/clangmetatool

A framework for reusing code in Clang tools

Primary LanguageC++Apache License 2.0Apache-2.0

clang-metatool - A framework for reusing code in clang tools

Build Status

About clangmetatool

When we first started writing clang tools, we realized that there is a lot of life cycle management that we had to repeat. In some cases, people advocate the usage of global variables to manage the life-cycle of that data, but that makes code reuse across tools even harder.

Additionally, we also learned that when writing a tool, it will be beneficial if the code is split in two phases. First a data collection phase, and later a post-processing phase that actually performed the bulk of the logic of the tool.

Essentially you will only need to write a class like:

class MyTool {
private:
  SomeDataCollector collector1;
  SomeOtherDataCollector collector2;
public:
  MyTool(clang::CompilerInstance* ci, clang::ast_matchers::MatchFinder *f)
   :collector1(ci, f), collector2(ci, f) {
   // the individual collectors will register their callbacks in their
   // constructor, the tool doesn't really need to do anything else here.
  }
  void postProcessing
  (std::map<std::string, clang::tooling::Replacements> &replacementsMap) {
   // use data from collector1 and collector2
   // generate warnings and notices
   // add replacements to replacementsMap
  }
};

And then you can use the clangmetatool::MetaToolFactory combined with the clangmetatool::MetaTool in your tool's main function:

int main(int argc, const char* argv[]) {
  llvm::cl::OptionCategory MyToolCategory("my-tool options");
  llvm::cl::extrahelp CommonHelp
    (clang::tooling::CommonOptionsParser::HelpMessage);
  clang::tooling::CommonOptionsParser
    optionsParser(argc, argv, MyToolCategory);
  clang::tooling::RefactoringTool tool(optionsParser.getCompilations(),
                                       optionsParser.getSourcePathList());
  clangmetatool::MetaToolFactory< clangmetatool::MetaTool<MyTool> >
    raf(tool.getReplacements());
  int r = tool.runAndSave(&raf);
  return r;
}

One way in which our initial tools got hard to write and maintain was by trying to perform analysis or even replacements during the callbacks. It was not immediately obvious that this would lead to hard-to-maintain code. After we switched to the two-phase approach, we were able to reuse a lot more code across tools.

Fork me at github

Infrastructure

clangmetatool::MetaToolFactory

This provides the boilerplate for a refactoring tool action, since you need a factory that passes the replacementsMap in to the frontend action class.

clangmetatool::MetaTool

This provides the boilerplate of a FrontendAction class that will perform data gathering and then run a post-processing phase that may do replacements. This simplifies the writing of the code into a constructor that registers preprocessor callbacks or ast matchers and a postprocessing phase.

clangmetatool cmake module

When building a clang tool you are expected to ship the builtin headers from the compiler with the tool, otherwise the tool will fail to find headers like stdarg.h. Clang expects to find the builtin headers relative to the absolute path of where the tool is installed. This cmake module will provide a function called clangmetatool_install which will handle all of that for you, example at skeleton/CMakeLists.txt.

Reusable data types

This defines types that can be used as building blocks, those will be in the clangmetatool::types namespace.

Reusable data collection

Another part of this library consists of a number of "Data Collectors". Those will be in the clangmetatool::collectors namespace.

"Data Collector" is a "design pattern" for reusing code in clang tools. It works by having a class that takes the CompilerInstance object as well as the match finder to the constructor and registers all required callbacks in order to collect the data later.

The collector class will also have a "getData" method that will return the pointer to a struct with the data. The "getData" method should only be called in the 'post-processing' phase of the tool.

Constant Propagation

Another part of this consists of constant propagators to assist with analysis. Those will be in the clangmetatool::propagation namespace.

More specifically, the current implementation provides propagation for the follwing types so that variables may be queried for their true values anywhere within the control-flow, so long as the value is deterministic:

  • Constant C-style string propagator, which propagates constant strings through the control flow graph

  • Constant integer propagation which propagates integer values through the code considering references, pointers, const-ness of int & int-like types

This could be useful for various purposes but especially for identifing things like which database a function is actually calling out to, etc.

clangmetatool::propagation::ConstantCStringPropagator

This provides infrastructure (utilizing clangmetatool::propagation::ConstantPropagator and clangmetatool::propagation::PropagationVisitor) to propagate constant C-style string values over the program. Resulting in the true value of a variable wherever the value is deterministic and "" anywhere else.

clangmetatool::propagation::ConstantPropagator and clangmetatool::propagation::PropagationVisitor

These two classes provide the boilerplate to create infrastructure to propagate constants of arbitrary types through the control flow graph of the program in such a way that anywhere the constant value of a variable would be deterministic one may query its value at that point.

These classes are private to the library, but additional propagators could be easily made using these facilities.

Skeleton for a new project

After you "git init" into an empty directory, copy the contents of the skeleton directory. To build that project, do something like:

( mkdir -p build && cd build/ && \
  cmake \
  -DClang_DIR=/path/to/clang/ \
  -Dclangmetatool_DIR=/path/to/clang/ \
  -DCMAKE_BUILD_TYPE=Debug \
  -DCMAKE_EXPORT_COMPILE_COMMANDS=1 \
  .. )
make -C build

Building

You need a full llvm+clang installation directory. Unfortunately, the Debian and Ubuntu packages are broken, so you may need to work-around by creating some symlinks (see .travis.Dockerfile in this repo for an example).

mkdir build
cd build
cmake -DClang_DIR=/path/to/clang/cmake ..
make
make install

License and Copyright

// ----------------------------------------------------------------------------
// Copyright 2018 Bloomberg Finance L.P.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// ----------------------------- END-OF-FILE ----------------------------------