lib/Analysis/ExprMutationAnalyzer.cpp - clang - Git at Google

 //===---------- ExprMutationAnalyzer.cpp ----------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 #include "clang/Analysis/Analyses/ExprMutationAnalyzer.h"
 #include "clang/ASTMatchers/ASTMatchFinder.h"
 #include "llvm/ADT/STLExtras.h"

 namespace clang {
 using namespace ast_matchers;

 namespace {

 AST_MATCHER_P(LambdaExpr, hasCaptureInit, const Expr *, E) {
   return llvm::is_contained(Node.capture_inits(), E);
 }

 AST_MATCHER_P(CXXForRangeStmt, hasRangeStmt,
               ast_matchers::internal::Matcher<DeclStmt>, InnerMatcher) {
   const DeclStmt *const Range = Node.getRangeStmt();
   return InnerMatcher.matches(*Range, Finder, Builder);
 }

 AST_MATCHER_P(Expr, maybeEvalCommaExpr,
              ast_matchers::internal::Matcher<Expr>, InnerMatcher) {
   const Expr* Result = &Node;
   while (const auto *BOComma =
                dyn_cast_or_null<BinaryOperator>(Result->IgnoreParens())) {
     if (!BOComma->isCommaOp())
       break;
     Result = BOComma->getRHS();
   }
   return InnerMatcher.matches(*Result, Finder, Builder);
 }

 const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt, CXXTypeidExpr>
     cxxTypeidExpr;

 AST_MATCHER(CXXTypeidExpr, isPotentiallyEvaluated) {
   return Node.isPotentiallyEvaluated();
 }

 const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt, CXXNoexceptExpr>
     cxxNoexceptExpr;

 const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt,
                                                           GenericSelectionExpr>
     genericSelectionExpr;

 AST_MATCHER_P(GenericSelectionExpr, hasControllingExpr,
               ast_matchers::internal::Matcher<Expr>, InnerMatcher) {
   return InnerMatcher.matches(*Node.getControllingExpr(), Finder, Builder);
 }

 const auto nonConstReferenceType = [] {
   return hasUnqualifiedDesugaredType(
       referenceType(pointee(unless(isConstQualified()))));
 };

 const auto nonConstPointerType = [] {
   return hasUnqualifiedDesugaredType(
       pointerType(pointee(unless(isConstQualified()))));
 };

 const auto isMoveOnly = [] {
   return cxxRecordDecl(
       hasMethod(cxxConstructorDecl(isMoveConstructor(), unless(isDeleted()))),
       hasMethod(cxxMethodDecl(isMoveAssignmentOperator(), unless(isDeleted()))),
       unless(anyOf(hasMethod(cxxConstructorDecl(isCopyConstructor(),
                                                 unless(isDeleted()))),
                    hasMethod(cxxMethodDecl(isCopyAssignmentOperator(),
                                            unless(isDeleted()))))));
 };

 template <class T> struct NodeID;
 template <> struct NodeID<Expr> { static const std::string value; };
 template <> struct NodeID<Decl> { static const std::string value; };
 const std::string NodeID<Expr>::value = "expr";
 const std::string NodeID<Decl>::value = "decl";

 template <class T, class F = const Stmt *(ExprMutationAnalyzer::*)(const T *)>
 const Stmt *tryEachMatch(ArrayRef<ast_matchers::BoundNodes> Matches,
                          ExprMutationAnalyzer *Analyzer, F Finder) {
   const StringRef ID = NodeID<T>::value;
   for (const auto &Nodes : Matches) {
     if (const Stmt *S = (Analyzer->*Finder)(Nodes.getNodeAs<T>(ID)))
       return S;
   }
   return nullptr;
 }

 } // namespace

 const Stmt *ExprMutationAnalyzer::findMutation(const Expr *Exp) {
   return findMutationMemoized(Exp,
                               {&ExprMutationAnalyzer::findDirectMutation,
                                &ExprMutationAnalyzer::findMemberMutation,
                                &ExprMutationAnalyzer::findArrayElementMutation,
                                &ExprMutationAnalyzer::findCastMutation,
                                &ExprMutationAnalyzer::findRangeLoopMutation,
                                &ExprMutationAnalyzer::findReferenceMutation,
                                &ExprMutationAnalyzer::findFunctionArgMutation},
                               Results);
 }

 const Stmt *ExprMutationAnalyzer::findMutation(const Decl *Dec) {
   return tryEachDeclRef(Dec, &ExprMutationAnalyzer::findMutation);
 }

 const Stmt *ExprMutationAnalyzer::findPointeeMutation(const Expr *Exp) {
   return findMutationMemoized(Exp, {/*TODO*/}, PointeeResults);
 }

 const Stmt *ExprMutationAnalyzer::findPointeeMutation(const Decl *Dec) {
   return tryEachDeclRef(Dec, &ExprMutationAnalyzer::findPointeeMutation);
 }

 const Stmt *ExprMutationAnalyzer::findMutationMemoized(
     const Expr *Exp, llvm::ArrayRef<MutationFinder> Finders,
     ResultMap &MemoizedResults) {
   const auto Memoized = MemoizedResults.find(Exp);
   if (Memoized != MemoizedResults.end())
     return Memoized->second;

