mojo/system/core.cc - platform/external/chromium_org - 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.

 #include "mojo/system/core.h"

 #include <vector>

 #include "base/logging.h"
 #include "base/time/time.h"
 #include "mojo/public/c/system/macros.h"
 #include "mojo/system/constants.h"
 #include "mojo/system/data_pipe.h"
 #include "mojo/system/data_pipe_consumer_dispatcher.h"
 #include "mojo/system/data_pipe_producer_dispatcher.h"
 #include "mojo/system/dispatcher.h"
 #include "mojo/system/local_data_pipe.h"
 #include "mojo/system/memory.h"
 #include "mojo/system/message_pipe.h"
 #include "mojo/system/message_pipe_dispatcher.h"
 #include "mojo/system/raw_shared_buffer.h"
 #include "mojo/system/shared_buffer_dispatcher.h"
 #include "mojo/system/waiter.h"

 namespace mojo {
 namespace system {

 // Implementation notes
 //
 // Mojo primitives are implemented by the singleton |Core| object. Most calls
 // are for a "primary" handle (the first argument). |Core::GetDispatcher()| is
 // used to look up a |Dispatcher| object for a given handle. That object
 // implements most primitives for that object. The wait primitives are not
 // attached to objects and are implemented by |Core| itself.
 //
 // Some objects have multiple handles associated to them, e.g., message pipes
 // (which have two). In such a case, there is still a |Dispatcher| (e.g.,
 // |MessagePipeDispatcher|) for each handle, with each handle having a strong
 // reference to the common "secondary" object (e.g., |MessagePipe|). This
 // secondary object does NOT have any references to the |Dispatcher|s (even if
 // it did, it wouldn't be able to do anything with them due to lock order
 // requirements -- see below).
 //
 // Waiting is implemented by having the thread that wants to wait call the
 // |Dispatcher|s for the handles that it wants to wait on with a |Waiter|
 // object; this |Waiter| object may be created on the stack of that thread or be
 // kept in thread local storage for that thread (TODO(vtl): future improvement).
 // The |Dispatcher| then adds the |Waiter| to a |WaiterList| that's either owned
 // by that |Dispatcher| (see |SimpleDispatcher|) or by a secondary object (e.g.,
 // |MessagePipe|). To signal/wake a |Waiter|, the object in question -- either a
 // |SimpleDispatcher| or a secondary object -- talks to its |WaiterList|.

 // Thread-safety notes
 //
 // Mojo primitives calls are thread-safe. We achieve this with relatively
 // fine-grained locking. There is a global handle table lock. This lock should
 // be held as briefly as possible (TODO(vtl): a future improvement would be to
 // switch it to a reader-writer lock). Each |Dispatcher| object then has a lock
 // (which subclasses can use to protect their data).
 //
 // The lock ordering is as follows:
 //   1. global handle table lock, global mapping table lock
 //   2. |Dispatcher| locks
 //   3. secondary object locks
 //   ...
 //   INF. |Waiter| locks
 //
 // Notes:
 //    - While holding a |Dispatcher| lock, you may not unconditionally attempt
 //      to take another |Dispatcher| lock. (This has consequences on the
 //      concurrency semantics of |MojoWriteMessage()| when passing handles.)
 //      Doing so would lead to deadlock.
 //    - Locks at the "INF" level may not have any locks taken while they are
 //      held.

 Core::Core() {
 }

 Core::~Core() {
 }

 MojoHandle Core::AddDispatcher(
     const scoped_refptr<Dispatcher>& dispatcher) {
   base::AutoLock locker(handle_table_lock_);
   return handle_table_.AddDispatcher(dispatcher);
 }

 scoped_refptr<Dispatcher> Core::GetDispatcher(MojoHandle handle) {
   if (handle == MOJO_HANDLE_INVALID)
     return NULL;

   base::AutoLock locker(handle_table_lock_);
   return handle_table_.GetDispatcher(handle);
 }

 MojoTimeTicks Core::GetTimeTicksNow() {
   return base::TimeTicks::Now().ToInternalValue();
 }

 MojoResult Core::Close(MojoHandle handle) {
   if (handle == MOJO_HANDLE_INVALID)
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_refptr<Dispatcher> dispatcher;
   {
     base::AutoLock locker(handle_table_lock_);
     MojoResult result = handle_table_.GetAndRemoveDispatcher(handle,
                                                              &dispatcher);
     if (result != MOJO_RESULT_OK)
       return result;
   }

   // The dispatcher doesn't have a say in being closed, but gets notified of it.
   // Note: This is done outside of |handle_table_lock_|. As a result, there's a
   // race condition that the dispatcher must handle; see the comment in
   // |Dispatcher| in dispatcher.h.
   return dispatcher->Close();
 }

 MojoResult Core::Wait(MojoHandle handle,
                       MojoHandleSignals signals,
                       MojoDeadline deadline) {
   return WaitManyInternal(&handle, &signals, 1, deadline);
 }

