src/third_party/llvm-project/clang/lib/Tooling/InterpolatingCompilationDatabase.cpp - cobalt - Git at Google

 //===- InterpolatingCompilationDatabase.cpp ---------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // InterpolatingCompilationDatabase wraps another CompilationDatabase and
 // attempts to heuristically determine appropriate compile commands for files
 // that are not included, such as headers or newly created files.
 //
 // Motivating cases include:
 //   Header files that live next to their implementation files. These typically
 // share a base filename. (libclang/CXString.h, libclang/CXString.cpp).
 //   Some projects separate headers from includes. Filenames still typically
 // match, maybe other path segments too. (include/llvm/IR/Use.h, lib/IR/Use.cc).
 //   Matches are sometimes only approximate (Sema.h, SemaDecl.cpp). This goes
 // for directories too (Support/Unix/Process.inc, lib/Support/Process.cpp).
 //   Even if we can't find a "right" compile command, even a random one from
 // the project will tend to get important flags like -I and -x right.
 //
 // We "borrow" the compile command for the closest available file:
 //   - points are awarded if the filename matches (ignoring extension)
 //   - points are awarded if the directory structure matches
 //   - ties are broken by length of path prefix match
 //
 // The compile command is adjusted, replacing the filename and removing output
 // file arguments. The -x and -std flags may be affected too.
 //
 // Source language is a tricky issue: is it OK to use a .c file's command
 // for building a .cc file? What language is a .h file in?
 //   - We only consider compile commands for c-family languages as candidates.
 //   - For files whose language is implied by the filename (e.g. .m, .hpp)
 //     we prefer candidates from the same language.
 //     If we must cross languages, we drop any -x and -std flags.
 //   - For .h files, candidates from any c-family language are acceptable.
 //     We use the candidate's language, inserting  e.g. -x c++-header.
 //
 // This class is only useful when wrapping databases that can enumerate all
 // their compile commands. If getAllFilenames() is empty, no inference occurs.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Driver/Options.h"
 #include "clang/Driver/Types.h"
 #include "clang/Frontend/LangStandard.h"
 #include "clang/Tooling/CompilationDatabase.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/ADT/StringSwitch.h"
 #include "llvm/Option/ArgList.h"
 #include "llvm/Option/OptTable.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/Path.h"
 #include "llvm/Support/StringSaver.h"
 #include "llvm/Support/raw_ostream.h"
 #include <memory>

 namespace clang {
 namespace tooling {
 namespace {
 using namespace llvm;
 namespace types = clang::driver::types;
 namespace path = llvm::sys::path;

 // The length of the prefix these two strings have in common.
 size_t matchingPrefix(StringRef L, StringRef R) {
   size_t Limit = std::min(L.size(), R.size());
   for (size_t I = 0; I < Limit; ++I)
     if (L[I] != R[I])
       return I;
   return Limit;
 }

 // A comparator for searching SubstringWithIndexes with std::equal_range etc.
 // Optionaly prefix semantics: compares equal if the key is a prefix.
 template <bool Prefix> struct Less {
   bool operator()(StringRef Key, std::pair<StringRef, size_t> Value) const {
     StringRef V = Prefix ? Value.first.substr(0, Key.size()) : Value.first;
     return Key < V;
   }
   bool operator()(std::pair<StringRef, size_t> Value, StringRef Key) const {
     StringRef V = Prefix ? Value.first.substr(0, Key.size()) : Value.first;
     return V < Key;
   }
 };

 // Infer type from filename. If we might have gotten it wrong, set *Certain.
 // *.h will be inferred as a C header, but not certain.
 types::ID guessType(StringRef Filename, bool *Certain = nullptr) {
   // path::extension is ".cpp", lookupTypeForExtension wants "cpp".
   auto Lang =
       types::lookupTypeForExtension(path::extension(Filename).substr(1));
   if (Certain)
     *Certain = Lang != types::TY_CHeader && Lang != types::TY_INVALID;
   return Lang;
 }

 // Return Lang as one of the canonical supported types.
 // e.g. c-header --> c; fortran --> TY_INVALID
 static types::ID foldType(types::ID Lang) {
   switch (Lang) {
   case types::TY_C:
   case types::TY_CHeader:
     return types::TY_C;
   case types::TY_ObjC:
   case types::TY_ObjCHeader:
     return types::TY_ObjC;
   case types::TY_CXX:
   case types::TY_CXXHeader:
     return types::TY_CXX;
   case types::TY_ObjCXX:
   case types::TY_ObjCXXHeader:
     return types::TY_ObjCXX;
   default:
     return types::TY_INVALID;
   }
 }

