// 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 "base/atomicops.h" #include "base/basictypes.h" #include "base/memory/scoped_ptr.h" #include "base/memory/shared_memory.h" #include "base/process/kill.h" #include "base/rand_util.h" #include "base/strings/string_number_conversions.h" #include "base/sys_info.h" #include "base/test/multiprocess_test.h" #include "base/threading/platform_thread.h" #include "base/time/time.h" #include "testing/gtest/include/gtest/gtest.h" #include "testing/multiprocess_func_list.h" #if defined(OS_POSIX) #include #include #include #include #include #include #endif #if defined(OS_WIN) #include "base/win/scoped_handle.h" #endif namespace base { namespace { #if !defined(OS_MACOSX) // Each thread will open the shared memory. Each thread will take a different 4 // byte int pointer, and keep changing it, with some small pauses in between. // Verify that each thread's value in the shared memory is always correct. class MultipleThreadMain : public PlatformThread::Delegate { public: explicit MultipleThreadMain(int16 id) : id_(id) {} ~MultipleThreadMain() override {} static void CleanUp() { SharedMemory memory; memory.Delete(s_test_name_); } // PlatformThread::Delegate interface. void ThreadMain() override { const uint32 kDataSize = 1024; SharedMemory memory; bool rv = memory.CreateNamedDeprecated(s_test_name_, true, kDataSize); EXPECT_TRUE(rv); rv = memory.Map(kDataSize); EXPECT_TRUE(rv); int* ptr = static_cast(memory.memory()) + id_; EXPECT_EQ(0, *ptr); for (int idx = 0; idx < 100; idx++) { *ptr = idx; PlatformThread::Sleep(TimeDelta::FromMilliseconds(1)); EXPECT_EQ(*ptr, idx); } // Reset back to 0 for the next test that uses the same name. *ptr = 0; memory.Close(); } private: int16 id_; static const char* const s_test_name_; DISALLOW_COPY_AND_ASSIGN(MultipleThreadMain); }; const char* const MultipleThreadMain::s_test_name_ = "SharedMemoryOpenThreadTest"; #endif // !defined(OS_MACOSX) } // namespace // Android/Mac doesn't support SharedMemory::Open/Delete/ // CreateNamedDeprecated(openExisting=true) #if !defined(OS_ANDROID) && !defined(OS_MACOSX) TEST(SharedMemoryTest, OpenClose) { const uint32 kDataSize = 1024; std::string test_name = "SharedMemoryOpenCloseTest"; // Open two handles to a memory segment, confirm that they are mapped // separately yet point to the same space. SharedMemory memory1; bool rv = memory1.Delete(test_name); EXPECT_TRUE(rv); rv = memory1.Delete(test_name); EXPECT_TRUE(rv); rv = memory1.Open(test_name, false); EXPECT_FALSE(rv); rv = memory1.CreateNamedDeprecated(test_name, false, kDataSize); EXPECT_TRUE(rv); rv = memory1.Map(kDataSize); EXPECT_TRUE(rv); SharedMemory memory2; rv = memory2.Open(test_name, false); EXPECT_TRUE(rv); rv = memory2.Map(kDataSize); EXPECT_TRUE(rv); EXPECT_NE(memory1.memory(), memory2.memory()); // Compare the pointers. // Make sure we don't segfault. (it actually happened!) ASSERT_NE(memory1.memory(), static_cast(NULL)); ASSERT_NE(memory2.memory(), static_cast(NULL)); // Write data to the first memory segment, verify contents of second. memset(memory1.memory(), '1', kDataSize); EXPECT_EQ(memcmp(memory1.memory(), memory2.memory(), kDataSize), 0); // Close the first memory segment, and verify the second has the right data. memory1.Close(); char* start_ptr = static_cast(memory2.memory()); char* end_ptr = start_ptr + kDataSize; for (char* ptr = start_ptr; ptr < end_ptr; ptr++) EXPECT_EQ(*ptr, '1'); // Close the second memory segment. memory2.Close(); rv = memory1.Delete(test_name); EXPECT_TRUE(rv); rv = memory2.Delete(test_name); EXPECT_TRUE(rv); } TEST(SharedMemoryTest, OpenExclusive) { const uint32 kDataSize = 1024; const uint32 kDataSize2 = 2048; std::ostringstream test_name_stream; test_name_stream << "SharedMemoryOpenExclusiveTest." << Time::Now().ToDoubleT(); std::string