blob: 33cbc715e9659289b65ae515b2a3943e256b93a0 [file]
//===------------------ ProjectModules.cpp --------- ------------*- 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 "ProjectModules.h"
#include "Compiler.h"
#include "support/Logger.h"
#include "clang/DependencyScanning/DependencyScanningService.h"
#include "clang/Tooling/DependencyScanningTool.h"
#include "clang/Tooling/Tooling.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringSet.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Path.h"
#include "llvm/TargetParser/Host.h"
namespace clang::clangd {
namespace {
llvm::SmallString<128> normalizePath(PathRef Path) {
llvm::SmallString<128> Result(Path);
llvm::sys::path::remove_dots(Result, /*remove_dot_dot=*/true);
llvm::sys::path::native(Result, llvm::sys::path::Style::posix);
return Result;
}
std::string normalizePath(PathRef Path, PathRef WorkingDir) {
if (Path.empty())
return {};
llvm::SmallString<128> Result;
if (llvm::sys::path::is_absolute(Path) || WorkingDir.empty())
Result = Path;
else {
Result = WorkingDir;
llvm::sys::path::append(Result, Path);
}
return normalizePath(Result).str().str();
}
/// The information related to modules parsed from compile commands.
/// Including the source file, the module file it produces (if it is a
/// producer), and the module and the corresponding module files it
/// requires (if it is a consumer)
struct ParsedCompileCommandInfo {
std::string SourceFile;
std::optional<std::string> OutputModuleFile;
// Map from required module name to the module file path.
llvm::StringMap<std::string> RequiredModuleFiles;
};
/// Get ParsedCompileCommandInfo by looking at the '--precompile',
/// '-fmodule-file=' and '-fmodule-file=' commands in the compile command.
std::optional<ParsedCompileCommandInfo>
parseCompileCommandInfo(tooling::CompileCommand Cmd, const ThreadsafeFS &TFS) {
auto FS = TFS.view(std::nullopt);
auto Tokenizer = llvm::Triple(llvm::sys::getProcessTriple()).isOSWindows()
? llvm::cl::TokenizeWindowsCommandLine
: llvm::cl::TokenizeGNUCommandLine;
tooling::addExpandedResponseFiles(Cmd.CommandLine, Cmd.Directory, Tokenizer,
*FS);
ParsedCompileCommandInfo Result;
Result.SourceFile = normalizePath(Cmd.Filename, Cmd.Directory);
bool SawPrecompile = false;
for (size_t I = 1; I < Cmd.CommandLine.size(); ++I) {
llvm::StringRef Arg = Cmd.CommandLine[I];
if (Arg == "--precompile") {
SawPrecompile = true;
continue;
}
if (Arg.consume_front("-fmodule-output=")) {
Result.OutputModuleFile = normalizePath(Arg, Cmd.Directory);
continue;
}
if (Arg == "-fmodule-output" && I + 1 < Cmd.CommandLine.size()) {
Result.OutputModuleFile =
normalizePath(Cmd.CommandLine[++I], Cmd.Directory);
continue;
}
if (SawPrecompile && Arg == "-o" && I + 1 < Cmd.CommandLine.size()) {
Result.OutputModuleFile =
normalizePath(Cmd.CommandLine[++I], Cmd.Directory);
continue;
}
if (SawPrecompile && Arg.starts_with("-o") && Arg.size() > 2) {
Result.OutputModuleFile = normalizePath(Arg.drop_front(2), Cmd.Directory);
continue;
}
if (!Arg.consume_front("-fmodule-file="))
continue;
auto Sep = Arg.find('=');
if (Sep == llvm::StringRef::npos || Sep == 0 || Sep + 1 == Arg.size())
continue;
Result.RequiredModuleFiles[Arg.take_front(Sep)] =
normalizePath(Arg.drop_front(Sep + 1), Cmd.Directory);
}
return Result;
}
std::optional<tooling::CompileCommand>
getCompileCommandForFile(const clang::tooling::CompilationDatabase &CDB,
PathRef FilePath,
const ProjectModules::CommandMangler &Mangler) {
auto Candidates = CDB.getCompileCommands(FilePath);
if (Candidates.empty())
return std::nullopt;
// Choose the first candidates as the compile commands as the file.
// Following the same logic with
// DirectoryBasedGlobalCompilationDatabase::getCompileCommand.
tooling::CompileCommand Cmd = std::move(Candidates.front());
if (Mangler)
Mangler(Cmd, FilePath);
return Cmd;
}
/// A scanner to query the dependency information for C++20 Modules.