 // A CompileCommand that can be applied to another file.
 struct TransferableCommand {
   // Flags that should not apply to all files are stripped from CommandLine.
   CompileCommand Cmd;
   // Language detected from -x or the filename.
   types::ID Type = types::TY_INVALID;
   // Standard specified by -std.
   LangStandard::Kind Std = LangStandard::lang_unspecified;

   TransferableCommand(CompileCommand C)
       : Cmd(std::move(C)), Type(guessType(Cmd.Filename)) {
     std::vector<std::string> NewArgs = {Cmd.CommandLine.front()};
     // Parse the old args in order to strip out and record unwanted flags.
     auto OptTable = clang::driver::createDriverOptTable();
     std::vector<const char *> Argv;
     for (unsigned I = 1; I < Cmd.CommandLine.size(); ++I)
       Argv.push_back(Cmd.CommandLine[I].c_str());
     unsigned MissingI, MissingC;
     auto ArgList = OptTable->ParseArgs(Argv, MissingI, MissingC);
     for (const auto *Arg : ArgList) {
       const auto &option = Arg->getOption();
       // Strip input and output files.
       if (option.matches(clang::driver::options::OPT_INPUT) ||
           option.matches(clang::driver::options::OPT_o)) {
         continue;
       }
       // Strip -x, but record the overridden language.
       if (option.matches(clang::driver::options::OPT_x)) {
         for (const char *Value : Arg->getValues())
           Type = types::lookupTypeForTypeSpecifier(Value);
         continue;
       }
       // Strip --std, but record the value.
       if (option.matches(clang::driver::options::OPT_std_EQ)) {
         for (const char *Value : Arg->getValues()) {
           Std = llvm::StringSwitch<LangStandard::Kind>(Value)
 #define LANGSTANDARD(id, name, lang, desc, features)                           \
   .Case(name, LangStandard::lang_##id)
 #define LANGSTANDARD_ALIAS(id, alias) .Case(alias, LangStandard::lang_##id)
 #include "clang/Frontend/LangStandards.def"
                     .Default(Std);
         }
         continue;
       }
       llvm::opt::ArgStringList ArgStrs;
       Arg->render(ArgList, ArgStrs);
       NewArgs.insert(NewArgs.end(), ArgStrs.begin(), ArgStrs.end());
     }
     Cmd.CommandLine = std::move(NewArgs);

     if (Std != LangStandard::lang_unspecified) // -std take precedence over -x
       Type = toType(LangStandard::getLangStandardForKind(Std).getLanguage());
     Type = foldType(Type);
   }

   // Produce a CompileCommand for \p filename, based on this one.
   CompileCommand transferTo(StringRef Filename) const {
     CompileCommand Result = Cmd;
     Result.Filename = Filename;
     bool TypeCertain;
     auto TargetType = guessType(Filename, &TypeCertain);
     // If the filename doesn't determine the language (.h), transfer with -x.
     if (!TypeCertain) {
       TargetType = types::onlyPrecompileType(TargetType) // header?
                        ? types::lookupHeaderTypeForSourceType(Type)
                        : Type;
       Result.CommandLine.push_back("-x");
       Result.CommandLine.push_back(types::getTypeName(TargetType));
     }
     // --std flag may only be transferred if the language is the same.
     // We may consider "translating" these, e.g. c++11 -> c11.
     if (Std != LangStandard::lang_unspecified && foldType(TargetType) == Type) {
       Result.CommandLine.push_back(
           "-std=" +
           std::string(LangStandard::getLangStandardForKind(Std).getName()));
     }
     Result.CommandLine.push_back(Filename);
     return Result;
   }

 private:
   // Map the language from the --std flag to that of the -x flag.
   static types::ID toType(InputKind::Language Lang) {
     switch (Lang) {
     case InputKind::C:
       return types::TY_C;
     case InputKind::CXX:
       return types::TY_CXX;
     case InputKind::ObjC:
       return types::TY_ObjC;
     case InputKind::ObjCXX:
       return types::TY_ObjCXX;
     default:
       return types::TY_INVALID;
     }
   }
 };

