mojo/public/cpp/bindings/tests/sample_service_unittest.cc - platform/external/libmojo - Git at Google

 // Copyright 2014 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 <stddef.h>
 #include <stdint.h>
 #include <algorithm>
 #include <ostream>
 #include <string>
 #include <utility>

 #include "mojo/public/interfaces/bindings/tests/sample_service.mojom.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace mojo {

 template <>
 struct TypeConverter<int32_t, sample::BarPtr> {
   static int32_t Convert(const sample::BarPtr& bar) {
     return static_cast<int32_t>(bar->alpha) << 16 |
            static_cast<int32_t>(bar->beta) << 8 |
            static_cast<int32_t>(bar->gamma);
   }
 };

 }  // namespace mojo

 namespace sample {
 namespace {

 // Set this variable to true to print the message in hex.
 bool g_dump_message_as_hex = false;

 // Set this variable to true to print the message in human readable form.
 bool g_dump_message_as_text = false;

 // Make a sample |Foo|.
 FooPtr MakeFoo() {
   std::string name("foopy");

   BarPtr bar(Bar::New(20, 40, 60, Bar::Type::VERTICAL));

   std::vector<BarPtr> extra_bars(3);
   for (size_t i = 0; i < extra_bars.size(); ++i) {
     Bar::Type type = i % 2 == 0 ? Bar::Type::VERTICAL : Bar::Type::HORIZONTAL;
     uint8_t base = static_cast<uint8_t>(i * 100);
     extra_bars[i] = Bar::New(base, base + 20, base + 40, type);
   }

   std::vector<uint8_t> data(10);
   for (size_t i = 0; i < data.size(); ++i)
     data[i] = static_cast<uint8_t>(data.size() - i);

   std::vector<mojo::ScopedDataPipeConsumerHandle> input_streams(2);
   std::vector<mojo::ScopedDataPipeProducerHandle> output_streams(2);
   for (size_t i = 0; i < input_streams.size(); ++i) {
     MojoCreateDataPipeOptions options;
     options.struct_size = sizeof(MojoCreateDataPipeOptions);
     options.flags = MOJO_CREATE_DATA_PIPE_OPTIONS_FLAG_NONE;
     options.element_num_bytes = 1;
     options.capacity_num_bytes = 1024;
     mojo::ScopedDataPipeProducerHandle producer;
     mojo::ScopedDataPipeConsumerHandle consumer;
     mojo::CreateDataPipe(&options, &producer, &consumer);
     input_streams[i] = std::move(consumer);
     output_streams[i] = std::move(producer);
   }

   std::vector<std::vector<bool>> array_of_array_of_bools(2);
   for (size_t i = 0; i < 2; ++i) {
     std::vector<bool> array_of_bools(2);
     for (size_t j = 0; j < 2; ++j)
       array_of_bools[j] = j;
     array_of_array_of_bools[i] = std::move(array_of_bools);
   }

   mojo::MessagePipe pipe;
   return Foo::New(name, 1, 2, false, true, false, std::move(bar),
                   std::move(extra_bars), std::move(data),
                   std::move(pipe.handle1), std::move(input_streams),
                   std::move(output_streams), std::move(array_of_array_of_bools),
                   base::nullopt, base::nullopt);
 }

 // Check that the given |Foo| is identical to the one made by |MakeFoo()|.
 void CheckFoo(const Foo& foo) {
   const std::string kName("foopy");
   EXPECT_EQ(kName.size(), foo.name.size());
   for (size_t i = 0; i < std::min(kName.size(), foo.name.size()); i++) {
     // Test both |operator[]| and |at|.
     EXPECT_EQ(kName[i], foo.name.at(i)) << i;
     EXPECT_EQ(kName[i], foo.name[i]) << i;
   }
   EXPECT_EQ(kName, foo.name);

   EXPECT_EQ(1, foo.x);
   EXPECT_EQ(2, foo.y);
   EXPECT_FALSE(foo.a);
   EXPECT_TRUE(foo.b);
   EXPECT_FALSE(foo.c);

