ppapi/proxy/serialized_var.cc - chromium/src - Git at Google

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

 #include "ppapi/proxy/serialized_var.h"

 #include "base/logging.h"
 #include "ipc/ipc_message_utils.h"
 #include "ppapi/c/pp_instance.h"
 #include "ppapi/proxy/dispatcher.h"
 #include "ppapi/proxy/interface_proxy.h"
 #include "ppapi/proxy/ppapi_param_traits.h"
 #include "ppapi/proxy/ppb_buffer_proxy.h"
 #include "ppapi/shared_impl/ppapi_globals.h"
 #include "ppapi/shared_impl/var.h"
 #include "ppapi/thunk/enter.h"

 namespace ppapi {
 namespace proxy {

 namespace {
 void DefaultHandleWriter(base::Pickle* m, const SerializedHandle& handle) {
   IPC::ParamTraits<SerializedHandle>::Write(m, handle);
 }
 }  // namespace

 // SerializedVar::Inner --------------------------------------------------------

 SerializedVar::Inner::Inner()
     : serialization_rules_(NULL),
       var_(PP_MakeUndefined()),
       instance_(0),
       cleanup_mode_(CLEANUP_NONE),
       is_valid_var_(true) {
 #ifndef NDEBUG
   has_been_serialized_ = false;
   has_been_deserialized_ = false;
 #endif
 }

 SerializedVar::Inner::Inner(VarSerializationRules* serialization_rules)
     : serialization_rules_(serialization_rules),
       var_(PP_MakeUndefined()),
       instance_(0),
       cleanup_mode_(CLEANUP_NONE) {
 #ifndef NDEBUG
   has_been_serialized_ = false;
   has_been_deserialized_ = false;
 #endif
 }

 SerializedVar::Inner::~Inner() {
   switch (cleanup_mode_) {
     case END_SEND_PASS_REF:
       serialization_rules_->EndSendPassRef(var_);
       break;
     case END_RECEIVE_CALLER_OWNED:
       serialization_rules_->EndReceiveCallerOwned(var_);
       break;
     default:
       break;
   }
 }

 PP_Var SerializedVar::Inner::GetVar() {
   DCHECK(serialization_rules_.get());

 #if defined(NACL_WIN64)
   NOTREACHED();
   return PP_MakeUndefined();
 #else
   if (raw_var_data_.get()) {
     var_ = raw_var_data_->CreatePPVar(instance_);
     raw_var_data_.reset(NULL);
   }

   return var_;
 #endif
 }

 void SerializedVar::Inner::SetVar(PP_Var var) {
   // Sanity check, when updating the var we should have received a
   // serialization rules pointer already.
   DCHECK(serialization_rules_.get());
   var_ = var;
   raw_var_data_.reset(NULL);
 }

 void SerializedVar::Inner::SetInstance(PP_Instance instance) {
   instance_ = instance;
 }

 void SerializedVar::Inner::ForceSetVarValueForTest(PP_Var value) {
   var_ = value;
   raw_var_data_.reset(NULL);
 }

 void SerializedVar::Inner::WriteToMessage(base::Pickle* m) const {
   // When writing to the IPC messages, a serialization rules handler should
   // always have been set.
   //
   // When sending a message, it should be difficult to trigger this if you're
   // using the SerializedVarSendInput class and giving a non-NULL dispatcher.
   // Make sure you're using the proper "Send" helper class.
   //
   // It should be more common to see this when handling an incoming message
   // that returns a var. This means the message handler didn't write to the
   // output parameter, or possibly you used the wrong helper class
   // (normally SerializedVarReturnValue).
   DCHECK(serialization_rules_.get());

