/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying file Copyright.txt or https://cmake.org/licensing for details. */ #include "cmNinjaNormalTargetGenerator.h" #include #include #include #include #include #include #include #include #include #include #include #include "cmComputeLinkInformation.h" #include "cmCustomCommand.h" // IWYU pragma: keep #include "cmCustomCommandGenerator.h" #include "cmGeneratedFileStream.h" #include "cmGeneratorTarget.h" #include "cmGlobalNinjaGenerator.h" #include "cmLinkLineComputer.h" #include "cmLinkLineDeviceComputer.h" #include "cmLocalCommonGenerator.h" #include "cmLocalGenerator.h" #include "cmLocalNinjaGenerator.h" #include "cmMakefile.h" #include "cmMessageType.h" #include "cmNinjaLinkLineDeviceComputer.h" #include "cmNinjaTypes.h" #include "cmOSXBundleGenerator.h" #include "cmOutputConverter.h" #include "cmRulePlaceholderExpander.h" #include "cmSourceFile.h" #include "cmState.h" #include "cmStateDirectory.h" #include "cmStateSnapshot.h" #include "cmStateTypes.h" #include "cmStringAlgorithms.h" #include "cmSystemTools.h" #include "cmValue.h" cmNinjaNormalTargetGenerator::cmNinjaNormalTargetGenerator( cmGeneratorTarget* target) : cmNinjaTargetGenerator(target) { if (target->GetType() != cmStateEnums::OBJECT_LIBRARY) { // on Windows the output dir is already needed at compile time // ensure the directory exists (OutDir test) for (auto const& config : this->GetConfigNames()) { this->EnsureDirectoryExists(target->GetDirectory(config)); } } this->OSXBundleGenerator = cm::make_unique(target); this->OSXBundleGenerator->SetMacContentFolders(&this->MacContentFolders); } cmNinjaNormalTargetGenerator::~cmNinjaNormalTargetGenerator() = default; void cmNinjaNormalTargetGenerator::Generate(const std::string& config) { std::string lang = this->GeneratorTarget->GetLinkerLanguage(config); if (this->TargetLinkLanguage(config).empty()) { cmSystemTools::Error("CMake can not determine linker language for " "target: " + this->GetGeneratorTarget()->GetName()); return; } // Write the rules for each language. this->WriteLanguagesRules(config); // Write the build statements bool firstForConfig = true; for (auto const& fileConfig : this->GetConfigNames()) { if (!this->GetGlobalGenerator() ->GetCrossConfigs(fileConfig) .count(config)) { continue; } this->WriteObjectBuildStatements(config, fileConfig, firstForConfig); firstForConfig = false; } if (this->GetGeneratorTarget()->GetType() == cmStateEnums::OBJECT_LIBRARY) { this->WriteObjectLibStatement(config); } else { firstForConfig = true; for (auto const& fileConfig : this->GetConfigNames()) { if (!this->GetGlobalGenerator() ->GetCrossConfigs(fileConfig) .count(config)) { continue; } // If this target has cuda language link inputs, and we need to do // device linking this->WriteDeviceLinkStatement(config, fileConfig, firstForConfig); this->WriteLinkStatement(config, fileConfig, firstForConfig); firstForConfig = false; } } if (this->GetGlobalGenerator()->EnableCrossConfigBuild()) { this->GetGlobalGenerator()->AddTargetAlias( this->GetTargetName(), this->GetGeneratorTarget(), "all"); } // Find ADDITIONAL_CLEAN_FILES this->AdditionalCleanFiles(config); } void cmNinjaNormalTargetGenerator::WriteLanguagesRules( const std::string& config) { #ifdef NINJA_GEN_VERBOSE_FILES cmGlobalNinjaGenerator::WriteDivider(this->GetRulesFileStream()); this->GetRulesFileStream() << "# Rules for each languages for " << cmState::GetTargetTypeName(this->GetGeneratorTarget()->GetType()) << " target " << this->GetTargetName() << "\n\n"; #endif // Write rules for languages compiled in this target. std::set languages; std::vector sourceFiles; this->GetGeneratorTarget()->GetObjectSources(sourceFiles, config); if (this->HaveRequiredLanguages(sourceFiles, languages)) { for (std::string const& language : languages) { this->WriteLanguageRules(language, config); } } } const char* cmNinjaNormalTargetGenerator::GetVisibleTypeName() const { switch (this->GetGeneratorTarget()->GetType()) { case cmStateEnums::STATIC_LIBRARY: return "static library"; case cmStateEnums::SHARED_LIBRARY: return "shared library"; case cmStateEnums::MODULE_LIBRARY: if (this->GetGeneratorTarget()->IsCFBundleOnApple()) { return "CFBundle shared module"; } else { return "shared module"; } case cmStateEnums::EXECUTABLE: return "executable"; default: return nullptr; } } std::string cmNinjaNormalTargetGenerator::LanguageLinkerRule( const std::string& config) const { return cmStrCat( this->TargetLinkLanguage(config), "_", cmState::GetTargetTypeName(this->GetGeneratorTarget()->GetType()), "_LINKER__", cmGlobalNinjaGenerator::EncodeRuleName( this->GetGeneratorTarget()->GetName()), "_", config); } std::string cmNinjaNormalTargetGenerator::LanguageLinkerDeviceRule( const std::string& config) const { return cmStrCat( this->TargetLinkLanguage(config), "_", cmState::GetTargetTypeName(this->GetGeneratorTarget()->GetType()), "_DEVICE_LINKER__", cmGlobalNinjaGenerator::EncodeRuleName( this->GetGeneratorTarget()->GetName()), "_", config); } std::string cmNinjaNormalTargetGenerator::LanguageLinkerCudaDeviceRule( const std::string& config) const { return cmStrCat( this->TargetLinkLanguage(config), "_DEVICE_LINK__", cmGlobalNinjaGenerator::EncodeRuleName(this->GeneratorTarget->GetName()), '_', config); } std::string cmNinjaNormalTargetGenerator::LanguageLinkerCudaDeviceCompileRule( const std::string& config) const { return cmStrCat( this->TargetLinkLanguage(config), "_DEVICE_LINK_COMPILE__", cmGlobalNinjaGenerator::EncodeRuleName(this->GeneratorTarget->GetName()), '_', config); } std::string cmNinjaNormalTargetGenerator::LanguageLinkerCudaFatbinaryRule( const std::string& config) const { return cmStrCat( this->TargetLinkLanguage(config), "_FATBINARY__", cmGlobalNinjaGenerator::EncodeRuleName(this->GeneratorTarget->GetName()), '_', config); } struct cmNinjaRemoveNoOpCommands { bool operator()(std::string const& cmd) { return cmd.empty() || cmd[0] == ':'; } }; void cmNinjaNormalTargetGenerator::WriteNvidiaDeviceLinkRule( bool useResponseFile, const std::string& config) { cmNinjaRule