// Copyright (c) 2009 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. #define _CRT_SECURE_NO_WARNINGS #include #include "base/command_line.h" #include "base/eintr_wrapper.h" #include "base/file_path.h" #include "base/multiprocess_test.h" #include "base/path_service.h" #include "base/platform_thread.h" #include "base/process_util.h" #include "base/scoped_ptr.h" #include "testing/gtest/include/gtest/gtest.h" #if defined(OS_LINUX) #include #include #include #endif #if defined(OS_POSIX) #include #include #include #include #endif #if defined(OS_WIN) #include #endif #if defined(OS_MACOSX) #include #include "base/process_util_unittest_mac.h" #endif namespace { #if defined(OS_WIN) const wchar_t* const kProcessName = L"base_unittests.exe"; #else const wchar_t* const kProcessName = L"base_unittests"; #endif // defined(OS_WIN) // Sleeps until file filename is created. void WaitToDie(const char* filename) { FILE *fp; do { PlatformThread::Sleep(10); fp = fopen(filename, "r"); } while (!fp); fclose(fp); } // Signals children they should die now. void SignalChildren(const char* filename) { FILE *fp = fopen(filename, "w"); fclose(fp); } } // namespace class ProcessUtilTest : public MultiProcessTest { #if defined(OS_POSIX) public: // Spawn a child process that counts how many file descriptors are open. int CountOpenFDsInChild(); #endif }; MULTIPROCESS_TEST_MAIN(SimpleChildProcess) { return 0; } TEST_F(ProcessUtilTest, SpawnChild) { base::ProcessHandle handle = this->SpawnChild(L"SimpleChildProcess"); ASSERT_NE(base::kNullProcessHandle, handle); EXPECT_TRUE(base::WaitForSingleProcess(handle, 5000)); base::CloseProcessHandle(handle); } MULTIPROCESS_TEST_MAIN(SlowChildProcess) { WaitToDie("SlowChildProcess.die"); return 0; } TEST_F(ProcessUtilTest, KillSlowChild) { remove("SlowChildProcess.die"); base::ProcessHandle handle = this->SpawnChild(L"SlowChildProcess"); ASSERT_NE(base::kNullProcessHandle, handle); SignalChildren("SlowChildProcess.die"); EXPECT_TRUE(base::WaitForSingleProcess(handle, 5000)); base::CloseProcessHandle(handle); remove("SlowChildProcess.die"); } TEST_F(ProcessUtilTest, DidProcessCrash) { remove("SlowChildProcess.die"); base::ProcessHandle handle = this->SpawnChild(L"SlowChildProcess"); ASSERT_NE(base::kNullProcessHandle, handle); bool child_exited = true; EXPECT_FALSE(base::DidProcessCrash(&child_exited, handle)); EXPECT_FALSE(child_exited); SignalChildren("SlowChildProcess.die"); EXPECT_TRUE(base::WaitForSingleProcess(handle, 5000)); EXPECT_FALSE(base::DidProcessCrash(&child_exited, handle)); base::CloseProcessHandle(handle); remove("SlowChildProcess.die"); } // Ensure that the priority of a process is restored correctly after // backgrounding and restoring. // Note: a platform may not be willing or able to lower the priority of // a process. The calls to SetProcessBackground should be noops then. TEST_F(ProcessUtilTest, SetProcessBackgrounded) { base::ProcessHandle handle = this->SpawnChild(L"SimpleChildProcess"); base::Process process(handle); int old_priority = process.GetPriority(); process.SetProcessBackgrounded(true); process.SetProcessBackgrounded(false); int new_priority = process.GetPriority(); EXPECT_EQ(old_priority, new_priority); } // TODO(estade): if possible, port these 2 tests. #if defined(OS_WIN) TEST_F(ProcessUtilTest, EnableLFH) { ASSERT_TRUE(base::EnableLowFragmentationHeap()); if (IsDebuggerPresent()) { // Under these conditions, LFH can't be enabled. There's no point to test // anything. const char* no_debug_env = getenv("_NO_DEBUG_HEAP"); if (!no_debug_env || strcmp(no_debug_env, "1")) return; } HANDLE heaps[1024] = { 0 }; unsigned number_heaps = GetProcessHeaps(1024, heaps); EXPECT_GT(number_heaps, 0u); for (unsigned i = 0; i < number_heaps; ++i) { ULONG flag = 0; SIZE_T length; ASSERT_NE(0, HeapQueryInformation(heaps[i], HeapCompatibilityInformation, &flag, sizeof(flag), &length)); // If flag is 0, the heap is a standard heap that does not support // look-asides. If flag is 1, the heap supports look-asides. If flag is 2, // the heap is a low-fragmentation heap (LFH). Note that look-asides are not // supported on the LFH. // We don't have any documented way of querying the HEAP_NO_SERIALIZE flag. EXPECT_LE(flag, 2u); EXPECT_NE(flag, 1u); } } TEST_F(ProcessUtilTest, CalcFreeMemory) { scoped_ptr metrics( base::ProcessMetrics::CreateProcessMetrics(::GetCurrentProcess())); ASSERT_TRUE(NULL != metrics.get()); // Typical values here is ~1900 for total and ~1000 for largest. Obviously // it depends in what other tests have done to this process. base::FreeMBytes free_mem1 = {0}; EXPECT_TRUE(metrics->CalculateFreeMemory(&free_mem1)); EXPECT_LT(10u, free_mem1.total); EXPECT_LT(10u, free_mem1.largest); EXPECT_GT(2048u, free_mem1.total); EXPECT_GT(2048u, free_mem1.largest); EXPECT_GE(free_mem1.total, free_mem1.largest); EXPECT_TRUE(NULL != free_mem1.largest_ptr); // Allocate 20M and check again. It should have gone down. const int kAllocMB = 20; scoped_array alloc(new char[kAllocMB * 1024 * 1024]); size_t expected_total = free_mem1.total - kAllocMB; size_t expected_largest = free_mem1.largest; base::FreeMBytes free_mem2 = {0}; EXPECT_TRUE(metrics->CalculateFreeMemory(&free_mem2)); EXPECT_GE(free_mem2.total, free_mem2.largest); EXPECT_GE(expected_total, free_mem2.total); EXPECT_GE(expected_largest, free_mem2.largest); EXPECT_TRUE(NULL != free_mem2.largest_ptr); } TEST_F(ProcessUtilTest, GetAppOutput) { // Let's create a decently long message. std::string message; for (int i = 0; i < 1025; i++) { // 1025 so it does not end on a kilo-byte // boundary. message += "Hello!"; } FilePath python_runtime; ASSERT_TRUE(PathService::Get(base::DIR_SOURCE_ROOT, &python_runtime)); python_runtime = python_runtime.Append(FILE_PATH_LITERAL("third_party")) .Append(FILE_PATH_LITERAL("python_24")) .Append(FILE_PATH_LITERAL("python.exe")); CommandLine cmd_line(python_runtime); cmd_line.AppendLooseValue(L"-c"); cmd_line.AppendLooseValue(L"\"import sys; sys.stdout.write('" + ASCIIToWide(message) + L"');\""); std::string output; ASSERT_TRUE(base::GetAppOutput(cmd_line, &output)); EXPECT_EQ(message, output); // Let's make sure stderr is ignored. CommandLine other_cmd_line(python_runtime); other_cmd_line.AppendLooseValue(L"-c"); other_cmd_line.AppendLooseValue( L"\"import sys; sys.stderr.write('Hello!');\""); output.clear(); ASSERT_TRUE(base::GetAppOutput(other_cmd_line, &output)); EXPECT_EQ("", output); } TEST_F(ProcessUtilTest, LaunchAsUser) { base::UserTokenHandle token; ASSERT_TRUE(OpenProcessToken(GetCurrentProcess(), TOKEN_ALL_ACCESS, &token)); std::wstring cmdline = this->MakeCmdLine(L"SimpleChildProcess", false).command_line_string(); EXPECT_TRUE(base::LaunchAppAsUser(token, cmdline, false, NULL)); } #endif // defined(OS_WIN) #if defined(OS_POSIX) namespace { // Returns the maximum number of files that a process can have open. // Returns 0 on error. int GetMaxFilesOpenInProcess() { struct rlimit rlim; if (getrlimit(RLIMIT_NOFILE, &rlim) != 0) { return 0; } // rlim_t is a uint64 - clip