resolver|.
   // |thread_number| is an identifier used when naming the worker thread.
   Executor(MultiThreadedProxyResolver* coordinator,
            ProxyResolver* resolver,
            int thread_number);

   // Submit a job to this executor.
   void StartJob(Job* job);

   // Callback for when a job has completed running on the executor's thread.
   void OnJobCompleted(Job* job);

   // Cleanup the executor. Cancels all outstanding work, and frees the thread
   // and resolver.
   void Destroy();

   void PurgeMemory();

   // Returns the outstanding job, or NULL.
   Job* outstanding_job() const { return outstanding_job_.get(); }

   ProxyResolver* resolver() { return resolver_.get(); }

   int thread_number() const { return thread_number_; }

  private:
   friend class base::RefCountedThreadSafe<Executor>;
   ~Executor();

   MultiThreadedProxyResolver* coordinator_;
   const int thread_number_;

   // The currently active job for this executor (either a SetPacScript or
   // GetProxyForURL task).
   scoped_refptr<Job> outstanding_job_;

   // The synchronous resolver implementation.
   scoped_ptr<ProxyResolver> resolver_;

   // The thread where |resolver_| is run on.
   // Note that declaration ordering is important here. |thread_| needs to be
   // destroyed *before* |resolver_|, in case |resolver_| is currently
   // executing on |thread_|.
   scoped_ptr<base::Thread> thread_;
 };

 // MultiThreadedProxyResolver::Job ---------------------------------------------

 class MultiThreadedProxyResolver::Job
     : public base::RefCountedThreadSafe<MultiThreadedProxyResolver::Job> {
  public:
   // Identifies the subclass of Job (only being used for debugging purposes).
   enum Type {
     TYPE_GET_PROXY_FOR_URL,
     TYPE_SET_PAC_SCRIPT,
     TYPE_SET_PAC_SCRIPT_INTERNAL,
   };

   Job(Type type, CompletionCallback* user_callback)
       : type_(type),
         user_callback_(user_callback),
         executor_(NULL),
         was_cancelled_(false) {
   }

   void set_executor(Executor* executor) {
     executor_ = executor;
   }

   // The "executor" is the job runner that is scheduling this job. If
   // this job has not been submitted to an executor yet, this will be
   // NULL (and we know it hasn't started yet).
   Executor* executor() {
     return executor_;
   }

   // Mark the job as having been cancelled.
   void Cancel() {
     was_cancelled_ = true;
   }

   // Returns true if Cancel() has been called.
   bool was_cancelled() const { return was_cancelled_; }

   Type type() const { return type_; }

   // Returns true if this job still has a user callback. Some jobs
   // do not have a user callback, because they were helper jobs
   // scheduled internally (for example TYPE_SET_PAC_SCRIPT_INTERNAL).
   //
   // Otherwise jobs that correspond with user-initiated work will
   // have a non-NULL callback up until the callback is run.
   bool has_user_callback() const { return user_callback_ != NULL; }

   // This method is called when the job is inserted into a wait queue
   // because no executors were ready to accept it.
   virtual void WaitingForThread() {}

   // This method is called just before the job is posted to the work thread.
   virtual void FinishedWaitingForThread() {}

   // This method is called on the worker thread to do the job's work. On
   // completion, implementors are expected to call OnJobCompleted() on
   // |origin_loop|.
   virtual void Run(MessageLoop* origin_loop) = 0;

  protected:
   void OnJobCompleted() {
     // |executor_| will be NULL if the executor has already been deleted.
     if (executor_)
       executor_->OnJobCompleted(this);
   }

   void RunUserCallback(int result) {
     DCHECK(has_user_callback());
     CompletionCallback* callback = user_callback_;
     // Null the callback so has_user_callback() will now return false.
     user_callback_ = NULL;
     callback->Run(result);
   }

   friend class base::RefCountedThreadSafe<MultiThreadedProxyResolver::Job>;

   virtual ~Job() {}

  private:
   const Type type_;
   CompletionCallback* user_callback_;
   Executor* executor_;
   bool was_cancelled_;
 };

 // MultiThreadedProxyResolver::SetPacScriptJob ---------------------------------

 // Runs on the worker thread to call ProxyResolver::SetPacScript.
 class MultiThreadedProxyResolver::SetPacScriptJob
     : public MultiThreadedProxyResolver::Job {
  public:
   SetPacScriptJob(const scoped_refptr<ProxyResolverScriptData>& script_data,
                   CompletionCallback* callback)
     : Job(callback ? TYPE_SET_PAC_SCRIPT : TYPE_SET_PAC_SCRIPT_INTERNAL,
           callback),
       script_data_(script_data) {
   }