///
/// The scanner can scan a single file with `scan(PathRef)` member function
/// or scan the whole project with `globalScan(vector<PathRef>)` member
/// function. See the comments of `globalScan` to see the details.
///
/// The ModuleDependencyScanner can get the directly required module names for a
/// specific source file. Also the ModuleDependencyScanner can get the source
/// file declaring the primary module interface for a specific module name.
///
/// IMPORTANT NOTE: we assume that every module unit is only declared once in a
/// source file in the project. But the assumption is not strictly true even
/// besides the invalid projects. The language specification requires that every
/// module unit should be unique in a valid program. But a project can contain
/// multiple programs. Then it is valid that we can have multiple source files
/// declaring the same module in a project as long as these source files don't
/// interfere with each other.
class ModuleDependencyScanner {
public:
ModuleDependencyScanner(
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB,
const ThreadsafeFS &TFS)
: CDB(CDB), Service([&TFS] {
dependencies::DependencyScanningServiceOptions Opts;
Opts.MakeVFS = [&] { return TFS.view(std::nullopt); };
Opts.Mode = dependencies::ScanningMode::CanonicalPreprocessing;
Opts.EmitWarnings = false;
Opts.ReportAbsolutePaths = false;
return Opts;
}()) {}
/// The scanned modules dependency information for a specific source file.
struct ModuleDependencyInfo {
/// The name of the module if the file is a module unit.
std::optional<std::string> ModuleName;
/// A list of names for the modules that the file directly depends.
std::vector<std::string> RequiredModules;
};
/// Scanning the single file specified by \param FilePath.
std::optional<ModuleDependencyInfo>
scan(PathRef FilePath, const ProjectModules::CommandMangler &Mangler);
/// Scanning every source file in the current project to get the
/// <module-name> to <module-unit-source> map.
/// TODO: We should find an efficient method to get the <module-name>
/// to <module-unit-source> map. We can make it either by providing
/// a global module dependency scanner to monitor every file. Or we
/// can simply require the build systems (or even the end users)
/// to provide the map.
void globalScan(const ProjectModules::CommandMangler &Mangler);
/// Get the source file from the module name. Note that the language
/// guarantees all the module names are unique in a valid program.
/// This function should only be called after globalScan.
///
/// TODO: We should handle the case that there are multiple source files
/// declaring the same module.
PathRef getSourceForModuleName(llvm::StringRef ModuleName) const;
/// Return the direct required modules. Indirect required modules are not
/// included.
std::vector<std::string>
getRequiredModules(PathRef File,
const ProjectModules::CommandMangler &Mangler);
private:
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB;
// Whether the scanner has scanned the project globally.
bool GlobalScanned = false;
clang::dependencies::DependencyScanningService Service;
// TODO: Add a scanning cache.
// Map module name to source file path.
llvm::StringMap<std::string> ModuleNameToSource;
};
std::optional<ModuleDependencyScanner::ModuleDependencyInfo>
ModuleDependencyScanner::scan(PathRef FilePath,
const ProjectModules::CommandMangler &Mangler) {
auto Cmd = getCompileCommandForFile(*CDB, FilePath, Mangler);
if (!Cmd)
return std::nullopt;
using namespace clang::tooling;
DependencyScanningTool ScanningTool(Service);
std::string S;
llvm::raw_string_ostream OS(S);
DiagnosticOptions DiagOpts;
DiagOpts.ShowCarets = false;
TextDiagnosticPrinter DiagConsumer(OS, DiagOpts);
std::optional<P1689Rule> ScanningResult =
ScanningTool.getP1689ModuleDependencyFile(*Cmd, Cmd->Directory,
DiagConsumer);
if (!ScanningResult) {
elog("Scanning modules dependencies for {0} failed: {1}", FilePath, S);
std::string Cmdline;
for (auto &Arg : Cmd->CommandLine)
Cmdline += Arg + " ";
elog("The command line the scanning tool use is: {0}", Cmdline);
return std::nullopt;
}
ModuleDependencyInfo Result;
if (ScanningResult->Provides) {
Result.ModuleName = ScanningResult->Provides->ModuleName;
auto [Iter, Inserted] = ModuleNameToSource.try_emplace(
