mirror of
https://github.com/chromium/crashpad.git
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80520bd937
This adds a runtime exception helper (& test module) for Windows and plumbing to allow the module to be registered by the crashpad client, and to trigger the crashpad handler. Embedders can build their own module to control which exceptions are passed to the handler. See: go/chrome-windows-runtime-exception-helper for motivation. When registered (which is the responsibility of the embedding application), the helper is loaded by WerFault.exe when Windows Error Reporting receives crashes that are not caught by crashpad's normal handlers - for instance a control-flow violation when a module is compiled with /guard:cf. Registration: The embedder must arrange for the full path to the helper to be added in the appropriate Windows Error Reporting\ RuntimeExceptionHelperModules registry key. Once an embedder's crashpad client is connected to a crashpad handler (e.g. through SetIpcPipeName()) the embedder calls RegisterWerModule. Internally, this registration includes handles used to trigger the crashpad handler, an area reserved to hold an exception and context, and structures needed by the crashpad handler. Following a crash: WerFault.exe handles the crash then validates and loads the helper module. WER hands the helper module a handle to the crashing target process and copies of the exception and context for the faulting thread. The helper then copies out the client's registration data and duplicates handles to the crashpad handler, then fills back the various structures in the paused client that the crashpad handler will need. The helper then signals the crashpad handler, which collects a dump then notifies the helper that it is done. Support: WerRegisterExceptionHelperModule has been availble since at least Windows 7 but WerFault would not pass on the exceptions that crashpad could not already handle. This changed in Windows 10 20H1 (19041), which supports HKCU and HKLM registrations, and passes in more types of crashes. It is harmless to register the module for earlier versions of Windows as it simply won't be loaded by WerFault.exe. Tests: snapshot/win/end_to_end_test.py has been refactored slightly to group crash generation and output validation in main() by breaking up RunTests into smaller functions. As the module works by being loaded in WerFault.exe it is tested in end_to_end_test.py. Bug: crashpad:133, 866033, 865632 Change-Id: Id668bd15a510a24c79753e1bb03e9456f41a9780 Reviewed-on: https://chromium-review.googlesource.com/c/crashpad/crashpad/+/3677284 Reviewed-by: Joshua Peraza <jperaza@chromium.org> Commit-Queue: Alex Gough <ajgo@chromium.org>
1106 lines
42 KiB
C++
1106 lines
42 KiB
C++
// Copyright 2015 The Crashpad Authors. All rights reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "client/crashpad_client.h"
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#include <windows.h>
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#include <werapi.h>
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#include <signal.h>
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#include <stdint.h>
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#include <string.h>
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#include <memory>
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#include "base/atomicops.h"
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#include "base/logging.h"
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#include "base/scoped_generic.h"
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#include "base/strings/stringprintf.h"
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#include "base/strings/utf_string_conversions.h"
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#include "base/synchronization/lock.h"
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#include "util/file/file_io.h"
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#include "util/misc/capture_context.h"
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#include "util/misc/from_pointer_cast.h"
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#include "util/misc/random_string.h"
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#include "util/win/address_types.h"
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#include "util/win/command_line.h"
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#include "util/win/context_wrappers.h"
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#include "util/win/critical_section_with_debug_info.h"
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#include "util/win/exception_codes.h"
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#include "util/win/get_function.h"
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#include "util/win/handle.h"
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#include "util/win/initial_client_data.h"
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#include "util/win/loader_lock.h"
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#include "util/win/nt_internals.h"
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#include "util/win/ntstatus_logging.h"
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#include "util/win/process_info.h"
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#include "util/win/registration_protocol_win.h"
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#include "util/win/safe_terminate_process.h"
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#include "util/win/scoped_process_suspend.h"
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#include "util/win/termination_codes.h"
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#include "util/win/xp_compat.h"
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namespace crashpad {
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namespace {
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// This handle is never closed. This is used to signal to the server that a dump
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// should be taken in the event of a crash.
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HANDLE g_signal_exception = INVALID_HANDLE_VALUE;
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// Where we store the exception information that the crash handler reads.
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ExceptionInformation g_crash_exception_information;
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// Guards multiple simultaneous calls to DumpWithoutCrash() in the client.
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// This is leaked.
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base::Lock* g_non_crash_dump_lock;
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// Where we store a pointer to the context information when taking a non-crash
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// dump.
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ExceptionInformation g_non_crash_exception_information;
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// Context for the out-of-process exception handler module and holds non-crash
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// dump handles. Handles are never closed once created.
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WerRegistration g_wer_registration = {WerRegistration::kWerRegistrationVersion,
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INVALID_HANDLE_VALUE,
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INVALID_HANDLE_VALUE,
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false,
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nullptr,
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{0},
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{0},
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{0}};
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enum class StartupState : int {
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kNotReady = 0, // This must be value 0 because it is the initial value of a
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// global AtomicWord.
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kSucceeded = 1, // The CreateProcess() for the handler succeeded.
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kFailed = 2, // The handler failed to start.
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};
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// This is a tri-state of type StartupState. It starts at 0 == kNotReady, and
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// when the handler is known to have started successfully, or failed to start
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// the value will be updated. The unhandled exception filter will not proceed
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// until one of those two cases happens.
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base::subtle::AtomicWord g_handler_startup_state;
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// A CRITICAL_SECTION initialized with
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// RTL_CRITICAL_SECTION_FLAG_FORCE_DEBUG_INFO to force it to be allocated with a
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// valid .DebugInfo field. The address of this critical section is given to the
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// handler. All critical sections with debug info are linked in a doubly-linked
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// list, so this allows the handler to capture all of them.
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CRITICAL_SECTION g_critical_section_with_debug_info;
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void SetHandlerStartupState(StartupState state) {
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DCHECK(state == StartupState::kSucceeded || state == StartupState::kFailed);
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base::subtle::Release_Store(&g_handler_startup_state,
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static_cast<base::subtle::AtomicWord>(state));
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}
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StartupState BlockUntilHandlerStartedOrFailed() {
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// Wait until we know the handler has either succeeded or failed to start.
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base::subtle::AtomicWord startup_state;
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while (
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(startup_state = base::subtle::Acquire_Load(&g_handler_startup_state)) ==
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static_cast<int>(StartupState::kNotReady)) {
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Sleep(1);
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}
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return static_cast<StartupState>(startup_state);
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}
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#if defined(ADDRESS_SANITIZER)
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extern "C" LONG __asan_unhandled_exception_filter(EXCEPTION_POINTERS* info);
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#endif
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LONG WINAPI UnhandledExceptionHandler(EXCEPTION_POINTERS* exception_pointers) {
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#if defined(ADDRESS_SANITIZER)
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// In ASan builds, delegate to the ASan exception filter.
