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291 lines
11 KiB
ReStructuredText
=============
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Type Metadata
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=============
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Type metadata is a mechanism that allows IR modules to co-operatively build
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pointer sets corresponding to addresses within a given set of globals. LLVM's
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`control flow integrity`_ implementation uses this metadata to efficiently
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check (at each call site) that a given address corresponds to either a
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valid vtable or function pointer for a given class or function type, and its
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whole-program devirtualization pass uses the metadata to identify potential
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callees for a given virtual call.
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To use the mechanism, a client creates metadata nodes with two elements:
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1. a byte offset into the global (generally zero for functions)
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2. a metadata object representing an identifier for the type
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These metadata nodes are associated with globals by using global object
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metadata attachments with the ``!type`` metadata kind.
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Each type identifier must exclusively identify either global variables
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or functions.
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.. admonition:: Limitation
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The current implementation only supports attaching metadata to functions on
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the x86-32 and x86-64 architectures.
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An intrinsic, :ref:`llvm.type.test <type.test>`, is used to test whether a
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given pointer is associated with a type identifier.
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.. _control flow integrity: https://clang.llvm.org/docs/ControlFlowIntegrity.html
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Representing Type Information using Type Metadata
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=================================================
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This section describes how Clang represents C++ type information associated with
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virtual tables using type metadata.
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Consider the following inheritance hierarchy:
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.. code-block:: c++
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struct A {
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virtual void f();
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};
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struct B : A {
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virtual void f();
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virtual void g();
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};
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struct C {
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virtual void h();
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};
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struct D : A, C {
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virtual void f();
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virtual void h();
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};
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The virtual table objects for A, B, C and D look like this (under the Itanium ABI):
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.. csv-table:: Virtual Table Layout for A, B, C, D
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:header: Class, 0, 1, 2, 3, 4, 5, 6
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A, A::offset-to-top, &A::rtti, &A::f
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B, B::offset-to-top, &B::rtti, &B::f, &B::g
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C, C::offset-to-top, &C::rtti, &C::h
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D, D::offset-to-top, &D::rtti, &D::f, &D::h, D::offset-to-top, &D::rtti, thunk for &D::h
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When an object of type A is constructed, the address of ``&A::f`` in A's
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virtual table object is stored in the object's vtable pointer. In ABI parlance
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this address is known as an `address point`_. Similarly, when an object of type
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B is constructed, the address of ``&B::f`` is stored in the vtable pointer. In
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this way, the vtable in B's virtual table object is compatible with A's vtable.
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D is a little more complicated, due to the use of multiple inheritance. Its
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virtual table object contains two vtables, one compatible with A's vtable and
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the other compatible with C's vtable. Objects of type D contain two virtual
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pointers, one belonging to the A subobject and containing the address of
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the vtable compatible with A's vtable, and the other belonging to the C
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subobject and containing the address of the vtable compatible with C's vtable.
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The full set of compatibility information for the above class hierarchy is
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shown below. The following table shows the name of a class, the offset of an
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address point within that class's vtable and the name of one of the classes
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with which that address point is compatible.
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.. csv-table:: Type Offsets for A, B, C, D
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:header: VTable for, Offset, Compatible Class
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A, 16, A
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B, 16, A
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, , B
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C, 16, C
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D, 16, A
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, , D
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, 48, C
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The next step is to encode this compatibility information into the IR. The way
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this is done is to create type metadata named after each of the compatible
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classes, with which we associate each of the compatible address points in
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each vtable. For example, these type metadata entries encode the compatibility
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information for the above hierarchy:
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::
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@_ZTV1A = constant [...], !type !0
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@_ZTV1B = constant [...], !type !0, !type !1
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@_ZTV1C = constant [...], !type !2
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@_ZTV1D = constant [...], !type !0, !type !3, !type !4
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!0 = !{i64 16, !"_ZTS1A"}
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!1 = !{i64 16, !"_ZTS1B"}
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!2 = !{i64 16, !"_ZTS1C"}
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!3 = !{i64 16, !"_ZTS1D"}
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!4 = !{i64 48, !"_ZTS1C"}
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With this type metadata, we can now use the ``llvm.type.test`` intrinsic to
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test whether a given pointer is compatible with a type identifier. Working
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backwards, if ``llvm.type.test`` returns true for a particular pointer,
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we can also statically determine the identities of the virtual functions
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that a particular virtual call may call. For example, if a program assumes
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a pointer to be a member of ``!"_ZST1A"``, we know that the address can
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be only be one of ``_ZTV1A+16``, ``_ZTV1B+16`` or ``_ZTV1D+16`` (i.e. the
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address points of the vtables of A, B and D respectively). If we then load
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an address from that pointer, we know that the address can only be one of
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``&A::f``, ``&B::f`` or ``&D::f``.
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.. _address point: https://itanium-cxx-abi.github.io/cxx-abi/abi.html#vtable-general
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Testing Addresses For Type Membership
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=====================================
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If a program tests an address using ``llvm.type.test``, this will cause
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a link-time optimization pass, ``LowerTypeTests``, to replace calls to this
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intrinsic with efficient code to perform type member tests. At a high level,
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the pass will lay out referenced globals in a consecutive memory region in
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the object file, construct bit vectors that map onto that memory region,
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and generate code at each of the ``llvm.type.test`` call sites to test
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pointers against those bit vectors. Because of the layout manipulation, the
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globals' definitions must be available at LTO time. For more information,
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see the `control flow integrity design document`_.