rule(this->LanguageLinkerDeviceRule(config)); if (!this->GetGlobalGenerator()->HasRule(rule.Name)) { cmRulePlaceholderExpander::RuleVariables vars; vars.CMTargetName = this->GetGeneratorTarget()->GetName().c_str(); vars.CMTargetType = cmState::GetTargetTypeName(this->GetGeneratorTarget()->GetType()) .c_str(); vars.Language = "CUDA"; // build response file name std::string responseFlag = this->GetMakefile()->GetSafeDefinition( "CMAKE_CUDA_RESPONSE_FILE_DEVICE_LINK_FLAG"); if (!useResponseFile || responseFlag.empty()) { vars.Objects = "$in"; vars.LinkLibraries = "$LINK_PATH $LINK_LIBRARIES"; } else { rule.RspFile = "$RSP_FILE"; responseFlag += rule.RspFile; // build response file content if (this->GetGlobalGenerator()->IsGCCOnWindows()) { rule.RspContent = "$in"; } else { rule.RspContent = "$in_newline"; } rule.RspContent += " $LINK_LIBRARIES"; vars.Objects = responseFlag.c_str(); vars.LinkLibraries = ""; } vars.ObjectDir = "$OBJECT_DIR"; vars.Target = "$TARGET_FILE"; vars.SONameFlag = "$SONAME_FLAG"; vars.TargetSOName = "$SONAME"; vars.TargetPDB = "$TARGET_PDB"; vars.TargetCompilePDB = "$TARGET_COMPILE_PDB"; vars.Flags = "$FLAGS"; vars.LinkFlags = "$LINK_FLAGS"; vars.Manifests = "$MANIFESTS"; vars.LanguageCompileFlags = "$LANGUAGE_COMPILE_FLAGS"; std::string launcher; cmValue val = this->GetLocalGenerator()->GetRuleLauncher( this->GetGeneratorTarget(), "RULE_LAUNCH_LINK"); if (cmNonempty(val)) { launcher = cmStrCat(*val, ' '); } std::unique_ptr rulePlaceholderExpander( this->GetLocalGenerator()->CreateRulePlaceholderExpander()); // Rule for linking library/executable. std::vector linkCmds = this->ComputeDeviceLinkCmd(); for (std::string& linkCmd : linkCmds) { linkCmd = cmStrCat(launcher, linkCmd); rulePlaceholderExpander->ExpandRuleVariables(this->GetLocalGenerator(), linkCmd, vars); } // If there is no ranlib the command will be ":". Skip it. cm::erase_if(linkCmds, cmNinjaRemoveNoOpCommands()); rule.Command = this->GetLocalGenerator()->BuildCommandLine(linkCmds, config, config); // Write the linker rule with response file if needed. rule.Comment = cmStrCat("Rule for linking ", this->TargetLinkLanguage(config), ' ', this->GetVisibleTypeName(), '.'); rule.Description = cmStrCat("Linking ", this->TargetLinkLanguage(config), ' ', this->GetVisibleTypeName(), " $TARGET_FILE"); rule.Restat = "$RESTAT"; this->GetGlobalGenerator()->AddRule(rule); } } void cmNinjaNormalTargetGenerator::WriteDeviceLinkRules( const std::string& config) { const cmMakefile* mf = this->GetMakefile(); cmNinjaRule rule(this->LanguageLinkerCudaDeviceRule(config)); rule.Command = this->GetLocalGenerator()->BuildCommandLine( { cmStrCat(mf->GetRequiredDefinition("CMAKE_CUDA_DEVICE_LINKER"), " -arch=$ARCH $REGISTER -o=$out $in") }, config, config); rule.Comment = "Rule for CUDA device linking."; rule.Description = "Linking CUDA $out"; this->GetGlobalGenerator()->AddRule(rule); cmRulePlaceholderExpander::RuleVariables vars; vars.CMTargetName = this->GetGeneratorTarget()->GetName().c_str(); vars.CMTargetType = cmState::GetTargetTypeName(this->GetGeneratorTarget()->GetType()).c_str(); vars.Language = "CUDA"; vars.Object = "$out"; vars.Fatbinary = "$FATBIN"; vars.RegisterFile = "$REGISTER"; vars.LinkFlags = "$LINK_FLAGS"; std::string flags = this->GetFlags("CUDA", config); vars.Flags = flags.c_str(); std::string compileCmd = this->GetMakefile()->GetRequiredDefinition( "CMAKE_CUDA_DEVICE_LINK_COMPILE"); std::unique_ptr rulePlaceholderExpander( this->GetLocalGenerator()->CreateRulePlaceholderExpander()); rulePlaceholderExpander->ExpandRuleVariables(this->GetLocalGenerator(), compileCmd, vars); rule.Name = this->LanguageLinkerCudaDeviceCompileRule(config); rule.Command = this->GetLocalGenerator()->BuildCommandLine({ compileCmd }, config, config); rule.Comment = "Rule for compiling CUDA device stubs."; rule.Description = "Compiling CUDA device stub $out"; this->GetGlobalGenerator()->AddRule(rule); rule.Name = this->LanguageLinkerCudaFatbinaryRule(config); rule.Command = this->GetLocalGenerator()->BuildCommandLine( { cmStrCat(mf->GetRequiredDefinition("CMAKE_CUDA_FATBINARY"), " -64 -cmdline=--compile-only -compress-all -link " "--embedded-fatbin=$out $PROFILES") }, config, config); rule.Comment = "Rule for CUDA fatbinaries."; rule.Description = "Creating fatbinary $out"; this->GetGlobalGenerator()->AddRule(rule); } void cmNinjaNormalTargetGenerator::WriteLinkRule(bool useResponseFile, const std::string& config) { cmStateEnums::TargetType targetType = this->GetGeneratorTarget()->GetType(); std::string linkRuleName = this->LanguageLinkerRule(config); if (!this->GetGlobalGenerator()->HasRule(linkRuleName)) { cmNinjaRule rule(std::move(linkRuleName)); cmRulePlaceholderExpander::RuleVariables vars; vars.CMTargetName = this->GetGeneratorTarget()->GetName().c_str(); vars.CMTargetType = cmState::GetTargetTypeName(targetType).c_str(); std::string lang = this->TargetLinkLanguage(config); vars.Language = lang.c_str(); vars.AIXExports = "$AIX_EXPORTS"; if (this->TargetLinkLanguage(config) == "Swift") { vars.SwiftLibraryName = "$SWIFT_LIBRARY_NAME"; vars.SwiftModule = "$SWIFT_MODULE"; vars.SwiftModuleName = "$SWIFT_MODULE_NAME"; vars.SwiftOutputFileMap = "$SWIFT_OUTPUT_FILE_MAP"; vars.SwiftSources = "$SWIFT_SOURCES"; vars.Defines = "$DEFINES"; vars.Flags = "$FLAGS"; vars.Includes = "$INCLUDES"; } std::string responseFlag; std::string cmakeVarLang = cmStrCat("CMAKE_", this->TargetLinkLanguage(config)); // build response file name std::string cmakeLinkVar = cmakeVarLang + "_RESPONSE_FILE_LINK_FLAG"; cmValue flag = this->GetMakefile()->GetDefinition(cmakeLinkVar); if (flag) { responseFlag = *flag; } else { responseFlag = "@"; } if (!useResponseFile || responseFlag.empty()) { vars.Objects = "$in"; vars.LinkLibraries = "$LINK_PATH $LINK_LIBRARIES"; } else { rule.RspFile = "$RSP_FILE"; responseFlag += rule.RspFile; // build response file content if (this->GetGlobalGenerator()->IsGCCOnWindows()) { rule.RspContent = "$in"; } else { rule.RspContent = "$in_newline"; } rule.RspContent += " $LINK_PATH $LINK_LIBRARIES"; if (this->TargetLinkLanguage(config) == "Swift") { vars.SwiftSources = responseFlag.c_str(); } else { vars.Objects = responseFlag.c_str(); } vars.LinkLibraries = ""; } vars.ObjectDir = "$OBJECT_DIR"; vars.Target = "$TARGET_FILE"; vars.SONameFlag = "$SONAME_FLAG"; vars.TargetSOName = "$SONAME"; vars.TargetInstallNameDir = "$INSTALLNAME_DIR"; vars.TargetPDB = "$TARGET_PDB"; // Setup the target version. std::string targetVersionMajor; std::string targetVersionMinor; { std::ostringstream majorStream; std::ostringstream minorStream; int major; int minor; this->GetGeneratorTarget()->GetTargetVersion(major, minor); majorStream << major; minorStream << minor; targetVersionMajor = majorStream.str(); targetVersionMinor = minorStream.str(); } vars.TargetVersionMajor = targetVersionMajor.c_str(); vars.TargetVersionMinor = targetVersionMinor.c_str(); vars.Flags = "$FLAGS"; vars.LinkFlags = "$LINK_FLAGS"; vars.Manifests = "$MANIFESTS"; std::string langFlags; if (targetType != cmStateEnums::EXECUTABLE) { langFlags += "$LANGUAGE_COMPILE_FLAGS $ARCH_FLAGS"; vars.LanguageCompileFlags = langFlags.c_str(); } std::string linkerLauncher = this->GetLinkerLauncher(config); if (cmNonempty(linkerLauncher)) { vars.Launcher = linkerLauncher.c_str(); } std::string launcher; cmValue val = this->GetLocalGenerator()->GetRuleLauncher( this->GetGeneratorTarget(), "RULE_LAUNCH_LINK"); if (cmNonempty(val)) { launcher = cmStrCat(*val, ' '); } std::unique_ptr rulePlaceholderExpander( this->GetLocalGenerator()->CreateRulePlaceholderExpander()); // Rule for linking library/executable. std::vector linkCmds = this->ComputeLinkCmd(config); for (std::string& linkCmd : linkCmds) { linkCmd = cmStrCat(launcher, linkCmd); rulePlaceholderExpander->ExpandRuleVariables(this->GetLocalGenerator(), linkCmd, vars); } // If there is no ranlib the command will be ":". Skip it. cm::erase_if(linkCmds, cmNinjaRemoveNoOpCommands()); linkCmds.insert(linkCmds.begin(), "$PRE_LINK"); linkCmds.emplace_back("$POST_BUILD"); rule.Command = this->GetLocalGenerator()->BuildCommandLine(linkCmds, config, config); // Write the linker rule with response file if needed. rule.Comment = cmStrCat("Rule for linking ", this->TargetLinkLanguage(config), ' ', this->GetVisibleTypeName(), '.'); rule.Description = cmStrCat("Linking ", this->TargetLinkLanguage(config), ' ', this->GetVisibleTypeName(), " $TARGET_FILE"); rule.Restat = "$RESTAT"; this->GetGlobalGenerator()->AddRule(rule); } auto const tgtNames = this->TargetNames(config); if (tgtNames.Output != tgtNames.Real && !this->GetGeneratorTarget()->IsFrameworkOnApple()) { std::string cmakeCommand = this->GetLocalGenerator()->ConvertToOutputFormat( cmSystemTools::GetCMakeCommand(), cmOutputConverter::SHELL); if (targetType == cmStateEnums::EXECUTABLE) { cmNinjaRule rule("CMAKE_SYMLINK_EXECUTABLE"); { std::vector cmd; cmd.push_back(cmakeCommand + " -E cmake_symlink_executable $in $out"); cmd.emplace_back("$POST_BUILD"); rule.Command = this->GetLocalGenerator()->BuildCommandLine(cmd, config, config); } rule.Description = "Creating executable symlink $out"; rule.Comment = "Rule for creating executable symlink."; this->GetGlobalGenerator()->AddRule(rule); } else { cmNinjaRule rule("CMAKE_SYMLINK_LIBRARY"); { std::vector cmd; cmd.push_back(cmakeCommand + " -E cmake_symlink_library $in $SONAME $out"); cmd.emplace_back("$POST_BUILD"); rule.Command = this->GetLocalGenerator()->BuildCommandLine(cmd, config, config); } rule.Description = "Creating library symlink $out"; rule.Comment = "Rule for creating library symlink."; this->GetGlobalGenerator()->AddRule(rule); } } } std::vector cmNinjaNormalTargetGenerator::ComputeDeviceLinkCmd() { std::vector linkCmds; // this target requires separable cuda compilation // now build the correct command depending on if the target is // an executable or a dynamic library. std::string linkCmd; switch (this->GetGeneratorTarget()->GetType()) { case cmStateEnums::STATIC_LIBRARY: case cmStateEnums::SHARED_LIBRARY: case cmStateEnums::MODULE_LIBRARY: { this->GetMakefile()->GetDefExpandList("CMAKE_CUDA_DEVICE_LINK_LIBRARY", linkCmds); } break; case cmStateEnums::EXECUTABLE: { this->GetMakefile()->GetDefExpandList( "CMAKE_CUDA_DEVICE_LINK_EXECUTABLE", linkCmds); } break; default: break; } return linkCmds; } std::vector cmNinjaNormalTargetGenerator::ComputeLinkCmd( const std::string& config) { std::vector linkCmds; cmMakefile* mf = this->GetMakefile(); { // If we have a rule variable prefer it. In the case of static libraries // this occurs when things like IPO is enabled, and we need to use the // CMAKE__CREATE_STATIC_LIBRARY_IPO define instead. std::string linkCmdVar = this->GetGeneratorTarget()->GetCreateRuleVariable( this->TargetLinkLanguage(config), config); cmValue linkCmd = mf->GetDefinition(linkCmdVar); if (linkCmd) { std::string linkCmdStr = *linkCmd; if (this->GetGeneratorTarget()->HasImplibGNUtoMS(config)) { std::string ruleVar = cmStrCat("CMAKE_", this->GeneratorTarget->GetLinkerLanguage(config), "_GNUtoMS_RULE"); if (cmValue rule = this->Makefile->GetDefinition(ruleVar)) { linkCmdStr += *rule; } } cmExpandList(linkCmdStr, linkCmds); if (this->UseLWYU) { cmValue lwyuCheck = mf->GetDefinition("CMAKE_LINK_WHAT_YOU_USE_CHECK"); if (lwyuCheck) { std::string cmakeCommand = cmStrCat( this->GetLocalGenerator()->ConvertToOutputFormat( cmSystemTools::GetCMakeCommand(), cmLocalGenerator::SHELL), " -E __run_co_compile --lwyu="); cmakeCommand += this->GetLocalGenerator()->EscapeForShell(*lwyuCheck); std::string targetOutputReal = this->ConvertToNinjaPath(this->GetGeneratorTarget()->GetFullPath( config, cmStateEnums::RuntimeBinaryArtifact, /*realname=*/true)); cmakeCommand += cmStrCat(" --source=", targetOutputReal); linkCmds.push_back(std::move(cmakeCommand)); } } return linkCmds; } } switch (this->GetGeneratorTarget()->GetType()) { case cmStateEnums::STATIC_LIBRARY: { // We have archive link commands set. First, delete the existing archive. { std::string cmakeCommand = this->GetLocalGenerator()->ConvertToOutputFormat( cmSystemTools::GetCMakeCommand(), cmOutputConverter::SHELL); linkCmds.push_back(cmakeCommand + " -E rm -f $TARGET_FILE"); } // TODO: Use ARCHIVE_APPEND for archives over a certain size. { std::string linkCmdVar = cmStrCat( "CMAKE_", this->TargetLinkLanguage(config), "_ARCHIVE_CREATE"); linkCmdVar = this->GeneratorTarget->GetFeatureSpecificLinkRuleVariable( linkCmdVar, this->TargetLinkLanguage(config), config); std::string const& linkCmd = mf->GetRequiredDefinition(linkCmdVar); cmExpandList(linkCmd, linkCmds); } { std::string linkCmdVar = cmStrCat( "CMAKE_", this->TargetLinkLanguage(config), "_ARCHIVE_FINISH"); linkCmdVar = this->GeneratorTarget->GetFeatureSpecificLinkRuleVariable( linkCmdVar, this->TargetLinkLanguage(config), config); std::string const& linkCmd = mf->GetRequiredDefinition(linkCmdVar); cmExpandList(linkCmd, linkCmds); } #ifdef __APPLE__ // On macOS ranlib truncates the fractional part of the static archive // file modification time. If the archive and at least one contained // object file were created within the same second this will make look // the archive older than the object file. On subsequent ninja runs this // leads to re-achiving and updating dependent targets. // As a work-around we touch the archive after ranlib (see #19222). { std::string cmakeCommand = this->GetLocalGenerator()->ConvertToOutputFormat( cmSystemTools::GetCMakeCommand(), cmOutputConverter::SHELL); linkCmds.push_back(cmakeCommand + " -E touch $TARGET_FILE"); } #endif } break; case cmStateEnums::SHARED_LIBRARY: case cmStateEnums::MODULE_LIBRARY: break; case cmStateEnums::EXECUTABLE: if (this->TargetLinkLanguage(config) == "Swift") { if (this->GeneratorTarget->IsExecutableWithExports()) { this->Makefile->GetDefExpandList("CMAKE_EXE_EXPORTS_Swift_FLAG", linkCmds); } } break; default: assert(false && "Unexpected target type"); } return linkCmds; } void cmNinjaNormalTargetGenerator::WriteDeviceLinkStatement( const std::string& config, const std::string& fileConfig, bool firstForConfig) { cmGlobalNinjaGenerator* globalGen = this->GetGlobalGenerator(); if (!globalGen->GetLanguageEnabled("CUDA")) { return; } cmGeneratorTarget* genTarget = this->GetGeneratorTarget(); bool requiresDeviceLinking = requireDeviceLinking( *this->GeneratorTarget, *this->GetLocalGenerator(), config); if (!requiresDeviceLinking) { return; } // First and very important step is to make sure while inside this // step our link language is set to CUDA std::string const& objExt = this->Makefile->GetSafeDefinition("CMAKE_CUDA_OUTPUT_EXTENSION"); std::string targetOutputDir = cmStrCat(this->GetLocalGenerator()->GetTargetDirectory(genTarget), globalGen->ConfigDirectory(config), "/"); targetOutputDir = globalGen->ExpandCFGIntDir(targetOutputDir, config); std::string targetOutputReal = this->ConvertToNinjaPath(targetOutputDir + "cmake_device_link" + objExt); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back(targetOutputReal); } this->DeviceLinkObject = targetOutputReal; // Write comments. cmGlobalNinjaGenerator::WriteDivider(this->GetCommonFileStream()); this->GetCommonFileStream() << "# Device Link build statements for " << cmState::GetTargetTypeName(genTarget->GetType()) << " target " << this->GetTargetName() << "\n\n"; if (this->Makefile->GetSafeDefinition("CMAKE_CUDA_COMPILER_ID") == "Clang") { std::string architecturesStr = this->GeneratorTarget->GetSafeProperty("CUDA_ARCHITECTURES"); if (cmIsOff(architecturesStr)) { this->Makefile->IssueMessage(MessageType::FATAL_ERROR, "CUDA_SEPARABLE_COMPILATION on Clang " "requires CUDA_ARCHITECTURES to be set."); return; } this->WriteDeviceLinkRules(config); this->WriteDeviceLinkStatements(config, cmExpandedList(architecturesStr), targetOutputReal); } else { this->WriteNvidiaDeviceLinkStatement(config, fileConfig, targetOutputDir, targetOutputReal); } } void cmNinjaNormalTargetGenerator::WriteDeviceLinkStatements( const std::string& config, const std::vector& architectures, const std::string& output) { // Ensure there are no duplicates. const cmNinjaDeps explicitDeps = [&]() -> std::vector { std::unordered_set depsSet; const cmNinjaDeps linkDeps = this->ComputeLinkDeps(this->TargetLinkLanguage(config), config, true); const cmNinjaDeps objects = this->GetObjects(config); depsSet.insert(linkDeps.begin(), linkDeps.end()); depsSet.insert(objects.begin(), objects.end()); std::vector deps; std::copy(depsSet.begin(), depsSet.end(), std::back_inserter(deps)); return deps; }(); cmGlobalNinjaGenerator* globalGen{ this->GetGlobalGenerator() }; const std::string objectDir = cmStrCat(this->GeneratorTarget->GetSupportDirectory(), globalGen->ConfigDirectory(config)); const std::string ninjaOutputDir = this->ConvertToNinjaPath(objectDir); cmNinjaBuild fatbinary(this->LanguageLinkerCudaFatbinaryRule(config)); // Link device code for each architecture. for (const std::string& architectureKind : architectures) { // Clang always generates real code, so strip the specifier. const std::string architecture = architectureKind.substr(0, architectureKind.find('-')); const std::string cubin = cmStrCat(ninjaOutputDir, "/sm_", architecture, ".cubin"); cmNinjaBuild dlink(this->LanguageLinkerCudaDeviceRule(config)); dlink.ExplicitDeps = explicitDeps; dlink.Outputs = { cubin }; dlink.Variables["ARCH"] = cmStrCat("sm_", architecture); // The generated register file contains macros that when expanded register // the device routines. Because the routines are the same for all // architectures the register file will be the same too. Thus generate it // only on the first invocation to reduce overhead. if (fatbinary.ExplicitDeps.empty()) { dlink.Variables["REGISTER"] = cmStrCat( "--register-link-binaries=", ninjaOutputDir, "/cmake_cuda_register.h"); } fatbinary.Variables["PROFILES"] += cmStrCat(" -im=profile=sm_", architecture, ",file=", cubin); fatbinary.ExplicitDeps.emplace_back(cubin); globalGen->WriteBuild(this->GetCommonFileStream(), dlink); } // Combine all architectures into a single fatbinary. fatbinary.Outputs = { cmStrCat(ninjaOutputDir, "/cmake_cuda_fatbin.h") }; globalGen->WriteBuild(this->GetCommonFileStream(), fatbinary); // Compile