71011a70a4
Running CSE on a whole design is neither necessary nor advisable. It forces all the dialects used to support CSE but at least one (which we use) has issues with it. So we add a PR which targets redundant operations in the `kanagawa` dialect which passes assume to be non-redundant. Also updates `kanagawatool` to add new passes which are now necessary. |
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| lib | ||
| llvm@945ce1aa3d | ||
| test | ||
| tools | ||
| unittests | ||
| utils | ||
| .clang-format | ||
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| README.md | ||
| SECURITY.md | ||
README.md
⚡️ "CIRCT" / Circuit IR Compilers and Tools
"CIRCT" stands for "Circuit Intermediate Representations (IR) Compilers and Tools". One might also interpret it as the recursively as "CIRCT IR Compiler and Tools". The T can be selectively expanded as Tool, Translator, Team, Technology, Target, Tree, Type, ... we're ok with the ambiguity.
The CIRCT community is an open and welcoming community. If you'd like to participate, you can do so in a number of different ways:
-
Join our Discourse Forum on the LLVM Discourse server. To get a "mailing list" like experience click the bell icon in the upper right and switch to "Watching". It is also helpful to go to your Discourse profile, then the "emails" tab, and check "Enable mailing list mode". You can also do chat with us on CIRCT channel of LLVM discord server.
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Join our weekly video chat. Please see the meeting notes document for more information.
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Contribute code. CIRCT follows all of the LLVM Policies: you can create pull requests for the CIRCT repository, and gain commit access using the standard LLVM policies.
Motivation
The EDA industry has well-known and widely used proprietary and open source tools. However, these tools are inconsistent, have usability concerns, and were not designed together into a common platform. Furthermore these tools are generally built with Verilog (also VHDL) as the IRs that they interchange. Verilog has well known design issues, and limitations, e.g. suffering from poor location tracking support.
The CIRCT project is an (experimental!) effort looking to apply MLIR and the LLVM development methodology to the domain of hardware design tools. Many of us dream of having reusable infrastructure that is modular, uses library-based design techniques, is more consistent, and builds on the best practices in compiler infrastructure and compiler design techniques.
By working together, we hope that we can build a new center of gravity to draw contributions from the small (but enthusiastic!) community of people who work on open hardware tooling. In turn we hope this will propel open tools forward, enables new higher-level abstractions for hardware design, and perhaps some pieces may even be adopted by proprietary tools in time.
For more information, please see our longer charter document.
Setting this up
These commands can be used to setup CIRCT project:
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Install Dependencies of LLVM/MLIR according to the instructions, including cmake and ninja.
-
Check out LLVM and CIRCT repos. CIRCT contains LLVM as a git submodule. The LLVM repo here includes staged changes to MLIR which may be necessary to support CIRCT. It also represents the version of LLVM that has been tested. MLIR is still changing relatively rapidly, so feel free to use the current version of LLVM, but APIs may have changed.
$ git clone git@github.com:llvm/circt.git
$ cd circt
$ git submodule init
$ git submodule update
Note: The repository is set up so that git submodule update performs a
shallow clone, meaning it downloads just enough of the LLVM repository to check
out the currently specified commit. If you wish to work with the full history of
the LLVM repository, you can manually "unshallow" the the submodule:
$ cd llvm
$ git fetch --unshallow
- Build and test LLVM/MLIR:
$ cd circt
$ mkdir llvm/build
$ cd llvm/build
$ cmake -G Ninja ../llvm \
-DLLVM_ENABLE_PROJECTS="mlir" \
-DLLVM_TARGETS_TO_BUILD="host" \
-DLLVM_ENABLE_ASSERTIONS=ON \
-DCMAKE_BUILD_TYPE=DEBUG \
-DCMAKE_EXPORT_COMPILE_COMMANDS=ON
$ ninja
$ ninja check-mlir
- Build and test CIRCT:
$ cd circt
$ mkdir build
$ cd build
$ cmake -G Ninja .. \
-DMLIR_DIR=$PWD/../llvm/build/lib/cmake/mlir \
-DLLVM_DIR=$PWD/../llvm/build/lib/cmake/llvm \
-DLLVM_ENABLE_ASSERTIONS=ON \
-DCMAKE_BUILD_TYPE=DEBUG \
-DCMAKE_EXPORT_COMPILE_COMMANDS=ON
$ ninja
$ ninja check-circt
$ ninja check-circt-integration # Run the integration tests.
The -DCMAKE_BUILD_TYPE=DEBUG flag enables debug information, which makes the
whole tree compile slower, but allows you to step through code into the LLVM
and MLIR frameworks. The -DCMAKE_EXPORT_COMPILE_COMMANDS=ON flag generates
a build/compile_commands.json file, which can be used by editors (or plugins)
for autocomplete and/or IDE-like features.
To get something that runs fast, use -DCMAKE_BUILD_TYPE=Release or
-DCMAKE_BUILD_TYPE=RelWithDebInfo if you want to go fast and optionally if
you want debug info to go with it. Release mode makes a very large difference
in performance.
Consult the Getting Started page for detailed information on configuring and compiling CIRCT.
Consult the Python Bindings page if you are mainly interested in using CIRCT from a Python prompt or script.