ScanningResult->Provides->ModuleName, FilePath);
if (!Inserted &&
!pathEqual(normalizePath(Iter->second), normalizePath(FilePath))) {
elog("Detected multiple source files ({0}, {1}) declaring the same "
"module: '{2}'. "
"Now clangd may find the wrong source in such case.",
Iter->second, FilePath, ScanningResult->Provides->ModuleName);
}
}
for (auto &Required : ScanningResult->Requires)
Result.RequiredModules.push_back(Required.ModuleName);
return Result;
}
void ModuleDependencyScanner::globalScan(
const ProjectModules::CommandMangler &Mangler) {
if (GlobalScanned)
return;
for (auto &File : CDB->getAllFiles())
scan(File, Mangler);
GlobalScanned = true;
}
PathRef ModuleDependencyScanner::getSourceForModuleName(
llvm::StringRef ModuleName) const {
assert(
GlobalScanned &&
"We should only call getSourceForModuleName after calling globalScan()");
if (auto It = ModuleNameToSource.find(ModuleName);
It != ModuleNameToSource.end())
return It->second;
return {};
}
std::vector<std::string> ModuleDependencyScanner::getRequiredModules(
PathRef File, const ProjectModules::CommandMangler &Mangler) {
auto ScanningResult = scan(File, Mangler);
if (!ScanningResult)
return {};
return ScanningResult->RequiredModules;
}
} // namespace
/// TODO: The existing `ScanningAllProjectModules` is not efficient. See the
/// comments in ModuleDependencyScanner for detail.
///
/// In the future, we wish the build system can provide a well design
/// compilation database for modules then we can query that new compilation
/// database directly. Or we need to have a global long-live scanner to detect
/// the state of each file.
class ScanningAllProjectModules : public ProjectModules {
public:
ScanningAllProjectModules(
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB,
const ThreadsafeFS &TFS)
: Scanner(CDB, TFS) {}
~ScanningAllProjectModules() override = default;
std::vector<std::string> getRequiredModules(PathRef File) override {
return Scanner.getRequiredModules(File, Mangler);
}
void setCommandMangler(CommandMangler Mangler) override {
this->Mangler = std::move(Mangler);
}
/// RequiredSourceFile is not used intentionally. See the comments of
/// ModuleDependencyScanner for detail.
std::string getSourceForModuleName(llvm::StringRef ModuleName,
PathRef RequiredSourceFile) override {
Scanner.globalScan(Mangler);
return Scanner.getSourceForModuleName(ModuleName).str();
}
std::string getModuleNameForSource(PathRef File) override {
auto ScanningResult = Scanner.scan(File, Mangler);
if (!ScanningResult || !ScanningResult->ModuleName)
return {};
return *ScanningResult->ModuleName;
}
// Determining Unique/Multiple needs a global scan; return Unknown for cost
// reasons. We will have other ProjectModules implementations can determine
// this more efficiently.
ModuleNameState getModuleNameState(llvm::StringRef /*ModuleName*/) override {
return ModuleNameState::Unknown;
}
private:
ModuleDependencyScanner Scanner;
CommandMangler Mangler;
};
/// Reads project module information directly from compile commands.
///
/// The key observation is that compile commands may already encode the mapping
/// between a TU, the module names it imports, and the BMI paths it uses:
/// - producers may spell the BMI path with `--precompile -o <bmi>` or
/// `-fmodule-output=<bmi>`
/// - consumers may spell the mapping from module name to BMI path with
/// `-fmodule-file=<module>=<bmi>`
///
/// When that information is present, we can answer
/// `getSourceForModuleName(ModuleName, RequiredSourceFile)` by first looking up
/// the BMI path the consumer TU uses for `ModuleName`, and then mapping that
/// BMI path back to the module unit source that produced it. This avoids the
/// older scanning-only approach of guessing the module unit from the module
/// name alone.
///
/// One subtle point is that producer commands alone do not reliably tell us the
/// module name associated with a BMI path. In practice this backend learns that
/// association from consumer `-fmodule-file=` entries, and then uses the BMI
/// path to recover the producer source file. That is why indexing is built from
/// both producer and consumer commands.
///
/// Note that compilation database can be stale, so results from this backend
/// should be treated as preferred hints rather than unquestionable truth.
