//===-- TargetLibraryInfo.cpp - Runtime library information ----------------==// // // 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 // //===----------------------------------------------------------------------===// // // This file implements the TargetLibraryInfo class. // //===----------------------------------------------------------------------===// #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/SmallString.h" #include "llvm/IR/Constants.h" #include "llvm/IR/Module.h" #include "llvm/InitializePasses.h" #include "llvm/Support/CommandLine.h" #include "llvm/TargetParser/Triple.h" using namespace llvm; static cl::opt ClVectorLibrary( "vector-library", cl::Hidden, cl::desc("Vector functions library"), cl::init(TargetLibraryInfoImpl::NoLibrary), cl::values(clEnumValN(TargetLibraryInfoImpl::NoLibrary, "none", "No vector functions library"), clEnumValN(TargetLibraryInfoImpl::Accelerate, "Accelerate", "Accelerate framework"), clEnumValN(TargetLibraryInfoImpl::DarwinLibSystemM, "Darwin_libsystem_m", "Darwin libsystem_m"), clEnumValN(TargetLibraryInfoImpl::LIBMVEC_X86, "LIBMVEC-X86", "GLIBC Vector Math library"), clEnumValN(TargetLibraryInfoImpl::MASSV, "MASSV", "IBM MASS vector library"), clEnumValN(TargetLibraryInfoImpl::SVML, "SVML", "Intel SVML library"), clEnumValN(TargetLibraryInfoImpl::SLEEFGNUABI, "sleefgnuabi", "SIMD Library for Evaluating Elementary Functions"), clEnumValN(TargetLibraryInfoImpl::ArmPL, "ArmPL", "Arm Performance Libraries"), clEnumValN(TargetLibraryInfoImpl::AMDLIBM, "AMDLIBM", "AMD vector math library"))); StringLiteral const TargetLibraryInfoImpl::StandardNames[LibFunc::NumLibFuncs] = { #define TLI_DEFINE_STRING #include "llvm/Analysis/TargetLibraryInfo.def" }; std::string VecDesc::getVectorFunctionABIVariantString() const { assert(!VectorFnName.empty() && "Vector function name must not be empty."); SmallString<256> Buffer; llvm::raw_svector_ostream Out(Buffer); Out << VABIPrefix << "_" << ScalarFnName << "(" << VectorFnName << ")"; return std::string(Out.str()); } // Recognized types of library function arguments and return types. enum FuncArgTypeID : char { Void = 0, // Must be zero. Bool, // 8 bits on all targets Int16, Int32, Int, IntPlus, // Int or bigger. Long, // Either 32 or 64 bits. IntX, // Any integer type. Int64, LLong, // 64 bits on all targets. SizeT, // size_t. SSizeT, // POSIX ssize_t. Flt, // IEEE float. Dbl, // IEEE double. LDbl, // Any floating type (TODO: tighten this up). Floating, // Any floating type. Ptr, // Any pointer type. Struct, // Any struct type. Ellip, // The ellipsis (...). Same, // Same argument type as the previous one. }; typedef std::array FuncProtoTy; static const FuncProtoTy Signatures[] = { #define TLI_DEFINE_SIG #include "llvm/Analysis/TargetLibraryInfo.def" }; static_assert(sizeof Signatures / sizeof *Signatures == LibFunc::NumLibFuncs, "Missing library function signatures"); static bool hasSinCosPiStret(const Triple &T) { // Only Darwin variants have _stret versions of combined trig functions. if (!T.isOSDarwin()) return false; // The ABI is rather complicated on x86, so don't do anything special there. if (T.getArch() == Triple::x86) return false; if (T.isMacOSX() && T.isMacOSXVersionLT(10, 9)) return false; if (T.isiOS() && T.isOSVersionLT(7, 0)) return false; return true; } static bool hasBcmp(const Triple &TT) { // Posix removed support from bcmp() in 2001, but the glibc and several // implementations of the libc still have it. if (TT.isOSLinux()) return TT.isGNUEnvironment() || TT.isMusl(); // Both NetBSD and OpenBSD are planning to remove the function. Windows does // not have it. return TT.isOSFreeBSD() || TT.isOSSolaris(); } static bool isCallingConvCCompatible(CallingConv::ID CC, StringRef TT, FunctionType *FuncTy) { switch (CC) { default: return false; case llvm::CallingConv::C: return true; case llvm::CallingConv::ARM_APCS: case llvm::CallingConv::ARM_AAPCS: case llvm::CallingConv::ARM_AAPCS_VFP: { // The iOS ABI diverges from the standard in some cases, so for now don't // try to simplify those calls. if (Triple(TT).isiOS()) return false; if (!FuncTy->getReturnType()->isPointerTy() && !FuncTy->getReturnType()->isIntegerTy() && !FuncTy->getReturnType()->isVoidTy()) return false; for (auto *Param : FuncTy->params()) { if (!Param->isPointerTy() && !Param->isIntegerTy()) return false; } return true; } } return false; } bool TargetLibraryInfoImpl::isCallingConvCCompatible(CallBase *CI) { return ::isCallingConvCCompatible(CI->getCallingConv(), CI->getModule()->getTargetTriple(), CI->getFunctionType()); } bool TargetLibraryInfoImpl::isCallingConvCCompatible(Function *F) { return ::isCallingConvCCompatible(F->getCallingConv(), F->getParent()->getTargetTriple(), F->getFunctionType()); } static void initializeBase(TargetLibraryInfoImpl &TLI, const Triple &T) { bool ShouldExtI32Param, ShouldExtI32Return; bool ShouldSignExtI32Param, ShouldSignExtI32Return; TargetLibraryInfo::initExtensionsForTriple( ShouldExtI32Param, ShouldExtI32Return, ShouldSignExtI32Param, ShouldSignExtI32Return, T); TLI.setShouldExtI32Param(ShouldExtI32Param); TLI.setShouldExtI32Return(ShouldExtI32Return); TLI.setShouldSignExtI32Param(ShouldSignExtI32Param); TLI.setShouldSignExtI32Return(ShouldSignExtI32Return); // Let's assume by default that the size of int is 32 bits, unless the target // is a 16-bit architecture because then it most likely is 16 bits. If that // isn't true for a target those defaults should be overridden below. TLI.setIntSize(T.isArch16Bit() ? 