| =============================================================== |
| Tutorial for building tools using LibTooling and LibASTMatchers |
| =============================================================== |
| |
| This document is intended to show how to build a useful source-to-source |
| translation tool based on Clang's `LibTooling <LibTooling.html>`_. It is |
| explicitly aimed at people who are new to Clang, so all you should need |
| is a working knowledge of C++ and the command line. |
| |
| In order to work on the compiler, you need some basic knowledge of the |
| abstract syntax tree (AST). To this end, the reader is incouraged to |
| skim the :doc:`Introduction to the Clang |
| AST <IntroductionToTheClangAST>` |
| |
| Step 0: Obtaining Clang |
| ======================= |
| |
| As Clang is part of the LLVM project, you'll need to download LLVM's |
| source code first. Both Clang and LLVM are maintained as Subversion |
| repositories, but we'll be accessing them through the git mirror. For |
| further information, see the `getting started |
| guide <http://llvm.org/docs/GettingStarted.html>`_. |
| |
| :: |
| |
| mkdir ~/clang-llvm && cd ~/clang-llvm |
| git clone http://llvm.org/git/llvm.git |
| cd llvm/tools |
| git clone http://llvm.org/git/clang.git |
| |
| Next you need to obtain the CMake build system and Ninja build tool. You |
| may already have CMake installed, but current binary versions of CMake |
| aren't built with Ninja support. |
| |
| :: |
| |
| cd ~/clang-llvm |
| git clone https://github.com/martine/ninja.git |
| cd ninja |
| git checkout release |
| ./bootstrap.py |
| sudo cp ninja /usr/bin/ |
| |
| cd ~/clang-llvm |
| git clone git://cmake.org/stage/cmake.git |
| cd cmake |
| git checkout next |
| ./bootstrap |
| make |
| sudo make install |
| |
| Okay. Now we'll build Clang! |
| |
| :: |
| |
| cd ~/clang-llvm |
| mkdir build && cd build |
| cmake -G Ninja ../llvm -DLLVM_BUILD_TESTS=ON # Enable tests; default is off. |
| ninja |
| ninja check # Test LLVM only. |
| ninja clang-test # Test Clang only. |
| ninja install |
| |
| And we're live. |
| |
| All of the tests should pass, though there is a (very) small chance that |
| you can catch LLVM and Clang out of sync. Running ``'git svn rebase'`` |
| in both the llvm and clang directories should fix any problems. |
| |
| Finally, we want to set Clang as its own compiler. |
| |
| :: |
| |
| cd ~/clang-llvm/build |
| ccmake ../llvm |
| |
| The second command will bring up a GUI for configuring Clang. You need |
| to set the entry for ``CMAKE_CXX_COMPILER``. Press ``'t'`` to turn on |
| advanced mode. Scroll down to ``CMAKE_CXX_COMPILER``, and set it to |
| ``/usr/bin/clang++``, or wherever you installed it. Press ``'c'`` to |
| configure, then ``'g'`` to generate CMake's files. |
| |
| Finally, run ninja one last time, and you're done. |
| |
| Step 1: Create a ClangTool |
| ========================== |
| |
| Now that we have enough background knowledge, it's time to create the |
| simplest productive ClangTool in existence: a syntax checker. While this |
| already exists as ``clang-check``, it's important to understand what's |
| going on. |
| |
| First, we'll need to create a new directory for our tool and tell CMake |
| that it exists. As this is not going to be a core clang tool, it will |
| live in the ``tools/extra`` repository. |
| |
| :: |
| |
| cd ~/clang-llvm/llvm/tools/clang |
| mkdir tools/extra/loop-convert |
| echo 'add_subdirectory(loop-convert)' >> tools/extra/CMakeLists.txt |
| vim tools/extra/loop-convert/CMakeLists.txt |
| |
| CMakeLists.txt should have the following contents: |
| |
| :: |
| |
| set(LLVM_LINK_COMPONENTS support) |
| set(LLVM_USED_LIBS clangTooling clangBasic clangAST) |
| |
| add_clang_executable(loop-convert |
| LoopConvert.cpp |
| ) |
| target_link_libraries(loop-convert |
| clangTooling |
| clangBasic |
| clangASTMatchers |
| ) |
| |
| With that done, Ninja will be able to compile our tool. Let's give it |
| something to compile! Put the following into |
