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As suggested in the review for r337007, this makes cfi-verify abort on unsupported targets instead of producing incorrect results. It also updates the design document to reflect this. Differential Revision: https://reviews.llvm.org/D49304 llvm-svn: 337181
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==============================================
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Control Flow Verification Tool Design Document
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==============================================
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.. contents::
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:local:
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Objective
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=========
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This document provides an overview of an external tool to verify the protection
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mechanisms implemented by Clang's *Control Flow Integrity* (CFI) schemes
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(``-fsanitize=cfi``). This tool, provided a binary or DSO, should infer whether
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indirect control flow operations are protected by CFI, and should output these
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results in a human-readable form.
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This tool should also be added as part of Clang's continuous integration testing
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framework, where modifications to the compiler ensure that CFI protection
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schemes are still present in the final binary.
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Location
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========
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This tool will be present as a part of the LLVM toolchain, and will reside in
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the "/llvm/tools/llvm-cfi-verify" directory, relative to the LLVM trunk. It will
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be tested in two methods:
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- Unit tests to validate code sections, present in
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"/llvm/unittests/tools/llvm-cfi-verify".
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- Integration tests, present in "/llvm/tools/clang/test/LLVMCFIVerify". These
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integration tests are part of clang as part of a continuous integration
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framework, ensuring updates to the compiler that reduce CFI coverage on
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indirect control flow instructions are identified.
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Background
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==========
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This tool will continuously validate that CFI directives are properly
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implemented around all indirect control flows by analysing the output machine
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code. The analysis of machine code is important as it ensures that any bugs
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present in linker or compiler do not subvert CFI protections in the final
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shipped binary.
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Unprotected indirect control flow instructions will be flagged for manual
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review. These unexpected control flows may simply have not been accounted for in
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the compiler implementation of CFI (e.g. indirect jumps to facilitate switch
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statements may not be fully protected).
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It may be possible in the future to extend this tool to flag unnecessary CFI
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directives (e.g. CFI directives around a static call to a non-polymorphic base
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type). This type of directive has no security implications, but may present
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performance impacts.
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Design Ideas
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============
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This tool will disassemble binaries and DSO's from their machine code format and
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analyse the disassembled machine code. The tool will inspect virtual calls and
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indirect function calls. This tool will also inspect indirect jumps, as inlined
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functions and jump tables should also be subject to CFI protections. Non-virtual
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calls (``-fsanitize=cfi-nvcall``) and cast checks (``-fsanitize=cfi-*cast*``)
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are not implemented due to a lack of information provided by the bytecode.
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The tool would operate by searching for indirect control flow instructions in
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the disassembly. A control flow graph would be generated from a small buffer of
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the instructions surrounding the 'target' control flow instruction. If the
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target instruction is branched-to, the fallthrough of the branch should be the
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CFI trap (on x86, this is a ``ud2`` instruction). If the target instruction is
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the fallthrough (i.e. immediately succeeds) of a conditional jump, the
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conditional jump target should be the CFI trap. If an indirect control flow
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instruction does not conform to one of these formats, the target will be noted
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as being CFI-unprotected.
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Note that in the second case outlined above (where the target instruction is the
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fallthrough of a conditional jump), if the target represents a vcall that takes
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arguments, these arguments may be pushed to the stack after the branch but
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before the target instruction. In these cases, a secondary 'spill graph' in
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constructed, to ensure the register argument used by the indirect jump/call is
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not spilled from the stack at any point in the interim period. If there are no
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spills that affect the target register, the target is marked as CFI-protected.
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Other Design Notes
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~~~~~~~~~~~~~~~~~~
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Only machine code sections that are marked as executable will be subject to this
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analysis. Non-executable sections do not require analysis as any execution
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present in these sections has already violated the control flow integrity.
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Suitable extensions may be made at a later date to include analysis for indirect
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control flow operations across DSO boundaries. Currently, these CFI features are
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only experimental with an unstable ABI, making them unsuitable for analysis.
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The tool currently only supports the x86, x86_64, and AArch64 architectures.
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