the stub that registers the kernels and contains the fatbinaries. cmLocalNinjaGenerator* localGen{ this->GetLocalGenerator() }; cmNinjaBuild dcompile(this->LanguageLinkerCudaDeviceCompileRule(config)); dcompile.Outputs = { output }; dcompile.ExplicitDeps = { cmStrCat(ninjaOutputDir, "/cmake_cuda_fatbin.h") }; dcompile.Variables["FATBIN"] = localGen->ConvertToOutputFormat( cmStrCat(objectDir, "/cmake_cuda_fatbin.h"), cmOutputConverter::SHELL); dcompile.Variables["REGISTER"] = localGen->ConvertToOutputFormat( cmStrCat(objectDir, "/cmake_cuda_register.h"), cmOutputConverter::SHELL); cmNinjaLinkLineDeviceComputer linkLineComputer( localGen, localGen->GetStateSnapshot().GetDirectory(), globalGen); linkLineComputer.SetUseNinjaMulti(globalGen->IsMultiConfig()); // Link libraries and paths are only used during the final executable/library // link. std::string frameworkPath; std::string linkPath; std::string linkLibs; localGen->GetDeviceLinkFlags(linkLineComputer, config, linkLibs, dcompile.Variables["LINK_FLAGS"], frameworkPath, linkPath, this->GetGeneratorTarget()); globalGen->WriteBuild(this->GetCommonFileStream(), dcompile); } void cmNinjaNormalTargetGenerator::WriteNvidiaDeviceLinkStatement( const std::string& config, const std::string& fileConfig, const std::string& outputDir, const std::string& output) { cmGeneratorTarget* genTarget = this->GetGeneratorTarget(); cmGlobalNinjaGenerator* globalGen = this->GetGlobalGenerator(); std::string targetOutputImplib = this->ConvertToNinjaPath( genTarget->GetFullPath(config, cmStateEnums::ImportLibraryArtifact)); if (config != fileConfig) { std::string targetOutputFileConfigDir = cmStrCat(this->GetLocalGenerator()->GetTargetDirectory(genTarget), globalGen->ConfigDirectory(fileConfig), "/"); targetOutputFileConfigDir = globalGen->ExpandCFGIntDir(outputDir, fileConfig); if (outputDir == targetOutputFileConfigDir) { return; } if (!genTarget->GetFullName(config, cmStateEnums::ImportLibraryArtifact) .empty() && !genTarget ->GetFullName(fileConfig, cmStateEnums::ImportLibraryArtifact) .empty() && targetOutputImplib == this->ConvertToNinjaPath(genTarget->GetFullPath( fileConfig, cmStateEnums::ImportLibraryArtifact))) { return; } } // Compute the comment. cmNinjaBuild build(this->LanguageLinkerDeviceRule(config)); build.Comment = cmStrCat("Link the ", this->GetVisibleTypeName(), ' ', output); cmNinjaVars& vars = build.Variables; // Compute outputs. build.Outputs.push_back(output); // Compute specific libraries to link with. build.ExplicitDeps = this->GetObjects(config); build.ImplicitDeps = this->ComputeLinkDeps(this->TargetLinkLanguage(config), config); std::string frameworkPath; std::string linkPath; std::string createRule = genTarget->GetCreateRuleVariable(this->TargetLinkLanguage(config), config); cmLocalNinjaGenerator& localGen = *this->GetLocalGenerator(); vars["TARGET_FILE"] = localGen.ConvertToOutputFormat(output, cmOutputConverter::SHELL); cmNinjaLinkLineDeviceComputer linkLineComputer( this->GetLocalGenerator(), this->GetLocalGenerator()->GetStateSnapshot().GetDirectory(), globalGen); linkLineComputer.SetUseNinjaMulti(globalGen->IsMultiConfig()); localGen.GetDeviceLinkFlags(linkLineComputer, config, vars["LINK_LIBRARIES"], vars["LINK_FLAGS"], frameworkPath, linkPath, genTarget); this->addPoolNinjaVariable("JOB_POOL_LINK", genTarget, vars); vars["LINK_FLAGS"] = globalGen->EncodeLiteral(vars["LINK_FLAGS"]); vars["MANIFESTS"] = this->GetManifests(config); vars["LINK_PATH"] = frameworkPath + linkPath; // Compute language specific link flags. std::string langFlags; localGen.AddLanguageFlagsForLinking(langFlags, genTarget, "CUDA", config); vars["LANGUAGE_COMPILE_FLAGS"] = langFlags; auto const tgtNames = this->TargetNames(config); if (genTarget->HasSOName(config)) { vars["SONAME_FLAG"] = this->GetMakefile()->GetSONameFlag(this->TargetLinkLanguage(config)); vars["SONAME"] = localGen.ConvertToOutputFormat(tgtNames.SharedObject, cmOutputConverter::SHELL); if (genTarget->GetType() == cmStateEnums::SHARED_LIBRARY) { std::string install_dir = this->GetGeneratorTarget()->GetInstallNameDirForBuildTree(config); if (!install_dir.empty()) { vars["INSTALLNAME_DIR"] = localGen.ConvertToOutputFormat( install_dir, cmOutputConverter::SHELL); } } } if (!tgtNames.ImportLibrary.empty()) { const std::string impLibPath = localGen.ConvertToOutputFormat( targetOutputImplib, cmOutputConverter::SHELL); vars["TARGET_IMPLIB"] = impLibPath; this->EnsureParentDirectoryExists(targetOutputImplib); } const std::string objPath = cmStrCat(this->GetGeneratorTarget()->GetSupportDirectory(), globalGen->ConfigDirectory(config)); vars["OBJECT_DIR"] = this->GetLocalGenerator()->ConvertToOutputFormat( this->ConvertToNinjaPath(objPath), cmOutputConverter::SHELL); this->EnsureDirectoryExists(objPath); this->SetMsvcTargetPdbVariable(vars, config); std::string& linkLibraries = vars["LINK_LIBRARIES"]; std::string& link_path = vars["LINK_PATH"]; if (globalGen->IsGCCOnWindows()) { // ar.exe can't handle backslashes in rsp files (implicitly used by gcc) std::replace(linkLibraries.begin(), linkLibraries.end(), '\\', '/'); std::replace(link_path.begin(), link_path.end(), '\\', '/'); } // Device linking currently doesn't support response files so // do not check if the user has explicitly forced a response file. int const commandLineLengthLimit = static_cast(cmSystemTools::CalculateCommandLineLengthLimit()) - globalGen->GetRuleCmdLength(build.Rule); build.RspFile = this->ConvertToNinjaPath( cmStrCat("CMakeFiles/", genTarget->GetName(), globalGen->IsMultiConfig() ? cmStrCat('.', config) : "", ".rsp")); // Gather order-only dependencies. this->GetLocalGenerator()->AppendTargetDepends( this->GetGeneratorTarget(), build.OrderOnlyDeps, config, config, DependOnTargetArtifact); // Write the build statement for this target. bool usedResponseFile = false; globalGen->WriteBuild(this->GetCommonFileStream(), build, commandLineLengthLimit, &usedResponseFile); this->WriteNvidiaDeviceLinkRule(usedResponseFile, config); } void