clang-tools-extra/clangd/ConfigYAML.cpp - llvm-project - Git at Google

 //===--- ConfigYAML.cpp - Loading configuration fragments from YAML files -===//
 //
 // 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 "ConfigFragment.h"
 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/SmallSet.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/MemoryBuffer.h"
 #include "llvm/Support/SourceMgr.h"
 #include "llvm/Support/YAMLParser.h"
 #include <string>
 #include <system_error>

 namespace clang {
 namespace clangd {
 namespace config {
 namespace {
 using llvm::yaml::BlockScalarNode;
 using llvm::yaml::MappingNode;
 using llvm::yaml::Node;
 using llvm::yaml::ScalarNode;
 using llvm::yaml::SequenceNode;

 llvm::Optional<llvm::StringRef>
 bestGuess(llvm::StringRef Search,
           llvm::ArrayRef<llvm::StringRef> AllowedValues) {
   unsigned MaxEdit = (Search.size() + 1) / 3;
   if (!MaxEdit)
     return llvm::None;
   llvm::Optional<llvm::StringRef> Result;
   for (const auto &AllowedValue : AllowedValues) {
     unsigned EditDistance = Search.edit_distance(AllowedValue, true, MaxEdit);
     // We can't do better than an edit distance of 1, so just return this and
     // save computing other values.
     if (EditDistance == 1U)
       return AllowedValue;
     if (EditDistance == MaxEdit && !Result) {
       Result = AllowedValue;
     } else if (EditDistance < MaxEdit) {
       Result = AllowedValue;
       MaxEdit = EditDistance;
     }
   }
   return Result;
 }

 class Parser {
   llvm::SourceMgr &SM;
   bool HadError = false;

 public:
   Parser(llvm::SourceMgr &SM) : SM(SM) {}

   // Tries to parse N into F, returning false if it failed and we couldn't
   // meaningfully recover (YAML syntax error, or hard semantic error).
   bool parse(Fragment &F, Node &N) {
     DictParser Dict("Config", this);
     Dict.handle("If", [&](Node &N) { parse(F.If, N); });
     Dict.handle("CompileFlags", [&](Node &N) { parse(F.CompileFlags, N); });
     Dict.handle("Index", [&](Node &N) { parse(F.Index, N); });
     Dict.handle("Style", [&](Node &N) { parse(F.Style, N); });
     Dict.handle("Diagnostics", [&](Node &N) { parse(F.Diagnostics, N); });
     Dict.handle("Completion", [&](Node &N) { parse(F.Completion, N); });
     Dict.parse(N);
     return !(N.failed() || HadError);
   }

 private:
   void parse(Fragment::IfBlock &F, Node &N) {
     DictParser Dict("If", this);
     Dict.unrecognized([&](Located<std::string>, Node &) {
       F.HasUnrecognizedCondition = true;
       return true; // Emit a warning for the unrecognized key.
     });
     Dict.handle("PathMatch", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.PathMatch = std::move(*Values);
     });
     Dict.handle("PathExclude", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.PathExclude = std::move(*Values);
     });
     Dict.parse(N);
   }

   void parse(Fragment::CompileFlagsBlock &F, Node &N) {
     DictParser Dict("CompileFlags", this);
     Dict.handle("Add", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.Add = std::move(*Values);
     });
     Dict.handle("Remove", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.Remove = std::move(*Values);
     });
     Dict.handle("CompilationDatabase", [&](Node &N) {
       F.CompilationDatabase = scalarValue(N, "CompilationDatabase");
     });
     Dict.parse(N);
   }

   void parse(Fragment::StyleBlock &F, Node &N) {
     DictParser Dict("Style", this);
     Dict.handle("FullyQualifiedNamespaces", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.FullyQualifiedNamespaces = std::move(*Values);
     });
     Dict.parse(N);
   }

   void parse(Fragment::DiagnosticsBlock &F, Node &N) {
     DictParser Dict("Diagnostics", this);
     Dict.handle("Suppress", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.Suppress = std::move(*Values);
     });
     Dict.handle("UnusedIncludes", [&](Node &N) {
       F.UnusedIncludes = scalarValue(N, "UnusedIncludes");
     });
     Dict.handle("ClangTidy", [&](Node &N) { parse(F.ClangTidy, N); });
     Dict.parse(N);
   }