 MojoResult Core::WaitMany(const MojoHandle* handles,
                           const MojoHandleSignals* signals,
                           uint32_t num_handles,
                           MojoDeadline deadline) {
   if (!VerifyUserPointerWithCount<MojoHandle>(handles, num_handles))
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (!VerifyUserPointerWithCount<MojoHandleSignals>(signals, num_handles))
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (num_handles < 1)
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (num_handles > kMaxWaitManyNumHandles)
     return MOJO_RESULT_RESOURCE_EXHAUSTED;
   return WaitManyInternal(handles, signals, num_handles, deadline);
 }

 MojoResult Core::CreateMessagePipe(const MojoCreateMessagePipeOptions* options,
                                    MojoHandle* message_pipe_handle0,
                                    MojoHandle* message_pipe_handle1) {
   MojoCreateMessagePipeOptions validated_options = {};
   // This will verify the |options| pointer.
   MojoResult result = MessagePipeDispatcher::ValidateCreateOptions(
       options, &validated_options);
   if (result != MOJO_RESULT_OK)
     return result;
   if (!VerifyUserPointer<MojoHandle>(message_pipe_handle0))
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (!VerifyUserPointer<MojoHandle>(message_pipe_handle1))
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_refptr<MessagePipeDispatcher> dispatcher0(
       new MessagePipeDispatcher(validated_options));
   scoped_refptr<MessagePipeDispatcher> dispatcher1(
       new MessagePipeDispatcher(validated_options));

   std::pair<MojoHandle, MojoHandle> handle_pair;
   {
     base::AutoLock locker(handle_table_lock_);
     handle_pair = handle_table_.AddDispatcherPair(dispatcher0, dispatcher1);
   }
   if (handle_pair.first == MOJO_HANDLE_INVALID) {
     DCHECK_EQ(handle_pair.second, MOJO_HANDLE_INVALID);
     LOG(ERROR) << "Handle table full";
     dispatcher0->Close();
     dispatcher1->Close();
     return MOJO_RESULT_RESOURCE_EXHAUSTED;
   }

   scoped_refptr<MessagePipe> message_pipe(new MessagePipe());
   dispatcher0->Init(message_pipe, 0);
   dispatcher1->Init(message_pipe, 1);

   *message_pipe_handle0 = handle_pair.first;
   *message_pipe_handle1 = handle_pair.second;
   return MOJO_RESULT_OK;
 }

 // Implementation note: To properly cancel waiters and avoid other races, this
 // does not transfer dispatchers from one handle to another, even when sending a
 // message in-process. Instead, it must transfer the "contents" of the
 // dispatcher to a new dispatcher, and then close the old dispatcher. If this
 // isn't done, in the in-process case, calls on the old handle may complete
 // after the the message has been received and a new handle created (and
 // possibly even after calls have been made on the new handle).
 MojoResult Core::WriteMessage(MojoHandle message_pipe_handle,
                               const void* bytes,
                               uint32_t num_bytes,
                               const MojoHandle* handles,
                               uint32_t num_handles,
                               MojoWriteMessageFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(GetDispatcher(message_pipe_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   // Easy case: not sending any handles.
   if (num_handles == 0)
     return dispatcher->WriteMessage(bytes, num_bytes, NULL, flags);

   // We have to handle |handles| here, since we have to mark them busy in the
   // global handle table. We can't delegate this to the dispatcher, since the
   // handle table lock must be acquired before the dispatcher lock.
   //
   // (This leads to an oddity: |handles|/|num_handles| are always verified for
   // validity, even for dispatchers that don't support |WriteMessage()| and will
   // simply return failure unconditionally. It also breaks the usual
   // left-to-right verification order of arguments.)
   if (!VerifyUserPointerWithCount<MojoHandle>(handles, num_handles))
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (num_handles > kMaxMessageNumHandles)
     return MOJO_RESULT_RESOURCE_EXHAUSTED;

   // We'll need to hold on to the dispatchers so that we can pass them on to
   // |WriteMessage()| and also so that we can unlock their locks afterwards
   // without accessing the handle table. These can be dumb pointers, since their
   // entries in the handle table won't get removed (since they'll be marked as
   // busy).
   std::vector<DispatcherTransport> transports(num_handles);

   // When we pass handles, we have to try to take all their dispatchers' locks
   // and mark the handles as busy. If the call succeeds, we then remove the
   // handles from the handle table.
   {
     base::AutoLock locker(handle_table_lock_);
     MojoResult result = handle_table_.MarkBusyAndStartTransport(
         message_pipe_handle, handles, num_handles, &transports);
     if (result != MOJO_RESULT_OK)
       return result;
   }

   MojoResult rv = dispatcher->WriteMessage(bytes, num_bytes, &transports,
                                            flags);

   // We need to release the dispatcher locks before we take the handle table
   // lock.
   for (uint32_t i = 0; i < num_handles; i++)
     transports[i].End();

   {
     base::AutoLock locker(handle_table_lock_);
     if (rv == MOJO_RESULT_OK)
       handle_table_.RemoveBusyHandles(handles, num_handles);
     else
       handle_table_.RestoreBusyHandles(handles, num_handles);
   }

   return rv;
 }

 MojoResult Core::ReadMessage(MojoHandle message_pipe_handle,
                              void* bytes,
                              uint32_t* num_bytes,
                              MojoHandle* handles,
                              uint32_t* num_handles,
                              MojoReadMessageFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(GetDispatcher(message_pipe_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   if (num_handles) {
     if (!VerifyUserPointer<uint32_t>(num_handles))
       return MOJO_RESULT_INVALID_ARGUMENT;
     if (!VerifyUserPointerWithCount<MojoHandle>(handles, *num_handles))
       return MOJO_RESULT_INVALID_ARGUMENT;
   }

