forked from OSchip/llvm-project
633 lines
20 KiB
C++
633 lines
20 KiB
C++
//===-- CGValue.h - LLVM CodeGen wrappers for llvm::Value* ------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// These classes implement wrappers around llvm::Value in order to
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// fully represent the range of values for C L- and R- values.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_CLANG_LIB_CODEGEN_CGVALUE_H
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#define LLVM_CLANG_LIB_CODEGEN_CGVALUE_H
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#include "clang/AST/ASTContext.h"
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#include "clang/AST/Type.h"
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#include "llvm/IR/Value.h"
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#include "llvm/IR/Type.h"
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#include "Address.h"
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#include "CodeGenTBAA.h"
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namespace llvm {
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class Constant;
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class MDNode;
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}
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namespace clang {
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namespace CodeGen {
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class AggValueSlot;
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class CodeGenFunction;
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struct CGBitFieldInfo;
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/// RValue - This trivial value class is used to represent the result of an
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/// expression that is evaluated. It can be one of three things: either a
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/// simple LLVM SSA value, a pair of SSA values for complex numbers, or the
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/// address of an aggregate value in memory.
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class RValue {
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enum Flavor { Scalar, Complex, Aggregate };
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// The shift to make to an aggregate's alignment to make it look
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// like a pointer.
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enum { AggAlignShift = 4 };
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// Stores first value and flavor.
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llvm::PointerIntPair<llvm::Value *, 2, Flavor> V1;
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// Stores second value and volatility.
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llvm::PointerIntPair<llvm::Value *, 1, bool> V2;
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public:
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bool isScalar() const { return V1.getInt() == Scalar; }
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bool isComplex() const { return V1.getInt() == Complex; }
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bool isAggregate() const { return V1.getInt() == Aggregate; }
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bool isVolatileQualified() const { return V2.getInt(); }
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/// getScalarVal() - Return the Value* of this scalar value.
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llvm::Value *getScalarVal() const {
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assert(isScalar() && "Not a scalar!");
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return V1.getPointer();
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}
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/// getComplexVal - Return the real/imag components of this complex value.
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///
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std::pair<llvm::Value *, llvm::Value *> getComplexVal() const {
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return std::make_pair(V1.getPointer(), V2.getPointer());
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}
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/// getAggregateAddr() - Return the Value* of the address of the aggregate.
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Address getAggregateAddress() const {
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assert(isAggregate() && "Not an aggregate!");
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auto align = reinterpret_cast<uintptr_t>(V2.getPointer()) >> AggAlignShift;
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return Address(V1.getPointer(), CharUnits::fromQuantity(align));
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}
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llvm::Value *getAggregatePointer() const {
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assert(isAggregate() && "Not an aggregate!");
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return V1.getPointer();
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}
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static RValue getIgnored() {
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// FIXME: should we make this a more explicit state?
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return get(nullptr);
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}
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static RValue get(llvm::Value *V) {
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RValue ER;
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ER.V1.setPointer(V);
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ER.V1.setInt(Scalar);
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ER.V2.setInt(false);
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return ER;
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}
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static RValue getComplex(llvm::Value *V1, llvm::Value *V2) {
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RValue ER;
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ER.V1.setPointer(V1);
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ER.V2.setPointer(V2);
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ER.V1.setInt(Complex);
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ER.V2.setInt(false);
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return ER;
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}
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static RValue getComplex(const std::pair<llvm::Value *, llvm::Value *> &C) {
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return getComplex(C.first, C.second);
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}
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// FIXME: Aggregate rvalues need to retain information about whether they are
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// volatile or not. Remove default to find all places that probably get this
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// wrong.
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static RValue getAggregate(Address addr, bool isVolatile = false) {
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RValue ER;
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ER.V1.setPointer(addr.getPointer());
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ER.V1.setInt(Aggregate);
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auto align = static_cast<uintptr_t>(addr.getAlignment().getQuantity());
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ER.V2.setPointer(reinterpret_cast<llvm::Value*>(align << AggAlignShift));
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ER.V2.setInt(isVolatile);
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return ER;
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}
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};
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/// Does an ARC strong l-value have precise lifetime?