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A type identifier that identifies functions is transformed into a jump table,
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which is a block of code consisting of one branch instruction for each
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of the functions associated with the type identifier that branches to the
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target function. The pass will redirect any taken function addresses to the
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corresponding jump table entry. In the object file's symbol table, the jump
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table entries take the identities of the original functions, so that addresses
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taken outside the module will pass any verification done inside the module.
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Jump tables may call external functions, so their definitions need not
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be available at LTO time. Note that if an externally defined function is
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associated with a type identifier, there is no guarantee that its identity
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within the module will be the same as its identity outside of the module,
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as the former will be the jump table entry if a jump table is necessary.
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The `GlobalLayoutBuilder`_ class is responsible for laying out the globals
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efficiently to minimize the sizes of the underlying bitsets.
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.. _control flow integrity design document: https://clang.llvm.org/docs/ControlFlowIntegrityDesign.html
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:Example:
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::
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target datalayout = "e-p:32:32"
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@a = internal global i32 0, !type !0
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@b = internal global i32 0, !type !0, !type !1
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@c = internal global i32 0, !type !1
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@d = internal global [2 x i32] [i32 0, i32 0], !type !2
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define void @e() !type !3 {
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ret void
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}
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define void @f() {
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ret void
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}
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declare void @g() !type !3
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!0 = !{i32 0, !"typeid1"}
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!1 = !{i32 0, !"typeid2"}
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!2 = !{i32 4, !"typeid2"}
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!3 = !{i32 0, !"typeid3"}
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declare i1 @llvm.type.test(i8* %ptr, metadata %typeid) nounwind readnone
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define i1 @foo(i32* %p) {
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%pi8 = bitcast i32* %p to i8*
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%x = call i1 @llvm.type.test(i8* %pi8, metadata !"typeid1")
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ret i1 %x
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}
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define i1 @bar(i32* %p) {
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%pi8 = bitcast i32* %p to i8*
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%x = call i1 @llvm.type.test(i8* %pi8, metadata !"typeid2")
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ret i1 %x
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}
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define i1 @baz(void ()* %p) {
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%pi8 = bitcast void ()* %p to i8*
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%x = call i1 @llvm.type.test(i8* %pi8, metadata !"typeid3")
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ret i1 %x
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}
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define void @main() {
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%a1 = call i1 @foo(i32* @a) ; returns 1
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%b1 = call i1 @foo(i32* @b) ; returns 1
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%c1 = call i1 @foo(i32* @c) ; returns 0
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%a2 = call i1 @bar(i32* @a) ; returns 0
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%b2 = call i1 @bar(i32* @b) ; returns 1
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%c2 = call i1 @bar(i32* @c) ; returns 1
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%d02 = call i1 @bar(i32* getelementptr ([2 x i32]* @d, i32 0, i32 0)) ; returns 0
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%d12 = call i1 @bar(i32* getelementptr ([2 x i32]* @d, i32 0, i32 1)) ; returns 1
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%e = call i1 @baz(void ()* @e) ; returns 1
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%f = call i1 @baz(void ()* @f) ; returns 0
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%g = call i1 @baz(void ()* @g) ; returns 1
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ret void
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}
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.. _GlobalLayoutBuilder: https://github.com/llvm/llvm-project/blob/master/llvm/include/llvm/Transforms/IPO/LowerTypeTests.h
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``!vcall_visibility`` Metadata
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==============================
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In order to allow removing unused function pointers from vtables, we need to
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know whether every virtual call which could use it is known to the compiler, or
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whether another translation unit could introduce more calls through the vtable.
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This is not the same as the linkage of the vtable, because call sites could be
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using a pointer of a more widely-visible base class. For example, consider this
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code:
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.. code-block:: c++
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__attribute__((visibility("default")))
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struct A {
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virtual void f();
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};
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__attribute__((visibility("hidden")))
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struct B : A {
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virtual void f();
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};
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With LTO, we know that all code which can see the declaration of ``B`` is
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visible to us. However, a pointer to a ``B`` could be cast to ``A*`` and passed
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to another linkage unit, which could then call ``f`` on it. This call would
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load from the vtable for ``B`` (using the object pointer), and then call
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``B::f``. This means we can't remove the function pointer from ``B``'s vtable,
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or the implementation of ``B::f``. However, if we can see all code which knows
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about any dynamic base class (which would be the case if ``B`` only inherited
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from classes with hidden visibility), then this optimisation would be valid.
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This concept is represented in IR by the ``!vcall_visibility`` metadata
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attached to vtable objects, with the following values:
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.. list-table::
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:header-rows: 1
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:widths: 10 90
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* - Value
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- Behavior
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* - 0 (or omitted)
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- **Public**
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Virtual function calls using this vtable could be made from external
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code.
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* - 1
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- **Linkage Unit**
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All virtual function calls which might use this vtable are in the
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current LTO unit, meaning they will be in the current module once
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LTO linking has been performed.
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* - 2
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- **Translation Unit**
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All virtual function calls which might use this vtable are in the
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current module.
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In addition, all function pointer loads from a vtable marked with the
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``!vcall_visibility`` metadata (with a non-zero value) must be done using the
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:ref:`llvm.type.checked.load <type.checked.load>` intrinsic, so that virtual
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calls sites can be correlated with the vtables which they might load from.
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Other parts of the vtable (RTTI, offset-to-top, ...) can still be accessed with
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normal loads.
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