//===--- ToolChains.cpp - ToolChain Implementations -----------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "ToolChains.h" #include "Tools.h" #include "clang/Basic/CharInfo.h" #include "clang/Basic/Version.h" #include "clang/Driver/Compilation.h" #include "clang/Driver/Driver.h" #include "clang/Driver/DriverDiagnostic.h" #include "clang/Driver/Options.h" #include "llvm/ADT/StringExtras.h" #include "llvm/Config/llvm-config.h" #include "llvm/Option/Arg.h" #include "llvm/Option/ArgList.h" #include "llvm/Support/ConvertUTF.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Process.h" #include // Include the necessary headers to interface with the Windows registry and // environment. #if defined(LLVM_ON_WIN32) #define USE_WIN32 #endif #ifdef USE_WIN32 #define WIN32_LEAN_AND_MEAN #define NOGDI #ifndef NOMINMAX #define NOMINMAX #endif #include #endif using namespace clang::driver; using namespace clang::driver::toolchains; using namespace clang; using namespace llvm::opt; MSVCToolChain::MSVCToolChain(const Driver &D, const llvm::Triple& Triple, const ArgList &Args) : ToolChain(D, Triple, Args) { getProgramPaths().push_back(getDriver().getInstalledDir()); if (getDriver().getInstalledDir() != getDriver().Dir) getProgramPaths().push_back(getDriver().Dir); } Tool *MSVCToolChain::buildLinker() const { return new tools::visualstudio::Linker(*this); } Tool *MSVCToolChain::buildAssembler() const { if (getTriple().isOSBinFormatMachO()) return new tools::darwin::Assembler(*this); getDriver().Diag(clang::diag::err_no_external_assembler); return nullptr; } bool MSVCToolChain::IsIntegratedAssemblerDefault() const { return true; } bool MSVCToolChain::IsUnwindTablesDefault() const { // Emit unwind tables by default on Win64. All non-x86_32 Windows platforms // such as ARM and PPC actually require unwind tables, but LLVM doesn't know // how to generate them yet. // Don't emit unwind tables by default for MachO targets. if (getTriple().isOSBinFormatMachO()) return false; return getArch() == llvm::Triple::x86_64; } bool MSVCToolChain::isPICDefault() const { return getArch() == llvm::Triple::x86_64; } bool MSVCToolChain::isPIEDefault() const { return false; } bool MSVCToolChain::isPICDefaultForced() const { return getArch() == llvm::Triple::x86_64; } #ifdef USE_WIN32 static bool readFullStringValue(HKEY hkey, const char *valueName, std::string &value) { std::wstring WideValueName; if (!llvm::ConvertUTF8toWide(valueName, WideValueName)) return false; DWORD result = 0; DWORD valueSize = 0; DWORD type = 0; // First just query for the required size. result = RegQueryValueExW(hkey, WideValueName.c_str(), NULL, &type, NULL, &valueSize); if (result != ERROR_SUCCESS || type != REG_SZ || !valueSize) return false; std::vector buffer(valueSize); result = RegQueryValueExW(hkey, WideValueName.c_str(), NULL, NULL, &buffer[0], &valueSize); if (result == ERROR_SUCCESS) { std::wstring WideValue(reinterpret_cast(buffer.data()), valueSize / sizeof(wchar_t)); // The destination buffer must be empty as an invariant of the conversion // function; but this function is sometimes called in a loop that passes in // the same buffer, however. Simply clear it out so we can overwrite it. value.clear(); return llvm::convertWideToUTF8(WideValue, value); } return false; } #endif /// \brief Read registry string. /// This also supports a means to look for high-versioned keys by use /// of a $VERSION placeholder in the key path. /// $VERSION in the key path is a placeholder for the version number, /// causing the highest value path to be searched for and used. /// I.e. "SOFTWARE\\Microsoft\\VisualStudio\\$VERSION". /// There