clang/lib/Tooling/Transformer/RewriteRule.cpp - rust-lang/llvm-project - Git at Google

 //===--- Transformer.cpp - Transformer library implementation ---*- C++ -*-===//
 //
 // 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/Tooling/Transformer/RewriteRule.h"
 #include "clang/AST/ASTTypeTraits.h"
 #include "clang/AST/Stmt.h"
 #include "clang/ASTMatchers/ASTMatchFinder.h"
 #include "clang/ASTMatchers/ASTMatchers.h"
 #include "clang/Basic/SourceLocation.h"
 #include "clang/Tooling/Transformer/SourceCode.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Errc.h"
 #include "llvm/Support/Error.h"
 #include <map>
 #include <string>
 #include <utility>
 #include <vector>

 using namespace clang;
 using namespace transformer;

 using ast_matchers::MatchFinder;
 using ast_matchers::internal::DynTypedMatcher;

 using MatchResult = MatchFinder::MatchResult;

 const char transformer::RootID[] = "___root___";

 static Expected<SmallVector<transformer::Edit, 1>>
 translateEdits(const MatchResult &Result, ArrayRef<ASTEdit> ASTEdits) {
   SmallVector<transformer::Edit, 1> Edits;
   for (const auto &E : ASTEdits) {
     Expected<CharSourceRange> Range = E.TargetRange(Result);
     if (!Range)
       return Range.takeError();
     std::optional<CharSourceRange> EditRange =
         tooling::getFileRangeForEdit(*Range, *Result.Context);
     // FIXME: let user specify whether to treat this case as an error or ignore
     // it as is currently done. This behavior is problematic in that it hides
     // failures from bad ranges. Also, the behavior here differs from
     // `flatten`. Here, we abort (without error), whereas flatten, if it hits an
     // empty list, does not abort. As a result, `editList({A,B})` is not
     // equivalent to `flatten(edit(A), edit(B))`. The former will abort if `A`
     // produces a bad range, whereas the latter will simply ignore A.
     if (!EditRange)
       return SmallVector<Edit, 0>();
     transformer::Edit T;
     T.Kind = E.Kind;
     T.Range = *EditRange;
     if (E.Replacement) {
       auto Replacement = E.Replacement->eval(Result);
       if (!Replacement)
         return Replacement.takeError();
       T.Replacement = std::move(*Replacement);
     }
     if (E.Note) {
       auto Note = E.Note->eval(Result);
       if (!Note)
         return Note.takeError();
       T.Note = std::move(*Note);
     }
     if (E.Metadata) {
       auto Metadata = E.Metadata(Result);
       if (!Metadata)
         return Metadata.takeError();
       T.Metadata = std::move(*Metadata);
     }
     Edits.push_back(std::move(T));
   }
   return Edits;
 }

 EditGenerator transformer::editList(SmallVector<ASTEdit, 1> Edits) {
   return [Edits = std::move(Edits)](const MatchResult &Result) {
     return translateEdits(Result, Edits);
   };
 }

 EditGenerator transformer::edit(ASTEdit Edit) {
   return [Edit = std::move(Edit)](const MatchResult &Result) {
     return translateEdits(Result, {Edit});
   };
 }

 EditGenerator transformer::noopEdit(RangeSelector Anchor) {
   return [Anchor = std::move(Anchor)](const MatchResult &Result)
              -> Expected<SmallVector<transformer::Edit, 1>> {
     Expected<CharSourceRange> Range = Anchor(Result);
     if (!Range)
       return Range.takeError();
     // In case the range is inside a macro expansion, map the location back to a
     // "real" source location.
     SourceLocation Begin =
         Result.SourceManager->getSpellingLoc(Range->getBegin());
     Edit E;
     // Implicitly, leave `E.Replacement` as the empty string.
     E.Kind = EditKind::Range;
     E.Range = CharSourceRange::getCharRange(Begin, Begin);
     return SmallVector<Edit, 1>{E};
   };
 }

 EditGenerator
 transformer::flattenVector(SmallVector<EditGenerator, 2> Generators) {
   if (Generators.size() == 1)
     return std::move(Generators[0]);
   return
       [Gs = std::move(Generators)](
           const MatchResult &Result) -> llvm::Expected<SmallVector<Edit, 1>> {
         SmallVector<Edit, 1> AllEdits;
         for (const auto &G : Gs) {
           llvm::Expected<SmallVector<Edit, 1>> Edits = G(Result);
           if (!Edits)
             return Edits.takeError();
           AllEdits.append(Edits->begin(), Edits->end());
         }
         return AllEdits;
       };
 }

 ASTEdit transformer::changeTo(RangeSelector Target, TextGenerator Replacement) {
   ASTEdit E;
   E.TargetRange = std::move(Target);
   E.Replacement = std::move(Replacement);
   return E;
 }

