//===--- Registry.cpp - Matcher registry -------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===------------------------------------------------------------===//
///
/// \file
/// \brief Registry map populated at static initialization time.
///
//===------------------------------------------------------------===//
#include "clang/ASTMatchers/Dynamic/Registry.h"
#include "Marshallers.h"
#include "clang/ASTMatchers/ASTMatchers.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/ManagedStatic.h"
#include <set>
#include <utility>
using namespace clang::ast_type_traits;
namespace clang {
namespace ast_matchers {
namespace dynamic {
namespace {
using internal::MatcherDescriptor;
typedef llvm::StringMap<const MatcherDescriptor *> ConstructorMap;
class RegistryMaps {
public:
RegistryMaps();
~RegistryMaps();
const ConstructorMap &constructors() const { return Constructors; }
private:
void registerMatcher(StringRef MatcherName, MatcherDescriptor *Callback);
ConstructorMap Constructors;
};
void RegistryMaps::registerMatcher(StringRef MatcherName,
MatcherDescriptor *Callback) {
assert(Constructors.find(MatcherName) == Constructors.end());
Constructors[MatcherName] = Callback;
}
#define REGISTER_MATCHER(name) \
registerMatcher(#name, internal::makeMatcherAutoMarshall( \
::clang::ast_matchers::name, #name));
#define SPECIFIC_MATCHER_OVERLOAD(name, Id) \
static_cast< ::clang::ast_matchers::name##_Type##Id>( \
::clang::ast_matchers::name)
#define REGISTER_OVERLOADED_2(name) \
do { \
MatcherDescriptor *Callbacks[] = { \
internal::makeMatcherAutoMarshall(SPECIFIC_MATCHER_OVERLOAD(name, 0), \
#name), \
internal::makeMatcherAutoMarshall(SPECIFIC_MATCHER_OVERLOAD(name, 1), \
#name) \
}; \
registerMatcher(#name, \
new internal::OverloadedMatcherDescriptor(Callbacks)); \
} while (0)
/// \brief Generate a registry map with all the known matchers.
RegistryMaps::RegistryMaps() {
// TODO: Here is the list of the missing matchers, grouped by reason.
//
// Need Variant/Parser fixes:
// ofKind
//
// Polymorphic + argument overload:
// findAll
//
// Other:
// equals
// equalsNode
REGISTER_OVERLOADED_2(callee);
REGISTER_OVERLOADED_2(hasPrefix);
REGISTER_OVERLOADED_2(hasType);
REGISTER_OVERLOADED_2(isDerivedFrom);
REGISTER_OVERLOADED_2(isSameOrDerivedFrom);
REGISTER_OVERLOADED_2(loc);
REGISTER_OVERLOADED_2(pointsTo);
REGISTER_OVERLOADED_2(references);
REGISTER_OVERLOADED_2(thisPointerType);
REGISTER_MATCHER(accessSpecDecl);
REGISTER_MATCHER(alignOfExpr);
REGISTER_MATCHER(allOf);
REGISTER_MATCHER(anyOf);
REGISTER_MATCHER(anything);
REGISTER_MATCHER(argumentCountIs);
REGISTER_MATCHER(arraySubscriptExpr);
REGISTER_MATCHER(arrayType);
REGISTER_MATCHER(asString);
REGISTER_MATCHER(asmStmt);
REGISTER_MATCHER(atomicType);
REGISTER_MATCHER(autoType);
REGISTER_MATCHER(binaryOperator);
REGISTER_MATCHER(bindTemporaryExpr);
REGISTER_MATCHER(blockPointerType);
REGISTER_MATCHER(boolLiteral);
REGISTER_MATCHER(breakStmt);
REGISTER_MATCHER(builtinType);
REGISTER_MATCHER(cStyleCastExpr);
REGISTER_MATCHER(callExpr);
REGISTER_MATCHER(caseStmt);
REGISTER_MATCHER(castExpr);