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LONG status = __asan_unhandled_exception_filter(exception_pointers);
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if (status != EXCEPTION_CONTINUE_SEARCH)
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return status;
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#endif
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if (BlockUntilHandlerStartedOrFailed() == StartupState::kFailed) {
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// If we know for certain that the handler has failed to start, then abort
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// here, rather than trying to signal to a handler that will never arrive,
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// and then sleeping unnecessarily.
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LOG(ERROR) << "crash server failed to launch, self-terminating";
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SafeTerminateProcess(GetCurrentProcess(), kTerminationCodeCrashNoDump);
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return EXCEPTION_CONTINUE_SEARCH;
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}
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// Otherwise, we know the handler startup has succeeded, and we can continue.
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// Tracks whether a thread has already entered UnhandledExceptionHandler.
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static base::subtle::AtomicWord have_crashed;
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// This is a per-process handler. While this handler is being invoked, other
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// threads are still executing as usual, so multiple threads could enter at
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// the same time. Because we're in a crashing state, we shouldn't be doing
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// anything that might cause allocations, call into kernel mode, etc. So, we
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// don't want to take a critical section here to avoid simultaneous access to
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// the global exception pointers in ExceptionInformation. Because the crash
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// handler will record all threads, it's fine to simply have the second and
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// subsequent entrants block here. They will soon be suspended by the crash
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// handler, and then the entire process will be terminated below. This means
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// that we won't save the exception pointers from the second and further
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// crashes, but contention here is very unlikely, and we'll still have a stack
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// that's blocked at this location.
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if (base::subtle::Barrier_AtomicIncrement(&have_crashed, 1) > 1) {
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SleepEx(INFINITE, false);
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}
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// Otherwise, we're the first thread, so record the exception pointer and
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// signal the crash handler.
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g_crash_exception_information.thread_id = GetCurrentThreadId();
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g_crash_exception_information.exception_pointers =
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FromPointerCast<WinVMAddress>(exception_pointers);
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// Now signal the crash server, which will take a dump and then terminate us
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// when it's complete.
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SetEvent(g_signal_exception);
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// Time to wait for the handler to create a dump.
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constexpr DWORD kMillisecondsUntilTerminate = 60 * 1000;
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// Sleep for a while to allow it to process us. Eventually, we terminate
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// ourselves in case the crash server is gone, so that we don't leave zombies
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// around. This would ideally never happen.
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Sleep(kMillisecondsUntilTerminate);
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LOG(ERROR) << "crash server did not respond, self-terminating";
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SafeTerminateProcess(GetCurrentProcess(), kTerminationCodeCrashNoDump);
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return EXCEPTION_CONTINUE_SEARCH;
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}
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void HandleAbortSignal(int signum) {
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DCHECK_EQ(signum, SIGABRT);
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CONTEXT context;
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CaptureContext(&context);
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EXCEPTION_RECORD record = {};
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record.ExceptionCode = STATUS_FATAL_APP_EXIT;
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record.ExceptionFlags = EXCEPTION_NONCONTINUABLE;
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record.ExceptionAddress = ProgramCounterFromCONTEXT(&context);
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EXCEPTION_POINTERS exception_pointers;
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exception_pointers.ContextRecord = &context;
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exception_pointers.ExceptionRecord = &record;
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UnhandledExceptionHandler(&exception_pointers);
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}
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std::wstring FormatArgumentString(const std::string& name,
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const std::wstring& value) {
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return std::wstring(L"--") + base::UTF8ToWide(name) + L"=" + value;
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}
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struct ScopedProcThreadAttributeListTraits {
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static PPROC_THREAD_ATTRIBUTE_LIST InvalidValue() { return nullptr; }
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static void Free(PPROC_THREAD_ATTRIBUTE_LIST proc_thread_attribute_list) {
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// This is able to use GET_FUNCTION_REQUIRED() instead of GET_FUNCTION()
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// because it will only be called if InitializeProcThreadAttributeList() and
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// UpdateProcThreadAttribute() are present.
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static const auto delete_proc_thread_attribute_list =
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GET_FUNCTION_REQUIRED(L"kernel32.dll", ::DeleteProcThreadAttributeList);
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delete_proc_thread_attribute_list(proc_thread_attribute_list);
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}
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};
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using ScopedProcThreadAttributeList =
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base::ScopedGeneric<PPROC_THREAD_ATTRIBUTE_LIST,
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ScopedProcThreadAttributeListTraits>;
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bool IsInheritableHandle(HANDLE handle) {
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if (!handle || handle == INVALID_HANDLE_VALUE)
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return false;
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// File handles (FILE_TYPE_DISK) and pipe handles (FILE_TYPE_PIPE) are known
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// to be inheritable. Console handles (FILE_TYPE_CHAR) are not inheritable via
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// PROC_THREAD_ATTRIBUTE_HANDLE_LIST. See
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// https://crashpad.chromium.org/bug/77.
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DWORD handle_type = GetFileType(handle);
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return handle_type == FILE_TYPE_DISK || handle_type == FILE_TYPE_PIPE;
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}
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// Adds |handle| to |handle_list| if it appears valid, and is not already in
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// |handle_list|.
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//
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// Invalid handles (including INVALID_HANDLE_VALUE and null handles) cannot be
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// added to a PPROC_THREAD_ATTRIBUTE_LIST’s PROC_THREAD_ATTRIBUTE_HANDLE_LIST.
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// If INVALID_HANDLE_VALUE appears, CreateProcess() will fail with
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// ERROR_INVALID_PARAMETER. If a null handle appears, the child process will
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// silently not inherit any handles.
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//
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// Use this function to add handles with uncertain validities.
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void AddHandleToListIfValidAndInheritable(std::vector<HANDLE>* handle_list,
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HANDLE handle) {
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// There doesn't seem to be any documentation of this, but if there's a handle
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// duplicated in this list, CreateProcess() fails with
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// ERROR_INVALID_PARAMETER.