 ASTEdit transformer::note(RangeSelector Anchor, TextGenerator Note) {
   ASTEdit E;
   E.TargetRange = transformer::before(Anchor);
   E.Note = std::move(Note);
   return E;
 }

 namespace {
 /// A \c TextGenerator that always returns a fixed string.
 class SimpleTextGenerator : public MatchComputation<std::string> {
   std::string S;

 public:
   SimpleTextGenerator(std::string S) : S(std::move(S)) {}
   llvm::Error eval(const ast_matchers::MatchFinder::MatchResult &,
                    std::string *Result) const override {
     Result->append(S);
     return llvm::Error::success();
   }
   std::string toString() const override {
     return (llvm::Twine("text(\"") + S + "\")").str();
   }
 };
 } // namespace

 static TextGenerator makeText(std::string S) {
   return std::make_shared<SimpleTextGenerator>(std::move(S));
 }

 ASTEdit transformer::remove(RangeSelector S) {
   return change(std::move(S), makeText(""));
 }

 static std::string formatHeaderPath(StringRef Header, IncludeFormat Format) {
   switch (Format) {
   case transformer::IncludeFormat::Quoted:
     return Header.str();
   case transformer::IncludeFormat::Angled:
     return ("<" + Header + ">").str();
   }
   llvm_unreachable("Unknown transformer::IncludeFormat enum");
 }

 ASTEdit transformer::addInclude(RangeSelector Target, StringRef Header,
                                 IncludeFormat Format) {
   ASTEdit E;
   E.Kind = EditKind::AddInclude;
   E.TargetRange = Target;
   E.Replacement = makeText(formatHeaderPath(Header, Format));
   return E;
 }

 EditGenerator
 transformer::detail::makeEditGenerator(llvm::SmallVector<ASTEdit, 1> Edits) {
   return editList(std::move(Edits));
 }

 EditGenerator transformer::detail::makeEditGenerator(ASTEdit Edit) {
   return edit(std::move(Edit));
 }

 RewriteRule transformer::detail::makeRule(DynTypedMatcher M,
                                           EditGenerator Edits) {
   RewriteRule R;
   R.Cases = {{std::move(M), std::move(Edits)}};
   return R;
 }

 RewriteRule transformer::makeRule(ast_matchers::internal::DynTypedMatcher M,
                                   std::initializer_list<ASTEdit> Edits) {
   return detail::makeRule(std::move(M),
                           detail::makeEditGenerator(std::move(Edits)));
 }

 namespace {

 /// Unconditionally binds the given node set before trying `InnerMatcher` and
 /// keeps the bound nodes on a successful match.
 template <typename T>
 class BindingsMatcher : public ast_matchers::internal::MatcherInterface<T> {
   ast_matchers::BoundNodes Nodes;
   const ast_matchers::internal::Matcher<T> InnerMatcher;

 public:
   explicit BindingsMatcher(ast_matchers::BoundNodes Nodes,
                            ast_matchers::internal::Matcher<T> InnerMatcher)
       : Nodes(std::move(Nodes)), InnerMatcher(std::move(InnerMatcher)) {}

   bool matches(
       const T &Node, ast_matchers::internal::ASTMatchFinder *Finder,
       ast_matchers::internal::BoundNodesTreeBuilder *Builder) const override {
     ast_matchers::internal::BoundNodesTreeBuilder Result(*Builder);
     for (const auto &N : Nodes.getMap())
       Result.setBinding(N.first, N.second);
     if (InnerMatcher.matches(Node, Finder, &Result)) {
       *Builder = std::move(Result);
       return true;
     }
     return false;
   }
 };

 /// Matches nodes of type T that have at least one descendant node for which the
 /// given inner matcher matches.  Will match for each descendant node that
 /// matches.  Based on ForEachDescendantMatcher, but takes a dynamic matcher,
 /// instead of a static one, because it is used by RewriteRule, which carries
 /// (only top-level) dynamic matchers.
 template <typename T>
 class DynamicForEachDescendantMatcher
     : public ast_matchers::internal::MatcherInterface<T> {
   const DynTypedMatcher DescendantMatcher;

 public:
   explicit DynamicForEachDescendantMatcher(DynTypedMatcher DescendantMatcher)
       : DescendantMatcher(std::move(DescendantMatcher)) {}

   bool matches(
       const T &Node, ast_matchers::internal::ASTMatchFinder *Finder,
       ast_matchers::internal::BoundNodesTreeBuilder *Builder) const override {
     return Finder->matchesDescendantOf(
         Node, this->DescendantMatcher, Builder,
         ast_matchers::internal::ASTMatchFinder::BK_All);
   }
 };