   void parse(Fragment::DiagnosticsBlock::ClangTidyBlock &F, Node &N) {
     DictParser Dict("ClangTidy", this);
     Dict.handle("Add", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.Add = std::move(*Values);
     });
     Dict.handle("Remove", [&](Node &N) {
       if (auto Values = scalarValues(N))
         F.Remove = std::move(*Values);
     });
     Dict.handle("CheckOptions", [&](Node &N) {
       DictParser CheckOptDict("CheckOptions", this);
       CheckOptDict.unrecognized([&](Located<std::string> &&Key, Node &Val) {
         if (auto Value = scalarValue(Val, *Key))
           F.CheckOptions.emplace_back(std::move(Key), std::move(*Value));
         return false; // Don't emit a warning
       });
       CheckOptDict.parse(N);
     });
     Dict.parse(N);
   }

   void parse(Fragment::IndexBlock &F, Node &N) {
     DictParser Dict("Index", this);
     Dict.handle("Background",
                 [&](Node &N) { F.Background = scalarValue(N, "Background"); });
     Dict.handle("External", [&](Node &N) {
       Fragment::IndexBlock::ExternalBlock External;
       // External block can either be a mapping or a scalar value. Dispatch
       // accordingly.
       if (N.getType() == Node::NK_Mapping) {
         parse(External, N);
       } else if (N.getType() == Node::NK_Scalar ||
                  N.getType() == Node::NK_BlockScalar) {
         parse(External, scalarValue(N, "External").getValue());
       } else {
         error("External must be either a scalar or a mapping.", N);
         return;
       }
       F.External.emplace(std::move(External));
       F.External->Range = N.getSourceRange();
     });
     Dict.parse(N);
   }

   void parse(Fragment::IndexBlock::ExternalBlock &F,
              Located<std::string> ExternalVal) {
     if (!llvm::StringRef(*ExternalVal).equals_insensitive("none")) {
       error("Only scalar value supported for External is 'None'",
             ExternalVal.Range);
       return;
     }
     F.IsNone = true;
     F.IsNone.Range = ExternalVal.Range;
   }

   void parse(Fragment::IndexBlock::ExternalBlock &F, Node &N) {
     DictParser Dict("External", this);
     Dict.handle("File", [&](Node &N) { F.File = scalarValue(N, "File"); });
     Dict.handle("Server",
                 [&](Node &N) { F.Server = scalarValue(N, "Server"); });
     Dict.handle("MountPoint",
                 [&](Node &N) { F.MountPoint = scalarValue(N, "MountPoint"); });
     Dict.parse(N);
   }

   void parse(Fragment::CompletionBlock &F, Node &N) {
     DictParser Dict("Completion", this);
     Dict.handle("AllScopes", [&](Node &N) {
       if (auto Value = scalarValue(N, "AllScopes")) {
         if (auto AllScopes = llvm::yaml::parseBool(**Value))
           F.AllScopes = *AllScopes;
         else
           warning("AllScopes should be a boolean", N);
       }
     });
     Dict.parse(N);
   }

   // Helper for parsing mapping nodes (dictionaries).
   // We don't use YamlIO as we want to control over unknown keys.
   class DictParser {
     llvm::StringRef Description;
     std::vector<std::pair<llvm::StringRef, std::function<void(Node &)>>> Keys;
     std::function<bool(Located<std::string>, Node &)> UnknownHandler;
     Parser *Outer;

   public:
     DictParser(llvm::StringRef Description, Parser *Outer)
         : Description(Description), Outer(Outer) {}

     // Parse is called when Key is encountered, and passed the associated value.
     // It should emit diagnostics if the value is invalid (e.g. wrong type).
     // If Key is seen twice, Parse runs only once and an error is reported.
     void handle(llvm::StringLiteral Key, std::function<void(Node &)> Parse) {
       for (const auto &Entry : Keys) {
         (void) Entry;
         assert(Entry.first != Key && "duplicate key handler");
       }
       Keys.emplace_back(Key, std::move(Parse));
     }

     // Handler is called when a Key is not matched by any handle().
     // If this is unset or the Handler returns true, a warning is emitted for
     // the unknown key.
     void
     unrecognized(std::function<bool(Located<std::string>, Node &)> Handler) {
       UnknownHandler = std::move(Handler);
     }