 #ifndef NDEBUG
   // We should only be serializing something once.
   DCHECK(!has_been_serialized_);
   has_been_serialized_ = true;
 #endif
   std::unique_ptr<RawVarDataGraph> data =
       RawVarDataGraph::Create(var_, instance_);
   if (data) {
     m->WriteBool(true);  // Success.
     data->Write(m, base::Bind(&DefaultHandleWriter));
   } else {
     m->WriteBool(false);  // Failure.
   }
 }

 void SerializedVar::Inner::WriteDataToMessage(
     base::Pickle* m,
     const HandleWriter& handle_writer) const {
   if (raw_var_data_) {
     m->WriteBool(true);  // Success.
     raw_var_data_->Write(m, handle_writer);
   } else {
     m->WriteBool(false);  // Failure.
   }
 }

 bool SerializedVar::Inner::ReadFromMessage(const base::Pickle* m,
                                            base::PickleIterator* iter) {
 #ifndef NDEBUG
   // We should only deserialize something once or will end up with leaked
   // references.
   //
   // One place this has happened in the past is using
   // std::vector<SerializedVar>.resize(). If you're doing this manually instead
   // of using the helper classes for handling in/out vectors of vars, be
   // sure you use the same pattern as the SerializedVarVector classes.
   DCHECK(!has_been_deserialized_);
   has_been_deserialized_ = true;
 #endif
   // When reading, the dispatcher should be set when we get a Deserialize
   // call (which will supply a dispatcher).
   if (!iter->ReadBool(&is_valid_var_))
       return false;
   if (is_valid_var_) {
     raw_var_data_ = RawVarDataGraph::Read(m, iter);
     if (!raw_var_data_)
       return false;
   }

   return true;
 }

 void SerializedVar::Inner::SetCleanupModeToEndSendPassRef() {
   cleanup_mode_ = END_SEND_PASS_REF;
 }

 void SerializedVar::Inner::SetCleanupModeToEndReceiveCallerOwned() {
   cleanup_mode_ = END_RECEIVE_CALLER_OWNED;
 }

 // SerializedVar ---------------------------------------------------------------

 SerializedVar::SerializedVar() : inner_(new Inner) {
 }

 SerializedVar::SerializedVar(VarSerializationRules* serialization_rules)
     : inner_(new Inner(serialization_rules)) {
 }

 SerializedVar::~SerializedVar() {
 }

 // SerializedVarSendInput ------------------------------------------------------

 SerializedVarSendInput::SerializedVarSendInput(Dispatcher* dispatcher,
                                                const PP_Var& var)
     : SerializedVar(dispatcher->serialization_rules()) {
   inner_->SetVar(dispatcher->serialization_rules()->SendCallerOwned(var));
 }

 // static
 void SerializedVarSendInput::ConvertVector(Dispatcher* dispatcher,
                                            const PP_Var* input,
                                            size_t input_count,
                                            std::vector<SerializedVar>* output) {
   output->reserve(input_count);
   for (size_t i = 0; i < input_count; i++)
     output->push_back(SerializedVarSendInput(dispatcher, input[i]));
 }

 // SerializedVarSendInputShmem -------------------------------------------------

 SerializedVarSendInputShmem::SerializedVarSendInputShmem(
     Dispatcher* dispatcher,
     const PP_Var& var,
     const PP_Instance& instance)
     : SerializedVar(dispatcher->serialization_rules()) {
   inner_->SetVar(dispatcher->serialization_rules()->SendCallerOwned(var));
   inner_->SetInstance(instance);
 }

 // ReceiveSerializedVarReturnValue ---------------------------------------------

 ReceiveSerializedVarReturnValue::ReceiveSerializedVarReturnValue() {
 }

 ReceiveSerializedVarReturnValue::ReceiveSerializedVarReturnValue(
     const SerializedVar& serialized)
     : SerializedVar(serialized) {
 }

 PP_Var ReceiveSerializedVarReturnValue::Return(Dispatcher* dispatcher) {
   inner_->set_serialization_rules(dispatcher->serialization_rules());
   inner_->SetVar(inner_->serialization_rules()->ReceivePassRef(
       inner_->GetVar()));
   return inner_->GetVar();
 }

 // ReceiveSerializedException --------------------------------------------------

 ReceiveSerializedException::ReceiveSerializedException(Dispatcher* dispatcher,
                                                        PP_Var* exception)
     : SerializedVar(dispatcher->serialization_rules()),
       exception_(exception) {
 }