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if (IsInheritableHandle(handle) &&
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std::find(handle_list->begin(), handle_list->end(), handle) ==
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handle_list->end()) {
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handle_list->push_back(handle);
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}
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}
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void AddUint32(std::vector<unsigned char>* data_vector, uint32_t data) {
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data_vector->push_back(static_cast<unsigned char>(data & 0xff));
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data_vector->push_back(static_cast<unsigned char>((data & 0xff00) >> 8));
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data_vector->push_back(static_cast<unsigned char>((data & 0xff0000) >> 16));
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data_vector->push_back(static_cast<unsigned char>((data & 0xff000000) >> 24));
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}
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void AddUint64(std::vector<unsigned char>* data_vector, uint64_t data) {
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AddUint32(data_vector, static_cast<uint32_t>(data & 0xffffffffULL));
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AddUint32(data_vector,
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static_cast<uint32_t>((data & 0xffffffff00000000ULL) >> 32));
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}
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//! \brief Creates a randomized pipe name to listen for client registrations
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//! on and returns its name.
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//!
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//! \param[out] pipe_name The pipe name that will be listened on.
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//! \param[out] pipe_handle The first pipe instance corresponding for the pipe.
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void CreatePipe(std::wstring* pipe_name, ScopedFileHANDLE* pipe_instance) {
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int tries = 5;
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std::string pipe_name_base = base::StringPrintf(
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#if defined(WINDOWS_UWP)
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"\\\\.\\pipe\\LOCAL\\crashpad_%lu_",
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#else
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"\\\\.\\pipe\\crashpad_%lu_",
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#endif
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GetCurrentProcessId());
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do {
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*pipe_name = base::UTF8ToWide(pipe_name_base + RandomString());
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pipe_instance->reset(CreateNamedPipeInstance(*pipe_name, true));
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// CreateNamedPipe() is documented as setting the error to
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// ERROR_ACCESS_DENIED if FILE_FLAG_FIRST_PIPE_INSTANCE is specified and the
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// pipe name is already in use. However it may set the error to other codes
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// such as ERROR_PIPE_BUSY (if the pipe already exists and has reached its
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// maximum instance count) or ERROR_INVALID_PARAMETER (if the pipe already
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// exists and its attributes differ from those specified to
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// CreateNamedPipe()). Some of these errors may be ambiguous: for example,
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// ERROR_INVALID_PARAMETER may also occur if CreateNamedPipe() is called
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// incorrectly even in the absence of an existing pipe by the same name.
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// Rather than chasing down all of the possible errors that might indicate
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// that a pipe name is already in use, retry up to a few times on any error.
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} while (!pipe_instance->is_valid() && --tries);
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PCHECK(pipe_instance->is_valid()) << "CreateNamedPipe";
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}
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struct BackgroundHandlerStartThreadData {
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BackgroundHandlerStartThreadData(
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const base::FilePath& handler,
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const base::FilePath& database,
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const base::FilePath& metrics_dir,
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const std::string& url,
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const std::map<std::string, std::string>& annotations,
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const std::vector<std::string>& arguments,
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const std::vector<base::FilePath>& attachments,
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const std::wstring& ipc_pipe,
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ScopedFileHANDLE ipc_pipe_handle)
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: handler(handler),
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database(database),
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metrics_dir(metrics_dir),
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url(url),
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annotations(annotations),
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arguments(arguments),
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attachments(attachments),
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ipc_pipe(ipc_pipe),
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ipc_pipe_handle(std::move(ipc_pipe_handle)) {}
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base::FilePath handler;
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base::FilePath database;
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base::FilePath metrics_dir;
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std::string url;
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std::map<std::string, std::string> annotations;
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std::vector<std::string> arguments;
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std::vector<base::FilePath> attachments;
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std::wstring ipc_pipe;
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ScopedFileHANDLE ipc_pipe_handle;
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};
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// Ensures that SetHandlerStartupState() is called on scope exit. Assumes
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// failure, and on success, SetSuccessful() should be called.
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class ScopedCallSetHandlerStartupState {
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public:
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ScopedCallSetHandlerStartupState() : successful_(false) {}
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ScopedCallSetHandlerStartupState(const ScopedCallSetHandlerStartupState&) =
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delete;
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ScopedCallSetHandlerStartupState& operator=(
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const ScopedCallSetHandlerStartupState&) = delete;
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~ScopedCallSetHandlerStartupState() {
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SetHandlerStartupState(successful_ ? StartupState::kSucceeded
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: StartupState::kFailed);
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}
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void SetSuccessful() { successful_ = true; }
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private:
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bool successful_;
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};
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bool StartHandlerProcess(
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std::unique_ptr<BackgroundHandlerStartThreadData> data) {
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CHECK(!IsThreadInLoaderLock());
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ScopedCallSetHandlerStartupState scoped_startup_state_caller;
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std::wstring command_line;
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AppendCommandLineArgument(data->handler.value(), &command_line);
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for (const std::string& argument : data->arguments) {
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AppendCommandLineArgument(base::UTF8ToWide(argument), &command_line);
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}
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if (!data->database.value().empty()) {
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AppendCommandLineArgument(
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FormatArgumentString("database", data->database.value()),
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&command_line);
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}
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if (!data->metrics_dir.value().empty()) {
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AppendCommandLineArgument(
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FormatArgumentString("metrics-dir", data->metrics_dir.value()),
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&command_line);
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}
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if (!data->url.empty()) {
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AppendCommandLineArgument(
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FormatArgumentString("url", base::UTF8ToWide(data->url)),
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&command_line);
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}
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for (const auto& kv : data->annotations) {
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AppendCommandLineArgument(
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FormatArgumentString("annotation",
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base::UTF8ToWide(kv.first + '=' + kv.second)),
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&command_line);
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}
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for (const base::FilePath& attachment : data->attachments) {
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AppendCommandLineArgument(
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FormatArgumentString("attachment", attachment.value()),
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&command_line);
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}
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ScopedKernelHANDLE this_process(
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OpenProcess(kXPProcessAllAccess, true, GetCurrentProcessId()));
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if (!this_process.is_valid()) {
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PLOG(ERROR) << "OpenProcess";
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return false;
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}
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InitialClientData initial_client_data(
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g_signal_exception,
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g_wer_registration.dump_without_crashing,
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g_wer_registration.dump_completed,
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data->ipc_pipe_handle.get(),
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this_process.get(),
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FromPointerCast<WinVMAddress>(&g_crash_exception_information),
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FromPointerCast<WinVMAddress>(&g_non_crash_exception_information),
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FromPointerCast<WinVMAddress>(&g_critical_section_with_debug_info));
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AppendCommandLineArgument(
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base::UTF8ToWide(std::string("--initial-client-data=") +
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initial_client_data.StringRepresentation()),
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&command_line);
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|
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BOOL rv;
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DWORD creation_flags;
|
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STARTUPINFOEX startup_info = {};
|
||
startup_info.StartupInfo.dwFlags = STARTF_USESTDHANDLES;
|
||
startup_info.StartupInfo.hStdInput = GetStdHandle(STD_INPUT_HANDLE);
|
||
startup_info.StartupInfo.hStdOutput = GetStdHandle(STD_OUTPUT_HANDLE);
|
||
startup_info.StartupInfo.hStdError = GetStdHandle(STD_ERROR_HANDLE);
|
||
|
||
std::vector<HANDLE> handle_list;
|
||
std::unique_ptr<uint8_t[]> proc_thread_attribute_list_storage;
|
||
ScopedProcThreadAttributeList proc_thread_attribute_list_owner;
|
||
|
||
static const auto initialize_proc_thread_attribute_list =
|
||
GET_FUNCTION(L"kernel32.dll", ::InitializeProcThreadAttributeList);
|
||
static const auto update_proc_thread_attribute =
|
||
initialize_proc_thread_attribute_list
|
||
? GET_FUNCTION(L"kernel32.dll", ::UpdateProcThreadAttribute)
|
||
: nullptr;
|
||
if (!initialize_proc_thread_attribute_list || !update_proc_thread_attribute) {
|
||
// The OS doesn’t allow handle inheritance to be restricted, so the handler
|
||
// will inherit every inheritable handle.