 template <typename T>
 ast_matchers::internal::Matcher<T>
 forEachDescendantDynamically(ast_matchers::BoundNodes Nodes,
                              DynTypedMatcher M) {
   return ast_matchers::internal::makeMatcher(new BindingsMatcher<T>(
       std::move(Nodes),
       ast_matchers::internal::makeMatcher(
           new DynamicForEachDescendantMatcher<T>(std::move(M)))));
 }

 class ApplyRuleCallback : public MatchFinder::MatchCallback {
 public:
   ApplyRuleCallback(RewriteRule Rule) : Rule(std::move(Rule)) {}

   template <typename T>
   void registerMatchers(const ast_matchers::BoundNodes &Nodes,
                         MatchFinder *MF) {
     for (auto &Matcher : transformer::detail::buildMatchers(Rule))
       MF->addMatcher(forEachDescendantDynamically<T>(Nodes, Matcher), this);
   }

   void run(const MatchFinder::MatchResult &Result) override {
     if (!Edits)
       return;
     size_t I = transformer::detail::findSelectedCase(Result, Rule);
     auto Transformations = Rule.Cases[I].Edits(Result);
     if (!Transformations) {
       Edits = Transformations.takeError();
       return;
     }
     Edits->append(Transformations->begin(), Transformations->end());
   }

   RewriteRule Rule;

   // Initialize to a non-error state.
   Expected<SmallVector<Edit, 1>> Edits = SmallVector<Edit, 1>();
 };
 } // namespace

 template <typename T>
 llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
 rewriteDescendantsImpl(const T &Node, RewriteRule Rule,
                        const MatchResult &Result) {
   ApplyRuleCallback Callback(std::move(Rule));
   MatchFinder Finder;
   Callback.registerMatchers<T>(Result.Nodes, &Finder);
   Finder.match(Node, *Result.Context);
   return std::move(Callback.Edits);
 }

 llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
 transformer::detail::rewriteDescendants(const Decl &Node, RewriteRule Rule,
                                         const MatchResult &Result) {
   return rewriteDescendantsImpl(Node, std::move(Rule), Result);
 }

 llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
 transformer::detail::rewriteDescendants(const Stmt &Node, RewriteRule Rule,
                                         const MatchResult &Result) {
   return rewriteDescendantsImpl(Node, std::move(Rule), Result);
 }

 llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
 transformer::detail::rewriteDescendants(const TypeLoc &Node, RewriteRule Rule,
                                         const MatchResult &Result) {
   return rewriteDescendantsImpl(Node, std::move(Rule), Result);
 }

 llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
 transformer::detail::rewriteDescendants(const DynTypedNode &DNode,
                                         RewriteRule Rule,
                                         const MatchResult &Result) {
   if (const auto *Node = DNode.get<Decl>())
     return rewriteDescendantsImpl(*Node, std::move(Rule), Result);
   if (const auto *Node = DNode.get<Stmt>())
     return rewriteDescendantsImpl(*Node, std::move(Rule), Result);
   if (const auto *Node = DNode.get<TypeLoc>())
     return rewriteDescendantsImpl(*Node, std::move(Rule), Result);

   return llvm::make_error<llvm::StringError>(
       llvm::errc::invalid_argument,
       "type unsupported for recursive rewriting, Kind=" +
           DNode.getNodeKind().asStringRef());
 }

 EditGenerator transformer::rewriteDescendants(std::string NodeId,
                                               RewriteRule Rule) {
   return [NodeId = std::move(NodeId),
           Rule = std::move(Rule)](const MatchResult &Result)
              -> llvm::Expected<SmallVector<clang::transformer::Edit, 1>> {
     const ast_matchers::BoundNodes::IDToNodeMap &NodesMap =
         Result.Nodes.getMap();
     auto It = NodesMap.find(NodeId);
     if (It == NodesMap.end())
       return llvm::make_error<llvm::StringError>(llvm::errc::invalid_argument,
                                                  "ID not bound: " + NodeId);
     return detail::rewriteDescendants(It->second, std::move(Rule), Result);
   };
 }

 void transformer::addInclude(RewriteRuleBase &Rule, StringRef Header,
                              IncludeFormat Format) {
   for (auto &Case : Rule.Cases)
     Case.Edits = flatten(std::move(Case.Edits), addInclude(Header, Format));
 }

 #ifndef NDEBUG
 // Filters for supported matcher kinds. FIXME: Explicitly list the allowed kinds
 // (all node matcher types except for `QualType` and `Type`), rather than just
 // banning `QualType` and `Type`.
 static bool hasValidKind(const DynTypedMatcher &M) {
   return !M.canConvertTo<QualType>();
 }
 #endif