   // Runs on the worker thread.
   virtual void Run(MessageLoop* origin_loop) {
     ProxyResolver* resolver = executor()->resolver();
     int rv = resolver->SetPacScript(script_data_, NULL);

     DCHECK_NE(rv, ERR_IO_PENDING);
     origin_loop->PostTask(
         FROM_HERE,
         NewRunnableMethod(this, &SetPacScriptJob::RequestComplete, rv));
   }

  private:
   // Runs the completion callback on the origin thread.
   void RequestComplete(int result_code) {
     // The task may have been cancelled after it was started.
     if (!was_cancelled() && has_user_callback()) {
       RunUserCallback(result_code);
     }
     OnJobCompleted();
   }

   const scoped_refptr<ProxyResolverScriptData> script_data_;
 };

 // MultiThreadedProxyResolver::GetProxyForURLJob ------------------------------

 class MultiThreadedProxyResolver::GetProxyForURLJob
     : public MultiThreadedProxyResolver::Job {
  public:
   // |url|         -- the URL of the query.
   // |results|     -- the structure to fill with proxy resolve results.
   GetProxyForURLJob(const GURL& url,
                     ProxyInfo* results,
                     CompletionCallback* callback,
                     const BoundNetLog& net_log)
       : Job(TYPE_GET_PROXY_FOR_URL, callback),
         results_(results),
         net_log_(net_log),
         url_(url),
         was_waiting_for_thread_(false) {
     DCHECK(callback);
   }

   BoundNetLog* net_log() { return &net_log_; }

   virtual void WaitingForThread() {
     was_waiting_for_thread_ = true;
     net_log_.BeginEvent(
         NetLog::TYPE_WAITING_FOR_PROXY_RESOLVER_THREAD, NULL);
   }

   virtual void FinishedWaitingForThread() {
     DCHECK(executor());

     if (was_waiting_for_thread_) {
       net_log_.EndEvent(
           NetLog::TYPE_WAITING_FOR_PROXY_RESOLVER_THREAD, NULL);
     }

     net_log_.AddEvent(
         NetLog::TYPE_SUBMITTED_TO_RESOLVER_THREAD,
         make_scoped_refptr(new NetLogIntegerParameter(
             "thread_number", executor()->thread_number())));
   }

   // Runs on the worker thread.
   virtual void Run(MessageLoop* origin_loop) {
     ProxyResolver* resolver = executor()->resolver();
     int rv = resolver->GetProxyForURL(
         url_, &results_buf_, NULL, NULL, net_log_);
     DCHECK_NE(rv, ERR_IO_PENDING);

     origin_loop->PostTask(
         FROM_HERE,
         NewRunnableMethod(this, &GetProxyForURLJob::QueryComplete, rv));
   }

  private:
   // Runs the completion callback on the origin thread.
   void QueryComplete(int result_code) {
     // The Job may have been cancelled after it was started.
     if (!was_cancelled()) {
       if (result_code >= OK) {  // Note: unit-tests use values > 0.
         results_->Use(results_buf_);
       }
       RunUserCallback(result_code);
     }
     OnJobCompleted();
   }

   // Must only be used on the "origin" thread.
   ProxyInfo* results_;

   // Can be used on either "origin" or worker thread.
   BoundNetLog net_log_;
   const GURL url_;

   // Usable from within DoQuery on the worker thread.
   ProxyInfo results_buf_;

   bool was_waiting_for_thread_;
 };

 // MultiThreadedProxyResolver::Executor ----------------------------------------

 MultiThreadedProxyResolver::Executor::Executor(
     MultiThreadedProxyResolver* coordinator,
     ProxyResolver* resolver,
     int thread_number)
     : coordinator_(coordinator),
       thread_number_(thread_number),
       resolver_(resolver) {
   DCHECK(coordinator);
   DCHECK(resolver);
   // Start up the thread.
   // Note that it is safe to pass a temporary C-String to Thread(), as it will
   // make a copy.
   std::string thread_name =
       base::StringPrintf("PAC thread #%d", thread_number);
   thread_.reset(new base::Thread(thread_name.c_str()));
   CHECK(thread_->Start());
 }

 void MultiThreadedProxyResolver::Executor::StartJob(Job* job) {
   DCHECK(!outstanding_job_);
   outstanding_job_ = job;

   // Run the job. Once it has completed (regardless of whether it was
   // cancelled), it will invoke OnJobCompleted() on this thread.
   job->set_executor(this);
   job->FinishedWaitingForThread();
   thread_->message_loop()->PostTask(
       FROM_HERE,
       NewRunnableMethod(job, &Job::Run, MessageLoop::current()));
 }

 void MultiThreadedProxyResolver::Executor::OnJobCompleted(Job* job) {
   DCHECK_EQ(job, outstanding_job_.get());
   outstanding_job_ = NULL;
   coordinator_->OnExecutorReady(this);
 }

 void MultiThreadedProxyResolver::Executor::Destroy() {
   DCHECK(coordinator_);