can be additional characters in the component. Only the numeric /// characters are compared. This function only searches HKLM. static bool getSystemRegistryString(const char *keyPath, const char *valueName, std::string &value, std::string *phValue) { #ifndef USE_WIN32 return false; #else HKEY hRootKey = HKEY_LOCAL_MACHINE; HKEY hKey = NULL; long lResult; bool returnValue = false; const char *placeHolder = strstr(keyPath, "$VERSION"); std::string bestName; // If we have a $VERSION placeholder, do the highest-version search. if (placeHolder) { const char *keyEnd = placeHolder - 1; const char *nextKey = placeHolder; // Find end of previous key. while ((keyEnd > keyPath) && (*keyEnd != '\\')) keyEnd--; // Find end of key containing $VERSION. while (*nextKey && (*nextKey != '\\')) nextKey++; size_t partialKeyLength = keyEnd - keyPath; char partialKey[256]; if (partialKeyLength >= sizeof(partialKey)) partialKeyLength = sizeof(partialKey) - 1; strncpy(partialKey, keyPath, partialKeyLength); partialKey[partialKeyLength] = '\0'; HKEY hTopKey = NULL; lResult = RegOpenKeyExA(hRootKey, partialKey, 0, KEY_READ | KEY_WOW64_32KEY, &hTopKey); if (lResult == ERROR_SUCCESS) { char keyName[256]; double bestValue = 0.0; DWORD index, size = sizeof(keyName) - 1; for (index = 0; RegEnumKeyExA(hTopKey, index, keyName, &size, NULL, NULL, NULL, NULL) == ERROR_SUCCESS; index++) { const char *sp = keyName; while (*sp && !isDigit(*sp)) sp++; if (!*sp) continue; const char *ep = sp + 1; while (*ep && (isDigit(*ep) || (*ep == '.'))) ep++; char numBuf[32]; strncpy(numBuf, sp, sizeof(numBuf) - 1); numBuf[sizeof(numBuf) - 1] = '\0'; double dvalue = strtod(numBuf, NULL); if (dvalue > bestValue) { // Test that InstallDir is indeed there before keeping this index. // Open the chosen key path remainder. bestName = keyName; // Append rest of key. bestName.append(nextKey); lResult = RegOpenKeyExA(hTopKey, bestName.c_str(), 0, KEY_READ | KEY_WOW64_32KEY, &hKey); if (lResult == ERROR_SUCCESS) { lResult = readFullStringValue(hKey, valueName, value); if (lResult == ERROR_SUCCESS) { bestValue = dvalue; if (phValue) *phValue = bestName; returnValue = true; } RegCloseKey(hKey); } } size = sizeof(keyName) - 1; } RegCloseKey(hTopKey); } } else { lResult = RegOpenKeyExA(hRootKey, keyPath, 0, KEY_READ | KEY_WOW64_32KEY, &hKey); if (lResult == ERROR_SUCCESS) { lResult = readFullStringValue(hKey, valueName, value); if (lResult == ERROR_SUCCESS) returnValue = true; if (phValue) phValue->clear(); RegCloseKey(hKey); } } return returnValue; #endif // USE_WIN32 } // Convert LLVM's ArchType // to the corresponding name of Windows SDK libraries subfolder static StringRef getWindowsSDKArch(llvm::Triple::ArchType Arch) { switch (Arch) { case llvm::Triple::x86: return "x86"; case llvm::Triple::x86_64: return "x64"; case llvm::Triple::arm: return "arm"; default: return ""; } } // Find the most recent version of Universal CRT or Windows 10 SDK. // vcvarsqueryregistry.bat from Visual Studio 2015 sorts entries in the include // directory by name and uses the last one of the list. // So we compare entry names lexicographically to find the greatest one. static bool getWindows10SDKVersion(const std::string &SDKPath, std::string &SDKVersion) { SDKVersion.clear(); std::error_code EC; llvm::SmallString<128> IncludePath(SDKPath); llvm::sys::path::append(IncludePath, "Include"); for (llvm::sys::fs::directory_iterator DirIt(IncludePath, EC), DirEnd; DirIt != DirEnd && !EC; DirIt.increment(EC)) { if (!llvm::sys::fs::is_directory(DirIt->path())) continue; StringRef CandidateName = llvm::sys::path::filename(DirIt->path()); // If