2015-02-21 04:30:56 +08:00
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===========================================
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Control Flow Integrity Design Documentation
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===========================================
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This page documents the design of the :doc:`ControlFlowIntegrity` schemes
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supported by Clang.
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Forward-Edge CFI for Virtual Calls
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2015-02-25 11:35:03 +08:00
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==================================
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2015-02-21 04:30:56 +08:00
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This scheme works by allocating, for each static type used to make a virtual
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call, a region of read-only storage in the object file holding a bit vector
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that maps onto to the region of storage used for those virtual tables. Each
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set bit in the bit vector corresponds to the `address point`_ for a virtual
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table compatible with the static type for which the bit vector is being built.
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For example, consider the following three C++ classes:
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.. code-block:: c++
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struct A {
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virtual void f1();
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virtual void f2();
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virtual void f3();
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};
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struct B : A {
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virtual void f1();
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virtual void f2();
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virtual void f3();
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};
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struct C : A {
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virtual void f1();
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virtual void f2();
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virtual void f3();
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};
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The scheme will cause the virtual tables for A, B and C to be laid out
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consecutively:
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.. csv-table:: Virtual Table Layout for A, B, C
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:header: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14
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A::offset-to-top, &A::rtti, &A::f1, &A::f2, &A::f3, B::offset-to-top, &B::rtti, &B::f1, &B::f2, &B::f3, C::offset-to-top, &C::rtti, &C::f1, &C::f2, &C::f3
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The bit vector for static types A, B and C will look like this:
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.. csv-table:: Bit Vectors for A, B, C
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:header: Class, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14
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A, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0
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B, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0
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C, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0
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2015-03-12 08:30:41 +08:00
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Bit vectors are represented in the object file as byte arrays. By loading
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from indexed offsets into the byte array and applying a mask, a program can
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test bits from the bit set with a relatively short instruction sequence. Bit
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vectors may overlap so long as they use different bits. For the full details,
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see the `ByteArrayBuilder`_ class.
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In this case, assuming A is laid out at offset 0 in bit 0, B at offset 0 in
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bit 1 and C at offset 0 in bit 2, the byte array would look like this:
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.. code-block:: c++
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char bits[] = { 0, 0, 1, 0, 0, 0, 3, 0, 0, 0, 0, 5, 0, 0 };
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To emit a virtual call, the compiler will assemble code that checks that
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the object's virtual table pointer is in-bounds and aligned and that the
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relevant bit is set in the bit vector.
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2015-02-25 11:35:03 +08:00
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For example on x86 a typical virtual call may look like this:
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.. code-block:: none
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2015-03-12 08:30:41 +08:00
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ca7fbb: 48 8b 0f mov (%rdi),%rcx
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ca7fbe: 48 8d 15 c3 42 fb 07 lea 0x7fb42c3(%rip),%rdx
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ca7fc5: 48 89 c8 mov %rcx,%rax
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ca7fc8: 48 29 d0 sub %rdx,%rax
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ca7fcb: 48 c1 c0 3d rol $0x3d,%rax
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ca7fcf: 48 3d 7f 01 00 00 cmp $0x17f,%rax
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ca7fd5: 0f 87 36 05 00 00 ja ca8511
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ca7fdb: 48 8d 15 c0 0b f7 06 lea 0x6f70bc0(%rip),%rdx
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ca7fe2: f6 04 10 10 testb $0x10,(%rax,%rdx,1)
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ca7fe6: 0f 84 25 05 00 00 je ca8511
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ca7fec: ff 91 98 00 00 00 callq *0x98(%rcx)
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[...]
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ca8511: 0f 0b ud2
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The compiler relies on co-operation from the linker in order to assemble
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the bit vectors for the whole program. It currently does this using LLVM's
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`bit sets`_ mechanism together with link-time optimization.
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.. _address point: https://mentorembedded.github.io/cxx-abi/abi.html#vtable-general
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.. _bit sets: http://llvm.org/docs/BitSets.html
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.. _ByteArrayBuilder: http://llvm.org/docs/doxygen/html/structllvm_1_1ByteArrayBuilder.html
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Optimizations
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-------------
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The scheme as described above is the fully general variant of the scheme.
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Most of the time we are able to apply one or more of the following
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optimizations to improve binary size or performance.
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2015-02-26 08:18:04 +08:00
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In fact, if you try the above example with the current version of the
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compiler, you will probably find that it will not use the described virtual
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table layout or machine instructions. Some of the optimizations we are about
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to introduce cause the compiler to use a different layout or a different
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sequence of machine instructions.
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2015-02-25 11:35:03 +08:00
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Stripping Leading/Trailing Zeros in Bit Vectors
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If a bit vector contains leading or trailing zeros, we can strip them from
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the vector. The compiler will emit code to check if the pointer is in range
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of the region covered by ones, and perform the bit vector check using a
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truncated version of the bit vector. For example, the bit vectors for our
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example class hierarchy will be emitted like this:
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.. csv-table:: Bit Vectors for A, B, C
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:header: Class, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14
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A, , , 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, ,
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B, , , , , , , , 1, , , , , , ,
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C, , , , , , , , , , , , , 1, ,
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Short Inline Bit Vectors
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~~~~~~~~~~~~~~~~~~~~~~~~
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If the vector is sufficiently short, we can represent it as an inline constant
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on x86. This saves us a few instructions when reading the correct element
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of the bit vector.