REGISTER_MATCHER(catchStmt);
REGISTER_MATCHER(characterLiteral);
REGISTER_MATCHER(classTemplateDecl);
REGISTER_MATCHER(classTemplateSpecializationDecl);
REGISTER_MATCHER(complexType);
REGISTER_MATCHER(compoundLiteralExpr);
REGISTER_MATCHER(compoundStmt);
REGISTER_MATCHER(conditionalOperator);
REGISTER_MATCHER(constCastExpr);
REGISTER_MATCHER(constantArrayType);
REGISTER_MATCHER(constructExpr);
REGISTER_MATCHER(constructorDecl);
REGISTER_MATCHER(containsDeclaration);
REGISTER_MATCHER(continueStmt);
REGISTER_MATCHER(ctorInitializer);
REGISTER_MATCHER(decl);
REGISTER_MATCHER(declCountIs);
REGISTER_MATCHER(declRefExpr);
REGISTER_MATCHER(declStmt);
REGISTER_MATCHER(declaratorDecl);
REGISTER_MATCHER(defaultArgExpr);
REGISTER_MATCHER(defaultStmt);
REGISTER_MATCHER(deleteExpr);
REGISTER_MATCHER(dependentSizedArrayType);
REGISTER_MATCHER(destructorDecl);
REGISTER_MATCHER(doStmt);
REGISTER_MATCHER(dynamicCastExpr);
REGISTER_MATCHER(eachOf);
REGISTER_MATCHER(elaboratedType);
REGISTER_MATCHER(enumConstantDecl);
REGISTER_MATCHER(enumDecl);
REGISTER_MATCHER(equalsBoundNode);
REGISTER_MATCHER(explicitCastExpr);
REGISTER_MATCHER(expr);
REGISTER_MATCHER(exprWithCleanups);
REGISTER_MATCHER(fieldDecl);
REGISTER_MATCHER(floatLiteral);
REGISTER_MATCHER(forEach);
REGISTER_MATCHER(forEachConstructorInitializer);
REGISTER_MATCHER(forEachDescendant);
REGISTER_MATCHER(forEachSwitchCase);
REGISTER_MATCHER(forField);
REGISTER_MATCHER(forRangeStmt);
REGISTER_MATCHER(forStmt);
REGISTER_MATCHER(friendDecl);
REGISTER_MATCHER(functionDecl);
REGISTER_MATCHER(functionTemplateDecl);
REGISTER_MATCHER(functionType);
REGISTER_MATCHER(functionalCastExpr);
REGISTER_MATCHER(gotoStmt);
REGISTER_MATCHER(has);
REGISTER_MATCHER(hasAncestor);
REGISTER_MATCHER(hasAnyArgument);
REGISTER_MATCHER(hasAnyConstructorInitializer);
REGISTER_MATCHER(hasAnyParameter);
REGISTER_MATCHER(hasAnySubstatement);
REGISTER_MATCHER(hasAnyTemplateArgument);
REGISTER_MATCHER(hasAnyUsingShadowDecl);
REGISTER_MATCHER(hasArgument);
REGISTER_MATCHER(hasArgumentOfType);
REGISTER_MATCHER(hasBase);
REGISTER_MATCHER(hasBody);
REGISTER_MATCHER(hasCanonicalType);
REGISTER_MATCHER(hasCaseConstant);
REGISTER_MATCHER(hasCondition);
REGISTER_MATCHER(hasConditionVariableStatement);
REGISTER_MATCHER(hasDeclContext);
REGISTER_MATCHER(hasDeclaration);
REGISTER_MATCHER(hasDeducedType);
REGISTER_MATCHER(hasDescendant);
REGISTER_MATCHER(hasDestinationType);
REGISTER_MATCHER(hasEitherOperand);
REGISTER_MATCHER(hasElementType);
REGISTER_MATCHER(hasFalseExpression);
REGISTER_MATCHER(hasGlobalStorage);
REGISTER_MATCHER(hasImplicitDestinationType);
REGISTER_MATCHER(hasIncrement);
REGISTER_MATCHER(hasIndex);
REGISTER_MATCHER(hasInitializer);
REGISTER_MATCHER(hasLHS);
REGISTER_MATCHER(hasLocalQualifiers);
REGISTER_MATCHER(hasLocalStorage);
REGISTER_MATCHER(hasLoopInit);
REGISTER_MATCHER(hasMethod);
REGISTER_MATCHER(hasName);
REGISTER_MATCHER(hasObjectExpression);
REGISTER_MATCHER(hasOperatorName);
REGISTER_MATCHER(hasOverloadedOperatorName);
REGISTER_MATCHER(hasParameter);
REGISTER_MATCHER(hasParent);
REGISTER_MATCHER(hasQualifier);
