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ReStructuredText
126 lines
7.7 KiB
ReStructuredText
==============
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LTO Visibility
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==============
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*LTO visibility* is a property of an entity that specifies whether it can be
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referenced from outside the current LTO unit. A *linkage unit* is a set of
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translation units linked together into an executable or DSO, and a linkage
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unit's *LTO unit* is the subset of the linkage unit that is linked together
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using link-time optimization; in the case where LTO is not being used, the
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linkage unit's LTO unit is empty. Each linkage unit has only a single LTO unit.
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The LTO visibility of a class is used by the compiler to determine which
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classes the whole-program devirtualization (``-fwhole-program-vtables``) and
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control flow integrity (``-fsanitize=cfi-vcall`` and ``-fsanitize=cfi-mfcall``)
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features apply to. These features use whole-program information, so they
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require the entire class hierarchy to be visible in order to work correctly.
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If any translation unit in the program uses either of the whole-program
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devirtualization or control flow integrity features, it is effectively an ODR
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violation to define a class with hidden LTO visibility in multiple linkage
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units. A class with public LTO visibility may be defined in multiple linkage
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units, but the tradeoff is that the whole-program devirtualization and
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control flow integrity features can only be applied to classes with hidden LTO
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visibility. A class's LTO visibility is treated as an ODR-relevant property
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of its definition, so it must be consistent between translation units.
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In translation units built with LTO, LTO visibility is based on the
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class's symbol visibility as expressed at the source level (i.e. the
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``__attribute__((visibility("...")))`` attribute, or the ``-fvisibility=``
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flag) or, on the Windows platform, the dllimport and dllexport attributes. When
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targeting non-Windows platforms, classes with a visibility other than hidden
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visibility receive public LTO visibility. When targeting Windows, classes
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with dllimport or dllexport attributes receive public LTO visibility. All
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other classes receive hidden LTO visibility. Classes with internal linkage
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(e.g. classes declared in unnamed namespaces) also receive hidden LTO
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visibility.
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During the LTO link, all classes with public LTO visibility but not marked with
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``[[clang::lto_visibility_public]]`` (see below) will be refined to hidden LTO
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visibility when the ``--lto-whole-program-visibility`` lld linker option is
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applied (``-plugin-opt=whole-program-visibility`` for gold). This flag can be
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used to defer specifying whether classes have hidden LTO visibility until link
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time, to allow bitcode objects to be shared by different LTO links. Due to an
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implementation limitation, symbols associated with classes with hidden LTO
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visibility may still be exported from the binary when using this flag. It is
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unsafe to refer to these symbols, and their visibility may be relaxed to hidden
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in a future compiler release.
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A class defined in a translation unit built without LTO receives public
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LTO visibility regardless of its object file visibility, linkage or other
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attributes.
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This mechanism will produce the correct result in most cases, but there are
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two cases where it may wrongly infer hidden LTO visibility.
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1. As a corollary of the above rules, if a linkage unit is produced from a
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combination of LTO object files and non-LTO object files, any hidden
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visibility class defined in both a translation unit built with LTO and
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a translation unit built without LTO must be defined with public LTO
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visibility in order to avoid an ODR violation.
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2. Some ABIs provide the ability to define an abstract base class without
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visibility attributes in multiple linkage units and have virtual calls
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to derived classes in other linkage units work correctly. One example of
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this is COM on Windows platforms. If the ABI allows this, any base class
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used in this way must be defined with public LTO visibility.
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Classes that fall into either of these categories can be marked up with the
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``[[clang::lto_visibility_public]]`` attribute. To specifically handle the
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COM case, classes with the ``__declspec(uuid())`` attribute receive public
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LTO visibility. On Windows platforms, clang-cl's ``/MT`` and ``/MTd``
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flags statically link the program against a prebuilt standard library;
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these flags imply public LTO visibility for every class declared in the
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``std`` and ``stdext`` namespaces.
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Example
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=======
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The following example shows how LTO visibility works in practice in several
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cases involving two linkage units, ``main`` and ``dso.so``.
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.. code-block:: none
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+-----------------------------------------------------------+ +----------------------------------------------------+
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| main (clang++ -fvisibility=hidden): | | dso.so (clang++ -fvisibility=hidden): |
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| | | |
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| +-----------------------------------------------------+ | | struct __attribute__((visibility("default"))) C { |
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| | LTO unit (clang++ -fvisibility=hidden -flto): | | | virtual void f(); |
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| | | | | } |
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| | struct A { ... }; | | | void C::f() {} |
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| | struct [[clang::lto_visibility_public]] B { ... }; | | | struct D { |
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| | struct __attribute__((visibility("default"))) C { | | | virtual void g() = 0; |
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| | virtual void f(); | | | }; |
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| | }; | | | struct E : D { |
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| | struct [[clang::lto_visibility_public]] D { | | | virtual void g() { ... } |
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| | virtual void g() = 0; | | | }; |
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| | }; | | | __attribute__((visibility("default"))) D *mkE() { |
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| | | | | return new E; |
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| +-----------------------------------------------------+ | | } |
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| | | |
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| struct B { ... }; | +----------------------------------------------------+
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+-----------------------------------------------------------+
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We will now describe the LTO visibility of each of the classes defined in
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these linkage units.
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Class ``A`` is not defined outside of ``main``'s LTO unit, so it can have
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hidden LTO visibility. This is inferred from the object file visibility
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specified on the command line.
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Class ``B`` is defined in ``main``, both inside and outside its LTO unit. The
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definition outside the LTO unit has public LTO visibility, so the definition
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inside the LTO unit must also have public LTO visibility in order to avoid
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an ODR violation.
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Class ``C`` is defined in both ``main`` and ``dso.so`` and therefore must
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have public LTO visibility. This is correctly inferred from the ``visibility``
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attribute.
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Class ``D`` is an abstract base class with a derived class ``E`` defined
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in ``dso.so``. This is an example of the COM scenario; the definition of
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``D`` in ``main``'s LTO unit must have public LTO visibility in order to be
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compatible with the definition of ``D`` in ``dso.so``, which is observable
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by calling the function ``mkE``.
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