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enum ARCPreciseLifetime_t {
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ARCImpreciseLifetime, ARCPreciseLifetime
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};
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/// The source of the alignment of an l-value; an expression of
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/// confidence in the alignment actually matching the estimate.
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enum class AlignmentSource {
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/// The l-value was an access to a declared entity or something
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/// equivalently strong, like the address of an array allocated by a
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/// language runtime.
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Decl,
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/// The l-value was considered opaque, so the alignment was
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/// determined from a type, but that type was an explicitly-aligned
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/// typedef.
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AttributedType,
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/// The l-value was considered opaque, so the alignment was
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/// determined from a type.
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Type
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};
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/// Given that the base address has the given alignment source, what's
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/// our confidence in the alignment of the field?
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static inline AlignmentSource getFieldAlignmentSource(AlignmentSource Source) {
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// For now, we don't distinguish fields of opaque pointers from
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// top-level declarations, but maybe we should.
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return AlignmentSource::Decl;
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}
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class LValueBaseInfo {
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AlignmentSource AlignSource;
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public:
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explicit LValueBaseInfo(AlignmentSource Source = AlignmentSource::Type)
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: AlignSource(Source) {}
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AlignmentSource getAlignmentSource() const { return AlignSource; }
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void setAlignmentSource(AlignmentSource Source) { AlignSource = Source; }
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void mergeForCast(const LValueBaseInfo &Info) {
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setAlignmentSource(Info.getAlignmentSource());
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}
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};
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/// LValue - This represents an lvalue references. Because C/C++ allow
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/// bitfields, this is not a simple LLVM pointer, it may be a pointer plus a
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/// bitrange.
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class LValue {
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enum {
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Simple, // This is a normal l-value, use getAddress().
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VectorElt, // This is a vector element l-value (V[i]), use getVector*
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BitField, // This is a bitfield l-value, use getBitfield*.
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ExtVectorElt, // This is an extended vector subset, use getExtVectorComp
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GlobalReg // This is a register l-value, use getGlobalReg()
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} LVType;
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llvm::Value *V;
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union {
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// Index into a vector subscript: V[i]
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llvm::Value *VectorIdx;
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// ExtVector element subset: V.xyx
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llvm::Constant *VectorElts;
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// BitField start bit and size
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const CGBitFieldInfo *BitFieldInfo;
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};
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QualType Type;
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// 'const' is unused here
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Qualifiers Quals;
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// The alignment to use when accessing this lvalue. (For vector elements,
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// this is the alignment of the whole vector.)
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unsigned Alignment;
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// objective-c's ivar
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bool Ivar:1;
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// objective-c's ivar is an array
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bool ObjIsArray:1;
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// LValue is non-gc'able for any reason, including being a parameter or local
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// variable.
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bool NonGC: 1;
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// Lvalue is a global reference of an objective-c object
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bool GlobalObjCRef : 1;
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// Lvalue is a thread local reference
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bool ThreadLocalRef : 1;
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// Lvalue has ARC imprecise lifetime. We store this inverted to try
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// to make the default bitfield pattern all-zeroes.
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bool ImpreciseLifetime : 1;
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// This flag shows if a nontemporal load/stores should be used when accessing
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// this lvalue.
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bool Nontemporal : 1;
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LValueBaseInfo BaseInfo;
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TBAAAccessInfo TBAAInfo;
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Expr *BaseIvarExp;
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private:
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void Initialize(QualType Type, Qualifiers Quals, CharUnits Alignment,
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LValueBaseInfo BaseInfo, TBAAAccessInfo TBAAInfo) {
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assert((!Alignment.isZero() || Type->isIncompleteType()) &&
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"initializing l-value with zero alignment!");
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this->Type = Type;
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this->Quals = Quals;
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const unsigned MaxAlign = 1U << 31;
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this->Alignment = Alignment.getQuantity() <= MaxAlign
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? Alignment.getQuantity()
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: MaxAlign;
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assert(this->Alignment == Alignment.getQuantity() &&
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"Alignment exceeds allowed max!");
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this->BaseInfo = BaseInfo;
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this->TBAAInfo = TBAAInfo;
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// Initialize Objective-C flags.