cmNinjaNormalTargetGenerator::WriteLinkStatement( const std::string& config, const std::string& fileConfig, bool firstForConfig) { cmMakefile* mf = this->GetMakefile(); cmGlobalNinjaGenerator* globalGen = this->GetGlobalGenerator(); cmGeneratorTarget* gt = this->GetGeneratorTarget(); std::string targetOutput = this->ConvertToNinjaPath(gt->GetFullPath(config)); std::string targetOutputReal = this->ConvertToNinjaPath( gt->GetFullPath(config, cmStateEnums::RuntimeBinaryArtifact, /*realname=*/true)); std::string targetOutputImplib = this->ConvertToNinjaPath( gt->GetFullPath(config, cmStateEnums::ImportLibraryArtifact)); if (config != fileConfig) { if (targetOutput == this->ConvertToNinjaPath(gt->GetFullPath(fileConfig))) { return; } if (targetOutputReal == this->ConvertToNinjaPath( gt->GetFullPath(fileConfig, cmStateEnums::RuntimeBinaryArtifact, /*realname=*/true))) { return; } if (!gt->GetFullName(config, cmStateEnums::ImportLibraryArtifact) .empty() && !gt->GetFullName(fileConfig, cmStateEnums::ImportLibraryArtifact) .empty() && targetOutputImplib == this->ConvertToNinjaPath(gt->GetFullPath( fileConfig, cmStateEnums::ImportLibraryArtifact))) { return; } } auto const tgtNames = this->TargetNames(config); if (gt->IsAppBundleOnApple()) { // Create the app bundle std::string outpath = gt->GetDirectory(config); this->OSXBundleGenerator->CreateAppBundle(tgtNames.Output, outpath, config); // Calculate the output path targetOutput = cmStrCat(outpath, '/', tgtNames.Output); targetOutput = this->ConvertToNinjaPath(targetOutput); targetOutputReal = cmStrCat(outpath, '/', tgtNames.Real); targetOutputReal = this->ConvertToNinjaPath(targetOutputReal); } else if (gt->IsFrameworkOnApple()) { // Create the library framework. cmOSXBundleGenerator::SkipParts bundleSkipParts; if (globalGen->GetName() == "Ninja Multi-Config") { const auto postFix = this->GeneratorTarget->GetFilePostfix(config); // Skip creating Info.plist when there are multiple configurations, and // the current configuration has a postfix. The non-postfix configuration // Info.plist can be used by all the other configurations. if (!postFix.empty()) { bundleSkipParts.infoPlist = true; } } this->OSXBundleGenerator->CreateFramework( tgtNames.Output, gt->GetDirectory(config), config, bundleSkipParts); } else if (gt->IsCFBundleOnApple()) { // Create the core foundation bundle. this->OSXBundleGenerator->CreateCFBundle(tgtNames.Output, gt->GetDirectory(config), config); } // Write comments. cmGlobalNinjaGenerator::WriteDivider(this->GetImplFileStream(fileConfig)); const cmStateEnums::TargetType targetType = gt->GetType(); this->GetImplFileStream(fileConfig) << "# Link build statements for " << cmState::GetTargetTypeName(targetType) << " target " << this->GetTargetName() << "\n\n"; cmNinjaBuild linkBuild(this->LanguageLinkerRule(config)); cmNinjaVars& vars = linkBuild.Variables; // Compute the comment. linkBuild.Comment = cmStrCat("Link the ", this->GetVisibleTypeName(), ' ', targetOutputReal); // Compute outputs. linkBuild.Outputs.push_back(targetOutputReal); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back(targetOutputReal); } if (this->TargetLinkLanguage(config) == "Swift") { vars["SWIFT_LIBRARY_NAME"] = [this, config]() -> std::string { cmGeneratorTarget::Names targetNames = this->GetGeneratorTarget()->GetLibraryNames(config); return targetNames.Base; }(); vars["SWIFT_MODULE_NAME"] = [gt]() -> std::string { if (cmValue name = gt->GetProperty("Swift_MODULE_NAME")) { return *name; } return gt->GetName(); }(); vars["SWIFT_MODULE"] = [this](const std::string& module) -> std::string { std::string directory = this->GetLocalGenerator()->GetCurrentBinaryDirectory(); if (cmValue prop = this->GetGeneratorTarget()->GetProperty( "Swift_MODULE_DIRECTORY")) { directory = *prop; } std::string name = module + ".swiftmodule"; if (cmValue prop = this->GetGeneratorTarget()->GetProperty("Swift_MODULE")) { name = *prop; } return this->GetLocalGenerator()->ConvertToOutputFormat( this->ConvertToNinjaPath(directory + "/" + name), cmOutputConverter::SHELL); }(vars["SWIFT_MODULE_NAME"]); const std::string map = cmStrCat(gt->GetSupportDirectory(), '/', config, '/', "output-file-map.json"); vars["SWIFT_OUTPUT_FILE_MAP"] = this->GetLocalGenerator()->ConvertToOutputFormat( this->ConvertToNinjaPath(map), cmOutputConverter::SHELL); vars["SWIFT_SOURCES"] = [this, config]() -> std::string { std::vector sources; std::stringstream oss; this->GetGeneratorTarget()->GetObjectSources(sources, config); cmLocalGenerator const* LocalGen = this->GetLocalGenerator(); for (const auto& source : sources) { oss << " " << LocalGen->ConvertToOutputFormat( this->GetCompiledSourceNinjaPath(source), cmOutputConverter::SHELL); } return oss.str(); }(); // Since we do not perform object builds, compute the // defines/flags/includes here so that they can be passed along // appropriately. vars["DEFINES"] = this->GetDefines("Swift", config); vars["FLAGS"] = this->GetFlags("Swift", config); vars["INCLUDES"] = this->GetIncludes("Swift", config); } // Compute specific libraries to link with. if (this->TargetLinkLanguage(config) == "Swift") { std::vector sources; gt->GetObjectSources(sources, config); for (const auto& source : sources) { linkBuild.Outputs.push_back( this->ConvertToNinjaPath(this->GetObjectFilePath(source, config))); linkBuild.ExplicitDeps.emplace_back( this->GetCompiledSourceNinjaPath(source)); } linkBuild.Outputs.push_back(vars["SWIFT_MODULE"]); } else { linkBuild.ExplicitDeps = this->GetObjects(config); } std::vector extraISPCObjects = this->GetGeneratorTarget()->GetGeneratedISPCObjects(config); std::transform(extraISPCObjects.begin(), extraISPCObjects.end(), std::back_inserter(linkBuild.ExplicitDeps), this->MapToNinjaPath()); linkBuild.ImplicitDeps = this->ComputeLinkDeps(this->TargetLinkLanguage(config), config); if (!this->DeviceLinkObject.empty()) { linkBuild.ExplicitDeps.push_back(this->DeviceLinkObject); } std::string frameworkPath; std::string linkPath; std::string createRule = gt->GetCreateRuleVariable(this->TargetLinkLanguage(config), config); bool