 // Binds each rule's matcher to a unique (and deterministic) tag based on
 // `TagBase` and the id paired with the case. All of the returned matchers have
 // their traversal kind explicitly set, either based on a pre-set kind or to the
 // provided `DefaultTraversalKind`.
 static std::vector<DynTypedMatcher> taggedMatchers(
     StringRef TagBase,
     const SmallVectorImpl<std::pair<size_t, RewriteRule::Case>> &Cases,
     TraversalKind DefaultTraversalKind) {
   std::vector<DynTypedMatcher> Matchers;
   Matchers.reserve(Cases.size());
   for (const auto &Case : Cases) {
     std::string Tag = (TagBase + Twine(Case.first)).str();
     // HACK: Many matchers are not bindable, so ensure that tryBind will work.
     DynTypedMatcher BoundMatcher(Case.second.Matcher);
     BoundMatcher.setAllowBind(true);
     auto M = *BoundMatcher.tryBind(Tag);
     Matchers.push_back(!M.getTraversalKind()
                            ? M.withTraversalKind(DefaultTraversalKind)
                            : std::move(M));
   }
   return Matchers;
 }

 // Simply gathers the contents of the various rules into a single rule. The
 // actual work to combine these into an ordered choice is deferred to matcher
 // registration.
 template <>
 RewriteRuleWith<void>
 transformer::applyFirst(ArrayRef<RewriteRuleWith<void>> Rules) {
   RewriteRule R;
   for (auto &Rule : Rules)
     R.Cases.append(Rule.Cases.begin(), Rule.Cases.end());
   return R;
 }

 std::vector<DynTypedMatcher>
 transformer::detail::buildMatchers(const RewriteRuleBase &Rule) {
   // Map the cases into buckets of matchers -- one for each "root" AST kind,
   // which guarantees that they can be combined in a single anyOf matcher. Each
   // case is paired with an identifying number that is converted to a string id
   // in `taggedMatchers`.
   std::map<ASTNodeKind,
            SmallVector<std::pair<size_t, RewriteRuleBase::Case>, 1>>
       Buckets;
   const SmallVectorImpl<RewriteRule::Case> &Cases = Rule.Cases;
   for (int I = 0, N = Cases.size(); I < N; ++I) {
     assert(hasValidKind(Cases[I].Matcher) &&
            "Matcher must be non-(Qual)Type node matcher");
     Buckets[Cases[I].Matcher.getSupportedKind()].emplace_back(I, Cases[I]);
   }

   // Each anyOf explicitly controls the traversal kind. The anyOf itself is set
   // to `TK_AsIs` to ensure no nodes are skipped, thereby deferring to the kind
   // of the branches. Then, each branch is either left as is, if the kind is
   // already set, or explicitly set to `TK_AsIs`. We choose this setting because
   // it is the default interpretation of matchers.
   std::vector<DynTypedMatcher> Matchers;
   for (const auto &Bucket : Buckets) {
     DynTypedMatcher M = DynTypedMatcher::constructVariadic(
         DynTypedMatcher::VO_AnyOf, Bucket.first,
         taggedMatchers("Tag", Bucket.second, TK_AsIs));
     M.setAllowBind(true);
     // `tryBind` is guaranteed to succeed, because `AllowBind` was set to true.
     Matchers.push_back(M.tryBind(RootID)->withTraversalKind(TK_AsIs));
   }
   return Matchers;
 }

 DynTypedMatcher transformer::detail::buildMatcher(const RewriteRuleBase &Rule) {
   std::vector<DynTypedMatcher> Ms = buildMatchers(Rule);
   assert(Ms.size() == 1 && "Cases must have compatible matchers.");
   return Ms[0];
 }

 SourceLocation transformer::detail::getRuleMatchLoc(const MatchResult &Result) {
   auto &NodesMap = Result.Nodes.getMap();
   auto Root = NodesMap.find(RootID);
   assert(Root != NodesMap.end() && "Transformation failed: missing root node.");
   std::optional<CharSourceRange> RootRange = tooling::getFileRangeForEdit(
       CharSourceRange::getTokenRange(Root->second.getSourceRange()),
       *Result.Context);
   if (RootRange)
     return RootRange->getBegin();
   // The match doesn't have a coherent range, so fall back to the expansion
   // location as the "beginning" of the match.
   return Result.SourceManager->getExpansionLoc(
       Root->second.getSourceRange().getBegin());
 }

