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#pragma once
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#endif
//==-- CGFunctionInfo.h - Representation of function argument/return types -==//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// Defines CGFunctionInfo and associated types used in representing the
// LLVM source types and ABI-coerced types for function arguments and
// return values.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_CODEGEN_CGFUNCTIONINFO_H
#define LLVM_CLANG_CODEGEN_CGFUNCTIONINFO_H
#include "clang/AST/CanonicalType.h"
#include "clang/AST/CharUnits.h"
#include "clang/AST/Decl.h"
#include "clang/AST/Type.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/ADT/FoldingSet.h"
#include "llvm/Support/TrailingObjects.h"
#include <cassert>
namespace clang {
namespace CodeGen {
/// ABIArgInfo - Helper class to encapsulate information about how a
/// specific C type should be passed to or returned from a function.
class ABIArgInfo {
public:
enum Kind : uint8_t {
/// Direct - Pass the argument directly using the normal converted LLVM
/// type, or by coercing to another specified type stored in
/// 'CoerceToType'). If an offset is specified (in UIntData), then the
/// argument passed is offset by some number of bytes in the memory
/// representation. A dummy argument is emitted before the real argument
/// if the specified type stored in "PaddingType" is not zero.
Direct,
/// Extend - Valid only for integer argument types. Same as 'direct'
/// but also emit a zero/sign extension attribute.
Extend,
/// Indirect - Pass the argument indirectly via a hidden pointer with the
/// specified alignment (0 indicates default alignment) and address space.
Indirect,
/// IndirectAliased - Similar to Indirect, but the pointer may be to an
/// object that is otherwise referenced. The object is known to not be
/// modified through any other references for the duration of the call, and
/// the callee must not itself modify the object. Because C allows
/// parameter variables to be modified and guarantees that they have unique
/// addresses, the callee must defensively copy the object into a local
/// variable if it might be modified or its address might be compared.
/// Since those are uncommon, in principle this convention allows programs
/// to avoid copies in more situations. However, it may introduce *extra*
/// copies if the callee fails to prove that a copy is unnecessary and the
/// caller naturally produces an unaliased object for the argument.
IndirectAliased,
/// Ignore - Ignore the argument (treat as void). Useful for void and
/// empty structs.
Ignore,
/// Expand - Only valid for aggregate argument types. The structure should
/// be expanded into consecutive arguments for its constituent fields.
/// Currently expand is only allowed on structures whose fields
/// are all scalar types or are themselves expandable types.
Expand,
/// CoerceAndExpand - Only valid for aggregate argument types. The
/// structure should be expanded into consecutive arguments corresponding
/// to the non-array elements of the type stored in CoerceToType.
/// Array elements in the type are assumed to be padding and skipped.
CoerceAndExpand,
/// InAlloca - Pass the argument directly using the LLVM inalloca attribute.
/// This is similar to indirect with byval, except it only applies to
/// arguments stored in memory and forbids any implicit copies. When
/// applied to a return type, it means the value is returned indirectly via
/// an implicit sret parameter stored in the argument struct.
