Structured Exception Handling (C/C++)
Structured exception handling (SEH) is a Microsoft extension to C and C++ to handle certain exceptional code situations, such as hardware faults, gracefully. Although Windows and Microsoft C++ support SEH, we recommend that you use ISO-standard C++ exception handling in C++ code. It makes your code more portable and flexible. However, to maintain existing code or for particular kinds of programs, you still might have to use SEH.
Microsoft-specific:
Grammar
try-except-statement
:
__try
compound-statement
__except
(
filter-expression
)
compound-statement
try-finally-statement
:
__try
compound-statement
__finally
compound-statement
Remarks
With SEH, you can ensure that resources, such as memory blocks and files, get released correctly if execution unexpectedly terminates. You can also handle specific problems—for example, insufficient memory—by using concise structured code that doesn't rely on goto
statements or elaborate testing of return codes.
The try-except
and try-finally
statements referred to in this article are Microsoft extensions to the C and C++ languages. They support SEH by enabling applications to gain control of a program after events that would otherwise terminate execution. Although SEH works with C++ source files, it's not specifically designed for C++. If you use SEH in a C++ program that you compile by using the /EHa
or /EHsc
option, destructors for local objects are called, but other execution behavior might not be what you expect. For an illustration, see the example later in this article. In most cases, instead of SEH we recommend that you use ISO-standard C++ exception handling. By using C++ exception handling, you can ensure that your code is more portable, and you can handle exceptions of any type.
If you have C code that uses SEH, you can mix it with C++ code that uses C++ exception handling. For information, see Handle structured exceptions in C++.
There are two SEH mechanisms:
Exception handlers, or
__except
blocks, which can respond to or dismiss the exception based on thefilter-expression
value. For more information, seetry-except
statement.Termination handlers, or
__finally
blocks, which are always called, whether an exception causes termination or not. For more information, seetry-finally
statement.
These two kinds of handlers are distinct, but are closely related through a process known as unwinding the stack. When a structured exception occurs, Windows looks for the most recently installed exception handler that's currently active. The handler can do one of three things:
Fail to recognize the exception and pass control to other handlers (
EXCEPTION_CONTINUE_SEARCH
).Recognize the exception but dismiss it (
EXCEPTION_CONTINUE_EXECUTION
).Recognize the exception and handle it (
EXCEPTION_EXECUTE_HANDLER
).
The exception handler that recognizes the exception may not be in the function that was running when the exception occurred. It may be in a function much higher on the stack. The currently running function and all other functions on the stack frame are terminated. During this process, the stack is unwound. That is, local non-static variables of terminated functions get cleared from the stack.
As it unwinds the stack, the operating system calls any termination handlers that you've written for each function. By using a termination handler, you clean up resources that otherwise would remain open because of an abnormal termination. If you've entered a critical section, you can exit it in the termination handler. When the program is going to shut down, you can do other housekeeping tasks such as closing and removing temporary files.
Next steps
Example
As stated earlier, destructors for local objects are called if you use SEH in a C++ program and compile it by using the /EHa
or /EHsc
option. However, the behavior during execution may not be what you expect if you're also using C++ exceptions. This example demonstrates these behavioral differences.
#include <stdio.h>
#include <Windows.h>
#include <exception>
class TestClass
{
public:
~TestClass()
{
printf("Destroying TestClass!\n");
}
};
__declspec(noinline) void TestCPPEX()
{
#ifdef CPPEX
printf("Throwing C++ exception\n");
throw std::exception("");
#else
printf("Triggering SEH exception\n");
volatile int *pInt = 0x00000000;
*pInt = 20;
#endif
}
__declspec(noinline) void TestExceptions()
{
TestClass d;
TestCPPEX();
}
int main()
{
__try
{
TestExceptions();
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
printf("Executing SEH __except block\n");
}
return 0;
}
If you use /EHsc
to compile this code but the local test control macro CPPEX
is undefined, the TestClass
destructor doesn't run. The output looks like this:
Triggering SEH exception
Executing SEH __except block
If you use /EHsc
to compile the code and CPPEX
is defined by using /DCPPEX
(so that a C++ exception is thrown), the TestClass
destructor runs, and the output looks like this:
Throwing C++ exception
Destroying TestClass!
Executing SEH __except block
If you use /EHa
to compile the code, the TestClass
destructor executes whether an exception was thrown using a standard C++ throw
expression or by using SEH. That is, whether CPPEX
is defined or not. The output looks like this:
Throwing C++ exception
Destroying TestClass!
Executing SEH __except block
For more information, see /EH
(Exception Handling Model).
END Microsoft-specific
See also
Exception handling
Keywords
<exception>
Errors and exception handling
Structured Exception Handling (Windows)