     // Process a mapping node and call handlers for each key/value pair.
     void parse(Node &N) const {
       if (N.getType() != Node::NK_Mapping) {
         Outer->error(Description + " should be a dictionary", N);
         return;
       }
       llvm::SmallSet<std::string, 8> Seen;
       llvm::SmallVector<Located<std::string>, 0> UnknownKeys;
       // We *must* consume all items, even on error, or the parser will assert.
       for (auto &KV : llvm::cast<MappingNode>(N)) {
         auto *K = KV.getKey();
         if (!K) // YAMLParser emitted an error.
           continue;
         auto Key = Outer->scalarValue(*K, "Dictionary key");
         if (!Key)
           continue;
         if (!Seen.insert(**Key).second) {
           Outer->warning("Duplicate key " + **Key + " is ignored", *K);
           if (auto *Value = KV.getValue())
             Value->skip();
           continue;
         }
         auto *Value = KV.getValue();
         if (!Value) // YAMLParser emitted an error.
           continue;
         bool Matched = false;
         for (const auto &Handler : Keys) {
           if (Handler.first == **Key) {
             Matched = true;
             Handler.second(*Value);
             break;
           }
         }
         if (!Matched) {
           bool Warn = !UnknownHandler;
           if (UnknownHandler)
             Warn = UnknownHandler(
                 Located<std::string>(**Key, K->getSourceRange()), *Value);
           if (Warn)
             UnknownKeys.push_back(std::move(*Key));
         }
       }
       if (!UnknownKeys.empty())
         warnUnknownKeys(UnknownKeys, Seen);
     }

   private:
     void warnUnknownKeys(llvm::ArrayRef<Located<std::string>> UnknownKeys,
                          const llvm::SmallSet<std::string, 8> &SeenKeys) const {
       llvm::SmallVector<llvm::StringRef> UnseenKeys;
       for (const auto &KeyAndHandler : Keys)
         if (!SeenKeys.count(KeyAndHandler.first.str()))
           UnseenKeys.push_back(KeyAndHandler.first);

       for (const Located<std::string> &UnknownKey : UnknownKeys)
         if (auto BestGuess = bestGuess(*UnknownKey, UnseenKeys))
           Outer->warning("Unknown " + Description + " key '" + *UnknownKey +
                              "'; did you mean '" + *BestGuess + "'?",
                          UnknownKey.Range);
         else
           Outer->warning("Unknown " + Description + " key '" + *UnknownKey +
                              "'",
                          UnknownKey.Range);
     }
   };

   // Try to parse a single scalar value from the node, warn on failure.
   llvm::Optional<Located<std::string>> scalarValue(Node &N,
                                                    llvm::StringRef Desc) {
     llvm::SmallString<256> Buf;
     if (auto *S = llvm::dyn_cast<ScalarNode>(&N))
       return Located<std::string>(S->getValue(Buf).str(), N.getSourceRange());
     if (auto *BS = llvm::dyn_cast<BlockScalarNode>(&N))
       return Located<std::string>(BS->getValue().str(), N.getSourceRange());
     warning(Desc + " should be scalar", N);
     return llvm::None;
   }

   // Try to parse a list of single scalar values, or just a single value.
   llvm::Optional<std::vector<Located<std::string>>> scalarValues(Node &N) {
     std::vector<Located<std::string>> Result;
     if (auto *S = llvm::dyn_cast<ScalarNode>(&N)) {
       llvm::SmallString<256> Buf;
       Result.emplace_back(S->getValue(Buf).str(), N.getSourceRange());
     } else if (auto *S = llvm::dyn_cast<BlockScalarNode>(&N)) {
       Result.emplace_back(S->getValue().str(), N.getSourceRange());
     } else if (auto *S = llvm::dyn_cast<SequenceNode>(&N)) {
       // We *must* consume all items, even on error, or the parser will assert.
       for (auto &Child : *S) {
         if (auto Value = scalarValue(Child, "List item"))
           Result.push_back(std::move(*Value));
       }
     } else {
       warning("Expected scalar or list of scalars", N);
       return llvm::None;
     }
     return Result;
   }

   // Report a "hard" error, reflecting a config file that can never be valid.
   void error(const llvm::Twine &Msg, llvm::SMRange Range) {
     HadError = true;
     SM.PrintMessage(Range.Start, llvm::SourceMgr::DK_Error, Msg, Range);
   }
   void error(const llvm::Twine &Msg, const Node &N) {
     return error(Msg, N.getSourceRange());
   }