   EXPECT_EQ(20, foo.bar->alpha);
   EXPECT_EQ(40, foo.bar->beta);
   EXPECT_EQ(60, foo.bar->gamma);
   EXPECT_EQ(Bar::Type::VERTICAL, foo.bar->type);

   EXPECT_EQ(3u, foo.extra_bars->size());
   for (size_t i = 0; i < foo.extra_bars->size(); i++) {
     uint8_t base = static_cast<uint8_t>(i * 100);
     Bar::Type type = i % 2 == 0 ? Bar::Type::VERTICAL : Bar::Type::HORIZONTAL;
     EXPECT_EQ(base, (*foo.extra_bars)[i]->alpha) << i;
     EXPECT_EQ(base + 20, (*foo.extra_bars)[i]->beta) << i;
     EXPECT_EQ(base + 40, (*foo.extra_bars)[i]->gamma) << i;
     EXPECT_EQ(type, (*foo.extra_bars)[i]->type) << i;
   }

   EXPECT_EQ(10u, foo.data->size());
   for (size_t i = 0; i < foo.data->size(); ++i) {
     EXPECT_EQ(static_cast<uint8_t>(foo.data->size() - i), (*foo.data)[i]) << i;
   }

   EXPECT_TRUE(foo.input_streams);
   EXPECT_EQ(2u, foo.input_streams->size());

   EXPECT_TRUE(foo.output_streams);
   EXPECT_EQ(2u, foo.output_streams->size());

   EXPECT_EQ(2u, foo.array_of_array_of_bools->size());
   for (size_t i = 0; i < foo.array_of_array_of_bools->size(); ++i) {
     EXPECT_EQ(2u, (*foo.array_of_array_of_bools)[i].size());
     for (size_t j = 0; j < (*foo.array_of_array_of_bools)[i].size(); ++j) {
       EXPECT_EQ(bool(j), (*foo.array_of_array_of_bools)[i][j]);
     }
   }
 }

 void PrintSpacer(int depth) {
   for (int i = 0; i < depth; ++i)
     std::cout << "   ";
 }

 void Print(int depth, const char* name, bool value) {
   PrintSpacer(depth);
   std::cout << name << ": " << (value ? "true" : "false") << std::endl;
 }

 void Print(int depth, const char* name, int32_t value) {
   PrintSpacer(depth);
   std::cout << name << ": " << value << std::endl;
 }

 void Print(int depth, const char* name, uint8_t value) {
   PrintSpacer(depth);
   std::cout << name << ": " << uint32_t(value) << std::endl;
 }

 template <typename H>
 void Print(int depth,
            const char* name,
            const mojo::ScopedHandleBase<H>& value) {
   PrintSpacer(depth);
   std::cout << name << ": 0x" << std::hex << value.get().value() << std::endl;
 }

 void Print(int depth, const char* name, const std::string& str) {
   PrintSpacer(depth);
   std::cout << name << ": \"" << str << "\"" << std::endl;
 }

 void Print(int depth, const char* name, const BarPtr& bar) {
   PrintSpacer(depth);
   std::cout << name << ":" << std::endl;
   if (!bar.is_null()) {
     ++depth;
     Print(depth, "alpha", bar->alpha);
     Print(depth, "beta", bar->beta);
     Print(depth, "gamma", bar->gamma);
     Print(depth, "packed", bar.To<int32_t>());
     --depth;
   }
 }

 template <typename T>
 void Print(int depth, const char* name, const std::vector<T>& array) {
   PrintSpacer(depth);
   std::cout << name << ":" << std::endl;
   ++depth;
   for (size_t i = 0; i < array.size(); ++i) {
     std::stringstream buf;
     buf << i;
     Print(depth, buf.str().data(), array.at(i));
   }
   --depth;
 }

 template <typename T>
 void Print(int depth,
            const char* name,
            const base::Optional<std::vector<T>>& array) {
   if (array)
     Print(depth, name, *array);
   else
     Print(depth, name, std::vector<T>());
 }