   // Give the resolver an opportunity to shutdown from THIS THREAD before
   // joining on the resolver thread. This allows certain implementations
   // to avoid deadlocks.
   resolver_->Shutdown();

   {
     // See http://crbug.com/69710.
     base::ThreadRestrictions::ScopedAllowIO allow_io;

     // Join the worker thread.
     thread_.reset();
   }

   // Cancel any outstanding job.
   if (outstanding_job_) {
     outstanding_job_->Cancel();
     // Orphan the job (since this executor may be deleted soon).
     outstanding_job_->set_executor(NULL);
   }

   // It is now safe to free the ProxyResolver, since all the tasks that
   // were using it on the resolver thread have completed.
   resolver_.reset();

   // Null some stuff as a precaution.
   coordinator_ = NULL;
   outstanding_job_ = NULL;
 }

 void MultiThreadedProxyResolver::Executor::PurgeMemory() {
   scoped_refptr<PurgeMemoryTask> helper(new PurgeMemoryTask(resolver_.get()));
   thread_->message_loop()->PostTask(
       FROM_HERE,
       NewRunnableMethod(helper.get(), &PurgeMemoryTask::PurgeMemory));
 }

 MultiThreadedProxyResolver::Executor::~Executor() {
   // The important cleanup happens as part of Destroy(), which should always be
   // called first.
   DCHECK(!coordinator_) << "Destroy() was not called";
   DCHECK(!thread_.get());
   DCHECK(!resolver_.get());
   DCHECK(!outstanding_job_);
 }

 // MultiThreadedProxyResolver --------------------------------------------------

 MultiThreadedProxyResolver::MultiThreadedProxyResolver(
     ProxyResolverFactory* resolver_factory,
     size_t max_num_threads)
     : ProxyResolver(resolver_factory->resolvers_expect_pac_bytes()),
       resolver_factory_(resolver_factory),
       max_num_threads_(max_num_threads) {
   DCHECK_GE(max_num_threads, 1u);
 }

 MultiThreadedProxyResolver::~MultiThreadedProxyResolver() {
   // We will cancel all outstanding requests.
   pending_jobs_.clear();
   ReleaseAllExecutors();
 }

 int MultiThreadedProxyResolver::GetProxyForURL(const GURL& url,
                                                ProxyInfo* results,
                                                CompletionCallback* callback,
                                                RequestHandle* request,
                                                const BoundNetLog& net_log) {
   DCHECK(CalledOnValidThread());
   DCHECK(callback);
   DCHECK(current_script_data_.get())
       << "Resolver is un-initialized. Must call SetPacScript() first!";

   scoped_refptr<GetProxyForURLJob> job(
       new GetProxyForURLJob(url, results, callback, net_log));

   // Completion will be notified through |callback|, unless the caller cancels
   // the request using |request|.
   if (request)
     *request = reinterpret_cast<RequestHandle>(job.get());

   // If there is an executor that is ready to run this request, submit it!
   Executor* executor = FindIdleExecutor();
   if (executor) {
     DCHECK_EQ(0u, pending_jobs_.size());
     executor->StartJob(job);
     return ERR_IO_PENDING;
   }

   // Otherwise queue this request. (We will schedule it to a thread once one
   // becomes available).
   job->WaitingForThread();
   pending_jobs_.push_back(job);

   // If we haven't already reached the thread limit, provision a new thread to
   // drain the requests more quickly.
   if (executors_.size() < max_num_threads_) {
     executor = AddNewExecutor();
     executor->StartJob(
         new SetPacScriptJob(current_script_data_, NULL));
   }

   return ERR_IO_PENDING;
 }

 void MultiThreadedProxyResolver::CancelRequest(RequestHandle req) {
   DCHECK(CalledOnValidThread());
   DCHECK(req);

   Job* job = reinterpret_cast<Job*>(req);
   DCHECK_EQ(Job::TYPE_GET_PROXY_FOR_URL, job->type());

   if (job->executor()) {
     // If the job was already submitted to the executor, just mark it
     // as cancelled so the user callback isn't run on completion.
     job->Cancel();
   } else {
     // Otherwise the job is just sitting in a queue.
     PendingJobsQueue::iterator it =
         std::find(pending_jobs_.begin(), pending_jobs_.end(), job);
     DCHECK(it != pending_jobs_.end());
     pending_jobs_.erase(it);
   }
 }

 void MultiThreadedProxyResolver::CancelSetPacScript() {
   DCHECK(CalledOnValidThread());
   DCHECK_EQ(0u, pending_jobs_.size());
   DCHECK_EQ(1u, executors_.size());
   DCHECK_EQ(Job::TYPE_SET_PAC_SCRIPT,
             executors_[0]->outstanding_job()->type());