   if (isUnevaluated(Exp))
     return MemoizedResults[Exp] = nullptr;

   for (const auto &Finder : Finders) {
     if (const Stmt *S = (this->*Finder)(Exp))
       return MemoizedResults[Exp] = S;
   }

   return MemoizedResults[Exp] = nullptr;
 }

 const Stmt *ExprMutationAnalyzer::tryEachDeclRef(const Decl *Dec,
                                                  MutationFinder Finder) {
   const auto Refs =
       match(findAll(declRefExpr(to(equalsNode(Dec))).bind(NodeID<Expr>::value)),
             Stm, Context);
   for (const auto &RefNodes : Refs) {
     const auto *E = RefNodes.getNodeAs<Expr>(NodeID<Expr>::value);
     if ((this->*Finder)(E))
       return E;
   }
   return nullptr;
 }

 bool ExprMutationAnalyzer::isUnevaluated(const Expr *Exp) {
   return selectFirst<Expr>(
              NodeID<Expr>::value,
              match(
                  findAll(
                      expr(equalsNode(Exp),
                           anyOf(
                               // `Exp` is part of the underlying expression of
                               // decltype/typeof if it has an ancestor of
                               // typeLoc.
                               hasAncestor(typeLoc(unless(
                                   hasAncestor(unaryExprOrTypeTraitExpr())))),
                               hasAncestor(expr(anyOf(
                                   // `UnaryExprOrTypeTraitExpr` is unevaluated
                                   // unless it's sizeof on VLA.
                                   unaryExprOrTypeTraitExpr(unless(sizeOfExpr(
                                       hasArgumentOfType(variableArrayType())))),
                                   // `CXXTypeidExpr` is unevaluated unless it's
                                   // applied to an expression of glvalue of
                                   // polymorphic class type.
                                   cxxTypeidExpr(
                                       unless(isPotentiallyEvaluated())),
                                   // The controlling expression of
                                   // `GenericSelectionExpr` is unevaluated.
                                   genericSelectionExpr(hasControllingExpr(
                                       hasDescendant(equalsNode(Exp)))),
                                   cxxNoexceptExpr())))))
                          .bind(NodeID<Expr>::value)),
                  Stm, Context)) != nullptr;
 }

 const Stmt *
 ExprMutationAnalyzer::findExprMutation(ArrayRef<BoundNodes> Matches) {
   return tryEachMatch<Expr>(Matches, this, &ExprMutationAnalyzer::findMutation);
 }

 const Stmt *
 ExprMutationAnalyzer::findDeclMutation(ArrayRef<BoundNodes> Matches) {
   return tryEachMatch<Decl>(Matches, this, &ExprMutationAnalyzer::findMutation);
 }

 const Stmt *ExprMutationAnalyzer::findExprPointeeMutation(
     ArrayRef<ast_matchers::BoundNodes> Matches) {
   return tryEachMatch<Expr>(Matches, this,
                             &ExprMutationAnalyzer::findPointeeMutation);
 }

 const Stmt *ExprMutationAnalyzer::findDeclPointeeMutation(
     ArrayRef<ast_matchers::BoundNodes> Matches) {
   return tryEachMatch<Decl>(Matches, this,
                             &ExprMutationAnalyzer::findPointeeMutation);
 }

 const Stmt *ExprMutationAnalyzer::findDirectMutation(const Expr *Exp) {
   // LHS of any assignment operators.
   const auto AsAssignmentLhs =
       binaryOperator(isAssignmentOperator(),
                      hasLHS(maybeEvalCommaExpr(equalsNode(Exp))));

   // Operand of increment/decrement operators.
   const auto AsIncDecOperand =
       unaryOperator(anyOf(hasOperatorName("++"), hasOperatorName("--")),
                     hasUnaryOperand(maybeEvalCommaExpr(equalsNode(Exp))));

   // Invoking non-const member function.
   // A member function is assumed to be non-const when it is unresolved.
   const auto NonConstMethod = cxxMethodDecl(unless(isConst()));
   const auto AsNonConstThis =
       expr(anyOf(cxxMemberCallExpr(callee(NonConstMethod),
                                    on(maybeEvalCommaExpr(equalsNode(Exp)))),
                  cxxOperatorCallExpr(callee(NonConstMethod),
                                      hasArgument(0,
                                                  maybeEvalCommaExpr(equalsNode(Exp)))),
                  callExpr(callee(expr(anyOf(
                      unresolvedMemberExpr(
                        hasObjectExpression(maybeEvalCommaExpr(equalsNode(Exp)))),
                      cxxDependentScopeMemberExpr(
                          hasObjectExpression(maybeEvalCommaExpr(equalsNode(Exp))))))))));