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this->Ivar = this->ObjIsArray = this->NonGC = this->GlobalObjCRef = false;
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this->ImpreciseLifetime = false;
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this->Nontemporal = false;
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this->ThreadLocalRef = false;
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this->BaseIvarExp = nullptr;
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}
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public:
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bool isSimple() const { return LVType == Simple; }
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bool isVectorElt() const { return LVType == VectorElt; }
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bool isBitField() const { return LVType == BitField; }
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bool isExtVectorElt() const { return LVType == ExtVectorElt; }
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bool isGlobalReg() const { return LVType == GlobalReg; }
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bool isVolatileQualified() const { return Quals.hasVolatile(); }
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bool isRestrictQualified() const { return Quals.hasRestrict(); }
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unsigned getVRQualifiers() const {
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return Quals.getCVRQualifiers() & ~Qualifiers::Const;
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}
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QualType getType() const { return Type; }
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Qualifiers::ObjCLifetime getObjCLifetime() const {
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return Quals.getObjCLifetime();
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}
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bool isObjCIvar() const { return Ivar; }
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void setObjCIvar(bool Value) { Ivar = Value; }
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bool isObjCArray() const { return ObjIsArray; }
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void setObjCArray(bool Value) { ObjIsArray = Value; }
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bool isNonGC () const { return NonGC; }
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void setNonGC(bool Value) { NonGC = Value; }
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bool isGlobalObjCRef() const { return GlobalObjCRef; }
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void setGlobalObjCRef(bool Value) { GlobalObjCRef = Value; }
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bool isThreadLocalRef() const { return ThreadLocalRef; }
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void setThreadLocalRef(bool Value) { ThreadLocalRef = Value;}
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ARCPreciseLifetime_t isARCPreciseLifetime() const {
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return ARCPreciseLifetime_t(!ImpreciseLifetime);
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}
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void setARCPreciseLifetime(ARCPreciseLifetime_t value) {
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ImpreciseLifetime = (value == ARCImpreciseLifetime);
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}
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bool isNontemporal() const { return Nontemporal; }
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void setNontemporal(bool Value) { Nontemporal = Value; }
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bool isObjCWeak() const {
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return Quals.getObjCGCAttr() == Qualifiers::Weak;
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}
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bool isObjCStrong() const {
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return Quals.getObjCGCAttr() == Qualifiers::Strong;
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}
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bool isVolatile() const {
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return Quals.hasVolatile();
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}
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Expr *getBaseIvarExp() const { return BaseIvarExp; }
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void setBaseIvarExp(Expr *V) { BaseIvarExp = V; }
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TBAAAccessInfo getTBAAInfo() const { return TBAAInfo; }
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void setTBAAInfo(TBAAAccessInfo Info) { TBAAInfo = Info; }
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const Qualifiers &getQuals() const { return Quals; }
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Qualifiers &getQuals() { return Quals; }
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LangAS getAddressSpace() const { return Quals.getAddressSpace(); }
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CharUnits getAlignment() const { return CharUnits::fromQuantity(Alignment); }
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void setAlignment(CharUnits A) { Alignment = A.getQuantity(); }
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LValueBaseInfo getBaseInfo() const { return BaseInfo; }
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void setBaseInfo(LValueBaseInfo Info) { BaseInfo = Info; }
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// simple lvalue
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llvm::Value *getPointer(CodeGenFunction &CGF) const {
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assert(isSimple());
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return V;
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}
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Address getAddress(CodeGenFunction &CGF) const {
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return Address(getPointer(CGF), getAlignment());
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}
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void setAddress(Address address) {
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assert(isSimple());
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V = address.getPointer();
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Alignment = address.getAlignment().getQuantity();
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}
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// vector elt lvalue
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Address getVectorAddress() const {
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return Address(getVectorPointer(), getAlignment());
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}
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llvm::Value *getVectorPointer() const { assert(isVectorElt()); return V; }
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llvm::Value *getVectorIdx() const { assert(isVectorElt()); return VectorIdx; }
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// extended vector elements.