 ReceiveSerializedException::~ReceiveSerializedException() {
   if (exception_) {
     // When an output exception is specified, it will take ownership of the
     // reference.
     inner_->SetVar(
         inner_->serialization_rules()->ReceivePassRef(inner_->GetVar()));
     *exception_ = inner_->GetVar();
   } else {
     // When no output exception is specified, the browser thinks we have a ref
     // to an object that we don't want (this will happen only in the plugin
     // since the browser will always specify an out exception for the plugin to
     // write into).
     //
     // Strings don't need this handling since we can just avoid creating a
     // Var from the std::string in the first place.
     if (inner_->GetVar().type == PP_VARTYPE_OBJECT)
       inner_->serialization_rules()->ReleaseObjectRef(inner_->GetVar());
   }
 }

 bool ReceiveSerializedException::IsThrown() const {
   return exception_ && exception_->type != PP_VARTYPE_UNDEFINED;
 }

 // ReceiveSerializedVarVectorOutParam ------------------------------------------

 ReceiveSerializedVarVectorOutParam::ReceiveSerializedVarVectorOutParam(
     Dispatcher* dispatcher,
     uint32_t* output_count,
     PP_Var** output)
     : dispatcher_(dispatcher),
       output_count_(output_count),
       output_(output) {
 }

 ReceiveSerializedVarVectorOutParam::~ReceiveSerializedVarVectorOutParam() {
   *output_count_ = static_cast<uint32_t>(vector_.size());
   if (vector_.empty()) {
     *output_ = nullptr;
     return;
   }

   *output_ = static_cast<PP_Var*>(malloc(vector_.size() * sizeof(PP_Var)));
   for (size_t i = 0; i < vector_.size(); i++) {
     // Here we just mimic what happens when returning a value.
     ReceiveSerializedVarReturnValue converted;
     SerializedVar* serialized = &converted;
     *serialized = vector_[i];
     (*output_)[i] = converted.Return(dispatcher_);
   }
 }

 std::vector<SerializedVar>* ReceiveSerializedVarVectorOutParam::OutParam() {
   return &vector_;
 }

 // SerializedVarReceiveInput ---------------------------------------------------

 SerializedVarReceiveInput::SerializedVarReceiveInput(
     const SerializedVar& serialized)
     : serialized_(serialized) {
 }

 SerializedVarReceiveInput::~SerializedVarReceiveInput() {
 }

 PP_Var SerializedVarReceiveInput::Get(Dispatcher* dispatcher) {
   serialized_.inner_->set_serialization_rules(
       dispatcher->serialization_rules());

   // Ensure that when the serialized var goes out of scope it cleans up the
   // stuff we're making in BeginReceiveCallerOwned.
   serialized_.inner_->SetCleanupModeToEndReceiveCallerOwned();

   serialized_.inner_->SetVar(
       serialized_.inner_->serialization_rules()->BeginReceiveCallerOwned(
           serialized_.inner_->GetVar()));
   return serialized_.inner_->GetVar();
 }


 PP_Var SerializedVarReceiveInput::GetForInstance(Dispatcher* dispatcher,
                                                  PP_Instance instance) {
   serialized_.inner_->SetInstance(instance);
   return Get(dispatcher);
 }

 // SerializedVarVectorReceiveInput ---------------------------------------------

 SerializedVarVectorReceiveInput::SerializedVarVectorReceiveInput(
     const std::vector<SerializedVar>& serialized)
     : serialized_(serialized) {
 }

 SerializedVarVectorReceiveInput::~SerializedVarVectorReceiveInput() {
   for (size_t i = 0; i < deserialized_.size(); i++) {
     serialized_[i].inner_->serialization_rules()->EndReceiveCallerOwned(
         deserialized_[i]);
   }
 }

 PP_Var* SerializedVarVectorReceiveInput::Get(Dispatcher* dispatcher,
                                              uint32_t* array_size) {
   deserialized_.resize(serialized_.size());
   for (size_t i = 0; i < serialized_.size(); i++) {
     // The vectors must be able to clean themselves up after this call is
     // torn down.
     serialized_[i].inner_->set_serialization_rules(
         dispatcher->serialization_rules());

     serialized_[i].inner_->SetVar(
         serialized_[i].inner_->serialization_rules()->BeginReceiveCallerOwned(
             serialized_[i].inner_->GetVar()));
     deserialized_[i] = serialized_[i].inner_->GetVar();
   }