|
||
creation_flags = 0;
|
||
startup_info.StartupInfo.cb = sizeof(startup_info.StartupInfo);
|
||
} else {
|
||
// Restrict handle inheritance to just those needed in the handler.
|
||
|
||
creation_flags = EXTENDED_STARTUPINFO_PRESENT;
|
||
startup_info.StartupInfo.cb = sizeof(startup_info);
|
||
SIZE_T size;
|
||
rv = initialize_proc_thread_attribute_list(nullptr, 1, 0, &size);
|
||
if (rv) {
|
||
LOG(ERROR) << "InitializeProcThreadAttributeList (size) succeeded, "
|
||
"expected failure";
|
||
return false;
|
||
} else if (GetLastError() != ERROR_INSUFFICIENT_BUFFER) {
|
||
PLOG(ERROR) << "InitializeProcThreadAttributeList (size)";
|
||
return false;
|
||
}
|
||
|
||
proc_thread_attribute_list_storage.reset(new uint8_t[size]);
|
||
startup_info.lpAttributeList =
|
||
reinterpret_cast<PPROC_THREAD_ATTRIBUTE_LIST>(
|
||
proc_thread_attribute_list_storage.get());
|
||
rv = initialize_proc_thread_attribute_list(
|
||
startup_info.lpAttributeList, 1, 0, &size);
|
||
if (!rv) {
|
||
PLOG(ERROR) << "InitializeProcThreadAttributeList";
|
||
return false;
|
||
}
|
||
proc_thread_attribute_list_owner.reset(startup_info.lpAttributeList);
|
||
|
||
handle_list.reserve(8);
|
||
handle_list.push_back(g_signal_exception);
|
||
handle_list.push_back(g_wer_registration.dump_without_crashing);
|
||
handle_list.push_back(g_wer_registration.dump_completed);
|
||
handle_list.push_back(data->ipc_pipe_handle.get());
|
||
handle_list.push_back(this_process.get());
|
||
AddHandleToListIfValidAndInheritable(&handle_list,
|
||
startup_info.StartupInfo.hStdInput);
|
||
AddHandleToListIfValidAndInheritable(&handle_list,
|
||
startup_info.StartupInfo.hStdOutput);
|
||
AddHandleToListIfValidAndInheritable(&handle_list,
|
||
startup_info.StartupInfo.hStdError);
|
||
rv = update_proc_thread_attribute(
|
||
startup_info.lpAttributeList,
|
||
0,
|
||
PROC_THREAD_ATTRIBUTE_HANDLE_LIST,
|
||
&handle_list[0],
|
||
handle_list.size() * sizeof(handle_list[0]),
|
||
nullptr,
|
||
nullptr);
|
||
if (!rv) {
|
||
PLOG(ERROR) << "UpdateProcThreadAttribute";
|
||
return false;
|
||
}
|
||
}
|
||
|
||
// If the embedded crashpad handler is being started via an entry point in a
|
||
// DLL (the handler executable is rundll32.exe), then don't pass
|
||
// the application name to CreateProcess as this appears to generate an
|
||
// invalid command line where the first argument needed by rundll32 is not in
|
||
// the correct format as required in:
|
||
// https://support.microsoft.com/en-ca/help/164787/info-windows-rundll-and-rundll32-interface
|
||
const base::WStringPiece kRunDll32Exe(L"rundll32.exe");
|
||
bool is_embedded_in_dll = false;
|
||
if (data->handler.value().size() >= kRunDll32Exe.size() &&
|
||
_wcsicmp(data->handler.value()
|
||
.substr(data->handler.value().size() - kRunDll32Exe.size())
|
||
.c_str(),
|
||
kRunDll32Exe.data()) == 0) {
|
||
is_embedded_in_dll = true;
|
||
}
|
||
|
||
PROCESS_INFORMATION process_info;
|
||
rv = CreateProcess(
|
||
is_embedded_in_dll ? nullptr : data->handler.value().c_str(),
|
||
&command_line[0],
|
||
nullptr,
|
||
nullptr,
|
||
true,
|
||
creation_flags,
|
||
nullptr,
|
||
nullptr,
|
||
&startup_info.StartupInfo,
|
||
&process_info);
|
||
if (!rv) {
|
||
PLOG(ERROR) << "CreateProcess";
|
||
return false;
|
||
}
|
||
|
||
rv = CloseHandle(process_info.hThread);
|
||
PLOG_IF(WARNING, !rv) << "CloseHandle thread";
|
||
|
||
rv = CloseHandle(process_info.hProcess);
|
||
PLOG_IF(WARNING, !rv) << "CloseHandle process";
|
||
|
||
// It is important to close our side of the pipe here before confirming that
|
||
// we can communicate with the server. By doing so, the only remaining copy of
|
||
// the server side of the pipe belongs to the exception handler process we
|
||
// just spawned. Otherwise, the pipe will continue to exist indefinitely, so
|
||
// the connection loop will not detect that it will never be serviced.
|
||
data->ipc_pipe_handle.reset();
|
||
|
||
// Confirm that the server is waiting for connections before continuing.
