//===--- CompileCommands.cpp ----------------------------------------------===// // // 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 "CompileCommands.h" #include "Config.h" #include "support/Logger.h" #include "clang/Driver/Options.h" #include "clang/Frontend/CompilerInvocation.h" #include "clang/Tooling/ArgumentsAdjusters.h" #include "llvm/Option/Option.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/Debug.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/FileUtilities.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/Program.h" namespace clang { namespace clangd { namespace { // Query apple's `xcrun` launcher, which is the source of truth for "how should" // clang be invoked on this system. llvm::Optional queryXcrun(llvm::ArrayRef Argv) { auto Xcrun = llvm::sys::findProgramByName("xcrun"); if (!Xcrun) { log("Couldn't find xcrun. Hopefully you have a non-apple toolchain..."); return llvm::None; } llvm::SmallString<64> OutFile; llvm::sys::fs::createTemporaryFile("clangd-xcrun", "", OutFile); llvm::FileRemover OutRemover(OutFile); llvm::Optional Redirects[3] = { /*stdin=*/{""}, /*stdout=*/{OutFile}, /*stderr=*/{""}}; vlog("Invoking {0} to find clang installation", *Xcrun); int Ret = llvm::sys::ExecuteAndWait(*Xcrun, Argv, /*Env=*/llvm::None, Redirects, /*SecondsToWait=*/10); if (Ret != 0) { log("xcrun exists but failed with code {0}. " "If you have a non-apple toolchain, this is OK. " "Otherwise, try xcode-select --install.", Ret); return llvm::None; } auto Buf = llvm::MemoryBuffer::getFile(OutFile); if (!Buf) { log("Can't read xcrun output: {0}", Buf.getError().message()); return llvm::None; } StringRef Path = Buf->get()->getBuffer().trim(); if (Path.empty()) { log("xcrun produced no output"); return llvm::None; } return Path.str(); } // Resolve symlinks if possible. std::string resolve(std::string Path) { llvm::SmallString<128> Resolved; if (llvm::sys::fs::real_path(Path, Resolved)) { log("Failed to resolve possible symlink {0}", Path); return Path; } return std::string(Resolved.str()); } // Get a plausible full `clang` path. // This is used in the fallback compile command, or when the CDB returns a // generic driver with no path. std::string detectClangPath() { // The driver and/or cc1 sometimes depend on the binary name to compute // useful things like the standard library location. // We need to emulate what clang on this system is likely to see. // cc1 in particular looks at the "real path" of the running process, and // so if /usr/bin/clang is a symlink, it sees the resolved path. // clangd doesn't have that luxury, so we resolve symlinks ourselves. // On Mac, `which clang` is /usr/bin/clang. It runs `xcrun clang`, which knows // where the real clang is kept. We need to do the same thing, // because cc1 (not the driver!) will find libc++ relative to argv[0]. #ifdef __APPLE__ if (auto MacClang = queryXcrun({"xcrun", "--find", "clang"})) return resolve(std::move(*MacClang)); #endif // On other platforms, just look for compilers on the PATH. for (const char *Name : {"clang", "gcc", "cc"}) if (auto PathCC = llvm::sys::findProgramByName(Name)) return resolve(std::move(*PathCC)); // Fallback: a nonexistent 'clang' binary next to clangd. static int Dummy; std::string ClangdExecutable = llvm::sys::fs::getMainExecutable("clangd", (void *)&Dummy); SmallString<128> ClangPath; ClangPath = llvm::sys::path::parent_path(ClangdExecutable); llvm::sys::path::append(ClangPath, "clang"); return std::string(ClangPath.str()); } // On mac, /usr/bin/clang sets SDKROOT and then invokes the real clang. // The effect of this is to set -isysroot correctly. We do the same. const llvm::Optional detectSysroot() { #ifndef __APPLE__ return llvm::None; #endif // SDKROOT overridden in environment, respect it. Driver will set isysroot. if (::getenv("SDKROOT")) return llvm::None; return queryXcrun({"xcrun", "--show-sdk-path"}); return llvm::None; } std::string detectStandardResourceDir() { static int Dummy; // Just an address in this process. return CompilerInvocation::GetResourcesPath("clangd", (void *)&Dummy); } // The path passed to argv[0] is important: // - its parent directory is Driver::Dir, used for library discovery // - its basename affects CLI parsing (clang-cl) and other settings // Where possible it should be an absolute path with sensible directory, but // with the original basename. static std::string resolveDriver(llvm::StringRef Driver, bool FollowSymlink, llvm::Optional ClangPath) { auto SiblingOf = [&](llvm::StringRef AbsPath) { llvm::SmallString<128> Result = llvm::sys::path::parent_path(AbsPath); llvm::sys::path::append(Result, llvm::sys::path::filename(Driver)); return Result.str().str(); }; // First, eliminate relative paths. std::string Storage; if (!llvm::sys::path::is_absolute(Driver)) { // If it's working-dir relative like bin/clang, we can't resolve it. // FIXME: we could if we had the working directory here. // Let's hope it's not a symlink. if (llvm::any_of(Driver, [](char C) { return llvm::sys::path::is_separator(C); })) return Driver.str(); // If the driver is a generic like "g++" with no path, add clang dir. if (ClangPath && (Driver == "clang" || Driver == "clang++" || Driver == "gcc" || Driver == "g++" || Driver == "cc" || Driver == "c++")) { return SiblingOf(*ClangPath); } // Otherwise try to look it up on PATH. This won't change basename. auto Absolute = llvm::sys::findProgramByName(Driver); if (Absolute && llvm::sys::path::is_absolute(*Absolute)) Driver = Storage = std::move(*Absolute); else if (ClangPath) // If we don't find it, use clang dir again. return SiblingOf(*ClangPath); else // Nothing to do: can't find the command and no detected dir. return Driver.str(); } // Now we have an absolute path, but it may be a symlink. assert(llvm::sys::path::is_absolute(Driver)); if (FollowSymlink) { llvm::SmallString<256> Resolved; if (!llvm::sys::fs::real_path(Driver, Resolved)) return SiblingOf(Resolved); } return Driver.str(); } } // namespace CommandMangler CommandMangler::detect() { CommandMangler Result; Result.ClangPath = detectClangPath(); Result.ResourceDir = detectStandardResourceDir(); Result.Sysroot = detectSysroot(); return Result; } CommandMangler CommandMangler::forTests() { return CommandMangler(); } void CommandMangler::adjust(std::vector &Cmd) const { for (auto &Edit : Config::current().CompileFlags.Edits) Edit(Cmd); // Check whether the flag exists, either as -flag or -flag=* auto Has = [&](llvm::StringRef Flag) { for (llvm::StringRef Arg : Cmd) { if (Arg.consume_front(Flag) && (Arg.empty() || Arg[0] == '=')) return true; } return false; }; // clangd should not write files to disk, including dependency files // requested on the command line. Cmd = tooling::getClangStripDependencyFileAdjuster()(Cmd, ""); // Strip plugin related command line arguments. Clangd does // not support plugins currently. Therefore it breaks if // compiler tries to load plugins. Cmd = tooling::getStripPluginsAdjuster()(Cmd, ""); Cmd = tooling::getClangSyntaxOnlyAdjuster()(Cmd, ""); if (ResourceDir && !Has("-resource-dir")) Cmd.push_back(("-resource-dir=" + *ResourceDir)); // Don't set `-isysroot` if it is already set or if `--sysroot` is set. // `--sysroot` is a superset of the `-isysroot` argument. if (Sysroot && !Has("-isysroot") && !Has("--sysroot")) { Cmd.push_back("-isysroot"); Cmd.push_back(*Sysroot); } if (!Cmd.empty()) { bool FollowSymlink = !Has("-no-canonical-prefixes"); Cmd.front() = (FollowSymlink ? ResolvedDrivers : ResolvedDriversNoFollow) .get(Cmd.front(), [&, this] { return resolveDriver(Cmd.front(), FollowSymlink, ClangPath); }); } } CommandMangler::operator clang::tooling::ArgumentsAdjuster() && { // ArgumentsAdjuster is a std::function and so must be copyable. return [Mangler = std::make_shared(std::move(*this))]( const std::vector &Args, llvm::StringRef File) { auto Result = Args; Mangler->adjust(Result); return Result; }; } // ArgStripper implementation namespace { // Determine total number of args consumed by this option. // Return answers for {Exact, Prefix} match. 