   // Easy case: won't receive any handles.
   if (!num_handles || *num_handles == 0)
     return dispatcher->ReadMessage(bytes, num_bytes, NULL, num_handles, flags);

   DispatcherVector dispatchers;
   MojoResult rv = dispatcher->ReadMessage(bytes, num_bytes,
                                           &dispatchers, num_handles,
                                           flags);
   if (!dispatchers.empty()) {
     DCHECK_EQ(rv, MOJO_RESULT_OK);
     DCHECK(num_handles);
     DCHECK_LE(dispatchers.size(), static_cast<size_t>(*num_handles));

     bool success;
     {
       base::AutoLock locker(handle_table_lock_);
       success = handle_table_.AddDispatcherVector(dispatchers, handles);
     }
     if (!success) {
       LOG(ERROR) << "Received message with " << dispatchers.size()
                  << " handles, but handle table full";
       // Close dispatchers (outside the lock).
       for (size_t i = 0; i < dispatchers.size(); i++) {
         if (dispatchers[i])
           dispatchers[i]->Close();
       }
     }
   }

   return rv;
 }

 MojoResult Core::CreateDataPipe(const MojoCreateDataPipeOptions* options,
                                 MojoHandle* data_pipe_producer_handle,
                                 MojoHandle* data_pipe_consumer_handle) {
   MojoCreateDataPipeOptions validated_options = {};
   // This will verify the |options| pointer.
   MojoResult result = DataPipe::ValidateCreateOptions(options,
                                                       &validated_options);
   if (result != MOJO_RESULT_OK)
     return result;
   if (!VerifyUserPointer<MojoHandle>(data_pipe_producer_handle))
     return MOJO_RESULT_INVALID_ARGUMENT;
   if (!VerifyUserPointer<MojoHandle>(data_pipe_consumer_handle))
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_refptr<DataPipeProducerDispatcher> producer_dispatcher(
       new DataPipeProducerDispatcher());
   scoped_refptr<DataPipeConsumerDispatcher> consumer_dispatcher(
       new DataPipeConsumerDispatcher());

   std::pair<MojoHandle, MojoHandle> handle_pair;
   {
     base::AutoLock locker(handle_table_lock_);
     handle_pair = handle_table_.AddDispatcherPair(producer_dispatcher,
                                                   consumer_dispatcher);
   }
   if (handle_pair.first == MOJO_HANDLE_INVALID) {
     DCHECK_EQ(handle_pair.second, MOJO_HANDLE_INVALID);
     LOG(ERROR) << "Handle table full";
     producer_dispatcher->Close();
     consumer_dispatcher->Close();
     return MOJO_RESULT_RESOURCE_EXHAUSTED;
   }
   DCHECK_NE(handle_pair.second, MOJO_HANDLE_INVALID);

   scoped_refptr<DataPipe> data_pipe(new LocalDataPipe(validated_options));
   producer_dispatcher->Init(data_pipe);
   consumer_dispatcher->Init(data_pipe);

   *data_pipe_producer_handle = handle_pair.first;
   *data_pipe_consumer_handle = handle_pair.second;
   return MOJO_RESULT_OK;
 }

 MojoResult Core::WriteData(MojoHandle data_pipe_producer_handle,
                            const void* elements,
                            uint32_t* num_bytes,
                            MojoWriteDataFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_producer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->WriteData(elements, num_bytes, flags);
 }

 MojoResult Core::BeginWriteData(MojoHandle data_pipe_producer_handle,
                                 void** buffer,
                                 uint32_t* buffer_num_bytes,
                                 MojoWriteDataFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_producer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->BeginWriteData(buffer, buffer_num_bytes, flags);
 }

 MojoResult Core::EndWriteData(MojoHandle data_pipe_producer_handle,
                               uint32_t num_bytes_written) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_producer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->EndWriteData(num_bytes_written);
 }

 MojoResult Core::ReadData(MojoHandle data_pipe_consumer_handle,
                           void* elements,
                           uint32_t* num_bytes,
                           MojoReadDataFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_consumer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->ReadData(elements, num_bytes, flags);
 }

 MojoResult Core::BeginReadData(MojoHandle data_pipe_consumer_handle,
                                const void** buffer,
                                uint32_t* buffer_num_bytes,
                                MojoReadDataFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_consumer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->BeginReadData(buffer, buffer_num_bytes, flags);
 }

 MojoResult Core::EndReadData(MojoHandle data_pipe_consumer_handle,
                              uint32_t num_bytes_read) {
   scoped_refptr<Dispatcher> dispatcher(
       GetDispatcher(data_pipe_consumer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   return dispatcher->EndReadData(num_bytes_read);
 }