   // Report a "soft" error that could be caused by e.g. version skew.
   void warning(const llvm::Twine &Msg, llvm::SMRange Range) {
     SM.PrintMessage(Range.Start, llvm::SourceMgr::DK_Warning, Msg, Range);
   }
   void warning(const llvm::Twine &Msg, const Node &N) {
     return warning(Msg, N.getSourceRange());
   }
 };

 } // namespace

 std::vector<Fragment> Fragment::parseYAML(llvm::StringRef YAML,
                                           llvm::StringRef BufferName,
                                           DiagnosticCallback Diags) {
   // The YAML document may contain multiple conditional fragments.
   // The SourceManager is shared for all of them.
   auto SM = std::make_shared<llvm::SourceMgr>();
   auto Buf = llvm::MemoryBuffer::getMemBufferCopy(YAML, BufferName);
   // Adapt DiagnosticCallback to function-pointer interface.
   // Callback receives both errors we emit and those from the YAML parser.
   SM->setDiagHandler(
       [](const llvm::SMDiagnostic &Diag, void *Ctx) {
         (*reinterpret_cast<DiagnosticCallback *>(Ctx))(Diag);
       },
       &Diags);
   std::vector<Fragment> Result;
   for (auto &Doc : llvm::yaml::Stream(*Buf, *SM)) {
     if (Node *N = Doc.getRoot()) {
       Fragment Fragment;
       Fragment.Source.Manager = SM;
       Fragment.Source.Location = N->getSourceRange().Start;
       SM->PrintMessage(Fragment.Source.Location, llvm::SourceMgr::DK_Note,
                        "Parsing config fragment");
       if (Parser(*SM).parse(Fragment, *N))
         Result.push_back(std::move(Fragment));
     }
   }
   SM->PrintMessage(SM->FindLocForLineAndColumn(SM->getMainFileID(), 0, 0),
                    llvm::SourceMgr::DK_Note,
                    "Parsed " + llvm::Twine(Result.size()) +
                        " fragments from file");
   // Hack: stash the buffer in the SourceMgr to keep it alive.
   // SM has two entries: "main" non-owning buffer, and ignored owning buffer.
   SM->AddNewSourceBuffer(std::move(Buf), llvm::SMLoc());
   return Result;
 }

 } // namespace config
 } // namespace clangd
 } // namespace clang
	//===--- ConfigYAML.cpp - Loading configuration fragments from YAML files -===//
	//
	// 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 "ConfigFragment.h"
	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/SmallSet.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/MemoryBuffer.h"
	#include "llvm/Support/SourceMgr.h"
	#include "llvm/Support/YAMLParser.h"
	#include <string>
	#include <system_error>

	namespace clang {
	namespace clangd {
	namespace config {
	namespace {
	using llvm::yaml::BlockScalarNode;
	using llvm::yaml::MappingNode;
	using llvm::yaml::Node;
	using llvm::yaml::ScalarNode;
	using llvm::yaml::SequenceNode;

	llvm::Optional<llvm::StringRef>
	bestGuess(llvm::StringRef Search,
	llvm::ArrayRef<llvm::StringRef> AllowedValues) {
	unsigned MaxEdit = (Search.size() + 1) / 3;
	if (!MaxEdit)
	return llvm::None;
	llvm::Optional<llvm::StringRef> Result;
	for (const auto &AllowedValue : AllowedValues) {
	unsigned EditDistance = Search.edit_distance(AllowedValue, true, MaxEdit);
	// We can't do better than an edit distance of 1, so just return this and
	// save computing other values.
	if (EditDistance == 1U)
	return AllowedValue;
	if (EditDistance == MaxEdit && !Result) {
	Result = AllowedValue;
	} else if (EditDistance < MaxEdit) {
	Result = AllowedValue;
	MaxEdit = EditDistance;
	}
	}
	return Result;
	}

	class Parser {
	llvm::SourceMgr &SM;
	bool HadError = false;

	public:
	Parser(llvm::SourceMgr &SM) : SM(SM) {}

	// Tries to parse N into F, returning false if it failed and we couldn't
	// meaningfully recover (YAML syntax error, or hard semantic error).
	bool parse(Fragment &F, Node &N) {
	DictParser Dict("Config", this);
	Dict.handle("If", [&](Node &N) { parse(F.If, N); });
	Dict.handle("CompileFlags", [&](Node &N) { parse(F.CompileFlags, N); });
	Dict.handle("Index", [&](Node &N) { parse(F.Index, N); });
	Dict.handle("Style", [&](Node &N) { parse(F.Style, N); });
	Dict.handle("Diagnostics", [&](Node &N) { parse(F.Diagnostics, N); });
	Dict.handle("Completion", [&](Node &N) { parse(F.Completion, N); });
	Dict.parse(N);
	return !(N.failed() \|\| HadError);
	}