 void Print(int depth, const char* name, const FooPtr& foo) {
   PrintSpacer(depth);
   std::cout << name << ":" << std::endl;
   if (!foo.is_null()) {
     ++depth;
     Print(depth, "name", foo->name);
     Print(depth, "x", foo->x);
     Print(depth, "y", foo->y);
     Print(depth, "a", foo->a);
     Print(depth, "b", foo->b);
     Print(depth, "c", foo->c);
     Print(depth, "bar", foo->bar);
     Print(depth, "extra_bars", foo->extra_bars);
     Print(depth, "data", foo->data);
     Print(depth, "source", foo->source);
     Print(depth, "input_streams", foo->input_streams);
     Print(depth, "output_streams", foo->output_streams);
     Print(depth, "array_of_array_of_bools", foo->array_of_array_of_bools);
     --depth;
   }
 }

 void DumpHex(const uint8_t* bytes, uint32_t num_bytes) {
   for (uint32_t i = 0; i < num_bytes; ++i) {
     std::cout << std::setw(2) << std::setfill('0') << std::hex
               << uint32_t(bytes[i]);

     if (i % 16 == 15) {
       std::cout << std::endl;
       continue;
     }

     if (i % 2 == 1)
       std::cout << " ";
     if (i % 8 == 7)
       std::cout << " ";
   }
 }

 class ServiceImpl : public Service {
  public:
   void Frobinate(FooPtr foo,
                  BazOptions baz,
                  PortPtr port,
                  const Service::FrobinateCallback& callback) override {
     // Users code goes here to handle the incoming Frobinate message.

     // We mainly check that we're given the expected arguments.
     EXPECT_FALSE(foo.is_null());
     if (!foo.is_null())
       CheckFoo(*foo);
     EXPECT_EQ(BazOptions::EXTRA, baz);

     if (g_dump_message_as_text) {
       // Also dump the Foo structure and all of its members.
       std::cout << "Frobinate:" << std::endl;
       int depth = 1;
       Print(depth, "foo", foo);
       Print(depth, "baz", static_cast<int32_t>(baz));
       Print(depth, "port", port.get());
     }
     callback.Run(5);
   }

   void GetPort(mojo::InterfaceRequest<Port> port_request) override {}
 };

 class ServiceProxyImpl : public ServiceProxy {
  public:
   explicit ServiceProxyImpl(mojo::MessageReceiverWithResponder* receiver)
       : ServiceProxy(receiver) {}
 };

 class SimpleMessageReceiver : public mojo::MessageReceiverWithResponder {
  public:
   bool Accept(mojo::Message* message) override {
     // Imagine some IPC happened here.

     if (g_dump_message_as_hex) {
       DumpHex(reinterpret_cast<const uint8_t*>(message->data()),
               message->data_num_bytes());
     }

     // In the receiving process, an implementation of ServiceStub is known to
     // the system. It receives the incoming message.
     ServiceImpl impl;

     ServiceStub<> stub;
     stub.set_sink(&impl);
     return stub.Accept(message);
   }

   bool AcceptWithResponder(
       mojo::Message* message,
       std::unique_ptr<mojo::MessageReceiver> responder) override {
     return false;
   }
 };

 using BindingsSampleTest = testing::Test;

 TEST_F(BindingsSampleTest, Basic) {
   SimpleMessageReceiver receiver;

   // User has a proxy to a Service somehow.
   Service* service = new ServiceProxyImpl(&receiver);

   // User constructs a message to send.

   // Notice that it doesn't matter in what order the structs / arrays are
   // allocated. Here, the various members of Foo are allocated before Foo is
   // allocated.