| ``tools/extra/loop-convert/LoopConvert.cpp``. A detailed explanation of |
| why the different parts are needed can be found in the `LibTooling |
| documentation <LibTooling.html>`_. |
| |
| :: |
| |
| // Declares clang::SyntaxOnlyAction. |
| #include "clang/Frontend/FrontendActions.h" |
| #include "clang/Tooling/CommonOptionsParser.h" |
| #include "clang/Tooling/Tooling.h" |
| // Declares llvm::cl::extrahelp. |
| #include "llvm/Support/CommandLine.h" |
| |
| using namespace clang::tooling; |
| using namespace llvm; |
| |
| // CommonOptionsParser declares HelpMessage with a description of the common |
| // command-line options related to the compilation database and input files. |
| // It's nice to have this help message in all tools. |
| static cl::extrahelp CommonHelp(CommonOptionsParser::HelpMessage); |
| |
| // A help message for this specific tool can be added afterwards. |
| static cl::extrahelp MoreHelp("\nMore help text..."); |
| |
| int main(int argc, const char **argv) { |
| CommonOptionsParser OptionsParser(argc, argv); |
| ClangTool Tool(OptionsParser.getCompilations(), |
| OptionsParser.getSourcePathList()); |
| return Tool.run(newFrontendActionFactory<clang::SyntaxOnlyAction>()); |
| } |
| |
| And that's it! You can compile our new tool by running ninja from the |
| ``build`` directory. |
| |
| :: |
| |
| cd ~/clang-llvm/build |
| ninja |
| |
| You should now be able to run the syntax checker, which is located in |
| ``~/clang-llvm/build/bin``, on any source file. Try it! |
| |
| :: |
| |
| cat "void main() {}" > test.cpp |
| bin/loop-convert test.cpp -- |
| |
| Note the two dashes after we specify the source file. The additional |
| options for the compiler are passed after the dashes rather than loading |
| them from a compilation database - there just aren't any options needed |
| right now. |
| |
| Intermezzo: Learn AST matcher basics |
| ==================================== |
| |
| Clang recently introduced the :doc:`ASTMatcher |
| library <LibASTMatchers>` to provide a simple, powerful, and |
| concise way to describe specific patterns in the AST. Implemented as a |
| DSL powered by macros and templates (see |
| `ASTMatchers.h <../doxygen/ASTMatchers_8h_source.html>`_ if you're |
| curious), matchers offer the feel of algebraic data types common to |
| functional programming languages. |
| |
| For example, suppose you wanted to examine only binary operators. There |
| is a matcher to do exactly that, conveniently named ``binaryOperator``. |
| I'll give you one guess what this matcher does: |
| |
| :: |
| |
| binaryOperator(hasOperatorName("+"), hasLHS(integerLiteral(equals(0)))) |
| |
| Shockingly, it will match against addition expressions whose left hand |
| side is exactly the literal 0. It will not match against other forms of |
| 0, such as ``'\0'`` or ``NULL``, but it will match against macros that |
| expand to 0. The matcher will also not match against calls to the |
| overloaded operator ``'+'``, as there is a separate ``operatorCallExpr`` |
| matcher to handle overloaded operators. |
| |
| There are AST matchers to match all the different nodes of the AST, |
| narrowing matchers to only match AST nodes fulfilling specific criteria, |
| and traversal matchers to get from one kind of AST node to another. For |
| a complete list of AST matchers, take a look at the `AST Matcher |
| References <LibASTMatchersReference.html>`_ |
| |
| All matcher that are nouns describe entities in the AST and can be |
| bound, so that they can be referred to whenever a match is found. To do |
| so, simply call the method ``bind`` on these matchers, e.g.: |
| |
| :: |
| |
| variable(hasType(isInteger())).bind("intvar") |
| |
| Step 2: Using AST matchers |
| ========================== |
| |
| Okay, on to using matchers for real. Let's start by defining a matcher |
| which will capture all ``for`` statements that define a new variable |
| initialized to zero. Let's start with matching all ``for`` loops: |
| |
| :: |