REGISTER_MATCHER(hasRHS);
REGISTER_MATCHER(hasSingleDecl);
REGISTER_MATCHER(hasSize);
REGISTER_MATCHER(hasSizeExpr);
REGISTER_MATCHER(hasSourceExpression);
REGISTER_MATCHER(hasTargetDecl);
REGISTER_MATCHER(hasTemplateArgument);
REGISTER_MATCHER(hasTrueExpression);
REGISTER_MATCHER(hasTypeLoc);
REGISTER_MATCHER(hasUnaryOperand);
REGISTER_MATCHER(hasValueType);
REGISTER_MATCHER(ifStmt);
REGISTER_MATCHER(ignoringImpCasts);
REGISTER_MATCHER(ignoringParenCasts);
REGISTER_MATCHER(ignoringParenImpCasts);
REGISTER_MATCHER(implicitCastExpr);
REGISTER_MATCHER(incompleteArrayType);
REGISTER_MATCHER(initListExpr);
REGISTER_MATCHER(innerType);
REGISTER_MATCHER(integerLiteral);
REGISTER_MATCHER(isArrow);
REGISTER_MATCHER(isConst);
REGISTER_MATCHER(isConstQualified);
REGISTER_MATCHER(isDefinition);
REGISTER_MATCHER(isExplicitTemplateSpecialization);
REGISTER_MATCHER(isExpr);
REGISTER_MATCHER(isExternC);
REGISTER_MATCHER(isImplicit);
REGISTER_MATCHER(isInteger);
REGISTER_MATCHER(isListInitialization);
REGISTER_MATCHER(isOverride);
REGISTER_MATCHER(isPrivate);
REGISTER_MATCHER(isProtected);
REGISTER_MATCHER(isPublic);
REGISTER_MATCHER(isTemplateInstantiation);
REGISTER_MATCHER(isVirtual);
REGISTER_MATCHER(isWritten);
REGISTER_MATCHER(lValueReferenceType);
REGISTER_MATCHER(labelStmt);
REGISTER_MATCHER(lambdaExpr);
REGISTER_MATCHER(matchesName);
REGISTER_MATCHER(materializeTemporaryExpr);
REGISTER_MATCHER(member);
REGISTER_MATCHER(memberCallExpr);
REGISTER_MATCHER(memberExpr);
REGISTER_MATCHER(memberPointerType);
REGISTER_MATCHER(methodDecl);
REGISTER_MATCHER(namedDecl);
REGISTER_MATCHER(namesType);
REGISTER_MATCHER(namespaceDecl);
REGISTER_MATCHER(nestedNameSpecifier);
REGISTER_MATCHER(nestedNameSpecifierLoc);
REGISTER_MATCHER(newExpr);
REGISTER_MATCHER(nullPtrLiteralExpr);
REGISTER_MATCHER(nullStmt);
REGISTER_MATCHER(ofClass);
REGISTER_MATCHER(on);
REGISTER_MATCHER(onImplicitObjectArgument);
REGISTER_MATCHER(operatorCallExpr);
REGISTER_MATCHER(parameterCountIs);
REGISTER_MATCHER(parenType);
REGISTER_MATCHER(parmVarDecl);
REGISTER_MATCHER(pointee);
REGISTER_MATCHER(pointerType);
REGISTER_MATCHER(qualType);
REGISTER_MATCHER(rValueReferenceType);
REGISTER_MATCHER(recordDecl);
REGISTER_MATCHER(recordType);
REGISTER_MATCHER(referenceType);
REGISTER_MATCHER(refersToDeclaration);
REGISTER_MATCHER(refersToType);
REGISTER_MATCHER(reinterpretCastExpr);
REGISTER_MATCHER(returnStmt);
REGISTER_MATCHER(returns);
REGISTER_MATCHER(sizeOfExpr);
REGISTER_MATCHER(specifiesNamespace);
REGISTER_MATCHER(specifiesType);
REGISTER_MATCHER(specifiesTypeLoc);
REGISTER_MATCHER(statementCountIs);
REGISTER_MATCHER(staticCastExpr);
REGISTER_MATCHER(stmt);
REGISTER_MATCHER(stringLiteral);
REGISTER_MATCHER(switchCase);
REGISTER_MATCHER(switchStmt);
REGISTER_MATCHER(templateSpecializationType);
REGISTER_MATCHER(temporaryObjectExpr);
REGISTER_MATCHER(thisExpr);
REGISTER_MATCHER(throughUsingDecl);
REGISTER_MATCHER(throwExpr);
REGISTER_MATCHER(to);
REGISTER_MATCHER(tryStmt);
REGISTER_MATCHER(type);
REGISTER_MATCHER(typeLoc);
REGISTER_MATCHER(typedefType);
REGISTER_MATCHER(unaryExprOrTypeTraitExpr);