to maxint. We do this since FD #s are ints // which are all 32 bits on the supported platforms. rlim_t max_int = static_cast(std::numeric_limits::max()); if (rlim.rlim_cur > max_int) { return max_int; } return rlim.rlim_cur; } const int kChildPipe = 20; // FD # for write end of pipe in child process. } // namespace MULTIPROCESS_TEST_MAIN(ProcessUtilsLeakFDChildProcess) { // This child process counts the number of open FDs, it then writes that // number out to a pipe connected to the parent. int num_open_files = 0; int write_pipe = kChildPipe; int max_files = GetMaxFilesOpenInProcess(); for (int i = STDERR_FILENO + 1; i < max_files; i++) { if (i != kChildPipe) { int fd; if ((fd = HANDLE_EINTR(dup(i))) != -1) { close(fd); num_open_files += 1; } } } int written = HANDLE_EINTR(write(write_pipe, &num_open_files, sizeof(num_open_files))); DCHECK_EQ(static_cast(written), sizeof(num_open_files)); int ret = HANDLE_EINTR(close(write_pipe)); DPCHECK(ret == 0); return 0; } int ProcessUtilTest::CountOpenFDsInChild() { int fds[2]; if (pipe(fds) < 0) NOTREACHED(); base::file_handle_mapping_vector fd_mapping_vec; fd_mapping_vec.push_back(std::pair(fds[1], kChildPipe)); base::ProcessHandle handle = this->SpawnChild( L"ProcessUtilsLeakFDChildProcess", fd_mapping_vec, false); CHECK(handle); int ret = HANDLE_EINTR(close(fds[1])); DPCHECK(ret == 0); // Read number of open files in client process from pipe; int num_open_files = -1; ssize_t bytes_read = HANDLE_EINTR(read(fds[0], &num_open_files, sizeof(num_open_files))); CHECK_EQ(bytes_read, static_cast(sizeof(num_open_files))); CHECK(base::WaitForSingleProcess(handle, 1000)); base::CloseProcessHandle(handle); ret = HANDLE_EINTR(close(fds[0])); DPCHECK(ret == 0); return num_open_files; } TEST_F(ProcessUtilTest, FDRemapping) { int fds_before = CountOpenFDsInChild(); // open some dummy fds to make sure they don't propagate over to the // child process. int dev_null = open("/dev/null", O_RDONLY); int sockets[2]; socketpair(AF_UNIX, SOCK_STREAM, 0, sockets); int fds_after = CountOpenFDsInChild(); ASSERT_EQ(fds_after, fds_before); int ret; ret = HANDLE_EINTR(close(sockets[0])); DPCHECK(ret == 0); ret = HANDLE_EINTR(close(sockets[1])); DPCHECK(ret == 0); ret = HANDLE_EINTR(close(dev_null)); DPCHECK(ret == 0); } namespace { std::string TestLaunchApp(const base::environment_vector& env_changes) { std::vector args; base::file_handle_mapping_vector fds_to_remap; base::ProcessHandle handle; args.push_back("bash"); args.push_back("-c"); args.push_back("echo $BASE_TEST"); int fds[2]; PCHECK(pipe(fds) == 0); fds_to_remap.push_back(std::make_pair(fds[1], 1)); EXPECT_TRUE(base::LaunchApp(args, env_changes, fds_to_remap, true /* wait for exit */, &handle)); PCHECK(close(fds[1]) == 0); char buf[512]; const ssize_t n = HANDLE_EINTR(read(fds[0], buf, sizeof(buf))); PCHECK(n > 0); return std::string(buf, n); } const char kLargeString[] = "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789" "0123456789012345678901234567890123456789012345678901234567890123456789"; } // namespace TEST_F(ProcessUtilTest, LaunchApp) { base::environment_vector env_changes; env_changes.push_back(std::make_pair(std::string("BASE_TEST"), std::string("bar"))); EXPECT_EQ("bar\n", TestLaunchApp(env_changes)); env_changes.clear(); EXPECT_EQ(0, setenv("BASE_TEST", "testing", 1 /* override */)); EXPECT_EQ("testing\n", TestLaunchApp(env_changes)); env_changes.push_back(std::make_pair(std::string("BASE_TEST"), std::string(""))); EXPECT_EQ("\n", TestLaunchApp(env_changes)); env_changes[0].second = "foo"; EXPECT_EQ("foo\n", TestLaunchApp(env_changes)); env_changes.clear(); EXPECT_EQ(0, setenv("BASE_TEST", kLargeString, 1 /* override */)); EXPECT_EQ(std::string(kLargeString) + "\n", TestLaunchApp(env_changes)); env_changes.push_back(std::make_pair(std::string("BASE_TEST"), std::string("wibble"))); EXPECT_EQ("wibble\n", TestLaunchApp(env_changes)); } TEST_F(ProcessUtilTest, AlterEnvironment) { const char* const empty[] = { NULL }; const char* const a2[] = { "A=2", NULL }; base::environment_vector changes; char** e; e = base::AlterEnvironment(changes, empty); EXPECT_TRUE(e[0] == NULL); delete[] e; changes.push_back(std::make_pair(std::string("A"), std::string("1"))); e = base::AlterEnvironment(changes, empty); EXPECT_EQ(std::string("A=1"), e[0]); EXPECT_TRUE(e[1] == NULL); delete[] e; changes.clear(); changes.push_back(std::make_pair(std::string("A"), std::string(""))); e = base::AlterEnvironment(changes, empty); EXPECT_TRUE(e[0] == NULL); delete[] e; changes.clear(); e = base::AlterEnvironment(changes, a2); EXPECT_EQ(std::string("A=2"), e[0]); EXPECT_TRUE(e[1] == NULL); delete[] e; changes.clear(); changes.push_back(std::make_pair(std::string("A"), std::string("1"))); e = base::AlterEnvironment(changes, a2); EXPECT_EQ(std::string("A=1"), e[0]); EXPECT_TRUE(e[1] == NULL); delete[] e; changes.clear(); changes.push_back(std::make_pair(std::string("A"), std::string(""))); e = base::AlterEnvironment(changes, a2); EXPECT_TRUE(e[0] == NULL); delete[] e; } TEST_F(ProcessUtilTest, GetAppOutput) { std::string output; EXPECT_TRUE(base::GetAppOutput(CommandLine(FilePath("true")), &output)); EXPECT_STREQ("", output.c_str()); EXPECT_FALSE(base::GetAppOutput(CommandLine(FilePath("false")), &output)); std::vector argv; argv.push_back("/bin/echo"); argv.push_back("-n"); argv.push_back("foobar42"); EXPECT_TRUE(base::GetAppOutput(CommandLine(argv), &output)); EXPECT_STREQ("foobar42", output.c_str()); } TEST_F(ProcessUtilTest, GetAppOutputRestricted) { // Unfortunately, since we can't rely on the path, we need to know where // everything is. So let's use /bin/sh, which is on every POSIX system, and // its built-ins. std::vector argv; argv.push_back("/bin/sh"); // argv[0] argv.push_back("-c"); // argv[1] // On success, should set |output|. We use |/bin/sh -c 'exit 0'| instead of // |true| since the location of the latter may be |/bin| or |/usr/bin| (and we // need absolute paths). argv.push_back("exit 0"); // argv[2]; equivalent to "true" std::string output = "abc"; EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 100)); EXPECT_STREQ("", output.c_str()); argv[2] = "exit 1"; // equivalent to "false" output = "before"; EXPECT_FALSE(base::GetAppOutputRestricted(CommandLine(argv), &output, 100)); EXPECT_STREQ("", output.c_str()); // Amount of output exactly equal to space allowed. argv[2] = "echo 123456789"; // (the sh built-in doesn't take "-n") output.clear(); EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 10)); EXPECT_STREQ("123456789\n", output.c_str()); // Amount of output greater than space allowed. output.clear(); EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 5)); EXPECT_STREQ("12345", output.c_str()); // Amount of output less than space allowed. output.clear(); EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 15)); EXPECT_STREQ("123456789\n", output.c_str()); // Zero space allowed. output = "abc"; EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 