 // CommandIndex does the real work: given a filename, it produces the best
 // matching TransferableCommand by matching filenames. Basic strategy:
 // - Build indexes of each of the substrings we want to look up by.
 //   These indexes are just sorted lists of the substrings.
 // - Forward requests to the inner CDB. If it fails, we must pick a proxy.
 // - Each criterion corresponds to a range lookup into the index, so we only
 //   need O(log N) string comparisons to determine scores.
 // - We then break ties among the candidates with the highest score.
 class CommandIndex {
 public:
   CommandIndex(std::vector<TransferableCommand> AllCommands)
       : Commands(std::move(AllCommands)), Strings(Arena) {
     // Sort commands by filename for determinism (index is a tiebreaker later).
     llvm::sort(
         Commands.begin(), Commands.end(),
         [](const TransferableCommand &Left, const TransferableCommand &Right) {
           return Left.Cmd.Filename < Right.Cmd.Filename;
         });
     for (size_t I = 0; I < Commands.size(); ++I) {
       StringRef Path =
           Strings.save(StringRef(Commands[I].Cmd.Filename).lower());
       Paths.push_back({Path, I});
       Stems.emplace_back(sys::path::stem(Path), I);
       auto Dir = ++sys::path::rbegin(Path), DirEnd = sys::path::rend(Path);
       for (int J = 0; J < DirectorySegmentsIndexed && Dir != DirEnd; ++J, ++Dir)
         if (Dir->size() > ShortDirectorySegment) // not trivial ones
           Components.emplace_back(*Dir, I);
     }
     llvm::sort(Paths.begin(), Paths.end());
     llvm::sort(Stems.begin(), Stems.end());
     llvm::sort(Components.begin(), Components.end());
   }

   bool empty() const { return Commands.empty(); }

   // Returns the command that best fits OriginalFilename.
   // Candidates with PreferLanguage will be chosen over others (unless it's
   // TY_INVALID, or all candidates are bad).
   const TransferableCommand &chooseProxy(StringRef OriginalFilename,
                                          types::ID PreferLanguage) const {
     assert(!empty() && "need at least one candidate!");
     std::string Filename = OriginalFilename.lower();
     auto Candidates = scoreCandidates(Filename);
     std::pair<size_t, int> Best =
         pickWinner(Candidates, Filename, PreferLanguage);

     DEBUG_WITH_TYPE("interpolate",
                     llvm::dbgs()
                         << "interpolate: chose "
                         << Commands[Best.first].Cmd.Filename << " as proxy for "
                         << OriginalFilename << " preferring "
                         << (PreferLanguage == types::TY_INVALID
                                 ? "none"
                                 : types::getTypeName(PreferLanguage))
                         << " score=" << Best.second << "\n");
     return Commands[Best.first];
   }

 private:
   using SubstringAndIndex = std::pair<StringRef, size_t>;
   // Directory matching parameters: we look at the last two segments of the
   // parent directory (usually the semantically significant ones in practice).
   // We search only the last four of each candidate (for efficiency).
   constexpr static int DirectorySegmentsIndexed = 4;
   constexpr static int DirectorySegmentsQueried = 2;
   constexpr static int ShortDirectorySegment = 1; // Only look at longer names.

   // Award points to candidate entries that should be considered for the file.
   // Returned keys are indexes into paths, and the values are (nonzero) scores.
   DenseMap<size_t, int> scoreCandidates(StringRef Filename) const {
     // Decompose Filename into the parts we care about.
     // /some/path/complicated/project/Interesting.h
     // [-prefix--][---dir---] [-dir-] [--stem---]
     StringRef Stem = sys::path::stem(Filename);
     llvm::SmallVector<StringRef, DirectorySegmentsQueried> Dirs;
     llvm::StringRef Prefix;
     auto Dir = ++sys::path::rbegin(Filename),
          DirEnd = sys::path::rend(Filename);
     for (int I = 0; I < DirectorySegmentsQueried && Dir != DirEnd; ++I, ++Dir) {
       if (Dir->size() > ShortDirectorySegment)
         Dirs.push_back(*Dir);
       Prefix = Filename.substr(0, Dir - DirEnd);
     }

     // Now award points based on lookups into our various indexes.
     DenseMap<size_t, int> Candidates; // Index -> score.
     auto Award = [&](int Points, ArrayRef<SubstringAndIndex> Range) {
       for (const auto &Entry : Range)
         Candidates[Entry.second] += Points;
     };
     // Award one point if the file's basename is a prefix of the candidate,
     // and another if it's an exact match (so exact matches get two points).
     Award(1, indexLookup</*Prefix=*/true>(Stem, Stems));
     Award(1, indexLookup</*Prefix=*/false>(Stem, Stems));
     // For each of the last few directories in the Filename, award a point
     // if it's present in the candidate.
     for (StringRef Dir : Dirs)
       Award(1, indexLookup</*Prefix=*/false>(Dir, Components));
     // Award one more point if the whole rest of the path matches.
     if (sys::path::root_directory(Prefix) != Prefix)
       Award(1, indexLookup</*Prefix=*/true>(Prefix, Paths));
     return Candidates;
   }