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Address getExtVectorAddress() const {
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return Address(getExtVectorPointer(), getAlignment());
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}
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llvm::Value *getExtVectorPointer() const {
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assert(isExtVectorElt());
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return V;
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}
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llvm::Constant *getExtVectorElts() const {
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assert(isExtVectorElt());
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return VectorElts;
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}
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// bitfield lvalue
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Address getBitFieldAddress() const {
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return Address(getBitFieldPointer(), getAlignment());
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}
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llvm::Value *getBitFieldPointer() const { assert(isBitField()); return V; }
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const CGBitFieldInfo &getBitFieldInfo() const {
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assert(isBitField());
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return *BitFieldInfo;
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}
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// global register lvalue
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llvm::Value *getGlobalReg() const { assert(isGlobalReg()); return V; }
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static LValue MakeAddr(Address address, QualType type, ASTContext &Context,
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LValueBaseInfo BaseInfo, TBAAAccessInfo TBAAInfo) {
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Qualifiers qs = type.getQualifiers();
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qs.setObjCGCAttr(Context.getObjCGCAttrKind(type));
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LValue R;
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R.LVType = Simple;
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assert(address.getPointer()->getType()->isPointerTy());
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R.V = address.getPointer();
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R.Initialize(type, qs, address.getAlignment(), BaseInfo, TBAAInfo);
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return R;
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}
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static LValue MakeVectorElt(Address vecAddress, llvm::Value *Idx,
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QualType type, LValueBaseInfo BaseInfo,
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TBAAAccessInfo TBAAInfo) {
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LValue R;
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R.LVType = VectorElt;
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R.V = vecAddress.getPointer();
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R.VectorIdx = Idx;
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R.Initialize(type, type.getQualifiers(), vecAddress.getAlignment(),
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BaseInfo, TBAAInfo);
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return R;
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}
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static LValue MakeExtVectorElt(Address vecAddress, llvm::Constant *Elts,
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QualType type, LValueBaseInfo BaseInfo,
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TBAAAccessInfo TBAAInfo) {
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LValue R;
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R.LVType = ExtVectorElt;
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R.V = vecAddress.getPointer();
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R.VectorElts = Elts;
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R.Initialize(type, type.getQualifiers(), vecAddress.getAlignment(),
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BaseInfo, TBAAInfo);
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return R;
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}
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/// Create a new object to represent a bit-field access.
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///
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/// \param Addr - The base address of the bit-field sequence this
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/// bit-field refers to.
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/// \param Info - The information describing how to perform the bit-field
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/// access.
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static LValue MakeBitfield(Address Addr, const CGBitFieldInfo &Info,
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QualType type, LValueBaseInfo BaseInfo,
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TBAAAccessInfo TBAAInfo) {
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LValue R;
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R.LVType = BitField;
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R.V = Addr.getPointer();
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R.BitFieldInfo = &Info;
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R.Initialize(type, type.getQualifiers(), Addr.getAlignment(), BaseInfo,
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TBAAInfo);
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return R;
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}
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static LValue MakeGlobalReg(Address Reg, QualType type) {
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LValue R;
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R.LVType = GlobalReg;
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R.V = Reg.getPointer();
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R.Initialize(type, type.getQualifiers(), Reg.getAlignment(),
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LValueBaseInfo(AlignmentSource::Decl), TBAAAccessInfo());
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return R;
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}
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RValue asAggregateRValue(CodeGenFunction &CGF) const {
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return RValue::getAggregate(getAddress(CGF), isVolatileQualified());
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}
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};
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/// An aggregate value slot.
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class AggValueSlot {
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/// The address.
