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An example usage of catchret omitted the "to" in "to label" in ExceptionHandling.rst. llvm-svn: 247086
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==========================
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Exception Handling in LLVM
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==========================
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.. contents::
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:local:
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Introduction
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============
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This document is the central repository for all information pertaining to
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exception handling in LLVM. It describes the format that LLVM exception
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handling information takes, which is useful for those interested in creating
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front-ends or dealing directly with the information. Further, this document
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provides specific examples of what exception handling information is used for in
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C and C++.
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Itanium ABI Zero-cost Exception Handling
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----------------------------------------
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Exception handling for most programming languages is designed to recover from
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conditions that rarely occur during general use of an application. To that end,
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exception handling should not interfere with the main flow of an application's
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algorithm by performing checkpointing tasks, such as saving the current pc or
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register state.
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The Itanium ABI Exception Handling Specification defines a methodology for
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providing outlying data in the form of exception tables without inlining
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speculative exception handling code in the flow of an application's main
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algorithm. Thus, the specification is said to add "zero-cost" to the normal
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execution of an application.
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A more complete description of the Itanium ABI exception handling runtime
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support of can be found at `Itanium C++ ABI: Exception Handling
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<http://mentorembedded.github.com/cxx-abi/abi-eh.html>`_. A description of the
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exception frame format can be found at `Exception Frames
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<http://refspecs.linuxfoundation.org/LSB_3.0.0/LSB-Core-generic/LSB-Core-generic/ehframechpt.html>`_,
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with details of the DWARF 4 specification at `DWARF 4 Standard
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<http://dwarfstd.org/Dwarf4Std.php>`_. A description for the C++ exception
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table formats can be found at `Exception Handling Tables
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<http://mentorembedded.github.com/cxx-abi/exceptions.pdf>`_.
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Setjmp/Longjmp Exception Handling
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---------------------------------
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Setjmp/Longjmp (SJLJ) based exception handling uses LLVM intrinsics
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`llvm.eh.sjlj.setjmp`_ and `llvm.eh.sjlj.longjmp`_ to handle control flow for
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exception handling.
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For each function which does exception processing --- be it ``try``/``catch``
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blocks or cleanups --- that function registers itself on a global frame
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list. When exceptions are unwinding, the runtime uses this list to identify
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which functions need processing.
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Landing pad selection is encoded in the call site entry of the function
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context. The runtime returns to the function via `llvm.eh.sjlj.longjmp`_, where
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a switch table transfers control to the appropriate landing pad based on the
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index stored in the function context.
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In contrast to DWARF exception handling, which encodes exception regions and
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frame information in out-of-line tables, SJLJ exception handling builds and
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removes the unwind frame context at runtime. This results in faster exception
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handling at the expense of slower execution when no exceptions are thrown. As
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exceptions are, by their nature, intended for uncommon code paths, DWARF
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exception handling is generally preferred to SJLJ.
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Windows Runtime Exception Handling
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-----------------------------------
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LLVM supports handling exceptions produced by the Windows runtime, but it
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requires a very different intermediate representation. It is not based on the
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":ref:`landingpad <i_landingpad>`" instruction like the other two models, and is
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described later in this document under :ref:`wineh`.
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Overview
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--------
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When an exception is thrown in LLVM code, the runtime does its best to find a
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handler suited to processing the circumstance.
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The runtime first attempts to find an *exception frame* corresponding to the
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function where the exception was thrown. If the programming language supports
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exception handling (e.g. C++), the exception frame contains a reference to an
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exception table describing how to process the exception. If the language does
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not support exception handling (e.g. C), or if the exception needs to be
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forwarded to a prior activation, the exception frame contains information about
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how to unwind the current activation and restore the state of the prior
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activation. This process is repeated until the exception is handled. If the
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exception is not handled and no activations remain, then the application is
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terminated with an appropriate error message.
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Because different programming languages have different behaviors when handling
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exceptions, the exception handling ABI provides a mechanism for
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supplying *personalities*. An exception handling personality is defined by
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way of a *personality function* (e.g. ``__gxx_personality_v0`` in C++),
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which receives the context of the exception, an *exception structure*
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containing the exception object type and value, and a reference to the exception
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table for the current function. The personality function for the current
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compile unit is specified in a *common exception frame*.