16 : 32); } /// Initialize the set of available library functions based on the specified /// target triple. This should be carefully written so that a missing target /// triple gets a sane set of defaults. static void initializeLibCalls(TargetLibraryInfoImpl &TLI, const Triple &T, ArrayRef StandardNames) { // Set IO unlocked variants as unavailable // Set them as available per system below TLI.setUnavailable(LibFunc_getc_unlocked); TLI.setUnavailable(LibFunc_getchar_unlocked); TLI.setUnavailable(LibFunc_putc_unlocked); TLI.setUnavailable(LibFunc_putchar_unlocked); TLI.setUnavailable(LibFunc_fputc_unlocked); TLI.setUnavailable(LibFunc_fgetc_unlocked); TLI.setUnavailable(LibFunc_fread_unlocked); TLI.setUnavailable(LibFunc_fwrite_unlocked); TLI.setUnavailable(LibFunc_fputs_unlocked); TLI.setUnavailable(LibFunc_fgets_unlocked); // There is really no runtime library on AMDGPU, apart from // __kmpc_alloc/free_shared. if (T.isAMDGPU()) { TLI.disableAllFunctions(); TLI.setAvailable(llvm::LibFunc___kmpc_alloc_shared); TLI.setAvailable(llvm::LibFunc___kmpc_free_shared); return; } // memset_pattern{4,8,16} is only available on iOS 3.0 and Mac OS X 10.5 and // later. All versions of watchOS support it. if (T.isMacOSX()) { // available IO unlocked variants on Mac OS X TLI.setAvailable(LibFunc_getc_unlocked); TLI.setAvailable(LibFunc_getchar_unlocked); TLI.setAvailable(LibFunc_putc_unlocked); TLI.setAvailable(LibFunc_putchar_unlocked); TLI.setUnavailable(LibFunc_memrchr); if (T.isMacOSXVersionLT(10, 5)) { TLI.setUnavailable(LibFunc_memset_pattern4); TLI.setUnavailable(LibFunc_memset_pattern8); TLI.setUnavailable(LibFunc_memset_pattern16); } } else if (T.isiOS()) { if (T.isOSVersionLT(3, 0)) { TLI.setUnavailable(LibFunc_memset_pattern4); TLI.setUnavailable(LibFunc_memset_pattern8); TLI.setUnavailable(LibFunc_memset_pattern16); } } else if (!T.isWatchOS()) { TLI.setUnavailable(LibFunc_memset_pattern4); TLI.setUnavailable(LibFunc_memset_pattern8); TLI.setUnavailable(LibFunc_memset_pattern16); } if (!hasSinCosPiStret(T)) { TLI.setUnavailable(LibFunc_sinpi); TLI.setUnavailable(LibFunc_sinpif); TLI.setUnavailable(LibFunc_cospi); TLI.setUnavailable(LibFunc_cospif); TLI.setUnavailable(LibFunc_sincospi_stret); TLI.setUnavailable(LibFunc_sincospif_stret); } if (!hasBcmp(T)) TLI.setUnavailable(LibFunc_bcmp); if (T.isMacOSX() && T.getArch() == Triple::x86 && !T.isMacOSXVersionLT(10, 7)) { // x86-32 OSX has a scheme where fwrite and fputs (and some other functions // we don't care about) have two versions; on recent OSX, the one we want // has a $UNIX2003 suffix. The two implementations are identical except // for the return value in some edge cases. However, we don't want to // generate code that depends on the old symbols. TLI.setAvailableWithName(LibFunc_fwrite, "fwrite$UNIX2003"); TLI.setAvailableWithName(LibFunc_fputs, "fputs$UNIX2003"); } // iprintf and friends are only available on XCore, TCE, and Emscripten. if (T.getArch() != Triple::xcore && T.getArch() != Triple::tce && T.getOS() != Triple::Emscripten) { TLI.setUnavailable(LibFunc_iprintf); TLI.setUnavailable(LibFunc_siprintf); TLI.setUnavailable(LibFunc_fiprintf); } // __small_printf and friends are only available on Emscripten. if (T.getOS() != Triple::Emscripten) { TLI.setUnavailable(LibFunc_small_printf); TLI.setUnavailable(LibFunc_small_sprintf); TLI.setUnavailable(LibFunc_small_fprintf); } if (T.isOSWindows() && !T.isOSCygMing()) { // XXX: The earliest documentation available at the moment is for VS2015/VC19: // https://docs.microsoft.com/en-us/cpp/c-runtime-library/floating-point-support?view=vs-2015 // XXX: In order to use an MSVCRT older than VC19, // the specific library version must be explicit in the target triple, // e.g., x86_64-pc-windows-msvc18. bool hasPartialC99 = true; if (T.isKnownWindowsMSVCEnvironment()) { VersionTuple Version = T.getEnvironmentVersion(); hasPartialC99 = (Version.getMajor() == 0 || Version.getMajor() >= 19); } // Latest targets support C89 math functions, in part. bool isARM = (T.getArch() == Triple::aarch64 || T.getArch() == Triple::arm); bool hasPartialFloat = (isARM || T.getArch() == Triple::x86_64); // Win32 does not support float C89 math functions, in general. if (!hasPartialFloat) { TLI.setUnavailable(LibFunc_acosf); TLI.setUnavailable(LibFunc_asinf); TLI.setUnavailable(LibFunc_atan2f); TLI.setUnavailable(LibFunc_atanf); TLI.setUnavailable(LibFunc_ceilf); TLI.setUnavailable(LibFunc_cosf); TLI.setUnavailable(LibFunc_coshf); TLI.setUnavailable(LibFunc_expf); TLI.setUnavailable(LibFunc_floorf); TLI.setUnavailable(LibFunc_fmodf); TLI.setUnavailable(LibFunc_log10f); TLI.setUnavailable(LibFunc_logf); TLI.setUnavailable(LibFunc_modff); TLI.setUnavailable(LibFunc_powf); TLI.setUnavailable(LibFunc_remainderf); TLI.setUnavailable(LibFunc_remquof); TLI.setUnavailable(LibFunc_sinf); TLI.setUnavailable(LibFunc_sinhf); TLI.setUnavailable(LibFunc_sqrtf); TLI.setUnavailable(LibFunc_tanf); TLI.setUnavailable(LibFunc_tanhf); } if (!isARM) TLI.setUnavailable(LibFunc_fabsf); TLI.setUnavailable(LibFunc_frexpf); TLI.setUnavailable(LibFunc_ldexpf); // Win32 does not support long double C89 math functions. TLI.setUnavailable(LibFunc_acosl); TLI.setUnavailable(LibFunc_asinl); TLI.setUnavailable(LibFunc_atan2l); TLI.setUnavailable(LibFunc_atanl); TLI.setUnavailable(LibFunc_ceill); TLI.setUnavailable(LibFunc_cosl); TLI.setUnavailable(LibFunc_coshl); TLI.setUnavailable(LibFunc_expl); TLI.setUnavailable(LibFunc_fabsl); TLI.setUnavailable(LibFunc_floorl); TLI.setUnavailable(LibFunc_fmodl); TLI.setUnavailable(LibFunc_frexpl); TLI.setUnavailable(LibFunc_ldexpl); TLI.setUnavailable(LibFunc_log10l); TLI.setUnavailable(LibFunc_logl); TLI.setUnavailable(LibFunc_modfl); TLI.setUnavailable(LibFunc_powl); TLI.setUnavailable(LibFunc_remainderl); TLI.setUnavailable(LibFunc_remquol); TLI.setUnavailable(LibFunc_sinl); TLI.setUnavailable(LibFunc_sinhl); TLI.setUnavailable(LibFunc_sqrtl); TLI.setUnavailable(LibFunc_tanl); TLI.setUnavailable(LibFunc_tanhl); // Win32 does not fully support C99 math functions. if (!hasPartialC99) { TLI.setUnavailable(LibFunc_acosh); TLI.setUnavailable(LibFunc_acoshf); TLI.setUnavailable(LibFunc_asinh); TLI.setUnavailable(LibFunc_asinhf); TLI.setUnavailable(LibFunc_atanh); TLI.setUnavailable(LibFunc_atanhf); TLI.setAvailableWithName(LibFunc_cabs, "_cabs"); TLI.setUnavailable(LibFunc_cabsf); TLI.setUnavailable(LibFunc_cbrt); TLI.setUnavailable(LibFunc_cbrtf); TLI.setAvailableWithName(LibFunc_copysign, "_copysign"); TLI.setAvailableWithName(LibFunc_copysignf, "_copysignf"); TLI.setUnavailable(LibFunc_exp2); TLI.setUnavailable(LibFunc_exp2f); TLI.setUnavailable(LibFunc_expm1); TLI.setUnavailable(LibFunc_expm1f); TLI.setUnavailable(LibFunc_fmax); TLI.setUnavailable(LibFunc_fmaxf); TLI.setUnavailable(LibFunc_fmin); TLI.setUnavailable(LibFunc_fminf); TLI.setUnavailable(LibFunc_log1p); TLI.setUnavailable(LibFunc_log1pf); TLI.setUnavailable(LibFunc_log2); TLI.setUnavailable(LibFunc_log2f); TLI.setAvailableWithName(LibFunc_logb, "_logb"); if (hasPartialFloat) TLI.setAvailableWithName(LibFunc_logbf, "_logbf"); else TLI.setUnavailable(LibFunc_logbf); TLI.setUnavailable(LibFunc_rint); TLI.setUnavailable(LibFunc_rintf); TLI.setUnavailable(LibFunc_round); TLI.setUnavailable(LibFunc_roundf); TLI.setUnavailable(LibFunc_trunc); TLI.setUnavailable(LibFunc_truncf); } // Win32 does not support long double C99 math functions. TLI.setUnavailable(LibFunc_acoshl); TLI.setUnavailable(LibFunc_asinhl); TLI.setUnavailable(LibFunc_atanhl); TLI.setUnavailable(LibFunc_cabsl); TLI.setUnavailable(LibFunc_cbrtl); TLI.setUnavailable(LibFunc_copysignl); TLI.setUnavailable(LibFunc_exp2l); TLI.setUnavailable(LibFunc_expm1l); TLI.setUnavailable(LibFunc_fmaxl); TLI.setUnavailable(LibFunc_fminl); TLI.setUnavailable(LibFunc_log1pl); TLI.setUnavailable(LibFunc_log2l); TLI.setUnavailable(LibFunc_logbl); TLI.setUnavailable(LibFunc_nearbyintl); TLI.setUnavailable(LibFunc_rintl); TLI.setUnavailable(LibFunc_roundl); TLI.setUnavailable(LibFunc_truncl); // Win32 does not support these functions, but // they are generally available on POSIX-compliant systems. TLI.setUnavailable(LibFunc_access); TLI.setUnavailable(LibFunc_chmod); TLI.setUnavailable(LibFunc_closedir); TLI.setUnavailable(LibFunc_fdopen); TLI.setUnavailable(LibFunc_fileno); TLI.setUnavailable(LibFunc_fseeko); TLI.setUnavailable(LibFunc_fstat); TLI.setUnavailable(LibFunc_ftello); TLI.setUnavailable(LibFunc_gettimeofday); TLI.setUnavailable(LibFunc_memccpy); TLI.setUnavailable(LibFunc_mkdir); TLI.setUnavailable(LibFunc_open); TLI.setUnavailable(LibFunc_opendir); TLI.setUnavailable(LibFunc_pclose); TLI.setUnavailable(LibFunc_popen); TLI.setUnavailable(LibFunc_read); TLI.setUnavailable(LibFunc_rmdir); TLI.setUnavailable(LibFunc_stat); TLI.setUnavailable(LibFunc_strcasecmp); TLI.setUnavailable(LibFunc_strncasecmp); TLI.setUnavailable(LibFunc_unlink); TLI.setUnavailable(LibFunc_utime); TLI.setUnavailable(LibFunc_write); } if (T.isOSWindows() && !T.isWindowsCygwinEnvironment()) { // These functions aren't available in either MSVC or MinGW environments. TLI.setUnavailable(LibFunc_bcmp); TLI.setUnavailable(LibFunc_bcopy); TLI.setUnavailable(LibFunc_bzero); TLI.setUnavailable(LibFunc_chown); TLI.setUnavailable(LibFunc_ctermid); TLI.setUnavailable(LibFunc_ffs); TLI.setUnavailable(LibFunc_flockfile); TLI.setUnavailable(LibFunc_fstatvfs); TLI.setUnavailable(LibFunc_ftrylockfile); TLI.setUnavailable(LibFunc_funlockfile); TLI.setUnavailable(LibFunc_getitimer); TLI.setUnavailable(LibFunc_getlogin_r); TLI.setUnavailable(LibFunc_getpwnam); TLI.setUnavailable(LibFunc_htonl); TLI.setUnavailable(LibFunc_htons); TLI.setUnavailable(LibFunc_lchown); TLI.setUnavailable(LibFunc_lstat); TLI.setUnavailable(LibFunc_memrchr); TLI.setUnavailable(LibFunc_ntohl); TLI.setUnavailable(LibFunc_ntohs); TLI.setUnavailable(LibFunc_pread); TLI.setUnavailable(LibFunc_pwrite); TLI.setUnavailable(LibFunc_readlink); TLI.setUnavailable(LibFunc_realpath); TLI.setUnavailable(LibFunc_setitimer); TLI.setUnavailable(LibFunc_statvfs); TLI.setUnavailable(LibFunc_stpcpy); TLI.setUnavailable(LibFunc_stpncpy); TLI.setUnavailable(LibFunc_times); TLI.setUnavailable(LibFunc_uname); TLI.setUnavailable(LibFunc_unsetenv); TLI.setUnavailable(LibFunc_utimes); // MinGW does have ldexpf, but it is a plain wrapper over regular ldexp. // Therefore it's not beneficial to transform code to use it, i.e. // just pretend that the function is not available. TLI.setUnavailable(LibFunc_ldexpf); } // Pick just one set of new/delete variants. if (T.isOSMSVCRT()) { // MSVC, doesn't have the Itanium new/delete. TLI.setUnavailable(LibFunc_ZdaPv); TLI.setUnavailable(LibFunc_ZdaPvRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZdaPvSt11align_val_t); TLI.setUnavailable(LibFunc_ZdaPvSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZdaPvj); TLI.setUnavailable(LibFunc_ZdaPvjSt11align_val_t); TLI.setUnavailable(LibFunc_ZdaPvm); TLI.setUnavailable(LibFunc_ZdaPvmSt11align_val_t); TLI.setUnavailable(LibFunc_ZdlPv); TLI.setUnavailable(LibFunc_ZdlPvRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZdlPvSt11align_val_t); TLI.setUnavailable(LibFunc_ZdlPvSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZdlPvj); TLI.setUnavailable(LibFunc_ZdlPvjSt11align_val_t); TLI.setUnavailable(LibFunc_ZdlPvm); TLI.setUnavailable(LibFunc_ZdlPvmSt11align_val_t); TLI.setUnavailable(LibFunc_Znaj); TLI.setUnavailable(LibFunc_ZnajRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnajSt11align_val_t); TLI.setUnavailable(LibFunc_ZnajSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_Znam); TLI.setUnavailable(LibFunc_ZnamRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnamRKSt9nothrow_t12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnamSt11align_val_t); TLI.setUnavailable(LibFunc_ZnamSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_Znwj); TLI.setUnavailable(LibFunc_ZnwjRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnwjSt11align_val_t); TLI.setUnavailable(LibFunc_ZnwjSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_Znwm); TLI.setUnavailable(LibFunc_ZnwmRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnwmRKSt9nothrow_t12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnwmSt11align_val_t); TLI.setUnavailable(LibFunc_ZnwmSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_Znwm12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnwmSt11align_val_t12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnwmSt11align_val_tRKSt9nothrow_t12__hot_cold_t); TLI.setUnavailable(LibFunc_Znam12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnamSt11align_val_t12__hot_cold_t); TLI.setUnavailable(LibFunc_ZnamSt11align_val_tRKSt9nothrow_t12__hot_cold_t); } else { // Not MSVC, assume it's Itanium. TLI.setUnavailable(LibFunc_msvc_new_int); TLI.setUnavailable(LibFunc_msvc_new_int_nothrow); TLI.setUnavailable(LibFunc_msvc_new_longlong); TLI.setUnavailable(LibFunc_msvc_new_longlong_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_ptr32); TLI.setUnavailable(LibFunc_msvc_delete_ptr32_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_ptr32_int); TLI.setUnavailable(LibFunc_msvc_delete_ptr64); TLI.setUnavailable(LibFunc_msvc_delete_ptr64_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_ptr64_longlong); TLI.setUnavailable(LibFunc_msvc_new_array_int); TLI.setUnavailable(LibFunc_msvc_new_array_int_nothrow); TLI.setUnavailable(LibFunc_msvc_new_array_longlong); TLI.setUnavailable(LibFunc_msvc_new_array_longlong_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr32); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr32_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr32_int); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr64); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr64_nothrow); TLI.setUnavailable(LibFunc_msvc_delete_array_ptr64_longlong); } switch (T.getOS()) { case Triple::MacOSX: // exp10 and exp10f are not available on OS X until 10.9 and iOS until 7.0 // and their names are __exp10 and __exp10f. exp10l is not available on // OS X or iOS. TLI.setUnavailable(LibFunc_exp10l); if (T.isMacOSXVersionLT(10, 9)) { TLI.setUnavailable(LibFunc_exp10); TLI.setUnavailable(LibFunc_exp10f); } else { TLI.setAvailableWithName(LibFunc_exp10, "__exp10"); TLI.setAvailableWithName(LibFunc_exp10f, "__exp10f"); } break; case Triple::IOS: case Triple::TvOS: case Triple::WatchOS: case Triple::XROS: TLI.setUnavailable(LibFunc_exp10l); if (!T.isWatchOS() && (T.isOSVersionLT(7, 0) || (T.isOSVersionLT(9, 0) && T.isX86()))) { TLI.setUnavailable(LibFunc_exp10); TLI.setUnavailable(LibFunc_exp10f); } else { TLI.setAvailableWithName(LibFunc_exp10, "__exp10"); TLI.setAvailableWithName(LibFunc_exp10f, "__exp10f"); } break; case Triple::Linux: // exp10, exp10f, exp10l is available on Linux (GLIBC) but are extremely // buggy prior to glibc version 2.18. Until this version is widely deployed // or we have a reasonable detection strategy, we cannot use exp10 reliably // on Linux. // // Fall through to disable all of them. [[fallthrough]]; default: TLI.setUnavailable(LibFunc_exp10); TLI.setUnavailable(LibFunc_exp10f); TLI.setUnavailable(LibFunc_exp10l); } // ffsl is available on at least Darwin, Mac OS X, iOS, FreeBSD, and // Linux (GLIBC): // http://developer.apple.com/library/mac/#documentation/Darwin/Reference/ManPages/man3/ffsl.3.html // http://svn.freebsd.org/base/head/lib/libc/string/ffsl.c // http://www.gnu.org/software/gnulib/manual/html_node/ffsl.html switch (T.getOS()) { case Triple::Darwin: case Triple::MacOSX: case Triple::IOS: case Triple::TvOS: case Triple::WatchOS: case Triple::XROS: case Triple::FreeBSD: case Triple::Linux: break; default: TLI.setUnavailable(LibFunc_ffsl); } // ffsll is available on at least FreeBSD and Linux (GLIBC): // http://svn.freebsd.org/base/head/lib/libc/string/ffsll.c // http://www.gnu.org/software/gnulib/manual/html_node/ffsll.html switch (T.getOS()) { case Triple::Darwin: case Triple::MacOSX: case Triple::IOS: case Triple::TvOS: case Triple::WatchOS: case Triple::XROS: case Triple::FreeBSD: case Triple::Linux: break; default: TLI.setUnavailable(LibFunc_ffsll); } // The following functions are available on at least FreeBSD: // http://svn.freebsd.org/base/head/lib/libc/string/fls.c // http://svn.freebsd.org/base/head/lib/libc/string/flsl.c // http://svn.freebsd.org/base/head/lib/libc/string/flsll.c if (!T.isOSFreeBSD()) { TLI.setUnavailable(LibFunc_fls); TLI.setUnavailable(LibFunc_flsl); TLI.setUnavailable(LibFunc_flsll); } // The following functions are only available on GNU/Linux (using glibc). // Linux variants without glibc (eg: bionic, musl) may have some subset. if (!T.isOSLinux() || !T.isGNUEnvironment()) { TLI.setUnavailable(LibFunc_dunder_strdup); TLI.setUnavailable(LibFunc_dunder_strtok_r); TLI.setUnavailable(LibFunc_dunder_isoc99_scanf); TLI.setUnavailable(LibFunc_dunder_isoc99_sscanf); TLI.setUnavailable(LibFunc_under_IO_getc); TLI.setUnavailable(LibFunc_under_IO_putc); // But, Android and musl have memalign. if (!T.isAndroid() && !T.isMusl()) TLI.setUnavailable(LibFunc_memalign); TLI.setUnavailable(LibFunc_fopen64); TLI.setUnavailable(LibFunc_fseeko64); TLI.setUnavailable(LibFunc_fstat64); TLI.setUnavailable(LibFunc_fstatvfs64); TLI.setUnavailable(LibFunc_ftello64); TLI.setUnavailable(LibFunc_lstat64); TLI.setUnavailable(LibFunc_open64); TLI.setUnavailable(LibFunc_stat64); TLI.setUnavailable(LibFunc_statvfs64); TLI.setUnavailable(LibFunc_tmpfile64); // Relaxed math functions are included in math-finite.h on Linux (GLIBC). // Note that math-finite.h is no longer supported by top-of-tree GLIBC, // so we keep these functions around just so that they're recognized by // the ConstantFolder. TLI.setUnavailable(LibFunc_acos_finite); TLI.setUnavailable(LibFunc_acosf_finite); TLI.setUnavailable(LibFunc_acosl_finite); TLI.setUnavailable(LibFunc_acosh_finite); TLI.setUnavailable(LibFunc_acoshf_finite); TLI.setUnavailable(LibFunc_acoshl_finite); TLI.setUnavailable(LibFunc_asin_finite); TLI.setUnavailable(LibFunc_asinf_finite); TLI.setUnavailable(LibFunc_asinl_finite); TLI.setUnavailable(LibFunc_atan2_finite); TLI.setUnavailable(LibFunc_atan2f_finite); TLI.setUnavailable(LibFunc_atan2l_finite); TLI.setUnavailable(LibFunc_atanh_finite); TLI.setUnavailable(LibFunc_atanhf_finite); TLI.setUnavailable(LibFunc_atanhl_finite); TLI.setUnavailable(LibFunc_cosh_finite); TLI.setUnavailable(LibFunc_coshf_finite); TLI.setUnavailable(LibFunc_coshl_finite); TLI.setUnavailable(LibFunc_exp10_finite); TLI.setUnavailable(LibFunc_exp10f_finite); TLI.setUnavailable(LibFunc_exp10l_finite); TLI.setUnavailable(LibFunc_exp2_finite); TLI.setUnavailable(LibFunc_exp2f_finite); TLI.setUnavailable(LibFunc_exp2l_finite); TLI.setUnavailable(LibFunc_exp_finite); TLI.setUnavailable(LibFunc_expf_finite); TLI.setUnavailable(LibFunc_expl_finite); TLI.setUnavailable(LibFunc_log10_finite); TLI.setUnavailable(LibFunc_log10f_finite); TLI.setUnavailable(LibFunc_log10l_finite); TLI.setUnavailable(LibFunc_log2_finite); TLI.setUnavailable(LibFunc_log2f_finite); TLI.setUnavailable(LibFunc_log2l_finite); TLI.setUnavailable(LibFunc_log_finite); TLI.setUnavailable(LibFunc_logf_finite); TLI.setUnavailable(LibFunc_logl_finite); TLI.setUnavailable(LibFunc_pow_finite); TLI.setUnavailable(LibFunc_powf_finite); TLI.setUnavailable(LibFunc_powl_finite); TLI.setUnavailable(LibFunc_sinh_finite); TLI.setUnavailable(LibFunc_sinhf_finite); TLI.setUnavailable(LibFunc_sinhl_finite); TLI.setUnavailable(LibFunc_sqrt_finite); TLI.setUnavailable(LibFunc_sqrtf_finite); TLI.setUnavailable(LibFunc_sqrtl_finite); } if ((T.isOSLinux() && T.isGNUEnvironment()) || (T.isAndroid() && !T.isAndroidVersionLT(28))) { // available IO unlocked variants on GNU/Linux and Android P or later TLI.setAvailable(LibFunc_getc_unlocked); TLI.setAvailable(LibFunc_getchar_unlocked); TLI.setAvailable(LibFunc_putc_unlocked); TLI.setAvailable(LibFunc_putchar_unlocked); TLI.setAvailable(LibFunc_fputc_unlocked); TLI.setAvailable(LibFunc_fgetc_unlocked); TLI.setAvailable(LibFunc_fread_unlocked); TLI.setAvailable(LibFunc_fwrite_unlocked); TLI.setAvailable(LibFunc_fputs_unlocked); TLI.setAvailable(LibFunc_fgets_unlocked); } if (T.isAndroid() && T.isAndroidVersionLT(21)) { TLI.setUnavailable(LibFunc_stpcpy); TLI.setUnavailable(LibFunc_stpncpy); } if (T.isPS()) { // PS4/PS5 do have memalign. TLI.setAvailable(LibFunc_memalign); // PS4/PS5 do not have new/delete with "unsigned int" size parameter; // they only have the "unsigned long" versions. TLI.setUnavailable(LibFunc_ZdaPvj); TLI.setUnavailable(LibFunc_ZdaPvjSt11align_val_t); TLI.setUnavailable(LibFunc_ZdlPvj); TLI.setUnavailable(LibFunc_ZdlPvjSt11align_val_t); TLI.setUnavailable(LibFunc_Znaj); TLI.setUnavailable(LibFunc_ZnajRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnajSt11align_val_t); TLI.setUnavailable(LibFunc_ZnajSt11align_val_tRKSt9nothrow_t); TLI.setUnavailable(LibFunc_Znwj); TLI.setUnavailable(LibFunc_ZnwjRKSt9nothrow_t); TLI.setUnavailable(LibFunc_ZnwjSt11align_val_t); TLI.setUnavailable(LibFunc_ZnwjSt11align_val_tRKSt9nothrow_t); // None of the *_chk functions. TLI.setUnavailable(LibFunc_memccpy_chk); TLI.setUnavailable(LibFunc_memcpy_chk); TLI.setUnavailable(LibFunc_memmove_chk); TLI.setUnavailable(LibFunc_mempcpy_chk); TLI.setUnavailable(LibFunc_memset_chk); TLI.setUnavailable(LibFunc_snprintf_chk); TLI.setUnavailable(LibFunc_sprintf_chk); TLI.setUnavailable(LibFunc_stpcpy_chk); TLI.setUnavailable(LibFunc_stpncpy_chk); TLI.setUnavailable(LibFunc_strcat_chk); TLI.setUnavailable(LibFunc_strcpy_chk); TLI.setUnavailable(LibFunc_strlcat_chk); TLI.setUnavailable(LibFunc_strlcpy_chk); TLI.setUnavailable(LibFunc_strlen_chk); TLI.setUnavailable(LibFunc_strncat_chk); TLI.setUnavailable(LibFunc_strncpy_chk); TLI.setUnavailable(LibFunc_vsnprintf_chk); TLI.setUnavailable(LibFunc_vsprintf_chk); // Various Posix system functions. TLI.setUnavailable(LibFunc_access); TLI.setUnavailable(LibFunc_chmod); TLI.setUnavailable(LibFunc_chown); TLI.setUnavailable(LibFunc_closedir); TLI.setUnavailable(LibFunc_ctermid); TLI.setUnavailable(LibFunc_execl); TLI.setUnavailable(LibFunc_execle); TLI.setUnavailable(LibFunc_execlp); TLI.setUnavailable(LibFunc_execv); TLI.setUnavailable(LibFunc_execvP); TLI.setUnavailable(LibFunc_execve); TLI.setUnavailable(LibFunc_execvp); TLI.setUnavailable(LibFunc_execvpe); TLI.setUnavailable(LibFunc_fork); TLI.setUnavailable(LibFunc_fstat); TLI.setUnavailable(LibFunc_fstatvfs); TLI.setUnavailable(LibFunc_getenv); TLI.setUnavailable(LibFunc_getitimer); TLI.setUnavailable(LibFunc_getlogin_r); TLI.setUnavailable(LibFunc_getpwnam); TLI.setUnavailable(LibFunc_gettimeofday); TLI.setUnavailable(LibFunc_lchown); TLI.setUnavailable(LibFunc_lstat); TLI.setUnavailable(LibFunc_mkdir); TLI.setUnavailable(LibFunc_open); TLI.setUnavailable(LibFunc_opendir); TLI.setUnavailable(LibFunc_pclose); TLI.setUnavailable(LibFunc_popen); TLI.setUnavailable(LibFunc_pread); TLI.setUnavailable(LibFunc_pwrite); TLI.setUnavailable(LibFunc_read); TLI.setUnavailable(LibFunc_readlink); TLI.setUnavailable(LibFunc_realpath); TLI.setUnavailable(LibFunc_rename); TLI.setUnavailable(LibFunc_rmdir); TLI.setUnavailable(LibFunc_setitimer); TLI.setUnavailable(LibFunc_stat); TLI.setUnavailable(LibFunc_statvfs); TLI.setUnavailable(LibFunc_system); TLI.setUnavailable(LibFunc_times); TLI.setUnavailable(LibFunc_tmpfile); TLI.setUnavailable(LibFunc_unlink); TLI.setUnavailable(LibFunc_uname); TLI.setUnavailable(LibFunc_unsetenv); TLI.setUnavailable(LibFunc_utime); TLI.setUnavailable(LibFunc_utimes); TLI.setUnavailable(LibFunc_valloc); TLI.setUnavailable(LibFunc_write); // Miscellaneous other functions not provided. TLI.setUnavailable(LibFunc_atomic_load); TLI.setUnavailable(LibFunc_atomic_store); TLI.setUnavailable(LibFunc___kmpc_alloc_shared); TLI.setUnavailable(LibFunc___kmpc_free_shared); TLI.setUnavailable(LibFunc_dunder_strndup); TLI.setUnavailable(LibFunc_bcmp); TLI.setUnavailable(LibFunc_bcopy); TLI.setUnavailable(LibFunc_bzero); TLI.setUnavailable(LibFunc_cabs); TLI.setUnavailable(LibFunc_cabsf); TLI.setUnavailable(LibFunc_cabsl); TLI.setUnavailable(LibFunc_ffs); TLI.setUnavailable(LibFunc_flockfile); TLI.setUnavailable(LibFunc_fseeko); TLI.setUnavailable(LibFunc_ftello); TLI.setUnavailable(LibFunc_ftrylockfile); TLI.setUnavailable(LibFunc_funlockfile); TLI.setUnavailable(LibFunc_htonl); TLI.setUnavailable(LibFunc_htons); TLI.setUnavailable(LibFunc_isascii); TLI.setUnavailable(LibFunc_memccpy); TLI.setUnavailable(LibFunc_mempcpy); TLI.setUnavailable(LibFunc_memrchr); TLI.setUnavailable(LibFunc_ntohl); TLI.setUnavailable(LibFunc_ntohs); TLI.setUnavailable(LibFunc_reallocf); TLI.setUnavailable(LibFunc_roundeven); TLI.setUnavailable(LibFunc_roundevenf); TLI.setUnavailable(LibFunc_roundevenl); TLI.setUnavailable(LibFunc_stpcpy); TLI.setUnavailable(LibFunc_stpncpy); TLI.setUnavailable(LibFunc_strlcat); TLI.setUnavailable(LibFunc_strlcpy); TLI.setUnavailable(LibFunc_strndup); TLI.setUnavailable(LibFunc_strnlen); TLI.setUnavailable(LibFunc_toascii); } // As