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276 lines
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ReStructuredText
======================
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Control Flow Integrity
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======================
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.. toctree::
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:hidden:
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ControlFlowIntegrityDesign
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.. contents::
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:local:
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Introduction
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============
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Clang includes an implementation of a number of control flow integrity (CFI)
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schemes, which are designed to abort the program upon detecting certain forms
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of undefined behavior that can potentially allow attackers to subvert the
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program's control flow. These schemes have been optimized for performance,
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allowing developers to enable them in release builds.
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To enable Clang's available CFI schemes, use the flag ``-fsanitize=cfi``.
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You can also enable a subset of available :ref:`schemes <cfi-schemes>`.
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As currently implemented, all schemes rely on link-time optimization (LTO);
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so it is required to specify ``-flto``, and the linker used must support LTO,
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for example via the `gold plugin`_.
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To allow the checks to be implemented efficiently, the program must be
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structured such that certain object files are compiled with CFI
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enabled, and are statically linked into the program. This may preclude
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the use of shared libraries in some cases. Experimental support for
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:ref:`cross-DSO control flow integrity <cfi-cross-dso>` exists that
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does not have these requirements. This cross-DSO support has unstable
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ABI at this time.
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.. _gold plugin: http://llvm.org/docs/GoldPlugin.html
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.. _cfi-schemes:
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Available schemes
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=================
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Available schemes are:
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- ``-fsanitize=cfi-cast-strict``: Enables :ref:`strict cast checks
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<cfi-strictness>`.
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- ``-fsanitize=cfi-derived-cast``: Base-to-derived cast to the wrong
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dynamic type.
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- ``-fsanitize=cfi-unrelated-cast``: Cast from ``void*`` or another
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unrelated type to the wrong dynamic type.
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- ``-fsanitize=cfi-nvcall``: Non-virtual call via an object whose vptr is of
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the wrong dynamic type.
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- ``-fsanitize=cfi-vcall``: Virtual call via an object whose vptr is of the
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wrong dynamic type.
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- ``-fsanitize=cfi-icall``: Indirect call of a function with wrong dynamic
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type.
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You can use ``-fsanitize=cfi`` to enable all the schemes and use
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``-fno-sanitize`` flag to narrow down the set of schemes as desired.
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For example, you can build your program with
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``-fsanitize=cfi -fno-sanitize=cfi-nvcall,cfi-icall``
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to use all schemes except for non-virtual member function call and indirect call
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checking.
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Remember that you have to provide ``-flto`` if at least one CFI scheme is
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enabled.
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Trapping and Diagnostics
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========================
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By default, CFI will abort the program immediately upon detecting a control
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flow integrity violation. You can use the :ref:`-fno-sanitize-trap=
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<controlling-code-generation>` flag to cause CFI to print a diagnostic
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similar to the one below before the program aborts.
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.. code-block:: console
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bad-cast.cpp:109:7: runtime error: control flow integrity check for type 'B' failed during base-to-derived cast (vtable address 0x000000425a50)
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0x000000425a50: note: vtable is of type 'A'
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00 00 00 00 f0 f1 41 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 20 5a 42 00
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^
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If diagnostics are enabled, you can also configure CFI to continue program
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execution instead of aborting by using the :ref:`-fsanitize-recover=
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<controlling-code-generation>` flag.
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Forward-Edge CFI for Virtual Calls
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==================================
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This scheme checks that virtual calls take place using a vptr of the correct
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dynamic type; that is, the dynamic type of the called object must be a
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derived class of the static type of the object used to make the call.
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This CFI scheme can be enabled on its own using ``-fsanitize=cfi-vcall``.
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For this scheme to work, all translation units containing the definition
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of a virtual member function (whether inline or not), other than members
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of :ref:`blacklisted <cfi-blacklist>` types, must be compiled with
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``-fsanitize=cfi-vcall`` enabled and be statically linked into the program.
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Performance
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-----------
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A performance overhead of less than 1% has been measured by running the
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Dromaeo benchmark suite against an instrumented version of the Chromium
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web browser. Another good performance benchmark for this mechanism is the
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virtual-call-heavy SPEC 2006 xalancbmk.
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Note that this scheme has not yet been optimized for binary size; an increase
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of up to 15% has been observed for Chromium.
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Bad Cast Checking
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=================
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This scheme checks that pointer casts are made to an object of the correct
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dynamic type; that is, the dynamic type of the object must be a derived class
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of the pointee type of the cast. The checks are currently only introduced
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where the class being casted to is a polymorphic class.
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Bad casts are not in themselves control flow integrity violations, but they
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can also create security vulnerabilities, and the implementation uses many
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of the same mechanisms.
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There are two types of bad cast that may be forbidden: bad casts
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from a base class to a derived class (which can be checked with
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``-fsanitize=cfi-derived-cast``), and bad casts from a pointer of
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type ``void*`` or another unrelated type (which can be checked with
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``-fsanitize=cfi-unrelated-cast``).
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The difference between these two types of casts is that the first is defined
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by the C++ standard to produce an undefined value, while the second is not
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in itself undefined behavior (it is well defined to cast the pointer back
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to its original type).
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If a program as a matter of policy forbids the second type of cast, that
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restriction can normally be enforced. However it may in some cases be necessary
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for a function to perform a forbidden cast to conform with an external API
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(e.g. the ``allocate`` member function of a standard library allocator). Such
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functions may be :ref:`blacklisted <cfi-blacklist>`.