   *array_size = static_cast<uint32_t>(serialized_.size());
   return deserialized_.empty() ? NULL : &deserialized_[0];
 }

 // SerializedVarReturnValue ----------------------------------------------------

 SerializedVarReturnValue::SerializedVarReturnValue(SerializedVar* serialized)
     : serialized_(serialized) {
 }

 void SerializedVarReturnValue::Return(Dispatcher* dispatcher,
                                       const PP_Var& var) {
   serialized_->inner_->set_serialization_rules(
       dispatcher->serialization_rules());

   // Var must clean up after our BeginSendPassRef call.
   serialized_->inner_->SetCleanupModeToEndSendPassRef();

   serialized_->inner_->SetVar(
       dispatcher->serialization_rules()->BeginSendPassRef(var));
 }

 // static
 SerializedVar SerializedVarReturnValue::Convert(Dispatcher* dispatcher,
                                                 const PP_Var& var) {
   // Mimic what happens in the normal case.
   SerializedVar result;
   SerializedVarReturnValue retvalue(&result);
   retvalue.Return(dispatcher, var);
   return result;
 }

 // SerializedVarOutParam -------------------------------------------------------

 SerializedVarOutParam::SerializedVarOutParam(SerializedVar* serialized)
     : serialized_(serialized),
       writable_var_(PP_MakeUndefined()),
       dispatcher_(NULL) {
 }

 SerializedVarOutParam::~SerializedVarOutParam() {
   if (serialized_->inner_->serialization_rules()) {
     // When unset, OutParam wasn't called. We'll just leave the var untouched
     // in that case.
     serialized_->inner_->SetVar(
         serialized_->inner_->serialization_rules()->BeginSendPassRef(
             writable_var_));

     // Normally the current object will be created on the stack to wrap a
     // SerializedVar and won't have a scope around the actual IPC send. So we
     // need to tell the SerializedVar to do the begin/end send pass ref calls.
     serialized_->inner_->SetCleanupModeToEndSendPassRef();
   }
 }

 PP_Var* SerializedVarOutParam::OutParam(Dispatcher* dispatcher) {
   dispatcher_ = dispatcher;
   serialized_->inner_->set_serialization_rules(
       dispatcher->serialization_rules());
   return &writable_var_;
 }

 // SerializedVarVectorOutParam -------------------------------------------------

 SerializedVarVectorOutParam::SerializedVarVectorOutParam(
     std::vector<SerializedVar>* serialized)
     : dispatcher_(NULL),
       serialized_(serialized),
       count_(0),
       array_(NULL) {
 }

 SerializedVarVectorOutParam::~SerializedVarVectorOutParam() {
   DCHECK(dispatcher_);

   // Convert the array written by the pepper code to the serialized structure.
   // Note we can't use resize here, we have to allocate a new SerializedVar
   // for each serialized item. See ParamTraits<vector<SerializedVar>>::Read.
   serialized_->reserve(count_);
   for (uint32_t i = 0; i < count_; i++) {
     // Just mimic what we do for regular OutParams.
     SerializedVar var;
     SerializedVarOutParam out(&var);
     *out.OutParam(dispatcher_) = array_[i];
     serialized_->push_back(var);
   }

   // When returning arrays, the pepper code expects the caller to take
   // ownership of the array.
   free(array_);
 }

 PP_Var** SerializedVarVectorOutParam::ArrayOutParam(Dispatcher* dispatcher) {
   DCHECK(!dispatcher_);  // Should only be called once.
   dispatcher_ = dispatcher;
   return &array_;
 }

 SerializedVarTestConstructor::SerializedVarTestConstructor(
     const PP_Var& pod_var) {
   DCHECK(pod_var.type != PP_VARTYPE_STRING);
   inner_->ForceSetVarValueForTest(pod_var);
 }

 SerializedVarTestConstructor::SerializedVarTestConstructor(
     const std::string& str) {
   inner_->ForceSetVarValueForTest(StringVar::StringToPPVar(str));
 }

 SerializedVarTestReader::SerializedVarTestReader(const SerializedVar& var)
     : SerializedVar(var) {
 }