test_name = test_name_stream.str(); // Open two handles to a memory segment and check that // open_existing_deprecated works as expected. SharedMemory memory1; bool rv = memory1.CreateNamedDeprecated(test_name, false, kDataSize); EXPECT_TRUE(rv); // Memory1 knows it's size because it created it. EXPECT_EQ(memory1.requested_size(), kDataSize); rv = memory1.Map(kDataSize); EXPECT_TRUE(rv); // The mapped memory1 must be at least the size we asked for. EXPECT_GE(memory1.mapped_size(), kDataSize); // The mapped memory1 shouldn't exceed rounding for allocation granularity. EXPECT_LT(memory1.mapped_size(), kDataSize + SysInfo::VMAllocationGranularity()); memset(memory1.memory(), 'G', kDataSize); SharedMemory memory2; // Should not be able to create if openExisting is false. rv = memory2.CreateNamedDeprecated(test_name, false, kDataSize2); EXPECT_FALSE(rv); // Should be able to create with openExisting true. rv = memory2.CreateNamedDeprecated(test_name, true, kDataSize2); EXPECT_TRUE(rv); // Memory2 shouldn't know the size because we didn't create it. EXPECT_EQ(memory2.requested_size(), 0U); // We should be able to map the original size. rv = memory2.Map(kDataSize); EXPECT_TRUE(rv); // The mapped memory2 must be at least the size of the original. EXPECT_GE(memory2.mapped_size(), kDataSize); // The mapped memory2 shouldn't exceed rounding for allocation granularity. EXPECT_LT(memory2.mapped_size(), kDataSize2 + SysInfo::VMAllocationGranularity()); // Verify that opening memory2 didn't truncate or delete memory 1. char* start_ptr = static_cast(memory2.memory()); char* end_ptr = start_ptr + kDataSize; for (char* ptr = start_ptr; ptr < end_ptr; ptr++) { EXPECT_EQ(*ptr, 'G'); } memory1.Close(); memory2.Close(); rv = memory1.Delete(test_name); EXPECT_TRUE(rv); } #endif // !defined(OS_ANDROID) && !defined(OS_MACOSX) // Check that memory is still mapped after its closed. TEST(SharedMemoryTest, CloseNoUnmap) { const size_t kDataSize = 4096; SharedMemory memory; ASSERT_TRUE(memory.CreateAndMapAnonymous(kDataSize)); char* ptr = static_cast(memory.memory()); ASSERT_NE(ptr, static_cast(NULL)); memset(ptr, 'G', kDataSize); memory.Close(); EXPECT_EQ(ptr, memory.memory()); EXPECT_EQ(SharedMemory::NULLHandle(), memory.handle()); for (size_t i = 0; i < kDataSize; i++) { EXPECT_EQ('G', ptr[i]); } memory.Unmap(); EXPECT_EQ(nullptr, memory.memory()); } #if !defined(OS_MACOSX) // Create a set of N threads to each open a shared memory segment and write to // it. Verify that they are always reading/writing consistent data. TEST(SharedMemoryTest, MultipleThreads) { const int kNumThreads = 5; MultipleThreadMain::CleanUp(); // On POSIX we have a problem when 2 threads try to create the shmem // (a file) at exactly the same time, since create both creates the // file and zerofills it. We solve the problem for this unit test // (make it not flaky) by starting with 1 thread, then // intentionally don't clean up its shmem before running with // kNumThreads. int threadcounts[] = { 1, kNumThreads }; for (size_t i = 0; i < arraysize(threadcounts); i++) { int numthreads = threadcounts[i]; scoped_ptr thread_handles; scoped_ptr thread_delegates; thread_handles.reset(new PlatformThreadHandle[numthreads]); thread_delegates.reset(new MultipleThreadMain*[numthreads]); // Spawn the threads. for (int16 index = 0; index < numthreads; index++) { PlatformThreadHandle pth; thread_delegates[index] = new MultipleThreadMain(index); EXPECT_TRUE(PlatformThread::Create(0, thread_delegates[index], &pth)); thread_handles[index] = pth; } // Wait for the threads to finish. for (int index = 0; index < numthreads; index++) { PlatformThread::Join(thread_handles[index]); delete thread_delegates[index]; } } MultipleThreadMain::CleanUp(); } #endif // Allocate private (unique) shared memory with an empty string for a // name. Make