   FooPtr foo = MakeFoo();
   CheckFoo(*foo);

   PortPtr port;
   service->Frobinate(std::move(foo), Service::BazOptions::EXTRA,
                      std::move(port), Service::FrobinateCallback());

   delete service;
 }

 TEST_F(BindingsSampleTest, DefaultValues) {
   DefaultsTestPtr defaults(DefaultsTest::New());
   EXPECT_EQ(-12, defaults->a0);
   EXPECT_EQ(kTwelve, defaults->a1);
   EXPECT_EQ(1234, defaults->a2);
   EXPECT_EQ(34567U, defaults->a3);
   EXPECT_EQ(123456, defaults->a4);
   EXPECT_EQ(3456789012U, defaults->a5);
   EXPECT_EQ(-111111111111LL, defaults->a6);
   EXPECT_EQ(9999999999999999999ULL, defaults->a7);
   EXPECT_EQ(0x12345, defaults->a8);
   EXPECT_EQ(-0x12345, defaults->a9);
   EXPECT_EQ(1234, defaults->a10);
   EXPECT_TRUE(defaults->a11);
   EXPECT_FALSE(defaults->a12);
   EXPECT_FLOAT_EQ(123.25f, defaults->a13);
   EXPECT_DOUBLE_EQ(1234567890.123, defaults->a14);
   EXPECT_DOUBLE_EQ(1E10, defaults->a15);
   EXPECT_DOUBLE_EQ(-1.2E+20, defaults->a16);
   EXPECT_DOUBLE_EQ(1.23E-20, defaults->a17);
   EXPECT_TRUE(defaults->a18.empty());
   EXPECT_TRUE(defaults->a19.empty());
   EXPECT_EQ(Bar::Type::BOTH, defaults->a20);
   EXPECT_TRUE(defaults->a21.is_null());
   ASSERT_FALSE(defaults->a22.is_null());
   EXPECT_EQ(imported::Shape::RECTANGLE, defaults->a22->shape);
   EXPECT_EQ(imported::Color::BLACK, defaults->a22->color);
   EXPECT_EQ(0xFFFFFFFFFFFFFFFFULL, defaults->a23);
   EXPECT_EQ(0x123456789, defaults->a24);
   EXPECT_EQ(-0x123456789, defaults->a25);
 }

 }  // namespace
 }  // namespace sample
	// Copyright 2014 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 <stddef.h>
	#include <stdint.h>
	#include <algorithm>
	#include <ostream>
	#include <string>
	#include <utility>

	#include "mojo/public/interfaces/bindings/tests/sample_service.mojom.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace mojo {

	template <>
	struct TypeConverter<int32_t, sample::BarPtr> {
	static int32_t Convert(const sample::BarPtr& bar) {
	return static_cast<int32_t>(bar->alpha) << 16 \|
	static_cast<int32_t>(bar->beta) << 8 \|
	static_cast<int32_t>(bar->gamma);
	}
	};

	} // namespace mojo

	namespace sample {
	namespace {

	// Set this variable to true to print the message in hex.
	bool g_dump_message_as_hex = false;

	// Set this variable to true to print the message in human readable form.
	bool g_dump_message_as_text = false;

	// Make a sample \|Foo\|.
	FooPtr MakeFoo() {
	std::string name("foopy");

	BarPtr bar(Bar::New(20, 40, 60, Bar::Type::VERTICAL));

	std::vector<BarPtr> extra_bars(3);
	for (size_t i = 0; i < extra_bars.size(); ++i) {
	Bar::Type type = i % 2 == 0 ? Bar::Type::VERTICAL : Bar::Type::HORIZONTAL;
	uint8_t base = static_cast<uint8_t>(i * 100);
	extra_bars[i] = Bar::New(base, base + 20, base + 40, type);
	}

	std::vector<uint8_t> data(10);
	for (size_t i = 0; i < data.size(); ++i)
	data[i] = static_cast<uint8_t>(data.size() - i);