 MojoResult Core::CreateSharedBuffer(
     const MojoCreateSharedBufferOptions* options,
     uint64_t num_bytes,
     MojoHandle* shared_buffer_handle) {
   MojoCreateSharedBufferOptions validated_options = {};
   // This will verify the |options| pointer.
   MojoResult result =
       SharedBufferDispatcher::ValidateCreateOptions(options,
                                                     &validated_options);
   if (result != MOJO_RESULT_OK)
     return result;
   if (!VerifyUserPointer<MojoHandle>(shared_buffer_handle))
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_refptr<SharedBufferDispatcher> dispatcher;
   result = SharedBufferDispatcher::Create(validated_options, num_bytes,
                                           &dispatcher);
   if (result != MOJO_RESULT_OK) {
     DCHECK(!dispatcher);
     return result;
   }

   MojoHandle h = AddDispatcher(dispatcher);
   if (h == MOJO_HANDLE_INVALID) {
     LOG(ERROR) << "Handle table full";
     dispatcher->Close();
     return MOJO_RESULT_RESOURCE_EXHAUSTED;
   }

   *shared_buffer_handle = h;
   return MOJO_RESULT_OK;
 }

 MojoResult Core::DuplicateBufferHandle(
     MojoHandle buffer_handle,
     const MojoDuplicateBufferHandleOptions* options,
     MojoHandle* new_buffer_handle) {
   scoped_refptr<Dispatcher> dispatcher(GetDispatcher(buffer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   // Don't verify |options| here; that's the dispatcher's job.
   if (!VerifyUserPointer<MojoHandle>(new_buffer_handle))
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_refptr<Dispatcher> new_dispatcher;
   MojoResult result = dispatcher->DuplicateBufferHandle(options,
                                                         &new_dispatcher);
   if (result != MOJO_RESULT_OK)
     return result;

   MojoHandle new_handle = AddDispatcher(new_dispatcher);
   if (new_handle == MOJO_HANDLE_INVALID) {
     LOG(ERROR) << "Handle table full";
     dispatcher->Close();
     return MOJO_RESULT_RESOURCE_EXHAUSTED;
   }

   *new_buffer_handle = new_handle;
   return MOJO_RESULT_OK;
 }

 MojoResult Core::MapBuffer(MojoHandle buffer_handle,
                            uint64_t offset,
                            uint64_t num_bytes,
                            void** buffer,
                            MojoMapBufferFlags flags) {
   scoped_refptr<Dispatcher> dispatcher(GetDispatcher(buffer_handle));
   if (!dispatcher)
     return MOJO_RESULT_INVALID_ARGUMENT;

   if (!VerifyUserPointerWithCount<void*>(buffer, 1))
     return MOJO_RESULT_INVALID_ARGUMENT;

   scoped_ptr<RawSharedBufferMapping> mapping;
   MojoResult result = dispatcher->MapBuffer(offset, num_bytes, flags, &mapping);
   if (result != MOJO_RESULT_OK)
     return result;

   DCHECK(mapping);
   void* address = mapping->base();
   {
     base::AutoLock locker(mapping_table_lock_);
     result = mapping_table_.AddMapping(mapping.Pass());
   }
   if (result != MOJO_RESULT_OK)
     return result;

   *buffer = address;
   return MOJO_RESULT_OK;
 }

 MojoResult Core::UnmapBuffer(void* buffer) {
   base::AutoLock locker(mapping_table_lock_);
   return mapping_table_.RemoveMapping(buffer);
 }

 // Note: We allow |handles| to repeat the same handle multiple times, since
 // different flags may be specified.
 // TODO(vtl): This incurs a performance cost in |RemoveWaiter()|. Analyze this
 // more carefully and address it if necessary.
 MojoResult Core::WaitManyInternal(const MojoHandle* handles,
                                   const MojoHandleSignals* signals,
                                   uint32_t num_handles,
                                   MojoDeadline deadline) {
   DCHECK_GT(num_handles, 0u);

   DispatcherVector dispatchers;
   dispatchers.reserve(num_handles);
   for (uint32_t i = 0; i < num_handles; i++) {
     scoped_refptr<Dispatcher> dispatcher = GetDispatcher(handles[i]);
     if (!dispatcher)
       return MOJO_RESULT_INVALID_ARGUMENT;
     dispatchers.push_back(dispatcher);
   }

   // TODO(vtl): Should make the waiter live (permanently) in TLS.
   Waiter waiter;
   waiter.Init();

   uint32_t i;
   MojoResult rv = MOJO_RESULT_OK;
   for (i = 0; i < num_handles; i++) {
     rv = dispatchers[i]->AddWaiter(&waiter, signals[i], i);
     if (rv != MOJO_RESULT_OK)
       break;
   }
   uint32_t num_added = i;

   if (rv == MOJO_RESULT_ALREADY_EXISTS) {
     rv = static_cast<MojoResult>(i);  // The i-th one is already "triggered".
   } else if (rv == MOJO_RESULT_OK) {
     uint32_t context = static_cast<uint32_t>(-1);
     rv = waiter.Wait(deadline, &context);
     if (rv == MOJO_RESULT_OK)
       rv = static_cast<MojoResult>(context);
   }

   // Make sure no other dispatchers try to wake |waiter| for the current
   // |Wait()|/|WaitMany()| call. (Only after doing this can |waiter| be
   // destroyed, but this would still be required if the waiter were in TLS.)
   for (i = 0; i < num_added; i++)
     dispatchers[i]->RemoveWaiter(&waiter);

   return rv;
 }

 }  // namespace system
 }  // namespace mojo
	// 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.