InAlloca,
KindFirst = Direct,
KindLast = InAlloca
};
private:
llvm::Type *TypeData; // canHaveCoerceToType()
union {
llvm::Type *PaddingType; // canHavePaddingType()
llvm::Type *UnpaddedCoerceAndExpandType; // isCoerceAndExpand()
};
struct DirectAttrInfo {
unsigned Offset;
unsigned Align;
};
struct IndirectAttrInfo {
unsigned Align;
unsigned AddrSpace;
};
union {
DirectAttrInfo DirectAttr; // isDirect() || isExtend()
IndirectAttrInfo IndirectAttr; // isIndirect()
unsigned AllocaFieldIndex; // isInAlloca()
};
Kind TheKind;
bool PaddingInReg : 1;
bool InAllocaSRet : 1; // isInAlloca()
bool InAllocaIndirect : 1;// isInAlloca()
bool IndirectByVal : 1; // isIndirect()
bool IndirectRealign : 1; // isIndirect()
bool SRetAfterThis : 1; // isIndirect()
bool InReg : 1; // isDirect() || isExtend() || isIndirect()
bool CanBeFlattened: 1; // isDirect()
bool SignExt : 1; // isExtend()
bool canHavePaddingType() const {
return isDirect() || isExtend() || isIndirect() || isIndirectAliased() ||
isExpand();
}
void setPaddingType(llvm::Type *T) {
assert(canHavePaddingType());
PaddingType = T;
}
void setUnpaddedCoerceToType(llvm::Type *T) {
assert(isCoerceAndExpand());
UnpaddedCoerceAndExpandType = T;
}
public:
ABIArgInfo(Kind K = Direct)
: TypeData(nullptr), PaddingType(nullptr), DirectAttr{0, 0}, TheKind(K),
PaddingInReg(false), InAllocaSRet(false),
InAllocaIndirect(false), IndirectByVal(false), IndirectRealign(false),
SRetAfterThis(false), InReg(false), CanBeFlattened(false),
SignExt(false) {}
static ABIArgInfo getDirect(llvm::Type *T = nullptr, unsigned Offset = 0,
llvm::Type *Padding = nullptr,
bool CanBeFlattened = true, unsigned Align = 0) {
auto AI = ABIArgInfo(Direct);
AI.setCoerceToType(T);
AI.setPaddingType(Padding);
AI.setDirectOffset(Offset);
AI.setDirectAlign(Align);
AI.setCanBeFlattened(CanBeFlattened);
return AI;
}
static ABIArgInfo getDirectInReg(llvm::Type *T = nullptr) {
auto AI = getDirect(T);
AI.setInReg(true);
return AI;
}
static ABIArgInfo getSignExtend(QualType Ty, llvm::Type *T = nullptr) {
assert(Ty->isIntegralOrEnumerationType() && "Unexpected QualType");
auto AI = ABIArgInfo(Extend);
AI.setCoerceToType(T);
AI.setPaddingType(nullptr);
AI.setDirectOffset(0);
AI.setDirectAlign(0);
AI.setSignExt(true);
return AI;
}
static ABIArgInfo getZeroExtend(QualType Ty, llvm::Type *T = nullptr) {
assert(Ty->isIntegralOrEnumerationType() && "Unexpected QualType");
auto AI = ABIArgInfo(Extend);
AI.setCoerceToType(T);
AI.setPaddingType(nullptr);
AI.setDirectOffset(0);
AI.setDirectAlign(0);
AI.setSignExt(false);
return AI;
}
// ABIArgInfo will record the argument as being extended based on the sign
// of its type.
static ABIArgInfo getExtend(QualType Ty, llvm::Type *T = nullptr) {
assert(Ty->isIntegralOrEnumerationType() && "Unexpected QualType");
if (Ty->hasSignedIntegerRepresentation())
return getSignExtend(Ty, T);
return getZeroExtend(Ty, T);
}
static ABIArgInfo getExtendInReg(QualType Ty, llvm::Type *T = nullptr) {
auto AI = getExtend(Ty, T);
AI.setInReg(true);
return AI;
}
static ABIArgInfo getIgnore() {
return ABIArgInfo(Ignore);
}
static ABIArgInfo getIndirect(CharUnits Alignment, bool ByVal = true,
bool Realign = false,
llvm::Type *Padding = nullptr) {
auto AI = ABIArgInfo(Indirect);
AI.setIndirectAlign(Alignment);
AI.setIndirectByVal(ByVal);
AI.setIndirectRealign(Realign);
AI.setSRetAfterThis(false);
AI.setPaddingType(Padding);
return AI;
}
/// Pass this in memory using the IR byref attribute.