useWatcomQuote = mf->IsOn(createRule + "_USE_WATCOM_QUOTE"); cmLocalNinjaGenerator& localGen = *this->GetLocalGenerator(); vars["TARGET_FILE"] = localGen.ConvertToOutputFormat(targetOutputReal, cmOutputConverter::SHELL); std::unique_ptr linkLineComputer = globalGen->CreateLinkLineComputer( this->GetLocalGenerator(), this->GetLocalGenerator()->GetStateSnapshot().GetDirectory()); linkLineComputer->SetUseWatcomQuote(useWatcomQuote); linkLineComputer->SetUseNinjaMulti(globalGen->IsMultiConfig()); localGen.GetTargetFlags(linkLineComputer.get(), config, vars["LINK_LIBRARIES"], vars["FLAGS"], vars["LINK_FLAGS"], frameworkPath, linkPath, gt); // Add OS X version flags, if any. if (this->GeneratorTarget->GetType() == cmStateEnums::SHARED_LIBRARY || this->GeneratorTarget->GetType() == cmStateEnums::MODULE_LIBRARY) { this->AppendOSXVerFlag(vars["LINK_FLAGS"], this->TargetLinkLanguage(config), "COMPATIBILITY", true); this->AppendOSXVerFlag(vars["LINK_FLAGS"], this->TargetLinkLanguage(config), "CURRENT", false); } this->addPoolNinjaVariable("JOB_POOL_LINK", gt, vars); this->AddModuleDefinitionFlag(linkLineComputer.get(), vars["LINK_FLAGS"], config); this->UseLWYU = this->GetLocalGenerator()->AppendLWYUFlags( vars["LINK_FLAGS"], this->GetGeneratorTarget(), this->TargetLinkLanguage(config)); vars["LINK_FLAGS"] = globalGen->EncodeLiteral(vars["LINK_FLAGS"]); vars["MANIFESTS"] = this->GetManifests(config); vars["AIX_EXPORTS"] = this->GetAIXExports(config); vars["LINK_PATH"] = frameworkPath + linkPath; // Compute architecture specific link flags. Yes, these go into a different // variable for executables, probably due to a mistake made when duplicating // code between the Makefile executable and library generators. if (targetType == cmStateEnums::EXECUTABLE) { std::string t = vars["FLAGS"]; localGen.AddArchitectureFlags(t, gt, this->TargetLinkLanguage(config), config); vars["FLAGS"] = t; } else { std::string t = vars["ARCH_FLAGS"]; localGen.AddArchitectureFlags(t, gt, this->TargetLinkLanguage(config), config); vars["ARCH_FLAGS"] = t; t.clear(); localGen.AddLanguageFlagsForLinking( t, gt, this->TargetLinkLanguage(config), config); vars["LANGUAGE_COMPILE_FLAGS"] = t; } if (gt->HasSOName(config)) { vars["SONAME_FLAG"] = mf->GetSONameFlag(this->TargetLinkLanguage(config)); vars["SONAME"] = localGen.ConvertToOutputFormat(tgtNames.SharedObject, cmOutputConverter::SHELL); if (targetType == cmStateEnums::SHARED_LIBRARY) { std::string install_dir = gt->GetInstallNameDirForBuildTree(config); if (!install_dir.empty()) { vars["INSTALLNAME_DIR"] = localGen.ConvertToOutputFormat( install_dir, cmOutputConverter::SHELL); } } } cmGlobalNinjaGenerator::CCOutputs byproducts(this->GetGlobalGenerator()); if (!tgtNames.ImportLibrary.empty()) { const std::string impLibPath = localGen.ConvertToOutputFormat( targetOutputImplib, cmOutputConverter::SHELL); vars["TARGET_IMPLIB"] = impLibPath; this->EnsureParentDirectoryExists(targetOutputImplib); if (gt->HasImportLibrary(config)) { // Some linkers may update a binary without touching its import lib. byproducts.ExplicitOuts.emplace_back(targetOutputImplib); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back( targetOutputImplib); } } } if (!this->SetMsvcTargetPdbVariable(vars, config)) { // It is common to place debug symbols at a specific place, // so we need a plain target name in the rule available. std::string prefix; std::string base; std::string suffix; gt->GetFullNameComponents(prefix, base, suffix, config); std::string dbg_suffix = ".dbg"; // TODO: Where to document? if (cmValue d = mf->GetDefinition("CMAKE_DEBUG_SYMBOL_SUFFIX")) { dbg_suffix = *d; } vars["TARGET_PDB"] = base + suffix + dbg_suffix; } const std::string objPath = cmStrCat(gt->GetSupportDirectory(), globalGen->ConfigDirectory(config)); vars["OBJECT_DIR"] = this->GetLocalGenerator()->ConvertToOutputFormat( this->ConvertToNinjaPath(objPath), cmOutputConverter::SHELL); this->EnsureDirectoryExists(objPath); std::string& linkLibraries = vars["LINK_LIBRARIES"]; std::string& link_path = vars["LINK_PATH"]; if (globalGen->IsGCCOnWindows()) { // ar.exe can't handle backslashes in rsp files (implicitly used by gcc) std::replace(linkLibraries.begin(), linkLibraries.end(), '\\', '/'); std::replace(link_path.begin(), link_path.end(), '\\', '/'); } const std::vector* cmdLists[3] = { >->GetPreBuildCommands(), >->GetPreLinkCommands(), >->GetPostBuildCommands() }; std::vector preLinkCmdLines; std::vector postBuildCmdLines; std::vector* cmdLineLists[3] = { &preLinkCmdLines, &preLinkCmdLines, &postBuildCmdLines }; for (unsigned i = 0; i != 3; ++i) { for (cmCustomCommand const& cc : *cmdLists[i]) { if (config == fileConfig || this->GetLocalGenerator()->HasUniqueByproducts(cc.GetByproducts(), cc.GetBacktrace())) { cmCustomCommandGenerator ccg(cc, fileConfig, this->GetLocalGenerator(), true, config); localGen.AppendCustomCommandLines(ccg, *cmdLineLists[i]); std::vector const& ccByproducts = ccg.GetByproducts(); byproducts.Add(ccByproducts); std::transform( ccByproducts.begin(), ccByproducts.end(), std::back_inserter(globalGen->GetByproductsForCleanTarget()), this->MapToNinjaPath()); } } } // maybe create .def file from list of objects cmGeneratorTarget::ModuleDefinitionInfo const* mdi = gt->GetModuleDefinitionInfo(config); if (mdi && mdi->DefFileGenerated) { std::string cmakeCommand = this->GetLocalGenerator()->ConvertToOutputFormat( cmSystemTools::GetCMakeCommand(), cmOutputConverter::SHELL); std::string cmd = cmStrCat(cmakeCommand, " -E __create_def ", this->GetLocalGenerator()->ConvertToOutputFormat( mdi->DefFile, cmOutputConverter::SHELL), ' '); std::string obj_list_file = mdi->DefFile + ".objs"; cmd += this->GetLocalGenerator()->ConvertToOutputFormat( obj_list_file, cmOutputConverter::SHELL); cmValue nm_executable = this->GetMakefile()->GetDefinition("CMAKE_NM"); if (cmNonempty(nm_executable)) { cmd += " --nm="; cmd += this->LocalCommonGenerator->ConvertToOutputFormat( *nm_executable, cmOutputConverter::SHELL); } preLinkCmdLines.push_back(std::move(cmd)); // create a list of obj