	#include "mojo/system/core.h"

	#include <vector>

	#include "base/logging.h"
	#include "base/time/time.h"
	#include "mojo/public/c/system/macros.h"
	#include "mojo/system/constants.h"
	#include "mojo/system/data_pipe.h"
	#include "mojo/system/data_pipe_consumer_dispatcher.h"
	#include "mojo/system/data_pipe_producer_dispatcher.h"
	#include "mojo/system/dispatcher.h"
	#include "mojo/system/local_data_pipe.h"
	#include "mojo/system/memory.h"
	#include "mojo/system/message_pipe.h"
	#include "mojo/system/message_pipe_dispatcher.h"
	#include "mojo/system/raw_shared_buffer.h"
	#include "mojo/system/shared_buffer_dispatcher.h"
	#include "mojo/system/waiter.h"

	namespace mojo {
	namespace system {

	// Implementation notes
	//
	// Mojo primitives are implemented by the singleton \|Core\| object. Most calls
	// are for a "primary" handle (the first argument). \|Core::GetDispatcher()\| is
	// used to look up a \|Dispatcher\| object for a given handle. That object
	// implements most primitives for that object. The wait primitives are not
	// attached to objects and are implemented by \|Core\| itself.
	//
	// Some objects have multiple handles associated to them, e.g., message pipes
	// (which have two). In such a case, there is still a \|Dispatcher\| (e.g.,
	// \|MessagePipeDispatcher\|) for each handle, with each handle having a strong
	// reference to the common "secondary" object (e.g., \|MessagePipe\|). This
	// secondary object does NOT have any references to the \|Dispatcher\|s (even if
	// it did, it wouldn't be able to do anything with them due to lock order
	// requirements -- see below).
	//
	// Waiting is implemented by having the thread that wants to wait call the
	// \|Dispatcher\|s for the handles that it wants to wait on with a \|Waiter\|
	// object; this \|Waiter\| object may be created on the stack of that thread or be
	// kept in thread local storage for that thread (TODO(vtl): future improvement).
	// The \|Dispatcher\| then adds the \|Waiter\| to a \|WaiterList\| that's either owned
	// by that \|Dispatcher\| (see \|SimpleDispatcher\|) or by a secondary object (e.g.,
	// \|MessagePipe\|). To signal/wake a \|Waiter\|, the object in question -- either a
	// \|SimpleDispatcher\| or a secondary object -- talks to its \|WaiterList\|.

	// Thread-safety notes
	//
	// Mojo primitives calls are thread-safe. We achieve this with relatively
	// fine-grained locking. There is a global handle table lock. This lock should
	// be held as briefly as possible (TODO(vtl): a future improvement would be to
	// switch it to a reader-writer lock). Each \|Dispatcher\| object then has a lock
	// (which subclasses can use to protect their data).
	//
	// The lock ordering is as follows:
	// 1. global handle table lock, global mapping table lock
	// 2. \|Dispatcher\| locks
	// 3. secondary object locks
	// ...
	// INF. \|Waiter\| locks
	//
	// Notes:
	// - While holding a \|Dispatcher\| lock, you may not unconditionally attempt
	// to take another \|Dispatcher\| lock. (This has consequences on the
	// concurrency semantics of \|MojoWriteMessage()\| when passing handles.)
	// Doing so would lead to deadlock.
	// - Locks at the "INF" level may not have any locks taken while they are
	// held.

	Core::Core() {
	}

	Core::~Core() {
	}

	MojoHandle Core::AddDispatcher(
	const scoped_refptr<Dispatcher>& dispatcher) {
	base::AutoLock locker(handle_table_lock_);
	return handle_table_.AddDispatcher(dispatcher);
	}

	scoped_refptr<Dispatcher> Core::GetDispatcher(MojoHandle handle) {
	if (handle == MOJO_HANDLE_INVALID)
	return NULL;

	base::AutoLock locker(handle_table_lock_);
	return handle_table_.GetDispatcher(handle);
	}

	MojoTimeTicks Core::GetTimeTicksNow() {
	return base::TimeTicks::Now().ToInternalValue();
	}

	MojoResult Core::Close(MojoHandle handle) {
	if (handle == MOJO_HANDLE_INVALID)
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_refptr<Dispatcher> dispatcher;
	{
	base::AutoLock locker(handle_table_lock_);
	MojoResult result = handle_table_.GetAndRemoveDispatcher(handle,
	&dispatcher);
	if (result != MOJO_RESULT_OK)
	return result;
	}

	// The dispatcher doesn't have a say in being closed, but gets notified of it.
	// Note: This is done outside of \|handle_table_lock_\|. As a result, there's a
	// race condition that the dispatcher must handle; see the comment in
	// \|Dispatcher\| in dispatcher.h.
	return dispatcher->Close();
	}

	MojoResult Core::Wait(MojoHandle handle,
	MojoHandleSignals signals,
	MojoDeadline deadline) {
	return WaitManyInternal(&handle, &signals, 1, deadline);
	}