static ABIArgInfo getIndirectAliased(CharUnits Alignment, unsigned AddrSpace,
bool Realign = false,
llvm::Type *Padding = nullptr) {
auto AI = ABIArgInfo(IndirectAliased);
AI.setIndirectAlign(Alignment);
AI.setIndirectRealign(Realign);
AI.setPaddingType(Padding);
AI.setIndirectAddrSpace(AddrSpace);
return AI;
}
static ABIArgInfo getIndirectInReg(CharUnits Alignment, bool ByVal = true,
bool Realign = false) {
auto AI = getIndirect(Alignment, ByVal, Realign);
AI.setInReg(true);
return AI;
}
static ABIArgInfo getInAlloca(unsigned FieldIndex, bool Indirect = false) {
auto AI = ABIArgInfo(InAlloca);
AI.setInAllocaFieldIndex(FieldIndex);
AI.setInAllocaIndirect(Indirect);
return AI;
}
static ABIArgInfo getExpand() {
auto AI = ABIArgInfo(Expand);
AI.setPaddingType(nullptr);
return AI;
}
static ABIArgInfo getExpandWithPadding(bool PaddingInReg,
llvm::Type *Padding) {
auto AI = getExpand();
AI.setPaddingInReg(PaddingInReg);
AI.setPaddingType(Padding);
return AI;
}
/// \param unpaddedCoerceToType The coerce-to type with padding elements
/// removed, canonicalized to a single element if it would otherwise
/// have exactly one element.
static ABIArgInfo getCoerceAndExpand(llvm::StructType *coerceToType,
llvm::Type *unpaddedCoerceToType) {
#ifndef NDEBUG
// Check that unpaddedCoerceToType has roughly the right shape.
// Assert that we only have a struct type if there are multiple elements.
auto unpaddedStruct = dyn_cast<llvm::StructType>(unpaddedCoerceToType);
assert(!unpaddedStruct || unpaddedStruct->getNumElements() != 1);
// Assert that all the non-padding elements have a corresponding element
// in the unpadded type.
unsigned unpaddedIndex = 0;
for (auto eltType : coerceToType->elements()) {
if (isPaddingForCoerceAndExpand(eltType)) continue;
if (unpaddedStruct) {
assert(unpaddedStruct->getElementType(unpaddedIndex) == eltType);
} else {
assert(unpaddedIndex == 0 && unpaddedCoerceToType == eltType);
}
unpaddedIndex++;
}
// Assert that there aren't extra elements in the unpadded type.
if (unpaddedStruct) {
assert(unpaddedStruct->getNumElements() == unpaddedIndex);
} else {
assert(unpaddedIndex == 1);
}
#endif
auto AI = ABIArgInfo(CoerceAndExpand);
AI.setCoerceToType(coerceToType);
AI.setUnpaddedCoerceToType(unpaddedCoerceToType);
return AI;
}
static bool isPaddingForCoerceAndExpand(llvm::Type *eltType) {
if (eltType->isArrayTy()) {
assert(eltType->getArrayElementType()->isIntegerTy(8));
return true;
} else {
return false;
}
}
Kind getKind() const { return TheKind; }
bool isDirect() const { return TheKind == Direct; }
bool isInAlloca() const { return TheKind == InAlloca; }
bool isExtend() const { return TheKind == Extend; }
bool isIgnore() const { return TheKind == Ignore; }
bool isIndirect() const { return TheKind == Indirect; }
bool isIndirectAliased() const { return TheKind == IndirectAliased; }
bool isExpand() const { return TheKind == Expand; }
bool isCoerceAndExpand() const { return TheKind == CoerceAndExpand; }
bool canHaveCoerceToType() const {
return isDirect() || isExtend() || isCoerceAndExpand();
}
// Direct/Extend accessors
unsigned getDirectOffset() const {
assert((isDirect() || isExtend()) && "Not a direct or extend kind");
return DirectAttr.Offset;
}
void setDirectOffset(unsigned Offset) {
assert((isDirect() || isExtend()) && "Not a direct or extend kind");
DirectAttr.Offset = Offset;
}
unsigned getDirectAlign() const {
