#pragma once #ifdef __GNUC__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-parameter" #endif //===-- TargetLibraryInfo.h - Library information ---------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLVM_ANALYSIS_TARGETLIBRARYINFO_H #define LLVM_ANALYSIS_TARGETLIBRARYINFO_H #include "llvm/ADT/BitVector.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Triple.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/PassManager.h" #include "llvm/Pass.h" #include namespace llvm { template class ArrayRef; class Function; class Module; class Triple; /// Describes a possible vectorization of a function. /// Function 'VectorFnName' is equivalent to 'ScalarFnName' vectorized /// by a factor 'VectorizationFactor'. struct VecDesc { StringRef ScalarFnName; StringRef VectorFnName; ElementCount VectorizationFactor; }; enum LibFunc : unsigned { #define TLI_DEFINE_ENUM #include "llvm/Analysis/TargetLibraryInfo.def" NumLibFuncs, NotLibFunc }; /// Implementation of the target library information. /// /// This class constructs tables that hold the target library information and /// make it available. However, it is somewhat expensive to compute and only /// depends on the triple. So users typically interact with the \c /// TargetLibraryInfo wrapper below. class TargetLibraryInfoImpl { friend class TargetLibraryInfo; unsigned char AvailableArray[(NumLibFuncs+3)/4]; DenseMap CustomNames; static StringLiteral const StandardNames[NumLibFuncs]; bool ShouldExtI32Param, ShouldExtI32Return, ShouldSignExtI32Param, ShouldSignExtI32Return; unsigned SizeOfInt; enum AvailabilityState { StandardName = 3, // (memset to all ones) CustomName = 1, Unavailable = 0 // (memset to all zeros) }; void setState(LibFunc F, AvailabilityState State) { AvailableArray[F/4] &= ~(3 << 2*(F&3)); AvailableArray[F/4] |= State << 2*(F&3); } AvailabilityState getState(LibFunc F) const { return static_cast((AvailableArray[F/4] >> 2*(F&3)) & 3); } /// Vectorization descriptors - sorted by ScalarFnName. std::vector VectorDescs; /// Scalarization descriptors - same content as VectorDescs but sorted based /// on VectorFnName rather than ScalarFnName. std::vector ScalarDescs; /// Return true if the function type FTy is valid for the library function /// F, regardless of whether the function is available. bool isValidProtoForLibFunc(const FunctionType &FTy, LibFunc F, const Module &M) const; public: /// List of known vector-functions libraries. /// /// The vector-functions library defines, which functions are vectorizable /// and with which factor. The library can be specified by either frontend, /// or a commandline option, and then used by /// addVectorizableFunctionsFromVecLib for filling up the tables of /// vectorizable functions. enum VectorLibrary { NoLibrary, // Don't use any vector library. Accelerate, // Use Accelerate framework. DarwinLibSystemM, // Use Darwin's libsystem_m. LIBMVEC_X86, // GLIBC Vector Math library. MASSV, // IBM MASS vector library. SVML, // Intel short vector math library. SLEEFGNUABI // SLEEF - SIMD Library for Evaluating Elementary Functions. }; TargetLibraryInfoImpl(); explicit TargetLibraryInfoImpl(const Triple &T); // Provide value semantics. TargetLibraryInfoImpl(const TargetLibraryInfoImpl &TLI); TargetLibraryInfoImpl(TargetLibraryInfoImpl &&TLI); TargetLibraryInfoImpl &operator=(const TargetLibraryInfoImpl &TLI); TargetLibraryInfoImpl &operator=(TargetLibraryInfoImpl &&TLI); /// Searches for a particular function name. /// /// If it is one of the known library functions, return true and set F to the /// corresponding value. bool getLibFunc(StringRef funcName, LibFunc &F) const; /// Searches for a particular function name, also checking that its type is /// valid for the library function matching that name. /// /// If it is one of the known library functions, return true and set F to the /// corresponding value. /// /// FDecl is assumed to have a parent Module when using this function. bool getLibFunc(const Function &FDecl, LibFunc &F) const; /// Forces a function to be marked as unavailable. void setUnavailable(LibFunc F) { setState(F, Unavailable); } /// Forces a function to be marked as available. void setAvailable(LibFunc F) { setState(F, StandardName); } /// Forces a function to be marked as available and provide an alternate name /// that must be used. void setAvailableWithName(LibFunc F, StringRef Name) { if (StandardNames[F] != Name) { setState(F, CustomName); CustomNames[F] = std::string(Name); assert(CustomNames.find(F) != CustomNames.end()); } else { setState(F, StandardName); } } /// Disables all builtins. /// /// This can be used for options like -fno-builtin. void disableAllFunctions(); /// Add a set of scalar -> vector mappings, queryable via /// getVectorizedFunction and getScalarizedFunction. void addVectorizableFunctions(ArrayRef Fns); /// Calls addVectorizableFunctions with a known preset of functions for the /// given vector library. void addVectorizableFunctionsFromVecLib(enum VectorLibrary VecLib, const llvm::Triple &TargetTriple); /// Return true if the function F has a vector equivalent with vectorization /// factor VF. bool isFunctionVectorizable(StringRef F, const ElementCount &VF) const { return !getVectorizedFunction(F, VF).empty(); } /// Return true if the function F has a vector equivalent with any /// vectorization factor. bool isFunctionVectorizable(StringRef F) const; /// Return the name of the equivalent of F, vectorized with factor VF. If no /// such mapping exists, return the empty string. StringRef getVectorizedFunction(StringRef F, const ElementCount &VF) const; /// Set to true iff i32 parameters to library functions should have signext /// or zeroext attributes if they correspond to C-level int or unsigned int, /// respectively. void setShouldExtI32Param(bool Val) { ShouldExtI32Param = Val; } /// Set to true iff i32 results from library functions should have signext /// or zeroext attributes if they correspond to C-level int or unsigned int, /// respectively. void setShouldExtI32Return(bool Val) { ShouldExtI32Return = Val; } /// Set to true iff i32 parameters to library functions should have signext /// attribute if they correspond to C-level int or unsigned int. void setShouldSignExtI32Param(bool Val) { ShouldSignExtI32Param = Val; } /// Set to true iff i32 results from library functions should have signext /// attribute if they correspond to C-level int or unsigned int. void setShouldSignExtI32Return(bool Val) { ShouldSignExtI32Return = Val; } /// Returns the size of the wchar_t type in bytes or 0 if the size is unknown. /// This queries the 'wchar_size' metadata. unsigned getWCharSize(const Module &M) const; /// Returns the size of the size_t type in bits. unsigned getSizeTSize(const Module &M) const; /// Get size of a C-level int or unsigned int, in bits. unsigned getIntSize() const { return SizeOfInt; } /// Initialize the C-level size of an integer. void setIntSize(unsigned Bits) { SizeOfInt = Bits; } /// Returns the largest vectorization factor used in the list of /// vector functions. void getWidestVF(StringRef ScalarF, ElementCount &FixedVF, ElementCount &Scalable) const; /// Returns true if call site / callee has cdecl-compatible calling /// conventions. static bool isCallingConvCCompatible(CallBase *CI); static bool isCallingConvCCompatible(Function *Callee); }; /// Provides information about what library functions are available for /// the current target. /// /// This both allows optimizations to handle them specially and frontends to /// disable such optimizations through -fno-builtin etc. class TargetLibraryInfo { friend class TargetLibraryAnalysis; friend class TargetLibraryInfoWrapperPass; /// The global (module level) TLI