	private:
	void parse(Fragment::IfBlock &F, Node &N) {
	DictParser Dict("If", this);
	Dict.unrecognized([&](Located<std::string>, Node &) {
	F.HasUnrecognizedCondition = true;
	return true; // Emit a warning for the unrecognized key.
	});
	Dict.handle("PathMatch", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.PathMatch = std::move(*Values);
	});
	Dict.handle("PathExclude", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.PathExclude = std::move(*Values);
	});
	Dict.parse(N);
	}

	void parse(Fragment::CompileFlagsBlock &F, Node &N) {
	DictParser Dict("CompileFlags", this);
	Dict.handle("Add", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.Add = std::move(*Values);
	});
	Dict.handle("Remove", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.Remove = std::move(*Values);
	});
	Dict.handle("CompilationDatabase", [&](Node &N) {
	F.CompilationDatabase = scalarValue(N, "CompilationDatabase");
	});
	Dict.parse(N);
	}

	void parse(Fragment::StyleBlock &F, Node &N) {
	DictParser Dict("Style", this);
	Dict.handle("FullyQualifiedNamespaces", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.FullyQualifiedNamespaces = std::move(*Values);
	});
	Dict.parse(N);
	}

	void parse(Fragment::DiagnosticsBlock &F, Node &N) {
	DictParser Dict("Diagnostics", this);
	Dict.handle("Suppress", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.Suppress = std::move(*Values);
	});
	Dict.handle("UnusedIncludes", [&](Node &N) {
	F.UnusedIncludes = scalarValue(N, "UnusedIncludes");
	});
	Dict.handle("ClangTidy", [&](Node &N) { parse(F.ClangTidy, N); });
	Dict.parse(N);
	}

	void parse(Fragment::DiagnosticsBlock::ClangTidyBlock &F, Node &N) {
	DictParser Dict("ClangTidy", this);
	Dict.handle("Add", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.Add = std::move(*Values);
	});
	Dict.handle("Remove", [&](Node &N) {
	if (auto Values = scalarValues(N))
	F.Remove = std::move(*Values);
	});
	Dict.handle("CheckOptions", [&](Node &N) {
	DictParser CheckOptDict("CheckOptions", this);
	CheckOptDict.unrecognized([&](Located<std::string> &&Key, Node &Val) {
	if (auto Value = scalarValue(Val, *Key))
	F.CheckOptions.emplace_back(std::move(Key), std::move(*Value));
	return false; // Don't emit a warning
	});
	CheckOptDict.parse(N);
	});
	Dict.parse(N);
	}

	void parse(Fragment::IndexBlock &F, Node &N) {
	DictParser Dict("Index", this);
	Dict.handle("Background",
	[&](Node &N) { F.Background = scalarValue(N, "Background"); });
	Dict.handle("External", [&](Node &N) {
	Fragment::IndexBlock::ExternalBlock External;
	// External block can either be a mapping or a scalar value. Dispatch
	// accordingly.
	if (N.getType() == Node::NK_Mapping) {
	parse(External, N);
	} else if (N.getType() == Node::NK_Scalar \|\|
	N.getType() == Node::NK_BlockScalar) {
	parse(External, scalarValue(N, "External").getValue());
	} else {
	error("External must be either a scalar or a mapping.", N);
	return;
	}
	F.External.emplace(std::move(External));
	F.External->Range = N.getSourceRange();
	});
	Dict.parse(N);
	}

	void parse(Fragment::IndexBlock::ExternalBlock &F,
	Located<std::string> ExternalVal) {
	if (!llvm::StringRef(*ExternalVal).equals_insensitive("none")) {
	error("Only scalar value supported for External is 'None'",
	ExternalVal.Range);
	return;
	}
	F.IsNone = true;
	F.IsNone.Range = ExternalVal.Range;
	}