   // Defensively clear some data which shouldn't be getting used
   // anymore.
   current_script_data_ = NULL;

   ReleaseAllExecutors();
 }

 void MultiThreadedProxyResolver::PurgeMemory() {
   DCHECK(CalledOnValidThread());
   for (ExecutorList::iterator it = executors_.begin();
        it != executors_.end(); ++it) {
     Executor* executor = *it;
     executor->PurgeMemory();
   }
 }

 int MultiThreadedProxyResolver::SetPacScript(
     const scoped_refptr<ProxyResolverScriptData>& script_data,
     CompletionCallback* callback) {
   DCHECK(CalledOnValidThread());
   DCHECK(callback);

   // Save the script details, so we can provision new executors later.
   current_script_data_ = script_data;

   // The user should not have any outstanding requests when they call
   // SetPacScript().
   CheckNoOutstandingUserRequests();

   // Destroy all of the current threads and their proxy resolvers.
   ReleaseAllExecutors();

   // Provision a new executor, and run the SetPacScript request. On completion
   // notification will be sent through |callback|.
   Executor* executor = AddNewExecutor();
   executor->StartJob(new SetPacScriptJob(script_data, callback));
   return ERR_IO_PENDING;
 }

 void MultiThreadedProxyResolver::CheckNoOutstandingUserRequests() const {
   DCHECK(CalledOnValidThread());
   CHECK_EQ(0u, pending_jobs_.size());

   for (ExecutorList::const_iterator it = executors_.begin();
        it != executors_.end(); ++it) {
     const Executor* executor = *it;
     Job* job = executor->outstanding_job();
     // The "has_user_callback()" is to exclude jobs for which the callback
     // has already been invoked, or was not user-initiated (as in the case of
     // lazy thread provisions). User-initiated jobs may !has_user_callback()
     // when the callback has already been run. (Since we only clear the
     // outstanding job AFTER the callback has been invoked, it is possible
     // for a new request to be started from within the callback).
     CHECK(!job || job->was_cancelled() || !job->has_user_callback());
   }
 }

 void MultiThreadedProxyResolver::ReleaseAllExecutors() {
   DCHECK(CalledOnValidThread());
   for (ExecutorList::iterator it = executors_.begin();
        it != executors_.end(); ++it) {
     Executor* executor = *it;
     executor->Destroy();
   }
   executors_.clear();
 }

 MultiThreadedProxyResolver::Executor*
 MultiThreadedProxyResolver::FindIdleExecutor() {
   DCHECK(CalledOnValidThread());
   for (ExecutorList::iterator it = executors_.begin();
        it != executors_.end(); ++it) {
     Executor* executor = *it;
     if (!executor->outstanding_job())
       return executor;
   }
   return NULL;
 }

 MultiThreadedProxyResolver::Executor*
 MultiThreadedProxyResolver::AddNewExecutor() {
   DCHECK(CalledOnValidThread());
   DCHECK_LT(executors_.size(), max_num_threads_);
   // The "thread number" is used to give the thread a unique name.
   int thread_number = executors_.size();
   ProxyResolver* resolver = resolver_factory_->CreateProxyResolver();
   Executor* executor = new Executor(
       this, resolver, thread_number);
   executors_.push_back(make_scoped_refptr(executor));
   return executor;
 }

 void MultiThreadedProxyResolver::OnExecutorReady(Executor* executor) {
   DCHECK(CalledOnValidThread());
   if (pending_jobs_.empty())
     return;

   // Get the next job to process (FIFO). Transfer it from the pending queue
   // to the executor.
   scoped_refptr<Job> job = pending_jobs_.front();
   pending_jobs_.pop_front();
   executor->StartJob(job);
 }

 }  // namespace net
	// Copyright (c) 2010 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/proxy/multi_threaded_proxy_resolver.h"

	#include "base/message_loop.h"
	#include "base/string_util.h"
	#include "base/stringprintf.h"
	#include "base/threading/thread.h"
	#include "base/threading/thread_restrictions.h"
	#include "net/base/net_errors.h"
	#include "net/base/net_log.h"
	#include "net/proxy/proxy_info.h"

	// TODO(eroman): Have the MultiThreadedProxyResolver clear its PAC script
	// data when SetPacScript fails. That will reclaim memory when
	// testing bogus scripts.

