Mercurial > hg > CbC > CbC_llvm
view clang-tools-extra/clangd/SourceCode.cpp @ 206:f17a3b42b08b
Added tag before-12 for changeset b7591485f4cd
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 07 Jun 2021 21:25:57 +0900 |
| parents | 0572611fdcc8 |
| children | 2e18cbf3894f |
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//===--- SourceCode.h - Manipulating source code as strings -----*- 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 "SourceCode.h" #include "FuzzyMatch.h" #include "Protocol.h" #include "refactor/Tweak.h" #include "support/Context.h" #include "support/Logger.h" #include "clang/AST/ASTContext.h" #include "clang/Basic/LangOptions.h" #include "clang/Basic/SourceLocation.h" #include "clang/Basic/SourceManager.h" #include "clang/Basic/TokenKinds.h" #include "clang/Driver/Types.h" #include "clang/Format/Format.h" #include "clang/Lex/Lexer.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/Token.h" #include "clang/Tooling/Core/Replacement.h" #include "clang/Tooling/Syntax/Tokens.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/None.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/StringRef.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Errc.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/LineIterator.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/SHA1.h" #include "llvm/Support/VirtualFileSystem.h" #include "llvm/Support/xxhash.h" #include <algorithm> #include <cstddef> #include <string> #include <vector> namespace clang { namespace clangd { // Here be dragons. LSP positions use columns measured in *UTF-16 code units*! // Clangd uses UTF-8 and byte-offsets internally, so conversion is nontrivial. // Iterates over unicode codepoints in the (UTF-8) string. For each, // invokes CB(UTF-8 length, UTF-16 length), and breaks if it returns true. // Returns true if CB returned true, false if we hit the end of string. template <typename Callback> static bool iterateCodepoints(llvm::StringRef U8, const Callback &CB) { // A codepoint takes two UTF-16 code unit if it's astral (outside BMP). // Astral codepoints are encoded as 4 bytes in UTF-8, starting with 11110xxx. for (size_t I = 0; I < U8.size();) { unsigned char C = static_cast<unsigned char>(U8[I]); if (LLVM_LIKELY(!(C & 0x80))) { // ASCII character. if (CB(1, 1)) return true; ++I; continue; } // This convenient property of UTF-8 holds for all non-ASCII characters. size_t UTF8Length = llvm::countLeadingOnes(C); // 0xxx is ASCII, handled above. 10xxx is a trailing byte, invalid here. // 11111xxx is not valid UTF-8 at all. Assert because it's probably our bug. assert((UTF8Length >= 2 && UTF8Length <= 4) && "Invalid UTF-8, or transcoding bug?"); I += UTF8Length; // Skip over all trailing bytes. // A codepoint takes two UTF-16 code unit if it's astral (outside BMP). // Astral codepoints are encoded as 4 bytes in UTF-8 (11110xxx ...) if (CB(UTF8Length, UTF8Length == 4 ? 2 : 1)) return true; } return false; } // Returns the byte offset into the string that is an offset of \p Units in // the specified encoding. // Conceptually, this converts to the encoding, truncates to CodeUnits, // converts back to UTF-8, and returns the length in bytes. static size_t measureUnits(llvm::StringRef U8, int Units, OffsetEncoding Enc, bool &Valid) { Valid = Units >= 0; if (Units <= 0) return 0; size_t Result = 0; switch (Enc) { case OffsetEncoding::UTF8: Result = Units; break; case OffsetEncoding::UTF16: Valid = iterateCodepoints(U8, [&](int U8Len, int U16Len) { Result += U8Len; Units -= U16Len; return Units <= 0; }); if (Units < 0) // Offset in the middle of a surrogate pair. Valid = false; break; case OffsetEncoding::UTF32: Valid = iterateCodepoints(U8, [&](int U8Len, int U16Len) { Result += U8Len; Units--; return Units <= 0; }); break; case OffsetEncoding::UnsupportedEncoding: llvm_unreachable("unsupported encoding"); } // Don't return an out-of-range index if we overran. if (Result > U8.size()) { Valid = false; return U8.size(); } return Result; } Key<OffsetEncoding> kCurrentOffsetEncoding; static OffsetEncoding lspEncoding() { auto *Enc = Context::current().get(kCurrentOffsetEncoding); return Enc ? *Enc : OffsetEncoding::UTF16; } // Like most strings in clangd, the input is UTF-8 encoded. size_t lspLength(llvm::StringRef Code) { size_t Count = 0; switch (lspEncoding()) { case OffsetEncoding::UTF8: Count = Code.size(); break; case OffsetEncoding::UTF16: iterateCodepoints(Code, [&](int U8Len, int U16Len) { Count += U16Len; return false; }); break; case OffsetEncoding::UTF32: iterateCodepoints(Code, [&](int U8Len, int U16Len) { ++Count; return false; }); break; case OffsetEncoding::UnsupportedEncoding: llvm_unreachable("unsupported encoding"); } return Count; } llvm::Expected<size_t> positionToOffset(llvm::StringRef Code, Position P, bool AllowColumnsBeyondLineLength) { if (P.line < 0) return llvm::make_error<llvm::StringError>( llvm::formatv("Line value can't be negative ({0})", P.line), llvm::errc::invalid_argument); if (P.character < 0) return llvm::make_error<llvm::StringError>( llvm::formatv("Character value can't be negative ({0})", P.character), llvm::errc::invalid_argument); size_t StartOfLine = 0; for (int I = 0; I != P.line; ++I) { size_t NextNL = Code.find('\n', StartOfLine); if (NextNL == llvm::StringRef::npos) return llvm::make_error<llvm::StringError>( llvm::formatv("Line value is out of range ({0})", P.line), llvm::errc::invalid_argument); StartOfLine = NextNL + 1; } StringRef Line = Code.substr(StartOfLine).take_until([](char C) { return C == '\n'; }); // P.character may be in UTF-16, transcode if necessary. bool Valid; size_t ByteInLine = measureUnits(Line, P.character, lspEncoding(), Valid); if (!Valid && !AllowColumnsBeyondLineLength) return llvm::make_error<llvm::StringError>( llvm::formatv("{0} offset {1} is invalid for line {2}", lspEncoding(), P.character, P.line), llvm::errc::invalid_argument); return StartOfLine + ByteInLine; } Position offsetToPosition(llvm::StringRef Code, size_t Offset) { Offset = std::min(Code.size(), Offset); llvm::StringRef Before = Code.substr(0, Offset); int Lines = Before.count('\n'); size_t PrevNL = Before.rfind('\n'); size_t StartOfLine = (PrevNL == llvm::StringRef::npos) ? 0 : (PrevNL + 1); Position Pos; Pos.line = Lines; Pos.character = lspLength(Before.substr(StartOfLine)); return Pos; } Position sourceLocToPosition(const SourceManager &SM, SourceLocation Loc) { // We use the SourceManager's line tables, but its column number is in bytes. FileID FID; unsigned Offset; std::tie(FID, Offset) = SM.getDecomposedSpellingLoc(Loc); Position P; P.line = static_cast<int>(SM.getLineNumber(FID, Offset)) - 1; bool Invalid = false; llvm::StringRef Code = SM.getBufferData(FID, &Invalid); if (!Invalid) { auto ColumnInBytes = SM.getColumnNumber(FID, Offset) - 1; auto LineSoFar = Code.substr(Offset - ColumnInBytes, ColumnInBytes); P.character = lspLength(LineSoFar); } return P; } bool isSpelledInSource(SourceLocation Loc, const SourceManager &SM) { if (Loc.isMacroID()) { std::string PrintLoc = SM.getSpellingLoc(Loc).printToString(SM); if (llvm::StringRef(PrintLoc).startswith("<scratch") || llvm::StringRef(PrintLoc).startswith("<command line>")) return false; } return true; } bool isValidFileRange(const SourceManager &Mgr, SourceRange R) { if (!R.getBegin().isValid() || !R.getEnd().isValid()) return false; FileID BeginFID; size_t BeginOffset = 0; std::tie(BeginFID, BeginOffset) = Mgr.getDecomposedLoc(R.getBegin()); FileID EndFID; size_t EndOffset = 0; std::tie(EndFID, EndOffset) = Mgr.getDecomposedLoc(R.getEnd()); return BeginFID.isValid() && BeginFID == EndFID && BeginOffset <= EndOffset; } SourceLocation includeHashLoc(FileID IncludedFile, const SourceManager &SM) { assert(SM.getLocForEndOfFile(IncludedFile).isFileID()); FileID IncludingFile; unsigned Offset; std::tie(IncludingFile, Offset) = SM.getDecomposedExpansionLoc(SM.getIncludeLoc(IncludedFile)); bool Invalid = false; llvm::StringRef Buf = SM.getBufferData(IncludingFile, &Invalid); if (Invalid) return SourceLocation(); // Now buf is "...\n#include <foo>\n..." // and Offset points here: ^ // Rewind to the preceding # on the line. assert(Offset < Buf.size()); for (;; --Offset) { if (Buf[Offset] == '#') return SM.getComposedLoc(IncludingFile, Offset); if (Buf[Offset] == '\n' || Offset == 0) // no hash, what's going on? return SourceLocation(); } } static unsigned getTokenLengthAtLoc(SourceLocation Loc, const SourceManager &SM, const LangOptions &LangOpts) { Token TheTok; if (Lexer::getRawToken(Loc, TheTok, SM, LangOpts)) return 0; // FIXME: Here we check whether the token at the location is a greatergreater // (>>) token and consider it as a single greater (>). This is to get it // working for templates but it isn't