path: root/clang-tools-extra/include-fixer/IncludeFixer.cpp

//===-- IncludeFixer.cpp - Include inserter based on sema callbacks -------===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#include "IncludeFixer.h"
#include "clang/Format/Format.h"
#include "clang/Frontend/CompilerInstance.h"
#include "clang/Lex/HeaderSearch.h"
#include "clang/Lex/Preprocessor.h"
#include "clang/Parse/ParseAST.h"
#include "clang/Sema/ExternalSemaSource.h"
#include "clang/Sema/Sema.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"

#define DEBUG_TYPE "include-fixer"

using namespace clang;

namespace clang {
namespace include_fixer {
namespace {

class Action;

/// Manages the parse, gathers include suggestions.
class Action : public clang::ASTFrontendAction,
               public clang::ExternalSemaSource {
public:
  explicit Action(SymbolIndexManager &SymbolIndexMgr, bool MinimizeIncludePaths)
      : SymbolIndexMgr(SymbolIndexMgr),
        MinimizeIncludePaths(MinimizeIncludePaths) {}

  std::unique_ptr<clang::ASTConsumer>
  CreateASTConsumer(clang::CompilerInstance &Compiler,
                    StringRef InFile) override {
    Filename = InFile;
    return llvm::make_unique<clang::ASTConsumer>();
  }

  void ExecuteAction() override {
    clang::CompilerInstance *Compiler = &getCompilerInstance();
    assert(!Compiler->hasSema() && "CI already has Sema");

    // Set up our hooks into sema and parse the AST.
    if (hasCodeCompletionSupport() &&
        !Compiler->getFrontendOpts().CodeCompletionAt.FileName.empty())
      Compiler->createCodeCompletionConsumer();

    clang::CodeCompleteConsumer *CompletionConsumer = nullptr;
    if (Compiler->hasCodeCompletionConsumer())
      CompletionConsumer = &Compiler->getCodeCompletionConsumer();

    Compiler->createSema(getTranslationUnitKind(), CompletionConsumer);
    Compiler->getSema().addExternalSource(this);

    clang::ParseAST(Compiler->getSema(), Compiler->getFrontendOpts().ShowStats,
                    Compiler->getFrontendOpts().SkipFunctionBodies);
  }

  /// Callback for incomplete types. If we encounter a forward declaration we
  /// have the fully qualified name ready. Just query that.
  bool MaybeDiagnoseMissingCompleteType(clang::SourceLocation Loc,
                                        clang::QualType T) override {
    // Ignore spurious callbacks from SFINAE contexts.
    if (getCompilerInstance().getSema().isSFINAEContext())
      return false;

    clang::ASTContext &context = getCompilerInstance().getASTContext();
    query(T.getUnqualifiedType().getAsString(context.getPrintingPolicy()), Loc);
    return false;
  }

  /// Callback for unknown identifiers. Try to piece together as much
  /// qualification as we can get and do a query.
  clang::TypoCorrection CorrectTypo(const DeclarationNameInfo &Typo,
                                    int LookupKind, Scope *S, CXXScopeSpec *SS,
                                    CorrectionCandidateCallback &CCC,
                                    DeclContext *MemberContext,
                                    bool EnteringContext,
                                    const ObjCObjectPointerType *OPT) override {
    // Ignore spurious callbacks from SFINAE contexts.
    if (getCompilerInstance().getSema().isSFINAEContext())
      return clang::TypoCorrection();

    std::string TypoScopeString;
    if (S) {
      // FIXME: Currently we only use namespace contexts. Use other context
      // types for query.
      for (const auto *Context = S->getEntity(); Context;
           Context = Context->getParent()) {
        if (const auto *ND = dyn_cast<NamespaceDecl>(Context)) {
          if (!ND->getName().empty())
            TypoScopeString = ND->getNameAsString() + "::" + TypoScopeString;
        }
      }
    }

    auto ExtendNestedNameSpecifier = [this](CharSourceRange Range) {
      StringRef Source =
          Lexer::getSourceText(Range, getCompilerInstance().getSourceManager(),
                               getCompilerInstance().getLangOpts());

      // Skip forward until we find a character that's neither identifier nor
      // colon. This is a bit of a hack around the fact that we will only get a
      // single callback for a long nested name if a part of the beginning is
      // unknown. For example:
      //
      // llvm::sys::path::parent_path(...)
      // ^~~~  ^~~
      //    known
      //            ^~~~
      //      unknown, last callback
      //                  ^~~~~~~~~~~
      //                  no callback
      //
      // With the extension we get the full nested name specifier including
      // parent_path.
      // FIXME: Don't rely on source text.
      const char *End = Source.end();
      while (isIdentifierBody(*End) || *End == ':')
        ++End;

      return std::string(Source.begin(), End);
    };

    /// If we have a scope specification, use that to get more precise results.
    std::string QueryString;
    if (SS && SS->getRange().isValid()) {
      auto Range = CharSourceRange::getTokenRange(SS->getRange().getBegin(),
                                                  Typo.getLoc());

      QueryString = ExtendNestedNameSpecifier(Range);
    } else if (Typo.getName().isIdentifier() && !Typo.getLoc().isMacroID()) {
      auto Range =
          CharSourceRange::getTokenRange(Typo.getBeginLoc(), Typo.getEndLoc());

      QueryString = ExtendNestedNameSpecifier(Range);
    } else {
      QueryString = Typo.getAsString();
    }

    // Follow C++ Lookup rules. Firstly, lookup the identifier with scoped
    // namespace contexts. If fails, falls back to identifier.
    // For example:
    //
    // namespace a {
    // b::foo f;
    // }
    //
    // 1. lookup a::b::foo.
    // 2. lookup b::foo.
    if (!query(TypoScopeString + QueryString, Typo.getLoc()))
      query(QueryString, Typo.getLoc());