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llvm::Value *Addr;
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// Qualifiers
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Qualifiers Quals;
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unsigned Alignment;
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/// DestructedFlag - This is set to true if some external code is
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/// responsible for setting up a destructor for the slot. Otherwise
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/// the code which constructs it should push the appropriate cleanup.
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bool DestructedFlag : 1;
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/// ObjCGCFlag - This is set to true if writing to the memory in the
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/// slot might require calling an appropriate Objective-C GC
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/// barrier. The exact interaction here is unnecessarily mysterious.
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bool ObjCGCFlag : 1;
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/// ZeroedFlag - This is set to true if the memory in the slot is
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/// known to be zero before the assignment into it. This means that
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/// zero fields don't need to be set.
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bool ZeroedFlag : 1;
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/// AliasedFlag - This is set to true if the slot might be aliased
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/// and it's not undefined behavior to access it through such an
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/// alias. Note that it's always undefined behavior to access a C++
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/// object that's under construction through an alias derived from
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/// outside the construction process.
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///
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/// This flag controls whether calls that produce the aggregate
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/// value may be evaluated directly into the slot, or whether they
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/// must be evaluated into an unaliased temporary and then memcpy'ed
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/// over. Since it's invalid in general to memcpy a non-POD C++
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/// object, it's important that this flag never be set when
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/// evaluating an expression which constructs such an object.
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bool AliasedFlag : 1;
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/// This is set to true if the tail padding of this slot might overlap
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/// another object that may have already been initialized (and whose
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/// value must be preserved by this initialization). If so, we may only
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/// store up to the dsize of the type. Otherwise we can widen stores to
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/// the size of the type.
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bool OverlapFlag : 1;
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/// If is set to true, sanitizer checks are already generated for this address
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/// or not required. For instance, if this address represents an object
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/// created in 'new' expression, sanitizer checks for memory is made as a part
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/// of 'operator new' emission and object constructor should not generate
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/// them.
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bool SanitizerCheckedFlag : 1;
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public:
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enum IsAliased_t { IsNotAliased, IsAliased };
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enum IsDestructed_t { IsNotDestructed, IsDestructed };
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enum IsZeroed_t { IsNotZeroed, IsZeroed };
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enum Overlap_t { DoesNotOverlap, MayOverlap };
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enum NeedsGCBarriers_t { DoesNotNeedGCBarriers, NeedsGCBarriers };
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enum IsSanitizerChecked_t { IsNotSanitizerChecked, IsSanitizerChecked };
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/// ignored - Returns an aggregate value slot indicating that the
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/// aggregate value is being ignored.
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static AggValueSlot ignored() {
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return forAddr(Address::invalid(), Qualifiers(), IsNotDestructed,
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DoesNotNeedGCBarriers, IsNotAliased, DoesNotOverlap);
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}
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|
|
|
/// forAddr - Make a slot for an aggregate value.
|
|
///
|
|
/// \param quals - The qualifiers that dictate how the slot should
|
|
/// be initialied. Only 'volatile' and the Objective-C lifetime
|
|
/// qualifiers matter.