| |
| forStmt() |
| |
| Next, we want to specify that a single variable is declared in the first |
| portion of the loop, so we can extend the matcher to |
| |
| :: |
| |
| forStmt(hasLoopInit(declStmt(hasSingleDecl(varDecl())))) |
| |
| Finally, we can add the condition that the variable is initialized to |
| zero. |
| |
| :: |
| |
| forStmt(hasLoopInit(declStmt(hasSingleDecl(varDecl( |
| hasInitializer(integerLiteral(equals(0)))))))) |
| |
| It is fairly easy to read and understand the matcher definition ("match |
| loops whose init portion declares a single variable which is initialized |
| to the integer literal 0"), but deciding that every piece is necessary |
| is more difficult. Note that this matcher will not match loops whose |
| variables are initialized to ``'\0'``, ``0.0``, ``NULL``, or any form of |
| zero besides the integer 0. |
| |
| The last step is giving the matcher a name and binding the ``ForStmt`` |
| as we will want to do something with it: |
| |
| :: |
| |
| StatementMatcher LoopMatcher = |
| forStmt(hasLoopInit(declStmt(hasSingleDecl(varDecl( |
| hasInitializer(integerLiteral(equals(0)))))))).bind("forLoop"); |
| |
| Once you have defined your matchers, you will need to add a little more |
| scaffolding in order to run them. Matchers are paired with a |
| ``MatchCallback`` and registered with a ``MatchFinder`` object, then run |
| from a ``ClangTool``. More code! |
| |
| Add the following to ``LoopConvert.cpp``: |
| |
| :: |
| |
| StatementMatcher LoopMatcher = |
| forStmt(hasLoopInit(declStmt(hasSingleDecl(varDecl( |
| hasInitializer(integerLiteral(equals(0)))))))).bind("forLoop"); |
| |
| class LoopPrinter : public MatchFinder::MatchCallback { |
| public : |
| virtual void run(const MatchFinder::MatchResult &Result) { |
| if (const ForStmt *FS = Result.Nodes.getNodeAs<clang::ForStmt>("forLoop")) |
| FS->dump(); |
| }; |
| |
| And change ``main()`` to: |
| |
| :: |
| |
| int main(int argc, const char **argv) { |
| CommonOptionsParser OptionsParser(argc, argv); |
| ClangTool Tool(OptionsParser.getCompilations(), |
| OptionsParser.getSourcePathList()); |
| |
| LoopPrinter Printer; |
| MatchFinder Finder; |
| Finder.addMatcher(LoopMatcher, &Printer); |
| |
| return Tool.run(newFrontendActionFactory(&Finder)); |
| } |
| |
| Now, you should be able to recompile and run the code to discover for |
| loops. Create a new file with a few examples, and test out our new |
| handiwork: |
| |
| :: |
| |
| cd ~/clang-llvm/llvm/llvm_build/ |
| ninja loop-convert |
| vim ~/test-files/simple-loops.cc |
| bin/loop-convert ~/test-files/simple-loops.cc |
| |
| Step 3.5: More Complicated Matchers |
| =================================== |
| |
| Our simple matcher is capable of discovering for loops, but we would |
| still need to filter out many more ourselves. We can do a good portion |
| of the remaining work with some cleverly chosen matchers, but first we |
| need to decide exactly which properties we want to allow. |
| |
| How can we characterize for loops over arrays which would be eligible |
| for translation to range-based syntax? Range based loops over arrays of |
| size ``N`` that: |
| |
| - start at index ``0`` |
| - iterate consecutively |
| - end at index ``N-1`` |
| |
| We already check for (1), so all we need to add is a check to the loop's |
| condition to ensure that the loop's index variable is compared against |
| ``N`` and another check to ensure that the increment step just |
| increments this same variable. The matcher for (2) is straightforward: |
| require a pre- or post-increment of the same variable declared in the |
| init portion. |
| |
| Unfortunately, such a matcher is impossible to write. Matchers contain |
| no logic for comparing two arbitrary AST nodes and determining whether |
| or not they are equal, so the best we can do is matching more than we |
| would like to allow, and punting extra comparisons to the callback. |
| |
| In any case, we can start building this sub-matcher. We can require that |