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

	#include "ppapi/proxy/serialized_var.h"

	#include "base/logging.h"
	#include "ipc/ipc_message_utils.h"
	#include "ppapi/c/pp_instance.h"
	#include "ppapi/proxy/dispatcher.h"
	#include "ppapi/proxy/interface_proxy.h"
	#include "ppapi/proxy/ppapi_param_traits.h"
	#include "ppapi/proxy/ppb_buffer_proxy.h"
	#include "ppapi/shared_impl/ppapi_globals.h"
	#include "ppapi/shared_impl/var.h"
	#include "ppapi/thunk/enter.h"

	namespace ppapi {
	namespace proxy {

	namespace {
	void DefaultHandleWriter(base::Pickle* m, const SerializedHandle& handle) {
	IPC::ParamTraits<SerializedHandle>::Write(m, handle);
	}
	} // namespace

	// SerializedVar::Inner --------------------------------------------------------

	SerializedVar::Inner::Inner()
	: serialization_rules_(NULL),
	var_(PP_MakeUndefined()),
	instance_(0),
	cleanup_mode_(CLEANUP_NONE),
	is_valid_var_(true) {
	#ifndef NDEBUG
	has_been_serialized_ = false;
	has_been_deserialized_ = false;
	#endif
	}

	SerializedVar::Inner::Inner(VarSerializationRules* serialization_rules)
	: serialization_rules_(serialization_rules),
	var_(PP_MakeUndefined()),
	instance_(0),
	cleanup_mode_(CLEANUP_NONE) {
	#ifndef NDEBUG
	has_been_serialized_ = false;
	has_been_deserialized_ = false;
	#endif
	}

	SerializedVar::Inner::~Inner() {
	switch (cleanup_mode_) {
	case END_SEND_PASS_REF:
	serialization_rules_->EndSendPassRef(var_);
	break;
	case END_RECEIVE_CALLER_OWNED:
	serialization_rules_->EndReceiveCallerOwned(var_);
	break;
	default:
	break;
	}
	}

	PP_Var SerializedVar::Inner::GetVar() {
	DCHECK(serialization_rules_.get());

	#if defined(NACL_WIN64)
	NOTREACHED();
	return PP_MakeUndefined();
	#else
	if (raw_var_data_.get()) {
	var_ = raw_var_data_->CreatePPVar(instance_);
	raw_var_data_.reset(NULL);
	}

	return var_;
	#endif
	}

	void SerializedVar::Inner::SetVar(PP_Var var) {
	// Sanity check, when updating the var we should have received a
	// serialization rules pointer already.
	DCHECK(serialization_rules_.get());
	var_ = var;
	raw_var_data_.reset(NULL);
	}

	void SerializedVar::Inner::SetInstance(PP_Instance instance) {
	instance_ = instance;
	}

	void SerializedVar::Inner::ForceSetVarValueForTest(PP_Var value) {
	var_ = value;
	raw_var_data_.reset(NULL);
	}

	void SerializedVar::Inner::WriteToMessage(base::Pickle* m) const {
	// When writing to the IPC messages, a serialization rules handler should
	// always have been set.
	//
	// When sending a message, it should be difficult to trigger this if you're
	// using the SerializedVarSendInput class and giving a non-NULL dispatcher.
	// Make sure you're using the proper "Send" helper class.
	//
	// It should be more common to see this when handling an incoming message
	// that returns a var. This means the message handler didn't write to the
	// output parameter, or possibly you used the wrong helper class
	// (normally SerializedVarReturnValue).
	DCHECK(serialization_rules_.get());