 // Finds the case that was "selected" -- that is, whose matcher triggered the
 // `MatchResult`.
 size_t transformer::detail::findSelectedCase(const MatchResult &Result,
                                              const RewriteRuleBase &Rule) {
   if (Rule.Cases.size() == 1)
     return 0;

   auto &NodesMap = Result.Nodes.getMap();
   for (size_t i = 0, N = Rule.Cases.size(); i < N; ++i) {
     std::string Tag = ("Tag" + Twine(i)).str();
     if (NodesMap.find(Tag) != NodesMap.end())
       return i;
   }
   llvm_unreachable("No tag found for this rule.");
 }
	//===--- Transformer.cpp - Transformer library implementation ---- C++ --===//
	//
	// 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/Tooling/Transformer/RewriteRule.h"
	#include "clang/AST/ASTTypeTraits.h"
	#include "clang/AST/Stmt.h"
	#include "clang/ASTMatchers/ASTMatchFinder.h"
	#include "clang/ASTMatchers/ASTMatchers.h"
	#include "clang/Basic/SourceLocation.h"
	#include "clang/Tooling/Transformer/SourceCode.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Errc.h"
	#include "llvm/Support/Error.h"
	#include <map>
	#include <string>
	#include <utility>
	#include <vector>

	using namespace clang;
	using namespace transformer;

	using ast_matchers::MatchFinder;
	using ast_matchers::internal::DynTypedMatcher;

	using MatchResult = MatchFinder::MatchResult;

	const char transformer::RootID[] = "___root___";

	static Expected<SmallVector<transformer::Edit, 1>>
	translateEdits(const MatchResult &Result, ArrayRef<ASTEdit> ASTEdits) {
	SmallVector<transformer::Edit, 1> Edits;
	for (const auto &E : ASTEdits) {
	Expected<CharSourceRange> Range = E.TargetRange(Result);
	if (!Range)
	return Range.takeError();
	std::optional<CharSourceRange> EditRange =
	tooling::getFileRangeForEdit(Range, Result.Context);
	// FIXME: let user specify whether to treat this case as an error or ignore
	// it as is currently done. This behavior is problematic in that it hides
	// failures from bad ranges. Also, the behavior here differs from
	// `flatten`. Here, we abort (without error), whereas flatten, if it hits an
	// empty list, does not abort. As a result, `editList({A,B})` is not
	// equivalent to `flatten(edit(A), edit(B))`. The former will abort if `A`
	// produces a bad range, whereas the latter will simply ignore A.
	if (!EditRange)
	return SmallVector<Edit, 0>();
	transformer::Edit T;
	T.Kind = E.Kind;
	T.Range = *EditRange;
	if (E.Replacement) {
	auto Replacement = E.Replacement->eval(Result);
	if (!Replacement)
	return Replacement.takeError();
	T.Replacement = std::move(*Replacement);
	}
	if (E.Note) {
	auto Note = E.Note->eval(Result);
	if (!Note)
	return Note.takeError();
	T.Note = std::move(*Note);
	}
	if (E.Metadata) {
	auto Metadata = E.Metadata(Result);
	if (!Metadata)
	return Metadata.takeError();
	T.Metadata = std::move(*Metadata);
	}
	Edits.push_back(std::move(T));
	}
	return Edits;
	}

	EditGenerator transformer::editList(SmallVector<ASTEdit, 1> Edits) {
	return [Edits = std::move(Edits)](const MatchResult &Result) {
	return translateEdits(Result, Edits);
	};
	}

	EditGenerator transformer::edit(ASTEdit Edit) {
	return [Edit = std::move(Edit)](const MatchResult &Result) {
	return translateEdits(Result, {Edit});
	};
	}

	EditGenerator transformer::noopEdit(RangeSelector Anchor) {
	return [Anchor = std::move(Anchor)](const MatchResult &Result)
	-> Expected<SmallVector<transformer::Edit, 1>> {
	Expected<CharSourceRange> Range = Anchor(Result);
	if (!Range)
	return Range.takeError();
	// In case the range is inside a macro expansion, map the location back to a
	// "real" source location.
	SourceLocation Begin =
	Result.SourceManager->getSpellingLoc(Range->getBegin());
	Edit E;
	// Implicitly, leave `E.Replacement` as the empty string.
	E.Kind = EditKind::Range;
	E.Range = CharSourceRange::getCharRange(Begin, Begin);
	return SmallVector<Edit, 1>{E};
	};
	}

	EditGenerator
	transformer::flattenVector(SmallVector<EditGenerator, 2> Generators) {
	if (Generators.size() == 1)
	return std::move(Generators[0]);
	return
	[Gs = std::move(Generators)](
	const MatchResult &Result) -> llvm::Expected<SmallVector<Edit, 1>> {
	SmallVector<Edit, 1> AllEdits;
	for (const auto &G : Gs) {
	llvm::Expected<SmallVector<Edit, 1>> Edits = G(Result);
	if (!Edits)
	return Edits.takeError();
	AllEdits.append(Edits->begin(), Edits->end());
	}
	return AllEdits;
	};
	}

	ASTEdit transformer::changeTo(RangeSelector Target, TextGenerator Replacement) {
	ASTEdit E;
	E.TargetRange = std::move(Target);
	E.Replacement = std::move(Replacement);
	return E;
	}