assert((isDirect() || isExtend()) && "Not a direct or extend kind");
return DirectAttr.Align;
}
void setDirectAlign(unsigned Align) {
assert((isDirect() || isExtend()) && "Not a direct or extend kind");
DirectAttr.Align = Align;
}
bool isSignExt() const {
assert(isExtend() && "Invalid kind!");
return SignExt;
}
void setSignExt(bool SExt) {
assert(isExtend() && "Invalid kind!");
SignExt = SExt;
}
llvm::Type *getPaddingType() const {
return (canHavePaddingType() ? PaddingType : nullptr);
}
bool getPaddingInReg() const {
return PaddingInReg;
}
void setPaddingInReg(bool PIR) {
PaddingInReg = PIR;
}
llvm::Type *getCoerceToType() const {
assert(canHaveCoerceToType() && "Invalid kind!");
return TypeData;
}
void setCoerceToType(llvm::Type *T) {
assert(canHaveCoerceToType() && "Invalid kind!");
TypeData = T;
}
llvm::StructType *getCoerceAndExpandType() const {
assert(isCoerceAndExpand());
return cast<llvm::StructType>(TypeData);
}
llvm::Type *getUnpaddedCoerceAndExpandType() const {
assert(isCoerceAndExpand());
return UnpaddedCoerceAndExpandType;
}
ArrayRef<llvm::Type *>getCoerceAndExpandTypeSequence() const {
assert(isCoerceAndExpand());
if (auto structTy =
dyn_cast<llvm::StructType>(UnpaddedCoerceAndExpandType)) {
return structTy->elements();
} else {
return llvm::ArrayRef(&UnpaddedCoerceAndExpandType, 1);
}
}
bool getInReg() const {
assert((isDirect() || isExtend() || isIndirect()) && "Invalid kind!");
return InReg;
}
void setInReg(bool IR) {
assert((isDirect() || isExtend() || isIndirect()) && "Invalid kind!");
InReg = IR;
}
// Indirect accessors
CharUnits getIndirectAlign() const {
assert((isIndirect() || isIndirectAliased()) && "Invalid kind!");
return CharUnits::fromQuantity(IndirectAttr.Align);
}
void setIndirectAlign(CharUnits IA) {
assert((isIndirect() || isIndirectAliased()) && "Invalid kind!");
IndirectAttr.Align = IA.getQuantity();
}
bool getIndirectByVal() const {
assert(isIndirect() && "Invalid kind!");
return IndirectByVal;
}
void setIndirectByVal(bool IBV) {
assert(isIndirect() && "Invalid kind!");
IndirectByVal = IBV;
}
unsigned getIndirectAddrSpace() const {
assert(isIndirectAliased() && "Invalid kind!");
return IndirectAttr.AddrSpace;
}
void setIndirectAddrSpace(unsigned AddrSpace) {
assert(isIndirectAliased() && "Invalid kind!");
IndirectAttr.AddrSpace = AddrSpace;
}
bool getIndirectRealign() const {
assert((isIndirect() || isIndirectAliased()) && "Invalid kind!");
return IndirectRealign;
}
void setIndirectRealign(bool IR) {
assert((isIndirect() || isIndirectAliased()) && "Invalid kind!");
IndirectRealign = IR;
}
bool isSRetAfterThis() const {
assert(isIndirect() && "Invalid kind!");
return SRetAfterThis;
}
void setSRetAfterThis(bool AfterThis) {
assert(isIndirect() && "Invalid kind!");
SRetAfterThis = AfterThis;
}
unsigned getInAllocaFieldIndex() const {
assert(isInAlloca() && "Invalid kind!");
return AllocaFieldIndex;
}
void setInAllocaFieldIndex(unsigned FieldIndex) {
assert(isInAlloca() && "Invalid kind!");
AllocaFieldIndex = FieldIndex;
}
unsigned getInAllocaIndirect() const {
assert(isInAlloca() && "Invalid kind!");
return InAllocaIndirect;
}
void setInAllocaIndirect(bool Indirect) {
assert(isInAlloca() && "Invalid kind!");
InAllocaIndirect = Indirect;
}
/// Return true if this field of an inalloca struct should be returned
/// to implement a struct return calling convention.