	#ifndef NDEBUG
	// We should only be serializing something once.
	DCHECK(!has_been_serialized_);
	has_been_serialized_ = true;
	#endif
	std::unique_ptr<RawVarDataGraph> data =
	RawVarDataGraph::Create(var_, instance_);
	if (data) {
	m->WriteBool(true); // Success.
	data->Write(m, base::Bind(&DefaultHandleWriter));
	} else {
	m->WriteBool(false); // Failure.
	}
	}

	void SerializedVar::Inner::WriteDataToMessage(
	base::Pickle* m,
	const HandleWriter& handle_writer) const {
	if (raw_var_data_) {
	m->WriteBool(true); // Success.
	raw_var_data_->Write(m, handle_writer);
	} else {
	m->WriteBool(false); // Failure.
	}
	}

	bool SerializedVar::Inner::ReadFromMessage(const base::Pickle* m,
	base::PickleIterator* iter) {
	#ifndef NDEBUG
	// We should only deserialize something once or will end up with leaked
	// references.
	//
	// One place this has happened in the past is using
	// std::vector<SerializedVar>.resize(). If you're doing this manually instead
	// of using the helper classes for handling in/out vectors of vars, be
	// sure you use the same pattern as the SerializedVarVector classes.
	DCHECK(!has_been_deserialized_);
	has_been_deserialized_ = true;
	#endif
	// When reading, the dispatcher should be set when we get a Deserialize
	// call (which will supply a dispatcher).
	if (!iter->ReadBool(&is_valid_var_))
	return false;
	if (is_valid_var_) {
	raw_var_data_ = RawVarDataGraph::Read(m, iter);
	if (!raw_var_data_)
	return false;
	}

	return true;
	}

	void SerializedVar::Inner::SetCleanupModeToEndSendPassRef() {
	cleanup_mode_ = END_SEND_PASS_REF;
	}

	void SerializedVar::Inner::SetCleanupModeToEndReceiveCallerOwned() {
	cleanup_mode_ = END_RECEIVE_CALLER_OWNED;
	}

	// SerializedVar ---------------------------------------------------------------

	SerializedVar::SerializedVar() : inner_(new Inner) {
	}

	SerializedVar::SerializedVar(VarSerializationRules* serialization_rules)
	: inner_(new Inner(serialization_rules)) {
	}

	SerializedVar::~SerializedVar() {
	}

	// SerializedVarSendInput ------------------------------------------------------

	SerializedVarSendInput::SerializedVarSendInput(Dispatcher* dispatcher,
	const PP_Var& var)
	: SerializedVar(dispatcher->serialization_rules()) {
	inner_->SetVar(dispatcher->serialization_rules()->SendCallerOwned(var));
	}

	// static
	void SerializedVarSendInput::ConvertVector(Dispatcher* dispatcher,
	const PP_Var* input,
	size_t input_count,
	std::vector<SerializedVar>* output) {
	output->reserve(input_count);
	for (size_t i = 0; i < input_count; i++)
	output->push_back(SerializedVarSendInput(dispatcher, input[i]));
	}

	// SerializedVarSendInputShmem -------------------------------------------------

	SerializedVarSendInputShmem::SerializedVarSendInputShmem(
	Dispatcher* dispatcher,
	const PP_Var& var,
	const PP_Instance& instance)
	: SerializedVar(dispatcher->serialization_rules()) {
	inner_->SetVar(dispatcher->serialization_rules()->SendCallerOwned(var));
	inner_->SetInstance(instance);
	}

	// ReceiveSerializedVarReturnValue ---------------------------------------------

	ReceiveSerializedVarReturnValue::ReceiveSerializedVarReturnValue() {
	}

	ReceiveSerializedVarReturnValue::ReceiveSerializedVarReturnValue(
	const SerializedVar& serialized)
	: SerializedVar(serialized) {
	}

	PP_Var ReceiveSerializedVarReturnValue::Return(Dispatcher* dispatcher) {
	inner_->set_serialization_rules(dispatcher->serialization_rules());
	inner_->SetVar(inner_->serialization_rules()->ReceivePassRef(
	inner_->GetVar()));
	return inner_->GetVar();
	}

	// ReceiveSerializedException --------------------------------------------------

	ReceiveSerializedException::ReceiveSerializedException(Dispatcher* dispatcher,
	PP_Var* exception)
	: SerializedVar(dispatcher->serialization_rules()),
	exception_(exception) {
	}