	std::vector<mojo::ScopedDataPipeConsumerHandle> input_streams(2);
	std::vector<mojo::ScopedDataPipeProducerHandle> output_streams(2);
	for (size_t i = 0; i < input_streams.size(); ++i) {
	MojoCreateDataPipeOptions options;
	options.struct_size = sizeof(MojoCreateDataPipeOptions);
	options.flags = MOJO_CREATE_DATA_PIPE_OPTIONS_FLAG_NONE;
	options.element_num_bytes = 1;
	options.capacity_num_bytes = 1024;
	mojo::ScopedDataPipeProducerHandle producer;
	mojo::ScopedDataPipeConsumerHandle consumer;
	mojo::CreateDataPipe(&options, &producer, &consumer);
	input_streams[i] = std::move(consumer);
	output_streams[i] = std::move(producer);
	}

	std::vector<std::vector<bool>> array_of_array_of_bools(2);
	for (size_t i = 0; i < 2; ++i) {
	std::vector<bool> array_of_bools(2);
	for (size_t j = 0; j < 2; ++j)
	array_of_bools[j] = j;
	array_of_array_of_bools[i] = std::move(array_of_bools);
	}

	mojo::MessagePipe pipe;
	return Foo::New(name, 1, 2, false, true, false, std::move(bar),
	std::move(extra_bars), std::move(data),
	std::move(pipe.handle1), std::move(input_streams),
	std::move(output_streams), std::move(array_of_array_of_bools),
	base::nullopt, base::nullopt);
	}

	// Check that the given \|Foo\| is identical to the one made by \|MakeFoo()\|.
	void CheckFoo(const Foo& foo) {
	const std::string kName("foopy");
	EXPECT_EQ(kName.size(), foo.name.size());
	for (size_t i = 0; i < std::min(kName.size(), foo.name.size()); i++) {
	// Test both \|operator[]\| and \|at\|.
	EXPECT_EQ(kName[i], foo.name.at(i)) << i;
	EXPECT_EQ(kName[i], foo.name[i]) << i;
	}
	EXPECT_EQ(kName, foo.name);

	EXPECT_EQ(1, foo.x);
	EXPECT_EQ(2, foo.y);
	EXPECT_FALSE(foo.a);
	EXPECT_TRUE(foo.b);
	EXPECT_FALSE(foo.c);

	EXPECT_EQ(20, foo.bar->alpha);
	EXPECT_EQ(40, foo.bar->beta);
	EXPECT_EQ(60, foo.bar->gamma);
	EXPECT_EQ(Bar::Type::VERTICAL, foo.bar->type);

	EXPECT_EQ(3u, foo.extra_bars->size());
	for (size_t i = 0; i < foo.extra_bars->size(); i++) {
	uint8_t base = static_cast<uint8_t>(i * 100);
	Bar::Type type = i % 2 == 0 ? Bar::Type::VERTICAL : Bar::Type::HORIZONTAL;
	EXPECT_EQ(base, (*foo.extra_bars)[i]->alpha) << i;
	EXPECT_EQ(base + 20, (*foo.extra_bars)[i]->beta) << i;
	EXPECT_EQ(base + 40, (*foo.extra_bars)[i]->gamma) << i;
	EXPECT_EQ(type, (*foo.extra_bars)[i]->type) << i;
	}

	EXPECT_EQ(10u, foo.data->size());
	for (size_t i = 0; i < foo.data->size(); ++i) {
	EXPECT_EQ(static_cast<uint8_t>(foo.data->size() - i), (*foo.data)[i]) << i;
	}

	EXPECT_TRUE(foo.input_streams);
	EXPECT_EQ(2u, foo.input_streams->size());

	EXPECT_TRUE(foo.output_streams);
	EXPECT_EQ(2u, foo.output_streams->size());