|
||
ClientToServerMessage message = {};
|
||
message.type = ClientToServerMessage::kPing;
|
||
ServerToClientMessage response = {};
|
||
if (!SendToCrashHandlerServer(data->ipc_pipe, message, &response)) {
|
||
return false;
|
||
}
|
||
|
||
scoped_startup_state_caller.SetSuccessful();
|
||
return true;
|
||
}
|
||
|
||
DWORD WINAPI BackgroundHandlerStartThreadProc(void* data) {
|
||
std::unique_ptr<BackgroundHandlerStartThreadData> data_as_ptr(
|
||
reinterpret_cast<BackgroundHandlerStartThreadData*>(data));
|
||
return StartHandlerProcess(std::move(data_as_ptr)) ? 0 : 1;
|
||
}
|
||
|
||
void CommonInProcessInitialization() {
|
||
// We create this dummy CRITICAL_SECTION with the
|
||
// RTL_CRITICAL_SECTION_FLAG_FORCE_DEBUG_INFO flag set to have an entry point
|
||
// into the doubly-linked list of RTL_CRITICAL_SECTION_DEBUG objects. This
|
||
// allows us to walk the list at crash time to gather data for !locks. A
|
||
// debugger would instead inspect ntdll!RtlCriticalSectionList to get the head
|
||
// of the list. But that is not an exported symbol, so on an arbitrary client
|
||
// machine, we don't have a way of getting that pointer.
|
||
InitializeCriticalSectionWithDebugInfoIfPossible(
|
||
&g_critical_section_with_debug_info);
|
||
|
||
g_non_crash_dump_lock = new base::Lock();
|
||
}
|
||
|
||
void RegisterHandlers() {
|
||
SetUnhandledExceptionFilter(&UnhandledExceptionHandler);
|
||
|
||
// The Windows CRT's signal.h lists:
|
||
// - SIGINT
|
||
// - SIGILL
|
||
// - SIGFPE
|
||
// - SIGSEGV
|
||
// - SIGTERM
|
||
// - SIGBREAK
|
||
// - SIGABRT
|
||
// SIGILL and SIGTERM are documented as not being generated. SIGBREAK and
|
||
// SIGINT are for Ctrl-Break and Ctrl-C, and aren't something for which
|
||
// capturing a dump is warranted. SIGFPE and SIGSEGV are captured as regular
|
||
// exceptions through the unhandled exception filter. This leaves SIGABRT. In
|
||
// the standard CRT, abort() is implemented as a synchronous call to the
|
||
// SIGABRT signal handler if installed, but after doing so, the unhandled
|
||
// exception filter is not triggered (it instead __fastfail()s). So, register
|
||
// to handle SIGABRT to catch abort() calls, as client code might use this and
|
||
// expect it to cause a crash dump. This will only work when the abort()
|
||
// that's called in client code is the same (or has the same behavior) as the
|
||
// one in use here.
|
||
void (*rv)(int) = signal(SIGABRT, HandleAbortSignal);
|
||
DCHECK_NE(rv, SIG_ERR);
|
||
}
|
||
|
||
} // namespace
|
||
|
||
CrashpadClient::CrashpadClient() : ipc_pipe_(), handler_start_thread_() {}
|
||
|
||
CrashpadClient::~CrashpadClient() {}
|
||
|
||
bool CrashpadClient::StartHandler(
|
||
const base::FilePath& handler,
|
||
const base::FilePath& database,
|
||
const base::FilePath& metrics_dir,
|
||
const std::string& url,
|
||
const std::map<std::string, std::string>& annotations,
|
||
const std::vector<std::string>& arguments,
|
||
bool restartable,
|
||
bool asynchronous_start,
|
||
const std::vector<base::FilePath>& attachments) {
|
||
DCHECK(ipc_pipe_.empty());
|
||
|
||
// Both the pipe and the signalling events have to be created on the main
|
||
// thread (not the spawning thread) so that they're valid after we return from
|
||
// this function.
|
||
ScopedFileHANDLE ipc_pipe_handle;
|
||
CreatePipe(&ipc_pipe_, &ipc_pipe_handle);
|
||
|
||
SECURITY_ATTRIBUTES security_attributes = {0};
|
||
security_attributes.nLength = sizeof(SECURITY_ATTRIBUTES);
|
||
security_attributes.bInheritHandle = true;
|
||
|
||
g_signal_exception =
|
||
CreateEvent(&security_attributes, false /* auto reset */, false, nullptr);
|
||
g_wer_registration.dump_without_crashing =
|
||
CreateEvent(&security_attributes, false /* auto reset */, false, nullptr);
|
||
g_wer_registration.dump_completed =
|
||
CreateEvent(&security_attributes, false /* auto reset */, false, nullptr);
|
||
|
||
CommonInProcessInitialization();
|
||
|
||
RegisterHandlers();
|
||
|
||
auto data = new BackgroundHandlerStartThreadData(handler,
|
||
database,
|
||
metrics_dir,
|
||
url,
|
||
annotations,
|
||
arguments,
|
||
attachments,
|
||
ipc_pipe_,
|
||
std::move(ipc_pipe_handle));
|
||
|
||
if (asynchronous_start) {
|
||
// It is important that the current thread not be synchronized with the
|
||
// thread that is created here. StartHandler() needs to be callable inside a
|
||
// DllMain(). In that case, the background thread will not start until the
|
||
// current DllMain() completes, which would cause deadlock if it was waited
|
||
// upon.
|
||
handler_start_thread_.reset(CreateThread(nullptr,
|
||
0,
|
||
&BackgroundHandlerStartThreadProc,
|
||
reinterpret_cast<void*>(data),
|
||
0,
|
||
nullptr));
|
||
if (!handler_start_thread_.is_valid()) {
|
||
PLOG(ERROR) << "CreateThread";
|
||
SetHandlerStartupState(StartupState::kFailed);
|
||
return false;
|
||
}
|
||
|
||
// In asynchronous mode, we can't report on the overall success or failure
|
||
// of initialization at this point.