currently implemented in clang, NVPTX code has no standard library to // speak of. Headers provide a standard-ish library implementation, but many // of the signatures are wrong -- for example, many libm functions are not // extern "C". // // libdevice, an IR library provided by nvidia, is linked in by the front-end, // but only used functions are provided to llvm. Moreover, most of the // functions in libdevice don't map precisely to standard library functions. // // FIXME: Having no standard library prevents e.g. many fastmath // optimizations, so this situation should be fixed. if (T.isNVPTX()) { TLI.disableAllFunctions(); TLI.setAvailable(LibFunc_nvvm_reflect); TLI.setAvailable(llvm::LibFunc_malloc); TLI.setAvailable(llvm::LibFunc_free); // TODO: We could enable the following two according to [0] but we haven't // done an evaluation wrt. the performance implications. // [0] // https://docs.nvidia.com/cuda/cuda-c-programming-guide/index.html#dynamic-global-memory-allocation-and-operations // // TLI.setAvailable(llvm::LibFunc_memcpy); // TLI.setAvailable(llvm::LibFunc_memset); TLI.setAvailable(llvm::LibFunc___kmpc_alloc_shared); TLI.setAvailable(llvm::LibFunc___kmpc_free_shared); } else { TLI.setUnavailable(LibFunc_nvvm_reflect); } // These vec_malloc/free routines are only available on AIX. if (!T.isOSAIX()) { TLI.setUnavailable(LibFunc_vec_calloc); TLI.setUnavailable(LibFunc_vec_malloc); TLI.setUnavailable(LibFunc_vec_realloc); TLI.setUnavailable(LibFunc_vec_free); } if (T.isOSAIX()) TLI.setUnavailable(LibFunc_memrchr); TLI.addVectorizableFunctionsFromVecLib(ClVectorLibrary, T); } /// Initialize the set of available library functions based on the specified /// target triple. This should be carefully written so that a missing target /// triple gets a sane set of defaults. static void initialize(TargetLibraryInfoImpl &TLI, const Triple &T, ArrayRef StandardNames) { initializeBase(TLI, T); initializeLibCalls(TLI, T, StandardNames); } TargetLibraryInfoImpl::TargetLibraryInfoImpl() { // Default to nothing being available. memset(AvailableArray, 0, sizeof(AvailableArray)); initializeBase(*this, Triple()); } TargetLibraryInfoImpl::TargetLibraryInfoImpl(const Triple &T) { // Default to everything being available. memset(AvailableArray, -1, sizeof(AvailableArray)); initialize(*this, T, StandardNames); } TargetLibraryInfoImpl::TargetLibraryInfoImpl(const TargetLibraryInfoImpl &TLI) : CustomNames(TLI.CustomNames), ShouldExtI32Param(TLI.ShouldExtI32Param), ShouldExtI32Return(TLI.ShouldExtI32Return), ShouldSignExtI32Param(TLI.ShouldSignExtI32Param), ShouldSignExtI32Return(TLI.ShouldSignExtI32Return), SizeOfInt(TLI.SizeOfInt) { memcpy(AvailableArray, TLI.AvailableArray, sizeof(AvailableArray)); VectorDescs = TLI.VectorDescs; ScalarDescs = TLI.ScalarDescs; } TargetLibraryInfoImpl::TargetLibraryInfoImpl(TargetLibraryInfoImpl &&TLI) : CustomNames(std::move(TLI.CustomNames)), ShouldExtI32Param(TLI.ShouldExtI32Param), ShouldExtI32Return(TLI.ShouldExtI32Return), ShouldSignExtI32Param(TLI.ShouldSignExtI32Param), ShouldSignExtI32Return(TLI.ShouldSignExtI32Return), SizeOfInt(TLI.SizeOfInt) { std::move(std::begin(TLI.AvailableArray), std::end(TLI.AvailableArray), AvailableArray); VectorDescs = TLI.VectorDescs; ScalarDescs = TLI.ScalarDescs; } TargetLibraryInfoImpl &TargetLibraryInfoImpl::operator=(const TargetLibraryInfoImpl &TLI) { CustomNames = TLI.CustomNames; ShouldExtI32Param = TLI.ShouldExtI32Param; ShouldExtI32Return = TLI.ShouldExtI32Return; ShouldSignExtI32Param = TLI.ShouldSignExtI32Param; ShouldSignExtI32Return = TLI.ShouldSignExtI32Return; SizeOfInt = TLI.SizeOfInt; memcpy(AvailableArray, TLI.AvailableArray, sizeof(AvailableArray)); return *this; } TargetLibraryInfoImpl &TargetLibraryInfoImpl::operator=(TargetLibraryInfoImpl &&TLI) { CustomNames = std::move(TLI.CustomNames); ShouldExtI32Param = TLI.ShouldExtI32Param; ShouldExtI32Return = TLI.ShouldExtI32Return; ShouldSignExtI32Param = TLI.ShouldSignExtI32Param; ShouldSignExtI32Return = TLI.ShouldSignExtI32Return; SizeOfInt = TLI.SizeOfInt; std::move(std::begin(TLI.AvailableArray), std::end(TLI.AvailableArray), AvailableArray); return *this; } static StringRef sanitizeFunctionName(StringRef funcName) { // Filter out empty names and names containing null bytes, those can't be in // our table. if (funcName.empty() || funcName.contains('\0')) return StringRef(); // Check for \01 prefix that is used to mangle __asm declarations and // strip it if present. return GlobalValue::dropLLVMManglingEscape(funcName); } static DenseMap buildIndexMap(ArrayRef StandardNames) { DenseMap Indices; unsigned Idx = 0; Indices.reserve(LibFunc::NumLibFuncs); for (const auto &Func : StandardNames) Indices[Func] = static_cast(Idx++); return Indices; } bool TargetLibraryInfoImpl::getLibFunc(StringRef funcName, LibFunc &F) const { funcName = sanitizeFunctionName(funcName); if (funcName.empty()) return false; static const DenseMap Indices = buildIndexMap(StandardNames); if (auto Loc = Indices.find(funcName); Loc != Indices.end()) { F = Loc->second; return true; } return false; } // Return true if ArgTy matches Ty. static bool matchType(FuncArgTypeID ArgTy, const Type *Ty, unsigned IntBits, unsigned SizeTBits) { switch (ArgTy) { case Void: return Ty->isVoidTy(); case Bool: return Ty->isIntegerTy(8); case Int16: return Ty->isIntegerTy(16); case Int32: return Ty->isIntegerTy(32); case Int: return Ty->isIntegerTy(IntBits); case IntPlus: return Ty->isIntegerTy() && Ty->getPrimitiveSizeInBits() >= IntBits; case IntX: return Ty->isIntegerTy(); case Long: // TODO: Figure out and use long size. return Ty->isIntegerTy() && Ty->getPrimitiveSizeInBits() >= IntBits; case Int64: return Ty->isIntegerTy(64); case LLong: return Ty->isIntegerTy(64); case SizeT: case SSizeT: return Ty->isIntegerTy(SizeTBits); case Flt: return