// Copyright (c) 2022 Slack Technologies, Inc. // Use of this source code is governed by the MIT license that can be // found in the LICENSE file. #include // windows.h must be included first #include // ensures that ATL statics like `_AtlWinModule` are initialized (it's an issue in static debug build) #include #include #include #include #include #include #include #include #include #include "base/at_exit.h" #include "base/environment.h" #include "base/i18n/icu_util.h" #include "base/process/launch.h" #include "base/strings/utf_string_conversions.h" #include "base/win/dark_mode_support.h" #include "base/win/windows_version.h" #include "chrome/app/exit_code_watcher_win.h" #include "components/crash/core/app/crash_switches.h" #include "components/crash/core/app/run_as_crashpad_handler_win.h" #include "content/public/app/content_main.h" #include "content/public/app/sandbox_helper_win.h" #include "electron/buildflags/buildflags.h" #include "electron/fuses.h" #include "sandbox/win/src/sandbox_types.h" #include "shell/app/command_line_args.h" #include "shell/app/electron_main_delegate.h" #include "shell/app/node_main.h" #include "shell/common/electron_command_line.h" #include "shell/common/electron_constants.h" #include "third_party/crashpad/crashpad/util/win/initial_client_data.h" namespace { // Redefined here so we don't have to introduce a dependency on //content // from //electron:electron_app const char kUserDataDir[] = "user-data-dir"; const char kProcessType[] = "type"; [[maybe_unused]] bool IsEnvSet(const char* name) { size_t required_size; getenv_s(&required_size, nullptr, 0, name); return required_size != 0; } } // namespace namespace crash_reporter { extern const char kCrashpadProcess[]; } // In 32-bit builds, the main thread starts with the default (small) stack size. // The ARCH_CPU_32_BITS blocks here and below are in support of moving the main // thread to a fiber with a larger stack size. #if defined(ARCH_CPU_32_BITS) // The information needed to transfer control to the large-stack fiber and later // pass the main routine's exit code back to the small-stack fiber prior to // termination. struct FiberState { HINSTANCE instance; LPVOID original_fiber; int fiber_result; }; // A PFIBER_START_ROUTINE function run on a large-stack fiber that calls the // main routine, stores its return value, and returns control to the small-stack // fiber. |params| must be a pointer to a FiberState struct. void WINAPI FiberBinder(void* params) { auto* fiber_state = static_cast(params); // Call the wWinMain routine from the fiber. Reusing the entry point minimizes // confusion when examining call stacks in crash reports - seeing wWinMain on // the stack is a handy hint that this is the main thread of the process. fiber_state->fiber_result = wWinMain(fiber_state->instance, nullptr, nullptr, 0); // Switch back to the main thread to exit. ::SwitchToFiber(fiber_state->original_fiber); } #endif // defined(ARCH_CPU_32_BITS) int APIENTRY wWinMain(HINSTANCE instance, HINSTANCE, wchar_t* cmd, int) { #if defined(ARCH_CPU_32_BITS) enum class FiberStatus { kConvertFailed, kCreateFiberFailed, kSuccess }; FiberStatus fiber_status = FiberStatus::kSuccess; // GetLastError result if fiber conversion failed. DWORD fiber_error = ERROR_SUCCESS; if (!::IsThreadAFiber()) { // Make the main thread's stack size 4 MiB so that it has roughly the same // effective size as the 64-bit build's 8 MiB stack. constexpr size_t kStackSize = 4 * 1024 * 1024; // 4 MiB // Leak the fiber on exit. LPVOID original_fiber = ::ConvertThreadToFiberEx(nullptr, FIBER_FLAG_FLOAT_SWITCH); if (original_fiber) { FiberState fiber_state = {instance, original_fiber}; // Create a fiber with a bigger stack and switch to it. Leak the fiber on // exit. LPVOID big_stack_fiber = ::CreateFiberEx( 0, kStackSize, FIBER_FLAG_FLOAT_SWITCH, FiberBinder, &fiber_state); if (big_stack_fiber) { ::SwitchToFiber(big_stack_fiber); // The fibers must be cleaned up to avoid obscure TLS-related shutdown // crashes. ::DeleteFiber(big_stack_fiber); ::ConvertFiberToThread(); // Control returns here after Chrome has finished running on FiberMain. return fiber_state.fiber_result; } fiber_status = FiberStatus::kCreateFiberFailed; } else { fiber_status = FiberStatus::kConvertFailed; } // If we reach here then creating and switching to a fiber has failed. This // probably means we are low on memory and will soon crash. Try to report // this error once crash reporting is initialized. fiber_error = ::GetLastError(); base::debug::Alias(&fiber_error); } // If we are already a fiber then continue normal execution. #endif // defined(ARCH_CPU_32_BITS) struct Arguments { int argc = 0; wchar_t** argv = ::CommandLineToArgvW(::GetCommandLineW(), &argc); ~Arguments() { LocalFree(argv); } } arguments; if (!arguments.argv) return -1; #ifdef _DEBUG // Don't display assert dialog boxes in CI test runs static const char kCI[] = "CI"; if (IsEnvSet(kCI)) { _CrtSetReportMode(_CRT_ERROR, _CRTDBG_MODE_DEBUG | _CRTDBG_MODE_FILE); _CrtSetReportFile(_CRT_ERROR, _CRTDBG_FILE_STDERR); _CrtSetReportMode(_CRT_ASSERT, _CRTDBG_MODE_DEBUG | _CRTDBG_MODE_FILE); _CrtSetReportFile(_CRT_ASSERT, _CRTDBG_FILE_STDERR); _set_error_mode(_OUT_TO_STDERR); } #endif #if BUILDFLAG(ENABLE_RUN_AS_NODE) bool run_as_node = electron::fuses::IsRunAsNodeEnabled() && IsEnvSet(electron::kRunAsNode); #else bool run_as_node = false; #endif // Make sure the output is printed to console. if (run_as_node || !IsEnvSet("ELECTRON_NO_ATTACH_CONSOLE")) base::RouteStdioToConsole(false); std::vector argv(arguments.argc); std::transform(arguments.argv, arguments.argv + arguments.argc, argv.begin(), [](auto& a) { return _strdup(base::WideToUTF8(a).c_str()); }); #if BUILDFLAG(ENABLE_RUN_AS_NODE) if (electron::fuses::IsRunAsNodeEnabled() && run_as_node) { base::AtExitManager atexit_manager; base::i18n::InitializeICU(); auto ret = electron::NodeMain(argv.size(), argv.data()); std::for_each(argv.begin(), argv.end(), free); return ret; } #endif base::CommandLine::Init(argv.size(), argv.data()); const base::CommandLine* command_line = base::CommandLine::ForCurrentProcess(); const std::string process_type = command_line->GetSwitchValueASCII(kProcessType); if (process_type == crash_reporter::switches::kCrashpadHandler) { // Check if we should monitor the exit code of this process std::unique_ptr exit_code_watcher; // Retrieve the client process from the command line crashpad::InitialClientData initial_client_data; if (initial_client_data.InitializeFromString( command_line->GetSwitchValueASCII("initial-client-data"))) { // Setup exit code watcher to monitor the parent process HANDLE duplicate_handle = INVALID_HANDLE_VALUE; if (DuplicateHandle( ::GetCurrentProcess(), initial_client_data.client_process(), ::GetCurrentProcess(), &duplicate_handle, PROCESS_QUERY_INFORMATION, FALSE, DUPLICATE_SAME_ACCESS)) { base::Process parent_process(duplicate_handle); exit_code_watcher = std::make_unique(); if (exit_code_watcher->Initialize(std::move(parent_process))) { exit_code_watcher->StartWatching(); } } } // The handler process must always be passed the user data dir on the // command line. DCHECK(command_line->HasSwitch(kUserDataDir)); base::FilePath user_data_dir = command_line->GetSwitchValuePath(kUserDataDir); int crashpad_status = crash_reporter::RunAsCrashpadHandler( *command_line, user_data_dir, kProcessType, kUserDataDir); if (crashpad_status != 0 && exit_code_watcher) { // Crashpad failed to initialize, explicitly stop the exit code watcher // so the crashpad-handler process can exit with an error exit_code_watcher->StopWatching(); } return crashpad_status; } #if BUILDFLAG(IS_WIN) // access ui native theme here to prevent blocking calls later base::win::AllowDarkModeForApp(true); #endif #if defined(ARCH_CPU_32_BITS) // Intentionally crash if converting to a fiber failed. CHECK_EQ(fiber_status, FiberStatus::kSuccess); #endif // defined(ARCH_CPU_32_BITS) if (!electron::CheckCommandLineArguments(arguments.argc, arguments.argv)) return -1; sandbox::SandboxInterfaceInfo sandbox_info = {nullptr}; content::InitializeSandboxInfo(&sandbox_info); electron::ElectronMainDelegate delegate; content::ContentMainParams params(&delegate); params.instance = instance; params.sandbox_info = &sandbox_info; electron::ElectronCommandLine::Init(arguments.argc, arguments.argv); return content::ContentMain(std::move(params)); }