bool getInAllocaSRet() const {
assert(isInAlloca() && "Invalid kind!");
return InAllocaSRet;
}
void setInAllocaSRet(bool SRet) {
assert(isInAlloca() && "Invalid kind!");
InAllocaSRet = SRet;
}
bool getCanBeFlattened() const {
assert(isDirect() && "Invalid kind!");
return CanBeFlattened;
}
void setCanBeFlattened(bool Flatten) {
assert(isDirect() && "Invalid kind!");
CanBeFlattened = Flatten;
}
void dump() const;
};
/// A class for recording the number of arguments that a function
/// signature requires.
class RequiredArgs {
/// The number of required arguments, or ~0 if the signature does
/// not permit optional arguments.
unsigned NumRequired;
public:
enum All_t { All };
RequiredArgs(All_t _) : NumRequired(~0U) {}
explicit RequiredArgs(unsigned n) : NumRequired(n) {
assert(n != ~0U);
}
/// Compute the arguments required by the given formal prototype,
/// given that there may be some additional, non-formal arguments
/// in play.
///
/// If FD is not null, this will consider pass_object_size params in FD.
static RequiredArgs forPrototypePlus(const FunctionProtoType *prototype,
unsigned additional) {
if (!prototype->isVariadic()) return All;
if (prototype->hasExtParameterInfos())
additional += llvm::count_if(
prototype->getExtParameterInfos(),
[](const FunctionProtoType::ExtParameterInfo &ExtInfo) {
return ExtInfo.hasPassObjectSize();
});
return RequiredArgs(prototype->getNumParams() + additional);
}
static RequiredArgs forPrototypePlus(CanQual<FunctionProtoType> prototype,
unsigned additional) {
return forPrototypePlus(prototype.getTypePtr(), additional);
}
static RequiredArgs forPrototype(const FunctionProtoType *prototype) {
return forPrototypePlus(prototype, 0);
}
static RequiredArgs forPrototype(CanQual<FunctionProtoType> prototype) {
return forPrototypePlus(prototype.getTypePtr(), 0);
}
bool allowsOptionalArgs() const { return NumRequired != ~0U; }
unsigned getNumRequiredArgs() const {
assert(allowsOptionalArgs());
return NumRequired;
}
unsigned getOpaqueData() const { return NumRequired; }
static RequiredArgs getFromOpaqueData(unsigned value) {
if (value == ~0U) return All;
return RequiredArgs(value);
}
};
// Implementation detail of CGFunctionInfo, factored out so it can be named
// in the TrailingObjects base class of CGFunctionInfo.
struct CGFunctionInfoArgInfo {
CanQualType type;
ABIArgInfo info;
};
/// CGFunctionInfo - Class to encapsulate the information about a
/// function definition.
class CGFunctionInfo final
: public llvm::FoldingSetNode,
private llvm::TrailingObjects<CGFunctionInfo, CGFunctionInfoArgInfo,
FunctionProtoType::ExtParameterInfo> {
typedef CGFunctionInfoArgInfo ArgInfo;
typedef FunctionProtoType::ExtParameterInfo ExtParameterInfo;
/// The LLVM::CallingConv to use for this function (as specified by the
/// user).
unsigned CallingConvention : 8;
/// The LLVM::CallingConv to actually use for this function, which may
/// depend on the ABI.
unsigned EffectiveCallingConvention : 8;
/// The clang::CallingConv that this was originally created with.
unsigned ASTCallingConvention : 6;
/// Whether this is an instance method.
unsigned InstanceMethod : 1;
/// Whether this is a chain call.
unsigned ChainCall : 1;
/// Whether this function is a CMSE nonsecure call
unsigned CmseNSCall : 1;
/// Whether this function is noreturn.
unsigned NoReturn : 1;
/// Whether this function is returns-retained.
unsigned ReturnsRetained : 1;
/// Whether this function saved caller registers.
unsigned NoCallerSavedRegs : 1;
/// How many arguments to pass inreg.
unsigned HasRegParm : 1;
unsigned RegParm : 3;
/// Whether this function has nocf_check attribute.
unsigned NoCfCheck : 1;
/// Log 2 of the maximum vector width.