   // Taking address of 'Exp'.
   // We're assuming 'Exp' is mutated as soon as its address is taken, though in
   // theory we can follow the pointer and see whether it escaped `Stm` or is
   // dereferenced and then mutated. This is left for future improvements.
   const auto AsAmpersandOperand =
       unaryOperator(hasOperatorName("&"),
                     // A NoOp implicit cast is adding const.
                     unless(hasParent(implicitCastExpr(hasCastKind(CK_NoOp)))),
                     hasUnaryOperand(maybeEvalCommaExpr(equalsNode(Exp))));
   const auto AsPointerFromArrayDecay =
       castExpr(hasCastKind(CK_ArrayToPointerDecay),
                unless(hasParent(arraySubscriptExpr())),
                has(maybeEvalCommaExpr(equalsNode(Exp))));
   // Treat calling `operator->()` of move-only classes as taking address.
   // These are typically smart pointers with unique ownership so we treat
   // mutation of pointee as mutation of the smart pointer itself.
   const auto AsOperatorArrowThis =
       cxxOperatorCallExpr(hasOverloadedOperatorName("->"),
                           callee(cxxMethodDecl(ofClass(isMoveOnly()),
                                                returns(nonConstPointerType()))),
                           argumentCountIs(1),
                           hasArgument(0, maybeEvalCommaExpr(equalsNode(Exp))));

   // Used as non-const-ref argument when calling a function.
   // An argument is assumed to be non-const-ref when the function is unresolved.
   // Instantiated template functions are not handled here but in
   // findFunctionArgMutation which has additional smarts for handling forwarding
   // references.
   const auto NonConstRefParam = forEachArgumentWithParam(
       maybeEvalCommaExpr(equalsNode(Exp)),
       parmVarDecl(hasType(nonConstReferenceType())));
   const auto NotInstantiated = unless(hasDeclaration(isInstantiated()));
   const auto AsNonConstRefArg = anyOf(
       callExpr(NonConstRefParam, NotInstantiated),
       cxxConstructExpr(NonConstRefParam, NotInstantiated),
       callExpr(callee(expr(anyOf(unresolvedLookupExpr(), unresolvedMemberExpr(),
                                  cxxDependentScopeMemberExpr(),
                                  hasType(templateTypeParmType())))),
                hasAnyArgument(maybeEvalCommaExpr(equalsNode(Exp)))),
       cxxUnresolvedConstructExpr(hasAnyArgument(maybeEvalCommaExpr(equalsNode(Exp)))));

   // Captured by a lambda by reference.
   // If we're initializing a capture with 'Exp' directly then we're initializing
   // a reference capture.
   // For value captures there will be an ImplicitCastExpr <LValueToRValue>.
   const auto AsLambdaRefCaptureInit = lambdaExpr(hasCaptureInit(Exp));

   // Returned as non-const-ref.
   // If we're returning 'Exp' directly then it's returned as non-const-ref.
   // For returning by value there will be an ImplicitCastExpr <LValueToRValue>.
   // For returning by const-ref there will be an ImplicitCastExpr <NoOp> (for
   // adding const.)
   const auto AsNonConstRefReturn = returnStmt(hasReturnValue(
                                                 maybeEvalCommaExpr(equalsNode(Exp))));

   const auto Matches =
       match(findAll(stmt(anyOf(AsAssignmentLhs, AsIncDecOperand, AsNonConstThis,
                                AsAmpersandOperand, AsPointerFromArrayDecay,
                                AsOperatorArrowThis, AsNonConstRefArg,
                                AsLambdaRefCaptureInit, AsNonConstRefReturn))
                         .bind("stmt")),
             Stm, Context);
   return selectFirst<Stmt>("stmt", Matches);
 }

 const Stmt *ExprMutationAnalyzer::findMemberMutation(const Expr *Exp) {
   // Check whether any member of 'Exp' is mutated.
   const auto MemberExprs =
       match(findAll(expr(anyOf(memberExpr(hasObjectExpression(equalsNode(Exp))),
                                cxxDependentScopeMemberExpr(
                                    hasObjectExpression(equalsNode(Exp)))))
                         .bind(NodeID<Expr>::value)),
             Stm, Context);
   return findExprMutation(MemberExprs);
 }

 const Stmt *ExprMutationAnalyzer::findArrayElementMutation(const Expr *Exp) {
   // Check whether any element of an array is mutated.
   const auto SubscriptExprs = match(
       findAll(arraySubscriptExpr(hasBase(ignoringImpCasts(equalsNode(Exp))))
                   .bind(NodeID<Expr>::value)),
       Stm, Context);
   return findExprMutation(SubscriptExprs);
 }

 const Stmt *ExprMutationAnalyzer::findCastMutation(const Expr *Exp) {
   // If 'Exp' is casted to any non-const reference type, check the castExpr.
   const auto Casts =
       match(findAll(castExpr(hasSourceExpression(equalsNode(Exp)),
                              anyOf(explicitCastExpr(hasDestinationType(
                                        nonConstReferenceType())),
                                    implicitCastExpr(hasImplicitDestinationType(
                                        nonConstReferenceType()))))
                         .bind(NodeID<Expr>::value)),
             Stm, Context);
   if (const Stmt *S = findExprMutation(Casts))
     return S;
   // Treat std::{move,forward} as cast.
   const auto Calls =
       match(findAll(callExpr(callee(namedDecl(
                                  hasAnyName("::std::move", "::std::forward"))),
                              hasArgument(0, equalsNode(Exp)))
                         .bind("expr")),
             Stm, Context);
   return findExprMutation(Calls);
 }

 const Stmt *ExprMutationAnalyzer::findRangeLoopMutation(const Expr *Exp) {
   // If range for looping over 'Exp' with a non-const reference loop variable,
   // check all declRefExpr of the loop variable.
   const auto LoopVars =
       match(findAll(cxxForRangeStmt(
                 hasLoopVariable(varDecl(hasType(nonConstReferenceType()))
                                     .bind(NodeID<Decl>::value)),
                 hasRangeInit(equalsNode(Exp)))),
             Stm, Context);
   return findDeclMutation(LoopVars);
 }