	void parse(Fragment::IndexBlock::ExternalBlock &F, Node &N) {
	DictParser Dict("External", this);
	Dict.handle("File", [&](Node &N) { F.File = scalarValue(N, "File"); });
	Dict.handle("Server",
	[&](Node &N) { F.Server = scalarValue(N, "Server"); });
	Dict.handle("MountPoint",
	[&](Node &N) { F.MountPoint = scalarValue(N, "MountPoint"); });
	Dict.parse(N);
	}

	void parse(Fragment::CompletionBlock &F, Node &N) {
	DictParser Dict("Completion", this);
	Dict.handle("AllScopes", [&](Node &N) {
	if (auto Value = scalarValue(N, "AllScopes")) {
	if (auto AllScopes = llvm::yaml::parseBool(**Value))
	F.AllScopes = *AllScopes;
	else
	warning("AllScopes should be a boolean", N);
	}
	});
	Dict.parse(N);
	}

	// Helper for parsing mapping nodes (dictionaries).
	// We don't use YamlIO as we want to control over unknown keys.
	class DictParser {
	llvm::StringRef Description;
	std::vector<std::pair<llvm::StringRef, std::function<void(Node &)>>> Keys;
	std::function<bool(Located<std::string>, Node &)> UnknownHandler;
	Parser *Outer;

	public:
	DictParser(llvm::StringRef Description, Parser *Outer)
	: Description(Description), Outer(Outer) {}

	// Parse is called when Key is encountered, and passed the associated value.
	// It should emit diagnostics if the value is invalid (e.g. wrong type).
	// If Key is seen twice, Parse runs only once and an error is reported.
	void handle(llvm::StringLiteral Key, std::function<void(Node &)> Parse) {
	for (const auto &Entry : Keys) {
	(void) Entry;
	assert(Entry.first != Key && "duplicate key handler");
	}
	Keys.emplace_back(Key, std::move(Parse));
	}

	// Handler is called when a Key is not matched by any handle().
	// If this is unset or the Handler returns true, a warning is emitted for
	// the unknown key.
	void
	unrecognized(std::function<bool(Located<std::string>, Node &)> Handler) {
	UnknownHandler = std::move(Handler);
	}

	// Process a mapping node and call handlers for each key/value pair.
	void parse(Node &N) const {
	if (N.getType() != Node::NK_Mapping) {
	Outer->error(Description + " should be a dictionary", N);
	return;
	}
	llvm::SmallSet<std::string, 8> Seen;
	llvm::SmallVector<Located<std::string>, 0> UnknownKeys;
	// We must consume all items, even on error, or the parser will assert.
	for (auto &KV : llvm::cast<MappingNode>(N)) {
	auto *K = KV.getKey();
	if (!K) // YAMLParser emitted an error.
	continue;
	auto Key = Outer->scalarValue(*K, "Dictionary key");
	if (!Key)
	continue;
	if (!Seen.insert(**Key).second) {
	Outer->warning("Duplicate key " + *Key + " is ignored", K);
	if (auto *Value = KV.getValue())
	Value->skip();
	continue;
	}
	auto *Value = KV.getValue();
	if (!Value) // YAMLParser emitted an error.
	continue;
	bool Matched = false;
	for (const auto &Handler : Keys) {
	if (Handler.first == **Key) {
	Matched = true;
	Handler.second(*Value);
	break;
	}
	}
	if (!Matched) {
	bool Warn = !UnknownHandler;
	if (UnknownHandler)
	Warn = UnknownHandler(
	Located<std::string>(*Key, K->getSourceRange()), Value);
	if (Warn)
	UnknownKeys.push_back(std::move(*Key));
	}
	}
	if (!UnknownKeys.empty())
	warnUnknownKeys(UnknownKeys, Seen);
	}

	private:
	void warnUnknownKeys(llvm::ArrayRef<Located<std::string>> UnknownKeys,
	const llvm::SmallSet<std::string, 8> &SeenKeys) const {
	llvm::SmallVector<llvm::StringRef> UnseenKeys;
	for (const auto &KeyAndHandler : Keys)
	if (!SeenKeys.count(KeyAndHandler.first.str()))
	UnseenKeys.push_back(KeyAndHandler.first);

	for (const Located<std::string> &UnknownKey : UnknownKeys)
	if (auto BestGuess = bestGuess(*UnknownKey, UnseenKeys))
	Outer->warning("Unknown " + Description + " key '" + *UnknownKey +
	"'; did you mean '" + *BestGuess + "'?",
	UnknownKey.Range);
	else
	Outer->warning("Unknown " + Description + " key '" + *UnknownKey +
	"'",
	UnknownKey.Range);
	}
	};