|
|
///
|
|
/// \param isDestructed - true if something else is responsible
|
|
/// for calling destructors on this object
|
|
/// \param needsGC - true if the slot is potentially located
|
|
/// somewhere that ObjC GC calls should be emitted for
|
|
static AggValueSlot forAddr(Address addr,
|
|
Qualifiers quals,
|
|
IsDestructed_t isDestructed,
|
|
NeedsGCBarriers_t needsGC,
|
|
IsAliased_t isAliased,
|
|
Overlap_t mayOverlap,
|
|
IsZeroed_t isZeroed = IsNotZeroed,
|
|
IsSanitizerChecked_t isChecked = IsNotSanitizerChecked) {
|
|
AggValueSlot AV;
|
|
if (addr.isValid()) {
|
|
AV.Addr = addr.getPointer();
|
|
AV.Alignment = addr.getAlignment().getQuantity();
|
|
} else {
|
|
AV.Addr = nullptr;
|
|
AV.Alignment = 0;
|
|
}
|
|
AV.Quals = quals;
|
|
AV.DestructedFlag = isDestructed;
|
|
AV.ObjCGCFlag = needsGC;
|
|
AV.ZeroedFlag = isZeroed;
|
|
AV.AliasedFlag = isAliased;
|
|
AV.OverlapFlag = mayOverlap;
|
|
AV.SanitizerCheckedFlag = isChecked;
|
|
return AV;
|
|
}
|
|
|
|
static AggValueSlot
|
|
forLValue(const LValue &LV, CodeGenFunction &CGF, IsDestructed_t isDestructed,
|
|
NeedsGCBarriers_t needsGC, IsAliased_t isAliased,
|
|
Overlap_t mayOverlap, IsZeroed_t isZeroed = IsNotZeroed,
|
|
IsSanitizerChecked_t isChecked = IsNotSanitizerChecked) {
|
|
return forAddr(LV.getAddress(CGF), LV.getQuals(), isDestructed, needsGC,
|
|
isAliased, mayOverlap, isZeroed, isChecked);
|
|
}
|
|
|
|
IsDestructed_t isExternallyDestructed() const {
|
|
return IsDestructed_t(DestructedFlag);
|
|
}
|
|
void setExternallyDestructed(bool destructed = true) {
|
|
DestructedFlag = destructed;
|
|
}
|
|
|
|
Qualifiers getQualifiers() const { return Quals; }
|
|
|
|
bool isVolatile() const {
|
|
return Quals.hasVolatile();
|
|
}
|
|
|
|
void setVolatile(bool flag) {
|
|
if (flag)
|
|
Quals.addVolatile();
|
|
else
|
|
Quals.removeVolatile();
|
|
}
|
|
|
|
Qualifiers::ObjCLifetime getObjCLifetime() const {
|
|
return Quals.getObjCLifetime();
|
|
}
|
|
|
|
NeedsGCBarriers_t requiresGCollection() const {
|
|
return NeedsGCBarriers_t(ObjCGCFlag);
|
|
}
|
|
|
|
llvm::Value *getPointer() const {
|
|
return Addr;
|
|
}
|
|
|
|
Address getAddress() const {
|
|
return Address(Addr, getAlignment());
|
|
}
|
|
|
|
bool isIgnored() const {
|
|
return Addr == nullptr;
|
|
}
|
|
|
|
CharUnits getAlignment() const {
|
|
return CharUnits::fromQuantity(Alignment);
|
|
}
|
|
|
|
IsAliased_t isPotentiallyAliased() const {
|
|
return IsAliased_t(AliasedFlag);
|
|
}
|
|
|
|
Overlap_t mayOverlap() const {
|
|
return Overlap_t(OverlapFlag);
|
|
}
|
|
|
|
bool isSanitizerChecked() const {
|
|
return SanitizerCheckedFlag;
|
|
}
|
|
|
|
RValue asRValue() const {
|
|
if (isIgnored()) {
|
|
return RValue::getIgnored();
|
|
} else {
|
|
return RValue::getAggregate(getAddress(), isVolatile());
|
|
}
|
|
}
|
|
|
|
void setZeroed(bool V = true) { ZeroedFlag = V; }
|
|
IsZeroed_t isZeroed() const {
|
|
return IsZeroed_t(ZeroedFlag);
|
|
}
|
|
|
|
/// Get the preferred size to use when storing a value to this slot. This
|
|
/// is the type size unless that might overlap another object, in which
|
|
/// case it's the dsize.
|
|
CharUnits getPreferredSize(ASTContext &Ctx, QualType Type) const {
|
|
return mayOverlap() ? Ctx.getTypeInfoDataSizeInChars(Type).first
|
|
: Ctx.getTypeSizeInChars(Type);
|
|
}
|
|
};
|
|
|
|
} // end namespace CodeGen
|
|
} // end namespace clang
|
|
|
|
#endif
|