sure several of them don't point to the same thing as // we might expect if the names are equal. TEST(SharedMemoryTest, AnonymousPrivate) { int i, j; int count = 4; bool rv; const uint32 kDataSize = 8192; scoped_ptr memories(new SharedMemory[count]); scoped_ptr pointers(new int*[count]); ASSERT_TRUE(memories.get()); ASSERT_TRUE(pointers.get()); for (i = 0; i < count; i++) { rv = memories[i].CreateAndMapAnonymous(kDataSize); EXPECT_TRUE(rv); int* ptr = static_cast(memories[i].memory()); EXPECT_TRUE(ptr); pointers[i] = ptr; } for (i = 0; i < count; i++) { // zero out the first int in each except for i; for that one, make it 100. for (j = 0; j < count; j++) { if (i == j) pointers[j][0] = 100; else pointers[j][0] = 0; } // make sure there is no bleeding of the 100 into the other pointers for (j = 0; j < count; j++) { if (i == j) EXPECT_EQ(100, pointers[j][0]); else EXPECT_EQ(0, pointers[j][0]); } } for (int i = 0; i < count; i++) { memories[i].Close(); } } TEST(SharedMemoryTest, ShareReadOnly) { StringPiece contents = "Hello World"; SharedMemory writable_shmem; SharedMemoryCreateOptions options; options.size = contents.size(); options.share_read_only = true; ASSERT_TRUE(writable_shmem.Create(options)); ASSERT_TRUE(writable_shmem.Map(options.size)); memcpy(writable_shmem.memory(), contents.data(), contents.size()); EXPECT_TRUE(writable_shmem.Unmap()); SharedMemoryHandle readonly_handle; ASSERT_TRUE(writable_shmem.ShareReadOnlyToProcess(GetCurrentProcessHandle(), &readonly_handle)); SharedMemory readonly_shmem(readonly_handle, /*readonly=*/true); ASSERT_TRUE(readonly_shmem.Map(contents.size())); EXPECT_EQ(contents, StringPiece(static_cast(readonly_shmem.memory()), contents.size())); EXPECT_TRUE(readonly_shmem.Unmap()); // Make sure the writable instance is still writable. ASSERT_TRUE(writable_shmem.Map(contents.size())); StringPiece new_contents = "Goodbye"; memcpy(writable_shmem.memory(), new_contents.data(), new_contents.size()); EXPECT_EQ(new_contents, StringPiece(static_cast(writable_shmem.memory()), new_contents.size())); // We'd like to check that if we send the read-only segment to another // process, then that other process can't reopen it read/write. (Since that // would be a security hole.) Setting up multiple processes is hard in a // unittest, so this test checks that the *current* process can't reopen the // segment read/write. I think the test here is stronger than we actually // care about, but there's a remote possibility that sending a file over a // pipe would transform it into read/write. SharedMemoryHandle handle = readonly_shmem.handle(); #if defined(OS_ANDROID) // The "read-only" handle is still writable on Android: // http://crbug.com/320865 (void)handle; #elif defined(OS_POSIX) int handle_fd = SharedMemory::GetFdFromSharedMemoryHandle(handle); EXPECT_EQ(O_RDONLY, fcntl(handle_fd, F_GETFL) & O_ACCMODE) << "The descriptor itself should be read-only."; errno = 0; void* writable = mmap(NULL, contents.size(), PROT_READ | PROT_WRITE, MAP_SHARED, handle_fd, 0); int mmap_errno = errno; EXPECT_EQ(MAP_FAILED, writable) << "It shouldn't be possible to re-mmap the descriptor writable."; EXPECT_EQ(EACCES, mmap_errno) << strerror(mmap_errno); if (writable != MAP_FAILED) EXPECT_EQ(0, munmap(writable, readonly_shmem.mapped_size())); #elif defined(OS_WIN) EXPECT_EQ(NULL, MapViewOfFile(handle.GetHandle(), FILE_MAP_WRITE, 0, 0, 0)) << "Shouldn't be able to map memory writable."; HANDLE temp_handle; BOOL rv = ::DuplicateHandle(GetCurrentProcess(), handle.GetHandle(), GetCurrentProcess(), &temp_handle, FILE_MAP_ALL_ACCESS, false, 0); EXPECT_EQ(FALSE, rv) << "Shouldn't be able to duplicate the handle into a writable one."; if (rv) win::ScopedHandle writable_handle(temp_handle); rv = ::DuplicateHandle(GetCurrentProcess(), handle.GetHandle(), GetCurrentProcess(), &temp_handle, FILE_MAP_READ, false, 