//===--- ConfigCompile.cpp - Translating Fragments into Config ------------===// // // 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 // //===----------------------------------------------------------------------===// // // Fragments are applied to Configs in two steps: // // 1. (When the fragment is first loaded) // FragmentCompiler::compile() traverses the Fragment and creates // function objects that know how to apply the configuration. // 2. (Every time a config is required) // CompiledFragment() executes these functions to populate the Config. // // Work could be split between these steps in different ways. We try to // do as much work as possible in the first step. For example, regexes are // compiled in stage 1 and captured by the apply function. This is because: // // - it's more efficient, as the work done in stage 1 must only be done once // - problems can be reported in stage 1, in stage 2 we must silently recover // //===----------------------------------------------------------------------===// #include "CompileCommands.h" #include "Config.h" #include "ConfigFragment.h" #include "ConfigProvider.h" #include "Diagnostics.h" #include "Feature.h" #include "TidyProvider.h" #include "support/Logger.h" #include "support/Path.h" #include "support/Trace.h" #include "llvm/ADT/None.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/StringSwitch.h" #include "llvm/Support/Error.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Format.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/Path.h" #include "llvm/Support/Regex.h" #include "llvm/Support/SMLoc.h" #include "llvm/Support/SourceMgr.h" #include #include namespace clang { namespace clangd { namespace config { namespace { // Returns an empty stringref if Path is not under FragmentDir. Returns Path // as-is when FragmentDir is empty. llvm::StringRef configRelative(llvm::StringRef Path, llvm::StringRef FragmentDir) { if (FragmentDir.empty()) return Path; if (!Path.consume_front(FragmentDir)) return llvm::StringRef(); return Path.empty() ? "." : Path; } struct CompiledFragmentImpl { // The independent conditions to check before using settings from this config. // The following fragment has *two* conditions: // If: { Platform: [mac, linux], PathMatch: foo/.* } // All of them must be satisfied: the platform and path conditions are ANDed. // The OR logic for the platform condition is implemented inside the function. std::vector> Conditions; // Mutations that this fragment will apply to the configuration. // These are invoked only if the conditions are satisfied. std::vector> Apply; bool operator()(const Params &P, Config &C) const { for (const auto &C : Conditions) { if (!C(P)) { dlog("Config fragment {0}: condition not met", this); return false; } } dlog("Config fragment {0}: applying {1} rules", this, Apply.size()); for (const auto &A : Apply) A(P, C); return true; } }; // Wrapper around condition compile() functions to reduce arg-passing. struct FragmentCompiler { FragmentCompiler(CompiledFragmentImpl &Out, DiagnosticCallback D, llvm::SourceMgr *SM) : Out(Out), Diagnostic(D), SourceMgr(SM) {} CompiledFragmentImpl &Out; DiagnosticCallback Diagnostic; llvm::SourceMgr *SourceMgr; // Normalized Fragment::SourceInfo::Directory. std::string FragmentDirectory; bool Trusted = false; llvm::Optional compileRegex(const Located &Text, llvm::Regex::RegexFlags Flags = llvm::Regex::NoFlags) { std::string Anchored = "^(" + *Text + ")$"; llvm::Regex Result(Anchored, Flags); std::string RegexError; if (!Result.isValid(RegexError)) { diag(Error, "Invalid regex " + Anchored + ": " + RegexError, Text.Range); return llvm::None; } return Result; } llvm::Optional makeAbsolute(Located Path, llvm::StringLiteral Description, llvm::sys::path::Style Style) { if (llvm::sys::path::is_absolute(*Path)) return *Path; if (FragmentDirectory.empty()) { diag(Error, llvm::formatv( "{0} must be an absolute path, because this fragment is not " "associated with any directory.", Description) .str(), Path.Range); return llvm::None; } llvm::SmallString<256> AbsPath = llvm::StringRef(*Path); llvm::sys::fs::make_absolute(FragmentDirectory, AbsPath); llvm::sys::path::native(AbsPath, Style); return