	namespace net {

	namespace {

	class PurgeMemoryTask : public base::RefCountedThreadSafe<PurgeMemoryTask> {
	public:
	explicit PurgeMemoryTask(ProxyResolver* resolver) : resolver_(resolver) {}
	void PurgeMemory() { resolver_->PurgeMemory(); }
	private:
	friend class base::RefCountedThreadSafe<PurgeMemoryTask>;
	~PurgeMemoryTask() {}
	ProxyResolver* resolver_;
	};

	} // namespace

	// An "executor" is a job-runner for PAC requests. It encapsulates a worker
	// thread and a synchronous ProxyResolver (which will be operated on said
	// thread.)
	class MultiThreadedProxyResolver::Executor
	: public base::RefCountedThreadSafe<MultiThreadedProxyResolver::Executor > {
	public:
	// \|coordinator\| must remain valid throughout our lifetime. It is used to
	// signal when the executor is ready to receive work by calling
	// \|coordinator->OnExecutorReady()\|.
	// The constructor takes ownership of \|resolver\|.
	// \|thread_number\| is an identifier used when naming the worker thread.
	Executor(MultiThreadedProxyResolver* coordinator,
	ProxyResolver* resolver,
	int thread_number);

	// Submit a job to this executor.
	void StartJob(Job* job);

	// Callback for when a job has completed running on the executor's thread.
	void OnJobCompleted(Job* job);

	// Cleanup the executor. Cancels all outstanding work, and frees the thread
	// and resolver.
	void Destroy();

	void PurgeMemory();

	// Returns the outstanding job, or NULL.
	Job* outstanding_job() const { return outstanding_job_.get(); }

	ProxyResolver* resolver() { return resolver_.get(); }

	int thread_number() const { return thread_number_; }

	private:
	friend class base::RefCountedThreadSafe<Executor>;
	~Executor();

	MultiThreadedProxyResolver* coordinator_;
	const int thread_number_;

	// The currently active job for this executor (either a SetPacScript or
	// GetProxyForURL task).
	scoped_refptr<Job> outstanding_job_;

	// The synchronous resolver implementation.
	scoped_ptr<ProxyResolver> resolver_;

	// The thread where \|resolver_\| is run on.
	// Note that declaration ordering is important here. \|thread_\| needs to be
	// destroyed before \|resolver_\|, in case \|resolver_\| is currently
	// executing on \|thread_\|.
	scoped_ptr<base::Thread> thread_;
	};

	// MultiThreadedProxyResolver::Job ---------------------------------------------

	class MultiThreadedProxyResolver::Job
	: public base::RefCountedThreadSafe<MultiThreadedProxyResolver::Job> {
	public:
	// Identifies the subclass of Job (only being used for debugging purposes).
	enum Type {
	TYPE_GET_PROXY_FOR_URL,
	TYPE_SET_PAC_SCRIPT,
	TYPE_SET_PAC_SCRIPT_INTERNAL,
	};

	Job(Type type, CompletionCallback* user_callback)
	: type_(type),
	user_callback_(user_callback),
	executor_(NULL),
	was_cancelled_(false) {
	}

	void set_executor(Executor* executor) {
	executor_ = executor;
	}

	// The "executor" is the job runner that is scheduling this job. If
	// this job has not been submitted to an executor yet, this will be
	// NULL (and we know it hasn't started yet).
	Executor* executor() {
	return executor_;
	}

	// Mark the job as having been cancelled.
	void Cancel() {
	was_cancelled_ = true;
	}

	// Returns true if Cancel() has been called.
	bool was_cancelled() const { return was_cancelled_; }

	Type type() const { return type_; }

	// Returns true if this job still has a user callback. Some jobs
	// do not have a user callback, because they were helper jobs
	// scheduled internally (for example TYPE_SET_PAC_SCRIPT_INTERNAL).
	//
	// Otherwise jobs that correspond with user-initiated work will
	// have a non-NULL callback up until the callback is run.
	bool has_user_callback() const { return user_callback_ != NULL; }

	// This method is called when the job is inserted into a wait queue
	// because no executors were ready to accept it.
	virtual void WaitingForThread() {}

	// This method is called just before the job is posted to the work thread.
	virtual void FinishedWaitingForThread() {}

	// This method is called on the worker thread to do the job's work. On
	// completion, implementors are expected to call OnJobCompleted() on
	// \|origin_loop\|.
	virtual void Run(MessageLoop* origin_loop) = 0;

	protected:
	void OnJobCompleted() {
	// \|executor_\| will be NULL if the executor has already been deleted.
	if (executor_)
	executor_->OnJobCompleted(this);
	}

	void RunUserCallback(int result) {
	DCHECK(has_user_callback());
	CompletionCallback* callback = user_callback_;
	// Null the callback so has_user_callback() will now return false.
	user_callback_ = NULL;
	callback->Run(result);
	}

	friend class base::RefCountedThreadSafe<MultiThreadedProxyResolver::Job>;

	virtual ~Job() {}

	private:
	const Type type_;
	CompletionCallback* user_callback_;
	Executor* executor_;
	bool was_cancelled_;
	};

