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//===-- llvm/Attributes.h - Container for Attributes ------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains the simple types necessary to represent the // attributes associated with functions and their calls. // //===----------------------------------------------------------------------===// #ifndef LLVM_ATTRIBUTES_H #define LLVM_ATTRIBUTES_H #include "llvm/Support/MathExtras.h" #include <cassert> #include <string> namespace llvm { class Type; namespace Attribute { /// We use this proxy POD type to allow constructing Attributes constants /// using initializer lists. Do not use this class directly. struct AttrConst { uint64_t v; AttrConst operator | (const AttrConst Attrs) const { AttrConst Res = {v | Attrs.v}; return Res; } AttrConst operator ~ () const { AttrConst Res = {~v}; return Res; } }; } // namespace Attribute /// Attributes - A bitset of attributes. class Attributes { public: Attributes() : Bits(0) { } explicit Attributes(uint64_t Val) : Bits(Val) { } /*implicit*/ Attributes(Attribute::AttrConst Val) : Bits(Val.v) { } Attributes(const Attributes &Attrs) : Bits(Attrs.Bits) { } // This is a "safe bool() operator". operator const void *() const { return Bits ? this : 0; } bool isEmptyOrSingleton() const { return (Bits & (Bits - 1)) == 0; } Attributes &operator = (const Attributes &Attrs) { Bits = Attrs.Bits; return *this; } bool operator == (const Attributes &Attrs) const { return Bits == Attrs.Bits; } bool operator != (const Attributes &Attrs) const { return Bits != Attrs.Bits; } Attributes operator | (const Attributes &Attrs) const { return Attributes(Bits | Attrs.Bits); } Attributes operator & (const Attributes &Attrs) const { return Attributes(Bits & Attrs.Bits); } Attributes operator ^ (const Attributes &Attrs) const { return Attributes(Bits ^ Attrs.Bits); } Attributes &operator |= (const Attributes &Attrs) { Bits |= Attrs.Bits; return *this; } Attributes &operator &= (const Attributes &Attrs) { Bits &= Attrs.Bits; return *this; } Attributes operator ~ () const { return Attributes(~Bits); } uint64_t Raw() const { return Bits; } private: // Currently, we need less than 64 bits. uint64_t Bits; }; namespace Attribute { /// Function parameters and results can have attributes to indicate how they /// should be treated by optimizations and code generation. This enumeration /// lists the attributes that can be associated with parameters, function /// results or the function itself. /// @brief Function attributes. // We declare AttrConst objects that will be used throughout the code // and also raw uint64_t objects with _i suffix to be used below for other // constant declarations. This is done to avoid static CTORs and at the same // time to keep type-safety of Attributes. #define DECLARE_LLVM_ATTRIBUTE(name, value) \ const uint64_t name##_i = value; \ const AttrConst name = {value}; DECLARE_LLVM_ATTRIBUTE(None,0) ///< No attributes have been set DECLARE_LLVM_ATTRIBUTE(ZExt,1<<0) ///< Zero extended before/after call DECLARE_LLVM_ATTRIBUTE(SExt,1<<1) ///< Sign extended before/after call DECLARE_LLVM_ATTRIBUTE(NoReturn,1<<2) ///< Mark the function as not returning DECLARE_LLVM_ATTRIBUTE(InReg,1<<3) ///< Force argument to be passed in register DECLARE_LLVM_ATTRIBUTE(StructRet,1<<4) ///< Hidden pointer to structure to return DECLARE_LLVM_ATTRIBUTE(NoUnwind,1<<5) ///< Function doesn't unwind stack DECLARE_LLVM_ATTRIBUTE(NoAlias,1<<6) ///< Considered to not alias after call DECLARE_LLVM_ATTRIBUTE(ByVal,1<<7) ///< Pass structure by value DECLARE_LLVM_ATTRIBUTE(Nest,1<<8) ///< Nested function static chain DECLARE_LLVM_ATTRIBUTE(ReadNone,1<<9) ///< Function does not access memory DECLARE_LLVM_ATTRIBUTE(ReadOnly,1<<10) ///< Function only reads from memory DECLARE_LLVM_ATTRIBUTE(NoInline,1<<11) ///< inline=never DECLARE_LLVM_ATTRIBUTE(AlwaysInline,1<<12) ///< inline=always DECLARE_LLVM_ATTRIBUTE(OptimizeForSize,1<<13) ///< opt_size DECLARE_LLVM_ATTRIBUTE(StackProtect,1<<14) ///< Stack protection. DECLARE_LLVM_ATTRIBUTE(StackProtectReq,1<<15) ///< Stack protection required. DECLARE_LLVM_ATTRIBUTE(Alignment,31<<16) ///< Alignment of parameter (5 bits) // stored as log2 of alignment with +1 bias // 0 means unaligned different from align 1 DECLARE_LLVM_ATTRIBUTE(NoCapture,1<<21) ///< Function creates no aliases of pointer DECLARE_LLVM_ATTRIBUTE(NoRedZone,1<<22) /// disable redzone DECLARE_LLVM_ATTRIBUTE(NoImplicitFloat,1<<23) /// disable implicit floating point /// instructions. DECLARE_LLVM_ATTRIBUTE(Naked,1<<24) ///< Naked function DECLARE_LLVM_ATTRIBUTE(InlineHint,1<<25) ///< source said inlining was ///desirable DECLARE_LLVM_ATTRIBUTE(StackAlignment,7<<26) ///< Alignment of stack for ///function (3 bits) stored as log2 ///of alignment with +1 bias ///0 means unaligned (different from ///alignstack= {1)) DECLARE_LLVM_ATTRIBUTE(ReturnsTwice,1<<29) ///< Function can return twice DECLARE_LLVM_ATTRIBUTE(UWTable,1<<30) ///< Function must be in a unwind ///table DECLARE_LLVM_ATTRIBUTE(NonLazyBind,1U<<31) ///< Function is called early and/or /// often, so lazy binding isn't /// worthwhile. DECLARE_LLVM_ATTRIBUTE(AddressSafety,1ULL<<32) ///< Address safety checking is on. #undef DECLARE_LLVM_ATTRIBUTE /// Note that uwtable is about the ABI or the user mandating an entry in the /// unwind table. The nounwind attribute is about an exception passing by the /// function. /// In a theoretical system that uses tables for profiling and sjlj for /// exceptions, they would be fully independent. In a normal system that /// uses tables for both, the semantics are: /// nil = Needs an entry because an exception might pass by. /// nounwind = No need for an entry /// uwtable = Needs an entry because the ABI says so and because /// an exception might pass by. /// uwtable + nounwind = Needs an entry because the ABI says so. /// @brief Attributes that only apply to function parameters. const AttrConst ParameterOnly = {ByVal_i | Nest_i | StructRet_i | NoCapture_i}; /// @brief Attributes that may be applied to the function itself. These cannot /// be used on return values or function parameters. const AttrConst FunctionOnly = {NoReturn_i | NoUnwind_i | ReadNone_i | ReadOnly_i | NoInline_i | AlwaysInline_i | OptimizeForSize_i | StackProtect_i | StackProtectReq_i | NoRedZone_i | NoImplicitFloat_i | Naked_i | InlineHint_i | StackAlignment_i | UWTable_i | NonLazyBind_i | ReturnsTwice_i | AddressSafety_i}; /// @brief Parameter attributes that do not apply to vararg call arguments. const AttrConst VarArgsIncompatible = {StructRet_i}; /// @brief Attributes that are mutually incompatible. const AttrConst MutuallyIncompatible[4] = { {ByVal_i | InReg_i | Nest_i | StructRet_i}, {ZExt_i | SExt_i}, {ReadNone_i | ReadOnly_i}, {NoInline_i | AlwaysInline_i} }; /// @brief Which attributes cannot be applied to a type. Attributes typeIncompatible(Type *Ty); /// This turns an int alignment (a power of 2, normally) into the /// form used internally in Attributes. inline Attributes constructAlignmentFromInt(unsigned i) { // Default alignment, allow the target to define how to align it. if (i == 0) return None; assert(isPowerOf2_32(i) && "Alignment must be a power of two."); assert(i <= 0x40000000 && "Alignment too large."); return Attributes((Log2_32(i)+1) << 16); } /// This returns the alignment field of an attribute as a byte alignment value. inline unsigned getAlignmentFromAttrs(Attributes A) { Attributes Align = A & Attribute::Alignment; if (!Align) return 0; return 1U << ((Align.Raw() >> 16) - 1); } /// This turns an int stack alignment (which must be a power of 2) into /// the form used internally in Attributes. inline Attributes constructStackAlignmentFromInt(unsigned i) { // Default alignment, allow the target to define how to align it. if (i == 0) return None; assert(isPowerOf2_32(i) && "Alignment must be a power of two."); assert(i <= 0x100 && "Alignment too large."); return Attributes((Log2_32(i)+1) << 26); } /// This returns the stack alignment field of an attribute as a byte alignment /// value. inline unsigned getStackAlignmentFromAttrs(Attributes A) { Attributes StackAlign = A & Attribute::StackAlignment; if (!StackAlign) return 0; return 1U << ((StackAlign.Raw() >> 26) - 1); } /// The set of Attributes set in Attributes is converted to a /// string of equivalent mnemonics. This is, presumably, for writing out /// the mnemonics for the assembly writer. /// @brief Convert attribute bits to text std::string getAsString(Attributes Attrs); } // end namespace Attribute /// This is just a pair of values to associate a set of attributes /// with an index. struct AttributeWithIndex { Attributes Attrs; ///< The attributes that are set, or'd together. unsigned Index; ///< Index of the parameter for which the attributes apply. ///< Index 0 is used for return value attributes. ///< Index ~0U is used for function attributes. static AttributeWithIndex get(unsigned Idx, Attributes Attrs) { AttributeWithIndex P; P.Index = Idx; P.Attrs = Attrs; return