// 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 "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 "testing/gtest/include/gtest/gtest.h"
#if defined(OS_LINUX)
#include <dlfcn.h>
#endif
#if defined(OS_POSIX)
#include <fcntl.h>
#include <sys/socket.h>
#endif
#if defined(OS_WIN)
#include <windows.h>
#endif
namespace base {
class ProcessUtilTest : public MultiProcessTest {
};
MULTIPROCESS_TEST_MAIN(SimpleChildProcess) {
return 0;
}
TEST_F(ProcessUtilTest, SpawnChild) {
ProcessHandle handle = this->SpawnChild(L"SimpleChildProcess");
ASSERT_NE(static_cast<ProcessHandle>(NULL), handle);
EXPECT_TRUE(WaitForSingleProcess(handle, 5000));
base::CloseProcessHandle(handle);
}
MULTIPROCESS_TEST_MAIN(SlowChildProcess) {
// Sleep until file "SlowChildProcess.die" is created.
FILE *fp;
do {
PlatformThread::Sleep(100);
fp = fopen("SlowChildProcess.die", "r");
} while (!fp);
fclose(fp);
remove("SlowChildProcess.die");
exit(0);
return 0;
}
TEST_F(ProcessUtilTest, KillSlowChild) {
remove("SlowChildProcess.die");
ProcessHandle handle = this->SpawnChild(L"SlowChildProcess");
ASSERT_NE(static_cast<ProcessHandle>(NULL), handle);
FILE *fp = fopen("SlowChildProcess.die", "w");
fclose(fp);
EXPECT_TRUE(base::WaitForSingleProcess(handle, 5000));
base::CloseProcessHandle(handle);
}
// TODO(estade): if possible, port these 2 tests.
#if defined(OS_WIN)
TEST_F(ProcessUtilTest, EnableLFH) {
ASSERT_TRUE(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) {
ProcessMetrics* metrics =
ProcessMetrics::CreateProcessMetrics(::GetCurrentProcess());
ASSERT_TRUE(NULL != metrics);
// Typical values here is ~1900 for total and ~1000 for largest. Obviously
// it depends in what other tests have done to this process.
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;
char* alloc = new char[kAllocMB * 1024 * 1024];
EXPECT_TRUE(NULL != alloc);
size_t expected_total = free_mem1.total - kAllocMB;
size_t expected_largest = free_mem1.largest;
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);
delete[] alloc;
delete metrics;
}
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.value());
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.value());
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);
}
#endif // defined(OS_WIN)
#if defined(OS_POSIX)
// 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<rlim_t>(std::numeric_limits<int32>::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.
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) {
if (HANDLE_EINTR(close(i)) != -1) {
LOG(WARNING) << "Leaked FD " << i;
num_open_files += 1;
}
}
}
// InitLogging always opens a file at startup.
int expected_num_open_fds = 1;
#if defined(OS_LINUX)
// On Linux, '/etc/localtime' is opened before the test's main() enters.
expected_num_open_fds += 1;
#endif // defined(OS_LINUX)
num_open_files -= expected_num_open_fds;
int written = HANDLE_EINTR(write(write_pipe, &num_open_files,
sizeof(num_open_files)));
DCHECK_EQ(static_cast<size_t>(written), sizeof(num_open_files));
HANDLE_EINTR(close(write_pipe));
return 0;
}
TEST_F(ProcessUtilTest, FDRemapping) {
// Open some files to check they don't get leaked to the child process.
int fds[2];
if (pipe(fds) < 0)
NOTREACHED();
int pipe_read_fd = fds[0];
int pipe_write_fd = fds[1];
// open some dummy fds to make sure they don't propogate over to the
// child process.
int dev_null = open("/dev/null", O_RDONLY);
int sockets[2];
socketpair(AF_UNIX, SOCK_STREAM, 0, sockets);
file_handle_mapping_vector fd_mapping_vec;
fd_mapping_vec.push_back(std::pair<int,int>(pipe_write_fd, kChildPipe));
ProcessHandle handle = this->SpawnChild(L"ProcessUtilsLeakFDChildProcess",
fd_mapping_vec,
false);
ASSERT_NE(static_cast<ProcessHandle>(NULL), handle);
HANDLE_EINTR(close(pipe_write_fd));
// Read number of open files in client process from pipe;
int num_open_files = -1;
ssize_t bytes_read =
HANDLE_EINTR(read(pipe_read_fd, &num_open_files, sizeof(num_open_files)));
ASSERT_EQ(bytes_read, static_cast<ssize_t>(sizeof(num_open_files)));
// Make sure 0 fds are leaked to the client.
ASSERT_EQ(0, num_open_files);
EXPECT_TRUE(WaitForSingleProcess(handle, 1000));
base::CloseProcessHandle(handle);
HANDLE_EINTR(close(fds[0]));
HANDLE_EINTR(close(sockets[0]));
HANDLE_EINTR(close(sockets[1]));
HANDLE_EINTR(close(dev_null));
}
TEST_F(ProcessUtilTest, GetAppOutput) {
std::string output;
EXPECT_TRUE(GetAppOutput(CommandLine(L"true"), &output));
EXPECT_STREQ("", output.c_str());
EXPECT_FALSE(GetAppOutput(CommandLine(L"false"), &output));
std::vector<std::string> argv;
argv.push_back("/bin/echo");
argv.push_back("-n");
argv.push_back("foobar42");
EXPECT_TRUE(GetAppOutput(CommandLine(argv), &output));
EXPECT_STREQ("foobar42", output.c_str());
}
#if defined(OS_LINUX)
TEST_F(ProcessUtilTest, GetParentProcessId) {
base::ProcessId ppid = GetParentProcessId(GetCurrentProcId());
EXPECT_EQ(ppid, getppid());
}
#endif
#endif // defined(OS_POSIX)
} // namespace base