   // Pick a single winner from the set of scored candidates.
   // Returns (index, score).
   std::pair<size_t, int> pickWinner(const DenseMap<size_t, int> &Candidates,
                                     StringRef Filename,
                                     types::ID PreferredLanguage) const {
     struct ScoredCandidate {
       size_t Index;
       bool Preferred;
       int Points;
       size_t PrefixLength;
     };
     // Choose the best candidate by (preferred, points, prefix length, alpha).
     ScoredCandidate Best = {size_t(-1), false, 0, 0};
     for (const auto &Candidate : Candidates) {
       ScoredCandidate S;
       S.Index = Candidate.first;
       S.Preferred = PreferredLanguage == types::TY_INVALID ||
                     PreferredLanguage == Commands[S.Index].Type;
       S.Points = Candidate.second;
       if (!S.Preferred && Best.Preferred)
         continue;
       if (S.Preferred == Best.Preferred) {
         if (S.Points < Best.Points)
           continue;
         if (S.Points == Best.Points) {
           S.PrefixLength = matchingPrefix(Filename, Paths[S.Index].first);
           if (S.PrefixLength < Best.PrefixLength)
             continue;
           // hidden heuristics should at least be deterministic!
           if (S.PrefixLength == Best.PrefixLength)
             if (S.Index > Best.Index)
               continue;
         }
       }
       // PrefixLength was only set above if actually needed for a tiebreak.
       // But it definitely needs to be set to break ties in the future.
       S.PrefixLength = matchingPrefix(Filename, Paths[S.Index].first);
       Best = S;
     }
     // Edge case: no candidate got any points.
     // We ignore PreferredLanguage at this point (not ideal).
     if (Best.Index == size_t(-1))
       return {longestMatch(Filename, Paths).second, 0};
     return {Best.Index, Best.Points};
   }

   // Returns the range within a sorted index that compares equal to Key.
   // If Prefix is true, it's instead the range starting with Key.
   template <bool Prefix>
   ArrayRef<SubstringAndIndex>
   indexLookup(StringRef Key, const std::vector<SubstringAndIndex> &Idx) const {
     // Use pointers as iteratiors to ease conversion of result to ArrayRef.
     auto Range = std::equal_range(Idx.data(), Idx.data() + Idx.size(), Key,
                                   Less<Prefix>());
     return {Range.first, Range.second};
   }

   // Performs a point lookup into a nonempty index, returning a longest match.
   SubstringAndIndex
   longestMatch(StringRef Key, const std::vector<SubstringAndIndex> &Idx) const {
     assert(!Idx.empty());
     // Longest substring match will be adjacent to a direct lookup.
     auto It =
         std::lower_bound(Idx.begin(), Idx.end(), SubstringAndIndex{Key, 0});
     if (It == Idx.begin())
       return *It;
     if (It == Idx.end())
       return *--It;
     // Have to choose between It and It-1
     size_t Prefix = matchingPrefix(Key, It->first);
     size_t PrevPrefix = matchingPrefix(Key, (It - 1)->first);
     return Prefix > PrevPrefix ? *It : *--It;
   }

   std::vector<TransferableCommand> Commands; // Indexes point into this.
   BumpPtrAllocator Arena;
   StringSaver Strings;
   // Indexes of candidates by certain substrings.
   // String is lowercase and sorted, index points into OriginalPaths.
   std::vector<SubstringAndIndex> Paths;      // Full path.
   std::vector<SubstringAndIndex> Stems;      // Basename, without extension.
   std::vector<SubstringAndIndex> Components; // Last path components.
 };

 // The actual CompilationDatabase wrapper delegates to its inner database.
 // If no match, looks up a command in CommandIndex and transfers it to the file.
 class InterpolatingCompilationDatabase : public CompilationDatabase {
 public:
   InterpolatingCompilationDatabase(std::unique_ptr<CompilationDatabase> Inner)
       : Inner(std::move(Inner)), Index(allCommands()) {}

   std::vector<CompileCommand>
   getCompileCommands(StringRef Filename) const override {
     auto Known = Inner->getCompileCommands(Filename);
     if (Index.empty() || !Known.empty())
       return Known;
     bool TypeCertain;
     auto Lang = guessType(Filename, &TypeCertain);
     if (!TypeCertain)
       Lang = types::TY_INVALID;
     return {Index.chooseProxy(Filename, foldType(Lang)).transferTo(Filename)};
   }

   std::vector<std::string> getAllFiles() const override {
     return Inner->getAllFiles();
   }

   std::vector<CompileCommand> getAllCompileCommands() const override {
     return Inner->getAllCompileCommands();
   }

 private:
   std::vector<TransferableCommand> allCommands() {
     std::vector<TransferableCommand> Result;
     for (auto Command : Inner->getAllCompileCommands()) {
       Result.emplace_back(std::move(Command));
       if (Result.back().Type == types::TY_INVALID)
         Result.pop_back();
     }
     return Result;
   }

   std::unique_ptr<CompilationDatabase> Inner;
   CommandIndex Index;
 };

 } // namespace

 std::unique_ptr<CompilationDatabase>
 inferMissingCompileCommands(std::unique_ptr<CompilationDatabase> Inner) {
   return llvm::make_unique<InterpolatingCompilationDatabase>(std::move(Inner));
 }