0); EXPECT_EQ(TRUE, rv) << "Should be able to duplicate the handle into a readable one."; if (rv) win::ScopedHandle writable_handle(temp_handle); #else #error Unexpected platform; write a test that tries to make 'handle' writable. #endif // defined(OS_POSIX) || defined(OS_WIN) } TEST(SharedMemoryTest, ShareToSelf) { StringPiece contents = "Hello World"; SharedMemory shmem; ASSERT_TRUE(shmem.CreateAndMapAnonymous(contents.size())); memcpy(shmem.memory(), contents.data(), contents.size()); EXPECT_TRUE(shmem.Unmap()); SharedMemoryHandle shared_handle; ASSERT_TRUE(shmem.ShareToProcess(GetCurrentProcessHandle(), &shared_handle)); SharedMemory shared(shared_handle, /*readonly=*/false); ASSERT_TRUE(shared.Map(contents.size())); EXPECT_EQ( contents, StringPiece(static_cast(shared.memory()), contents.size())); shared_handle = SharedMemoryHandle(); ASSERT_TRUE(shmem.ShareToProcess(GetCurrentProcessHandle(), &shared_handle)); SharedMemory readonly(shared_handle, /*readonly=*/true); ASSERT_TRUE(readonly.Map(contents.size())); EXPECT_EQ(contents, StringPiece(static_cast(readonly.memory()), contents.size())); } TEST(SharedMemoryTest, MapAt) { ASSERT_TRUE(SysInfo::VMAllocationGranularity() >= sizeof(uint32)); const size_t kCount = SysInfo::VMAllocationGranularity(); const size_t kDataSize = kCount * sizeof(uint32); SharedMemory memory; ASSERT_TRUE(memory.CreateAndMapAnonymous(kDataSize)); uint32* ptr = static_cast(memory.memory()); ASSERT_NE(ptr, static_cast(NULL)); for (size_t i = 0; i < kCount; ++i) { ptr[i] = i; } memory.Unmap(); off_t offset = SysInfo::VMAllocationGranularity(); ASSERT_TRUE(memory.MapAt(offset, kDataSize - offset)); offset /= sizeof(uint32); ptr = static_cast(memory.memory()); ASSERT_NE(ptr, static_cast(NULL)); for (size_t i = offset; i < kCount; ++i) { EXPECT_EQ(ptr[i - offset], i); } } TEST(SharedMemoryTest, MapTwice) { const uint32 kDataSize = 1024; SharedMemory memory; bool rv = memory.CreateAndMapAnonymous(kDataSize); EXPECT_TRUE(rv); void* old_address = memory.memory(); rv = memory.Map(kDataSize); EXPECT_FALSE(rv); EXPECT_EQ(old_address, memory.memory()); } #if defined(OS_POSIX) // This test is not applicable for iOS (crbug.com/399384). #if !defined(OS_IOS) // Create a shared memory object, mmap it, and mprotect it to PROT_EXEC. TEST(SharedMemoryTest, AnonymousExecutable) { const uint32 kTestSize = 1 << 16; SharedMemory shared_memory; SharedMemoryCreateOptions options; options.size = kTestSize; options.executable = true; EXPECT_TRUE(shared_memory.Create(options)); EXPECT_TRUE(shared_memory.Map(shared_memory.requested_size())); EXPECT_EQ(0, mprotect(shared_memory.memory(), shared_memory.requested_size(), PROT_READ | PROT_EXEC)); } #endif // !defined(OS_IOS) // Android supports a different permission model than POSIX for its "ashmem" // shared memory implementation. So the tests about file permissions are not // included on Android. #if !defined(OS_ANDROID) // Set a umask and restore the old mask on destruction. class ScopedUmaskSetter { public: explicit ScopedUmaskSetter(mode_t target_mask) { old_umask_ = umask(target_mask); } ~ScopedUmaskSetter() { umask(old_umask_); } private: mode_t old_umask_; DISALLOW_IMPLICIT_CONSTRUCTORS(ScopedUmaskSetter); }; // Create a shared memory object, check its permissions. TEST(SharedMemoryTest, FilePermissionsAnonymous) { const uint32 kTestSize = 1 << 8; SharedMemory shared_memory; SharedMemoryCreateOptions options; options.size = kTestSize; // Set a file mode creation mask that gives all permissions. ScopedUmaskSetter permissive_mask(S_IWGRP | S_IWOTH); EXPECT_TRUE(shared_memory.Create(options)); int shm_fd = SharedMemory::GetFdFromSharedMemoryHandle(shared_memory.handle()); struct stat shm_stat; EXPECT_EQ(0, fstat(shm_fd, &shm_stat)); // Neither the group, nor