| the increment step be a unary increment like this: |
| |
| :: |
| |
| hasIncrement(unaryOperator(hasOperatorName("++"))) |
| |
| Specifying what is incremented introduces another quirk of Clang's AST: |
| Usages of variables are represented as ``DeclRefExpr``'s ("declaration |
| reference expressions") because they are expressions which refer to |
| variable declarations. To find a ``unaryOperator`` that refers to a |
| specific declaration, we can simply add a second condition to it: |
| |
| :: |
| |
| hasIncrement(unaryOperator( |
| hasOperatorName("++"), |
| hasUnaryOperand(declRefExpr()))) |
| |
| Furthermore, we can restrict our matcher to only match if the |
| incremented variable is an integer: |
| |
| :: |
| |
| hasIncrement(unaryOperator( |
| hasOperatorName("++"), |
| hasUnaryOperand(declRefExpr(to(varDecl(hasType(isInteger()))))))) |
| |
| And the last step will be to attach an identifier to this variable, so |
| that we can retrieve it in the callback: |
| |
| :: |
| |
| hasIncrement(unaryOperator( |
| hasOperatorName("++"), |
| hasUnaryOperand(declRefExpr(to( |
| varDecl(hasType(isInteger())).bind("incrementVariable")))))) |
| |
| We can add this code to the definition of ``LoopMatcher`` and make sure |
| that our program, outfitted with the new matcher, only prints out loops |
| that declare a single variable initialized to zero and have an increment |
| step consisting of a unary increment of some variable. |
| |
| Now, we just need to add a matcher to check if the condition part of the |
| ``for`` loop compares a variable against the size of the array. There is |
| only one problem - we don't know which array we're iterating over |
| without looking at the body of the loop! We are again restricted to |
| approximating the result we want with matchers, filling in the details |
| in the callback. So we start with: |
| |
| :: |
| |
| hasCondition(binaryOperator(hasOperatorName("<")) |
| |
| It makes sense to ensure that the left-hand side is a reference to a |
| variable, and that the right-hand side has integer type. |
| |
| :: |
| |
| hasCondition(binaryOperator( |
| hasOperatorName("<"), |
| hasRHS(expr(hasType(isInteger()))), |
| hasLHS(declRefExpr(to(varDecl(hasType(isInteger()))))))) |
| |
| Why? Because it doesn't work. Of the three loops provided in |
| ``test-files/simple.cpp``, zero of them have a matching condition. A |
| quick look at the AST dump of the first for loop, produced by the |
| previous iteration of loop-convert, shows us the answer: |
| |
| :: |
| |
| (ForStmt 0x173b240 |
| (DeclStmt 0x173afc8 |
| 0x173af50 "int i = |
| (IntegerLiteral 0x173afa8 'int' 0)") |
| <<>> |
| (BinaryOperator 0x173b060 '_Bool' '<' |
| (ImplicitCastExpr 0x173b030 'int' |
| (DeclRefExpr 0x173afe0 'int' lvalue Var 0x173af50 'i' 'int')) |
| (ImplicitCastExpr 0x173b048 'int' |
| (DeclRefExpr 0x173b008 'const int' lvalue Var 0x170fa80 'N' 'const int'))) |
| (UnaryOperator 0x173b0b0 'int' lvalue prefix '++' |
| (DeclRefExpr 0x173b088 'int' lvalue Var 0x173af50 'i' 'int')) |
| (CompoundStatement … |
| |
| We already know that the declaration and increments both match, or this |
| loop wouldn't have been dumped. The culprit lies in the implicit cast |
| applied to the first operand (i.e. the LHS) of the less-than operator, |
| an L-value to R-value conversion applied to the expression referencing |
| ``i``. Thankfully, the matcher library offers a solution to this problem |
| in the form of ``ignoringParenImpCasts``, which instructs the matcher to |
| ignore implicit casts and parentheses before continuing to match. |
| Adjusting the condition operator will restore the desired match. |
| |
| :: |
| |
| hasCondition(binaryOperator( |
| hasOperatorName("<"), |
| hasLHS(expr(hasType(isInteger()))), |
| hasRHS(ignoringParenImpCasts(declRefExpr( |
| to(varDecl(hasType(isInteger())))))))) |
| |
| After adding binds to the expressions we wished to capture and |
| extracting the identifier strings into variables, we have array-step-2 |
| completed. |