 } // namespace tooling
 } // namespace clang
	//===- InterpolatingCompilationDatabase.cpp ---------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// InterpolatingCompilationDatabase wraps another CompilationDatabase and
	// attempts to heuristically determine appropriate compile commands for files
	// that are not included, such as headers or newly created files.
	//
	// Motivating cases include:
	// Header files that live next to their implementation files. These typically
	// share a base filename. (libclang/CXString.h, libclang/CXString.cpp).
	// Some projects separate headers from includes. Filenames still typically
	// match, maybe other path segments too. (include/llvm/IR/Use.h, lib/IR/Use.cc).
	// Matches are sometimes only approximate (Sema.h, SemaDecl.cpp). This goes
	// for directories too (Support/Unix/Process.inc, lib/Support/Process.cpp).
	// Even if we can't find a "right" compile command, even a random one from
	// the project will tend to get important flags like -I and -x right.
	//
	// We "borrow" the compile command for the closest available file:
	// - points are awarded if the filename matches (ignoring extension)
	// - points are awarded if the directory structure matches
	// - ties are broken by length of path prefix match
	//
	// The compile command is adjusted, replacing the filename and removing output
	// file arguments. The -x and -std flags may be affected too.
	//
	// Source language is a tricky issue: is it OK to use a .c file's command
	// for building a .cc file? What language is a .h file in?
	// - We only consider compile commands for c-family languages as candidates.
	// - For files whose language is implied by the filename (e.g. .m, .hpp)
	// we prefer candidates from the same language.
	// If we must cross languages, we drop any -x and -std flags.
	// - For .h files, candidates from any c-family language are acceptable.
	// We use the candidate's language, inserting e.g. -x c++-header.
	//
	// This class is only useful when wrapping databases that can enumerate all
	// their compile commands. If getAllFilenames() is empty, no inference occurs.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Driver/Options.h"
	#include "clang/Driver/Types.h"
	#include "clang/Frontend/LangStandard.h"
	#include "clang/Tooling/CompilationDatabase.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/ADT/StringSwitch.h"
	#include "llvm/Option/ArgList.h"
	#include "llvm/Option/OptTable.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/Path.h"
	#include "llvm/Support/StringSaver.h"
	#include "llvm/Support/raw_ostream.h"
	#include <memory>

	namespace clang {
	namespace tooling {
	namespace {
	using namespace llvm;
	namespace types = clang::driver::types;
	namespace path = llvm::sys::path;

	// The length of the prefix these two strings have in common.
	size_t matchingPrefix(StringRef L, StringRef R) {
	size_t Limit = std::min(L.size(), R.size());
	for (size_t I = 0; I < Limit; ++I)
	if (L[I] != R[I])
	return I;
	return Limit;
	}

	// A comparator for searching SubstringWithIndexes with std::equal_range etc.
	// Optionaly prefix semantics: compares equal if the key is a prefix.
	template <bool Prefix> struct Less {
	bool operator()(StringRef Key, std::pair<StringRef, size_t> Value) const {
	StringRef V = Prefix ? Value.first.substr(0, Key.size()) : Value.first;
	return Key < V;
	}
	bool operator()(std::pair<StringRef, size_t> Value, StringRef Key) const {
	StringRef V = Prefix ? Value.first.substr(0, Key.size()) : Value.first;
	return V < Key;
	}
	};

	// Infer type from filename. If we might have gotten it wrong, set *Certain.
	// *.h will be inferred as a C header, but not certain.
	types::ID guessType(StringRef Filename, bool *Certain = nullptr) {
	// path::extension is ".cpp", lookupTypeForExtension wants "cpp".
	auto Lang =
	types::lookupTypeForExtension(path::extension(Filename).substr(1));
	if (Certain)
	*Certain = Lang != types::TY_CHeader && Lang != types::TY_INVALID;
	return Lang;
	}

	// Return Lang as one of the canonical supported types.
	// e.g. c-header --> c; fortran --> TY_INVALID
	static types::ID foldType(types::ID Lang) {
	switch (Lang) {
	case types::TY_C:
	case types::TY_CHeader:
	return types::TY_C;
	case types::TY_ObjC:
	case types::TY_ObjCHeader:
	return types::TY_ObjC;
	case types::TY_CXX:
	case types::TY_CXXHeader:
	return types::TY_CXX;
	case types::TY_ObjCXX:
	case types::TY_ObjCXXHeader:
	return types::TY_ObjCXX;
	default:
	return types::TY_INVALID;
	}
	}

	// A CompileCommand that can be applied to another file.
	struct TransferableCommand {
	// Flags that should not apply to all files are stripped from CommandLine.
	CompileCommand Cmd;
	// Language detected from -x or the filename.
	types::ID Type = types::TY_INVALID;
	// Standard specified by -std.
	LangStandard::Kind Std = LangStandard::lang_unspecified;