P; } }; //===----------------------------------------------------------------------===// // AttrListPtr Smart Pointer //===----------------------------------------------------------------------===// class AttributeListImpl; /// AttrListPtr - This class manages the ref count for the opaque /// AttributeListImpl object and provides accessors for it. class AttrListPtr { /// AttrList - The attributes that we are managing. This can be null /// to represent the empty attributes list. AttributeListImpl *AttrList; public: AttrListPtr() : AttrList(0) {} AttrListPtr(const AttrListPtr &P); const AttrListPtr &operator=(const AttrListPtr &RHS); ~AttrListPtr(); //===--------------------------------------------------------------------===// // Attribute List Construction and Mutation //===--------------------------------------------------------------------===// /// get - Return a Attributes list with the specified parameter in it. static AttrListPtr get(const AttributeWithIndex *Attr, unsigned NumAttrs); /// get - Return a Attribute list with the parameters specified by the /// consecutive random access iterator range. template <typename Iter> static AttrListPtr get(const Iter &I, const Iter &E) { if (I == E) return AttrListPtr(); // Empty list. return get(&*I, static_cast<unsigned>(E-I)); } /// addAttr - Add the specified attribute at the specified index to this /// attribute list. Since attribute lists are immutable, this /// returns the new list. AttrListPtr addAttr(unsigned Idx, Attributes Attrs) const; /// removeAttr - Remove the specified attribute at the specified index from /// this attribute list. Since attribute lists are immutable, this /// returns the new list. AttrListPtr removeAttr(unsigned Idx, Attributes Attrs) const; //===--------------------------------------------------------------------===// // Attribute List Accessors //===--------------------------------------------------------------------===// /// getParamAttributes - The attributes for the specified index are /// returned. Attributes getParamAttributes(unsigned Idx) const { assert (Idx && Idx != ~0U && "Invalid parameter index!"); return getAttributes(Idx); } /// getRetAttributes - The attributes for the ret value are /// returned. Attributes getRetAttributes() const { return getAttributes(0); } /// getFnAttributes - The function attributes are returned. Attributes getFnAttributes() const { return getAttributes(~0U); } /// paramHasAttr - Return true if the specified parameter index has the /// specified attribute set. bool paramHasAttr(unsigned Idx, Attributes Attr) const { return getAttributes(Idx) & Attr; } /// getParamAlignment - Return the alignment for the specified function /// parameter. unsigned getParamAlignment(unsigned Idx) const { return Attribute::getAlignmentFromAttrs(getAttributes(Idx)); } /// hasAttrSomewhere - Return true if the specified attribute is set for at /// least one parameter or for the return value. bool hasAttrSomewhere(Attributes Attr) const; /// operator==/!= - Provide equality predicates. bool operator==(const AttrListPtr &RHS) const { return AttrList == RHS.AttrList; } bool operator!=(const AttrListPtr &RHS) const { return AttrList != RHS.AttrList; } void dump() const; //===--------------------------------------------------------------------===// // Attribute List Introspection //===--------------------------------------------------------------------===// /// getRawPointer - Return a raw pointer that uniquely identifies this /// attribute list. void *getRawPointer() const { return AttrList; } // Attributes are stored as a dense set of slots, where there is one // slot for each argument that has an attribute. This allows walking over the // dense set instead of walking the sparse list of attributes. /// isEmpty - Return true if there are no attributes. /// bool isEmpty() const { return AttrList == 0; } /// getNumSlots - Return the number of slots used in this attribute list. /// This is the number of arguments that have an attribute set on them /// (including the function itself). unsigned getNumSlots() const; /// getSlot - Return the AttributeWithIndex at the specified slot. This /// holds a index number plus a set of attributes. const AttributeWithIndex &getSlot(unsigned Slot) const; private: explicit AttrListPtr(AttributeListImpl *L); /// getAttributes - The attributes for the specified index are /// returned. Attributes for the result are denoted with Idx = 0. Attributes getAttributes(unsigned Idx) const; }; } // End llvm namespace #endif