unsigned MaxVectorWidth : 4;
RequiredArgs Required;
/// The struct representing all arguments passed in memory. Only used when
/// passing non-trivial types with inalloca. Not part of the profile.
llvm::StructType *ArgStruct;
unsigned ArgStructAlign : 31;
unsigned HasExtParameterInfos : 1;
unsigned NumArgs;
ArgInfo *getArgsBuffer() {
return getTrailingObjects<ArgInfo>();
}
const ArgInfo *getArgsBuffer() const {
return getTrailingObjects<ArgInfo>();
}
ExtParameterInfo *getExtParameterInfosBuffer() {
return getTrailingObjects<ExtParameterInfo>();
}
const ExtParameterInfo *getExtParameterInfosBuffer() const{
return getTrailingObjects<ExtParameterInfo>();
}
CGFunctionInfo() : Required(RequiredArgs::All) {}
public:
static CGFunctionInfo *create(unsigned llvmCC,
bool instanceMethod,
bool chainCall,
const FunctionType::ExtInfo &extInfo,
ArrayRef<ExtParameterInfo> paramInfos,
CanQualType resultType,
ArrayRef<CanQualType> argTypes,
RequiredArgs required);
void operator delete(void *p) { ::operator delete(p); }
// Friending class TrailingObjects is apparently not good enough for MSVC,
// so these have to be public.
friend class TrailingObjects;
size_t numTrailingObjects(OverloadToken<ArgInfo>) const {
return NumArgs + 1;
}
size_t numTrailingObjects(OverloadToken<ExtParameterInfo>) const {
return (HasExtParameterInfos ? NumArgs : 0);
}
typedef const ArgInfo *const_arg_iterator;
typedef ArgInfo *arg_iterator;
MutableArrayRef<ArgInfo> arguments() {
return MutableArrayRef<ArgInfo>(arg_begin(), NumArgs);
}
ArrayRef<ArgInfo> arguments() const {
return ArrayRef<ArgInfo>(arg_begin(), NumArgs);
}
const_arg_iterator arg_begin() const { return getArgsBuffer() + 1; }
const_arg_iterator arg_end() const { return getArgsBuffer() + 1 + NumArgs; }
arg_iterator arg_begin() { return getArgsBuffer() + 1; }
arg_iterator arg_end() { return getArgsBuffer() + 1 + NumArgs; }
unsigned arg_size() const { return NumArgs; }
bool isVariadic() const { return Required.allowsOptionalArgs(); }
RequiredArgs getRequiredArgs() const { return Required; }
unsigned getNumRequiredArgs() const {
return isVariadic() ? getRequiredArgs().getNumRequiredArgs() : arg_size();
}
bool isInstanceMethod() const { return InstanceMethod; }
bool isChainCall() const { return ChainCall; }
bool isCmseNSCall() const { return CmseNSCall; }
bool isNoReturn() const { return NoReturn; }
/// In ARC, whether this function retains its return value. This
/// is not always reliable for call sites.
bool isReturnsRetained() const { return ReturnsRetained; }
/// Whether this function no longer saves caller registers.
bool isNoCallerSavedRegs() const { return NoCallerSavedRegs; }
/// Whether this function has nocf_check attribute.
bool isNoCfCheck() const { return NoCfCheck; }
/// getASTCallingConvention() - Return the AST-specified calling
/// convention.
CallingConv getASTCallingConvention() const {
return CallingConv(ASTCallingConvention);
}
/// getCallingConvention - Return the user specified calling
/// convention, which has been translated into an LLVM CC.
unsigned getCallingConvention() const { return CallingConvention; }
/// getEffectiveCallingConvention - Return the actual calling convention to
/// use, which may depend on the ABI.
