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ipc / ipc_message_utils_unittest.cc [blame]
// Copyright 2012 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "ipc/ipc_message_utils.h"
#include <stddef.h>
#include <stdint.h>
#include <memory>
#include "base/files/file_path.h"
#include "base/json/json_reader.h"
#include "base/memory/ptr_util.h"
#include "base/test/test_shared_memory_util.h"
#include "base/unguessable_token.h"
#include "build/build_config.h"
#include "ipc/ipc_channel_handle.h"
#include "ipc/ipc_message.h"
#include "testing/gtest/include/gtest/gtest.h"
#if BUILDFLAG(IS_WIN)
#include <windows.h>
#endif
namespace IPC {
namespace {
// Tests nesting of messages as parameters to other messages.
TEST(IPCMessageUtilsTest, NestedMessages) {
int32_t nested_routing = 12;
uint32_t nested_type = 78;
int nested_content = 456789;
Message::PriorityValue nested_priority = Message::PRIORITY_HIGH;
Message nested_msg(nested_routing, nested_type, nested_priority);
nested_msg.set_sync();
ParamTraits<int>::Write(&nested_msg, nested_content);
// Outer message contains the nested one as its parameter.
int32_t outer_routing = 91;
uint32_t outer_type = 88;
Message::PriorityValue outer_priority = Message::PRIORITY_NORMAL;
Message outer_msg(outer_routing, outer_type, outer_priority);
ParamTraits<Message>::Write(&outer_msg, nested_msg);
// Read back the nested message.
base::PickleIterator iter(outer_msg);
IPC::Message result_msg;
ASSERT_TRUE(ParamTraits<Message>::Read(&outer_msg, &iter, &result_msg));
// Verify nested message headers.
EXPECT_EQ(nested_msg.routing_id(), result_msg.routing_id());
EXPECT_EQ(nested_msg.type(), result_msg.type());
EXPECT_EQ(nested_msg.priority(), result_msg.priority());
EXPECT_EQ(nested_msg.flags(), result_msg.flags());
// Verify nested message content
base::PickleIterator nested_iter(nested_msg);
int result_content = 0;
ASSERT_TRUE(ParamTraits<int>::Read(&nested_msg, &nested_iter,
&result_content));
EXPECT_EQ(nested_content, result_content);
// Try reading past the ends for both messages and make sure it fails.
IPC::Message dummy;
ASSERT_FALSE(ParamTraits<Message>::Read(&outer_msg, &iter, &dummy));
ASSERT_FALSE(ParamTraits<int>::Read(&nested_msg, &nested_iter,
&result_content));
}
// Tests that detection of various bad parameters is working correctly.
TEST(IPCMessageUtilsTest, ParameterValidation) {
base::FilePath::StringType ok_string(FILE_PATH_LITERAL("hello"), 5);
base::FilePath::StringType bad_string(FILE_PATH_LITERAL("hel\0o"), 5);
// Change this if ParamTraits<FilePath>::Write() changes.
IPC::Message message;
ParamTraits<base::FilePath::StringType>::Write(&message, ok_string);
ParamTraits<base::FilePath::StringType>::Write(&message, bad_string);
base::PickleIterator iter(message);
base::FilePath ok_path;
base::FilePath bad_path;
ASSERT_TRUE(ParamTraits<base::FilePath>::Read(&message, &iter, &ok_path));
ASSERT_FALSE(ParamTraits<base::FilePath>::Read(&message, &iter, &bad_path));
}
TEST(IPCMessageUtilsTest, InlinedVector) {
static constexpr size_t stack_capacity = 5;
absl::InlinedVector<double, stack_capacity> inlined_vector;
for (size_t i = 0; i < 2 * stack_capacity; i++) {
inlined_vector.push_back(i * 2.0);
}
IPC::Message msg(1, 2, IPC::Message::PRIORITY_NORMAL);
IPC::WriteParam(&msg, inlined_vector);
absl::InlinedVector<double, stack_capacity> output;
base::PickleIterator iter(msg);
EXPECT_TRUE(IPC::ReadParam(&msg, &iter, &output));
ASSERT_EQ(inlined_vector.size(), output.size());
for (size_t i = 0; i < 2 * stack_capacity; i++) {
EXPECT_EQ(inlined_vector[i], output[i]);
}
}
TEST(IPCMessageUtilsTest, MojoChannelHandle) {
mojo::MessagePipe message_pipe;
IPC::ChannelHandle channel_handle(message_pipe.handle0.release());
IPC::Message message;
IPC::WriteParam(&message, channel_handle);
base::PickleIterator iter(message);
IPC::ChannelHandle result_handle;
EXPECT_TRUE(IPC::ReadParam(&message, &iter, &result_handle));
EXPECT_EQ(channel_handle.mojo_handle, result_handle.mojo_handle);
}
TEST(IPCMessageUtilsTest, OptionalUnset) {
std::optional<int> opt;
base::Pickle pickle;
IPC::WriteParam(&pickle, opt);
std::string log;
IPC::LogParam(opt, &log);
EXPECT_EQ("(unset)", log);
std::optional<int> unserialized_opt;
base::PickleIterator iter(pickle);
EXPECT_TRUE(IPC::ReadParam(&pickle, &iter, &unserialized_opt));
EXPECT_FALSE(unserialized_opt);
}
TEST(IPCMessageUtilsTest, OptionalSet) {