/// The compound layer below validates or falls back when needed.
class CompileCommandsProjectModules : public ProjectModules {
public:
CompileCommandsProjectModules(
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB,
const ThreadsafeFS &TFS)
: CDB(std::move(CDB)), TFS(TFS) {}
std::vector<std::string> getRequiredModules(PathRef File) override {
auto Parsed = parseFileCommand(File);
if (!Parsed)
return {};
std::vector<std::string> Result;
Result.reserve(Parsed->RequiredModuleFiles.size());
for (const auto &Required : Parsed->RequiredModuleFiles)
Result.push_back(Required.getKey().str());
return Result;
}
std::string getModuleNameForSource(PathRef File) override {
indexProducerCommands();
auto It = SourceToModuleName.find(
maybeCaseFoldPath(normalizePath(File, /*WorkingDir=*/{})));
if (It == SourceToModuleName.end() || It->second.Ambiguous)
return {};
return It->second.Name;
}
ModuleNameState getModuleNameState(llvm::StringRef ModuleName) override {
indexProducerCommands();
auto It = ModuleNameToDistinctSources.find(ModuleName);
if (It == ModuleNameToDistinctSources.end())
return ModuleNameState::Unknown;
return It->second.size() > 1 ? ModuleNameState::Multiple
: ModuleNameState::Unique;
}
std::string getSourceForModuleName(llvm::StringRef ModuleName,
PathRef RequiredSourceFile) override {
auto Parsed = parseFileCommand(RequiredSourceFile);
if (!Parsed)
return {};
auto It = Parsed->RequiredModuleFiles.find(ModuleName);
if (It == Parsed->RequiredModuleFiles.end())
return {};
indexProducerCommands();
auto SourceIt = PCMToSource.find(maybeCaseFoldPath(It->second));
if (SourceIt == PCMToSource.end())
return {};
return SourceIt->second;
}
void setCommandMangler(CommandMangler Mangler) override {
this->Mangler = std::move(Mangler);
ProducerCommandsIndexed = false;
PCMToSource.clear();
ModuleNameToDistinctSources.clear();
SourceToModuleName.clear();
}
private:
/// Parses the compile command for \p File into the module information
/// encoded in the command line.
std::optional<ParsedCompileCommandInfo> parseFileCommand(PathRef File) const {
auto Cmd = getCompileCommandForFile(*CDB, File, Mangler);
if (!Cmd)
return std::nullopt;
return parseCompileCommandInfo(std::move(*Cmd), TFS);
}
/// Builds indexes from producer and consumer compile commands.
///
/// Compile commands are parsed once up front. The first pass records which
/// source file produces each BMI path. The second pass walks consumer
/// commands, uses `-fmodule-file=` information to associate module names with
/// those BMI paths, and then records which producer source files are
/// referenced for each module name.
void indexProducerCommands() {
if (ProducerCommandsIndexed)
return;
std::vector<ParsedCompileCommandInfo> ParsedCommands;
auto AllFiles = CDB->getAllFiles();
ParsedCommands.reserve(AllFiles.size());
for (const auto &File : AllFiles) {
auto Parsed = parseFileCommand(File);
if (!Parsed)
continue;
if (Parsed->OutputModuleFile)
PCMToSource[maybeCaseFoldPath(*Parsed->OutputModuleFile)] =
Parsed->SourceFile;
ParsedCommands.push_back(std::move(*Parsed));
}
for (const auto &Parsed : ParsedCommands) {
for (const auto &Required : Parsed.RequiredModuleFiles) {
auto SourceIt =
PCMToSource.find(maybeCaseFoldPath(Required.getValue()));
if (SourceIt == PCMToSource.end())
continue;
ModuleNameToDistinctSources[Required.getKey()].insert(
maybeCaseFoldPath(SourceIt->second));
auto &Recovered =
SourceToModuleName[maybeCaseFoldPath(SourceIt->second)];
if (Recovered.Name.empty())
Recovered.Name = Required.getKey().str();
else if (Recovered.Name != Required.getKey()) {
if (!Recovered.Ambiguous) {
elog("Detected conflicting module names ('{0}' and '{1}') for "
"the same module file {2} produced by source {3}",
Recovered.Name, Required.getKey(), Required.getValue(),
SourceIt->second);
}
Recovered.Ambiguous = true;
}
}
}
ProducerCommandsIndexed = true;
}
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB;
const ThreadsafeFS &TFS;
CommandMangler Mangler;
bool ProducerCommandsIndexed = false;
llvm::StringMap<std::string> PCMToSource;
using DistinctSourceSet = llvm::StringSet<>;
llvm::StringMap<DistinctSourceSet> ModuleNameToDistinctSources;
struct RecoveredModuleName {
std::string Name;
bool Ambiguous = false;
};
llvm::StringMap<RecoveredModuleName> SourceToModuleName;
};
/// Combines the compile-commands backend with the scanning backend.