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The organization of an exception table is language dependent. For C++, an
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exception table is organized as a series of code ranges defining what to do if
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an exception occurs in that range. Typically, the information associated with a
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range defines which types of exception objects (using C++ *type info*) that are
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handled in that range, and an associated action that should take place. Actions
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typically pass control to a *landing pad*.
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A landing pad corresponds roughly to the code found in the ``catch`` portion of
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a ``try``/``catch`` sequence. When execution resumes at a landing pad, it
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receives an *exception structure* and a *selector value* corresponding to the
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*type* of exception thrown. The selector is then used to determine which *catch*
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should actually process the exception.
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LLVM Code Generation
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====================
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From a C++ developer's perspective, exceptions are defined in terms of the
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``throw`` and ``try``/``catch`` statements. In this section we will describe the
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implementation of LLVM exception handling in terms of C++ examples.
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Throw
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-----
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Languages that support exception handling typically provide a ``throw``
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operation to initiate the exception process. Internally, a ``throw`` operation
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breaks down into two steps.
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#. A request is made to allocate exception space for an exception structure.
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This structure needs to survive beyond the current activation. This structure
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will contain the type and value of the object being thrown.
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#. A call is made to the runtime to raise the exception, passing the exception
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structure as an argument.
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In C++, the allocation of the exception structure is done by the
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``__cxa_allocate_exception`` runtime function. The exception raising is handled
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by ``__cxa_throw``. The type of the exception is represented using a C++ RTTI
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structure.
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Try/Catch
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---------
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A call within the scope of a *try* statement can potentially raise an
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exception. In those circumstances, the LLVM C++ front-end replaces the call with
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an ``invoke`` instruction. Unlike a call, the ``invoke`` has two potential
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continuation points:
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#. where to continue when the call succeeds as per normal, and
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#. where to continue if the call raises an exception, either by a throw or the
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unwinding of a throw
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The term used to define the place where an ``invoke`` continues after an
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exception is called a *landing pad*. LLVM landing pads are conceptually
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alternative function entry points where an exception structure reference and a
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type info index are passed in as arguments. The landing pad saves the exception
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structure reference and then proceeds to select the catch block that corresponds
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to the type info of the exception object.
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The LLVM :ref:`i_landingpad` is used to convey information about the landing
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pad to the back end. For C++, the ``landingpad`` instruction returns a pointer
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and integer pair corresponding to the pointer to the *exception structure* and
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the *selector value* respectively.
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The ``landingpad`` instruction looks for a reference to the personality
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function to be used for this ``try``/``catch`` sequence in the parent
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function's attribute list. The instruction contains a list of *cleanup*,
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*catch*, and *filter* clauses. The exception is tested against the clauses
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sequentially from first to last. The clauses have the following meanings:
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- ``catch <type> @ExcType``
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- This clause means that the landingpad block should be entered if the
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exception being thrown is of type ``@ExcType`` or a subtype of
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``@ExcType``. For C++, ``@ExcType`` is a pointer to the ``std::type_info``
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object (an RTTI object) representing the C++ exception type.
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- If ``@ExcType`` is ``null``, any exception matches, so the landingpad
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should always be entered. This is used for C++ catch-all blocks ("``catch
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(...)``").
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- When this clause is matched, the selector value will be equal to the value
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returned by "``@llvm.eh.typeid.for(i8* @ExcType)``". This will always be a
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positive value.
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- ``filter <type> [<type> @ExcType1, ..., <type> @ExcTypeN]``
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- This clause means that the landingpad should be entered if the exception
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being thrown does *not* match any of the types in the list (which, for C++,
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are again specified as ``std::type_info`` pointers).
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- C++ front-ends use this to implement C++ exception specifications, such as
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"``void foo() throw (ExcType1, ..., ExcTypeN) { ... }``".
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- When this clause is matched, the selector value will be negative.
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- The array argument to ``filter`` may be empty; for example, "``[0 x i8**]
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undef``". This means that the landingpad should always be entered. (Note
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that such a ``filter`` would not be equivalent to "``catch i8* null``",
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because ``filter`` and ``catch`` produce negative and positive selector
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values respectively.)
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- ``cleanup``
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- This clause means that the landingpad should always be entered.
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- C++ front-ends use this for calling objects' destructors.
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- When this clause is matched, the selector value will be zero.
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- The runtime may treat "``cleanup``" differently from "``catch <type>
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null``".