 const Stmt *ExprMutationAnalyzer::findReferenceMutation(const Expr *Exp) {
   // Follow non-const reference returned by `operator*()` of move-only classes.
   // These are typically smart pointers with unique ownership so we treat
   // mutation of pointee as mutation of the smart pointer itself.
   const auto Ref =
       match(findAll(cxxOperatorCallExpr(
                         hasOverloadedOperatorName("*"),
                         callee(cxxMethodDecl(ofClass(isMoveOnly()),
                                              returns(nonConstReferenceType()))),
                         argumentCountIs(1), hasArgument(0, equalsNode(Exp)))
                         .bind(NodeID<Expr>::value)),
             Stm, Context);
   if (const Stmt *S = findExprMutation(Ref))
     return S;

   // If 'Exp' is bound to a non-const reference, check all declRefExpr to that.
   const auto Refs = match(
       stmt(forEachDescendant(
           varDecl(
               hasType(nonConstReferenceType()),
               hasInitializer(anyOf(equalsNode(Exp),
                                    conditionalOperator(anyOf(
                                        hasTrueExpression(equalsNode(Exp)),
                                        hasFalseExpression(equalsNode(Exp)))))),
               hasParent(declStmt().bind("stmt")),
               // Don't follow the reference in range statement, we've handled
               // that separately.
               unless(hasParent(declStmt(hasParent(
                   cxxForRangeStmt(hasRangeStmt(equalsBoundNode("stmt"))))))))
               .bind(NodeID<Decl>::value))),
       Stm, Context);
   return findDeclMutation(Refs);
 }

 const Stmt *ExprMutationAnalyzer::findFunctionArgMutation(const Expr *Exp) {
   const auto NonConstRefParam = forEachArgumentWithParam(
       equalsNode(Exp),
       parmVarDecl(hasType(nonConstReferenceType())).bind("parm"));
   const auto IsInstantiated = hasDeclaration(isInstantiated());
   const auto FuncDecl = hasDeclaration(functionDecl().bind("func"));
   const auto Matches = match(
       findAll(expr(anyOf(callExpr(NonConstRefParam, IsInstantiated, FuncDecl,
                                   unless(callee(namedDecl(hasAnyName(
                                       "::std::move", "::std::forward"))))),
                          cxxConstructExpr(NonConstRefParam, IsInstantiated,
                                           FuncDecl)))
                   .bind(NodeID<Expr>::value)),
       Stm, Context);
   for (const auto &Nodes : Matches) {
     const auto *Exp = Nodes.getNodeAs<Expr>(NodeID<Expr>::value);
     const auto *Func = Nodes.getNodeAs<FunctionDecl>("func");
     if (!Func->getBody() || !Func->getPrimaryTemplate())
       return Exp;

     const auto *Parm = Nodes.getNodeAs<ParmVarDecl>("parm");
     const ArrayRef<ParmVarDecl *> AllParams =
         Func->getPrimaryTemplate()->getTemplatedDecl()->parameters();
     QualType ParmType =
         AllParams[std::min<size_t>(Parm->getFunctionScopeIndex(),
                                    AllParams.size() - 1)]
             ->getType();
     if (const auto *T = ParmType->getAs<PackExpansionType>())
       ParmType = T->getPattern();

     // If param type is forwarding reference, follow into the function
     // definition and see whether the param is mutated inside.
     if (const auto *RefType = ParmType->getAs<RValueReferenceType>()) {
       if (!RefType->getPointeeType().getQualifiers() &&
           RefType->getPointeeType()->getAs<TemplateTypeParmType>()) {
         std::unique_ptr<FunctionParmMutationAnalyzer> &Analyzer =
             FuncParmAnalyzer[Func];
         if (!Analyzer)
           Analyzer.reset(new FunctionParmMutationAnalyzer(*Func, Context));
         if (Analyzer->findMutation(Parm))
           return Exp;
         continue;
       }
     }
     // Not forwarding reference.
     return Exp;
   }
   return nullptr;
 }

 FunctionParmMutationAnalyzer::FunctionParmMutationAnalyzer(
     const FunctionDecl &Func, ASTContext &Context)
     : BodyAnalyzer(*Func.getBody(), Context) {
   if (const auto *Ctor = dyn_cast<CXXConstructorDecl>(&Func)) {
     // CXXCtorInitializer might also mutate Param but they're not part of
     // function body, check them eagerly here since they're typically trivial.
     for (const CXXCtorInitializer *Init : Ctor->inits()) {
       ExprMutationAnalyzer InitAnalyzer(*Init->getInit(), Context);
       for (const ParmVarDecl *Parm : Ctor->parameters()) {
         if (Results.find(Parm) != Results.end())
           continue;
         if (const Stmt *S = InitAnalyzer.findMutation(Parm))
           Results[Parm] = S;
       }
     }
   }
 }

 const Stmt *
 FunctionParmMutationAnalyzer::findMutation(const ParmVarDecl *Parm) {
   const auto Memoized = Results.find(Parm);
   if (Memoized != Results.end())
     return Memoized->second;

   if (const Stmt *S = BodyAnalyzer.findMutation(Parm))
     return Results[Parm] = S;

   return Results[Parm] = nullptr;
 }

 } // namespace clang
	//===---------- ExprMutationAnalyzer.cpp ----------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	#include "clang/Analysis/Analyses/ExprMutationAnalyzer.h"
	#include "clang/ASTMatchers/ASTMatchFinder.h"
	#include "llvm/ADT/STLExtras.h"

	namespace clang {
	using namespace ast_matchers;

	namespace {

	AST_MATCHER_P(LambdaExpr, hasCaptureInit, const Expr *, E) {
	return llvm::is_contained(Node.capture_inits(), E);
	}