	// Try to parse a single scalar value from the node, warn on failure.
	llvm::Optional<Located<std::string>> scalarValue(Node &N,
	llvm::StringRef Desc) {
	llvm::SmallString<256> Buf;
	if (auto *S = llvm::dyn_cast<ScalarNode>(&N))
	return Located<std::string>(S->getValue(Buf).str(), N.getSourceRange());
	if (auto *BS = llvm::dyn_cast<BlockScalarNode>(&N))
	return Located<std::string>(BS->getValue().str(), N.getSourceRange());
	warning(Desc + " should be scalar", N);
	return llvm::None;
	}

	// Try to parse a list of single scalar values, or just a single value.
	llvm::Optional<std::vector<Located<std::string>>> scalarValues(Node &N) {
	std::vector<Located<std::string>> Result;
	if (auto *S = llvm::dyn_cast<ScalarNode>(&N)) {
	llvm::SmallString<256> Buf;
	Result.emplace_back(S->getValue(Buf).str(), N.getSourceRange());
	} else if (auto *S = llvm::dyn_cast<BlockScalarNode>(&N)) {
	Result.emplace_back(S->getValue().str(), N.getSourceRange());
	} else if (auto *S = llvm::dyn_cast<SequenceNode>(&N)) {
	// We must consume all items, even on error, or the parser will assert.
	for (auto &Child : *S) {
	if (auto Value = scalarValue(Child, "List item"))
	Result.push_back(std::move(*Value));
	}
	} else {
	warning("Expected scalar or list of scalars", N);
	return llvm::None;
	}
	return Result;
	}

	// Report a "hard" error, reflecting a config file that can never be valid.
	void error(const llvm::Twine &Msg, llvm::SMRange Range) {
	HadError = true;
	SM.PrintMessage(Range.Start, llvm::SourceMgr::DK_Error, Msg, Range);
	}
	void error(const llvm::Twine &Msg, const Node &N) {
	return error(Msg, N.getSourceRange());
	}

	// Report a "soft" error that could be caused by e.g. version skew.
	void warning(const llvm::Twine &Msg, llvm::SMRange Range) {
	SM.PrintMessage(Range.Start, llvm::SourceMgr::DK_Warning, Msg, Range);
	}
	void warning(const llvm::Twine &Msg, const Node &N) {
	return warning(Msg, N.getSourceRange());
	}
	};

	} // namespace

	std::vector<Fragment> Fragment::parseYAML(llvm::StringRef YAML,
	llvm::StringRef BufferName,
	DiagnosticCallback Diags) {
	// The YAML document may contain multiple conditional fragments.
	// The SourceManager is shared for all of them.
	auto SM = std::make_shared<llvm::SourceMgr>();
	auto Buf = llvm::MemoryBuffer::getMemBufferCopy(YAML, BufferName);
	// Adapt DiagnosticCallback to function-pointer interface.
	// Callback receives both errors we emit and those from the YAML parser.
	SM->setDiagHandler(
	[](const llvm::SMDiagnostic &Diag, void *Ctx) {
	(reinterpret_cast<DiagnosticCallback >(Ctx))(Diag);
	},
	&Diags);
	std::vector<Fragment> Result;
	for (auto &Doc : llvm::yaml::Stream(Buf, SM)) {
	if (Node *N = Doc.getRoot()) {
	Fragment Fragment;
	Fragment.Source.Manager = SM;
	Fragment.Source.Location = N->getSourceRange().Start;
	SM->PrintMessage(Fragment.Source.Location, llvm::SourceMgr::DK_Note,
	"Parsing config fragment");
	if (Parser(SM).parse(Fragment, N))
	Result.push_back(std::move(Fragment));
	}
	}
	SM->PrintMessage(SM->FindLocForLineAndColumn(SM->getMainFileID(), 0, 0),
	llvm::SourceMgr::DK_Note,
	"Parsed " + llvm::Twine(Result.size()) +
	" fragments from file");
	// Hack: stash the buffer in the SourceMgr to keep it alive.
	// SM has two entries: "main" non-owning buffer, and ignored owning buffer.
	SM->AddNewSourceBuffer(std::move(Buf), llvm::SMLoc());
	return Result;
	}

	} // namespace config
	} // namespace clangd
	} // namespace clang