others should be able to read the shared memory // file. EXPECT_FALSE(shm_stat.st_mode & S_IRWXO); EXPECT_FALSE(shm_stat.st_mode & S_IRWXG); } // Create a shared memory object, check its permissions. TEST(SharedMemoryTest, FilePermissionsNamed) { const uint32_t kTestSize = 1 << 8; SharedMemory shared_memory; SharedMemoryCreateOptions options; options.size = kTestSize; // Set a file mode creation mask that gives all permissions. ScopedUmaskSetter permissive_mask(S_IWGRP | S_IWOTH); EXPECT_TRUE(shared_memory.Create(options)); int fd = SharedMemory::GetFdFromSharedMemoryHandle(shared_memory.handle()); struct stat shm_stat; EXPECT_EQ(0, fstat(fd, &shm_stat)); // Neither the group, nor others should have been able to open the shared // memory file while its name existed. EXPECT_FALSE(shm_stat.st_mode & S_IRWXO); EXPECT_FALSE(shm_stat.st_mode & S_IRWXG); } #endif // !defined(OS_ANDROID) #endif // defined(OS_POSIX) // Map() will return addresses which are aligned to the platform page size, this // varies from platform to platform though. Since we'd like to advertise a // minimum alignment that callers can count on, test for it here. TEST(SharedMemoryTest, MapMinimumAlignment) { static const int kDataSize = 8192; SharedMemory shared_memory; ASSERT_TRUE(shared_memory.CreateAndMapAnonymous(kDataSize)); EXPECT_EQ(0U, reinterpret_cast( shared_memory.memory()) & (SharedMemory::MAP_MINIMUM_ALIGNMENT - 1)); shared_memory.Close(); } // iOS does not allow multiple processes. // Android ashmem does not support named shared memory. // Mac SharedMemory does not support named shared memory. crbug.com/345734 #if !defined(OS_IOS) && !defined(OS_ANDROID) && !defined(OS_MACOSX) // On POSIX it is especially important we test shmem across processes, // not just across threads. But the test is enabled on all platforms. class SharedMemoryProcessTest : public MultiProcessTest { public: static void CleanUp() { SharedMemory memory; memory.Delete(s_test_name_); } static int TaskTestMain() { int errors = 0; SharedMemory memory; bool rv = memory.CreateNamedDeprecated(s_test_name_, true, s_data_size_); EXPECT_TRUE(rv); if (rv != true) errors++; rv = memory.Map(s_data_size_); EXPECT_TRUE(rv); if (rv != true) errors++; int* ptr = static_cast(memory.memory()); // This runs concurrently in multiple processes. Writes need to be atomic. subtle::Barrier_AtomicIncrement(ptr, 1); memory.Close(); return errors; } static const char* const s_test_name_; static const uint32 s_data_size_; }; const char* const SharedMemoryProcessTest::s_test_name_ = "MPMem"; const uint32 SharedMemoryProcessTest::s_data_size_ = 1024; TEST_F(SharedMemoryProcessTest, SharedMemoryAcrossProcesses) { const int kNumTasks = 5; SharedMemoryProcessTest::CleanUp(); // Create a shared memory region. Set the first word to 0. SharedMemory memory; bool rv = memory.CreateNamedDeprecated(s_test_name_, true, s_data_size_); ASSERT_TRUE(rv); rv = memory.Map(s_data_size_); ASSERT_TRUE(rv); int* ptr = static_cast(memory.memory()); *ptr = 0; // Start |kNumTasks| processes, each of which atomically increments the first // word by 1. Process processes[kNumTasks]; for (int index = 0; index < kNumTasks; ++index) { processes[index] = SpawnChild("SharedMemoryTestMain"); ASSERT_TRUE(processes[index].IsValid()); } // Check that each process exited correctly. int exit_code = 0; for (int index = 0; index < kNumTasks; ++index) { EXPECT_TRUE(processes[index].WaitForExit(&exit_code)); EXPECT_EQ(0, exit_code); } // Check that the shared memory region reflects |kNumTasks| increments. ASSERT_EQ(kNumTasks, *ptr); memory.Close(); SharedMemoryProcessTest::CleanUp(); } MULTIPROCESS_TEST_MAIN(SharedMemoryTestMain) { return SharedMemoryProcessTest::TaskTestMain(); } #endif // !defined(OS_IOS) && !defined(OS_ANDROID) && !defined(OS_MACOSX) } // namespace base