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In C++, if an unhandled exception occurs, the language runtime will call
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``std::terminate()``, but it is implementation-defined whether the runtime
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unwinds the stack and calls object destructors first. For example, the GNU
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C++ unwinder does not call object destructors when an unhandled exception
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occurs. The reason for this is to improve debuggability: it ensures that
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``std::terminate()`` is called from the context of the ``throw``, so that
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this context is not lost by unwinding the stack. A runtime will typically
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implement this by searching for a matching non-``cleanup`` clause, and
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aborting if it does not find one, before entering any landingpad blocks.
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Once the landing pad has the type info selector, the code branches to the code
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for the first catch. The catch then checks the value of the type info selector
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against the index of type info for that catch. Since the type info index is not
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known until all the type infos have been gathered in the backend, the catch code
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must call the `llvm.eh.typeid.for`_ intrinsic to determine the index for a given
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type info. If the catch fails to match the selector then control is passed on to
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the next catch.
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Finally, the entry and exit of catch code is bracketed with calls to
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``__cxa_begin_catch`` and ``__cxa_end_catch``.
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* ``__cxa_begin_catch`` takes an exception structure reference as an argument
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and returns the value of the exception object.
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* ``__cxa_end_catch`` takes no arguments. This function:
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#. Locates the most recently caught exception and decrements its handler
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count,
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#. Removes the exception from the *caught* stack if the handler count goes to
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zero, and
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#. Destroys the exception if the handler count goes to zero and the exception
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was not re-thrown by throw.
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.. note::
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a rethrow from within the catch may replace this call with a
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``__cxa_rethrow``.
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Cleanups
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--------
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A cleanup is extra code which needs to be run as part of unwinding a scope. C++
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destructors are a typical example, but other languages and language extensions
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provide a variety of different kinds of cleanups. In general, a landing pad may
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need to run arbitrary amounts of cleanup code before actually entering a catch
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block. To indicate the presence of cleanups, a :ref:`i_landingpad` should have
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a *cleanup* clause. Otherwise, the unwinder will not stop at the landing pad if
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there are no catches or filters that require it to.
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.. note::
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Do not allow a new exception to propagate out of the execution of a
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cleanup. This can corrupt the internal state of the unwinder. Different
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languages describe different high-level semantics for these situations: for
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example, C++ requires that the process be terminated, whereas Ada cancels both
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exceptions and throws a third.
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When all cleanups are finished, if the exception is not handled by the current
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function, resume unwinding by calling the :ref:`resume instruction <i_resume>`,
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passing in the result of the ``landingpad`` instruction for the original
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landing pad.
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Throw Filters
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-------------
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C++ allows the specification of which exception types may be thrown from a
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function. To represent this, a top level landing pad may exist to filter out
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invalid types. To express this in LLVM code the :ref:`i_landingpad` will have a
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filter clause. The clause consists of an array of type infos.
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``landingpad`` will return a negative value
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if the exception does not match any of the type infos. If no match is found then
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a call to ``__cxa_call_unexpected`` should be made, otherwise
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``_Unwind_Resume``. Each of these functions requires a reference to the
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exception structure. Note that the most general form of a ``landingpad``
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instruction can have any number of catch, cleanup, and filter clauses (though
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having more than one cleanup is pointless). The LLVM C++ front-end can generate
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such ``landingpad`` instructions due to inlining creating nested exception
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handling scopes.
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.. _undefined:
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Restrictions
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------------
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The unwinder delegates the decision of whether to stop in a call frame to that
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call frame's language-specific personality function. Not all unwinders guarantee
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that they will stop to perform cleanups. For example, the GNU C++ unwinder
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doesn't do so unless the exception is actually caught somewhere further up the
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stack.
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In order for inlining to behave correctly, landing pads must be prepared to
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handle selector results that they did not originally advertise. Suppose that a
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function catches exceptions of type ``A``, and it's inlined into a function that
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catches exceptions of type ``B``. The inliner will update the ``landingpad``
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instruction for the inlined landing pad to include the fact that ``B`` is also
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caught. If that landing pad assumes that it will only be entered to catch an
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``A``, it's in for a rude awakening. Consequently, landing pads must test for
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the selector results they understand and then resume exception propagation with
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the `resume instruction <LangRef.html#i_resume>`_ if none of the conditions
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match.
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Exception Handling Intrinsics
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=============================
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In addition to the ``landingpad`` and ``resume`` instructions, LLVM uses several
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intrinsic functions (name prefixed with ``llvm.eh``) to provide exception
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handling information at various points in generated code.
