2013-12-19 03:14:12 +01:00
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==========================================
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Design and Usage of the InAlloca Attribute
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==========================================
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Introduction
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============
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2014-01-16 23:59:24 +01:00
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The :ref:`inalloca <attr_inalloca>` attribute is designed to allow
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taking the address of an aggregate argument that is being passed by
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value through memory. Primarily, this feature is required for
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compatibility with the Microsoft C++ ABI. Under that ABI, class
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instances that are passed by value are constructed directly into
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argument stack memory. Prior to the addition of inalloca, calls in LLVM
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were indivisible instructions. There was no way to perform intermediate
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work, such as object construction, between the first stack adjustment
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and the final control transfer. With inalloca, all arguments passed in
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memory are modelled as a single alloca, which can be stored to prior to
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the call. Unfortunately, this complicated feature comes with a large
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set of restrictions designed to bound the lifetime of the argument
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memory around the call.
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2013-12-19 03:14:12 +01:00
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For now, it is recommended that frontends and optimizers avoid producing
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this construct, primarily because it forces the use of a base pointer.
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This feature may grow in the future to allow general mid-level
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optimization, but for now, it should be regarded as less efficient than
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passing by value with a copy.
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Intended Usage
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==============
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2014-01-16 23:59:24 +01:00
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The example below is the intended LLVM IR lowering for some C++ code
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2014-03-27 02:32:22 +01:00
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that passes two default-constructed ``Foo`` objects to ``g`` in the
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32-bit Microsoft C++ ABI.
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2014-01-16 23:59:24 +01:00
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.. code-block:: c++
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// Foo is non-trivial.
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2014-03-27 02:32:22 +01:00
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struct Foo { int a, b; Foo(); ~Foo(); Foo(const Foo &); };
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void g(Foo a, Foo b);
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void f() {
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g(Foo(), Foo());
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}
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2013-12-19 03:14:12 +01:00
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.. code-block:: llvm
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2014-01-16 23:59:24 +01:00
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%struct.Foo = type { i32, i32 }
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declare void @Foo_ctor(%struct.Foo* %this)
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declare void @Foo_dtor(%struct.Foo* %this)
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declare void @g(<{ %struct.Foo, %struct.Foo }>* inalloca %memargs)
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define void @f() {
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entry:
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%base = call i8* @llvm.stacksave()
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%memargs = alloca <{ %struct.Foo, %struct.Foo }>
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2014-03-27 02:38:48 +01:00
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%b = getelementptr <{ %struct.Foo, %struct.Foo }>* %memargs, i32 1
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call void @Foo_ctor(%struct.Foo* %b)
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; If a's ctor throws, we must destruct b.
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%a = getelementptr <{ %struct.Foo, %struct.Foo }>* %memargs, i32 0
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invoke void @Foo_ctor(%struct.Foo* %a)
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to label %invoke.cont unwind %invoke.unwind
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invoke.cont:
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call void @g(<{ %struct.Foo, %struct.Foo }>* inalloca %memargs)
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call void @llvm.stackrestore(i8* %base)
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...
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invoke.unwind:
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call void @Foo_dtor(%struct.Foo* %b)
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call void @llvm.stackrestore(i8* %base)
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...
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}
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2014-01-16 23:59:24 +01:00
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To avoid stack leaks, the frontend saves the current stack pointer with
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a call to :ref:`llvm.stacksave <int_stacksave>`. Then, it allocates the
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argument stack space with alloca and calls the default constructor. The
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default constructor could throw an exception, so the frontend has to
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create a landing pad. The frontend has to destroy the already
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constructed argument ``b`` before restoring the stack pointer. If the
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constructor does not unwind, ``g`` is called. In the Microsoft C++ ABI,
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``g`` will destroy its arguments, and then the stack is restored in
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``f``.
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2013-12-19 03:14:12 +01:00
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Design Considerations
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=====================
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Lifetime
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--------
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The biggest design consideration for this feature is object lifetime.
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We cannot model the arguments as static allocas in the entry block,
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2014-01-16 23:59:24 +01:00
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because all calls need to use the memory at the top of the stack to pass
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arguments. We cannot vend pointers to that memory at function entry
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because after code generation they will alias.
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The rule against allocas between argument allocations and the call site
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avoids this problem, but it creates a cleanup problem. Cleanup and
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lifetime is handled explicitly with stack save and restore calls. In
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the future, we may want to introduce a new construct such as ``freea``
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or ``afree`` to make it clear that this stack adjusting cleanup is less
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powerful than a full stack save and restore.
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2013-12-19 03:14:12 +01:00
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Nested Calls and Copy Elision
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-----------------------------
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2014-01-16 23:59:24 +01:00
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We also want to be able to support copy elision into these argument
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slots. This means we have to support multiple live argument
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allocations.
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Consider the evaluation of:
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.. code-block:: c++
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// Foo is non-trivial.
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struct Foo { int a; Foo(); Foo(const &Foo); ~Foo(); };
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Foo bar(Foo b);
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int main() {
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bar(bar(Foo()));
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}
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In this case, we want to be able to elide copies into ``bar``'s argument
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slots. That means we need to have more than one set of argument frames
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active at the same time. First, we need to allocate the frame for the
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outer call so we can pass it in as the hidden struct return pointer to
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the middle call. Then we do the same for the middle call, allocating a
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frame and passing its address to ``Foo``'s default constructor. By
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wrapping the evaluation of the inner ``bar`` with stack save and
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restore, we can have multiple overlapping active call frames.
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2013-12-19 03:14:12 +01:00
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Callee-cleanup Calling Conventions
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----------------------------------
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Another wrinkle is the existence of callee-cleanup conventions. On
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Windows, all methods and many other functions adjust the stack to clear
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the memory used to pass their arguments. In some sense, this means that
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the allocas are automatically cleared by the call. However, LLVM
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instead models this as a write of undef to all of the inalloca values
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passed to the call instead of a stack adjustment. Frontends should
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still restore the stack pointer to avoid a stack leak.
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Exceptions
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----------
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There is also the possibility of an exception. If argument evaluation
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or copy construction throws an exception, the landing pad must do
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cleanup, which includes adjusting the stack pointer to avoid a stack
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leak. This means the cleanup of the stack memory cannot be tied to the
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call itself. There needs to be a separate IR-level instruction that can
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perform independent cleanup of arguments.
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Efficiency
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----------
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Eventually, it should be possible to generate efficient code for this
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construct. In particular, using inalloca should not require a base
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pointer. If the backend can prove that all points in the CFG only have
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one possible stack level, then it can address the stack directly from
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the stack pointer. While this is not yet implemented, the plan is that
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the inalloca attribute should not change much, but the frontend IR
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generation recommendations may change.
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