	ReceiveSerializedException::~ReceiveSerializedException() {
	if (exception_) {
	// When an output exception is specified, it will take ownership of the
	// reference.
	inner_->SetVar(
	inner_->serialization_rules()->ReceivePassRef(inner_->GetVar()));
	*exception_ = inner_->GetVar();
	} else {
	// When no output exception is specified, the browser thinks we have a ref
	// to an object that we don't want (this will happen only in the plugin
	// since the browser will always specify an out exception for the plugin to
	// write into).
	//
	// Strings don't need this handling since we can just avoid creating a
	// Var from the std::string in the first place.
	if (inner_->GetVar().type == PP_VARTYPE_OBJECT)
	inner_->serialization_rules()->ReleaseObjectRef(inner_->GetVar());
	}
	}

	bool ReceiveSerializedException::IsThrown() const {
	return exception_ && exception_->type != PP_VARTYPE_UNDEFINED;
	}

	// ReceiveSerializedVarVectorOutParam ------------------------------------------

	ReceiveSerializedVarVectorOutParam::ReceiveSerializedVarVectorOutParam(
	Dispatcher* dispatcher,
	uint32_t* output_count,
	PP_Var** output)
	: dispatcher_(dispatcher),
	output_count_(output_count),
	output_(output) {
	}

	ReceiveSerializedVarVectorOutParam::~ReceiveSerializedVarVectorOutParam() {
	*output_count_ = static_cast<uint32_t>(vector_.size());
	if (vector_.empty()) {
	*output_ = nullptr;
	return;
	}

	output_ = static_cast<PP_Var>(malloc(vector_.size() * sizeof(PP_Var)));
	for (size_t i = 0; i < vector_.size(); i++) {
	// Here we just mimic what happens when returning a value.
	ReceiveSerializedVarReturnValue converted;
	SerializedVar* serialized = &converted;
	*serialized = vector_[i];
	(*output_)[i] = converted.Return(dispatcher_);
	}
	}

	std::vector<SerializedVar>* ReceiveSerializedVarVectorOutParam::OutParam() {
	return &vector_;
	}

	// SerializedVarReceiveInput ---------------------------------------------------

	SerializedVarReceiveInput::SerializedVarReceiveInput(
	const SerializedVar& serialized)
	: serialized_(serialized) {
	}

	SerializedVarReceiveInput::~SerializedVarReceiveInput() {
	}

	PP_Var SerializedVarReceiveInput::Get(Dispatcher* dispatcher) {
	serialized_.inner_->set_serialization_rules(
	dispatcher->serialization_rules());

	// Ensure that when the serialized var goes out of scope it cleans up the
	// stuff we're making in BeginReceiveCallerOwned.
	serialized_.inner_->SetCleanupModeToEndReceiveCallerOwned();

	serialized_.inner_->SetVar(
	serialized_.inner_->serialization_rules()->BeginReceiveCallerOwned(
	serialized_.inner_->GetVar()));
	return serialized_.inner_->GetVar();
	}


	PP_Var SerializedVarReceiveInput::GetForInstance(Dispatcher* dispatcher,
	PP_Instance instance) {
	serialized_.inner_->SetInstance(instance);
	return Get(dispatcher);
	}

	// SerializedVarVectorReceiveInput ---------------------------------------------

	SerializedVarVectorReceiveInput::SerializedVarVectorReceiveInput(
	const std::vector<SerializedVar>& serialized)
	: serialized_(serialized) {
	}

	SerializedVarVectorReceiveInput::~SerializedVarVectorReceiveInput() {
	for (size_t i = 0; i < deserialized_.size(); i++) {
	serialized_[i].inner_->serialization_rules()->EndReceiveCallerOwned(
	deserialized_[i]);
	}
	}

	PP_Var* SerializedVarVectorReceiveInput::Get(Dispatcher* dispatcher,
	uint32_t* array_size) {
	deserialized_.resize(serialized_.size());
	for (size_t i = 0; i < serialized_.size(); i++) {
	// The vectors must be able to clean themselves up after this call is
	// torn down.
	serialized_[i].inner_->set_serialization_rules(
	dispatcher->serialization_rules());

	serialized_[i].inner_->SetVar(
	serialized_[i].inner_->serialization_rules()->BeginReceiveCallerOwned(
	serialized_[i].inner_->GetVar()));
	deserialized_[i] = serialized_[i].inner_->GetVar();
	}