0)); EXPECT_STREQ("", output.c_str()); } TEST_F(ProcessUtilTest, GetAppOutputRestrictedNoZombies) { std::vector argv; argv.push_back("/bin/sh"); // argv[0] argv.push_back("-c"); // argv[1] argv.push_back("echo 123456789012345678901234567890"); // argv[2] // Run |GetAppOutputRestricted()| 300 (> default per-user processes on Mac OS // 10.5) times with an output buffer big enough to capture all output. for (int i = 0; i < 300; i++) { std::string output; EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 100)); EXPECT_STREQ("123456789012345678901234567890\n", output.c_str()); } // Ditto, but with an output buffer too small to capture all output. for (int i = 0; i < 300; i++) { std::string output; EXPECT_TRUE(base::GetAppOutputRestricted(CommandLine(argv), &output, 10)); EXPECT_STREQ("1234567890", output.c_str()); } } #if defined(OS_LINUX) TEST_F(ProcessUtilTest, GetParentProcessId) { base::ProcessId ppid = base::GetParentProcessId(base::GetCurrentProcId()); EXPECT_EQ(ppid, getppid()); } TEST_F(ProcessUtilTest, ParseProcStatCPU) { // /proc/self/stat for a process running "top". const char kTopStat[] = "960 (top) S 16230 960 16230 34818 960 " "4202496 471 0 0 0 " "12 16 0 0 " // <- These are the goods. "20 0 1 0 121946157 15077376 314 18446744073709551615 4194304 " "4246868 140733983044336 18446744073709551615 140244213071219 " "0 0 0 138047495 0 0 0 17 1 0 0 0 0 0"; EXPECT_EQ(12 + 16, base::ParseProcStatCPU(kTopStat)); // cat /proc/self/stat on a random other machine I have. const char kSelfStat[] = "5364 (cat) R 5354 5364 5354 34819 5364 " "0 142 0 0 0 " "0 0 0 0 " // <- No CPU, apparently. "16 0 1 0 1676099790 2957312 114 4294967295 134512640 134528148 " "3221224832 3221224344 3086339742 0 0 0 0 0 0 0 17 0 0 0"; EXPECT_EQ(0, base::ParseProcStatCPU(kSelfStat)); } #endif #endif // defined(OS_POSIX) // TODO(vandebo) make this work on Windows too. #if !defined(OS_WIN) #if defined(USE_TCMALLOC) extern "C" { int tc_set_new_mode(int mode); } #endif // defined(USE_TCMALLOC) class OutOfMemoryTest : public testing::Test { public: OutOfMemoryTest() : value_(NULL), // Make test size as large as possible minus a few pages so // that alignment or other rounding doesn't make it wrap. test_size_(std::numeric_limits::max() - 12 * 1024), signed_test_size_(std::numeric_limits::max()) { } virtual void SetUp() { // Must call EnableTerminationOnOutOfMemory() because that is called from // chrome's main function and therefore hasn't been called yet. base::EnableTerminationOnOutOfMemory(); #if defined(USE_TCMALLOC) tc_set_new_mode(1); } virtual void TearDown() { tc_set_new_mode(0); #endif // defined(USE_TCMALLOC) } void* value_; size_t test_size_; ssize_t signed_test_size_; }; TEST_F(OutOfMemoryTest, New) { ASSERT_DEATH(value_ = operator new(test_size_), ""); } TEST_F(OutOfMemoryTest, NewArray) { ASSERT_DEATH(value_ = new char[test_size_], ""); } TEST_F(OutOfMemoryTest, Malloc) { ASSERT_DEATH(value_ = malloc(test_size_), ""); } TEST_F(OutOfMemoryTest, Realloc) { ASSERT_DEATH(value_ = realloc(NULL, test_size_), ""); } TEST_F(OutOfMemoryTest, Calloc) { ASSERT_DEATH(value_ = calloc(1024, test_size_ / 1024L), ""); } TEST_F(OutOfMemoryTest, Valloc) { ASSERT_DEATH(value_ = valloc(test_size_), ""); } #if defined(OS_LINUX) TEST_F(OutOfMemoryTest, Pvalloc) { ASSERT_DEATH(value_ = pvalloc(test_size_), ""); } TEST_F(OutOfMemoryTest, Memalign) { ASSERT_DEATH(value_ = memalign(4, test_size_), ""); } TEST_F(OutOfMemoryTest, ViaSharedLibraries) { // g_try_malloc is documented to return NULL on failure. (g_malloc is the // 