files for the -E __create_def to read cmGeneratedFileStream fout(obj_list_file); if (mdi->WindowsExportAllSymbols) { cmNinjaDeps objs = this->GetObjects(config); for (std::string const& obj : objs) { if (cmHasLiteralSuffix(obj, ".obj")) { fout << obj << "\n"; } } } for (cmSourceFile const* src : mdi->Sources) { fout << src->GetFullPath() << "\n"; } } // If we have any PRE_LINK commands, we need to go back to CMAKE_BINARY_DIR // for the link commands. if (!preLinkCmdLines.empty()) { const std::string homeOutDir = localGen.ConvertToOutputFormat( localGen.GetBinaryDirectory(), cmOutputConverter::SHELL); preLinkCmdLines.push_back("cd " + homeOutDir); } vars["PRE_LINK"] = localGen.BuildCommandLine( preLinkCmdLines, config, fileConfig, "pre-link", this->GeneratorTarget); std::string postBuildCmdLine = localGen.BuildCommandLine(postBuildCmdLines, config, fileConfig, "post-build", this->GeneratorTarget); cmNinjaVars symlinkVars; bool const symlinkNeeded = (targetOutput != targetOutputReal && !gt->IsFrameworkOnApple()); if (!symlinkNeeded) { vars["POST_BUILD"] = postBuildCmdLine; } else { vars["POST_BUILD"] = cmGlobalNinjaGenerator::SHELL_NOOP; symlinkVars["POST_BUILD"] = postBuildCmdLine; } std::string cmakeVarLang = cmStrCat("CMAKE_", this->TargetLinkLanguage(config)); // build response file name std::string cmakeLinkVar = cmakeVarLang + "_RESPONSE_FILE_LINK_FLAG"; cmValue flag = this->GetMakefile()->GetDefinition(cmakeLinkVar); bool const lang_supports_response = !(this->TargetLinkLanguage(config) == "RC" || (this->TargetLinkLanguage(config) == "CUDA" && !flag)); int commandLineLengthLimit = -1; if (!lang_supports_response || !this->ForceResponseFile()) { commandLineLengthLimit = static_cast(cmSystemTools::CalculateCommandLineLengthLimit()) - globalGen->GetRuleCmdLength(linkBuild.Rule); } linkBuild.RspFile = this->ConvertToNinjaPath( cmStrCat("CMakeFiles/", gt->GetName(), globalGen->IsMultiConfig() ? cmStrCat('.', config) : "", ".rsp")); // Gather order-only dependencies. this->GetLocalGenerator()->AppendTargetDepends( gt, linkBuild.OrderOnlyDeps, config, fileConfig, DependOnTargetArtifact); // Add order-only dependencies on versioning symlinks of shared libs we link. if (!this->GeneratorTarget->IsDLLPlatform()) { if (cmComputeLinkInformation* cli = this->GeneratorTarget->GetLinkInformation(config)) { for (auto const& item : cli->GetItems()) { if (item.Target && item.Target->GetType() == cmStateEnums::SHARED_LIBRARY && !item.Target->IsFrameworkOnApple()) { std::string const& lib = this->ConvertToNinjaPath(item.Target->GetFullPath(config)); if (std::find(linkBuild.ImplicitDeps.begin(), linkBuild.ImplicitDeps.end(), lib) == linkBuild.ImplicitDeps.end()) { linkBuild.OrderOnlyDeps.emplace_back(lib); } } } } } // Ninja should restat after linking if and only if there are byproducts. vars["RESTAT"] = byproducts.ExplicitOuts.empty() ? "" : "1"; linkBuild.Outputs.reserve(linkBuild.Outputs.size() + byproducts.ExplicitOuts.size()); std::move(byproducts.ExplicitOuts.begin(), byproducts.ExplicitOuts.end(), std::back_inserter(linkBuild.Outputs)); linkBuild.WorkDirOuts = std::move(byproducts.WorkDirOuts); // Write the build statement for this target. bool usedResponseFile = false; globalGen->WriteBuild(this->GetImplFileStream(fileConfig), linkBuild, commandLineLengthLimit, &usedResponseFile); this->WriteLinkRule(usedResponseFile, config); if (symlinkNeeded) { if (targetType == cmStateEnums::EXECUTABLE) { cmNinjaBuild build("CMAKE_SYMLINK_EXECUTABLE"); build.Comment = "Create executable symlink " + targetOutput; build.Outputs.push_back(targetOutput); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back(targetOutput); } build.ExplicitDeps.push_back(targetOutputReal); build.Variables = std::move(symlinkVars); globalGen->WriteBuild(this->GetImplFileStream(fileConfig), build); } else { cmNinjaBuild build("CMAKE_SYMLINK_LIBRARY"); build.Comment = "Create library symlink " + targetOutput; std::string const soName = this->ConvertToNinjaPath( this->GetTargetFilePath(tgtNames.SharedObject, config)); // If one link has to be created. if (targetOutputReal == soName || targetOutput == soName) { symlinkVars["SONAME"] = this->GetLocalGenerator()->ConvertToOutputFormat( soName, cmOutputConverter::SHELL); } else { symlinkVars["SONAME"].clear(); build.Outputs.push_back(soName); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back(soName); } } build.Outputs.push_back(targetOutput); if (firstForConfig) { globalGen->GetByproductsForCleanTarget(config).push_back(targetOutput); } build.ExplicitDeps.push_back(targetOutputReal); build.Variables = std::move(symlinkVars); globalGen->WriteBuild(this->GetImplFileStream(fileConfig), build); } } // Add aliases for the file name and the target name. globalGen->AddTargetAlias(tgtNames.Output, gt, config); globalGen->AddTargetAlias(this->GetTargetName(), gt, config); } void cmNinjaNormalTargetGenerator::WriteObjectLibStatement( const std::string& config) { // Write a phony output that depends on all object files. { cmNinjaBuild build("phony"); build.Comment = "Object library " + this->GetTargetName(); this->GetLocalGenerator()->AppendTargetOutputs(this->GetGeneratorTarget(), build.Outputs, config); this->GetLocalGenerator()->AppendTargetOutputs( this->GetGeneratorTarget(), this->GetGlobalGenerator()->GetByproductsForCleanTarget(config), config); build.ExplicitDeps = this->GetObjects(config); this->GetGlobalGenerator()->WriteBuild(this->GetCommonFileStream(), build); } // Add aliases for the target name. this->GetGlobalGenerator()->AddTargetAlias( this->GetTargetName(), this->GetGeneratorTarget(), config); } cmGeneratorTarget::Names cmNinjaNormalTargetGenerator::TargetNames( const std::string& config) const { if (this->GeneratorTarget->GetType() == cmStateEnums::EXECUTABLE) { return this->GeneratorTarget->GetExecutableNames(config); } return this->GeneratorTarget->GetLibraryNames(config); } std::string cmNinjaNormalTargetGenerator::TargetLinkLanguage( const std::string& config) const { return this->GeneratorTarget->GetLinkerLanguage(config); }