AbsPath.str().str(); } // Helper with similar API to StringSwitch, for parsing enum values. template class EnumSwitch { FragmentCompiler &Outer; llvm::StringRef EnumName; const Located &Input; llvm::Optional Result; llvm::SmallVector ValidValues; public: EnumSwitch(llvm::StringRef EnumName, const Located &In, FragmentCompiler &Outer) : Outer(Outer), EnumName(EnumName), Input(In) {} EnumSwitch &map(llvm::StringLiteral Name, T Value) { assert(!llvm::is_contained(ValidValues, Name) && "Duplicate value!"); ValidValues.push_back(Name); if (!Result && *Input == Name) Result = Value; return *this; } llvm::Optional value() { if (!Result) Outer.diag( Warning, llvm::formatv("Invalid {0} value '{1}'. Valid values are {2}.", EnumName, *Input, llvm::join(ValidValues, ", ")) .str(), Input.Range); return Result; }; }; // Attempt to parse a specified string into an enum. // Yields llvm::None and produces a diagnostic on failure. // // Optional Value = compileEnum("Foo", Frag.Foo) // .map("Foo", Enum::Foo) // .map("Bar", Enum::Bar) // .value(); template EnumSwitch compileEnum(llvm::StringRef EnumName, const Located &In) { return EnumSwitch(EnumName, In, *this); } void compile(Fragment &&F) { Trusted = F.Source.Trusted; if (!F.Source.Directory.empty()) { FragmentDirectory = llvm::sys::path::convert_to_slash(F.Source.Directory); if (FragmentDirectory.back() != '/') FragmentDirectory += '/'; } compile(std::move(F.If)); compile(std::move(F.CompileFlags)); compile(std::move(F.Index)); compile(std::move(F.Diagnostics)); compile(std::move(F.Completion)); compile(std::move(F.Hover)); compile(std::move(F.InlayHints)); } void compile(Fragment::IfBlock &&F) { if (F.HasUnrecognizedCondition) Out.Conditions.push_back([&](const Params &) { return false; }); #ifdef CLANGD_PATH_CASE_INSENSITIVE llvm::Regex::RegexFlags Flags = llvm::Regex::IgnoreCase; #else llvm::Regex::RegexFlags Flags = llvm::Regex::NoFlags; #endif auto PathMatch = std::make_unique>(); for (auto &Entry : F.PathMatch) { if (auto RE = compileRegex(Entry, Flags)) PathMatch->push_back(std::move(*RE)); } if (!PathMatch->empty()) { Out.Conditions.push_back( [PathMatch(std::move(PathMatch)), FragmentDir(FragmentDirectory)](const Params &P) { if (P.Path.empty()) return false; llvm::StringRef Path = configRelative(P.Path, FragmentDir); // Ignore the file if it is not nested under Fragment. if (Path.empty()) return false; return llvm::any_of(*PathMatch, [&](const llvm::Regex &RE) { return RE.match(Path); }); }); } auto PathExclude = std::make_unique>(); for (auto &Entry : F.PathExclude) { if (auto RE = compileRegex(Entry, Flags)) PathExclude->push_back(std::move(*RE)); } if (!PathExclude->empty()) { Out.Conditions.push_back( [PathExclude(std::move(PathExclude)), FragmentDir(FragmentDirectory)](const Params &P) { if (P.Path.empty()) return false; llvm::StringRef Path = configRelative(P.Path, FragmentDir); // Ignore the file if it is not nested under Fragment. if (Path.empty()) return true; return llvm::none_of(*PathExclude, [&](const llvm::Regex &RE) { return RE.match(Path); }); }); } } void compile(Fragment::CompileFlagsBlock &&F) { if (F.Compiler) Out.Apply.push_back( [Compiler(std::move(**F.Compiler))](const Params &, Config &C) { C.CompileFlags.Edits.push_back( [Compiler](std::vector &Args) { if (!Args.empty()) Args.front() = Compiler; }); }); if (!F.Remove.empty()) { auto Remove = std::make_shared(); for (auto &A : F.Remove) Remove->strip(*A); Out.Apply.push_back([Remove(std::shared_ptr( std::move(Remove)))](const Params &, Config &C) { C.CompileFlags.Edits.push_back( [Remove](std::vector &Args) { Remove->process(Args); }); }); } if (!F.Add.empty()) { std::vector Add; for (auto &A : F.Add) Add.push_back(std::move(*A)); Out.Apply.push_back([Add(std::move(Add))](const Params &, Config &C) { C.CompileFlags.Edits.push_back([Add](std::vector &Args) { // The point to insert at. Just append when `--` isn't present. auto It = llvm::find(Args, "--"); Args.insert(It, Add.begin(), Add.end()); }); }); } if (F.CompilationDatabase) { llvm::Optional Spec; if (**F.CompilationDatabase == "Ancestors") { Spec.emplace(); Spec->Policy = Config::CDBSearchSpec::Ancestors; } else if (**F.CompilationDatabase == "None") { Spec.emplace(); Spec->Policy = Config::CDBSearchSpec::NoCDBSearch; } else { if (auto Path = makeAbsolute(*F.CompilationDatabase, "CompilationDatabase", llvm::sys::path::Style::native)) { // Drop trailing slash to put the path in canonical form. // Should makeAbsolute do this? llvm::StringRef Rel = llvm::sys::path::relative_path(*Path); if (!Rel.empty() && llvm::sys::path::is_separator(Rel.back())) Path->pop_back(); Spec.emplace(); Spec->Policy = Config::CDBSearchSpec::FixedDir; Spec->FixedCDBPath = std::move(Path); } } if (Spec) Out.Apply.push_back( [Spec(std::move(*Spec))](const Params &, Config &C) { C.CompileFlags.CDBSearch = Spec; }); } } void compile(Fragment::IndexBlock &&F) { if (F.Background) { if (auto Val = compileEnum("Background", **F.Background) .map("Build", Config::BackgroundPolicy::Build) .map("Skip", Config::BackgroundPolicy::Skip) .value()) Out.Apply.push_back( [Val](const Params &, Config &C) { C.Index.Background = *Val; }); } if (F.External) compile(std::move(**F.External), F.External->Range); } void compile(Fragment::IndexBlock::ExternalBlock &&External, llvm::SMRange BlockRange) { if (External.Server && !Trusted) { diag(Error, "Remote index may not be specified by untrusted configuration. " "Copy this into user config to use it.", External.Server->Range); return; } #ifndef CLANGD_ENABLE_REMOTE if (External.Server) { elog("Clangd isn't compiled with remote index support, ignoring Server: " "{0}", *External.Server); External.Server.reset(); } #endif // Make sure exactly one of the Sources is set. unsigned SourceCount = External.File.hasValue() + External.Server.hasValue() + *External.IsNone; if (SourceCount != 1) { diag(Error, "Exactly one of File, Server or None must be set.", BlockRange); return; } Config::ExternalIndexSpec Spec; if (External.Server) { Spec.Kind = Config::ExternalIndexSpec::Server; Spec.Location = std::move(**External.Server); } else if (External.File) { Spec.Kind = Config::ExternalIndexSpec::File; auto AbsPath = makeAbsolute(std::move(*External.File), "File", llvm::sys::path::Style::native); if (!AbsPath) return; Spec.Location = std::move(*AbsPath); } else { assert(*External.IsNone); Spec.Kind = Config::ExternalIndexSpec::None; } if (Spec.Kind != Config::ExternalIndexSpec::None) { // Make sure MountPoint is an absolute path with forward slashes. if (!External.MountPoint) External.MountPoint.emplace(FragmentDirectory); if ((**External.MountPoint).empty()) { diag(Error, "A mountpoint is required.", BlockRange); return; } auto AbsPath = makeAbsolute(std::move(*External.MountPoint), "MountPoint", llvm::sys::path::Style::posix); if (!AbsPath) return; Spec.MountPoint = std::move(*AbsPath); } Out.Apply.push_back([Spec(std::move(Spec))](const Params &P, Config &C) { if (Spec.Kind == Config::ExternalIndexSpec::None) { C.Index.External = Spec; return; } if (P.Path.empty() || !pathStartsWith(Spec.MountPoint, P.Path, llvm::sys::path::Style::posix)) return; C.Index.External = Spec; // Disable background indexing for the files under the mountpoint. // Note that this will overwrite statements in any previous fragments // (including the current one). C.Index.Background = Config::BackgroundPolicy::Skip; }); } void compile(Fragment::DiagnosticsBlock &&F) { std::vector Normalized; for (const auto &Suppressed : F.Suppress) { if (*Suppressed == "*") { Out.Apply.push_back([&](const Params &, Config &C) { C.Diagnostics.SuppressAll = true; C.Diagnostics.Suppress.clear(); }); return; } Normalized.push_back(normalizeSuppressedCode(*Suppressed).str()); } if (!Normalized.empty()) Out.Apply.push_back( [Normalized(std::move(Normalized))](const Params &, Config &C) { if (C.Diagnostics.SuppressAll) return; for (llvm::StringRef N : Normalized) C.Diagnostics.Suppress.insert(N); }); if (F.UnusedIncludes) if (auto Val = compileEnum( "UnusedIncludes", **F.UnusedIncludes) .map("Strict", Config::UnusedIncludesPolicy::Strict) .map("None", Config::UnusedIncludesPolicy::None) .value()) Out.Apply.push_back([Val](const Params &, Config &C) { C.Diagnostics.UnusedIncludes = *Val; }); compile(std::move(F.ClangTidy)); } void compile(Fragment::StyleBlock &&F) { if (!F.FullyQualifiedNamespaces.empty()) { std::vector