info. const TargetLibraryInfoImpl *Impl; /// Support for -fno-builtin* options as function attributes, overrides /// information in global TargetLibraryInfoImpl. BitVector OverrideAsUnavailable; public: explicit TargetLibraryInfo(const TargetLibraryInfoImpl &Impl, std::optional F = std::nullopt) : Impl(&Impl), OverrideAsUnavailable(NumLibFuncs) { if (!F) return; if ((*F)->hasFnAttribute("no-builtins")) disableAllFunctions(); else { // Disable individual libc/libm calls in TargetLibraryInfo. LibFunc LF; AttributeSet FnAttrs = (*F)->getAttributes().getFnAttrs(); for (const Attribute &Attr : FnAttrs) { if (!Attr.isStringAttribute()) continue; auto AttrStr = Attr.getKindAsString(); if (!AttrStr.consume_front("no-builtin-")) continue; if (getLibFunc(AttrStr, LF)) setUnavailable(LF); } } } // Provide value semantics. TargetLibraryInfo(const TargetLibraryInfo &TLI) = default; TargetLibraryInfo(TargetLibraryInfo &&TLI) : Impl(TLI.Impl), OverrideAsUnavailable(TLI.OverrideAsUnavailable) {} TargetLibraryInfo &operator=(const TargetLibraryInfo &TLI) = default; TargetLibraryInfo &operator=(TargetLibraryInfo &&TLI) { Impl = TLI.Impl; OverrideAsUnavailable = TLI.OverrideAsUnavailable; return *this; } /// Determine whether a callee with the given TLI can be inlined into /// caller with this TLI, based on 'nobuiltin' attributes. When requested, /// allow inlining into a caller with a superset of the callee's nobuiltin /// attributes, which is conservatively correct. bool areInlineCompatible(const TargetLibraryInfo &CalleeTLI, bool AllowCallerSuperset) const { if (!AllowCallerSuperset) return OverrideAsUnavailable == CalleeTLI.OverrideAsUnavailable; BitVector B = OverrideAsUnavailable; B |= CalleeTLI.OverrideAsUnavailable; // We can inline if the union of the caller and callee's nobuiltin // attributes is no stricter than the caller's nobuiltin attributes. return B == OverrideAsUnavailable; } /// Return true if the function type FTy is valid for the library function /// F, regardless of whether the function is available. bool isValidProtoForLibFunc(const FunctionType &FTy, LibFunc F, const Module &M) const { return Impl->isValidProtoForLibFunc(FTy, F, M); } /// Searches for a particular function name. /// /// If it is one of the known library functions, return true and set F to the /// corresponding value. bool getLibFunc(StringRef funcName, LibFunc &F) const { return Impl->getLibFunc(funcName, F); } bool getLibFunc(const Function &FDecl, LibFunc &F) const { return Impl->getLibFunc(FDecl, F); } /// If a callbase does not have the 'nobuiltin' attribute, return if the /// called function is a known library function and set F to that function. bool getLibFunc(const CallBase &CB, LibFunc &F) const { return !CB.isNoBuiltin() && CB.getCalledFunction() && getLibFunc(*(CB.getCalledFunction()), F); } /// Disables all builtins. /// /// This can be used for options like -fno-builtin. void disableAllFunctions() LLVM_ATTRIBUTE_UNUSED { OverrideAsUnavailable.set(); } /// Forces a function to be marked as unavailable. void setUnavailable(LibFunc F) LLVM_ATTRIBUTE_UNUSED { OverrideAsUnavailable.set(F); } TargetLibraryInfoImpl::AvailabilityState getState(LibFunc F) const { if (OverrideAsUnavailable[F]) return TargetLibraryInfoImpl::Unavailable; return Impl->getState(F); } /// Tests whether a library function is available. bool has(LibFunc F) const { return getState(F) != TargetLibraryInfoImpl::Unavailable; } bool isFunctionVectorizable(StringRef F, const ElementCount &VF) const { return Impl->isFunctionVectorizable(F, VF); } bool isFunctionVectorizable(StringRef F) const { return Impl->isFunctionVectorizable(F); } StringRef getVectorizedFunction(StringRef F, const ElementCount &VF) const { return Impl->getVectorizedFunction(F, VF); } /// Tests if the function is both available and a candidate for optimized code /// generation. bool hasOptimizedCodeGen(LibFunc F) const { if (getState(F) == TargetLibraryInfoImpl::Unavailable) return false; switch (F) { default: break; case LibFunc_copysign: case LibFunc_copysignf: case LibFunc_copysignl: case LibFunc_fabs: case LibFunc_fabsf: case LibFunc_fabsl: case LibFunc_sin: case LibFunc_sinf: case LibFunc_sinl: case LibFunc_cos: case LibFunc_cosf: case LibFunc_cosl: case LibFunc_sqrt: case LibFunc_sqrtf: case LibFunc_sqrtl: case LibFunc_sqrt_finite: case LibFunc_sqrtf_finite: case LibFunc_sqrtl_finite: case LibFunc_fmax: case LibFunc_fmaxf: case LibFunc_fmaxl: case LibFunc_fmin: case LibFunc_fminf: case LibFunc_fminl: case LibFunc_floor: case LibFunc_floorf: case LibFunc_floorl: case LibFunc_nearbyint: case LibFunc_nearbyintf: case LibFunc_nearbyintl: case LibFunc_ceil: case LibFunc_ceilf: case LibFunc_ceill: case LibFunc_rint: case LibFunc_rintf: case LibFunc_rintl: case LibFunc_round: case LibFunc_roundf: case LibFunc_roundl: case LibFunc_trunc: case LibFunc_truncf: case LibFunc_truncl: case LibFunc_log2: case LibFunc_log2f: case LibFunc_log2l: case LibFunc_exp2: case LibFunc_exp2f: case LibFunc_exp2l: case LibFunc_memcpy: case LibFunc_memset: case LibFunc_memmove: case LibFunc_memcmp: case LibFunc_bcmp: case LibFunc_strcmp: case LibFunc_strcpy: case LibFunc_stpcpy: case LibFunc_strlen: case LibFunc_strnlen: case LibFunc_memchr: case LibFunc_mempcpy: return true; } return false; } StringRef getName(LibFunc F) const { auto State = getState(F); if (State == TargetLibraryInfoImpl::Unavailable) return StringRef(); if (State == TargetLibraryInfoImpl::StandardName) return Impl->StandardNames[F]; assert(State == TargetLibraryInfoImpl::CustomName); return Impl->CustomNames.find(F)->second; } static void initExtensionsForTriple(bool &ShouldExtI32Param, bool &ShouldExtI32Return, bool &ShouldSignExtI32Param, bool &ShouldSignExtI32Return, const Triple &T) { ShouldExtI32Param = ShouldExtI32Return = false; ShouldSignExtI32Param = ShouldSignExtI32Return = false; // PowerPC64, Sparc64, SystemZ need signext/zeroext on i32 parameters and // returns corresponding to C-level ints and unsigned ints. if (T.isPPC64() || T.getArch() == Triple::sparcv9 || T.getArch() == Triple::systemz) { ShouldExtI32Param = true; ShouldExtI32Return = true; } // Mips and riscv64, on the other hand, needs signext on i32 parameters // corresponding to both signed and unsigned ints. if (T.isMIPS() || T.isRISCV64()) { ShouldSignExtI32Param = true; } // riscv64 needs signext on i32 returns corresponding to both signed and // unsigned ints. if (T.isRISCV64()) { ShouldSignExtI32Return = true; } } /// Returns extension attribute kind to be used for i32 parameters /// corresponding to C-level int or unsigned int. May be zeroext, signext, /// or none. private: static Attribute::AttrKind getExtAttrForI32Param(bool ShouldExtI32Param_, bool ShouldSignExtI32Param_, bool Signed = true) { if (ShouldExtI32Param_) return Signed ? Attribute::SExt : Attribute::ZExt; if (ShouldSignExtI32Param_) return Attribute::SExt; return Attribute::None; } public: static Attribute::AttrKind getExtAttrForI32Param(const Triple &T, bool Signed = true) { bool ShouldExtI32Param, ShouldExtI32Return; bool ShouldSignExtI32Param, ShouldSignExtI32Return; initExtensionsForTriple(ShouldExtI32Param, ShouldExtI32Return, ShouldSignExtI32Param, ShouldSignExtI32Return, T); return getExtAttrForI32Param(ShouldExtI32Param, ShouldSignExtI32Param, Signed); } Attribute::AttrKind getExtAttrForI32Param(bool Signed = true) const { return getExtAttrForI32Param(Impl->ShouldExtI32Param, Impl->ShouldSignExtI32Param, Signed); } /// Returns extension attribute kind to be used for i32 return values /// corresponding to C-level int or unsigned int. May be zeroext, signext, /// or none. private: static Attribute::AttrKind getExtAttrForI32Return(bool