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.. _llvm.eh.typeid.for:
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``llvm.eh.typeid.for``
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----------------------
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.. code-block:: llvm
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i32 @llvm.eh.typeid.for(i8* %type_info)
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This intrinsic returns the type info index in the exception table of the current
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function. This value can be used to compare against the result of
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``landingpad`` instruction. The single argument is a reference to a type info.
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Uses of this intrinsic are generated by the C++ front-end.
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.. _llvm.eh.begincatch:
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``llvm.eh.begincatch``
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----------------------
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.. code-block:: llvm
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void @llvm.eh.begincatch(i8* %ehptr, i8* %ehobj)
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This intrinsic marks the beginning of catch handling code within the blocks
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following a ``landingpad`` instruction. The exact behavior of this function
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depends on the compilation target and the personality function associated
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with the ``landingpad`` instruction.
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The first argument to this intrinsic is a pointer that was previously extracted
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from the aggregate return value of the ``landingpad`` instruction. The second
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argument to the intrinsic is a pointer to stack space where the exception object
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should be stored. The runtime handles the details of copying the exception
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object into the slot. If the second parameter is null, no copy occurs.
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Uses of this intrinsic are generated by the C++ front-end. Many targets will
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use implementation-specific functions (such as ``__cxa_begin_catch``) instead
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of this intrinsic. The intrinsic is provided for targets that require a more
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abstract interface.
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When used in the native Windows C++ exception handling implementation, this
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intrinsic serves as a placeholder to delimit code before a catch handler is
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outlined. When the handler is is outlined, this intrinsic will be replaced
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by instructions that retrieve the exception object pointer from the frame
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allocation block.
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.. _llvm.eh.endcatch:
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``llvm.eh.endcatch``
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----------------------
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.. code-block:: llvm
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void @llvm.eh.endcatch()
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This intrinsic marks the end of catch handling code within the current block,
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which will be a successor of a block which called ``llvm.eh.begincatch''.
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The exact behavior of this function depends on the compilation target and the
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personality function associated with the corresponding ``landingpad``
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instruction.
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There may be more than one call to ``llvm.eh.endcatch`` for any given call to
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``llvm.eh.begincatch`` with each ``llvm.eh.endcatch`` call corresponding to the
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end of a different control path. All control paths following a call to
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``llvm.eh.begincatch`` must reach a call to ``llvm.eh.endcatch``.
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Uses of this intrinsic are generated by the C++ front-end. Many targets will
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use implementation-specific functions (such as ``__cxa_begin_catch``) instead
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of this intrinsic. The intrinsic is provided for targets that require a more
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abstract interface.
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When used in the native Windows C++ exception handling implementation, this
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intrinsic serves as a placeholder to delimit code before a catch handler is
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outlined. After the handler is outlined, this intrinsic is simply removed.
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.. _llvm.eh.exceptionpointer:
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``llvm.eh.exceptionpointer``
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----------------------------
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.. code-block:: llvm
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i8 addrspace(N)* @llvm.eh.padparam.pNi8(token %catchpad)
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This intrinsic retrieves a pointer to the exception caught by the given
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``catchpad``.
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SJLJ Intrinsics
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---------------
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The ``llvm.eh.sjlj`` intrinsics are used internally within LLVM's
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backend. Uses of them are generated by the backend's
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``SjLjEHPrepare`` pass.
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.. _llvm.eh.sjlj.setjmp:
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``llvm.eh.sjlj.setjmp``
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~~~~~~~~~~~~~~~~~~~~~~~
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.. code-block:: llvm
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i32 @llvm.eh.sjlj.setjmp(i8* %setjmp_buf)
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For SJLJ based exception handling, this intrinsic forces register saving for the
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current function and stores the address of the following instruction for use as
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a destination address by `llvm.eh.sjlj.longjmp`_. The buffer format and the
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overall functioning of this intrinsic is compatible with the GCC
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``__builtin_setjmp`` implementation allowing code built with the clang and GCC
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to interoperate.
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The single parameter is a pointer to a five word buffer in which the calling
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context is saved. The front end places the frame pointer in the first word, and
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the target implementation of this intrinsic should place the destination address
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for a `llvm.eh.sjlj.longjmp`_ in the second word. The following three words are
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available for use in a target-specific manner.