	TransferableCommand(CompileCommand C)
	: Cmd(std::move(C)), Type(guessType(Cmd.Filename)) {
	std::vector<std::string> NewArgs = {Cmd.CommandLine.front()};
	// Parse the old args in order to strip out and record unwanted flags.
	auto OptTable = clang::driver::createDriverOptTable();
	std::vector<const char *> Argv;
	for (unsigned I = 1; I < Cmd.CommandLine.size(); ++I)
	Argv.push_back(Cmd.CommandLine[I].c_str());
	unsigned MissingI, MissingC;
	auto ArgList = OptTable->ParseArgs(Argv, MissingI, MissingC);
	for (const auto *Arg : ArgList) {
	const auto &option = Arg->getOption();
	// Strip input and output files.
	if (option.matches(clang::driver::options::OPT_INPUT) \|\|
	option.matches(clang::driver::options::OPT_o)) {
	continue;
	}
	// Strip -x, but record the overridden language.
	if (option.matches(clang::driver::options::OPT_x)) {
	for (const char *Value : Arg->getValues())
	Type = types::lookupTypeForTypeSpecifier(Value);
	continue;
	}
	// Strip --std, but record the value.
	if (option.matches(clang::driver::options::OPT_std_EQ)) {
	for (const char *Value : Arg->getValues()) {
	Std = llvm::StringSwitch<LangStandard::Kind>(Value)
	#define LANGSTANDARD(id, name, lang, desc, features) \
	.Case(name, LangStandard::lang_##id)
	#define LANGSTANDARD_ALIAS(id, alias) .Case(alias, LangStandard::lang_##id)
	#include "clang/Frontend/LangStandards.def"
	.Default(Std);
	}
	continue;
	}
	llvm::opt::ArgStringList ArgStrs;
	Arg->render(ArgList, ArgStrs);
	NewArgs.insert(NewArgs.end(), ArgStrs.begin(), ArgStrs.end());
	}
	Cmd.CommandLine = std::move(NewArgs);

	if (Std != LangStandard::lang_unspecified) // -std take precedence over -x
	Type = toType(LangStandard::getLangStandardForKind(Std).getLanguage());
	Type = foldType(Type);
	}

	// Produce a CompileCommand for \p filename, based on this one.
	CompileCommand transferTo(StringRef Filename) const {
	CompileCommand Result = Cmd;
	Result.Filename = Filename;
	bool TypeCertain;
	auto TargetType = guessType(Filename, &TypeCertain);
	// If the filename doesn't determine the language (.h), transfer with -x.
	if (!TypeCertain) {
	TargetType = types::onlyPrecompileType(TargetType) // header?
	? types::lookupHeaderTypeForSourceType(Type)
	: Type;
	Result.CommandLine.push_back("-x");
	Result.CommandLine.push_back(types::getTypeName(TargetType));
	}
	// --std flag may only be transferred if the language is the same.
	// We may consider "translating" these, e.g. c++11 -> c11.
	if (Std != LangStandard::lang_unspecified && foldType(TargetType) == Type) {
	Result.CommandLine.push_back(
	"-std=" +
	std::string(LangStandard::getLangStandardForKind(Std).getName()));
	}
	Result.CommandLine.push_back(Filename);
	return Result;
	}

	private:
	// Map the language from the --std flag to that of the -x flag.
	static types::ID toType(InputKind::Language Lang) {
	switch (Lang) {
	case InputKind::C:
	return types::TY_C;
	case InputKind::CXX:
	return types::TY_CXX;
	case InputKind::ObjC:
	return types::TY_ObjC;
	case InputKind::ObjCXX:
	return types::TY_ObjCXX;
	default:
	return types::TY_INVALID;
	}
	}
	};

	// CommandIndex does the real work: given a filename, it produces the best
	// matching TransferableCommand by matching filenames. Basic strategy:
	// - Build indexes of each of the substrings we want to look up by.
	// These indexes are just sorted lists of the substrings.
	// - Forward requests to the inner CDB. If it fails, we must pick a proxy.
	// - Each criterion corresponds to a range lookup into the index, so we only
	// need O(log N) string comparisons to determine scores.
	// - We then break ties among the candidates with the highest score.
	class CommandIndex {
	public:
	CommandIndex(std::vector<TransferableCommand> AllCommands)
	: Commands(std::move(AllCommands)), Strings(Arena) {
	// Sort commands by filename for determinism (index is a tiebreaker later).
	llvm::sort(
	Commands.begin(), Commands.end(),
	[](const TransferableCommand &Left, const TransferableCommand &Right) {
	return Left.Cmd.Filename < Right.Cmd.Filename;
	});
	for (size_t I = 0; I < Commands.size(); ++I) {
	StringRef Path =
	Strings.save(StringRef(Commands[I].Cmd.Filename).lower());
	Paths.push_back({Path, I});
	Stems.emplace_back(sys::path::stem(Path), I);
	auto Dir = ++sys::path::rbegin(Path), DirEnd = sys::path::rend(Path);
	for (int J = 0; J < DirectorySegmentsIndexed && Dir != DirEnd; ++J, ++Dir)
	if (Dir->size() > ShortDirectorySegment) // not trivial ones
	Components.emplace_back(*Dir, I);
	}
	llvm::sort(Paths.begin(), Paths.end());
	llvm::sort(Stems.begin(), Stems.end());
	llvm::sort(Components.begin(), Components.end());
	}