	*array_size = static_cast<uint32_t>(serialized_.size());
	return deserialized_.empty() ? NULL : &deserialized_[0];
	}

	// SerializedVarReturnValue ----------------------------------------------------

	SerializedVarReturnValue::SerializedVarReturnValue(SerializedVar* serialized)
	: serialized_(serialized) {
	}

	void SerializedVarReturnValue::Return(Dispatcher* dispatcher,
	const PP_Var& var) {
	serialized_->inner_->set_serialization_rules(
	dispatcher->serialization_rules());

	// Var must clean up after our BeginSendPassRef call.
	serialized_->inner_->SetCleanupModeToEndSendPassRef();

	serialized_->inner_->SetVar(
	dispatcher->serialization_rules()->BeginSendPassRef(var));
	}

	// static
	SerializedVar SerializedVarReturnValue::Convert(Dispatcher* dispatcher,
	const PP_Var& var) {
	// Mimic what happens in the normal case.
	SerializedVar result;
	SerializedVarReturnValue retvalue(&result);
	retvalue.Return(dispatcher, var);
	return result;
	}

	// SerializedVarOutParam -------------------------------------------------------

	SerializedVarOutParam::SerializedVarOutParam(SerializedVar* serialized)
	: serialized_(serialized),
	writable_var_(PP_MakeUndefined()),
	dispatcher_(NULL) {
	}

	SerializedVarOutParam::~SerializedVarOutParam() {
	if (serialized_->inner_->serialization_rules()) {
	// When unset, OutParam wasn't called. We'll just leave the var untouched
	// in that case.
	serialized_->inner_->SetVar(
	serialized_->inner_->serialization_rules()->BeginSendPassRef(
	writable_var_));

	// Normally the current object will be created on the stack to wrap a
	// SerializedVar and won't have a scope around the actual IPC send. So we
	// need to tell the SerializedVar to do the begin/end send pass ref calls.
	serialized_->inner_->SetCleanupModeToEndSendPassRef();
	}
	}

	PP_Var* SerializedVarOutParam::OutParam(Dispatcher* dispatcher) {
	dispatcher_ = dispatcher;
	serialized_->inner_->set_serialization_rules(
	dispatcher->serialization_rules());
	return &writable_var_;
	}

	// SerializedVarVectorOutParam -------------------------------------------------

	SerializedVarVectorOutParam::SerializedVarVectorOutParam(
	std::vector<SerializedVar>* serialized)
	: dispatcher_(NULL),
	serialized_(serialized),
	count_(0),
	array_(NULL) {
	}

	SerializedVarVectorOutParam::~SerializedVarVectorOutParam() {
	DCHECK(dispatcher_);

	// Convert the array written by the pepper code to the serialized structure.
	// Note we can't use resize here, we have to allocate a new SerializedVar
	// for each serialized item. See ParamTraits<vector<SerializedVar>>::Read.
	serialized_->reserve(count_);
	for (uint32_t i = 0; i < count_; i++) {
	// Just mimic what we do for regular OutParams.
	SerializedVar var;
	SerializedVarOutParam out(&var);
	*out.OutParam(dispatcher_) = array_[i];
	serialized_->push_back(var);
	}

	// When returning arrays, the pepper code expects the caller to take
	// ownership of the array.
	free(array_);
	}

	PP_Var** SerializedVarVectorOutParam::ArrayOutParam(Dispatcher* dispatcher) {
	DCHECK(!dispatcher_); // Should only be called once.
	dispatcher_ = dispatcher;
	return &array_;
	}

	SerializedVarTestConstructor::SerializedVarTestConstructor(
	const PP_Var& pod_var) {
	DCHECK(pod_var.type != PP_VARTYPE_STRING);
	inner_->ForceSetVarValueForTest(pod_var);
	}

	SerializedVarTestConstructor::SerializedVarTestConstructor(
	const std::string& str) {
	inner_->ForceSetVarValueForTest(StringVar::StringToPPVar(str));
	}

	SerializedVarTestReader::SerializedVarTestReader(const SerializedVar& var)
	: SerializedVar(var) {
	}

	} // namespace proxy
	} // namespace ppapi