	EXPECT_EQ(2u, foo.array_of_array_of_bools->size());
	for (size_t i = 0; i < foo.array_of_array_of_bools->size(); ++i) {
	EXPECT_EQ(2u, (*foo.array_of_array_of_bools)[i].size());
	for (size_t j = 0; j < (*foo.array_of_array_of_bools)[i].size(); ++j) {
	EXPECT_EQ(bool(j), (*foo.array_of_array_of_bools)[i][j]);
	}
	}
	}

	void PrintSpacer(int depth) {
	for (int i = 0; i < depth; ++i)
	std::cout << " ";
	}

	void Print(int depth, const char* name, bool value) {
	PrintSpacer(depth);
	std::cout << name << ": " << (value ? "true" : "false") << std::endl;
	}

	void Print(int depth, const char* name, int32_t value) {
	PrintSpacer(depth);
	std::cout << name << ": " << value << std::endl;
	}

	void Print(int depth, const char* name, uint8_t value) {
	PrintSpacer(depth);
	std::cout << name << ": " << uint32_t(value) << std::endl;
	}

	template <typename H>
	void Print(int depth,
	const char* name,
	const mojo::ScopedHandleBase<H>& value) {
	PrintSpacer(depth);
	std::cout << name << ": 0x" << std::hex << value.get().value() << std::endl;
	}

	void Print(int depth, const char* name, const std::string& str) {
	PrintSpacer(depth);
	std::cout << name << ": \"" << str << "\"" << std::endl;
	}

	void Print(int depth, const char* name, const BarPtr& bar) {
	PrintSpacer(depth);
	std::cout << name << ":" << std::endl;
	if (!bar.is_null()) {
	++depth;
	Print(depth, "alpha", bar->alpha);
	Print(depth, "beta", bar->beta);
	Print(depth, "gamma", bar->gamma);
	Print(depth, "packed", bar.To<int32_t>());
	--depth;
	}
	}

	template <typename T>
	void Print(int depth, const char* name, const std::vector<T>& array) {
	PrintSpacer(depth);
	std::cout << name << ":" << std::endl;
	++depth;
	for (size_t i = 0; i < array.size(); ++i) {
	std::stringstream buf;
	buf << i;
	Print(depth, buf.str().data(), array.at(i));
	}
	--depth;
	}

	template <typename T>
	void Print(int depth,
	const char* name,
	const base::Optional<std::vector<T>>& array) {
	if (array)
	Print(depth, name, *array);
	else
	Print(depth, name, std::vector<T>());
	}

	void Print(int depth, const char* name, const FooPtr& foo) {
	PrintSpacer(depth);
	std::cout << name << ":" << std::endl;
	if (!foo.is_null()) {
	++depth;
	Print(depth, "name", foo->name);
	Print(depth, "x", foo->x);
	Print(depth, "y", foo->y);
	Print(depth, "a", foo->a);
	Print(depth, "b", foo->b);
	Print(depth, "c", foo->c);
	Print(depth, "bar", foo->bar);
	Print(depth, "extra_bars", foo->extra_bars);
	Print(depth, "data", foo->data);
	Print(depth, "source", foo->source);
	Print(depth, "input_streams", foo->input_streams);
	Print(depth, "output_streams", foo->output_streams);
	Print(depth, "array_of_array_of_bools", foo->array_of_array_of_bools);
	--depth;
	}
	}

	void DumpHex(const uint8_t* bytes, uint32_t num_bytes) {
	for (uint32_t i = 0; i < num_bytes; ++i) {
	std::cout << std::setw(2) << std::setfill('0') << std::hex
	<< uint32_t(bytes[i]);

	if (i % 16 == 15) {
	std::cout << std::endl;
	continue;
	}

	if (i % 2 == 1)
	std::cout << " ";
	if (i % 8 == 7)
	std::cout << " ";
	}
	}

	class ServiceImpl : public Service {
	public:
	void Frobinate(FooPtr foo,
	BazOptions baz,
	PortPtr port,
	const Service::FrobinateCallback& callback) override {
	// Users code goes here to handle the incoming Frobinate message.