| |
| Step 4: Retrieving Matched Nodes |
| ================================ |
| |
| So far, the matcher callback isn't very interesting: it just dumps the |
| loop's AST. At some point, we will need to make changes to the input |
| source code. Next, we'll work on using the nodes we bound in the |
| previous step. |
| |
| The ``MatchFinder::run()`` callback takes a |
| ``MatchFinder::MatchResult&`` as its parameter. We're most interested in |
| its ``Context`` and ``Nodes`` members. Clang uses the ``ASTContext`` |
| class to represent contextual information about the AST, as the name |
| implies, though the most functionally important detail is that several |
| operations require an ``ASTContext*`` parameter. More immediately useful |
| is the set of matched nodes, and how we retrieve them. |
| |
| Since we bind three variables (identified by ConditionVarName, |
| InitVarName, and IncrementVarName), we can obtain the matched nodes by |
| using the ``getNodeAs()`` member function. |
| |
| In ``LoopActions.cpp``: |
| |
| :: |
| |
| #include "clang/AST/ASTContext.h" |
| |
| void LoopPrinter::run(const MatchFinder::MatchResult &Result) { |
| ASTContext *Context = Result.Context; |
| const ForStmt *FS = Result.Nodes.getStmtAs<ForStmt>(LoopName); |
| // We do not want to convert header files! |
| if (!FS || !Context->getSourceManager().isFromMainFile(FS->getForLoc())) |
| return; |
| const VarDecl *IncVar = Result.Nodes.getNodeAs<VarDecl>(IncrementVarName); |
| const VarDecl *CondVar = Result.Nodes.getNodeAs<VarDecl>(ConditionVarName); |
| const VarDecl *InitVar = Result.Nodes.getNodeAs<VarDecl>(InitVarName); |
| |
| Now that we have the three variables, represented by their respective |
| declarations, let's make sure that they're all the same, using a helper |
| function I call ``areSameVariable()``. |
| |
| :: |
| |
| if (!areSameVariable(IncVar, CondVar) || !areSameVariable(IncVar, InitVar)) |
| return; |
| llvm::outs() << "Potential array-based loop discovered.\n"; |
| } |
| |
| If execution reaches the end of ``LoopPrinter::run()``, we know that the |
| loop shell that looks like |
| |
| :: |
| |
| for (int i= 0; i < expr(); ++i) { ... } |
| |
| For now, we will just print a message explaining that we found a loop. |
| The next section will deal with recursively traversing the AST to |
| discover all changes needed. |
| |
| As a side note, here is the implementation of ``areSameVariable``. Clang |
| associates a ``VarDecl`` with each variable to represent the variable's |
| declaration. Since the "canonical" form of each declaration is unique by |
| address, all we need to do is make sure neither ``ValueDecl`` (base |
| class of ``VarDecl``) is ``NULL`` and compare the canonical Decls. |
| |
| :: |
| |
| static bool areSameVariable(const ValueDecl *First, const ValueDecl *Second) { |
| return First && Second && |
| First->getCanonicalDecl() == Second->getCanonicalDecl(); |
| } |
| |
| It's not as trivial to test if two expressions are the same, though |
| Clang has already done the hard work for us by providing a way to |
| canonicalize expressions: |
| |
| :: |
| |
| static bool areSameExpr(ASTContext* Context, const Expr *First, |
| const Expr *Second) { |
| if (!First || !Second) |
| return false; |
| llvm::FoldingSetNodeID FirstID, SecondID; |
| First->Profile(FirstID, *Context, true); |
| Second->Profile(SecondID, *Context, true); |
| return FirstID == SecondID; |
| } |
| |
| This code relies on the comparison between two |
| ``llvm::FoldingSetNodeIDs``. As the documentation for |
| ``Stmt::Profile()`` indicates, the ``Profile()`` member function builds |
| a description of a node in the AST, based on its properties, along with |
| those of its children. ``FoldingSetNodeID`` then serves as a hash we can |
| use to compare expressions. We will need ``areSameExpr`` later. Before |
| you run the new code on the additional loops added to |
| test-files/simple.cpp, try to figure out which ones will be considered |
| potentially convertible. |