	// MultiThreadedProxyResolver::SetPacScriptJob ---------------------------------

	// Runs on the worker thread to call ProxyResolver::SetPacScript.
	class MultiThreadedProxyResolver::SetPacScriptJob
	: public MultiThreadedProxyResolver::Job {
	public:
	SetPacScriptJob(const scoped_refptr<ProxyResolverScriptData>& script_data,
	CompletionCallback* callback)
	: Job(callback ? TYPE_SET_PAC_SCRIPT : TYPE_SET_PAC_SCRIPT_INTERNAL,
	callback),
	script_data_(script_data) {
	}

	// Runs on the worker thread.
	virtual void Run(MessageLoop* origin_loop) {
	ProxyResolver* resolver = executor()->resolver();
	int rv = resolver->SetPacScript(script_data_, NULL);

	DCHECK_NE(rv, ERR_IO_PENDING);
	origin_loop->PostTask(
	FROM_HERE,
	NewRunnableMethod(this, &SetPacScriptJob::RequestComplete, rv));
	}

	private:
	// Runs the completion callback on the origin thread.
	void RequestComplete(int result_code) {
	// The task may have been cancelled after it was started.
	if (!was_cancelled() && has_user_callback()) {
	RunUserCallback(result_code);
	}
	OnJobCompleted();
	}

	const scoped_refptr<ProxyResolverScriptData> script_data_;
	};

	// MultiThreadedProxyResolver::GetProxyForURLJob ------------------------------

	class MultiThreadedProxyResolver::GetProxyForURLJob
	: public MultiThreadedProxyResolver::Job {
	public:
	// \|url\| -- the URL of the query.
	// \|results\| -- the structure to fill with proxy resolve results.
	GetProxyForURLJob(const GURL& url,
	ProxyInfo* results,
	CompletionCallback* callback,
	const BoundNetLog& net_log)
	: Job(TYPE_GET_PROXY_FOR_URL, callback),
	results_(results),
	net_log_(net_log),
	url_(url),
	was_waiting_for_thread_(false) {
	DCHECK(callback);
	}

	BoundNetLog* net_log() { return &net_log_; }

	virtual void WaitingForThread() {
	was_waiting_for_thread_ = true;
	net_log_.BeginEvent(
	NetLog::TYPE_WAITING_FOR_PROXY_RESOLVER_THREAD, NULL);
	}

	virtual void FinishedWaitingForThread() {
	DCHECK(executor());

	if (was_waiting_for_thread_) {
	net_log_.EndEvent(
	NetLog::TYPE_WAITING_FOR_PROXY_RESOLVER_THREAD, NULL);
	}

	net_log_.AddEvent(
	NetLog::TYPE_SUBMITTED_TO_RESOLVER_THREAD,
	make_scoped_refptr(new NetLogIntegerParameter(
	"thread_number", executor()->thread_number())));
	}

	// Runs on the worker thread.
	virtual void Run(MessageLoop* origin_loop) {
	ProxyResolver* resolver = executor()->resolver();
	int rv = resolver->GetProxyForURL(
	url_, &results_buf_, NULL, NULL, net_log_);
	DCHECK_NE(rv, ERR_IO_PENDING);

	origin_loop->PostTask(
	FROM_HERE,
	NewRunnableMethod(this, &GetProxyForURLJob::QueryComplete, rv));
	}

	private:
	// Runs the completion callback on the origin thread.
	void QueryComplete(int result_code) {
	// The Job may have been cancelled after it was started.
	if (!was_cancelled()) {
	if (result_code >= OK) { // Note: unit-tests use values > 0.
	results_->Use(results_buf_);
	}
	RunUserCallback(result_code);
	}
	OnJobCompleted();
	}

	// Must only be used on the "origin" thread.
	ProxyInfo* results_;

	// Can be used on either "origin" or worker thread.
	BoundNetLog net_log_;
	const GURL url_;

	// Usable from within DoQuery on the worker thread.
	ProxyInfo results_buf_;

	bool was_waiting_for_thread_;
	};

	// MultiThreadedProxyResolver::Executor ----------------------------------------

	MultiThreadedProxyResolver::Executor::Executor(
	MultiThreadedProxyResolver* coordinator,
	ProxyResolver* resolver,
	int thread_number)
	: coordinator_(coordinator),
	thread_number_(thread_number),
	resolver_(resolver) {
	DCHECK(coordinator);
	DCHECK(resolver);
	// Start up the thread.
	// Note that it is safe to pass a temporary C-String to Thread(), as it will
	// make a copy.
	std::string thread_name =
	base::StringPrintf("PAC thread #%d", thread_number);
	thread_.reset(new base::Thread(thread_name.c_str()));
	CHECK(thread_->Start());
	}

	void MultiThreadedProxyResolver::Executor::StartJob(Job* job) {
	DCHECK(!outstanding_job_);
	outstanding_job_ = job;