	AST_MATCHER_P(CXXForRangeStmt, hasRangeStmt,
	ast_matchers::internal::Matcher<DeclStmt>, InnerMatcher) {
	const DeclStmt *const Range = Node.getRangeStmt();
	return InnerMatcher.matches(*Range, Finder, Builder);
	}

	AST_MATCHER_P(Expr, maybeEvalCommaExpr,
	ast_matchers::internal::Matcher<Expr>, InnerMatcher) {
	const Expr* Result = &Node;
	while (const auto *BOComma =
	dyn_cast_or_null<BinaryOperator>(Result->IgnoreParens())) {
	if (!BOComma->isCommaOp())
	break;
	Result = BOComma->getRHS();
	}
	return InnerMatcher.matches(*Result, Finder, Builder);
	}

	const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt, CXXTypeidExpr>
	cxxTypeidExpr;

	AST_MATCHER(CXXTypeidExpr, isPotentiallyEvaluated) {
	return Node.isPotentiallyEvaluated();
	}

	const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt, CXXNoexceptExpr>
	cxxNoexceptExpr;

	const ast_matchers::internal::VariadicDynCastAllOfMatcher<Stmt,
	GenericSelectionExpr>
	genericSelectionExpr;

	AST_MATCHER_P(GenericSelectionExpr, hasControllingExpr,
	ast_matchers::internal::Matcher<Expr>, InnerMatcher) {
	return InnerMatcher.matches(*Node.getControllingExpr(), Finder, Builder);
	}

	const auto nonConstReferenceType = [] {
	return hasUnqualifiedDesugaredType(
	referenceType(pointee(unless(isConstQualified()))));
	};

	const auto nonConstPointerType = [] {
	return hasUnqualifiedDesugaredType(
	pointerType(pointee(unless(isConstQualified()))));
	};

	const auto isMoveOnly = [] {
	return cxxRecordDecl(
	hasMethod(cxxConstructorDecl(isMoveConstructor(), unless(isDeleted()))),
	hasMethod(cxxMethodDecl(isMoveAssignmentOperator(), unless(isDeleted()))),
	unless(anyOf(hasMethod(cxxConstructorDecl(isCopyConstructor(),
	unless(isDeleted()))),
	hasMethod(cxxMethodDecl(isCopyAssignmentOperator(),
	unless(isDeleted()))))));
	};

	template <class T> struct NodeID;
	template <> struct NodeID<Expr> { static const std::string value; };
	template <> struct NodeID<Decl> { static const std::string value; };
	const std::string NodeID<Expr>::value = "expr";
	const std::string NodeID<Decl>::value = "decl";

	template <class T, class F = const Stmt (ExprMutationAnalyzer::)(const T *)>
	const Stmt *tryEachMatch(ArrayRef<ast_matchers::BoundNodes> Matches,
	ExprMutationAnalyzer *Analyzer, F Finder) {
	const StringRef ID = NodeID<T>::value;
	for (const auto &Nodes : Matches) {
	if (const Stmt S = (Analyzer->Finder)(Nodes.getNodeAs<T>(ID)))
	return S;
	}
	return nullptr;
	}

	} // namespace

	const Stmt ExprMutationAnalyzer::findMutation(const Expr Exp) {
	return findMutationMemoized(Exp,
	{&ExprMutationAnalyzer::findDirectMutation,
	&ExprMutationAnalyzer::findMemberMutation,
	&ExprMutationAnalyzer::findArrayElementMutation,
	&ExprMutationAnalyzer::findCastMutation,
	&ExprMutationAnalyzer::findRangeLoopMutation,
	&ExprMutationAnalyzer::findReferenceMutation,
	&ExprMutationAnalyzer::findFunctionArgMutation},
	Results);
	}

	const Stmt ExprMutationAnalyzer::findMutation(const Decl Dec) {
	return tryEachDeclRef(Dec, &ExprMutationAnalyzer::findMutation);
	}

	const Stmt ExprMutationAnalyzer::findPointeeMutation(const Expr Exp) {
	return findMutationMemoized(Exp, {/TODO/}, PointeeResults);
	}

	const Stmt ExprMutationAnalyzer::findPointeeMutation(const Decl Dec) {
	return tryEachDeclRef(Dec, &ExprMutationAnalyzer::findPointeeMutation);
	}

	const Stmt *ExprMutationAnalyzer::findMutationMemoized(
	const Expr *Exp, llvm::ArrayRef<MutationFinder> Finders,
	ResultMap &MemoizedResults) {
	const auto Memoized = MemoizedResults.find(Exp);
	if (Memoized != MemoizedResults.end())
	return Memoized->second;