	MojoResult Core::WaitMany(const MojoHandle* handles,
	const MojoHandleSignals* signals,
	uint32_t num_handles,
	MojoDeadline deadline) {
	if (!VerifyUserPointerWithCount<MojoHandle>(handles, num_handles))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (!VerifyUserPointerWithCount<MojoHandleSignals>(signals, num_handles))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (num_handles < 1)
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (num_handles > kMaxWaitManyNumHandles)
	return MOJO_RESULT_RESOURCE_EXHAUSTED;
	return WaitManyInternal(handles, signals, num_handles, deadline);
	}

	MojoResult Core::CreateMessagePipe(const MojoCreateMessagePipeOptions* options,
	MojoHandle* message_pipe_handle0,
	MojoHandle* message_pipe_handle1) {
	MojoCreateMessagePipeOptions validated_options = {};
	// This will verify the \|options\| pointer.
	MojoResult result = MessagePipeDispatcher::ValidateCreateOptions(
	options, &validated_options);
	if (result != MOJO_RESULT_OK)
	return result;
	if (!VerifyUserPointer<MojoHandle>(message_pipe_handle0))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (!VerifyUserPointer<MojoHandle>(message_pipe_handle1))
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_refptr<MessagePipeDispatcher> dispatcher0(
	new MessagePipeDispatcher(validated_options));
	scoped_refptr<MessagePipeDispatcher> dispatcher1(
	new MessagePipeDispatcher(validated_options));

	std::pair<MojoHandle, MojoHandle> handle_pair;
	{
	base::AutoLock locker(handle_table_lock_);
	handle_pair = handle_table_.AddDispatcherPair(dispatcher0, dispatcher1);
	}
	if (handle_pair.first == MOJO_HANDLE_INVALID) {
	DCHECK_EQ(handle_pair.second, MOJO_HANDLE_INVALID);
	LOG(ERROR) << "Handle table full";
	dispatcher0->Close();
	dispatcher1->Close();
	return MOJO_RESULT_RESOURCE_EXHAUSTED;
	}

	scoped_refptr<MessagePipe> message_pipe(new MessagePipe());
	dispatcher0->Init(message_pipe, 0);
	dispatcher1->Init(message_pipe, 1);

	*message_pipe_handle0 = handle_pair.first;
	*message_pipe_handle1 = handle_pair.second;
	return MOJO_RESULT_OK;
	}

	// Implementation note: To properly cancel waiters and avoid other races, this
	// does not transfer dispatchers from one handle to another, even when sending a
	// message in-process. Instead, it must transfer the "contents" of the
	// dispatcher to a new dispatcher, and then close the old dispatcher. If this
	// isn't done, in the in-process case, calls on the old handle may complete
	// after the the message has been received and a new handle created (and
	// possibly even after calls have been made on the new handle).
	MojoResult Core::WriteMessage(MojoHandle message_pipe_handle,
	const void* bytes,
	uint32_t num_bytes,
	const MojoHandle* handles,
	uint32_t num_handles,
	MojoWriteMessageFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(GetDispatcher(message_pipe_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	// Easy case: not sending any handles.
	if (num_handles == 0)
	return dispatcher->WriteMessage(bytes, num_bytes, NULL, flags);

	// We have to handle \|handles\| here, since we have to mark them busy in the
	// global handle table. We can't delegate this to the dispatcher, since the
	// handle table lock must be acquired before the dispatcher lock.
	//
	// (This leads to an oddity: \|handles\|/\|num_handles\| are always verified for
	// validity, even for dispatchers that don't support \|WriteMessage()\| and will
	// simply return failure unconditionally. It also breaks the usual
	// left-to-right verification order of arguments.)
	if (!VerifyUserPointerWithCount<MojoHandle>(handles, num_handles))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (num_handles > kMaxMessageNumHandles)
	return MOJO_RESULT_RESOURCE_EXHAUSTED;

	// We'll need to hold on to the dispatchers so that we can pass them on to
	// \|WriteMessage()\| and also so that we can unlock their locks afterwards
	// without accessing the handle table. These can be dumb pointers, since their
	// entries in the handle table won't get removed (since they'll be marked as
	// busy).
	std::vector<DispatcherTransport> transports(num_handles);

	// When we pass handles, we have to try to take all their dispatchers' locks
	// and mark the handles as busy. If the call succeeds, we then remove the
	// handles from the handle table.
	{
	base::AutoLock locker(handle_table_lock_);
	MojoResult result = handle_table_.MarkBusyAndStartTransport(
	message_pipe_handle, handles, num_handles, &transports);
	if (result != MOJO_RESULT_OK)
	return result;
	}

	MojoResult rv = dispatcher->WriteMessage(bytes, num_bytes, &transports,
	flags);

	// We need to release the dispatcher locks before we take the handle table
	// lock.
	for (uint32_t i = 0; i < num_handles; i++)
	transports[i].End();

	{
	base::AutoLock locker(handle_table_lock_);
	if (rv == MOJO_RESULT_OK)
	handle_table_.RemoveBusyHandles(handles, num_handles);
	else
	handle_table_.RestoreBusyHandles(handles, num_handles);
	}

	return rv;
	}

	MojoResult Core::ReadMessage(MojoHandle message_pipe_handle,
	void* bytes,
	uint32_t* num_bytes,
	MojoHandle* handles,
	uint32_t* num_handles,
	MojoReadMessageFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(GetDispatcher(message_pipe_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	if (num_handles) {
	if (!VerifyUserPointer<uint32_t>(num_handles))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (!VerifyUserPointerWithCount<MojoHandle>(handles, *num_handles))
	return MOJO_RESULT_INVALID_ARGUMENT;
	}