	// Run the job. Once it has completed (regardless of whether it was
	// cancelled), it will invoke OnJobCompleted() on this thread.
	job->set_executor(this);
	job->FinishedWaitingForThread();
	thread_->message_loop()->PostTask(
	FROM_HERE,
	NewRunnableMethod(job, &Job::Run, MessageLoop::current()));
	}

	void MultiThreadedProxyResolver::Executor::OnJobCompleted(Job* job) {
	DCHECK_EQ(job, outstanding_job_.get());
	outstanding_job_ = NULL;
	coordinator_->OnExecutorReady(this);
	}

	void MultiThreadedProxyResolver::Executor::Destroy() {
	DCHECK(coordinator_);

	// Give the resolver an opportunity to shutdown from THIS THREAD before
	// joining on the resolver thread. This allows certain implementations
	// to avoid deadlocks.
	resolver_->Shutdown();

	{
	// See http://crbug.com/69710.
	base::ThreadRestrictions::ScopedAllowIO allow_io;

	// Join the worker thread.
	thread_.reset();
	}

	// Cancel any outstanding job.
	if (outstanding_job_) {
	outstanding_job_->Cancel();
	// Orphan the job (since this executor may be deleted soon).
	outstanding_job_->set_executor(NULL);
	}

	// It is now safe to free the ProxyResolver, since all the tasks that
	// were using it on the resolver thread have completed.
	resolver_.reset();

	// Null some stuff as a precaution.
	coordinator_ = NULL;
	outstanding_job_ = NULL;
	}

	void MultiThreadedProxyResolver::Executor::PurgeMemory() {
	scoped_refptr<PurgeMemoryTask> helper(new PurgeMemoryTask(resolver_.get()));
	thread_->message_loop()->PostTask(
	FROM_HERE,
	NewRunnableMethod(helper.get(), &PurgeMemoryTask::PurgeMemory));
	}

	MultiThreadedProxyResolver::Executor::~Executor() {
	// The important cleanup happens as part of Destroy(), which should always be
	// called first.
	DCHECK(!coordinator_) << "Destroy() was not called";
	DCHECK(!thread_.get());
	DCHECK(!resolver_.get());
	DCHECK(!outstanding_job_);
	}

	// MultiThreadedProxyResolver --------------------------------------------------

	MultiThreadedProxyResolver::MultiThreadedProxyResolver(
	ProxyResolverFactory* resolver_factory,
	size_t max_num_threads)
	: ProxyResolver(resolver_factory->resolvers_expect_pac_bytes()),
	resolver_factory_(resolver_factory),
	max_num_threads_(max_num_threads) {
	DCHECK_GE(max_num_threads, 1u);
	}

	MultiThreadedProxyResolver::~MultiThreadedProxyResolver() {
	// We will cancel all outstanding requests.
	pending_jobs_.clear();
	ReleaseAllExecutors();
	}

	int MultiThreadedProxyResolver::GetProxyForURL(const GURL& url,
	ProxyInfo* results,
	CompletionCallback* callback,
	RequestHandle* request,
	const BoundNetLog& net_log) {
	DCHECK(CalledOnValidThread());
	DCHECK(callback);
	DCHECK(current_script_data_.get())
	<< "Resolver is un-initialized. Must call SetPacScript() first!";

	scoped_refptr<GetProxyForURLJob> job(
	new GetProxyForURLJob(url, results, callback, net_log));

	// Completion will be notified through \|callback\|, unless the caller cancels
	// the request using \|request\|.
	if (request)
	*request = reinterpret_cast<RequestHandle>(job.get());

	// If there is an executor that is ready to run this request, submit it!
	Executor* executor = FindIdleExecutor();
	if (executor) {
	DCHECK_EQ(0u, pending_jobs_.size());
	executor->StartJob(job);
	return ERR_IO_PENDING;
	}

	// Otherwise queue this request. (We will schedule it to a thread once one
	// becomes available).
	job->WaitingForThread();
	pending_jobs_.push_back(job);

	// If we haven't already reached the thread limit, provision a new thread to
	// drain the requests more quickly.
	if (executors_.size() < max_num_threads_) {
	executor = AddNewExecutor();
	executor->StartJob(
	new SetPacScriptJob(current_script_data_, NULL));
	}

	return ERR_IO_PENDING;
	}

	void MultiThreadedProxyResolver::CancelRequest(RequestHandle req) {
	DCHECK(CalledOnValidThread());
	DCHECK(req);