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For this scheme to work, all translation units containing the definition
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of a virtual member function (whether inline or not), other than members
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of :ref:`blacklisted <cfi-blacklist>` types, must be compiled with
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``-fsanitize=cfi-derived-cast`` or ``-fsanitize=cfi-unrelated-cast`` enabled
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and be statically linked into the program.
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Non-Virtual Member Function Call Checking
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=========================================
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This scheme checks that non-virtual calls take place using an object of
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the correct dynamic type; that is, the dynamic type of the called object
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must be a derived class of the static type of the object used to make the
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call. The checks are currently only introduced where the object is of a
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polymorphic class type. This CFI scheme can be enabled on its own using
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``-fsanitize=cfi-nvcall``.
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For this scheme to work, all translation units containing the definition
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of a virtual member function (whether inline or not), other than members
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of :ref:`blacklisted <cfi-blacklist>` types, must be compiled with
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``-fsanitize=cfi-nvcall`` enabled and be statically linked into the program.
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.. _cfi-strictness:
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Strictness
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----------
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If a class has a single non-virtual base and does not introduce or override
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virtual member functions or fields other than an implicitly defined virtual
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destructor, it will have the same layout and virtual function semantics as
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its base. By default, casts to such classes are checked as if they were made
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to the least derived such class.
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Casting an instance of a base class to such a derived class is technically
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undefined behavior, but it is a relatively common hack for introducing
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member functions on class instances with specific properties that works under
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most compilers and should not have security implications, so we allow it by
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default. It can be disabled with ``-fsanitize=cfi-cast-strict``.
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Indirect Function Call Checking
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===============================
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This scheme checks that function calls take place using a function of the
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correct dynamic type; that is, the dynamic type of the function must match
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the static type used at the call. This CFI scheme can be enabled on its own
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using ``-fsanitize=cfi-icall``.
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For this scheme to work, each indirect function call in the program, other
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than calls in :ref:`blacklisted <cfi-blacklist>` functions, must call a
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function which was either compiled with ``-fsanitize=cfi-icall`` enabled,
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or whose address was taken by a function in a translation unit compiled with
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``-fsanitize=cfi-icall``.
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If a function in a translation unit compiled with ``-fsanitize=cfi-icall``
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takes the address of a function not compiled with ``-fsanitize=cfi-icall``,
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that address may differ from the address taken by a function in a translation
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unit not compiled with ``-fsanitize=cfi-icall``. This is technically a
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violation of the C and C++ standards, but it should not affect most programs.
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Each translation unit compiled with ``-fsanitize=cfi-icall`` must be
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statically linked into the program or shared library, and calls across
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shared library boundaries are handled as if the callee was not compiled with
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``-fsanitize=cfi-icall``.
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This scheme is currently only supported on the x86 and x86_64 architectures.
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``-fsanitize=cfi-icall`` and ``-fsanitize=function``
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----------------------------------------------------
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This tool is similar to ``-fsanitize=function`` in that both tools check
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the types of function calls. However, the two tools occupy different points
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on the design space; ``-fsanitize=function`` is a developer tool designed
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to find bugs in local development builds, whereas ``-fsanitize=cfi-icall``
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is a security hardening mechanism designed to be deployed in release builds.
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``-fsanitize=function`` has a higher space and time overhead due to a more
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complex type check at indirect call sites, as well as a need for run-time
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type information (RTTI), which may make it unsuitable for deployment. Because
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of the need for RTTI, ``-fsanitize=function`` can only be used with C++
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programs, whereas ``-fsanitize=cfi-icall`` can protect both C and C++ programs.
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On the other hand, ``-fsanitize=function`` conforms more closely with the C++
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standard and user expectations around interaction with shared libraries;
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the identity of function pointers is maintained, and calls across shared
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library boundaries are no different from calls within a single program or
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shared library.
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.. _cfi-blacklist:
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Blacklist
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=========
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A :doc:`SanitizerSpecialCaseList` can be used to relax CFI checks for certain
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source files, functions and types using the ``src``, ``fun`` and ``type``
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entity types.
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In addition, if a type has a ``uuid`` attribute and the blacklist contains
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the type entry ``attr:uuid``, CFI checks are suppressed for that type. This
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allows all COM types to be easily blacklisted, which is useful as COM types
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are typically defined outside of the linked program.
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.. code-block:: bash
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# Suppress checking for code in a file.
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src:bad_file.cpp
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src:bad_header.h
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# Ignore all functions with names containing MyFooBar.
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fun:*MyFooBar*
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# Ignore all types in the standard library.
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type:std::*
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# Ignore all types with a uuid attribute.
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type:attr:uuid
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.. _cfi-cross-dso:
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Shared library support
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======================
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Use **-f[no-]sanitize-cfi-cross-dso** to enable the cross-DSO control
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flow integrity mode, which allows all CFI schemes listed above to
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apply across DSO boundaries. As in the regular CFI, each DSO must be
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built with ``-flto``.
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Design
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======
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Please refer to the :doc:`design document<ControlFlowIntegrityDesign>`.
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Publications
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============
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`Control-Flow Integrity: Principles, Implementations, and Applications <http://research.microsoft.com/pubs/64250/ccs05.pdf>`_.
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Martin Abadi, Mihai Budiu, Úlfar Erlingsson, Jay Ligatti.
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`Enforcing Forward-Edge Control-Flow Integrity in GCC & LLVM <http://www.pcc.me.uk/~peter/acad/usenix14.pdf>`_.
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Caroline Tice, Tom Roeder, Peter Collingbourne, Stephen Checkoway,
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Úlfar Erlingsson, Luis Lozano, Geoff Pike.
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