WDK is installed, there could be subfolders like "wdf" in the // "Include" directory. // Allow only directories which names start with "10.". if (!CandidateName.startswith("10.")) continue; if (CandidateName > SDKVersion) SDKVersion = CandidateName; } return !SDKVersion.empty(); } /// \brief Get Windows SDK installation directory. bool MSVCToolChain::getWindowsSDKDir(std::string &Path, int &Major, std::string &WindowsSDKIncludeVersion, std::string &WindowsSDKLibVersion) const { std::string RegistrySDKVersion; // Try the Windows registry. if (!getSystemRegistryString( "SOFTWARE\\Microsoft\\Microsoft SDKs\\Windows\\$VERSION", "InstallationFolder", Path, &RegistrySDKVersion)) return false; if (Path.empty() || RegistrySDKVersion.empty()) return false; WindowsSDKIncludeVersion.clear(); WindowsSDKLibVersion.clear(); Major = 0; std::sscanf(RegistrySDKVersion.c_str(), "v%d.", &Major); if (Major <= 7) return true; if (Major == 8) { // Windows SDK 8.x installs libraries in a folder whose names depend on the // version of the OS you're targeting. By default choose the newest, which // usually corresponds to the version of the OS you've installed the SDK on. const char *Tests[] = {"winv6.3", "win8", "win7"}; for (const char *Test : Tests) { llvm::SmallString<128> TestPath(Path); llvm::sys::path::append(TestPath, "Lib", Test); if (llvm::sys::fs::exists(TestPath.c_str())) { WindowsSDKLibVersion = Test; break; } } return !WindowsSDKLibVersion.empty(); } if (Major == 10) { if (!getWindows10SDKVersion(Path, WindowsSDKIncludeVersion)) return false; WindowsSDKLibVersion = WindowsSDKIncludeVersion; return true; } // Unsupported SDK version return false; } // Gets the library path required to link against the Windows SDK. bool MSVCToolChain::getWindowsSDKLibraryPath(std::string &path) const { std::string sdkPath; int sdkMajor = 0; std::string windowsSDKIncludeVersion; std::string windowsSDKLibVersion; path.clear(); if (!getWindowsSDKDir(sdkPath, sdkMajor, windowsSDKIncludeVersion, windowsSDKLibVersion)) return false; llvm::SmallString<128> libPath(sdkPath); llvm::sys::path::append(libPath, "Lib"); if (sdkMajor <= 7) { switch (getArch()) { // In Windows SDK 7.x, x86 libraries are directly in the Lib folder. case llvm::Triple::x86: break; case llvm::Triple::x86_64: llvm::sys::path::append(libPath, "x64"); break; case llvm::Triple::arm: // It is not necessary to link against Windows SDK 7.x when targeting ARM. return false; default: return false; } } else { const StringRef archName = getWindowsSDKArch(getArch()); if (archName.empty()) return false; llvm::sys::path::append(libPath, windowsSDKLibVersion, "um", archName); } path = libPath.str(); return true; } // Check if the Include path of a specified version of Visual Studio contains // specific header files. If not, they are probably shipped with Universal CRT. bool clang::driver::toolchains::MSVCToolChain::useUniversalCRT( std::string &VisualStudioDir) const { llvm::SmallString<128> TestPath(VisualStudioDir); llvm::sys::path::append(TestPath, "VC\\include\\stdlib.h"); return !llvm::sys::fs::exists(TestPath); } bool MSVCToolChain::getUniversalCRTSdkDir(std::string &Path, std::string &UCRTVersion) const { // vcvarsqueryregistry.bat for Visual Studio 2015 queries the registry // for the specific key "KitsRoot10". So do we. if (!getSystemRegistryString( "SOFTWARE\\Microsoft\\Windows Kits\\Installed Roots", "KitsRoot10", Path, nullptr)) return false; return getWindows10SDKVersion(Path, UCRTVersion); } bool MSVCToolChain::getUniversalCRTLibraryPath(std::string &Path) const { std::string UniversalCRTSdkPath; std::string UCRTVersion; Path.clear(); if (!getUniversalCRTSdkDir(UniversalCRTSdkPath, UCRTVersion)) return false; StringRef ArchName = getWindowsSDKArch(getArch()); if (ArchName.empty()) return false; llvm::SmallString<128> LibPath(UniversalCRTSdkPath); llvm::sys::path::append(LibPath, "Lib", UCRTVersion, "ucrt", ArchName); Path = LibPath.str(); return true; } // Get the location to use for Visual Studio binaries. The location priority // is: %VCINSTALLDIR% > %PATH% > newest copy of Visual Studio installed on // system (as reported by the registry). bool MSVCToolChain::getVisualStudioBinariesFolder(const char *clangProgramPath, std::string &path) const { path.clear(); SmallString<128> BinDir; // First check the environment variables that vsvars32.bat sets. llvm::Optional VcInstallDir = llvm::sys::Process::GetEnv("VCINSTALLDIR"); if (VcInstallDir.hasValue()) { BinDir = VcInstallDir.getValue(); llvm::sys::path::append(BinDir, "bin"); } else { // Next walk the PATH, trying to find a cl.exe in the path. If we find one, // use that. However, make sure it's not clang's cl.exe. llvm::Optional OptPath = llvm::sys::Process::GetEnv("PATH"); if (OptPath.hasValue()) { const char EnvPathSeparatorStr[] = {llvm::sys::EnvPathSeparator, '\0'}; SmallVector PathSegments; llvm::SplitString(OptPath.getValue(), PathSegments, EnvPathSeparatorStr); for (StringRef PathSegment : PathSegments) { if (PathSegment.empty()) continue; SmallString<128> FilePath(PathSegment); llvm::sys::path::append(FilePath, "cl.exe"); // Checking if cl.exe exists is a small optimization over calling // can_execute, which really only checks for existence but will also do // extra checks for cl.exe.exe. These add up when walking a long path. if (llvm::sys::fs::exists(FilePath.c_str()) && !llvm::sys::fs::equivalent(FilePath.c_str(), clangProgramPath)) { // If we found it on the PATH, use it exactly as is with no // modifications. path = PathSegment; return true; } } } std::string installDir; // With no VCINSTALLDIR and nothing on the PATH, if we can't find it in the // registry then we have no choice but to fail. if (!getVisualStudioInstallDir(installDir)) return false; // Regardless of what binary we're ultimately trying to find, we make sure // that this is a Visual Studio directory by checking for cl.exe. We use // cl.exe instead of other binaries like link.exe because programs such as // GnuWin32 also have a utility called link.exe, so cl.exe is the least // ambiguous. BinDir = installDir; llvm::sys::path::append(BinDir, "VC", "bin"); SmallString<128> ClPath(BinDir); llvm::sys::path::append(ClPath, "cl.exe"); if (!llvm::sys::fs::can_execute(ClPath.c_str())) return false; } if (BinDir.empty()) return false; switch (getArch()) { case llvm::Triple::x86: break; case llvm::Triple::x86_64: llvm::sys::path::append(BinDir, "amd64"); break; case llvm::Triple::arm: llvm::sys::path::append(BinDir, "arm"); break; default: // Whatever this is, Visual Studio doesn't have a toolchain for it. return false; } path = BinDir.str(); return true; } VersionTuple MSVCToolChain::getMSVCVersionFromExe() const { VersionTuple Version; #ifdef USE_WIN32 std::string BinPath; if (!getVisualStudioBinariesFolder("", BinPath)) return Version; SmallString<128> ClExe(BinPath); llvm::sys::path::append(ClExe, "cl.exe"); std::wstring ClExeWide; if (!llvm::ConvertUTF8toWide(ClExe.c_str(), ClExeWide)) return Version; const DWORD VersionSize = ::GetFileVersionInfoSizeW(ClExeWide.c_str(), nullptr); if (VersionSize == 0) return Version; SmallVector VersionBlock(VersionSize); if (!::GetFileVersionInfoW(ClExeWide.c_str(), 0, VersionSize, VersionBlock.data())) return Version; VS_FIXEDFILEINFO *FileInfo = nullptr; UINT FileInfoSize = 0; if (!::VerQueryValueW(VersionBlock.data(), L"\\", reinterpret_cast(&FileInfo), &FileInfoSize) || FileInfoSize < sizeof(*FileInfo)) return Version; const unsigned Major = (FileInfo->dwFileVersionMS >> 16) & 0xFFFF; const unsigned Minor = (FileInfo->dwFileVersionMS ) & 0xFFFF; const unsigned Micro = (FileInfo->dwFileVersionLS >> 16) & 0xFFFF; Version = VersionTuple(Major, Minor, Micro); #endif return Version; } // Get Visual Studio installation directory. bool MSVCToolChain::getVisualStudioInstallDir(std::string &path) const { // First check the environment variables that vsvars32.bat sets. const char *vcinstalldir = getenv("VCINSTALLDIR"); if (vcinstalldir) { path = vcinstalldir; path = path.substr(0, path.find("\\VC")); return true; } std::string vsIDEInstallDir; std::string vsExpressIDEInstallDir; // Then try the windows registry. bool hasVCDir = getSystemRegistryString("SOFTWARE\\Microsoft\\VisualStudio\\$VERSION", "InstallDir", vsIDEInstallDir, nullptr); if (hasVCDir && !vsIDEInstallDir.empty()) { path = vsIDEInstallDir.substr(0, vsIDEInstallDir.find("\\Common7\\IDE")); return true; } bool hasVCExpressDir = getSystemRegistryString("SOFTWARE\\Microsoft\\VCExpress\\$VERSION", "InstallDir", vsExpressIDEInstallDir, nullptr); if (hasVCExpressDir && !vsExpressIDEInstallDir.empty()) { path = vsExpressIDEInstallDir.substr( 0, vsIDEInstallDir.find("\\Common7\\IDE")); return true; } // Try the environment. const char *vs120comntools = getenv("VS120COMNTOOLS"); const char *vs100comntools = getenv("VS100COMNTOOLS"); const char *vs90comntools = getenv("VS90COMNTOOLS"); const char *vs80comntools = getenv("VS80COMNTOOLS"); const char *vscomntools = nullptr; // Find any version we can if (vs120comntools) vscomntools = vs120comntools; else if (vs100comntools) vscomntools = vs100comntools; else if (vs90comntools) vscomntools = vs90comntools; else if (vs80comntools) vscomntools = vs80comntools; if (vscomntools && *vscomntools) { const char *p = strstr(vscomntools, "\\Common7\\Tools"); path = p ? std::string(vscomntools, p) : vscomntools; return true; } return false; } void MSVCToolChain::AddSystemIncludeWithSubfolder( const ArgList &DriverArgs, ArgStringList &CC1Args, const std::string &folder, const Twine &subfolder1, const Twine &subfolder2, const Twine &subfolder3) const { llvm::SmallString<128> path(folder); llvm::sys::path::append(path, subfolder1, subfolder2, subfolder3); addSystemInclude(DriverArgs, CC1Args, path); } void MSVCToolChain::AddClangSystemIncludeArgs(const ArgList &DriverArgs, ArgStringList &CC1Args) const { if (DriverArgs.hasArg(options::OPT_nostdinc)) return; if (!DriverArgs.hasArg(options::OPT_nobuiltininc)) { AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, getDriver().ResourceDir, "include"); } // Add %INCLUDE%-like directories from the -imsvc flag. for (const auto &Path : DriverArgs.getAllArgValues(options::OPT__SLASH_imsvc)) addSystemInclude(DriverArgs, CC1Args, Path); if (DriverArgs.hasArg(options::OPT_nostdlibinc)) return; // Honor %INCLUDE%. It should know essential search paths with vcvarsall.bat. if (const char *cl_include_dir = getenv("INCLUDE")) { SmallVector Dirs; StringRef(cl_include_dir) .split(Dirs, ";", /*MaxSplit=*/-1, /*KeepEmpty=*/false); for (StringRef Dir : Dirs) addSystemInclude(DriverArgs, CC1Args, Dir); if (!Dirs.empty()) return; } std::string VSDir; // When built with access to the proper Windows APIs, try to actually find // the correct include paths first. if (getVisualStudioInstallDir(VSDir)) { AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, VSDir, "VC\\include"); if (useUniversalCRT(VSDir)) { std::string UniversalCRTSdkPath; std::string UCRTVersion; if (getUniversalCRTSdkDir(UniversalCRTSdkPath, UCRTVersion)) { AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, UniversalCRTSdkPath, "Include", UCRTVersion, "ucrt"); } } std::string WindowsSDKDir; int major; std::string windowsSDKIncludeVersion; std::string windowsSDKLibVersion; if (getWindowsSDKDir(WindowsSDKDir, major, windowsSDKIncludeVersion, windowsSDKLibVersion)) { if (major >= 8) { // Note: windowsSDKIncludeVersion is empty for SDKs prior to v10. // Anyway, llvm::sys::path::append is able to manage it. AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, WindowsSDKDir, "include", windowsSDKIncludeVersion, "shared"); AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, WindowsSDKDir, "include", windowsSDKIncludeVersion, "um"); AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, WindowsSDKDir, "include", windowsSDKIncludeVersion, "winrt"); } else { AddSystemIncludeWithSubfolder(DriverArgs, CC1Args, WindowsSDKDir, "include"); } } else { addSystemInclude(DriverArgs, CC1Args, VSDir); } return; } // As a fallback, select default install paths. // FIXME: Don't guess drives and paths like this on Windows. const StringRef Paths[] = { "C:/Program Files/Microsoft Visual Studio 10.0/VC/include", "C:/Program Files/Microsoft Visual Studio 9.0/VC/include", "C:/Program Files/Microsoft Visual Studio 9.0/VC/PlatformSDK/Include", "C:/Program Files/Microsoft Visual Studio 8/VC/include", "C:/Program Files/Microsoft Visual Studio 8/VC/PlatformSDK/Include" }; addSystemIncludes(DriverArgs, CC1Args, Paths); } void MSVCToolChain::AddClangCXXStdlibIncludeArgs(const ArgList &DriverArgs, ArgStringList &CC1Args) const { // FIXME: There should probably be logic here to find libc++ on Windows. } std::string MSVCToolChain::ComputeEffectiveClangTriple(const ArgList &Args, types::ID InputType) const { std::string TripleStr = ToolChain::ComputeEffectiveClangTriple(Args, InputType); llvm::Triple Triple(TripleStr); VersionTuple MSVT = tools::visualstudio::getMSVCVersion(/*D=*/nullptr, *this, Triple, Args, /*IsWindowsMSVC=*/true); if (MSVT.empty()) return TripleStr; MSVT = VersionTuple(MSVT.getMajor(), MSVT.getMinor().getValueOr(0), MSVT.getSubminor().getValueOr(0)); if (Triple.getEnvironment() == llvm::Triple::MSVC) { StringRef ObjFmt = Triple.getEnvironmentName().split('-').second; if (ObjFmt.empty()) Triple.setEnvironmentName((Twine("msvc") + MSVT.getAsString()).str()); else Triple.setEnvironmentName( (Twine("msvc") + MSVT.getAsString() + Twine('-') + ObjFmt).str()); } return Triple.getTriple(); } SanitizerMask MSVCToolChain::getSupportedSanitizers() const { SanitizerMask Res = ToolChain::getSupportedSanitizers(); Res |= SanitizerKind::Address; return Res; } static void TranslateOptArg(Arg *A, llvm::opt::DerivedArgList &DAL, bool SupportsForcingFramePointer, const char *ExpandChar, const OptTable &Opts) { assert(A->getOption().matches(options::OPT__SLASH_O)); StringRef OptStr = A->getValue(); for (size_t I = 0, E = OptStr.size(); I != E; ++I) { const char &OptChar = *(OptStr.data() + I); switch (OptChar) { default: break; case '1': case '2': case 'x': case 'd': if (&OptChar == ExpandChar) { if (OptChar == 'd') { DAL.AddFlagArg(A, Opts.getOption(options::OPT_O0)); } else { if (OptChar == '1') { DAL.AddJoinedArg(A, Opts.getOption(options::OPT_O), "s"); } else if (OptChar == '2' || OptChar == 'x') { DAL.AddFlagArg(A, Opts.getOption(options::OPT_fbuiltin)); DAL.AddJoinedArg(A, Opts.getOption(options::OPT_O), "2"); } if (SupportsForcingFramePointer && !DAL.hasArgNoClaim(options::OPT_fno_omit_frame_pointer)) DAL.AddFlagArg(A, Opts.getOption(options::OPT_fomit_frame_pointer)); if (OptChar == '1' || OptChar == '2') DAL.AddFlagArg(A, Opts.getOption(options::OPT_ffunction_sections)); } } break; case 'b': if (I + 1 != E && isdigit(OptStr[I + 1])) { switch (OptStr[I + 1]) { case '0': DAL.AddFlagArg(A, Opts.getOption(options::OPT_fno_inline)); break; case '1': DAL.AddFlagArg(A, Opts.getOption(options::OPT_finline_hint_functions)); break; case '2': DAL.AddFlagArg(A, Opts.getOption(options::OPT_finline_functions)); break; } ++I; } break; case 'g': break; case 'i': if (I + 1 != E && OptStr[I + 1] == '-') { ++I; DAL.AddFlagArg(A, Opts.getOption(options::OPT_fno_builtin)); } else { DAL.AddFlagArg(A, Opts.getOption(options::OPT_fbuiltin)); } break; case 's': DAL.AddJoinedArg(A, Opts.getOption(options::OPT_O), "s"); break; case 't': DAL.AddJoinedArg(A, Opts.getOption(options::OPT_O), "2"); break; case 'y': { bool OmitFramePointer = true; if (I + 1 != E && OptStr[I + 1] == '-') { OmitFramePointer = false; ++I; } if (SupportsForcingFramePointer) { if (OmitFramePointer) DAL.AddFlagArg(A, Opts.getOption(options::OPT_fomit_frame_pointer)); else DAL.AddFlagArg( A, Opts.getOption(options::OPT_fno_omit_frame_pointer)); } else { // Don't warn about /Oy- in 64-bit builds (where // SupportsForcingFramePointer is false). The flag having no effect // there is a compiler-internal optimization, and people shouldn't have // to special-case their build files for 64-bit clang-cl. A->claim(); } break; } } } } static void TranslateDArg(Arg *A, llvm::opt::DerivedArgList &DAL, const OptTable &Opts) { assert(A->getOption().matches(options::OPT_D)); StringRef Val = A->getValue(); size_t Hash = Val.find('#'); if (Hash == StringRef::npos || Hash > Val.find('=')) { DAL.append(A); return; } std::string NewVal = Val; NewVal[Hash] = '='; DAL.AddJoinedArg(A, Opts.getOption(options::OPT_D), NewVal); } llvm::opt::DerivedArgList * MSVCToolChain::TranslateArgs(const llvm::opt::DerivedArgList &Args, const char *BoundArch) const { DerivedArgList *DAL = new DerivedArgList(Args.getBaseArgs()); const OptTable &Opts = getDriver().getOpts(); // /Oy and /Oy- only has an effect under X86-32. bool SupportsForcingFramePointer = getArch() == llvm::Triple::x86; // The -O[12xd] flag actually expands to several flags. We must desugar the // flags so that options embedded can be negated. For example, the '-O2' flag // enables '-Oy'. Expanding '-O2' into its constituent flags allows us to // correctly handle '-O2 -Oy-' where the trailing '-Oy-' disables a single // aspect of '-O2'. // // Note that this expansion logic only applies to the *last* of '[12xd]'. // First step is to search for the character we'd like to expand. const char *ExpandChar = nullptr; for (Arg *A : Args) { if (!A->getOption().matches(options::OPT__SLASH_O)) continue; StringRef OptStr = A->getValue(); for (size_t I = 0, E = OptStr.size(); I != E; ++I) { char OptChar = OptStr[I]; char PrevChar = I > 0 ? OptStr[I - 1] : '0'; if (PrevChar == 'b') { // OptChar does not expand; it's an argument to the previous char. continue; } if (OptChar == '1' || OptChar == '2' || OptChar == 'x' || OptChar == 'd') ExpandChar = OptStr.data() + I; } } for (Arg *A : Args) { if (A->getOption().matches(options::OPT__SLASH_O)) { // The -O flag actually takes an amalgam of other options. For example, // '/Ogyb2' is equivalent to '/Og' '/Oy' '/Ob2'. TranslateOptArg(A, *DAL, SupportsForcingFramePointer, ExpandChar, Opts); } else if (A->getOption().matches(options::OPT_D)) { // Translate -Dfoo#bar into -Dfoo=bar. TranslateDArg(A, *DAL, Opts); } else { DAL->append(A); } } return DAL; }