|
||
return true;
|
||
} else {
|
||
return StartHandlerProcess(
|
||
std::unique_ptr<BackgroundHandlerStartThreadData>(data));
|
||
}
|
||
}
|
||
|
||
bool CrashpadClient::SetHandlerIPCPipe(const std::wstring& ipc_pipe) {
|
||
DCHECK(ipc_pipe_.empty());
|
||
DCHECK(!ipc_pipe.empty());
|
||
|
||
ipc_pipe_ = ipc_pipe;
|
||
|
||
DCHECK(!ipc_pipe_.empty());
|
||
DCHECK_EQ(g_signal_exception, INVALID_HANDLE_VALUE);
|
||
DCHECK_EQ(g_wer_registration.dump_without_crashing, INVALID_HANDLE_VALUE);
|
||
DCHECK_EQ(g_wer_registration.dump_completed, INVALID_HANDLE_VALUE);
|
||
DCHECK(!g_critical_section_with_debug_info.DebugInfo);
|
||
DCHECK(!g_non_crash_dump_lock);
|
||
|
||
ClientToServerMessage message;
|
||
memset(&message, 0, sizeof(message));
|
||
message.type = ClientToServerMessage::kRegister;
|
||
message.registration.version = RegistrationRequest::kMessageVersion;
|
||
message.registration.client_process_id = GetCurrentProcessId();
|
||
message.registration.crash_exception_information =
|
||
FromPointerCast<WinVMAddress>(&g_crash_exception_information);
|
||
message.registration.non_crash_exception_information =
|
||
FromPointerCast<WinVMAddress>(&g_non_crash_exception_information);
|
||
|
||
CommonInProcessInitialization();
|
||
|
||
message.registration.critical_section_address =
|
||
FromPointerCast<WinVMAddress>(&g_critical_section_with_debug_info);
|
||
|
||
ServerToClientMessage response = {};
|
||
|
||
if (!SendToCrashHandlerServer(ipc_pipe_, message, &response)) {
|
||
return false;
|
||
}
|
||
|
||
SetHandlerStartupState(StartupState::kSucceeded);
|
||
|
||
RegisterHandlers();
|
||
|
||
// The server returns these already duplicated to be valid in this process.
|
||
g_signal_exception =
|
||
IntToHandle(response.registration.request_crash_dump_event);
|
||
g_wer_registration.dump_without_crashing =
|
||
IntToHandle(response.registration.request_non_crash_dump_event);
|
||
g_wer_registration.dump_completed =
|
||
IntToHandle(response.registration.non_crash_dump_completed_event);
|
||
|
||
return true;
|
||
}
|
||
|
||
std::wstring CrashpadClient::GetHandlerIPCPipe() const {
|
||
DCHECK(!ipc_pipe_.empty());
|
||
return ipc_pipe_;
|
||
}
|
||
|
||
bool CrashpadClient::WaitForHandlerStart(unsigned int timeout_ms) {
|
||
DCHECK(handler_start_thread_.is_valid());
|
||
DWORD result = WaitForSingleObject(handler_start_thread_.get(), timeout_ms);
|
||
if (result == WAIT_TIMEOUT) {
|
||
LOG(ERROR) << "WaitForSingleObject timed out";
|
||
return false;
|
||
} else if (result == WAIT_ABANDONED) {
|
||
LOG(ERROR) << "WaitForSingleObject abandoned";
|
||
return false;
|
||
} else if (result != WAIT_OBJECT_0) {
|
||
PLOG(ERROR) << "WaitForSingleObject";
|
||
return false;
|
||
}
|
||
|
||
DWORD exit_code;
|
||
if (!GetExitCodeThread(handler_start_thread_.get(), &exit_code)) {
|
||
PLOG(ERROR) << "GetExitCodeThread";
|
||
return false;
|
||
}
|
||
|
||
handler_start_thread_.reset();
|
||
return exit_code == 0;
|
||
}
|
||
|
||
bool CrashpadClient::RegisterWerModule(const std::wstring& path) {
|
||
if (g_wer_registration.dump_completed == INVALID_HANDLE_VALUE ||
|
||
g_wer_registration.dump_without_crashing == INVALID_HANDLE_VALUE) {
|
||
LOG(ERROR) << "not connected";
|
||
return false;
|
||
}
|
||
// We cannot point (*context).exception_pointers to our pointers yet as it
|
||
// might get used for other non-crash dumps.
|
||
g_wer_registration.crashpad_exception_info =
|
||
&g_non_crash_exception_information;
|
||
// we can point these as we are the only users.
|
||
g_wer_registration.pointers.ExceptionRecord = &g_wer_registration.exception;
|
||
g_wer_registration.pointers.ContextRecord = &g_wer_registration.context;
|
||
|
||
HRESULT res =
|
||
WerRegisterRuntimeExceptionModule(path.c_str(), &g_wer_registration);
|
||
return res == S_OK;
|
||
}
|
||
|
||
// static
|
||
void CrashpadClient::DumpWithoutCrash(const CONTEXT& context) {
|
||
if (g_wer_registration.dump_without_crashing == INVALID_HANDLE_VALUE ||
|
||
g_wer_registration.dump_completed == INVALID_HANDLE_VALUE) {
|
||
LOG(ERROR) << "not connected";
|
||
return;
|
||
}
|
||
|
||
if (BlockUntilHandlerStartedOrFailed() == StartupState::kFailed) {
|
||
// If we know for certain that the handler has failed to start, then abort
|
||
// here, as we would otherwise wait indefinitely for the
|
||
// g_wer_registration.dump_completed event that would never be signalled.
|
||
LOG(ERROR) << "crash server failed to launch, no dump captured";
|
||
return;
|
||
}
|
||
|
||
// In the non-crashing case, we aren't concerned about avoiding calls into
|
||
// Win32 APIs, so just use regular locking here in case of multiple threads
|
||
// calling this function. If a crash occurs while we're in here, the worst
|
||
// that can happen is that the server captures a partial dump for this path
|
||
// because another thread’s crash processing finished and the process was
|
||
// terminated before this thread’s non-crash processing could be completed.
|
||
base::AutoLock lock(*g_non_crash_dump_lock);
|
||
|
||
// Create a fake EXCEPTION_POINTERS to give the handler something to work
|
||
// with.
|
||
EXCEPTION_POINTERS exception_pointers = {};
|
||
|
||
// This is logically const, but EXCEPTION_POINTERS does not declare it as
|
||
// const, so we have to cast that away from the argument.
|
||
exception_pointers.ContextRecord = const_cast<CONTEXT*>(&context);
|
||
|
||
// We include a fake exception and use a code of '0x517a7ed' (something like
|
||
// "simulated") so that it's relatively obvious in windbg that it's not
|
||
// actually an exception. Most values in
|
||
// https://msdn.microsoft.com/library/aa363082.aspx have some of the top
|
||
// nibble set, so we make sure to pick a value that doesn't, so as to be
|
||
// unlikely to conflict.