	bool empty() const { return Commands.empty(); }

	// Returns the command that best fits OriginalFilename.
	// Candidates with PreferLanguage will be chosen over others (unless it's
	// TY_INVALID, or all candidates are bad).
	const TransferableCommand &chooseProxy(StringRef OriginalFilename,
	types::ID PreferLanguage) const {
	assert(!empty() && "need at least one candidate!");
	std::string Filename = OriginalFilename.lower();
	auto Candidates = scoreCandidates(Filename);
	std::pair<size_t, int> Best =
	pickWinner(Candidates, Filename, PreferLanguage);

	DEBUG_WITH_TYPE("interpolate",
	llvm::dbgs()
	<< "interpolate: chose "
	<< Commands[Best.first].Cmd.Filename << " as proxy for "
	<< OriginalFilename << " preferring "
	<< (PreferLanguage == types::TY_INVALID
	? "none"
	: types::getTypeName(PreferLanguage))
	<< " score=" << Best.second << "\n");
	return Commands[Best.first];
	}

	private:
	using SubstringAndIndex = std::pair<StringRef, size_t>;
	// Directory matching parameters: we look at the last two segments of the
	// parent directory (usually the semantically significant ones in practice).
	// We search only the last four of each candidate (for efficiency).
	constexpr static int DirectorySegmentsIndexed = 4;
	constexpr static int DirectorySegmentsQueried = 2;
	constexpr static int ShortDirectorySegment = 1; // Only look at longer names.

	// Award points to candidate entries that should be considered for the file.
	// Returned keys are indexes into paths, and the values are (nonzero) scores.
	DenseMap<size_t, int> scoreCandidates(StringRef Filename) const {
	// Decompose Filename into the parts we care about.
	// /some/path/complicated/project/Interesting.h
	// [-prefix--][---dir---] [-dir-] [--stem---]
	StringRef Stem = sys::path::stem(Filename);
	llvm::SmallVector<StringRef, DirectorySegmentsQueried> Dirs;
	llvm::StringRef Prefix;
	auto Dir = ++sys::path::rbegin(Filename),
	DirEnd = sys::path::rend(Filename);
	for (int I = 0; I < DirectorySegmentsQueried && Dir != DirEnd; ++I, ++Dir) {
	if (Dir->size() > ShortDirectorySegment)
	Dirs.push_back(*Dir);
	Prefix = Filename.substr(0, Dir - DirEnd);
	}

	// Now award points based on lookups into our various indexes.
	DenseMap<size_t, int> Candidates; // Index -> score.
	auto Award = [&](int Points, ArrayRef<SubstringAndIndex> Range) {
	for (const auto &Entry : Range)
	Candidates[Entry.second] += Points;
	};
	// Award one point if the file's basename is a prefix of the candidate,
	// and another if it's an exact match (so exact matches get two points).
	Award(1, indexLookup</Prefix=/true>(Stem, Stems));
	Award(1, indexLookup</Prefix=/false>(Stem, Stems));
	// For each of the last few directories in the Filename, award a point
	// if it's present in the candidate.
	for (StringRef Dir : Dirs)
	Award(1, indexLookup</Prefix=/false>(Dir, Components));
	// Award one more point if the whole rest of the path matches.
	if (sys::path::root_directory(Prefix) != Prefix)
	Award(1, indexLookup</Prefix=/true>(Prefix, Paths));
	return Candidates;
	}