	ASTEdit transformer::note(RangeSelector Anchor, TextGenerator Note) {
	ASTEdit E;
	E.TargetRange = transformer::before(Anchor);
	E.Note = std::move(Note);
	return E;
	}

	namespace {
	/// A \c TextGenerator that always returns a fixed string.
	class SimpleTextGenerator : public MatchComputation<std::string> {
	std::string S;

	public:
	SimpleTextGenerator(std::string S) : S(std::move(S)) {}
	llvm::Error eval(const ast_matchers::MatchFinder::MatchResult &,
	std::string *Result) const override {
	Result->append(S);
	return llvm::Error::success();
	}
	std::string toString() const override {
	return (llvm::Twine("text(\"") + S + "\")").str();
	}
	};
	} // namespace

	static TextGenerator makeText(std::string S) {
	return std::make_shared<SimpleTextGenerator>(std::move(S));
	}

	ASTEdit transformer::remove(RangeSelector S) {
	return change(std::move(S), makeText(""));
	}

	static std::string formatHeaderPath(StringRef Header, IncludeFormat Format) {
	switch (Format) {
	case transformer::IncludeFormat::Quoted:
	return Header.str();
	case transformer::IncludeFormat::Angled:
	return ("<" + Header + ">").str();
	}
	llvm_unreachable("Unknown transformer::IncludeFormat enum");
	}

	ASTEdit transformer::addInclude(RangeSelector Target, StringRef Header,
	IncludeFormat Format) {
	ASTEdit E;
	E.Kind = EditKind::AddInclude;
	E.TargetRange = Target;
	E.Replacement = makeText(formatHeaderPath(Header, Format));
	return E;
	}

	EditGenerator
	transformer::detail::makeEditGenerator(llvm::SmallVector<ASTEdit, 1> Edits) {
	return editList(std::move(Edits));
	}

	EditGenerator transformer::detail::makeEditGenerator(ASTEdit Edit) {
	return edit(std::move(Edit));
	}

	RewriteRule transformer::detail::makeRule(DynTypedMatcher M,
	EditGenerator Edits) {
	RewriteRule R;
	R.Cases = {{std::move(M), std::move(Edits)}};
	return R;
	}

	RewriteRule transformer::makeRule(ast_matchers::internal::DynTypedMatcher M,
	std::initializer_list<ASTEdit> Edits) {
	return detail::makeRule(std::move(M),
	detail::makeEditGenerator(std::move(Edits)));
	}

	namespace {

	/// Unconditionally binds the given node set before trying `InnerMatcher` and
	/// keeps the bound nodes on a successful match.
	template <typename T>
	class BindingsMatcher : public ast_matchers::internal::MatcherInterface<T> {
	ast_matchers::BoundNodes Nodes;
	const ast_matchers::internal::Matcher<T> InnerMatcher;

	public:
	explicit BindingsMatcher(ast_matchers::BoundNodes Nodes,
	ast_matchers::internal::Matcher<T> InnerMatcher)
	: Nodes(std::move(Nodes)), InnerMatcher(std::move(InnerMatcher)) {}

	bool matches(
	const T &Node, ast_matchers::internal::ASTMatchFinder *Finder,
	ast_matchers::internal::BoundNodesTreeBuilder *Builder) const override {
	ast_matchers::internal::BoundNodesTreeBuilder Result(*Builder);
	for (const auto &N : Nodes.getMap())
	Result.setBinding(N.first, N.second);
	if (InnerMatcher.matches(Node, Finder, &Result)) {
	*Builder = std::move(Result);
	return true;
	}
	return false;
	}
	};

	/// Matches nodes of type T that have at least one descendant node for which the
	/// given inner matcher matches. Will match for each descendant node that
	/// matches. Based on ForEachDescendantMatcher, but takes a dynamic matcher,
	/// instead of a static one, because it is used by RewriteRule, which carries
	/// (only top-level) dynamic matchers.
	template <typename T>
	class DynamicForEachDescendantMatcher
	: public ast_matchers::internal::MatcherInterface<T> {
	const DynTypedMatcher DescendantMatcher;

	public:
	explicit DynamicForEachDescendantMatcher(DynTypedMatcher DescendantMatcher)
	: DescendantMatcher(std::move(DescendantMatcher)) {}

	bool matches(
	const T &Node, ast_matchers::internal::ASTMatchFinder *Finder,
	ast_matchers::internal::BoundNodesTreeBuilder *Builder) const override {
	return Finder->matchesDescendantOf(
	Node, this->DescendantMatcher, Builder,
	ast_matchers::internal::ASTMatchFinder::BK_All);
	}
	};

