/// This is where the link is actually performed. bool Driver::link(LinkingContext &ctx, raw_ostream &diagnostics) { if (ctx.getNodes().empty()) return false; for (std::unique_ptr<Node> &ie : ctx.getNodes()) if (FileNode *node = dyn_cast<FileNode>(ie.get())) ctx.getTaskGroup().spawn([node] { node->getFile()->parse(); }); std::vector<std::unique_ptr<File>> internalFiles; ctx.createInternalFiles(internalFiles); for (auto i = internalFiles.rbegin(), e = internalFiles.rend(); i != e; ++i) { auto &members = ctx.getNodes(); members.insert(members.begin(), llvm::make_unique<FileNode>(std::move(*i))); } // Give target a chance to add files. std::vector<std::unique_ptr<File>> implicitFiles; ctx.createImplicitFiles(implicitFiles); for (auto i = implicitFiles.rbegin(), e = implicitFiles.rend(); i != e; ++i) { auto &members = ctx.getNodes(); members.insert(members.begin(), llvm::make_unique<FileNode>(std::move(*i))); } // Give target a chance to postprocess input files. // Mach-O uses this chance to move all object files before library files. // ELF adds specific undefined symbols resolver. ctx.finalizeInputFiles(); // Do core linking. ScopedTask resolveTask(getDefaultDomain(), "Resolve"); Resolver resolver(ctx); if (!resolver.resolve()) { ctx.getTaskGroup().sync(); return false; } std::unique_ptr<SimpleFile> merged = resolver.resultFile(); resolveTask.end(); // Run passes on linked atoms. ScopedTask passTask(getDefaultDomain(), "Passes"); PassManager pm; ctx.addPasses(pm); if (std::error_code ec = pm.runOnFile(*merged)) { diagnostics << "Failed to write file '" << ctx.outputPath() << "': " << ec.message() << "\n"; return false; } passTask.end(); // Give linked atoms to Writer to generate output file. ScopedTask writeTask(getDefaultDomain(), "Write"); if (std::error_code ec = ctx.writeFile(*merged)) { diagnostics << "Failed to write file '" << ctx.outputPath() << "': " << ec.message() << "\n"; return false; } return true; }
/// This is where the link is actually performed. bool Driver::link(const LinkingContext &context, raw_ostream &diagnostics) { // Honor -mllvm if (!context.llvmOptions().empty()) { unsigned numArgs = context.llvmOptions().size(); const char **args = new const char *[numArgs + 2]; args[0] = "lld (LLVM option parsing)"; for (unsigned i = 0; i != numArgs; ++i) args[i + 1] = context.llvmOptions()[i]; args[numArgs + 1] = 0; llvm::cl::ParseCommandLineOptions(numArgs + 1, args); } InputGraph &inputGraph = context.inputGraph(); if (!inputGraph.numFiles()) return false; // Read inputs ScopedTask readTask(getDefaultDomain(), "Read Args"); std::vector<std::vector<std::unique_ptr<File> > > files( inputGraph.numFiles()); size_t index = 0; std::atomic<bool> fail(false); TaskGroup tg; std::vector<std::unique_ptr<LinkerInput> > linkerInputs; for (auto &ie : inputGraph.inputElements()) { if (ie->kind() == InputElement::Kind::File) { FileNode *fileNode = (llvm::dyn_cast<FileNode>)(ie.get()); auto linkerInput = fileNode->createLinkerInput(context); if (!linkerInput) { llvm::outs() << fileNode->errStr(error_code(linkerInput)) << "\n"; return false; } linkerInputs.push_back(std::move(*linkerInput)); } else { llvm_unreachable("Not handling other types of InputElements"); } } for (const auto &input : linkerInputs) { if (context.logInputFiles()) llvm::outs() << input->getUserPath() << "\n"; tg.spawn([ &, index]{ if (error_code ec = context.parseFile(*input, files[index])) { diagnostics << "Failed to read file: " << input->getUserPath() << ": " << ec.message() << "\n"; fail = true; return; } }); ++index; } tg.sync(); readTask.end(); if (fail) return false; InputFiles inputs; for (auto &f : inputGraph.internalFiles()) inputs.appendFile(*f.get()); for (auto &f : files) inputs.appendFiles(f); // Give target a chance to add files. context.addImplicitFiles(inputs); // assign an ordinal to each file so sort() can preserve command line order inputs.assignFileOrdinals(); // Do core linking. ScopedTask resolveTask(getDefaultDomain(), "Resolve"); Resolver resolver(context, inputs); if (resolver.resolve()) { if (!context.allowRemainingUndefines()) return false; } MutableFile &merged = resolver.resultFile(); resolveTask.end(); // Run passes on linked atoms. ScopedTask passTask(getDefaultDomain(), "Passes"); PassManager pm; context.addPasses(pm); pm.runOnFile(merged); passTask.end(); // Give linked atoms to Writer to generate output file. ScopedTask writeTask(getDefaultDomain(), "Write"); if (error_code ec = context.writeFile(merged)) { diagnostics << "Failed to write file '" << context.outputPath() << "': " << ec.message() << "\n"; return false; } return true; }