    // FIXME: We should just return the name we got as input here and prevent
    // clang from trying to correct the typo by itself. That may change the
    // identifier to something that's not wanted by the user.
    return clang::TypoCorrection();
  }

  StringRef filename() const { return Filename; }

  /// Get the minimal include for a given path.
  std::string minimizeInclude(StringRef Include,
                              const clang::SourceManager &SourceManager,
                              clang::HeaderSearch &HeaderSearch) {
    if (!MinimizeIncludePaths)
      return Include;

    // Get the FileEntry for the include.
    StringRef StrippedInclude = Include.trim("\"<>");
    const FileEntry *Entry =
        SourceManager.getFileManager().getFile(StrippedInclude);

    // If the file doesn't exist return the path from the database.
    // FIXME: This should never happen.
    if (!Entry)
      return Include;

    bool IsSystem;
    std::string Suggestion =
        HeaderSearch.suggestPathToFileForDiagnostics(Entry, &IsSystem);

    return IsSystem ? '<' + Suggestion + '>' : '"' + Suggestion + '"';
  }

  /// Get the include fixer context for the queried symbol.
  IncludeFixerContext
  getIncludeFixerContext(const clang::SourceManager &SourceManager,
                         clang::HeaderSearch &HeaderSearch) {
    IncludeFixerContext FixerContext;
    if (SymbolQueryResults.empty())
      return FixerContext;

    FixerContext.SymbolIdentifer = QuerySymbol;
    for (const auto &Header : SymbolQueryResults)
      FixerContext.Headers.push_back(
          minimizeInclude(Header, SourceManager, HeaderSearch));

    return FixerContext;
  }

private:
  /// Query the database for a given identifier.
  bool query(StringRef Query, SourceLocation Loc) {
    assert(!Query.empty() && "Empty query!");

    // Skip other identifers once we have discovered an identfier successfully.
    if (!SymbolQueryResults.empty())
      return false;

    DEBUG(llvm::dbgs() << "Looking up '" << Query << "' at ");
    DEBUG(Loc.print(llvm::dbgs(), getCompilerInstance().getSourceManager()));
    DEBUG(llvm::dbgs() << " ...");

    QuerySymbol = Query.str();
    SymbolQueryResults = SymbolIndexMgr.search(Query);
    DEBUG(llvm::dbgs() << SymbolQueryResults.size() << " replies\n");
    return !SymbolQueryResults.empty();
  }

  /// The client to use to find cross-references.
  SymbolIndexManager &SymbolIndexMgr;

  /// The absolute path to the file being processed.
  std::string Filename;

  /// The symbol being queried.
  std::string QuerySymbol;

  /// The query results of an identifier. We only include the first discovered
  /// identifier to avoid getting caught in results from error recovery.
  std::vector<std::string> SymbolQueryResults;

  /// Whether we should use the smallest possible include path.
  bool MinimizeIncludePaths = true;
};

} // namespace

IncludeFixerActionFactory::IncludeFixerActionFactory(
    SymbolIndexManager &SymbolIndexMgr, IncludeFixerContext &Context,
    StringRef StyleName, bool MinimizeIncludePaths)
    : SymbolIndexMgr(SymbolIndexMgr), Context(Context),
      MinimizeIncludePaths(MinimizeIncludePaths) {}

IncludeFixerActionFactory::~IncludeFixerActionFactory() = default;

bool IncludeFixerActionFactory::runInvocation(
    clang::CompilerInvocation *Invocation, clang::FileManager *Files,
    std::shared_ptr<clang::PCHContainerOperations> PCHContainerOps,
    clang::DiagnosticConsumer *Diagnostics) {
  assert(Invocation->getFrontendOpts().Inputs.size() == 1);

  // Set up Clang.
  clang::CompilerInstance Compiler(PCHContainerOps);
  Compiler.setInvocation(Invocation);
  Compiler.setFileManager(Files);

  // Create the compiler's actual diagnostics engine. We want to drop all
  // diagnostics here.
  Compiler.createDiagnostics(new clang::IgnoringDiagConsumer,
                             /*ShouldOwnClient=*/true);
  Compiler.createSourceManager(*Files);

  // We abort on fatal errors so don't let a large number of errors become
  // fatal. A missing #include can cause thousands of errors.
  Compiler.getDiagnostics().setErrorLimit(0);

  // Run the parser, gather missing includes.
  auto ScopedToolAction =
      llvm::make_unique<Action>(SymbolIndexMgr, MinimizeIncludePaths);
  Compiler.ExecuteAction(*ScopedToolAction);

  Context = ScopedToolAction->getIncludeFixerContext(
      Compiler.getSourceManager(),
      Compiler.getPreprocessor().getHeaderSearchInfo());

  // Technically this should only return true if we're sure that we have a
  // parseable file. We don't know that though. Only inform users of fatal
  // errors.
  return !Compiler.getDiagnostics().hasFatalErrorOccurred();
}

tooling::Replacements
createInsertHeaderReplacements(StringRef Code, StringRef FilePath,
                               StringRef Header,
                               const clang::format::FormatStyle &Style) {
  if (Header.empty())
    return tooling::Replacements();
  std::string IncludeName = "#include " + Header.str() + "\n";
  // Create replacements for the new header.
  clang::tooling::Replacements Insertions = {
      tooling::Replacement(FilePath, UINT_MAX, 0, IncludeName)};

  return formatReplacements(
      Code, cleanupAroundReplacements(Code, Insertions, Style), Style);
}

} // namespace include_fixer
} // namespace clang