REGISTER_MATCHER(unaryOperator);
REGISTER_MATCHER(unaryTransformType);
REGISTER_MATCHER(unless);
REGISTER_MATCHER(unresolvedConstructExpr);
REGISTER_MATCHER(unresolvedUsingValueDecl);
REGISTER_MATCHER(userDefinedLiteral);
REGISTER_MATCHER(usingDecl);
REGISTER_MATCHER(varDecl);
REGISTER_MATCHER(variableArrayType);
REGISTER_MATCHER(whileStmt);
REGISTER_MATCHER(withInitializer);
}
RegistryMaps::~RegistryMaps() {
for (ConstructorMap::iterator it = Constructors.begin(),
end = Constructors.end();
it != end; ++it) {
delete it->second;
}
}
static llvm::ManagedStatic<RegistryMaps> RegistryData;
} // anonymous namespace
// static
llvm::Optional<MatcherCtor> Registry::lookupMatcherCtor(StringRef MatcherName) {
ConstructorMap::const_iterator it =
RegistryData->constructors().find(MatcherName);
return it == RegistryData->constructors().end()
? llvm::Optional<MatcherCtor>()
: it->second;
}
namespace {
llvm::raw_ostream &operator<<(llvm::raw_ostream &OS,
const std::set<ASTNodeKind> &KS) {
unsigned Count = 0;
for (std::set<ASTNodeKind>::const_iterator I = KS.begin(), E = KS.end();
I != E; ++I) {
if (I != KS.begin())
OS << "|";
if (Count++ == 3) {
OS << "...";
break;
}
OS << *I;
}
return OS;
}
struct ReverseSpecificityThenName {
bool operator()(const std::pair<unsigned, std::string> &A,
const std::pair<unsigned, std::string> &B) const {
return A.first > B.first || (A.first == B.first && A.second < B.second);
}
};
}
std::vector<MatcherCompletion> Registry::getCompletions(
ArrayRef<std::pair<MatcherCtor, unsigned> > Context) {
ASTNodeKind InitialTypes[] = {
ASTNodeKind::getFromNodeKind<Decl>(),
ASTNodeKind::getFromNodeKind<QualType>(),
ASTNodeKind::getFromNodeKind<Type>(),
ASTNodeKind::getFromNodeKind<Stmt>(),
ASTNodeKind::getFromNodeKind<NestedNameSpecifier>(),
ASTNodeKind::getFromNodeKind<NestedNameSpecifierLoc>(),
ASTNodeKind::getFromNodeKind<TypeLoc>()
};
ArrayRef<ASTNodeKind> InitialTypesRef(InitialTypes);
// Starting with the above seed of acceptable top-level matcher types, compute
// the acceptable type set for the argument indicated by each context element.
std::set<ASTNodeKind> TypeSet(InitialTypesRef.begin(), InitialTypesRef.end());
for (ArrayRef<std::pair<MatcherCtor, unsigned> >::iterator
CtxI = Context.begin(),
CtxE = Context.end();
CtxI != CtxE; ++CtxI) {
std::vector<internal::ArgKind> NextTypeSet;
for (std::set<ASTNodeKind>::iterator I = TypeSet.begin(), E = TypeSet.end();
I != E; ++I) {
if (CtxI->first->isConvertibleTo(*I) &&
(CtxI->first->isVariadic() ||
CtxI->second < CtxI->first->getNumArgs()))
CtxI->first->getArgKinds(*I, CtxI->second, NextTypeSet);
}
TypeSet.clear();
for (std::vector<internal::ArgKind>::iterator I = NextTypeSet.begin(),
E = NextTypeSet.end();
I != E; ++I) {
if (I->getArgKind() == internal::ArgKind::AK_Matcher)
TypeSet.insert(I->getMatcherKind());
}
}
typedef std::map<std::pair<unsigned, std::string>, MatcherCompletion,
ReverseSpecificityThenName> CompletionsTy;
CompletionsTy Completions;
// TypeSet now contains the list of acceptable types for the argument we are
// completing. Search the registry for acceptable matchers.