	// We mainly check that we're given the expected arguments.
	EXPECT_FALSE(foo.is_null());
	if (!foo.is_null())
	CheckFoo(*foo);
	EXPECT_EQ(BazOptions::EXTRA, baz);

	if (g_dump_message_as_text) {
	// Also dump the Foo structure and all of its members.
	std::cout << "Frobinate:" << std::endl;
	int depth = 1;
	Print(depth, "foo", foo);
	Print(depth, "baz", static_cast<int32_t>(baz));
	Print(depth, "port", port.get());
	}
	callback.Run(5);
	}

	void GetPort(mojo::InterfaceRequest<Port> port_request) override {}
	};

	class ServiceProxyImpl : public ServiceProxy {
	public:
	explicit ServiceProxyImpl(mojo::MessageReceiverWithResponder* receiver)
	: ServiceProxy(receiver) {}
	};

	class SimpleMessageReceiver : public mojo::MessageReceiverWithResponder {
	public:
	bool Accept(mojo::Message* message) override {
	// Imagine some IPC happened here.

	if (g_dump_message_as_hex) {
	DumpHex(reinterpret_cast<const uint8_t*>(message->data()),
	message->data_num_bytes());
	}

	// In the receiving process, an implementation of ServiceStub is known to
	// the system. It receives the incoming message.
	ServiceImpl impl;

	ServiceStub<> stub;
	stub.set_sink(&impl);
	return stub.Accept(message);
	}

	bool AcceptWithResponder(
	mojo::Message* message,
	std::unique_ptr<mojo::MessageReceiver> responder) override {
	return false;
	}
	};

	using BindingsSampleTest = testing::Test;

	TEST_F(BindingsSampleTest, Basic) {
	SimpleMessageReceiver receiver;

	// User has a proxy to a Service somehow.
	Service* service = new ServiceProxyImpl(&receiver);

	// User constructs a message to send.

	// Notice that it doesn't matter in what order the structs / arrays are
	// allocated. Here, the various members of Foo are allocated before Foo is
	// allocated.

	FooPtr foo = MakeFoo();
	CheckFoo(*foo);

	PortPtr port;
	service->Frobinate(std::move(foo), Service::BazOptions::EXTRA,
	std::move(port), Service::FrobinateCallback());

	delete service;
	}

	TEST_F(BindingsSampleTest, DefaultValues) {
	DefaultsTestPtr defaults(DefaultsTest::New());
	EXPECT_EQ(-12, defaults->a0);
	EXPECT_EQ(kTwelve, defaults->a1);
	EXPECT_EQ(1234, defaults->a2);
	EXPECT_EQ(34567U, defaults->a3);
	EXPECT_EQ(123456, defaults->a4);
	EXPECT_EQ(3456789012U, defaults->a5);
	EXPECT_EQ(-111111111111LL, defaults->a6);
	EXPECT_EQ(9999999999999999999ULL, defaults->a7);
	EXPECT_EQ(0x12345, defaults->a8);
	EXPECT_EQ(-0x12345, defaults->a9);
	EXPECT_EQ(1234, defaults->a10);
	EXPECT_TRUE(defaults->a11);
	EXPECT_FALSE(defaults->a12);
	EXPECT_FLOAT_EQ(123.25f, defaults->a13);
	EXPECT_DOUBLE_EQ(1234567890.123, defaults->a14);
	EXPECT_DOUBLE_EQ(1E10, defaults->a15);
	EXPECT_DOUBLE_EQ(-1.2E+20, defaults->a16);
	EXPECT_DOUBLE_EQ(1.23E-20, defaults->a17);
	EXPECT_TRUE(defaults->a18.empty());
	EXPECT_TRUE(defaults->a19.empty());
	EXPECT_EQ(Bar::Type::BOTH, defaults->a20);
	EXPECT_TRUE(defaults->a21.is_null());
	ASSERT_FALSE(defaults->a22.is_null());
	EXPECT_EQ(imported::Shape::RECTANGLE, defaults->a22->shape);
	EXPECT_EQ(imported::Color::BLACK, defaults->a22->color);
	EXPECT_EQ(0xFFFFFFFFFFFFFFFFULL, defaults->a23);
	EXPECT_EQ(0x123456789, defaults->a24);
	EXPECT_EQ(-0x123456789, defaults->a25);
	}

	} // namespace
	} // namespace sample