	// Easy case: won't receive any handles.
	if (!num_handles \|\| *num_handles == 0)
	return dispatcher->ReadMessage(bytes, num_bytes, NULL, num_handles, flags);

	DispatcherVector dispatchers;
	MojoResult rv = dispatcher->ReadMessage(bytes, num_bytes,
	&dispatchers, num_handles,
	flags);
	if (!dispatchers.empty()) {
	DCHECK_EQ(rv, MOJO_RESULT_OK);
	DCHECK(num_handles);
	DCHECK_LE(dispatchers.size(), static_cast<size_t>(*num_handles));

	bool success;
	{
	base::AutoLock locker(handle_table_lock_);
	success = handle_table_.AddDispatcherVector(dispatchers, handles);
	}
	if (!success) {
	LOG(ERROR) << "Received message with " << dispatchers.size()
	<< " handles, but handle table full";
	// Close dispatchers (outside the lock).
	for (size_t i = 0; i < dispatchers.size(); i++) {
	if (dispatchers[i])
	dispatchers[i]->Close();
	}
	}
	}

	return rv;
	}

	MojoResult Core::CreateDataPipe(const MojoCreateDataPipeOptions* options,
	MojoHandle* data_pipe_producer_handle,
	MojoHandle* data_pipe_consumer_handle) {
	MojoCreateDataPipeOptions validated_options = {};
	// This will verify the \|options\| pointer.
	MojoResult result = DataPipe::ValidateCreateOptions(options,
	&validated_options);
	if (result != MOJO_RESULT_OK)
	return result;
	if (!VerifyUserPointer<MojoHandle>(data_pipe_producer_handle))
	return MOJO_RESULT_INVALID_ARGUMENT;
	if (!VerifyUserPointer<MojoHandle>(data_pipe_consumer_handle))
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_refptr<DataPipeProducerDispatcher> producer_dispatcher(
	new DataPipeProducerDispatcher());
	scoped_refptr<DataPipeConsumerDispatcher> consumer_dispatcher(
	new DataPipeConsumerDispatcher());

	std::pair<MojoHandle, MojoHandle> handle_pair;
	{
	base::AutoLock locker(handle_table_lock_);
	handle_pair = handle_table_.AddDispatcherPair(producer_dispatcher,
	consumer_dispatcher);
	}
	if (handle_pair.first == MOJO_HANDLE_INVALID) {
	DCHECK_EQ(handle_pair.second, MOJO_HANDLE_INVALID);
	LOG(ERROR) << "Handle table full";
	producer_dispatcher->Close();
	consumer_dispatcher->Close();
	return MOJO_RESULT_RESOURCE_EXHAUSTED;
	}
	DCHECK_NE(handle_pair.second, MOJO_HANDLE_INVALID);

	scoped_refptr<DataPipe> data_pipe(new LocalDataPipe(validated_options));
	producer_dispatcher->Init(data_pipe);
	consumer_dispatcher->Init(data_pipe);

	*data_pipe_producer_handle = handle_pair.first;
	*data_pipe_consumer_handle = handle_pair.second;
	return MOJO_RESULT_OK;
	}

	MojoResult Core::WriteData(MojoHandle data_pipe_producer_handle,
	const void* elements,
	uint32_t* num_bytes,
	MojoWriteDataFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_producer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->WriteData(elements, num_bytes, flags);
	}

	MojoResult Core::BeginWriteData(MojoHandle data_pipe_producer_handle,
	void** buffer,
	uint32_t* buffer_num_bytes,
	MojoWriteDataFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_producer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->BeginWriteData(buffer, buffer_num_bytes, flags);
	}

	MojoResult Core::EndWriteData(MojoHandle data_pipe_producer_handle,
	uint32_t num_bytes_written) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_producer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->EndWriteData(num_bytes_written);
	}

	MojoResult Core::ReadData(MojoHandle data_pipe_consumer_handle,
	void* elements,
	uint32_t* num_bytes,
	MojoReadDataFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_consumer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->ReadData(elements, num_bytes, flags);
	}

	MojoResult Core::BeginReadData(MojoHandle data_pipe_consumer_handle,
	const void** buffer,
	uint32_t* buffer_num_bytes,
	MojoReadDataFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_consumer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->BeginReadData(buffer, buffer_num_bytes, flags);
	}

	MojoResult Core::EndReadData(MojoHandle data_pipe_consumer_handle,
	uint32_t num_bytes_read) {
	scoped_refptr<Dispatcher> dispatcher(
	GetDispatcher(data_pipe_consumer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	return dispatcher->EndReadData(num_bytes_read);
	}