for (ConstructorMap::const_iterator I = RegistryData->constructors().begin(),
E = RegistryData->constructors().end();
I != E; ++I) {
std::set<ASTNodeKind> RetKinds;
unsigned NumArgs = I->second->isVariadic() ? 1 : I->second->getNumArgs();
bool IsPolymorphic = I->second->isPolymorphic();
std::vector<std::vector<internal::ArgKind> > ArgsKinds(NumArgs);
unsigned MaxSpecificity = 0;
for (std::set<ASTNodeKind>::iterator TI = TypeSet.begin(),
TE = TypeSet.end();
TI != TE; ++TI) {
unsigned Specificity;
ASTNodeKind LeastDerivedKind;
if (I->second->isConvertibleTo(*TI, &Specificity, &LeastDerivedKind)) {
if (MaxSpecificity < Specificity)
MaxSpecificity = Specificity;
RetKinds.insert(LeastDerivedKind);
for (unsigned Arg = 0; Arg != NumArgs; ++Arg)
I->second->getArgKinds(*TI, Arg, ArgsKinds[Arg]);
if (IsPolymorphic)
break;
}
}
if (!RetKinds.empty() && MaxSpecificity > 0) {
std::string Decl;
llvm::raw_string_ostream OS(Decl);
if (IsPolymorphic) {
OS << "Matcher<T> " << I->first() << "(Matcher<T>";
} else {
OS << "Matcher<" << RetKinds << "> " << I->first() << "(";
for (std::vector<std::vector<internal::ArgKind> >::iterator
KI = ArgsKinds.begin(),
KE = ArgsKinds.end();
KI != KE; ++KI) {
if (KI != ArgsKinds.begin())
OS << ", ";
// This currently assumes that a matcher may not overload a
// non-matcher, and all non-matcher overloads have identical
// arguments.
if ((*KI)[0].getArgKind() == internal::ArgKind::AK_Matcher) {
std::set<ASTNodeKind> MatcherKinds;
std::transform(
KI->begin(), KI->end(),
std::inserter(MatcherKinds, MatcherKinds.end()),
std::mem_fun_ref(&internal::ArgKind::getMatcherKind));
OS << "Matcher<" << MatcherKinds << ">";
} else {
OS << (*KI)[0].asString();
}
}
}
if (I->second->isVariadic())
OS << "...";
OS << ")";
std::string TypedText = I->first();
TypedText += "(";
if (ArgsKinds.empty())
TypedText += ")";
else if (ArgsKinds[0][0].getArgKind() == internal::ArgKind::AK_String)
TypedText += "\"";
Completions[std::make_pair(MaxSpecificity, I->first())] =
MatcherCompletion(TypedText, OS.str());
}
}
std::vector<MatcherCompletion> RetVal;
for (CompletionsTy::iterator I = Completions.begin(), E = Completions.end();
I != E; ++I)
RetVal.push_back(I->second);
return RetVal;
}
// static
VariantMatcher Registry::constructMatcher(MatcherCtor Ctor,
const SourceRange &NameRange,
ArrayRef<ParserValue> Args,
Diagnostics *Error) {
return Ctor->create(NameRange, Args, Error);
}
// static
VariantMatcher Registry::constructBoundMatcher(MatcherCtor Ctor,
const SourceRange &NameRange,
StringRef BindID,
ArrayRef<ParserValue> Args,
Diagnostics *Error) {
VariantMatcher Out = constructMatcher(Ctor, NameRange, Args, Error);
if (Out.isNull()) return Out;
llvm::Optional<DynTypedMatcher> Result = Out.getSingleMatcher();
if (Result.hasValue()) {
llvm::Optional<DynTypedMatcher> Bound = Result->tryBind(BindID);
if (Bound.hasValue()) {
return VariantMatcher::SingleMatcher(*Bound);
}
}
Error->addError(NameRange, Error->ET_RegistryNotBindable);
return VariantMatcher();
}
} // namespace dynamic
} // namespace ast_matchers
} // namespace clang