	template <typename T>
	ast_matchers::internal::Matcher<T>
	forEachDescendantDynamically(ast_matchers::BoundNodes Nodes,
	DynTypedMatcher M) {
	return ast_matchers::internal::makeMatcher(new BindingsMatcher<T>(
	std::move(Nodes),
	ast_matchers::internal::makeMatcher(
	new DynamicForEachDescendantMatcher<T>(std::move(M)))));
	}

	class ApplyRuleCallback : public MatchFinder::MatchCallback {
	public:
	ApplyRuleCallback(RewriteRule Rule) : Rule(std::move(Rule)) {}

	template <typename T>
	void registerMatchers(const ast_matchers::BoundNodes &Nodes,
	MatchFinder *MF) {
	for (auto &Matcher : transformer::detail::buildMatchers(Rule))
	MF->addMatcher(forEachDescendantDynamically<T>(Nodes, Matcher), this);
	}

	void run(const MatchFinder::MatchResult &Result) override {
	if (!Edits)
	return;
	size_t I = transformer::detail::findSelectedCase(Result, Rule);
	auto Transformations = Rule.Cases[I].Edits(Result);
	if (!Transformations) {
	Edits = Transformations.takeError();
	return;
	}
	Edits->append(Transformations->begin(), Transformations->end());
	}

	RewriteRule Rule;

	// Initialize to a non-error state.
	Expected<SmallVector<Edit, 1>> Edits = SmallVector<Edit, 1>();
	};
	} // namespace

	template <typename T>
	llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
	rewriteDescendantsImpl(const T &Node, RewriteRule Rule,
	const MatchResult &Result) {
	ApplyRuleCallback Callback(std::move(Rule));
	MatchFinder Finder;
	Callback.registerMatchers<T>(Result.Nodes, &Finder);
	Finder.match(Node, *Result.Context);
	return std::move(Callback.Edits);
	}

	llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
	transformer::detail::rewriteDescendants(const Decl &Node, RewriteRule Rule,
	const MatchResult &Result) {
	return rewriteDescendantsImpl(Node, std::move(Rule), Result);
	}

	llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
	transformer::detail::rewriteDescendants(const Stmt &Node, RewriteRule Rule,
	const MatchResult &Result) {
	return rewriteDescendantsImpl(Node, std::move(Rule), Result);
	}

	llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
	transformer::detail::rewriteDescendants(const TypeLoc &Node, RewriteRule Rule,
	const MatchResult &Result) {
	return rewriteDescendantsImpl(Node, std::move(Rule), Result);
	}

	llvm::Expected<SmallVector<clang::transformer::Edit, 1>>
	transformer::detail::rewriteDescendants(const DynTypedNode &DNode,
	RewriteRule Rule,
	const MatchResult &Result) {
	if (const auto *Node = DNode.get<Decl>())
	return rewriteDescendantsImpl(*Node, std::move(Rule), Result);
	if (const auto *Node = DNode.get<Stmt>())
	return rewriteDescendantsImpl(*Node, std::move(Rule), Result);
	if (const auto *Node = DNode.get<TypeLoc>())
	return rewriteDescendantsImpl(*Node, std::move(Rule), Result);

	return llvm::make_error<llvm::StringError>(
	llvm::errc::invalid_argument,
	"type unsupported for recursive rewriting, Kind=" +
	DNode.getNodeKind().asStringRef());
	}

	EditGenerator transformer::rewriteDescendants(std::string NodeId,
	RewriteRule Rule) {
	return [NodeId = std::move(NodeId),
	Rule = std::move(Rule)](const MatchResult &Result)
	-> llvm::Expected<SmallVector<clang::transformer::Edit, 1>> {
	const ast_matchers::BoundNodes::IDToNodeMap &NodesMap =
	Result.Nodes.getMap();
	auto It = NodesMap.find(NodeId);
	if (It == NodesMap.end())
	return llvm::make_error<llvm::StringError>(llvm::errc::invalid_argument,
	"ID not bound: " + NodeId);
	return detail::rewriteDescendants(It->second, std::move(Rule), Result);
	};
	}

	void transformer::addInclude(RewriteRuleBase &Rule, StringRef Header,
	IncludeFormat Format) {
	for (auto &Case : Rule.Cases)
	Case.Edits = flatten(std::move(Case.Edits), addInclude(Header, Format));
	}

	#ifndef NDEBUG
	// Filters for supported matcher kinds. FIXME: Explicitly list the allowed kinds
	// (all node matcher types except for `QualType` and `Type`), rather than just
	// banning `QualType` and `Type`.
	static bool hasValidKind(const DynTypedMatcher &M) {
	return !M.canConvertTo<QualType>();
	}
	#endif