ShouldExtI32Return_, bool ShouldSignExtI32Return_, bool Signed) { if (ShouldExtI32Return_) return Signed ? Attribute::SExt : Attribute::ZExt; if (ShouldSignExtI32Return_) return Attribute::SExt; return Attribute::None; } public: static Attribute::AttrKind getExtAttrForI32Return(const Triple &T, bool Signed = true) { bool ShouldExtI32Param, ShouldExtI32Return; bool ShouldSignExtI32Param, ShouldSignExtI32Return; initExtensionsForTriple(ShouldExtI32Param, ShouldExtI32Return, ShouldSignExtI32Param, ShouldSignExtI32Return, T); return getExtAttrForI32Return(ShouldExtI32Return, ShouldSignExtI32Return, Signed); } Attribute::AttrKind getExtAttrForI32Return(bool Signed = true) const { return getExtAttrForI32Return(Impl->ShouldExtI32Return, Impl->ShouldSignExtI32Return, Signed); } // Helper to create an AttributeList for args (and ret val) which all have // the same signedness. Attributes in AL may be passed in to include them // as well in the returned AttributeList. AttributeList getAttrList(LLVMContext *C, ArrayRef ArgNos, bool Signed, bool Ret = false, AttributeList AL = AttributeList()) const { if (auto AK = getExtAttrForI32Param(Signed)) for (auto ArgNo : ArgNos) AL = AL.addParamAttribute(*C, ArgNo, AK); if (Ret) if (auto AK = getExtAttrForI32Return(Signed)) AL = AL.addRetAttribute(*C, AK); return AL; } /// \copydoc TargetLibraryInfoImpl::getWCharSize() unsigned getWCharSize(const Module &M) const { return Impl->getWCharSize(M); } /// \copydoc TargetLibraryInfoImpl::getSizeTSize() unsigned getSizeTSize(const Module &M) const { return Impl->getSizeTSize(M); } /// \copydoc TargetLibraryInfoImpl::getIntSize() unsigned getIntSize() const { return Impl->getIntSize(); } /// Handle invalidation from the pass manager. /// /// If we try to invalidate this info, just return false. It cannot become /// invalid even if the module or function changes. bool invalidate(Module &, const PreservedAnalyses &, ModuleAnalysisManager::Invalidator &) { return false; } bool invalidate(Function &, const PreservedAnalyses &, FunctionAnalysisManager::Invalidator &) { return false; } /// Returns the largest vectorization factor used in the list of /// vector functions. void getWidestVF(StringRef ScalarF, ElementCount &FixedVF, ElementCount &ScalableVF) const { Impl->getWidestVF(ScalarF, FixedVF, ScalableVF); } /// Check if the function "F" is listed in a library known to LLVM. bool isKnownVectorFunctionInLibrary(StringRef F) const { return this->isFunctionVectorizable(F); } }; /// Analysis pass providing the \c TargetLibraryInfo. /// /// Note that this pass's result cannot be invalidated, it is immutable for the /// life of the module. class TargetLibraryAnalysis : public AnalysisInfoMixin { public: typedef TargetLibraryInfo Result; /// Default construct the library analysis. /// /// This will use the module's triple to construct the library info for that /// module. TargetLibraryAnalysis() = default; /// Construct a library analysis with baseline Module-level info. /// /// This will be supplemented with Function-specific info in the Result. TargetLibraryAnalysis(TargetLibraryInfoImpl BaselineInfoImpl) : BaselineInfoImpl(std::move(BaselineInfoImpl)) {} TargetLibraryInfo run(const Function &F, FunctionAnalysisManager &); private: friend AnalysisInfoMixin; static AnalysisKey Key; std::optional BaselineInfoImpl; }; class TargetLibraryInfoWrapperPass : public ImmutablePass { TargetLibraryAnalysis TLA; std::optional TLI; virtual void anchor(); public: static char ID; TargetLibraryInfoWrapperPass(); explicit TargetLibraryInfoWrapperPass(const Triple &T); explicit TargetLibraryInfoWrapperPass(const TargetLibraryInfoImpl &TLI); TargetLibraryInfo &getTLI(const Function &F) { FunctionAnalysisManager DummyFAM; TLI = TLA.run(F, DummyFAM); return *TLI; } }; } // end namespace llvm #endif #ifdef __GNUC__ #pragma GCC diagnostic pop #endif