Remill is a static binary translator that translates machine code instructions into LLVM bitcode. It translates AArch64 (64-bit ARMv8), SPARC32 (SPARCv8), SPARC64 (SPARCv9), x86 and amd64 machine code (including AVX and AVX512) into LLVM bitcode. AArch32 (32-bit ARMv8 / ARMv7) support is underway.
Remill focuses on accurately lifting instructions. It is meant to be used as a library for other tools, e.g. McSema.
unreachable function only support on arm32.
To understand how Remill works you can take a look at the following resources:
- Step-by-step guide on how Remill lifts an instruction
- How to implement the semantics of an instruction
- The design and architecture of Remill
If you would like to contribute you can check out: How to contribute
If you are experiencing undocumented problems with Remill then ask for help in the #binary-lifting
channel of the Empire Hacking Slack.
Remill is supported on Linux platforms and has been tested on Ubuntu 22.04. Remill also works on macOS, and has experimental support for Windows.
Remill's Linux version can also be built via Docker for quicker testing.
Most of Remill's dependencies can be provided by the cxx-common repository. Trail of Bits hosts downloadable, pre-built versions of cxx-common, which makes it substantially easier to get up and running with Remill. Nonetheless, the following table represents most of Remill's dependencies.
Name | Version |
---|---|
Git | Latest |
CMake | 3.14+ |
Google Flags | Latest |
Google Log | Latest |
Google Test | Latest |
LLVM | 15+ |
Clang | 15 |
Intel XED | Latest |
Python | 2.7 |
Unzip | Latest |
ccache | Latest |
Remill now comes with a Dockerfile for easier testing. This Dockerfile references the cxx-common container to have all pre-requisite libraries available.
The Dockerfile allows for quick builds of multiple supported LLVM, and Ubuntu configurations.
Important
Not all LLVM and Ubuntu configurations are supported---Please refer to the CI results to get an idea about configurations that are tested and supported. The Docker image should build on both x86_64 and ARM64, but we only test x86_64 in CI. ARM64 should build, but if it doesn't, please open an issue.
Quickstart (builds Remill against LLVM 17 on Ubuntu 22.04).
Clone Remill:
git clone https://github.com/lifting-bits/remill.git
cd remill
Build Remill Docker container:
docker build . -t remill \
-f Dockerfile \
--build-arg UBUNTU_VERSION=22.04 \
--build-arg LLVM_VERSION=17
Ensure remill works:
Decode some AMD64 instructions to LLVM:
docker run --rm -it remill \
--arch amd64 --ir_out /dev/stdout --bytes c704ba01000000
Decode some AArch64 instructions to LLVM:
docker run --rm -it remill \
--arch aarch64 --address 0x400544 --ir_out /dev/stdout \
--bytes FD7BBFA90000009000601891FD030091B7FFFF97E0031F2AFD7BC1A8C0035FD6
First, update aptitude and get install the baseline dependencies.
sudo dpkg --add-architecture i386
sudo apt-get update
sudo apt-get upgrade
sudo apt-get install \
git \
python3 \
wget \
curl \
build-essential \
lsb-release \
ccache \
libc6-dev:i386 \
'libstdc++-*-dev:i386' \
g++-multilib
Next, clone the repository. This will clone the code into the remill
directory.
git clone https://github.com/lifting-bits/remill.git
Next, we build Remill. This script will create another directory, remill-build
,
in the current working directory. All remaining dependencies needed
by Remill will be built in the remill-build
directory.
./remill/scripts/build.sh
Next, we can install Remill. Remill itself is a library, and so there is no real way to try it. However, you can head on over to the McSema repository, which uses Remill for lifting instructions.
cd ./remill-build
sudo make install
We can also build and run Remill's test suite.
cd ./remill-build
make test_dependencies
make test
Sometimes, you want to build everything from source, including the cxx-common libraries remill depends on. To build against a custom cxx-common location, you can use the following cmake
invocation:
mkdir build
cd build
cmake \
-DCMAKE_INSTALL_PREFIX="<path where remill will install>" \
-DCMAKE_TOOLCHAIN_FILE="<path to cxx-common directory>/vcpkg/scripts/buildsystems/vcpkg.cmake" \
-G Ninja \
..
cmake --build .
cmake --build . --target install
The output may produce some CMake warnings about policy CMP0003. These warnings are safe to ignore.
If you see errors similar to the following:
fatal error: 'bits/c++config.h' file not found
Then you need to install 32-bit libstdc++ headers and libraries. On a Debian/Ubuntu based distribution, You would want to do something like this:
sudo dpkg --add-architecture i386
sudo apt-get update
sudo apt-get install libc6-dev:i386 libstdc++-10-dev:i386 g++-multilib
This error happens because the SPARC32 runtime semantics (the bitcode library which lives in <install directory>/share/remill/<version>/semantics/sparc32.bc
) are built as 32-bit code, but 32-bit development libraries are not installed by default.
A similar situation occurs when building remill on arm64 Linux. In that case, you want to follow a similar workflow, except the architecture used in dpkg
and apt-get
commands would be armhf
instead of i386
.
Another alternative is to disable SPARC32 runtime semantics. To do that, use the -DREMILL_BUILD_SPARC32_RUNTIME=False
option when invoking cmake
.