// 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/process/launch.h" #include <fcntl.h> #include <io.h> #include <windows.h> #include <userenv.h> #include <psapi.h> #include <ios> #include <limits> #include "base/bind.h" #include "base/bind_helpers.h" #include "base/command_line.h" #include "base/debug/stack_trace.h" #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "base/message_loop/message_loop.h" #include "base/metrics/histogram.h" #include "base/process/kill.h" #include "base/sys_info.h" #include "base/win/object_watcher.h" #include "base/win/scoped_handle.h" #include "base/win/scoped_process_information.h" #include "base/win/startup_information.h" #include "base/win/windows_version.h" // userenv.dll is required for CreateEnvironmentBlock(). #pragma comment(lib, "userenv.lib") namespace base { namespace { // This exit code is used by the Windows task manager when it kills a // process. It's value is obviously not that unique, and it's // surprising to me that the task manager uses this value, but it // seems to be common practice on Windows to test for it as an // indication that the task manager has killed something if the // process goes away. const DWORD kProcessKilledExitCode = 1; } // namespace void RouteStdioToConsole() { // Don't change anything if stdout or stderr already point to a // valid stream. // // If we are running under Buildbot or under Cygwin's default // terminal (mintty), stderr and stderr will be pipe handles. In // that case, we don't want to open CONOUT$, because its output // likely does not go anywhere. // // We don't use GetStdHandle() to check stdout/stderr here because // it can return dangling IDs of handles that were never inherited // by this process. These IDs could have been reused by the time // this function is called. The CRT checks the validity of // stdout/stderr on startup (before the handle IDs can be reused). // _fileno(stdout) will return -2 (_NO_CONSOLE_FILENO) if stdout was // invalid. if (_fileno(stdout) >= 0 || _fileno(stderr) >= 0) return; if (!AttachConsole(ATTACH_PARENT_PROCESS)) { unsigned int result = GetLastError(); // Was probably already attached. if (result == ERROR_ACCESS_DENIED) return; // Don't bother creating a new console for each child process if the // parent process is invalid (eg: crashed). if (result == ERROR_GEN_FAILURE) return; // Make a new console if attaching to parent fails with any other error. // It should be ERROR_INVALID_HANDLE at this point, which means the browser // was likely not started from a console. AllocConsole(); } // Arbitrary byte count to use when buffering output lines. More // means potential waste, less means more risk of interleaved // log-lines in output. enum { kOutputBufferSize = 64 * 1024 }; if (freopen("CONOUT$", "w", stdout)) { setvbuf(stdout, NULL, _IOLBF, kOutputBufferSize); // Overwrite FD 1 for the benefit of any code that uses this FD // directly. This is safe because the CRT allocates FDs 0, 1 and // 2 at startup even if they don't have valid underlying Windows // handles. This means we won't be overwriting an FD created by // _open() after startup. _dup2(_fileno(stdout), 1); } if (freopen("CONOUT$", "w", stderr)) { setvbuf(stderr, NULL, _IOLBF, kOutputBufferSize); _dup2(_fileno(stderr), 2); } // Fix all cout, wcout, cin, wcin, cerr, wcerr, clog and wclog. std::ios::sync_with_stdio(); } bool LaunchProcess(const string16& cmdline, const LaunchOptions& options, win::ScopedHandle* process_handle) { win::StartupInformation startup_info_wrapper; STARTUPINFO* startup_info = startup_info_wrapper.startup_info(); bool inherit_handles = options.inherit_handles; DWORD flags = 0; if (options.handles_to_inherit) { if (options.handles_to_inherit->empty()) { inherit_handles = false; } else { if (base::win::GetVersion() < base::win::VERSION_VISTA) { DLOG(ERROR) << "Specifying handles to inherit requires Vista or later."; return false; } if (options.handles_to_inherit->size() > std::numeric_limits<DWORD>::max() / sizeof(HANDLE)) { DLOG(ERROR) << "Too many handles to inherit."; return false; } if (!startup_info_wrapper.InitializeProcThreadAttributeList(1)) { DPLOG(ERROR); return false; } if (!startup_info_wrapper.UpdateProcThreadAttribute( PROC_THREAD_ATTRIBUTE_HANDLE_LIST, const_cast<HANDLE*>(&options.handles_to_inherit->at(0)), static_cast<DWORD>(options.handles_to_inherit->size() * sizeof(HANDLE)))) { DPLOG(ERROR); return false; } inherit_handles = true; flags |= EXTENDED_STARTUPINFO_PRESENT; } } if (options.empty_desktop_name) startup_info->lpDesktop = L""; startup_info->dwFlags = STARTF_USESHOWWINDOW; startup_info->wShowWindow = options.start_hidden ? SW_HIDE : SW_SHOW; if (options.stdin_handle || options.stdout_handle || options.stderr_handle) { DCHECK(inherit_handles); DCHECK(options.stdin_handle); DCHECK(options.stdout_handle); DCHECK(options.stderr_handle); startup_info->dwFlags |= STARTF_USESTDHANDLES; startup_info->hStdInput = options.stdin_handle; startup_info->hStdOutput = options.stdout_handle; startup_info->hStdError = options.stderr_handle; } if (options.job_handle) { flags |= CREATE_SUSPENDED; // If this code is run under a debugger, the launched process is // automatically associated with a job object created by the debugger. // The CREATE_BREAKAWAY_FROM_JOB flag is used to prevent this. flags |= CREATE_BREAKAWAY_FROM_JOB; } if (options.force_breakaway_from_job_) flags |= CREATE_BREAKAWAY_FROM_JOB; PROCESS_INFORMATION temp_process_info = {}; if (options.as_user) { flags |= CREATE_UNICODE_ENVIRONMENT; void* enviroment_block = NULL; if (!CreateEnvironmentBlock(&enviroment_block, options.as_user, FALSE)) { DPLOG(ERROR); return false; } BOOL launched = CreateProcessAsUser(options.as_user, NULL, const_cast<wchar_t*>(cmdline.c_str()), NULL, NULL, inherit_handles, flags, enviroment_block, NULL, startup_info, &temp_process_info); DestroyEnvironmentBlock(enviroment_block); if (!launched) { DPLOG(ERROR); return false; } } else { if (!CreateProcess(NULL, const_cast<wchar_t*>(cmdline.c_str()), NULL, NULL, inherit_handles, flags, NULL, NULL, startup_info, &temp_process_info)) { DPLOG(ERROR); return false; } } base::win::ScopedProcessInformation process_info(temp_process_info); if (options.job_handle) { if (0 == AssignProcessToJobObject(options.job_handle, process_info.process_handle())) { DLOG(ERROR) << "Could not AssignProcessToObject."; KillProcess(process_info.process_handle(), kProcessKilledExitCode, true); return false; } ResumeThread(process_info.thread_handle()); } if (options.wait) WaitForSingleObject(process_info.process_handle(), INFINITE); // If the caller wants the process handle, we won't close it. if (process_handle) process_handle->Set(process_info.TakeProcessHandle()); return true; } bool LaunchProcess(const CommandLine& cmdline, const LaunchOptions& options, ProcessHandle* process_handle) { if (!process_handle) return LaunchProcess(cmdline.GetCommandLineString(), options, NULL); win::ScopedHandle process; bool rv = LaunchProcess(cmdline.GetCommandLineString(), options, &process); *process_handle = process.Take(); return rv; } bool SetJobObjectLimitFlags(HANDLE job_object, DWORD limit_flags) { JOBOBJECT_EXTENDED_LIMIT_INFORMATION limit_info = {0}; limit_info.BasicLimitInformation.LimitFlags = limit_flags; return 0 != SetInformationJobObject( job_object, JobObjectExtendedLimitInformation, &limit_info, sizeof(limit_info)); } bool GetAppOutput(const CommandLine& cl, std::string* output) { return GetAppOutput(cl.GetCommandLineString(), output); } bool GetAppOutput(const StringPiece16& cl, std::string* output) { HANDLE out_read = NULL; HANDLE out_write = NULL; SECURITY_ATTRIBUTES sa_attr; // Set the bInheritHandle flag so pipe handles are inherited. sa_attr.nLength = sizeof(SECURITY_ATTRIBUTES); sa_attr.bInheritHandle = TRUE; sa_attr.lpSecurityDescriptor = NULL; // Create the pipe for the child process's STDOUT. if (!CreatePipe(&out_read, &out_write, &sa_attr, 0)) { NOTREACHED() << "Failed to create pipe"; return false; } // Ensure we don't leak the handles. win::ScopedHandle scoped_out_read(out_read); win::ScopedHandle scoped_out_write(out_write); // Ensure the read handle to the pipe for STDOUT is not inherited. if (!SetHandleInformation(out_read, HANDLE_FLAG_INHERIT, 0)) { NOTREACHED() << "Failed to disabled pipe inheritance"; return false; } FilePath::StringType writable_command_line_string; writable_command_line_string.assign(cl.data(), cl.size()); STARTUPINFO start_info = {}; start_info.cb = sizeof(STARTUPINFO); start_info.hStdOutput = out_write; // Keep the normal stdin and stderr. start_info.hStdInput = GetStdHandle(STD_INPUT_HANDLE); start_info.hStdError = GetStdHandle(STD_ERROR_HANDLE); start_info.dwFlags |= STARTF_USESTDHANDLES; // Create the child process. PROCESS_INFORMATION temp_process_info = {}; if (!CreateProcess(NULL, &writable_command_line_string[0], NULL, NULL, TRUE, // Handles are inherited. 0, NULL, NULL, &start_info, &temp_process_info)) { NOTREACHED() << "Failed to start process"; return false; } base::win::ScopedProcessInformation proc_info(temp_process_info); // Close our writing end of pipe now. Otherwise later read would not be able // to detect end of child's output. scoped_out_write.Close(); // Read output from the child process's pipe for STDOUT const int kBufferSize = 1024; char buffer[kBufferSize]; for (;;) { DWORD bytes_read = 0; BOOL success = ReadFile(out_read, buffer, kBufferSize, &bytes_read, NULL); if (!success || bytes_read == 0) break; output->append(buffer, bytes_read); } // Let's wait for the process to finish. WaitForSingleObject(proc_info.process_handle(), INFINITE); return true; } void RaiseProcessToHighPriority() { SetPriorityClass(GetCurrentProcess(), HIGH_PRIORITY_CLASS); } } // namespace base