///
/// For getSourceForModuleName, it prefers compile-command-derived results when
/// available to avoid scanning the whole project, but validates them against
/// scanning results to avoid returning stale information. For other queries,
/// it returns scanning results directly as scanning information is update to
/// date.
class CompoundProjectModules : public ProjectModules {
public:
CompoundProjectModules(
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB,
const ThreadsafeFS &TFS)
: CompileCommands(
std::make_unique<CompileCommandsProjectModules>(CDB, TFS)),
Scanning(
std::make_unique<ScanningAllProjectModules>(std::move(CDB), TFS)) {}
std::vector<std::string> getRequiredModules(PathRef File) override {
// Return scanning results directly as it is fast enough and up to date.
return Scanning->getRequiredModules(File);
}
std::string getModuleNameForSource(PathRef File) override {
// Return scanning results directly as it is fast enough and up to date.
return Scanning->getModuleNameForSource(File);
}
std::string getSourceForModuleName(llvm::StringRef ModuleName,
PathRef RequiredSourceFile) override {
auto FromCompileCommands =
CompileCommands->getSourceForModuleName(ModuleName, RequiredSourceFile);
// Check if the source still declares the module.
// This is to validate compile-command-derived results may be stale and
// scan a single file is fast enough. We just don't want to scan the project
// entirely.
if (!FromCompileCommands.empty() &&
Scanning->getModuleNameForSource(FromCompileCommands) == ModuleName)
return FromCompileCommands;
return Scanning->getSourceForModuleName(ModuleName, RequiredSourceFile);
}
ModuleNameState getModuleNameState(llvm::StringRef ModuleName) override {
auto FromCompileCommands = CompileCommands->getModuleNameState(ModuleName);
if (FromCompileCommands != ModuleNameState::Unknown)
return FromCompileCommands;
return Scanning->getModuleNameState(ModuleName);
}
void setCommandMangler(CommandMangler Mangler) override {
this->Mangler = std::move(Mangler);
auto ForwardMangler = [this](tooling::CompileCommand &Command,
PathRef CommandPath) {
if (this->Mangler)
this->Mangler(Command, CommandPath);
};
CompileCommands->setCommandMangler(ForwardMangler);
Scanning->setCommandMangler(std::move(ForwardMangler));
}
private:
std::unique_ptr<CompileCommandsProjectModules> CompileCommands;
std::unique_ptr<ScanningAllProjectModules> Scanning;
CommandMangler Mangler;
};
/// Creates the project-modules facade used by clangd.
///
/// The implementation is intentionally layered:
///
/// CompoundProjectModules
/// / \
/// v v
/// CompileCommands ScanningAllProjectModules
/// ProjectModules |
/// | v
/// | ModuleDependencyScanner
/// |
/// +-- preferred specifically for recovering the source file for a module
/// | name in the context of a consumer TU, because compile commands
/// | encode `module name -> BMI -> producer source`
/// |
/// +-- scanning remains fallback/validation for stale or missing data
///
/// - `CompileCommandsProjectModules` reads module relationships that the build
/// system already made explicit in compile commands. In particular, it uses
/// producer-side BMI output paths together with consumer-side
/// `-fmodule-file=<module>=<bmi>` entries to recover the module unit source a
/// TU actually depends on. This is the preferred source because it can
/// distinguish different module producers for the same module name when
/// different translation units reference different BMIs.
/// - `ScanningAllProjectModules` derives module information by scanning source
/// files. It is more expensive, but it can still answer queries that are not
/// present in compile commands and validate compile-command-derived results.
/// - `CompoundProjectModules` arbitrates between the two backends on a
/// per-query basis. Compile commands are especially valuable for
/// `getSourceForModuleName()` because they preserve the consumer TU's actual
/// `module name -> BMI` choice. Other queries may still fall back to, or be
/// validated by, scanning because compile-command information may be
/// incomplete or stale.
///
/// This split keeps the logic simple: compile commands provide precision when
/// available, while scanning preserves compatibility with projects that have
/// incomplete module information in their compilation database.
std::unique_ptr<ProjectModules> getProjectModules(
std::shared_ptr<const clang::tooling::CompilationDatabase> CDB,
const ThreadsafeFS &TFS) {
return std::make_unique<CompoundProjectModules>(std::move(CDB), TFS);
}
} // namespace clang::clangd