Microsoft Windows OS family employs some exception handling mechanisms that are based on the operation system specifics.
Contents |
Microsoft Structured Exception Handling is the native exception handling mechanism for Windows and a forerunner technology to VEH.[1] It features the finally
mechanism not present in standard С++ exceptions (but present in most imperative languages introduced later).
SEH is set up and handled separately for each thread of execution.
Microsoft supports SEH as a programming technique at compiler level only. MS Visual C++ compiler features 3 non-standard keywords: __try
, __except
and __finally
— for this purpose. Other exception handling aspects are backed up by a number of Win32 API functions,[2] e.g. RaiseException
to raise SEH exceptions manually.
Each thread of execution in Windows has a link to an undocumented _EXCEPTION_REGISTRATION_RECORD list at the start of its Thread Information Block. The __try
statement essentially calls a compiler-defined EH_prolog
function. That function allocates an _EXCEPTION_REGISTRATION_RECORD on the stack pointing to __except_handler3
function in msvcrt.dll
,[3] then adds the record to the list's head. At the end of the __try
block a compiler-defined EH_epilog
function is called that does the reverse operation. Either of these compiler-defined routines can be inline. All the programmer-defined __except
and __finally
blocks are called from within __except_handler3
. If such blocks are present, _EXCEPTION_REGISTRATION_RECORD being created is extended with a few additional fields used by __except_handler3
.[4]
In a case of an exception in a user mode code, the operating system[5] parses the thread's _EXCEPTION_REGISTRATION_RECORD list and calls each exception handler in sequence until a handler signals it has handled the exception (by return value) or the list is exhausted. The last one in the list is always the kernel32!UnhandledExceptionFilter
which displayes the General protection fault error message.[6] Then the list is traversed once more giving handlers a chance to clean up any resources used. Finally, the execution returns to kernel mode[7] where the process is either resumed or terminated.
Vectored Exception Handling was introduced in Windows XP.[8] Vectored Exception Handling is made available to Windows programmers using languages such as C++ and Visual Basic. VEH does not replace Structured Exception Handling (SEH), rather VEH and SEH coexist with VEH handlers having priority over SEH handlers.[1][8] Compared with SEH, VEH works more like a traditional notification callback scheme.[9]
Use AddVectoredExceptionHandler API
ntdll.dll
and kernel32.dll
have this function compiled-in insteadntdll!RtlDispatchException
system routine called from ntdll!KiUserExceptionDispatcher
which is in turn called from the nt!KiDispatchException
kernel function. (See Ken Johnson (November 16, 2007, 7:00 am). "A catalog of NTDLL kernel mode to user mode callbacks, part 2: KiUserExceptionDispatcher". http://www.nynaeve.net/?p=201. for details)ntdll!KiUserExceptionDispatcher
calls either nt!ZwContinue
or nt!ZwRaiseException