'safe' default that crashes if allocation fails). However, since we have // hopefully overridden malloc, even g_try_malloc should fail. This tests // that the run-time symbol resolution is overriding malloc for shared // libraries as well as for our code. ASSERT_DEATH(value_ = g_try_malloc(test_size_), ""); } #endif // OS_LINUX #if defined(OS_POSIX) TEST_F(OutOfMemoryTest, Posix_memalign) { typedef int (*memalign_t)(void **, size_t, size_t); #if defined(OS_MACOSX) // posix_memalign only exists on >= 10.6. Use dlsym to grab it at runtime // because it may not be present in the SDK used for compilation. memalign_t memalign = reinterpret_cast(dlsym(RTLD_DEFAULT, "posix_memalign")); #else memalign_t memalign = posix_memalign; #endif // OS_* if (memalign) { // Grab the return value of posix_memalign to silence a compiler warning // about unused return values. We don't actually care about the return // value, since we're asserting death. ASSERT_DEATH(EXPECT_EQ(ENOMEM, memalign(&value_, 8, test_size_)), ""); } } #endif // OS_POSIX #if defined(OS_MACOSX) // Purgeable zone tests (if it exists) TEST_F(OutOfMemoryTest, MallocPurgeable) { malloc_zone_t* zone = base::GetPurgeableZone(); if (zone) ASSERT_DEATH(value_ = malloc_zone_malloc(zone, test_size_), ""); } TEST_F(OutOfMemoryTest, ReallocPurgeable) { malloc_zone_t* zone = base::GetPurgeableZone(); if (zone) ASSERT_DEATH(value_ = malloc_zone_realloc(zone, NULL, test_size_), ""); } TEST_F(OutOfMemoryTest, CallocPurgeable) { malloc_zone_t* zone = base::GetPurgeableZone(); if (zone) ASSERT_DEATH(value_ = malloc_zone_calloc(zone, 1024, test_size_ / 1024L), ""); } TEST_F(OutOfMemoryTest, VallocPurgeable) { malloc_zone_t* zone = base::GetPurgeableZone(); if (zone) ASSERT_DEATH(value_ = malloc_zone_valloc(zone, test_size_), ""); } TEST_F(OutOfMemoryTest, PosixMemalignPurgeable) { malloc_zone_t* zone = base::GetPurgeableZone(); typedef void* (*zone_memalign_t)(malloc_zone_t*, size_t, size_t); // malloc_zone_memalign only exists on >= 10.6. Use dlsym to grab it at // runtime because it may not be present in the SDK used for compilation. zone_memalign_t zone_memalign = reinterpret_cast( dlsym(RTLD_DEFAULT, "malloc_zone_memalign")); if (zone && zone_memalign) { ASSERT_DEATH(value_ = zone_memalign(zone, 8, test_size_), ""); } } // Since these allocation functions take a signed size, it's possible that // calling them just once won't be enough to exhaust memory. In the 32-bit // environment, it's likely that these allocation attempts will fail because // not enough contiguous address space is availble. In the 64-bit environment, // it's likely that they'll fail because they would require a preposterous // amount of (virtual) memory. TEST_F(OutOfMemoryTest, CFAllocatorSystemDefault) { ASSERT_DEATH(while ((value_ = base::AllocateViaCFAllocatorSystemDefault(signed_test_size_))) {}, ""); } TEST_F(OutOfMemoryTest, CFAllocatorMalloc) { ASSERT_DEATH(while ((value_ = base::AllocateViaCFAllocatorMalloc(signed_test_size_))) {}, ""); } TEST_F(OutOfMemoryTest, CFAllocatorMallocZone) { ASSERT_DEATH(while ((value_ = base::AllocateViaCFAllocatorMallocZone(signed_test_size_))) {}, ""); } #if !defined(ARCH_CPU_64_BITS) // See process_util_unittest_mac.mm for an explanation of why this test isn't // run in the 64-bit environment. TEST_F(OutOfMemoryTest, PsychoticallyBigObjCObject) { ASSERT_DEATH(while ((value_ = base::AllocatePsychoticallyBigObjCObject())) {}, ""); } #endif // !ARCH_CPU_64_BITS #endif // OS_MACOSX #endif // !defined(OS_WIN)