0 means not allowed. std::pair getArgCount(const llvm::opt::Option &Opt) { constexpr static unsigned Rest = 10000; // Should be all the rest! // Reference is llvm::opt::Option::acceptInternal() using llvm::opt::Option; switch (Opt.getKind()) { case Option::FlagClass: return {1, 0}; case Option::JoinedClass: case Option::CommaJoinedClass: return {1, 1}; case Option::GroupClass: case Option::InputClass: case Option::UnknownClass: case Option::ValuesClass: return {1, 0}; case Option::JoinedAndSeparateClass: return {2, 2}; case Option::SeparateClass: return {2, 0}; case Option::MultiArgClass: return {1 + Opt.getNumArgs(), 0}; case Option::JoinedOrSeparateClass: return {2, 1}; case Option::RemainingArgsClass: return {Rest, 0}; case Option::RemainingArgsJoinedClass: return {Rest, Rest}; } llvm_unreachable("Unhandled option kind"); } // Flag-parsing mode, which affects which flags are available. enum DriverMode : unsigned char { DM_None = 0, DM_GCC = 1, // Default mode e.g. when invoked as 'clang' DM_CL = 2, // MS CL.exe compatible mode e.g. when invoked as 'clang-cl' DM_CC1 = 4, // When invoked as 'clang -cc1' or after '-Xclang' DM_All = 7 }; // Examine args list to determine if we're in GCC, CL-compatible, or cc1 mode. DriverMode getDriverMode(const std::vector &Args) { DriverMode Mode = DM_GCC; llvm::StringRef Argv0 = Args.front(); if (Argv0.endswith_lower(".exe")) Argv0 = Argv0.drop_back(strlen(".exe")); if (Argv0.endswith_lower("cl")) Mode = DM_CL; for (const llvm::StringRef Arg : Args) { if (Arg == "--driver-mode=cl") { Mode = DM_CL; break; } if (Arg == "-cc1") { Mode = DM_CC1; break; } } return Mode; } // Returns the set of DriverModes where an option may be used. unsigned char getModes(const llvm::opt::Option &Opt) { // Why is this so complicated?! // Reference is clang::driver::Driver::getIncludeExcludeOptionFlagMasks() unsigned char Result = DM_None; if (Opt.hasFlag(driver::options::CC1Option)) Result |= DM_CC1; if (!Opt.hasFlag(driver::options::NoDriverOption)) { if (Opt.hasFlag(driver::options::CLOption)) { Result |= DM_CL; } else { Result |= DM_GCC; if (Opt.hasFlag(driver::options::CoreOption)) { Result |= DM_CL; } } } return Result; } } // namespace llvm::ArrayRef ArgStripper::rulesFor(llvm::StringRef Arg) { // All the hard work is done once in a static initializer. // We compute a table containing strings to look for and #args to skip. // e.g. "-x" => {-x 2 args, -x* 1 arg, --language 2 args, --language=* 1 arg} using TableTy = llvm::StringMap, llvm::BumpPtrAllocator>; static TableTy *Table = [] { auto &DriverTable = driver::getDriverOptTable(); using DriverID = clang::driver::options::ID; // Collect sets of aliases, so we can treat -foo and -foo= as synonyms. // Conceptually a double-linked list: PrevAlias[I] -> I -> NextAlias[I]. // If PrevAlias[I] is INVALID, then I is canonical. DriverID PrevAlias[DriverID::LastOption] = {DriverID::OPT_INVALID}; DriverID NextAlias[DriverID::LastOption] = {DriverID::OPT_INVALID}; auto AddAlias = [&](DriverID Self, DriverID T) { if (NextAlias[T]) { PrevAlias[NextAlias[T]] = Self; NextAlias[Self] = NextAlias[T]; } PrevAlias[Self] = T; NextAlias[T] = Self; }; // Also grab prefixes for each option, these are not fully exposed. const char *const *Prefixes[DriverID::LastOption] = {nullptr}; #define PREFIX(NAME, VALUE) static const char *const NAME[] = VALUE; #define OPTION(PREFIX, NAME, ID, KIND, GROUP, ALIAS, ALIASARGS, FLAGS, PARAM, \ HELP, METAVAR, VALUES) \ if (DriverID::OPT_##ALIAS != DriverID::OPT_INVALID && ALIASARGS == nullptr) \ AddAlias(DriverID::OPT_##ID, DriverID::OPT_##ALIAS); \ Prefixes[DriverID::OPT_##ID] = PREFIX; #include "clang/Driver/Options.inc" #undef OPTION #undef PREFIX auto Result = std::make_unique(); // Iterate over distinct options (represented by the canonical alias). // Every spelling of this option will get the same set of rules. for (unsigned ID = 1 /*Skip INVALID */; ID < DriverID::LastOption; ++ID) { if (PrevAlias[ID] || ID == DriverID::OPT_Xclang) continue; // Not canonical, or specially handled. llvm::SmallVector Rules; // Iterate over each alias, to add rules for parsing it. for (unsigned A = ID; A != DriverID::OPT_INVALID; A = NextAlias[A]) { if (Prefixes[A] == nullptr) // option groups. continue; auto Opt = DriverTable.getOption(A); // Exclude - and -foo pseudo-options. if (Opt.getName().empty()) continue; auto Modes = getModes(Opt); std::pair ArgCount = getArgCount(Opt); // Iterate over each spelling of the alias, e.g. -foo vs --foo. for (auto *Prefix = Prefixes[A]; *Prefix != nullptr; ++Prefix) { llvm::SmallString<64> Buf(*Prefix); Buf.append(Opt.getName()); llvm::StringRef Spelling = Result->try_emplace(Buf).first->getKey(); Rules.emplace_back(); Rule &R = Rules.back(); R.Text = Spelling; R.Modes = Modes; R.ExactArgs = ArgCount.first; R.PrefixArgs = ArgCount.second; // Concrete priority is the index into the option table. // Effectively, earlier entries take priority over later ones. assert(ID < std::numeric_limits::max() && "Rules::Priority overflowed by options table"); R.Priority = ID; } } // Register the set of rules under each possible name. for (const auto &R : Rules) Result->find(R.Text)->second.append(Rules.begin(), Rules.end()); } #ifndef NDEBUG // Dump the table and various measures of its size. unsigned RuleCount = 0; dlog("ArgStripper Option spelling table"); for (const auto &Entry : *Result) { dlog("{0}", Entry.first()); RuleCount += Entry.second.size(); for (const auto &R : Entry.second) dlog(" {0} #={1} *={2} Mode={3}", R.Text, R.ExactArgs, R.PrefixArgs, int(R.Modes)); } dlog("Table spellings={0} rules={1} string-bytes={2}", Result->size(), RuleCount, Result->getAllocator().getBytesAllocated()); #endif // The static table will never be destroyed. return Result.release(); }(); auto It = Table->find(Arg); return (It == Table->end()) ? llvm::ArrayRef() : It->second; } void ArgStripper::strip(llvm::StringRef Arg) { auto OptionRules = rulesFor(Arg); if (OptionRules.empty()) { // Not a recognized flag. Strip it literally. Storage.emplace_back(Arg); Rules.emplace_back(); Rules.back().Text = Storage.back(); Rules.back().ExactArgs = 1; if (Rules.back().Text.consume_back("*")) Rules.back().PrefixArgs = 1; Rules.back().Modes = DM_All; Rules.back().Priority = -1; // Max unsigned = lowest priority. } else { Rules.append(OptionRules.begin(), OptionRules.end()); } } const ArgStripper::Rule *ArgStripper::matchingRule(llvm::StringRef Arg, unsigned Mode, unsigned &ArgCount) const { const ArgStripper::Rule *BestRule = nullptr; for (const Rule &R : Rules) { // Rule can fail to match if... if (!(R.Modes & Mode)) continue; // not applicable to current driver mode if (BestRule && BestRule->Priority < R.Priority) continue; // lower-priority than best candidate. if (!Arg.startswith(R.Text)) continue; // current arg doesn't match the prefix string bool PrefixMatch = Arg.size() > R.Text.size(); // Can rule apply as an exact/prefix match? if (unsigned Count = PrefixMatch ? R.PrefixArgs : R.ExactArgs) { BestRule = &R; ArgCount = Count; } // Continue in case we find a higher-priority rule. } return BestRule; } void ArgStripper::process(std::vector &Args) const { if (Args.empty()) return; // We're parsing the args list in some mode (e.g. gcc-compatible) but may // temporarily switch to another mode with the -Xclang flag. DriverMode MainMode = getDriverMode(Args); DriverMode CurrentMode = MainMode; // Read and write heads for in-place deletion. unsigned Read = 0, Write = 0; bool WasXclang = false; while (Read < Args.size()) { unsigned ArgCount = 0; if (matchingRule(Args[Read], CurrentMode, ArgCount)) { // Delete it and its args. if (WasXclang) { assert(Write > 0); --Write; // Drop previous -Xclang arg CurrentMode = MainMode; WasXclang = false; } // Advance to last arg. An arg may be foo or -Xclang foo. for (unsigned I = 1; Read < Args.size() && I < ArgCount; ++I) { ++Read; if (Read < Args.size() && Args[Read] == "-Xclang") ++Read; } } else { // No match, just copy the arg through. WasXclang = Args[Read] == "-Xclang"; CurrentMode = WasXclang ? DM_CC1 : MainMode; if (Write != Read) Args[Write] = std::move(Args[Read]); ++Write; } ++Read; } Args.resize(Write); } } // namespace clangd } // namespace clang