FullyQualifiedNamespaces; for (auto &N : F.FullyQualifiedNamespaces) { // Normalize the data by dropping both leading and trailing :: StringRef Namespace(*N); Namespace.consume_front("::"); Namespace.consume_back("::"); FullyQualifiedNamespaces.push_back(Namespace.str()); } Out.Apply.push_back([FullyQualifiedNamespaces( std::move(FullyQualifiedNamespaces))]( const Params &, Config &C) { C.Style.FullyQualifiedNamespaces.insert( C.Style.FullyQualifiedNamespaces.begin(), FullyQualifiedNamespaces.begin(), FullyQualifiedNamespaces.end()); }); } } void appendTidyCheckSpec(std::string &CurSpec, const Located &Arg, bool IsPositive) { StringRef Str = StringRef(*Arg).trim(); // Don't support negating here, its handled if the item is in the Add or // Remove list. if (Str.startswith("-") || Str.contains(',')) { diag(Error, "Invalid clang-tidy check name", Arg.Range); return; } if (!Str.contains('*') && !isRegisteredTidyCheck(Str)) { diag(Warning, llvm::formatv("clang-tidy check '{0}' was not found", Str).str(), Arg.Range); return; } CurSpec += ','; if (!IsPositive) CurSpec += '-'; CurSpec += Str; } void compile(Fragment::DiagnosticsBlock::ClangTidyBlock &&F) { std::string Checks; for (auto &CheckGlob : F.Add) appendTidyCheckSpec(Checks, CheckGlob, true); for (auto &CheckGlob : F.Remove) appendTidyCheckSpec(Checks, CheckGlob, false); if (!Checks.empty()) Out.Apply.push_back( [Checks = std::move(Checks)](const Params &, Config &C) { C.Diagnostics.ClangTidy.Checks.append( Checks, C.Diagnostics.ClangTidy.Checks.empty() ? /*skip comma*/ 1 : 0, std::string::npos); }); if (!F.CheckOptions.empty()) { std::vector> CheckOptions; for (auto &Opt : F.CheckOptions) CheckOptions.emplace_back(std::move(*Opt.first), std::move(*Opt.second)); Out.Apply.push_back( [CheckOptions = std::move(CheckOptions)](const Params &, Config &C) { for (auto &StringPair : CheckOptions) C.Diagnostics.ClangTidy.CheckOptions.insert_or_assign( StringPair.first, StringPair.second); }); } } void compile(Fragment::CompletionBlock &&F) { if (F.AllScopes) { Out.Apply.push_back( [AllScopes(**F.AllScopes)](const Params &, Config &C) { C.Completion.AllScopes = AllScopes; }); } } void compile(Fragment::HoverBlock &&F) { if (F.ShowAKA) { Out.Apply.push_back([ShowAKA(**F.ShowAKA)](const Params &, Config &C) { C.Hover.ShowAKA = ShowAKA; }); } } void compile(Fragment::InlayHintsBlock &&F) { if (F.Enabled) Out.Apply.push_back([Value(**F.Enabled)](const Params &, Config &C) { C.InlayHints.Enabled = Value; }); if (F.ParameterNames) Out.Apply.push_back( [Value(**F.ParameterNames)](const Params &, Config &C) { C.InlayHints.Parameters = Value; }); if (F.DeducedTypes) Out.Apply.push_back([Value(**F.DeducedTypes)](const Params &, Config &C) { C.InlayHints.DeducedTypes = Value; }); if (F.Designators) Out.Apply.push_back([Value(**F.Designators)](const Params &, Config &C) { C.InlayHints.Designators = Value; }); } constexpr static llvm::SourceMgr::DiagKind Error = llvm::SourceMgr::DK_Error; constexpr static llvm::SourceMgr::DiagKind Warning = llvm::SourceMgr::DK_Warning; void diag(llvm::SourceMgr::DiagKind Kind, llvm::StringRef Message, llvm::SMRange Range) { if (Range.isValid() && SourceMgr != nullptr) Diagnostic(SourceMgr->GetMessage(Range.Start, Kind, Message, Range)); else Diagnostic(llvm::SMDiagnostic("", Kind, Message)); } }; } // namespace CompiledFragment Fragment::compile(DiagnosticCallback D) && { llvm::StringRef ConfigFile = ""; std::pair LineCol = {0, 0}; if (auto *SM = Source.Manager.get()) { unsigned BufID = SM->getMainFileID(); LineCol = SM->getLineAndColumn(Source.Location, BufID); ConfigFile = SM->getBufferInfo(BufID).Buffer->getBufferIdentifier(); } trace::Span Tracer("ConfigCompile"); SPAN_ATTACH(Tracer, "ConfigFile", ConfigFile); auto Result = std::make_shared(); vlog("Config fragment: compiling {0}:{1} -> {2} (trusted={3})", ConfigFile, LineCol.first, Result.get(), Source.Trusted); FragmentCompiler{*Result, D, Source.Manager.get()}.compile(std::move(*this)); // Return as cheaply-copyable wrapper. return [Result(std::move(Result))](const Params &P, Config &C) { return (*Result)(P, C); }; } } // namespace config } // namespace clangd } // namespace clang