	Job* job = reinterpret_cast<Job*>(req);
	DCHECK_EQ(Job::TYPE_GET_PROXY_FOR_URL, job->type());

	if (job->executor()) {
	// If the job was already submitted to the executor, just mark it
	// as cancelled so the user callback isn't run on completion.
	job->Cancel();
	} else {
	// Otherwise the job is just sitting in a queue.
	PendingJobsQueue::iterator it =
	std::find(pending_jobs_.begin(), pending_jobs_.end(), job);
	DCHECK(it != pending_jobs_.end());
	pending_jobs_.erase(it);
	}
	}

	void MultiThreadedProxyResolver::CancelSetPacScript() {
	DCHECK(CalledOnValidThread());
	DCHECK_EQ(0u, pending_jobs_.size());
	DCHECK_EQ(1u, executors_.size());
	DCHECK_EQ(Job::TYPE_SET_PAC_SCRIPT,
	executors_[0]->outstanding_job()->type());

	// Defensively clear some data which shouldn't be getting used
	// anymore.
	current_script_data_ = NULL;

	ReleaseAllExecutors();
	}

	void MultiThreadedProxyResolver::PurgeMemory() {
	DCHECK(CalledOnValidThread());
	for (ExecutorList::iterator it = executors_.begin();
	it != executors_.end(); ++it) {
	Executor* executor = *it;
	executor->PurgeMemory();
	}
	}

	int MultiThreadedProxyResolver::SetPacScript(
	const scoped_refptr<ProxyResolverScriptData>& script_data,
	CompletionCallback* callback) {
	DCHECK(CalledOnValidThread());
	DCHECK(callback);

	// Save the script details, so we can provision new executors later.
	current_script_data_ = script_data;

	// The user should not have any outstanding requests when they call
	// SetPacScript().
	CheckNoOutstandingUserRequests();

	// Destroy all of the current threads and their proxy resolvers.
	ReleaseAllExecutors();

	// Provision a new executor, and run the SetPacScript request. On completion
	// notification will be sent through \|callback\|.
	Executor* executor = AddNewExecutor();
	executor->StartJob(new SetPacScriptJob(script_data, callback));
	return ERR_IO_PENDING;
	}

	void MultiThreadedProxyResolver::CheckNoOutstandingUserRequests() const {
	DCHECK(CalledOnValidThread());
	CHECK_EQ(0u, pending_jobs_.size());

	for (ExecutorList::const_iterator it = executors_.begin();
	it != executors_.end(); ++it) {
	const Executor* executor = *it;
	Job* job = executor->outstanding_job();
	// The "has_user_callback()" is to exclude jobs for which the callback
	// has already been invoked, or was not user-initiated (as in the case of
	// lazy thread provisions). User-initiated jobs may !has_user_callback()
	// when the callback has already been run. (Since we only clear the
	// outstanding job AFTER the callback has been invoked, it is possible
	// for a new request to be started from within the callback).
	CHECK(!job \|\| job->was_cancelled() \|\| !job->has_user_callback());
	}
	}

	void MultiThreadedProxyResolver::ReleaseAllExecutors() {
	DCHECK(CalledOnValidThread());
	for (ExecutorList::iterator it = executors_.begin();
	it != executors_.end(); ++it) {
	Executor* executor = *it;
	executor->Destroy();
	}
	executors_.clear();
	}

	MultiThreadedProxyResolver::Executor*
	MultiThreadedProxyResolver::FindIdleExecutor() {
	DCHECK(CalledOnValidThread());
	for (ExecutorList::iterator it = executors_.begin();
	it != executors_.end(); ++it) {
	Executor* executor = *it;
	if (!executor->outstanding_job())
	return executor;
	}
	return NULL;
	}

	MultiThreadedProxyResolver::Executor*
	MultiThreadedProxyResolver::AddNewExecutor() {
	DCHECK(CalledOnValidThread());
	DCHECK_LT(executors_.size(), max_num_threads_);
	// The "thread number" is used to give the thread a unique name.
	int thread_number = executors_.size();
	ProxyResolver* resolver = resolver_factory_->CreateProxyResolver();
	Executor* executor = new Executor(
	this, resolver, thread_number);
	executors_.push_back(make_scoped_refptr(executor));
	return executor;
	}

	void MultiThreadedProxyResolver::OnExecutorReady(Executor* executor) {
	DCHECK(CalledOnValidThread());
	if (pending_jobs_.empty())
	return;

	// Get the next job to process (FIFO). Transfer it from the pending queue
	// to the executor.
	scoped_refptr<Job> job = pending_jobs_.front();
	pending_jobs_.pop_front();
	executor->StartJob(job);
	}

	} // namespace net