	if (isUnevaluated(Exp))
	return MemoizedResults[Exp] = nullptr;

	for (const auto &Finder : Finders) {
	if (const Stmt S = (this->Finder)(Exp))
	return MemoizedResults[Exp] = S;
	}

	return MemoizedResults[Exp] = nullptr;
	}

	const Stmt ExprMutationAnalyzer::tryEachDeclRef(const Decl Dec,
	MutationFinder Finder) {
	const auto Refs =
	match(findAll(declRefExpr(to(equalsNode(Dec))).bind(NodeID<Expr>::value)),
	Stm, Context);
	for (const auto &RefNodes : Refs) {
	const auto *E = RefNodes.getNodeAs<Expr>(NodeID<Expr>::value);
	if ((this->*Finder)(E))
	return E;
	}
	return nullptr;
	}

	bool ExprMutationAnalyzer::isUnevaluated(const Expr *Exp) {
	return selectFirst<Expr>(
	NodeID<Expr>::value,
	match(
	findAll(
	expr(equalsNode(Exp),
	anyOf(
	// `Exp` is part of the underlying expression of
	// decltype/typeof if it has an ancestor of
	// typeLoc.
	hasAncestor(typeLoc(unless(
	hasAncestor(unaryExprOrTypeTraitExpr())))),
	hasAncestor(expr(anyOf(
	// `UnaryExprOrTypeTraitExpr` is unevaluated
	// unless it's sizeof on VLA.
	unaryExprOrTypeTraitExpr(unless(sizeOfExpr(
	hasArgumentOfType(variableArrayType())))),
	// `CXXTypeidExpr` is unevaluated unless it's
	// applied to an expression of glvalue of
	// polymorphic class type.
	cxxTypeidExpr(
	unless(isPotentiallyEvaluated())),
	// The controlling expression of
	// `GenericSelectionExpr` is unevaluated.
	genericSelectionExpr(hasControllingExpr(
	hasDescendant(equalsNode(Exp)))),
	cxxNoexceptExpr())))))
	.bind(NodeID<Expr>::value)),
	Stm, Context)) != nullptr;
	}

	const Stmt *
	ExprMutationAnalyzer::findExprMutation(ArrayRef<BoundNodes> Matches) {
	return tryEachMatch<Expr>(Matches, this, &ExprMutationAnalyzer::findMutation);
	}

	const Stmt *
	ExprMutationAnalyzer::findDeclMutation(ArrayRef<BoundNodes> Matches) {
	return tryEachMatch<Decl>(Matches, this, &ExprMutationAnalyzer::findMutation);
	}

	const Stmt *ExprMutationAnalyzer::findExprPointeeMutation(
	ArrayRef<ast_matchers::BoundNodes> Matches) {
	return tryEachMatch<Expr>(Matches, this,
	&ExprMutationAnalyzer::findPointeeMutation);
	}

	const Stmt *ExprMutationAnalyzer::findDeclPointeeMutation(
	ArrayRef<ast_matchers::BoundNodes> Matches) {
	return tryEachMatch<Decl>(Matches, this,
	&ExprMutationAnalyzer::findPointeeMutation);
	}

	const Stmt ExprMutationAnalyzer::findDirectMutation(const Expr Exp) {
	// LHS of any assignment operators.
	const auto AsAssignmentLhs =
	binaryOperator(isAssignmentOperator(),
	hasLHS(maybeEvalCommaExpr(equalsNode(Exp))));

	// Operand of increment/decrement operators.
	const auto AsIncDecOperand =
	unaryOperator(anyOf(hasOperatorName("++"), hasOperatorName("--")),
	hasUnaryOperand(maybeEvalCommaExpr(equalsNode(Exp))));

	// Invoking non-const member function.
	// A member function is assumed to be non-const when it is unresolved.
	const auto NonConstMethod = cxxMethodDecl(unless(isConst()));
	const auto AsNonConstThis =
	expr(anyOf(cxxMemberCallExpr(callee(NonConstMethod),
	on(maybeEvalCommaExpr(equalsNode(Exp)))),
	cxxOperatorCallExpr(callee(NonConstMethod),
	hasArgument(0,
	maybeEvalCommaExpr(equalsNode(Exp)))),
	callExpr(callee(expr(anyOf(
	unresolvedMemberExpr(
	hasObjectExpression(maybeEvalCommaExpr(equalsNode(Exp)))),
	cxxDependentScopeMemberExpr(
	hasObjectExpression(maybeEvalCommaExpr(equalsNode(Exp))))))))));

	// Taking address of 'Exp'.
	// We're assuming 'Exp' is mutated as soon as its address is taken, though in
	// theory we can follow the pointer and see whether it escaped `Stm` or is
	// dereferenced and then mutated. This is left for future improvements.
	const auto AsAmpersandOperand =
	unaryOperator(hasOperatorName("&"),
	// A NoOp implicit cast is adding const.
	unless(hasParent(implicitCastExpr(hasCastKind(CK_NoOp)))),
	hasUnaryOperand(maybeEvalCommaExpr(equalsNode(Exp))));
	const auto AsPointerFromArrayDecay =
	castExpr(hasCastKind(CK_ArrayToPointerDecay),
	unless(hasParent(arraySubscriptExpr())),
	has(maybeEvalCommaExpr(equalsNode(Exp))));
	// Treat calling `operator->()` of move-only classes as taking address.
	// These are typically smart pointers with unique ownership so we treat
	// mutation of pointee as mutation of the smart pointer itself.
	const auto AsOperatorArrowThis =
	cxxOperatorCallExpr(hasOverloadedOperatorName("->"),
	callee(cxxMethodDecl(ofClass(isMoveOnly()),
	returns(nonConstPointerType()))),
	argumentCountIs(1),
	hasArgument(0, maybeEvalCommaExpr(equalsNode(Exp))));