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.. _llvm.eh.sjlj.longjmp:
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``llvm.eh.sjlj.longjmp``
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~~~~~~~~~~~~~~~~~~~~~~~~
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.. code-block:: llvm
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void @llvm.eh.sjlj.longjmp(i8* %setjmp_buf)
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For SJLJ based exception handling, the ``llvm.eh.sjlj.longjmp`` intrinsic is
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used to implement ``__builtin_longjmp()``. The single parameter is a pointer to
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a buffer populated by `llvm.eh.sjlj.setjmp`_. The frame pointer and stack
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pointer are restored from the buffer, then control is transferred to the
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destination address.
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``llvm.eh.sjlj.lsda``
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~~~~~~~~~~~~~~~~~~~~~
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.. code-block:: llvm
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i8* @llvm.eh.sjlj.lsda()
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For SJLJ based exception handling, the ``llvm.eh.sjlj.lsda`` intrinsic returns
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the address of the Language Specific Data Area (LSDA) for the current
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function. The SJLJ front-end code stores this address in the exception handling
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function context for use by the runtime.
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``llvm.eh.sjlj.callsite``
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~~~~~~~~~~~~~~~~~~~~~~~~~
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.. code-block:: llvm
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void @llvm.eh.sjlj.callsite(i32 %call_site_num)
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For SJLJ based exception handling, the ``llvm.eh.sjlj.callsite`` intrinsic
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identifies the callsite value associated with the following ``invoke``
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instruction. This is used to ensure that landing pad entries in the LSDA are
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generated in matching order.
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Asm Table Formats
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=================
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There are two tables that are used by the exception handling runtime to
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determine which actions should be taken when an exception is thrown.
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Exception Handling Frame
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------------------------
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An exception handling frame ``eh_frame`` is very similar to the unwind frame
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used by DWARF debug info. The frame contains all the information necessary to
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tear down the current frame and restore the state of the prior frame. There is
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an exception handling frame for each function in a compile unit, plus a common
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exception handling frame that defines information common to all functions in the
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unit.
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The format of this call frame information (CFI) is often platform-dependent,
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however. ARM, for example, defines their own format. Apple has their own compact
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unwind info format. On Windows, another format is used for all architectures
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since 32-bit x86. LLVM will emit whatever information is required by the
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target.
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Exception Tables
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----------------
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An exception table contains information about what actions to take when an
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exception is thrown in a particular part of a function's code. This is typically
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referred to as the language-specific data area (LSDA). The format of the LSDA
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table is specific to the personality function, but the majority of personalities
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out there use a variation of the tables consumed by ``__gxx_personality_v0``.
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There is one exception table per function, except leaf functions and functions
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that have calls only to non-throwing functions. They do not need an exception
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table.
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.. _wineh:
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Exception Handling using the Windows Runtime
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=================================================
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(Note: Windows C++ exception handling support is a work in progress and is not
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yet fully implemented. The text below describes how it will work when
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completed.)
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Background on Windows exceptions
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---------------------------------
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Interacting with exceptions on Windows is significantly more complicated than on
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Itanium C++ ABI platforms. The fundamental difference between the two models is
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that Itanium EH is designed around the idea of "successive unwinding," while
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Windows EH is not.
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Under Itanium, throwing an exception typically involes allocating thread local
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memory to hold the exception, and calling into the EH runtime. The runtime
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identifies frames with appropriate exception handling actions, and successively
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resets the register context of the current thread to the most recently active
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frame with actions to run. In LLVM, execution resumes at a ``landingpad``
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instruction, which produces register values provided by the runtime. If a
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function is only cleaning up allocated resources, the function is responsible
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for calling ``_Unwind_Resume`` to transition to the next most recently active
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frame after it is finished cleaning up. Eventually, the frame responsible for
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handling the exception calls ``__cxa_end_catch`` to destroy the exception,
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release its memory, and resume normal control flow.
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The Windows EH model does not use these successive register context resets.
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Instead, the active exception is typically described by a frame on the stack.
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In the case of C++ exceptions, the exception object is allocated in stack memory
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and its address is passed to ``__CxxThrowException``. General purpose structured
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exceptions (SEH) are more analogous to Linux signals, and they are dispatched by
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userspace DLLs provided with Windows. Each frame on the stack has an assigned EH
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personality routine, which decides what actions to take to handle the exception.