Ty->isFloatTy(); case Dbl: return Ty->isDoubleTy(); // TODO: Tighten this up. case LDbl: return Ty->isFloatingPointTy(); case Floating: return Ty->isFloatingPointTy(); case Ptr: return Ty->isPointerTy(); case Struct: return Ty->isStructTy(); default: break; } llvm_unreachable("Invalid type"); } bool TargetLibraryInfoImpl::isValidProtoForLibFunc(const FunctionType &FTy, LibFunc F, const Module &M) const { unsigned NumParams = FTy.getNumParams(); switch (F) { // Special handling for functions: case LibFunc_cabs: case LibFunc_cabsf: case LibFunc_cabsl: { Type *RetTy = FTy.getReturnType(); if (!RetTy->isFloatingPointTy()) return false; Type *ParamTy = FTy.getParamType(0); // NOTE: These prototypes are target specific and currently support // "complex" passed as an array or discrete real & imaginary parameters. // Add other calling conventions to enable libcall optimizations. if (NumParams == 1) return (ParamTy->isArrayTy() && ParamTy->getArrayNumElements() == 2 && ParamTy->getArrayElementType() == RetTy); else if (NumParams == 2) return ParamTy == RetTy && FTy.getParamType(1) == RetTy; return false; } // Special handling for the sincospi functions that return either // a struct or vector: case LibFunc_sincospi_stret: case LibFunc_sincospif_stret: { if (NumParams != 1) return false; Type *RetTy = FTy.getReturnType(); Type *ParamTy = FTy.getParamType(0); if (auto *Ty = dyn_cast(RetTy)) { if (Ty->getNumElements() != 2) return false; return (Ty->getElementType(0) == ParamTy && Ty->getElementType(1) == ParamTy); } if (auto *Ty = dyn_cast(RetTy)) { if (Ty->getNumElements() != 2) return false; return Ty->getElementType() == ParamTy; } return false; } default: break; } unsigned IntBits = getIntSize(); unsigned SizeTBits = getSizeTSize(M); unsigned Idx = 0; // Iterate over the type ids in the function prototype, matching each // against the function's type FTy, starting with its return type. // Return true if both match in number and kind, inclduing the ellipsis. Type *Ty = FTy.getReturnType(), *LastTy = Ty; const auto &ProtoTypes = Signatures[F]; for (auto TyID : ProtoTypes) { if (Idx && TyID == Void) // Except in the first position where it designates the function's // return type Void ends the argument list. break; if (TyID == Ellip) { // The ellipsis ends the protoype list but is not a part of FTy's // argument list. Except when it's last it must be followed by // Void. assert(Idx == ProtoTypes.size() - 1 || ProtoTypes[Idx + 1] == Void); return FTy.isFunctionVarArg(); } if (TyID == Same) { assert(Idx != 0 && "Type ID 'Same' must not be first!"); if (Ty != LastTy) return false; } else { if (!Ty || !matchType(TyID, Ty, IntBits, SizeTBits)) return false; LastTy = Ty; } if (Idx == NumParams) { // There's at least one and at most two more type ids than there are // arguments in FTy's argument list. Ty = nullptr; ++Idx; continue; } Ty = FTy.getParamType(Idx++); } // Return success only if all entries on both lists have been processed // and the function is not a variadic one. return Idx == NumParams + 1 && !FTy.isFunctionVarArg(); } bool TargetLibraryInfoImpl::getLibFunc(const Function &FDecl, LibFunc &F) const { // Intrinsics don't overlap w/libcalls; if our module has a large number of // intrinsics, this ends up being an interesting compile time win since we // avoid string normalization and comparison. if (FDecl.isIntrinsic()) return false; const Module *M = FDecl.getParent(); assert(M && "Expecting FDecl to be connected to a Module."); if (FDecl.LibFuncCache == Function::UnknownLibFunc) if (!getLibFunc(FDecl.getName(), FDecl.LibFuncCache)) FDecl.LibFuncCache = NotLibFunc; if (FDecl.LibFuncCache == NotLibFunc) return false; F = FDecl.LibFuncCache; return isValidProtoForLibFunc(*FDecl.getFunctionType(), F, *M); } bool TargetLibraryInfoImpl::getLibFunc(unsigned int Opcode, Type *Ty, LibFunc &F) const { // Must be a frem instruction with float or double arguments. if (Opcode != Instruction::FRem || (!Ty->isDoubleTy() && !Ty->isFloatTy())) return false; F = Ty->isDoubleTy() ? LibFunc_fmod : LibFunc_fmodf; return true; } void TargetLibraryInfoImpl::disableAllFunctions() { memset(AvailableArray, 0, sizeof(AvailableArray)); } static bool compareByScalarFnName(const VecDesc &LHS, const VecDesc &RHS) { return LHS.getScalarFnName() < RHS.getScalarFnName(); } static bool compareByVectorFnName(const VecDesc &LHS, const VecDesc &RHS) { return LHS.getVectorFnName() < RHS.getVectorFnName(); } static bool compareWithScalarFnName(const VecDesc &LHS, StringRef S) { return LHS.getScalarFnName() < S; } void TargetLibraryInfoImpl::addVectorizableFunctions(ArrayRef Fns) { llvm::append_range(VectorDescs, Fns); llvm::sort(VectorDescs, compareByScalarFnName); llvm::append_range(ScalarDescs, Fns); llvm::sort(ScalarDescs, compareByVectorFnName); } static const VecDesc VecFuncs_Accelerate[] = { #define TLI_DEFINE_ACCELERATE_VECFUNCS #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_ACCELERATE_VECFUNCS }; static const VecDesc VecFuncs_DarwinLibSystemM[] = { #define TLI_DEFINE_DARWIN_LIBSYSTEM_M_VECFUNCS #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_DARWIN_LIBSYSTEM_M_VECFUNCS }; static const VecDesc VecFuncs_LIBMVEC_X86[] = { #define TLI_DEFINE_LIBMVEC_X86_VECFUNCS #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_LIBMVEC_X86_VECFUNCS }; static const VecDesc VecFuncs_MASSV[] = { #define TLI_DEFINE_MASSV_VECFUNCS #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_MASSV_VECFUNCS }; static const VecDesc VecFuncs_SVML[] = { #define TLI_DEFINE_SVML_VECFUNCS #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_SVML_VECFUNCS }; static const VecDesc VecFuncs_SLEEFGNUABI_VF2[] = { #define TLI_DEFINE_SLEEFGNUABI_VF2_VECFUNCS #define TLI_DEFINE_VECFUNC(SCAL, VEC, VF, VABI_PREFIX) \ {SCAL, VEC, VF, /* MASK = */ false, VABI_PREFIX}, #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_SLEEFGNUABI_VF2_VECFUNCS }; static const VecDesc VecFuncs_SLEEFGNUABI_VF4[] = { #define TLI_DEFINE_SLEEFGNUABI_VF4_VECFUNCS #define TLI_DEFINE_VECFUNC(SCAL, VEC, VF, VABI_PREFIX) \ {SCAL, VEC, VF, /* MASK = */ false, VABI_PREFIX}, #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_SLEEFGNUABI_VF4_VECFUNCS }; static const VecDesc VecFuncs_SLEEFGNUABI_VFScalable[] = { #define TLI_DEFINE_SLEEFGNUABI_SCALABLE_VECFUNCS #define TLI_DEFINE_VECFUNC(SCAL, VEC, VF, MASK, VABI_PREFIX) \ {SCAL, VEC, VF, MASK, VABI_PREFIX}, #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_SLEEFGNUABI_SCALABLE_VECFUNCS }; static const VecDesc VecFuncs_ArmPL[] = { #define TLI_DEFINE_ARMPL_VECFUNCS #define TLI_DEFINE_VECFUNC(SCAL, VEC, VF, MASK, VABI_PREFIX) \ {SCAL, VEC, VF, MASK, VABI_PREFIX}, #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_ARMPL_VECFUNCS }; const VecDesc VecFuncs_AMDLIBM[] = { #define TLI_DEFINE_AMDLIBM_VECFUNCS #define TLI_DEFINE_VECFUNC(SCAL, VEC, VF, MASK, VABI_PREFIX) \ {SCAL, VEC, VF, MASK, VABI_PREFIX}, #include "llvm/Analysis/VecFuncs.def" #undef TLI_DEFINE_AMDLIBM_VECFUNCS }; void TargetLibraryInfoImpl::addVectorizableFunctionsFromVecLib( enum VectorLibrary VecLib, const llvm::Triple &TargetTriple) { switch (VecLib) { case Accelerate: { addVectorizableFunctions(VecFuncs_Accelerate); break; } case DarwinLibSystemM: { addVectorizableFunctions(VecFuncs_DarwinLibSystemM); break; } case LIBMVEC_X86: { addVectorizableFunctions(VecFuncs_LIBMVEC_X86); break; } case MASSV: { addVectorizableFunctions(VecFuncs_MASSV); break; } case SVML: { addVectorizableFunctions(VecFuncs_SVML); break; } case SLEEFGNUABI: { switch (TargetTriple.getArch()) { default: break; case llvm::Triple::aarch64: case llvm::Triple::aarch64_be: addVectorizableFunctions(VecFuncs_SLEEFGNUABI_VF2); addVectorizableFunctions(VecFuncs_SLEEFGNUABI_VF4); addVectorizableFunctions(VecFuncs_SLEEFGNUABI_VFScalable); break; } break; } case ArmPL: { switch (TargetTriple.getArch()) { default: break; case llvm::Triple::aarch64: case llvm::Triple::aarch64_be: addVectorizableFunctions(VecFuncs_ArmPL); break; } break; } case AMDLIBM: { addVectorizableFunctions(VecFuncs_AMDLIBM); break; } case NoLibrary: break; } } bool TargetLibraryInfoImpl::isFunctionVectorizable(StringRef funcName) const { funcName = sanitizeFunctionName(funcName); if (funcName.empty()) return false; std::vector::const_iterator I = llvm::lower_bound(VectorDescs, funcName, compareWithScalarFnName); return I != VectorDescs.end() && StringRef(I->getScalarFnName()) == funcName; } StringRef TargetLibraryInfoImpl::getVectorizedFunction(StringRef F, const ElementCount &VF, bool Masked) const { const VecDesc *VD = getVectorMappingInfo(F, VF, Masked); if (VD) return VD->getVectorFnName(); return StringRef(); } const VecDesc * TargetLibraryInfoImpl::getVectorMappingInfo(StringRef F, const ElementCount &VF, bool Masked) const { F = sanitizeFunctionName(F); if (F.empty()) return nullptr; std::vector::const_iterator I = llvm::lower_bound(VectorDescs, F, compareWithScalarFnName); while (I != VectorDescs.end() && StringRef(I->getScalarFnName()) == F) { if ((I->getVectorizationFactor() == VF) && (I->isMasked() == Masked)) return &(*I); ++I; } return nullptr; } TargetLibraryInfo TargetLibraryAnalysis::run(const Function &F, FunctionAnalysisManager &) { if (!BaselineInfoImpl) BaselineInfoImpl = TargetLibraryInfoImpl(Triple(F.getParent()->getTargetTriple())); return TargetLibraryInfo(*BaselineInfoImpl, &F); } unsigned TargetLibraryInfoImpl::getWCharSize(const Module &M) const { if (auto *ShortWChar = cast_or_null( M.getModuleFlag("wchar_size"))) return cast(ShortWChar->getValue())->getZExtValue(); return 0; } unsigned TargetLibraryInfoImpl::getSizeTSize(const Module &M) const { // There is really no guarantee that sizeof(size_t) is equal to sizeof(int*). // If that isn't true then it should be possible to derive the SizeTTy from // the target triple here instead and do an early return. // Historically LLVM assume that size_t has same size as intptr_t (hence // deriving the size from sizeof(int*) in address space zero). This should // work for most targets. For future consideration: DataLayout also implement // getIndexSizeInBits which might map better to size_t compared to // getPointerSizeInBits. Hard coding address space zero here might be // unfortunate as well. Maybe getDefaultGlobalsAddressSpace() or // getAllocaAddrSpace() is better. unsigned AddressSpace = 0; return M.getDataLayout().getPointerSizeInBits(AddressSpace); } TargetLibraryInfoWrapperPass::TargetLibraryInfoWrapperPass() : ImmutablePass(ID), TLA(TargetLibraryInfoImpl()) { initializeTargetLibraryInfoWrapperPassPass(*PassRegistry::getPassRegistry()); } TargetLibraryInfoWrapperPass::TargetLibraryInfoWrapperPass(const Triple &T) : ImmutablePass(ID), TLA(TargetLibraryInfoImpl(T)) { initializeTargetLibraryInfoWrapperPassPass(*PassRegistry::getPassRegistry()); } TargetLibraryInfoWrapperPass::TargetLibraryInfoWrapperPass( const TargetLibraryInfoImpl &TLIImpl) : ImmutablePass(ID), TLA(TLIImpl) { initializeTargetLibraryInfoWrapperPassPass(*PassRegistry::getPassRegistry()); } TargetLibraryInfoWrapperPass::TargetLibraryInfoWrapperPass( const TargetLibraryInfo &TLIOther) : TargetLibraryInfoWrapperPass(*TLIOther.Impl) {} AnalysisKey TargetLibraryAnalysis::Key; // Register the basic pass. INITIALIZE_PASS(TargetLibraryInfoWrapperPass, "targetlibinfo", "Target Library Information", false, true) char TargetLibraryInfoWrapperPass::ID = 0; void TargetLibraryInfoWrapperPass::anchor() {} void TargetLibraryInfoImpl::getWidestVF(StringRef ScalarF, ElementCount &FixedVF, ElementCount &ScalableVF) const { ScalarF = sanitizeFunctionName(ScalarF); // Use '0' here because a type of the form is not the // same as a scalar. ScalableVF = ElementCount::getScalable(0); FixedVF = ElementCount::getFixed(1); if (ScalarF.empty()) return; std::vector::const_iterator I = llvm::lower_bound(VectorDescs, ScalarF, compareWithScalarFnName); while (I != VectorDescs.end() && StringRef(I->getScalarFnName()) == ScalarF) { ElementCount *VF = I->getVectorizationFactor().isScalable() ? &ScalableVF : &FixedVF; if (ElementCount::isKnownGT(I->getVectorizationFactor(), *VF)) *VF = I->getVectorizationFactor(); ++I; } }