	// Used as non-const-ref argument when calling a function.
	// An argument is assumed to be non-const-ref when the function is unresolved.
	// Instantiated template functions are not handled here but in
	// findFunctionArgMutation which has additional smarts for handling forwarding
	// references.
	const auto NonConstRefParam = forEachArgumentWithParam(
	maybeEvalCommaExpr(equalsNode(Exp)),
	parmVarDecl(hasType(nonConstReferenceType())));
	const auto NotInstantiated = unless(hasDeclaration(isInstantiated()));
	const auto AsNonConstRefArg = anyOf(
	callExpr(NonConstRefParam, NotInstantiated),
	cxxConstructExpr(NonConstRefParam, NotInstantiated),
	callExpr(callee(expr(anyOf(unresolvedLookupExpr(), unresolvedMemberExpr(),
	cxxDependentScopeMemberExpr(),
	hasType(templateTypeParmType())))),
	hasAnyArgument(maybeEvalCommaExpr(equalsNode(Exp)))),
	cxxUnresolvedConstructExpr(hasAnyArgument(maybeEvalCommaExpr(equalsNode(Exp)))));

	// Captured by a lambda by reference.
	// If we're initializing a capture with 'Exp' directly then we're initializing
	// a reference capture.
	// For value captures there will be an ImplicitCastExpr <LValueToRValue>.
	const auto AsLambdaRefCaptureInit = lambdaExpr(hasCaptureInit(Exp));

	// Returned as non-const-ref.
	// If we're returning 'Exp' directly then it's returned as non-const-ref.
	// For returning by value there will be an ImplicitCastExpr <LValueToRValue>.
	// For returning by const-ref there will be an ImplicitCastExpr <NoOp> (for
	// adding const.)
	const auto AsNonConstRefReturn = returnStmt(hasReturnValue(
	maybeEvalCommaExpr(equalsNode(Exp))));

	const auto Matches =
	match(findAll(stmt(anyOf(AsAssignmentLhs, AsIncDecOperand, AsNonConstThis,
	AsAmpersandOperand, AsPointerFromArrayDecay,
	AsOperatorArrowThis, AsNonConstRefArg,
	AsLambdaRefCaptureInit, AsNonConstRefReturn))
	.bind("stmt")),
	Stm, Context);
	return selectFirst<Stmt>("stmt", Matches);
	}

	const Stmt ExprMutationAnalyzer::findMemberMutation(const Expr Exp) {
	// Check whether any member of 'Exp' is mutated.
	const auto MemberExprs =
	match(findAll(expr(anyOf(memberExpr(hasObjectExpression(equalsNode(Exp))),
	cxxDependentScopeMemberExpr(
	hasObjectExpression(equalsNode(Exp)))))
	.bind(NodeID<Expr>::value)),
	Stm, Context);
	return findExprMutation(MemberExprs);
	}

	const Stmt ExprMutationAnalyzer::findArrayElementMutation(const Expr Exp) {
	// Check whether any element of an array is mutated.
	const auto SubscriptExprs = match(
	findAll(arraySubscriptExpr(hasBase(ignoringImpCasts(equalsNode(Exp))))
	.bind(NodeID<Expr>::value)),
	Stm, Context);
	return findExprMutation(SubscriptExprs);
	}

	const Stmt ExprMutationAnalyzer::findCastMutation(const Expr Exp) {
	// If 'Exp' is casted to any non-const reference type, check the castExpr.
	const auto Casts =
	match(findAll(castExpr(hasSourceExpression(equalsNode(Exp)),
	anyOf(explicitCastExpr(hasDestinationType(
	nonConstReferenceType())),
	implicitCastExpr(hasImplicitDestinationType(
	nonConstReferenceType()))))
	.bind(NodeID<Expr>::value)),
	Stm, Context);
	if (const Stmt *S = findExprMutation(Casts))
	return S;
	// Treat std::{move,forward} as cast.
	const auto Calls =
	match(findAll(callExpr(callee(namedDecl(
	hasAnyName("::std::move", "::std::forward"))),
	hasArgument(0, equalsNode(Exp)))
	.bind("expr")),
	Stm, Context);
	return findExprMutation(Calls);
	}

	const Stmt ExprMutationAnalyzer::findRangeLoopMutation(const Expr Exp) {
	// If range for looping over 'Exp' with a non-const reference loop variable,
	// check all declRefExpr of the loop variable.
	const auto LoopVars =
	match(findAll(cxxForRangeStmt(
	hasLoopVariable(varDecl(hasType(nonConstReferenceType()))
	.bind(NodeID<Decl>::value)),
	hasRangeInit(equalsNode(Exp)))),
	Stm, Context);
	return findDeclMutation(LoopVars);
	}