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There are a few major personalities for C and C++ code: the C++ personality
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(``__CxxFrameHandler3``) and the SEH personalities (``_except_handler3``,
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``_except_handler4``, and ``__C_specific_handler``). All of them implement
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cleanups by calling back into a "funclet" contained in the parent function.
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Funclets, in this context, are regions of the parent function that can be called
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as though they were a function pointer with a very special calling convention.
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The frame pointer of the parent frame is passed into the funclet either using
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the standard EBP register or as the first parameter register, depending on the
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architecture. The funclet implements the EH action by accessing local variables
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in memory through the frame pointer, and returning some appropriate value,
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continuing the EH process. No variables live in to or out of the funclet can be
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allocated in registers.
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The C++ personality also uses funclets to contain the code for catch blocks
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(i.e. all user code between the braces in ``catch (Type obj) { ... }``). The
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runtime must use funclets for catch bodies because the C++ exception object is
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allocated in a child stack frame of the function handling the exception. If the
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runtime rewound the stack back to frame of the catch, the memory holding the
|
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exception would be overwritten quickly by subsequent function calls. The use of
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funclets also allows ``__CxxFrameHandler3`` to implement rethrow without
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resorting to TLS. Instead, the runtime throws a special exception, and then uses
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SEH (``__try / __except``) to resume execution with new information in the child
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frame.
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In other words, the successive unwinding approach is incompatible with Visual
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C++ exceptions and general purpose Windows exception handling. Because the C++
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exception object lives in stack memory, LLVM cannot provide a custom personality
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function that uses landingpads. Similarly, SEH does not provide any mechanism
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to rethrow an exception or continue unwinding. Therefore, LLVM must use the IR
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constructs described later in this document to implement compatible exception
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handling.
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SEH filter expressions
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-----------------------
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The SEH personality functions also use funclets to implement filter expressions,
|
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which allow executing arbitrary user code to decide which exceptions to catch.
|
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Filter expressions should not be confused with the ``filter`` clause of the LLVM
|
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``landingpad`` instruction. Typically filter expressions are used to determine
|
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if the exception came from a particular DLL or code region, or if code faulted
|
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while accessing a particular memory address range. LLVM does not currently have
|
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IR to represent filter expressions because it is difficult to represent their
|
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control dependencies. Filter expressions run during the first phase of EH,
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before cleanups run, making it very difficult to build a faithful control flow
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graph. For now, the new EH instructions cannot represent SEH filter
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expressions, and frontends must outline them ahead of time. Local variables of
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the parent function can be escaped and accessed using the ``llvm.localescape``
|
|
and ``llvm.localrecover`` intrinsics.
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New exception handling instructions
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------------------------------------
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The primary design goal of the new EH instructions is to support funclet
|
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generation while preserving information about the CFG so that SSA formation
|
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still works. As a secondary goal, they are designed to be generic across MSVC
|
|
and Itanium C++ exceptions. They make very few assumptions about the data
|
|
required by the personality, so long as it uses the familiar core EH actions:
|
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catch, cleanup, and terminate. However, the new instructions are hard to modify
|
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without knowing details of the EH personality. While they can be used to
|
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represent Itanium EH, the landingpad model is strictly better for optimization
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purposes.
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The following new instructions are considered "exception handling pads", in that
|
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they must be the first non-phi instruction of a basic block that may be the
|
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unwind destination of an invoke: ``catchpad``, ``cleanuppad``, and
|
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``terminatepad``. As with landingpads, when entering a try scope, if the
|
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frontend encounters a call site that may throw an exception, it should emit an
|
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invoke that unwinds to a ``catchpad`` block. Similarly, inside the scope of a
|
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C++ object with a destructor, invokes should unwind to a ``cleanuppad``. The
|
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``terminatepad`` instruction exists to represent ``noexcept`` and throw
|
|
specifications with one combined instruction. All potentially throwing calls in
|
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a ``noexcept`` function should transitively unwind to a terminateblock. Throw
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specifications are not implemented by MSVC, and are not yet supported.