	// Pick a single winner from the set of scored candidates.
	// Returns (index, score).
	std::pair<size_t, int> pickWinner(const DenseMap<size_t, int> &Candidates,
	StringRef Filename,
	types::ID PreferredLanguage) const {
	struct ScoredCandidate {
	size_t Index;
	bool Preferred;
	int Points;
	size_t PrefixLength;
	};
	// Choose the best candidate by (preferred, points, prefix length, alpha).
	ScoredCandidate Best = {size_t(-1), false, 0, 0};
	for (const auto &Candidate : Candidates) {
	ScoredCandidate S;
	S.Index = Candidate.first;
	S.Preferred = PreferredLanguage == types::TY_INVALID \|\|
	PreferredLanguage == Commands[S.Index].Type;
	S.Points = Candidate.second;
	if (!S.Preferred && Best.Preferred)
	continue;
	if (S.Preferred == Best.Preferred) {
	if (S.Points < Best.Points)
	continue;
	if (S.Points == Best.Points) {
	S.PrefixLength = matchingPrefix(Filename, Paths[S.Index].first);
	if (S.PrefixLength < Best.PrefixLength)
	continue;
	// hidden heuristics should at least be deterministic!
	if (S.PrefixLength == Best.PrefixLength)
	if (S.Index > Best.Index)
	continue;
	}
	}
	// PrefixLength was only set above if actually needed for a tiebreak.
	// But it definitely needs to be set to break ties in the future.
	S.PrefixLength = matchingPrefix(Filename, Paths[S.Index].first);
	Best = S;
	}
	// Edge case: no candidate got any points.
	// We ignore PreferredLanguage at this point (not ideal).
	if (Best.Index == size_t(-1))
	return {longestMatch(Filename, Paths).second, 0};
	return {Best.Index, Best.Points};
	}

	// Returns the range within a sorted index that compares equal to Key.
	// If Prefix is true, it's instead the range starting with Key.
	template <bool Prefix>
	ArrayRef<SubstringAndIndex>
	indexLookup(StringRef Key, const std::vector<SubstringAndIndex> &Idx) const {
	// Use pointers as iteratiors to ease conversion of result to ArrayRef.
	auto Range = std::equal_range(Idx.data(), Idx.data() + Idx.size(), Key,
	Less<Prefix>());
	return {Range.first, Range.second};
	}

	// Performs a point lookup into a nonempty index, returning a longest match.
	SubstringAndIndex
	longestMatch(StringRef Key, const std::vector<SubstringAndIndex> &Idx) const {
	assert(!Idx.empty());
	// Longest substring match will be adjacent to a direct lookup.
	auto It =
	std::lower_bound(Idx.begin(), Idx.end(), SubstringAndIndex{Key, 0});
	if (It == Idx.begin())
	return *It;
	if (It == Idx.end())
	return *--It;
	// Have to choose between It and It-1
	size_t Prefix = matchingPrefix(Key, It->first);
	size_t PrevPrefix = matchingPrefix(Key, (It - 1)->first);
	return Prefix > PrevPrefix ? It : --It;
	}

	std::vector<TransferableCommand> Commands; // Indexes point into this.
	BumpPtrAllocator Arena;
	StringSaver Strings;
	// Indexes of candidates by certain substrings.
	// String is lowercase and sorted, index points into OriginalPaths.
	std::vector<SubstringAndIndex> Paths; // Full path.
	std::vector<SubstringAndIndex> Stems; // Basename, without extension.
	std::vector<SubstringAndIndex> Components; // Last path components.
	};

	// The actual CompilationDatabase wrapper delegates to its inner database.
	// If no match, looks up a command in CommandIndex and transfers it to the file.
	class InterpolatingCompilationDatabase : public CompilationDatabase {
	public:
	InterpolatingCompilationDatabase(std::unique_ptr<CompilationDatabase> Inner)
	: Inner(std::move(Inner)), Index(allCommands()) {}

	std::vector<CompileCommand>
	getCompileCommands(StringRef Filename) const override {
	auto Known = Inner->getCompileCommands(Filename);
	if (Index.empty() \|\| !Known.empty())
	return Known;
	bool TypeCertain;
	auto Lang = guessType(Filename, &TypeCertain);
	if (!TypeCertain)
	Lang = types::TY_INVALID;
	return {Index.chooseProxy(Filename, foldType(Lang)).transferTo(Filename)};
	}

	std::vector<std::string> getAllFiles() const override {
	return Inner->getAllFiles();
	}

	std::vector<CompileCommand> getAllCompileCommands() const override {
	return Inner->getAllCompileCommands();
	}

	private:
	std::vector<TransferableCommand> allCommands() {
	std::vector<TransferableCommand> Result;
	for (auto Command : Inner->getAllCompileCommands()) {
	Result.emplace_back(std::move(Command));
	if (Result.back().Type == types::TY_INVALID)
	Result.pop_back();
	}
	return Result;
	}

	std::unique_ptr<CompilationDatabase> Inner;
	CommandIndex Index;
	};

	} // namespace

	std::unique_ptr<CompilationDatabase>
	inferMissingCompileCommands(std::unique_ptr<CompilationDatabase> Inner) {
	return llvm::make_unique<InterpolatingCompilationDatabase>(std::move(Inner));
	}

	} // namespace tooling
	} // namespace clang