	const Stmt ExprMutationAnalyzer::findReferenceMutation(const Expr Exp) {
	// Follow non-const reference returned by `operator*()` of move-only classes.
	// These are typically smart pointers with unique ownership so we treat
	// mutation of pointee as mutation of the smart pointer itself.
	const auto Ref =
	match(findAll(cxxOperatorCallExpr(
	hasOverloadedOperatorName("*"),
	callee(cxxMethodDecl(ofClass(isMoveOnly()),
	returns(nonConstReferenceType()))),
	argumentCountIs(1), hasArgument(0, equalsNode(Exp)))
	.bind(NodeID<Expr>::value)),
	Stm, Context);
	if (const Stmt *S = findExprMutation(Ref))
	return S;

	// If 'Exp' is bound to a non-const reference, check all declRefExpr to that.
	const auto Refs = match(
	stmt(forEachDescendant(
	varDecl(
	hasType(nonConstReferenceType()),
	hasInitializer(anyOf(equalsNode(Exp),
	conditionalOperator(anyOf(
	hasTrueExpression(equalsNode(Exp)),
	hasFalseExpression(equalsNode(Exp)))))),
	hasParent(declStmt().bind("stmt")),
	// Don't follow the reference in range statement, we've handled
	// that separately.
	unless(hasParent(declStmt(hasParent(
	cxxForRangeStmt(hasRangeStmt(equalsBoundNode("stmt"))))))))
	.bind(NodeID<Decl>::value))),
	Stm, Context);
	return findDeclMutation(Refs);
	}

	const Stmt ExprMutationAnalyzer::findFunctionArgMutation(const Expr Exp) {
	const auto NonConstRefParam = forEachArgumentWithParam(
	equalsNode(Exp),
	parmVarDecl(hasType(nonConstReferenceType())).bind("parm"));
	const auto IsInstantiated = hasDeclaration(isInstantiated());
	const auto FuncDecl = hasDeclaration(functionDecl().bind("func"));
	const auto Matches = match(
	findAll(expr(anyOf(callExpr(NonConstRefParam, IsInstantiated, FuncDecl,
	unless(callee(namedDecl(hasAnyName(
	"::std::move", "::std::forward"))))),
	cxxConstructExpr(NonConstRefParam, IsInstantiated,
	FuncDecl)))
	.bind(NodeID<Expr>::value)),
	Stm, Context);
	for (const auto &Nodes : Matches) {
	const auto *Exp = Nodes.getNodeAs<Expr>(NodeID<Expr>::value);
	const auto *Func = Nodes.getNodeAs<FunctionDecl>("func");
	if (!Func->getBody() \|\| !Func->getPrimaryTemplate())
	return Exp;

	const auto *Parm = Nodes.getNodeAs<ParmVarDecl>("parm");
	const ArrayRef<ParmVarDecl *> AllParams =
	Func->getPrimaryTemplate()->getTemplatedDecl()->parameters();
	QualType ParmType =
	AllParams[std::min<size_t>(Parm->getFunctionScopeIndex(),
	AllParams.size() - 1)]
	->getType();
	if (const auto *T = ParmType->getAs<PackExpansionType>())
	ParmType = T->getPattern();

	// If param type is forwarding reference, follow into the function
	// definition and see whether the param is mutated inside.
	if (const auto *RefType = ParmType->getAs<RValueReferenceType>()) {
	if (!RefType->getPointeeType().getQualifiers() &&
	RefType->getPointeeType()->getAs<TemplateTypeParmType>()) {
	std::unique_ptr<FunctionParmMutationAnalyzer> &Analyzer =
	FuncParmAnalyzer[Func];
	if (!Analyzer)
	Analyzer.reset(new FunctionParmMutationAnalyzer(*Func, Context));
	if (Analyzer->findMutation(Parm))
	return Exp;
	continue;
	}
	}
	// Not forwarding reference.
	return Exp;
	}
	return nullptr;
	}

	FunctionParmMutationAnalyzer::FunctionParmMutationAnalyzer(
	const FunctionDecl &Func, ASTContext &Context)
	: BodyAnalyzer(*Func.getBody(), Context) {
	if (const auto *Ctor = dyn_cast<CXXConstructorDecl>(&Func)) {
	// CXXCtorInitializer might also mutate Param but they're not part of
	// function body, check them eagerly here since they're typically trivial.
	for (const CXXCtorInitializer *Init : Ctor->inits()) {
	ExprMutationAnalyzer InitAnalyzer(*Init->getInit(), Context);
	for (const ParmVarDecl *Parm : Ctor->parameters()) {
	if (Results.find(Parm) != Results.end())
	continue;
	if (const Stmt *S = InitAnalyzer.findMutation(Parm))
	Results[Parm] = S;
	}
	}
	}
	}

	const Stmt *
	FunctionParmMutationAnalyzer::findMutation(const ParmVarDecl *Parm) {
	const auto Memoized = Results.find(Parm);
	if (Memoized != Results.end())
	return Memoized->second;

	if (const Stmt *S = BodyAnalyzer.findMutation(Parm))
	return Results[Parm] = S;

	return Results[Parm] = nullptr;
	}

	} // namespace clang