|
||
constexpr uint32_t kSimulatedExceptionCode = 0x517a7ed;
|
||
EXCEPTION_RECORD record = {};
|
||
record.ExceptionCode = kSimulatedExceptionCode;
|
||
record.ExceptionAddress = ProgramCounterFromCONTEXT(&context);
|
||
|
||
exception_pointers.ExceptionRecord = &record;
|
||
|
||
g_non_crash_exception_information.thread_id = GetCurrentThreadId();
|
||
g_non_crash_exception_information.exception_pointers =
|
||
FromPointerCast<WinVMAddress>(&exception_pointers);
|
||
|
||
g_wer_registration.in_dump_without_crashing = true;
|
||
bool set_event_result = !!SetEvent(g_wer_registration.dump_without_crashing);
|
||
PLOG_IF(ERROR, !set_event_result) << "SetEvent";
|
||
|
||
DWORD wfso_result =
|
||
WaitForSingleObject(g_wer_registration.dump_completed, INFINITE);
|
||
PLOG_IF(ERROR, wfso_result != WAIT_OBJECT_0) << "WaitForSingleObject";
|
||
g_wer_registration.in_dump_without_crashing = false;
|
||
}
|
||
|
||
// static
|
||
void CrashpadClient::DumpAndCrash(EXCEPTION_POINTERS* exception_pointers) {
|
||
if (g_signal_exception == INVALID_HANDLE_VALUE) {
|
||
LOG(ERROR) << "not connected";
|
||
SafeTerminateProcess(GetCurrentProcess(),
|
||
kTerminationCodeNotConnectedToHandler);
|
||
return;
|
||
}
|
||
|
||
// We don't need to check for handler startup here, as
|
||
// UnhandledExceptionHandler() necessarily does that.
|
||
|
||
UnhandledExceptionHandler(exception_pointers);
|
||
}
|
||
|
||
// static
|
||
bool CrashpadClient::DumpAndCrashTargetProcess(HANDLE process,
|
||
HANDLE blame_thread,
|
||
DWORD exception_code) {
|
||
// Confirm we're on Vista or later.
|
||
const DWORD version = GetVersion();
|
||
const DWORD major_version = LOBYTE(LOWORD(version));
|
||
if (major_version < 6) {
|
||
LOG(ERROR) << "unavailable before Vista";
|
||
return false;
|
||
}
|
||
|
||
// Confirm that our bitness is the same as the process we're crashing.
|
||
ProcessInfo process_info;
|
||
if (!process_info.Initialize(process)) {
|
||
LOG(ERROR) << "ProcessInfo::Initialize";
|
||
return false;
|
||
}
|
||
#if defined(ARCH_CPU_64_BITS)
|
||
if (!process_info.Is64Bit()) {
|
||
LOG(ERROR) << "DumpAndCrashTargetProcess currently not supported x64->x86";
|
||
return false;
|
||
}
|
||
#endif // ARCH_CPU_64_BITS
|
||
|
||
ScopedProcessSuspend suspend(process);
|
||
|
||
// If no thread handle was provided, or the thread has already exited, we pass
|
||
// 0 to the handler, which indicates no fake exception record to be created.
|
||
DWORD thread_id = 0;
|
||
if (blame_thread) {
|
||
// Now that we've suspended the process, if our thread hasn't exited, we
|
||
// know we're relatively safe to pass the thread id through.
|
||
if (WaitForSingleObject(blame_thread, 0) == WAIT_TIMEOUT) {
|
||
static const auto get_thread_id =
|
||
GET_FUNCTION_REQUIRED(L"kernel32.dll", ::GetThreadId);
|
||
thread_id = get_thread_id(blame_thread);
|
||
}
|
||
}
|
||
|
||
constexpr size_t kInjectBufferSize = 4 * 1024;
|
||
WinVMAddress inject_memory =
|
||
FromPointerCast<WinVMAddress>(VirtualAllocEx(process,
|
||
nullptr,
|
||
kInjectBufferSize,
|
||
MEM_RESERVE | MEM_COMMIT,
|
||
PAGE_READWRITE));
|
||
if (!inject_memory) {
|
||
PLOG(ERROR) << "VirtualAllocEx";
|
||
return false;
|
||
}
|
||
|
||
// Because we're the same bitness as our target, we can rely kernel32 being
|
||
// loaded at the same address in our process as the target, and just look up
|
||
// its address here.
|
||
WinVMAddress raise_exception_address =
|
||
FromPointerCast<WinVMAddress>(&RaiseException);
|
||
|
||
WinVMAddress code_entry_point = 0;
|
||
std::vector<unsigned char> data_to_write;
|
||
if (process_info.Is64Bit()) {
|
||
// Data written is first, the data for the 4th argument (lpArguments) to
|
||
// RaiseException(). A two element array:
|
||
//
|
||
// DWORD64: thread_id
|
||
// DWORD64: exception_code
|
||
//
|
||
// Following that, code which sets the arguments to RaiseException() and
|
||
// then calls it:
|
||
//
|
||
// mov r9, <data_array_address>
|
||
// mov r8d, 2 ; nNumberOfArguments
|
||
// mov edx, 1 ; dwExceptionFlags = EXCEPTION_NONCONTINUABLE
|
||
// mov ecx, 0xcca11ed ; dwExceptionCode, interpreted specially by the
|
||
// ; handler.
|
||
// jmp <address_of_RaiseException>
|
||
//
|
||
// Note that the first three arguments to RaiseException() are DWORDs even
|
||
// on x64, so only the 4th argument (a pointer) is a full-width register.
|
||
//
|
||
// We also don't need to set up a stack or use call, since the only
|
||
// registers modified are volatile ones, and we can just jmp straight to
|
||
// RaiseException().
|
||
|
||
// The data array.
|
||
AddUint64(&data_to_write, thread_id);
|
||
AddUint64(&data_to_write, exception_code);
|
||
|
||
// The thread entry point.
|
||
code_entry_point = inject_memory + data_to_write.size();
|
||
|
||
// r9 = pointer to data.
|
||
data_to_write.push_back(0x49);
|
||
data_to_write.push_back(0xb9);
|
||
AddUint64(&data_to_write, inject_memory);
|
||
|
||
// r8d = 2 for nNumberOfArguments.
|
||
data_to_write.push_back(0x41);
|
||
data_to_write.push_back(0xb8);
|
||
AddUint32(&data_to_write, 2);
|
||
|
||
// edx = 1 for dwExceptionFlags.