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New instructions are also used to mark the points where control is transferred
|
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out of a catch/cleanup handler (which will correspond to exits from the
|
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generated funclet). A catch handler which reaches its end by normal execution
|
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executes a ``catchret`` instruction, which is a terminator indicating where in
|
|
the function control is returned to. A cleanup handler which reaches its end
|
|
by normal execution executes a ``cleanupret`` instruction, which is a terminator
|
|
indicating where the active exception will unwind to next. A catch or cleanup
|
|
handler which is exited by another exception being raised during its execution will
|
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unwind through a ``catchendpad`` or ``cleanuupendpad`` (respectively). The
|
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``catchendpad`` and ``cleanupendpad`` instructions are considered "exception
|
|
handling pads" in the same sense that ``catchpad``, ``cleanuppad``, and
|
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``terminatepad`` are.
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|
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Each of these new EH pad instructions has a way to identify which
|
|
action should be considered after this action. The ``catchpad`` and
|
|
``terminatepad`` instructions are terminators, and have a label operand considered
|
|
to be an unwind destination analogous to the unwind destination of an invoke. The
|
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``cleanuppad`` instruction is different from the other two in that it is not a
|
|
terminator. The code inside a cleanuppad runs before transferring control to the
|
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next action, so the ``cleanupret`` and ``cleanupendpad`` instructions are the
|
|
instructions that hold a label operand and unwind to the next EH pad. All of
|
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these "unwind edges" may refer to a basic block that contains an EH pad instruction,
|
|
or they may simply unwind to the caller. Unwinding to the caller has roughly the
|
|
same semantics as the ``resume`` instruction in the ``landingpad`` model. When
|
|
inlining through an invoke, instructions that unwind to the caller are hooked
|
|
up to unwind to the unwind destination of the call site.
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|
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Putting things together, here is a hypothetical lowering of some C++ that uses
|
|
all of the new IR instructions:
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|
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.. code-block:: c
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|
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struct Cleanup {
|
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Cleanup();
|
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~Cleanup();
|
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int m;
|
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};
|
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void may_throw();
|
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int f() noexcept {
|
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try {
|
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Cleanup obj;
|
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may_throw();
|
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} catch (int e) {
|
|
may_throw();
|
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return e;
|
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}
|
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return 0;
|
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}
|
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|
|
.. code-block:: llvm
|
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|
|
define i32 @f() nounwind personality i32 (...)* @__CxxFrameHandler3 {
|
|
entry:
|
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%obj = alloca %struct.Cleanup, align 4
|
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%e = alloca i32, align 4
|
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%call = invoke %struct.Cleanup* @"\01??0Cleanup@@QEAA@XZ"(%struct.Cleanup* nonnull %obj)
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to label %invoke.cont unwind label %lpad.catch
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invoke.cont: ; preds = %entry
|
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invoke void @"\01?may_throw@@YAXXZ"()
|
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to label %invoke.cont.2 unwind label %lpad.cleanup
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|
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invoke.cont.2: ; preds = %invoke.cont
|
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call void @"\01??_DCleanup@@QEAA@XZ"(%struct.Cleanup* nonnull %obj) nounwind
|
|
br label %return
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|
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return: ; preds = %invoke.cont.2, %invoke.cont.3
|
|
%retval.0 = phi i32 [ 0, %invoke.cont.2 ], [ %9, %catch ]
|
|
ret i32 %retval.0
|
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|
|
; EH scope code, ordered innermost to outermost:
|
|
|
|
lpad.cleanup: ; preds = %invoke.cont
|
|
%cleanup = cleanuppad []
|
|
call void @"\01??_DCleanup@@QEAA@XZ"(%struct.Cleanup* nonnull %obj) nounwind
|
|
cleanupret %cleanup unwind label %lpad.catch
|
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|
|
lpad.catch: ; preds = %entry, %lpad.cleanup
|
|
%catch = catchpad [%rtti.TypeDescriptor2* @"\01??_R0H@8", i32 0, i32* %e]
|
|
to label %catch.body unwind label %catchend
|
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|
|
catch.body: ; preds = %lpad.catch
|
|
invoke void @"\01?may_throw@@YAXXZ"()
|
|
to label %invoke.cont.3 unwind label %catchend
|
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|
|
invoke.cont.3: ; preds = %catch.body
|
|
%9 = load i32, i32* %e, align 4
|
|
catchret %catch to label %return
|
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|
|
catchend: ; preds = %lpad.catch, %catch.body
|
|
catchendpad unwind label %lpad.terminate
|
|
|
|
lpad.terminate: ; preds = %catchend
|
|
terminatepad [void ()* @"\01?terminate@@YAXXZ"]
|
|
unwind to caller
|
|
}
|