	// Binds each rule's matcher to a unique (and deterministic) tag based on
	// `TagBase` and the id paired with the case. All of the returned matchers have
	// their traversal kind explicitly set, either based on a pre-set kind or to the
	// provided `DefaultTraversalKind`.
	static std::vector<DynTypedMatcher> taggedMatchers(
	StringRef TagBase,
	const SmallVectorImpl<std::pair<size_t, RewriteRule::Case>> &Cases,
	TraversalKind DefaultTraversalKind) {
	std::vector<DynTypedMatcher> Matchers;
	Matchers.reserve(Cases.size());
	for (const auto &Case : Cases) {
	std::string Tag = (TagBase + Twine(Case.first)).str();
	// HACK: Many matchers are not bindable, so ensure that tryBind will work.
	DynTypedMatcher BoundMatcher(Case.second.Matcher);
	BoundMatcher.setAllowBind(true);
	auto M = *BoundMatcher.tryBind(Tag);
	Matchers.push_back(!M.getTraversalKind()
	? M.withTraversalKind(DefaultTraversalKind)
	: std::move(M));
	}
	return Matchers;
	}

	// Simply gathers the contents of the various rules into a single rule. The
	// actual work to combine these into an ordered choice is deferred to matcher
	// registration.
	template <>
	RewriteRuleWith<void>
	transformer::applyFirst(ArrayRef<RewriteRuleWith<void>> Rules) {
	RewriteRule R;
	for (auto &Rule : Rules)
	R.Cases.append(Rule.Cases.begin(), Rule.Cases.end());
	return R;
	}

	std::vector<DynTypedMatcher>
	transformer::detail::buildMatchers(const RewriteRuleBase &Rule) {
	// Map the cases into buckets of matchers -- one for each "root" AST kind,
	// which guarantees that they can be combined in a single anyOf matcher. Each
	// case is paired with an identifying number that is converted to a string id
	// in `taggedMatchers`.
	std::map<ASTNodeKind,
	SmallVector<std::pair<size_t, RewriteRuleBase::Case>, 1>>
	Buckets;
	const SmallVectorImpl<RewriteRule::Case> &Cases = Rule.Cases;
	for (int I = 0, N = Cases.size(); I < N; ++I) {
	assert(hasValidKind(Cases[I].Matcher) &&
	"Matcher must be non-(Qual)Type node matcher");
	Buckets[Cases[I].Matcher.getSupportedKind()].emplace_back(I, Cases[I]);
	}

	// Each anyOf explicitly controls the traversal kind. The anyOf itself is set
	// to `TK_AsIs` to ensure no nodes are skipped, thereby deferring to the kind
	// of the branches. Then, each branch is either left as is, if the kind is
	// already set, or explicitly set to `TK_AsIs`. We choose this setting because
	// it is the default interpretation of matchers.
	std::vector<DynTypedMatcher> Matchers;
	for (const auto &Bucket : Buckets) {
	DynTypedMatcher M = DynTypedMatcher::constructVariadic(
	DynTypedMatcher::VO_AnyOf, Bucket.first,
	taggedMatchers("Tag", Bucket.second, TK_AsIs));
	M.setAllowBind(true);
	// `tryBind` is guaranteed to succeed, because `AllowBind` was set to true.
	Matchers.push_back(M.tryBind(RootID)->withTraversalKind(TK_AsIs));
	}
	return Matchers;
	}

	DynTypedMatcher transformer::detail::buildMatcher(const RewriteRuleBase &Rule) {
	std::vector<DynTypedMatcher> Ms = buildMatchers(Rule);
	assert(Ms.size() == 1 && "Cases must have compatible matchers.");
	return Ms[0];
	}

	SourceLocation transformer::detail::getRuleMatchLoc(const MatchResult &Result) {
	auto &NodesMap = Result.Nodes.getMap();
	auto Root = NodesMap.find(RootID);
	assert(Root != NodesMap.end() && "Transformation failed: missing root node.");
	std::optional<CharSourceRange> RootRange = tooling::getFileRangeForEdit(
	CharSourceRange::getTokenRange(Root->second.getSourceRange()),
	*Result.Context);
	if (RootRange)
	return RootRange->getBegin();
	// The match doesn't have a coherent range, so fall back to the expansion
	// location as the "beginning" of the match.
	return Result.SourceManager->getExpansionLoc(
	Root->second.getSourceRange().getBegin());
	}

	// Finds the case that was "selected" -- that is, whose matcher triggered the
	// `MatchResult`.
	size_t transformer::detail::findSelectedCase(const MatchResult &Result,
	const RewriteRuleBase &Rule) {
	if (Rule.Cases.size() == 1)
	return 0;

	auto &NodesMap = Result.Nodes.getMap();
	for (size_t i = 0, N = Rule.Cases.size(); i < N; ++i) {
	std::string Tag = ("Tag" + Twine(i)).str();
	if (NodesMap.find(Tag) != NodesMap.end())
	return i;
	}
	llvm_unreachable("No tag found for this rule.");
	}