std::optional<int> opt(10);
base::Pickle pickle;
IPC::WriteParam(&pickle, opt);
std::string log;
IPC::LogParam(opt, &log);
EXPECT_EQ("10", log);
std::optional<int> unserialized_opt;
base::PickleIterator iter(pickle);
EXPECT_TRUE(IPC::ReadParam(&pickle, &iter, &unserialized_opt));
EXPECT_TRUE(unserialized_opt);
EXPECT_EQ(opt.value(), unserialized_opt.value());
}
template <typename SharedMemoryRegionType>
class SharedMemoryRegionTypedTest : public ::testing::Test {};
typedef ::testing::Types<base::WritableSharedMemoryRegion,
base::UnsafeSharedMemoryRegion,
base::ReadOnlySharedMemoryRegion>
AllSharedMemoryRegionTypes;
TYPED_TEST_SUITE(SharedMemoryRegionTypedTest, AllSharedMemoryRegionTypes);
TYPED_TEST(SharedMemoryRegionTypedTest, WriteAndRead) {
const size_t size = 2314;
auto [pre_pickle, pre_mapping] = base::CreateMappedRegion<TypeParam>(size);
const size_t pre_size = pre_pickle.GetSize();
const std::string content = "Hello, world!";
memcpy(pre_mapping.memory(), content.data(), content.size());
IPC::Message message;
IPC::WriteParam(&message, pre_pickle);
EXPECT_FALSE(pre_pickle.IsValid());
TypeParam post_pickle;
base::PickleIterator iter(message);
EXPECT_TRUE(IPC::ReadParam(&message, &iter, &post_pickle));
EXPECT_EQ(pre_size, post_pickle.GetSize());
typename TypeParam::MappingType post_mapping = post_pickle.Map();
EXPECT_EQ(pre_mapping.guid(), post_mapping.guid());
EXPECT_EQ(0, memcmp(pre_mapping.memory(), post_mapping.memory(),
post_pickle.GetSize()));
}
TYPED_TEST(SharedMemoryRegionTypedTest, InvalidRegion) {
TypeParam pre_pickle;
EXPECT_FALSE(pre_pickle.IsValid());
IPC::Message message;
IPC::WriteParam(&message, pre_pickle);
TypeParam post_pickle;
base::PickleIterator iter(message);
EXPECT_TRUE(IPC::ReadParam(&message, &iter, &post_pickle));
EXPECT_FALSE(post_pickle.IsValid());
}
TEST(IPCMessageUtilsTest, UnguessableTokenTest) {
base::UnguessableToken token = base::UnguessableToken::Create();
base::Pickle pickle;
IPC::WriteParam(&pickle, token);
std::string log;
IPC::LogParam(token, &log);
EXPECT_EQ(token.ToString(), log);
base::UnguessableToken deserialized_token;
base::PickleIterator iter(pickle);
EXPECT_TRUE(IPC::ReadParam(&pickle, &iter, &deserialized_token));
EXPECT_EQ(token, deserialized_token);
}
TEST(IPCMessageUtilsTest, FlatMap) {
base::flat_map<std::string, int> input;
input["foo"] = 42;
input["bar"] = 96;
base::Pickle pickle;
IPC::WriteParam(&pickle, input);
base::PickleIterator iter(pickle);
base::flat_map<std::string, int> output;
EXPECT_TRUE(IPC::ReadParam(&pickle, &iter, &output));
EXPECT_EQ(input, output);
}
TEST(IPCMessageUtilsTest, StrongAlias) {
using TestType = base::StrongAlias<class Tag, int>;
TestType input(42);
base::Pickle pickle;
IPC::WriteParam(&pickle, input);
base::PickleIterator iter(pickle);
TestType output;
EXPECT_TRUE(IPC::ReadParam(&pickle, &iter, &output));
EXPECT_EQ(input, output);
}
TEST(IPCMessageUtilsTest, DictValueConversion) {
base::Value::Dict dict_value;
dict_value.Set("path1", 42);
dict_value.Set("path2", 84);
base::Value::List subvalue;
subvalue.Append(1234);
subvalue.Append(5678);
dict_value.Set("path3", std::move(subvalue));
IPC::Message message;
ParamTraits<base::Value::Dict>::Write(&message, dict_value);
base::PickleIterator iter(message);
base::Value::Dict read_value;
ASSERT_TRUE(
ParamTraits<base::Value::Dict>::Read(&message, &iter, &read_value));
EXPECT_EQ(dict_value, read_value);
}
TEST(IPCMessageUtilsTest, ListValueConversion) {
base::Value::List list_value;
list_value.Append(42);
list_value.Append(84);
IPC::Message message;
ParamTraits<base::Value::List>::Write(&message, list_value);
base::PickleIterator iter(message);
base::Value::List read_value;
ASSERT_TRUE(
ParamTraits<base::Value::List>::Read(&message, &iter, &read_value));
EXPECT_EQ(list_value, read_value);
}
#if BUILDFLAG(IS_WIN)
TEST(IPCMessageUtilsTest, ScopedHandle) {
HANDLE raw_dupe_handle;
ASSERT_TRUE(::DuplicateHandle(::GetCurrentProcess(), ::GetCurrentProcess(),
::GetCurrentProcess(), &raw_dupe_handle, 0,
FALSE, DUPLICATE_SAME_ACCESS));
base::win::ScopedHandle dupe_handle(raw_dupe_handle);
Message message(0, 0, Message::PRIORITY_LOW);
WriteParam(&message, dupe_handle);
base::PickleIterator iter(message);
base::win::ScopedHandle read_handle;
EXPECT_TRUE(ReadParam(&message, &iter, &read_handle));
EXPECT_TRUE(read_handle.IsValid());
}
#endif // BUILDFLAG(IS_WIN)
} // namespace
} // namespace IPC