unsigned getEffectiveCallingConvention() const {
return EffectiveCallingConvention;
}
void setEffectiveCallingConvention(unsigned Value) {
EffectiveCallingConvention = Value;
}
bool getHasRegParm() const { return HasRegParm; }
unsigned getRegParm() const { return RegParm; }
FunctionType::ExtInfo getExtInfo() const {
return FunctionType::ExtInfo(isNoReturn(), getHasRegParm(), getRegParm(),
getASTCallingConvention(), isReturnsRetained(),
isNoCallerSavedRegs(), isNoCfCheck(),
isCmseNSCall());
}
CanQualType getReturnType() const { return getArgsBuffer()[0].type; }
ABIArgInfo &getReturnInfo() { return getArgsBuffer()[0].info; }
const ABIArgInfo &getReturnInfo() const { return getArgsBuffer()[0].info; }
ArrayRef<ExtParameterInfo> getExtParameterInfos() const {
if (!HasExtParameterInfos) return {};
return llvm::ArrayRef(getExtParameterInfosBuffer(), NumArgs);
}
ExtParameterInfo getExtParameterInfo(unsigned argIndex) const {
assert(argIndex <= NumArgs);
if (!HasExtParameterInfos) return ExtParameterInfo();
return getExtParameterInfos()[argIndex];
}
/// Return true if this function uses inalloca arguments.
bool usesInAlloca() const { return ArgStruct; }
/// Get the struct type used to represent all the arguments in memory.
llvm::StructType *getArgStruct() const { return ArgStruct; }
CharUnits getArgStructAlignment() const {
return CharUnits::fromQuantity(ArgStructAlign);
}
void setArgStruct(llvm::StructType *Ty, CharUnits Align) {
ArgStruct = Ty;
ArgStructAlign = Align.getQuantity();
}
/// Return the maximum vector width in the arguments.
unsigned getMaxVectorWidth() const {
return MaxVectorWidth ? 1U << (MaxVectorWidth - 1) : 0;
}
/// Set the maximum vector width in the arguments.
void setMaxVectorWidth(unsigned Width) {
assert(llvm::isPowerOf2_32(Width) && "Expected power of 2 vector");
MaxVectorWidth = llvm::countTrailingZeros(Width) + 1;
}
void Profile(llvm::FoldingSetNodeID &ID) {
ID.AddInteger(getASTCallingConvention());
ID.AddBoolean(InstanceMethod);
ID.AddBoolean(ChainCall);
ID.AddBoolean(NoReturn);
ID.AddBoolean(ReturnsRetained);
ID.AddBoolean(NoCallerSavedRegs);
ID.AddBoolean(HasRegParm);
ID.AddInteger(RegParm);
ID.AddBoolean(NoCfCheck);
ID.AddBoolean(CmseNSCall);
ID.AddInteger(Required.getOpaqueData());
ID.AddBoolean(HasExtParameterInfos);
if (HasExtParameterInfos) {
for (auto paramInfo : getExtParameterInfos())
ID.AddInteger(paramInfo.getOpaqueValue());
}
getReturnType().Profile(ID);
for (const auto &I : arguments())
I.type.Profile(ID);
}
static void Profile(llvm::FoldingSetNodeID &ID,
bool InstanceMethod,
bool ChainCall,
const FunctionType::ExtInfo &info,
ArrayRef<ExtParameterInfo> paramInfos,
RequiredArgs required,
CanQualType resultType,
ArrayRef<CanQualType> argTypes) {
ID.AddInteger(info.getCC());
ID.AddBoolean(InstanceMethod);
ID.AddBoolean(ChainCall);
ID.AddBoolean(info.getNoReturn());
ID.AddBoolean(info.getProducesResult());
ID.AddBoolean(info.getNoCallerSavedRegs());
ID.AddBoolean(info.getHasRegParm());
ID.AddInteger(info.getRegParm());
ID.AddBoolean(info.getNoCfCheck());
ID.AddBoolean(info.getCmseNSCall());
ID.AddInteger(required.getOpaqueData());
ID.AddBoolean(!paramInfos.empty());
if (!paramInfos.empty()) {
for (auto paramInfo : paramInfos)
ID.AddInteger(paramInfo.getOpaqueValue());
}
resultType.Profile(ID);
for (ArrayRef<CanQualType>::iterator
i = argTypes.begin(), e = argTypes.end(); i != e; ++i) {
i->Profile(ID);
}
}
};
} // end namespace CodeGen
} // end namespace clang
#endif
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif
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