correct for the right shift operator. We // can avoid this by using half open char ranges in getFileRange() but getting // token ending is not well supported in macroIDs. if (TheTok.is(tok::greatergreater)) return 1; return TheTok.getLength(); } // Returns location of the last character of the token at a given loc static SourceLocation getLocForTokenEnd(SourceLocation BeginLoc, const SourceManager &SM, const LangOptions &LangOpts) { unsigned Len = getTokenLengthAtLoc(BeginLoc, SM, LangOpts); return BeginLoc.getLocWithOffset(Len ? Len - 1 : 0); } // Returns location of the starting of the token at a given EndLoc static SourceLocation getLocForTokenBegin(SourceLocation EndLoc, const SourceManager &SM, const LangOptions &LangOpts) { return EndLoc.getLocWithOffset( -(signed)getTokenLengthAtLoc(EndLoc, SM, LangOpts)); } // Converts a char source range to a token range. static SourceRange toTokenRange(CharSourceRange Range, const SourceManager &SM, const LangOptions &LangOpts) { if (!Range.isTokenRange()) Range.setEnd(getLocForTokenBegin(Range.getEnd(), SM, LangOpts)); return Range.getAsRange(); } // Returns the union of two token ranges. // To find the maximum of the Ends of the ranges, we compare the location of the // last character of the token. static SourceRange unionTokenRange(SourceRange R1, SourceRange R2, const SourceManager &SM, const LangOptions &LangOpts) { SourceLocation Begin = SM.isBeforeInTranslationUnit(R1.getBegin(), R2.getBegin()) ? R1.getBegin() : R2.getBegin(); SourceLocation End = SM.isBeforeInTranslationUnit(getLocForTokenEnd(R1.getEnd(), SM, LangOpts), getLocForTokenEnd(R2.getEnd(), SM, LangOpts)) ? R2.getEnd() : R1.getEnd(); return SourceRange(Begin, End); } // Given a range whose endpoints may be in different expansions or files, // tries to find a range within a common file by following up the expansion and // include location in each. static SourceRange rangeInCommonFile(SourceRange R, const SourceManager &SM, const LangOptions &LangOpts) { // Fast path for most common cases. if (SM.isWrittenInSameFile(R.getBegin(), R.getEnd())) return R; // Record the stack of expansion locations for the beginning, keyed by FileID. llvm::DenseMap<FileID, SourceLocation> BeginExpansions; for (SourceLocation Begin = R.getBegin(); Begin.isValid(); Begin = Begin.isFileID() ? includeHashLoc(SM.getFileID(Begin), SM) : SM.getImmediateExpansionRange(Begin).getBegin()) { BeginExpansions[SM.getFileID(Begin)] = Begin; } // Move up the stack of expansion locations for the end until we find the // location in BeginExpansions with that has the same file id. for (SourceLocation End = R.getEnd(); End.isValid(); End = End.isFileID() ? includeHashLoc(SM.getFileID(End), SM) : toTokenRange(SM.getImmediateExpansionRange(End), SM, LangOpts) .getEnd()) { auto It = BeginExpansions.find(SM.getFileID(End)); if (It != BeginExpansions.end()) { if (SM.getFileOffset(It->second) > SM.getFileOffset(End)) return SourceLocation(); return {It->second, End}; } } return SourceRange(); } // Find an expansion range (not necessarily immediate) the ends of which are in // the same file id. static SourceRange getExpansionTokenRangeInSameFile(SourceLocation Loc, const SourceManager &SM, const LangOptions &LangOpts) { return rangeInCommonFile( toTokenRange(SM.getImmediateExpansionRange(Loc), SM, LangOpts), SM, LangOpts); } // Returns the file range for a given Location as a Token Range // This is quite similar to getFileLoc in SourceManager as both use // getImmediateExpansionRange and getImmediateSpellingLoc (for macro IDs). // However: // - We want to maintain the full range information as we move from one file to // the next. getFileLoc only uses the BeginLoc of getImmediateExpansionRange. // - We want to split '>>' tokens as the lexer parses the '>>' in nested // template instantiations as a '>>' instead of two '>'s. // There is also getExpansionRange but it simply calls // getImmediateExpansionRange on the begin and ends separately which is wrong. static SourceRange getTokenFileRange(SourceLocation Loc, const SourceManager &SM, const LangOptions &LangOpts) { SourceRange FileRange = Loc; while (!FileRange.getBegin().isFileID()) { if (SM.isMacroArgExpansion(FileRange.getBegin())) { FileRange = unionTokenRange( SM.getImmediateSpellingLoc(FileRange.getBegin()), SM.getImmediateSpellingLoc(FileRange.getEnd()), SM, LangOpts); assert(SM.isWrittenInSameFile(FileRange.getBegin(), FileRange.getEnd())); } else { SourceRange ExpansionRangeForBegin = getExpansionTokenRangeInSameFile(FileRange.getBegin(), SM, LangOpts); SourceRange ExpansionRangeForEnd = getExpansionTokenRangeInSameFile(FileRange.getEnd(), SM, LangOpts); if (ExpansionRangeForBegin.isInvalid() || ExpansionRangeForEnd.isInvalid()) return SourceRange(); assert(SM.isWrittenInSameFile(ExpansionRangeForBegin.getBegin(), ExpansionRangeForEnd.getBegin()) && "Both Expansion ranges should be in same file."); FileRange = unionTokenRange(ExpansionRangeForBegin, ExpansionRangeForEnd, SM, LangOpts); } } return FileRange; } bool isInsideMainFile(SourceLocation Loc, const SourceManager &SM) { if (!Loc.isValid()) return false; FileID FID = SM.getFileID(SM.getExpansionLoc(Loc)); return FID == SM.getMainFileID() || FID == SM.getPreambleFileID(); } llvm::Optional<SourceRange> toHalfOpenFileRange(const SourceManager &SM, const LangOptions &LangOpts, SourceRange R) { SourceRange R1 = getTokenFileRange(R.getBegin(), SM, LangOpts); if (!isValidFileRange(SM, R1)) return llvm::None; SourceRange R2 = getTokenFileRange(R.getEnd(), SM, LangOpts); if (!isValidFileRange(SM, R2)) return llvm::None; SourceRange Result = rangeInCommonFile(unionTokenRange(R1, R2, SM, LangOpts), SM, LangOpts); unsigned TokLen = getTokenLengthAtLoc(Result.getEnd(), SM, LangOpts); // Convert from closed token range to half-open (char) range Result.setEnd(Result.getEnd().getLocWithOffset(TokLen)); if (!isValidFileRange(SM, Result)) return llvm::None; return Result; } llvm::StringRef toSourceCode(const SourceManager &SM, SourceRange R) { assert(isValidFileRange(SM, R)); bool Invalid = false; auto *Buf = SM.getBuffer(SM.getFileID(R.getBegin()), &Invalid); assert(!Invalid); size_t BeginOffset = SM.getFileOffset(R.getBegin()); size_t EndOffset = SM.getFileOffset(R.getEnd()); return Buf->getBuffer().substr(BeginOffset, EndOffset - BeginOffset); } llvm::Expected<SourceLocation> sourceLocationInMainFile(const SourceManager &SM, Position P) { llvm::StringRef Code = SM.getBuffer(SM.getMainFileID())->getBuffer(); auto Offset = positionToOffset(Code, P, /*AllowColumnBeyondLineLength=*/false); if (!Offset) return Offset.takeError(); return SM.getLocForStartOfFile(SM.getMainFileID()).getLocWithOffset(*Offset); } Range halfOpenToRange(const SourceManager &SM, CharSourceRange R) { // Clang is 1-based, LSP uses 0-based indexes. Position Begin = sourceLocToPosition(SM, R.getBegin()); Position End = sourceLocToPosition(SM, R.getEnd()); return {Begin, End}; } std::pair<size_t, size_t> offsetToClangLineColumn(llvm::StringRef Code, size_t Offset) { Offset = std::min(Code.size(), Offset); llvm::StringRef Before = Code.substr(0, Offset); int Lines = Before.count('\n'); size_t PrevNL = Before.rfind('\n'); size_t StartOfLine = (PrevNL == llvm::StringRef::npos) ? 0 : (PrevNL + 1); return {Lines + 1, Offset - StartOfLine + 1}; } std::pair<StringRef, StringRef> splitQualifiedName(StringRef QName) { size_t Pos = QName.rfind("::"); if (Pos == llvm::StringRef::npos) return {llvm::StringRef(), QName}; return {QName.substr(0, Pos + 2), QName.substr(Pos + 2)}; } TextEdit replacementToEdit(llvm::StringRef Code, const tooling::Replacement &R) { Range ReplacementRange = { offsetToPosition(Code, R.getOffset()), offsetToPosition(Code, R.getOffset() + R.getLength())}; return {ReplacementRange, std::string(R.getReplacementText())}; } std::vector<TextEdit> replacementsToEdits(llvm::StringRef Code, const tooling::Replacements &Repls) { std::vector<TextEdit> Edits; for (const auto &R : Repls) Edits.push_back(replacementToEdit(Code, R)); return Edits; } llvm::Optional<std::string> getCanonicalPath(const FileEntry *F, const SourceManager &SourceMgr) { if (!F) return None; llvm::SmallString<128> FilePath = F->getName(); if (!llvm::sys::path::is_absolute(FilePath)) { if (auto EC = SourceMgr.getFileManager().getVirtualFileSystem().makeAbsolute( FilePath)) { elog("Could not turn relative path '{0}' to absolute: {1}", FilePath, EC.message()); return None; } } // Handle the symbolic link path case where the current working directory // (getCurrentWorkingDirectory) is a symlink. We always want to the real // file path (instead of the symlink path) for the C++ symbols. // // Consider the following example: // // src dir: /project/src/foo.h // current working directory (symlink): /tmp/build -> /project/src/ // // The file path of Symbol is "/project/src/foo.h" instead of // "/tmp/build/foo.h" if (auto Dir = SourceMgr.getFileManager().getDirectory( llvm::sys::path::parent_path(FilePath))) { llvm::SmallString<128> RealPath; llvm::StringRef DirName = SourceMgr.getFileManager().getCanonicalName(*Dir); llvm::sys::path::append(RealPath, DirName, llvm::sys::path::filename(FilePath)); return RealPath.str().str(); } return FilePath.str().str(); } TextEdit toTextEdit(const FixItHint &FixIt, const SourceManager &M, const LangOptions &L) { TextEdit Result; Result.range = halfOpenToRange(M, Lexer::makeFileCharRange(FixIt.RemoveRange, M, L)); Result.newText = FixIt.CodeToInsert; return Result; } FileDigest digest(llvm::StringRef Content) { uint64_t Hash{llvm::xxHash64(Content)}; FileDigest Result; for (unsigned I = 0; I < Result.size(); ++I) { Result[I] = uint8_t(Hash); Hash >>= 8; } return Result; } llvm::Optional<FileDigest> digestFile(const SourceManager &SM, FileID FID) { bool Invalid = false; llvm::StringRef Content = SM.getBufferData(FID, &Invalid); if (Invalid) return None; return digest(Content); } format::FormatStyle getFormatStyleForFile(llvm::StringRef File, llvm::StringRef Content, llvm::vfs::FileSystem *FS) { auto Style = format::getStyle(format::DefaultFormatStyle, File, format::DefaultFallbackStyle, Content, FS); if (!Style) { log("getStyle() failed for file {0}: {1}. Fallback is LLVM style.", File, Style.takeError()); return format::getLLVMStyle(); } return *Style; } llvm::Expected<tooling::Replacements> cleanupAndFormat(StringRef Code, const tooling::Replacements &Replaces, const format::FormatStyle &Style) { auto CleanReplaces = cleanupAroundReplacements(Code, Replaces, Style); if (!CleanReplaces) return CleanReplaces; return formatReplacements(Code, std::move(*CleanReplaces), Style); } static void lex(llvm::StringRef Code, const LangOptions &LangOpts, llvm::function_ref<void(const syntax::Token &, const SourceManager &SM)> Action) { // FIXME: InMemoryFileAdapter crashes unless the buffer is null terminated! std::string NullTerminatedCode = Code.str(); SourceManagerForFile FileSM("dummy.cpp", NullTerminatedCode); auto &SM = FileSM.get(); for (const auto &Tok : syntax::tokenize(SM.getMainFileID(), SM, LangOpts)) Action(Tok, SM); } llvm::StringMap<unsigned> collectIdentifiers(llvm::StringRef Content, const format::FormatStyle &Style) { llvm::StringMap<unsigned> Identifiers; auto LangOpt = format::getFormattingLangOpts(Style); lex(Content, LangOpt, [&](const syntax::Token &Tok, const SourceManager &SM) { if (Tok.kind() == tok::identifier) ++Identifiers[Tok.text(SM)]; // FIXME: Should this function really return keywords too ? else if (const auto *Keyword = tok::getKeywordSpelling(Tok.kind())) ++Identifiers[Keyword]; }); return Identifiers; } std::vector<Range> collectIdentifierRanges(llvm::StringRef Identifier, llvm::StringRef Content, const LangOptions &LangOpts) { std::vector<Range> Ranges; lex(Content, LangOpts, [&](const syntax::Token &Tok, const SourceManager &SM) { if (Tok.kind() != tok::identifier || Tok.text(SM) != Identifier) return; Ranges.push_back(halfOpenToRange(SM, Tok.range(SM).toCharRange(SM))); }); return Ranges; } namespace { struct NamespaceEvent { enum { BeginNamespace, // namespace <ns> {. Payload is resolved <ns>. EndNamespace, // } // namespace <ns>. Payload is resolved *outer* // namespace. UsingDirective // using namespace <ns>. Payload is unresolved <ns>. } Trigger; std::string Payload; Position Pos; }; // Scans C++ source code for constructs that change the visible namespaces. void parseNamespaceEvents(llvm::StringRef Code, const LangOptions &LangOpts, llvm::function_ref<void(NamespaceEvent)> Callback) { // Stack of enclosing namespaces, e.g. {"clang", "clangd"} std::vector<std::string> Enclosing; // Contains e.g. "clang", "clangd" // Stack counts open braces. true if the brace opened a namespace. std::vector<bool> BraceStack; enum { Default, Namespace, // just saw 'namespace' NamespaceName, // just saw 'namespace' NSName Using, // just saw 'using' UsingNamespace, // just saw 'using namespace' UsingNamespaceName, // just saw 'using namespace' NSName } State = Default; std::string NSName; NamespaceEvent Event; lex(Code, LangOpts, [&](const syntax::Token &Tok, const SourceManager &SM) { Event.Pos = sourceLocToPosition(SM, Tok.location()); switch (Tok.kind()) { case tok::kw_using: State = State == Default ? Using : Default; break; case tok::kw_namespace: switch (State) { case Using: State = UsingNamespace; break; case Default: State = Namespace; break; default: State = Default; break; } break; case tok::identifier: switch (State) { case UsingNamespace: NSName.clear(); LLVM_FALLTHROUGH; case UsingNamespaceName: NSName.append(Tok.text(SM).str()); State = UsingNamespaceName; break; case Namespace: NSName.clear(); LLVM_FALLTHROUGH; case NamespaceName: NSName.append(Tok.text(SM).str()); State = NamespaceName; break; case Using: case Default: State = Default; break; } break; case tok::coloncolon: // This can come at the beginning or in the middle of a namespace // name. switch (State) { case UsingNamespace: NSName.clear(); LLVM_FALLTHROUGH; case UsingNamespaceName: NSName.append("::"); State = UsingNamespaceName; break; case NamespaceName: NSName.append("::"); State = NamespaceName; break; case Namespace: // Not legal here. case Using: case Default: State = Default; break; } break; case tok::l_brace: // Record which { started a namespace, so we know when } ends one. if (State == NamespaceName) { // Parsed: namespace <name> { BraceStack.push_back(true); Enclosing.push_back(NSName); Event.Trigger = NamespaceEvent::BeginNamespace; Event.Payload = llvm::join(Enclosing, "::"); Callback(Event); } else { // This case includes anonymous namespaces (State = Namespace). // For our purposes, they're not namespaces and we ignore them. BraceStack.push_back(false); } State = Default; break; case tok::r_brace: // If braces are unmatched, we're going to be confused, but don't // crash. if (!BraceStack.empty()) { if (BraceStack.back()) { // Parsed: } // namespace Enclosing.pop_back(); Event.Trigger = NamespaceEvent::EndNamespace; Event.Payload = llvm::join(Enclosing, "::"); Callback(Event); } BraceStack.pop_back(); } break; case tok::semi: if (State == UsingNamespaceName) { // Parsed: using namespace <name> ; Event.Trigger = NamespaceEvent::UsingDirective; Event.Payload = std::move(NSName); Callback(Event); } State = Default; break; default: State = Default; break; } }); } // Returns the prefix namespaces of NS: {"" ... NS}. llvm::SmallVector<llvm::StringRef, 8> ancestorNamespaces(llvm::StringRef NS) { llvm::SmallVector<llvm::StringRef, 8> Results; Results.push_back(NS.take_front(0)); NS.split(Results, "::", /*MaxSplit=*/-1, /*KeepEmpty=*/false); for (llvm::StringRef &R : Results) R = NS.take_front(R.end() - NS.begin()); return Results; } } // namespace std::vector<std::string> visibleNamespaces(llvm::StringRef Code, const LangOptions &LangOpts) { std::string Current; // Map from namespace to (resolved) namespaces introduced via using directive. llvm::StringMap<llvm::StringSet<>> UsingDirectives; parseNamespaceEvents(Code, LangOpts, [&](NamespaceEvent Event) { llvm::StringRef NS = Event.Payload; switch (Event.Trigger) { case NamespaceEvent::BeginNamespace: case NamespaceEvent::EndNamespace: Current = std::move(Event.Payload); break; case NamespaceEvent::UsingDirective: if (NS.consume_front("::")) UsingDirectives[Current].insert(NS); else { for (llvm::StringRef Enclosing : ancestorNamespaces(Current)) { if (Enclosing.empty()) UsingDirectives[Current].insert(NS); else UsingDirectives[Current].insert((Enclosing + "::" + NS).str()); } } break; } }); std::vector<std::string> Found; for (llvm::StringRef Enclosing : ancestorNamespaces(Current)) { Found.push_back(std::string(Enclosing)); auto It = UsingDirectives.find(Enclosing); if (It != UsingDirectives.end()) for (const auto &Used : It->second) Found.push_back(std::string(Used.getKey())); } llvm::sort(Found, [&](const std::string &LHS, const std::string &RHS) { if (Current == RHS) return false; if (Current == LHS) return true; return LHS < RHS; }); Found.erase(std::unique(Found.begin(), Found.end()), Found.end()); return Found; } llvm::StringSet<> collectWords(llvm::StringRef Content) { // We assume short words are not significant. // We may want to consider other stopwords, e.g. language keywords. // (A very naive implementation showed no benefit, but lexing might do better) static constexpr int MinWordLength = 4; std::vector<CharRole> Roles(Content.size()); calculateRoles(Content, Roles); llvm::StringSet<> Result; llvm::SmallString<256> Word; auto Flush = [&] { if (Word.size() >= MinWordLength) { for (char &C : Word) C = llvm::toLower(C); Result.insert(Word); } Word.clear(); }; for (unsigned I = 0; I < Content.size(); ++I) { switch (Roles[I]) { case Head: Flush(); LLVM_FALLTHROUGH; case Tail: Word.push_back(Content[I]); break; case Unknown: case Separator: Flush(); break; } } Flush(); return Result; } static bool isLikelyIdentifier(llvm::StringRef Word, llvm::StringRef Before, llvm::StringRef After) { // `foo` is an identifier. if (Before.endswith("`") && After.startswith("`")) return true; // In foo::bar, both foo and bar are identifiers. if (Before.endswith("::") || After.startswith("::")) return true; // Doxygen tags like \c foo indicate identifiers. // Don't search too far back. // This duplicates clang's doxygen parser, revisit if it gets complicated. Before = Before.take_back(100); // Don't search too far back. auto Pos = Before.find_last_of("\\@"); if (Pos != llvm::StringRef::npos) { llvm::StringRef Tag = Before.substr(Pos + 1).rtrim(' '); if (Tag == "p" || Tag == "c" || Tag == "class" || Tag == "tparam" || Tag == "param" || Tag == "param[in]" || Tag == "param[out]" || Tag == "param[in,out]" || Tag == "retval" || Tag == "throw" || Tag == "throws" || Tag == "link") return true; } // Word contains underscore. // This handles things like snake_case and MACRO_CASE. if (Word.contains('_')) { return true; } // Word contains capital letter other than at beginning. // This handles things like lowerCamel and UpperCamel. // The check for also containing a lowercase letter is to rule out // initialisms like "HTTP". bool HasLower = Word.find_if(clang::isLowercase) != StringRef::npos; bool HasUpper = Word.substr(1).find_if(clang::isUppercase) != StringRef::npos; if (HasLower && HasUpper) { return true; } // FIXME: consider mid-sentence Capitalization? return false; } llvm::Optional<SpelledWord> SpelledWord::touching(SourceLocation SpelledLoc, const syntax::TokenBuffer &TB, const LangOptions &LangOpts) { const auto &SM = TB.sourceManager(); auto Touching = syntax::spelledTokensTouching(SpelledLoc, TB); for (const auto &T : Touching) { // If the token is an identifier or a keyword, don't use any heuristics. if (tok::isAnyIdentifier(T.kind()) || tok::getKeywordSpelling(T.kind())) { SpelledWord Result; Result.Location = T.location(); Result.Text = T.text(SM); Result.LikelyIdentifier = tok::isAnyIdentifier(T.kind()); Result.PartOfSpelledToken = &T; Result.SpelledToken = &T; auto Expanded = TB.expandedTokens(SM.getMacroArgExpandedLocation(T.location())); if (Expanded.size() == 1 && Expanded.front().text(SM) == Result.Text) Result.ExpandedToken = &Expanded.front(); return Result; } } FileID File; unsigned Offset; std::tie(File, Offset) = SM.getDecomposedLoc(SpelledLoc); bool Invalid = false; llvm::StringRef Code = SM.getBufferData(File, &Invalid); if (Invalid) return llvm::None; unsigned B = Offset, E = Offset; while (B > 0 && isIdentifierBody(Code[B - 1])) --B; while (E < Code.size() && isIdentifierBody(Code[E])) ++E; if (B == E) return llvm::None; SpelledWord Result; Result.Location = SM.getComposedLoc(File, B); Result.Text = Code.slice(B, E); Result.LikelyIdentifier = isLikelyIdentifier(Result.Text, Code.substr(0, B), Code.substr(E)) && // should not be a keyword tok::isAnyIdentifier( IdentifierTable(LangOpts).get(Result.Text).getTokenID()); for (const auto &T : Touching) if (T.location() <= Result.Location) Result.PartOfSpelledToken = &T; return Result; } llvm::Optional<DefinedMacro> locateMacroAt(const syntax::Token &SpelledTok, Preprocessor &PP) { SourceLocation Loc = SpelledTok.location(); assert(Loc.isFileID()); const auto &SM = PP.getSourceManager(); IdentifierInfo *IdentifierInfo = PP.getIdentifierInfo(SpelledTok.text(SM)); if (!IdentifierInfo || !IdentifierInfo->hadMacroDefinition()) return None; // Get the definition just before the searched location so that a macro // referenced in a '#undef MACRO' can still be found. Note that we only do // that if Loc is not pointing at start of file. if (SM.getLocForStartOfFile(SM.getFileID(Loc)) != Loc) Loc = Loc.getLocWithOffset(-1); MacroDefinition MacroDef = PP.getMacroDefinitionAtLoc(IdentifierInfo, Loc); if (auto *MI = MacroDef.getMacroInfo()) return DefinedMacro{IdentifierInfo->getName(), MI}; return None; } llvm::Expected<std::string> Edit::apply() const { return tooling::applyAllReplacements(InitialCode, Replacements); } std::vector<TextEdit> Edit::asTextEdits() const { return replacementsToEdits(InitialCode, Replacements); } bool Edit::canApplyTo(llvm::StringRef Code) const { // Create line iterators, since line numbers are important while applying our // edit we cannot skip blank lines. auto LHS = llvm::MemoryBuffer::getMemBuffer(Code); llvm::line_iterator LHSIt(*LHS, /*SkipBlanks=*/false); auto RHS = llvm::MemoryBuffer::getMemBuffer(InitialCode); llvm::line_iterator RHSIt(*RHS, /*SkipBlanks=*/false); // Compare the InitialCode we prepared the edit for with the Code we received // line by line to make sure there are no differences. // FIXME: This check is too conservative now, it should be enough to only // check lines around the replacements contained inside the Edit. while (!LHSIt.is_at_eof() && !RHSIt.is_at_eof()) { if (*LHSIt != *RHSIt) return false; ++LHSIt; ++RHSIt; } // After we reach EOF for any of the files we make sure the other one doesn't // contain any additional content except empty lines, they should not // interfere with the edit we produced. while (!LHSIt.is_at_eof()) { if (!LHSIt->empty()) return false; ++LHSIt; } while (!RHSIt.is_at_eof()) { if (!RHSIt->empty()) return false; ++RHSIt; } return true; } llvm::Error reformatEdit(Edit &E, const format::FormatStyle &Style) { if (auto NewEdits = cleanupAndFormat(E.InitialCode, E.Replacements, Style)) E.Replacements = std::move(*NewEdits); else return NewEdits.takeError(); return llvm::Error::success(); } EligibleRegion getEligiblePoints(llvm::StringRef Code, llvm::StringRef FullyQualifiedName, const LangOptions &LangOpts) { EligibleRegion ER; // Start with global namespace. std::vector<std::string> Enclosing = {""}; // FIXME: In addition to namespaces try to generate events for function // definitions as well. One might use a closing parantheses(")" followed by an // opening brace "{" to trigger the start. parseNamespaceEvents(Code, LangOpts, [&](NamespaceEvent Event) { // Using Directives only introduces declarations to current scope, they do // not change the current namespace, so skip them. if (Event.Trigger == NamespaceEvent::UsingDirective) return; // Do not qualify the global namespace. if (!Event.Payload.empty()) Event.Payload.append("::"); std::string CurrentNamespace; if (Event.Trigger == NamespaceEvent::BeginNamespace) { Enclosing.emplace_back(std::move(Event.Payload)); CurrentNamespace = Enclosing.back(); // parseNameSpaceEvents reports the beginning position of a token; we want // to insert after '{', so increment by one. ++Event.Pos.character; } else { // Event.Payload points to outer namespace when exiting a scope, so use // the namespace we've last entered instead. CurrentNamespace = std::move(Enclosing.back()); Enclosing.pop_back(); assert(Enclosing.back() == Event.Payload); } // Ignore namespaces that are not a prefix of the target. if (!FullyQualifiedName.startswith(CurrentNamespace)) return; // Prefer the namespace that shares the longest prefix with target. if (CurrentNamespace.size() > ER.EnclosingNamespace.size()) { ER.EligiblePoints.clear(); ER.EnclosingNamespace = CurrentNamespace; } if (CurrentNamespace.size() == ER.EnclosingNamespace.size()) ER.EligiblePoints.emplace_back(std::move(Event.Pos)); }); // If there were no shared namespaces just return EOF. if (ER.EligiblePoints.empty()) { assert(ER.EnclosingNamespace.empty()); ER.EligiblePoints.emplace_back(offsetToPosition(Code, Code.size())); } return ER; } bool isHeaderFile(llvm::StringRef FileName, llvm::Optional<LangOptions> LangOpts) { // Respect the langOpts, for non-file-extension cases, e.g. standard library // files. if (LangOpts && LangOpts->IsHeaderFile) return true; namespace types = clang::driver::types; auto Lang = types::lookupTypeForExtension( llvm::sys::path::extension(FileName).substr(1)); return Lang != types::TY_INVALID && types::onlyPrecompileType(Lang); } bool isProtoFile(SourceLocation Loc, const SourceManager &SM) { auto FileName = SM.getFilename(Loc); if (!FileName.endswith(".proto.h") && !FileName.endswith(".pb.h")) return false; auto FID = SM.getFileID(Loc); // All proto generated headers should start with this line. static const char *PROTO_HEADER_COMMENT = "// Generated by the protocol buffer compiler. DO NOT EDIT!"; // Double check that this is an actual protobuf header. return SM.getBufferData(FID).startswith(PROTO_HEADER_COMMENT); } } // namespace clangd } // namespace clang