|
||
data_to_write.push_back(0xba);
|
||
AddUint32(&data_to_write, 1);
|
||
|
||
// ecx = kTriggeredExceptionCode for dwExceptionCode.
|
||
data_to_write.push_back(0xb9);
|
||
AddUint32(&data_to_write, ExceptionCodes::kTriggeredExceptionCode);
|
||
|
||
// jmp to RaiseException() via rax.
|
||
data_to_write.push_back(0x48); // mov rax, imm.
|
||
data_to_write.push_back(0xb8);
|
||
AddUint64(&data_to_write, raise_exception_address);
|
||
data_to_write.push_back(0xff); // jmp rax.
|
||
data_to_write.push_back(0xe0);
|
||
} else {
|
||
// Data written is first, the data for the 4th argument (lpArguments) to
|
||
// RaiseException(). A two element array:
|
||
//
|
||
// DWORD: thread_id
|
||
// DWORD: exception_code
|
||
//
|
||
// Following that, code which pushes our arguments to RaiseException() and
|
||
// then calls it:
|
||
//
|
||
// push <data_array_address>
|
||
// push 2 ; nNumberOfArguments
|
||
// push 1 ; dwExceptionFlags = EXCEPTION_NONCONTINUABLE
|
||
// push 0xcca11ed ; dwExceptionCode, interpreted specially by the handler.
|
||
// call <address_of_RaiseException>
|
||
// ud2 ; Generate invalid opcode to make sure we still crash if we return
|
||
// ; for some reason.
|
||
//
|
||
// No need to clean up the stack, as RaiseException() is __stdcall.
|
||
|
||
// The data array.
|
||
AddUint32(&data_to_write, thread_id);
|
||
AddUint32(&data_to_write, exception_code);
|
||
|
||
// The thread entry point.
|
||
code_entry_point = inject_memory + data_to_write.size();
|
||
|
||
// Push data address.
|
||
data_to_write.push_back(0x68);
|
||
AddUint32(&data_to_write, static_cast<uint32_t>(inject_memory));
|
||
|
||
// Push 2 for nNumberOfArguments.
|
||
data_to_write.push_back(0x6a);
|
||
data_to_write.push_back(2);
|
||
|
||
// Push 1 for dwExceptionCode.
|
||
data_to_write.push_back(0x6a);
|
||
data_to_write.push_back(1);
|
||
|
||
// Push dwExceptionFlags.
|
||
data_to_write.push_back(0x68);
|
||
AddUint32(&data_to_write, kTriggeredExceptionCode);
|
||
|
||
// Relative call to RaiseException().
|
||
int64_t relative_address_to_raise_exception =
|
||
raise_exception_address - (inject_memory + data_to_write.size() + 5);
|
||
data_to_write.push_back(0xe8);
|
||
AddUint32(&data_to_write,
|
||
static_cast<uint32_t>(relative_address_to_raise_exception));
|
||
|
||
// ud2.
|
||
data_to_write.push_back(0x0f);
|
||
data_to_write.push_back(0x0b);
|
||
}
|
||
|
||
DCHECK_LT(data_to_write.size(), kInjectBufferSize);
|
||
|
||
SIZE_T bytes_written;
|
||
if (!WriteProcessMemory(process,
|
||
reinterpret_cast<void*>(inject_memory),
|
||
data_to_write.data(),
|
||
data_to_write.size(),
|
||
&bytes_written)) {
|
||
PLOG(ERROR) << "WriteProcessMemory";
|
||
return false;
|
||
}
|
||
|
||
if (bytes_written != data_to_write.size()) {
|
||
LOG(ERROR) << "WriteProcessMemory unexpected number of bytes";
|
||
return false;
|
||
}
|
||
|
||
if (!FlushInstructionCache(
|
||
process, reinterpret_cast<void*>(inject_memory), bytes_written)) {
|
||
PLOG(ERROR) << "FlushInstructionCache";
|
||
return false;
|
||
}
|
||
|
||
DWORD old_protect;
|
||
if (!VirtualProtectEx(process,
|
||
reinterpret_cast<void*>(inject_memory),
|
||
kInjectBufferSize,
|
||
PAGE_EXECUTE_READ,
|
||
&old_protect)) {
|
||
PLOG(ERROR) << "VirtualProtectEx";
|
||
return false;
|
||
}
|
||
|
||
// Cause an exception in the target process by creating a thread which calls
|
||
// RaiseException with our arguments above. Note that we cannot get away with
|
||
// using DebugBreakProcess() (nothing happens unless a debugger is attached)
|
||
// and we cannot get away with CreateRemoteThread() because it doesn't work if
|
||
// the target is hung waiting for the loader lock. We use NtCreateThreadEx()
|
||
// with the SKIP_THREAD_ATTACH flag, which skips various notifications,
|
||
// letting this cause an exception, even when the target is stuck in the
|
||
// loader lock.
|
||
HANDLE injected_thread;
|
||
|
||
// This is what DebugBreakProcess() uses.
|
||
constexpr size_t kStackSize = 0x4000;
|
||
|
||
NTSTATUS status = NtCreateThreadEx(&injected_thread,
|
||
STANDARD_RIGHTS_ALL | SPECIFIC_RIGHTS_ALL,
|
||
nullptr,
|
||
process,
|
||
reinterpret_cast<void*>(code_entry_point),
|
||
nullptr,
|
||
THREAD_CREATE_FLAGS_SKIP_THREAD_ATTACH,
|
||
0,
|
||
kStackSize,
|
||
0,
|
||
nullptr);
|
||
if (!NT_SUCCESS(status)) {
|
||
NTSTATUS_LOG(ERROR, status) << "NtCreateThreadEx";
|
||
return false;
|
||
}
|
||
|
||
// The injected thread raises an exception and ultimately results in process
|
||
// termination. The suspension must be made aware that the process may be
|
||
// terminating, otherwise it’ll log an extraneous error.
|
||
suspend.TolerateTermination();
|
||
|
||
bool result = true;
|
||
if (WaitForSingleObject(injected_thread, 60 * 1000) != WAIT_OBJECT_0) {
|
||
PLOG(ERROR) << "WaitForSingleObject";
|
||
result = false;
|
||
}
|
||
|
||
status = NtClose(injected_thread);
|
||
if (!NT_SUCCESS(status)) {
|
||
NTSTATUS_LOG(ERROR, status) << "NtClose";
|
||
result = false;
|
||
}
|
||
|
||
return result;
|
||
}
|
||
|
||
} // namespace crashpad
|