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If the bit vector fits in 32 bits, the code looks like this:
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.. code-block:: none
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dc2: 48 8b 03 mov (%rbx),%rax
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dc5: 48 8d 15 14 1e 00 00 lea 0x1e14(%rip),%rdx
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dcc: 48 89 c1 mov %rax,%rcx
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dcf: 48 29 d1 sub %rdx,%rcx
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dd2: 48 c1 c1 3d rol $0x3d,%rcx
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dd6: 48 83 f9 03 cmp $0x3,%rcx
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dda: 77 2f ja e0b <main+0x9b>
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ddc: ba 09 00 00 00 mov $0x9,%edx
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de1: 0f a3 ca bt %ecx,%edx
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de4: 73 25 jae e0b <main+0x9b>
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de6: 48 89 df mov %rbx,%rdi
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de9: ff 10 callq *(%rax)
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[...]
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e0b: 0f 0b ud2
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Or if the bit vector fits in 64 bits:
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.. code-block:: none
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11a6: 48 8b 03 mov (%rbx),%rax
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11a9: 48 8d 15 d0 28 00 00 lea 0x28d0(%rip),%rdx
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11b0: 48 89 c1 mov %rax,%rcx
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11b3: 48 29 d1 sub %rdx,%rcx
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11b6: 48 c1 c1 3d rol $0x3d,%rcx
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11ba: 48 83 f9 2a cmp $0x2a,%rcx
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11be: 77 35 ja 11f5 <main+0xb5>
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11c0: 48 ba 09 00 00 00 00 movabs $0x40000000009,%rdx
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11c7: 04 00 00
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11ca: 48 0f a3 ca bt %rcx,%rdx
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11ce: 73 25 jae 11f5 <main+0xb5>
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11d0: 48 89 df mov %rbx,%rdi
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11d3: ff 10 callq *(%rax)
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[...]
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11f5: 0f 0b ud2
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2015-02-25 11:35:03 +08:00
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If the bit vector consists of a single bit, there is only one possible
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virtual table, and the check can consist of a single equality comparison:
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2015-02-25 11:35:03 +08:00
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.. code-block:: none
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9a2: 48 8b 03 mov (%rbx),%rax
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9a5: 48 8d 0d a4 13 00 00 lea 0x13a4(%rip),%rcx
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9ac: 48 39 c8 cmp %rcx,%rax
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9af: 75 25 jne 9d6 <main+0x86>
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9b1: 48 89 df mov %rbx,%rdi
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9b4: ff 10 callq *(%rax)
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[...]
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9d6: 0f 0b ud2
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Virtual Table Layout
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~~~~~~~~~~~~~~~~~~~~
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The compiler lays out classes of disjoint hierarchies in separate regions
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of the object file. At worst, bit vectors in disjoint hierarchies only
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need to cover their disjoint hierarchy. But the closer that classes in
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sub-hierarchies are laid out to each other, the smaller the bit vectors for
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those sub-hierarchies need to be (see "Stripping Leading/Trailing Zeros in Bit
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Vectors" above). The `GlobalLayoutBuilder`_ class is responsible for laying
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out the globals efficiently to minimize the sizes of the underlying bitsets.
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2015-02-26 08:18:04 +08:00
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.. _GlobalLayoutBuilder: http://llvm.org/viewvc/llvm-project/llvm/trunk/include/llvm/Transforms/IPO/LowerBitSets.h?view=markup
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Alignment
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~~~~~~~~~
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If all gaps between address points in a particular bit vector are multiples
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of powers of 2, the compiler can compress the bit vector by strengthening
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the alignment requirements of the virtual table pointer. For example, given
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this class hierarchy:
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.. code-block:: c++
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struct A {
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virtual void f1();
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virtual void f2();
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};
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struct B : A {
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virtual void f1();
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virtual void f2();
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virtual void f3();
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virtual void f4();
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virtual void f5();
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virtual void f6();
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};
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struct C : A {
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virtual void f1();
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virtual void f2();
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};
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The virtual tables will be laid out like this:
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.. csv-table:: Virtual Table Layout for A, B, C
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:header: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15
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A::offset-to-top, &A::rtti, &A::f1, &A::f2, B::offset-to-top, &B::rtti, &B::f1, &B::f2, &B::f3, &B::f4, &B::f5, &B::f6, C::offset-to-top, &C::rtti, &C::f1, &C::f2
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Notice that each address point for A is separated by 4 words. This lets us
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emit a compressed bit vector for A that looks like this:
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.. csv-table::
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:header: 2, 6, 10, 14
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1, 1, 0, 1
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At call sites, the compiler will strengthen the alignment requirements by
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using a different rotate count. For example, on a 64-bit machine where the
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address points are 4-word aligned (as in A from our example), the ``rol``
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instruction may look like this:
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.. code-block:: none
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dd2: 48 c1 c1 3b rol $0x3b,%rcx
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Padding to Powers of 2
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~~~~~~~~~~~~~~~~~~~~~~
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Of course, this alignment scheme works best if the address points are
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in fact aligned correctly. To make this more likely to happen, we insert
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padding between virtual tables that in many cases aligns address points to
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a power of 2. Specifically, our padding aligns virtual tables to the next
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highest power of 2 bytes; because address points for specific base classes
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normally appear at fixed offsets within the virtual table, this normally
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has the effect of aligning the address points as well.
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This scheme introduces tradeoffs between decreased space overhead for
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instructions and bit vectors and increased overhead in the form of padding. We
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therefore limit the amount of padding so that we align to no more than 128
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bytes. This number was found experimentally to provide a good tradeoff.
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Eliminating Bit Vector Checks for All-Ones Bit Vectors
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If the bit vector is all ones, the bit vector check is redundant; we simply
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need to check that the address is in range and well aligned. This is more
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likely to occur if the virtual tables are padded.
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