	MojoResult Core::CreateSharedBuffer(
	const MojoCreateSharedBufferOptions* options,
	uint64_t num_bytes,
	MojoHandle* shared_buffer_handle) {
	MojoCreateSharedBufferOptions validated_options = {};
	// This will verify the \|options\| pointer.
	MojoResult result =
	SharedBufferDispatcher::ValidateCreateOptions(options,
	&validated_options);
	if (result != MOJO_RESULT_OK)
	return result;
	if (!VerifyUserPointer<MojoHandle>(shared_buffer_handle))
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_refptr<SharedBufferDispatcher> dispatcher;
	result = SharedBufferDispatcher::Create(validated_options, num_bytes,
	&dispatcher);
	if (result != MOJO_RESULT_OK) {
	DCHECK(!dispatcher);
	return result;
	}

	MojoHandle h = AddDispatcher(dispatcher);
	if (h == MOJO_HANDLE_INVALID) {
	LOG(ERROR) << "Handle table full";
	dispatcher->Close();
	return MOJO_RESULT_RESOURCE_EXHAUSTED;
	}

	*shared_buffer_handle = h;
	return MOJO_RESULT_OK;
	}

	MojoResult Core::DuplicateBufferHandle(
	MojoHandle buffer_handle,
	const MojoDuplicateBufferHandleOptions* options,
	MojoHandle* new_buffer_handle) {
	scoped_refptr<Dispatcher> dispatcher(GetDispatcher(buffer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	// Don't verify \|options\| here; that's the dispatcher's job.
	if (!VerifyUserPointer<MojoHandle>(new_buffer_handle))
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_refptr<Dispatcher> new_dispatcher;
	MojoResult result = dispatcher->DuplicateBufferHandle(options,
	&new_dispatcher);
	if (result != MOJO_RESULT_OK)
	return result;

	MojoHandle new_handle = AddDispatcher(new_dispatcher);
	if (new_handle == MOJO_HANDLE_INVALID) {
	LOG(ERROR) << "Handle table full";
	dispatcher->Close();
	return MOJO_RESULT_RESOURCE_EXHAUSTED;
	}

	*new_buffer_handle = new_handle;
	return MOJO_RESULT_OK;
	}

	MojoResult Core::MapBuffer(MojoHandle buffer_handle,
	uint64_t offset,
	uint64_t num_bytes,
	void** buffer,
	MojoMapBufferFlags flags) {
	scoped_refptr<Dispatcher> dispatcher(GetDispatcher(buffer_handle));
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;

	if (!VerifyUserPointerWithCount<void*>(buffer, 1))
	return MOJO_RESULT_INVALID_ARGUMENT;

	scoped_ptr<RawSharedBufferMapping> mapping;
	MojoResult result = dispatcher->MapBuffer(offset, num_bytes, flags, &mapping);
	if (result != MOJO_RESULT_OK)
	return result;

	DCHECK(mapping);
	void* address = mapping->base();
	{
	base::AutoLock locker(mapping_table_lock_);
	result = mapping_table_.AddMapping(mapping.Pass());
	}
	if (result != MOJO_RESULT_OK)
	return result;

	*buffer = address;
	return MOJO_RESULT_OK;
	}

	MojoResult Core::UnmapBuffer(void* buffer) {
	base::AutoLock locker(mapping_table_lock_);
	return mapping_table_.RemoveMapping(buffer);
	}

	// Note: We allow \|handles\| to repeat the same handle multiple times, since
	// different flags may be specified.
	// TODO(vtl): This incurs a performance cost in \|RemoveWaiter()\|. Analyze this
	// more carefully and address it if necessary.
	MojoResult Core::WaitManyInternal(const MojoHandle* handles,
	const MojoHandleSignals* signals,
	uint32_t num_handles,
	MojoDeadline deadline) {
	DCHECK_GT(num_handles, 0u);

	DispatcherVector dispatchers;
	dispatchers.reserve(num_handles);
	for (uint32_t i = 0; i < num_handles; i++) {
	scoped_refptr<Dispatcher> dispatcher = GetDispatcher(handles[i]);
	if (!dispatcher)
	return MOJO_RESULT_INVALID_ARGUMENT;
	dispatchers.push_back(dispatcher);
	}

	// TODO(vtl): Should make the waiter live (permanently) in TLS.
	Waiter waiter;
	waiter.Init();

	uint32_t i;
	MojoResult rv = MOJO_RESULT_OK;
	for (i = 0; i < num_handles; i++) {
	rv = dispatchers[i]->AddWaiter(&waiter, signals[i], i);
	if (rv != MOJO_RESULT_OK)
	break;
	}
	uint32_t num_added = i;

	if (rv == MOJO_RESULT_ALREADY_EXISTS) {
	rv = static_cast<MojoResult>(i); // The i-th one is already "triggered".
	} else if (rv == MOJO_RESULT_OK) {
	uint32_t context = static_cast<uint32_t>(-1);
	rv = waiter.Wait(deadline, &context);
	if (rv == MOJO_RESULT_OK)
	rv = static_cast<MojoResult>(context);
	}

	// Make sure no other dispatchers try to wake \|waiter\| for the current
	// \|Wait()\|/\|WaitMany()\| call. (Only after doing this can \|waiter\| be
	// destroyed, but this would still be required if the waiter were in TLS.)
	for (i = 0; i < num_added; i++)
	dispatchers[i]->RemoveWaiter(&waiter);

	return rv;
	}

	} // namespace system
	} // namespace mojo