llvm-project/clang/lib/CodeGen/TargetInfo.cpp

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//===---- TargetInfo.cpp - Encapsulate target details -----------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// These classes wrap the information about a call or function
// definition used to handle ABI compliancy.
//
//===----------------------------------------------------------------------===//
#include "TargetInfo.h"
#include "ABIInfo.h"
#include "CGCXXABI.h"
#include "CodeGenFunction.h"
2009-07-19 03:43:29 +08:00
#include "clang/AST/RecordLayout.h"
#include "clang/CodeGen/CGFunctionInfo.h"
#include "clang/Frontend/CodeGenOptions.h"
#include "llvm/ADT/Triple.h"
#include "llvm/IR/DataLayout.h"
#include "llvm/IR/Type.h"
#include "llvm/Support/raw_ostream.h"
using namespace clang;
using namespace CodeGen;
static void AssignToArrayRange(CodeGen::CGBuilderTy &Builder,
llvm::Value *Array,
llvm::Value *Value,
unsigned FirstIndex,
unsigned LastIndex) {
// Alternatively, we could emit this as a loop in the source.
for (unsigned I = FirstIndex; I <= LastIndex; ++I) {
llvm::Value *Cell = Builder.CreateConstInBoundsGEP1_32(Array, I);
Builder.CreateStore(Value, Cell);
}
}
static bool isAggregateTypeForABI(QualType T) {
return !CodeGenFunction::hasScalarEvaluationKind(T) ||
T->isMemberFunctionPointerType();
}
ABIInfo::~ABIInfo() {}
static bool isRecordReturnIndirect(const RecordType *RT,
CGCXXABI &CXXABI) {
const CXXRecordDecl *RD = dyn_cast<CXXRecordDecl>(RT->getDecl());
if (!RD)
return false;
return CXXABI.isReturnTypeIndirect(RD);
}
static bool isRecordReturnIndirect(QualType T, CGCXXABI &CXXABI) {
const RecordType *RT = T->getAs<RecordType>();
if (!RT)
return false;
return isRecordReturnIndirect(RT, CXXABI);
}
static CGCXXABI::RecordArgABI getRecordArgABI(const RecordType *RT,
CGCXXABI &CXXABI) {
const CXXRecordDecl *RD = dyn_cast<CXXRecordDecl>(RT->getDecl());
if (!RD)
return CGCXXABI::RAA_Default;
return CXXABI.getRecordArgABI(RD);
}
static CGCXXABI::RecordArgABI getRecordArgABI(QualType T,
CGCXXABI &CXXABI) {
const RecordType *RT = T->getAs<RecordType>();
if (!RT)
return CGCXXABI::RAA_Default;
return getRecordArgABI(RT, CXXABI);
}
CGCXXABI &ABIInfo::getCXXABI() const {
return CGT.getCXXABI();
}
ASTContext &ABIInfo::getContext() const {
return CGT.getContext();
}
llvm::LLVMContext &ABIInfo::getVMContext() const {
return CGT.getLLVMContext();
}
const llvm::DataLayout &ABIInfo::getDataLayout() const {
return CGT.getDataLayout();
}
const TargetInfo &ABIInfo::getTarget() const {
return CGT.getTarget();
}
void ABIArgInfo::dump() const {
raw_ostream &OS = llvm::errs();
OS << "(ABIArgInfo Kind=";
switch (TheKind) {
case Direct:
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
OS << "Direct Type=";
if (llvm::Type *Ty = getCoerceToType())
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
Ty->print(OS);
else
OS << "null";
break;
case Extend:
OS << "Extend";
break;
case Ignore:
OS << "Ignore";
break;
case InAlloca:
OS << "InAlloca Offset=" << getInAllocaFieldIndex();
break;
case Indirect:
OS << "Indirect Align=" << getIndirectAlign()
2011-07-16 02:23:44 +08:00
<< " ByVal=" << getIndirectByVal()
<< " Realign=" << getIndirectRealign();
break;
case Expand:
OS << "Expand";
break;
}
OS << ")\n";
}
TargetCodeGenInfo::~TargetCodeGenInfo() { delete Info; }
// If someone can figure out a general rule for this, that would be great.
// It's probably just doomed to be platform-dependent, though.
unsigned TargetCodeGenInfo::getSizeOfUnwindException() const {
// Verified for:
// x86-64 FreeBSD, Linux, Darwin
// x86-32 FreeBSD, Linux, Darwin
// PowerPC Linux, Darwin
// ARM Darwin (*not* EABI)
// AArch64 Linux
return 32;
}
bool TargetCodeGenInfo::isNoProtoCallVariadic(const CallArgList &args,
const FunctionNoProtoType *fnType) const {
// The following conventions are known to require this to be false:
// x86_stdcall
// MIPS
// For everything else, we just prefer false unless we opt out.
return false;
}
void
TargetCodeGenInfo::getDependentLibraryOption(llvm::StringRef Lib,
llvm::SmallString<24> &Opt) const {
// This assumes the user is passing a library name like "rt" instead of a
// filename like "librt.a/so", and that they don't care whether it's static or
// dynamic.
Opt = "-l";
Opt += Lib;
}
static bool isEmptyRecord(ASTContext &Context, QualType T, bool AllowArrays);
/// isEmptyField - Return true iff a the field is "empty", that is it
/// is an unnamed bit-field or an (array of) empty record(s).
static bool isEmptyField(ASTContext &Context, const FieldDecl *FD,
bool AllowArrays) {
if (FD->isUnnamedBitfield())
return true;
QualType FT = FD->getType();
// Constant arrays of empty records count as empty, strip them off.
// Constant arrays of zero length always count as empty.
if (AllowArrays)
while (const ConstantArrayType *AT = Context.getAsConstantArrayType(FT)) {
if (AT->getSize() == 0)
return true;
FT = AT->getElementType();
}
const RecordType *RT = FT->getAs<RecordType>();
if (!RT)
return false;
// C++ record fields are never empty, at least in the Itanium ABI.
//
// FIXME: We should use a predicate for whether this behavior is true in the
// current ABI.
if (isa<CXXRecordDecl>(RT->getDecl()))
return false;
return isEmptyRecord(Context, FT, AllowArrays);
}
/// isEmptyRecord - Return true iff a structure contains only empty
/// fields. Note that a structure with a flexible array member is not
/// considered empty.
static bool isEmptyRecord(ASTContext &Context, QualType T, bool AllowArrays) {
const RecordType *RT = T->getAs<RecordType>();
if (!RT)
return 0;
const RecordDecl *RD = RT->getDecl();
if (RD->hasFlexibleArrayMember())
return false;
// If this is a C++ record, check the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD))
for (CXXRecordDecl::base_class_const_iterator i = CXXRD->bases_begin(),
e = CXXRD->bases_end(); i != e; ++i)
if (!isEmptyRecord(Context, i->getType(), true))
return false;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i)
if (!isEmptyField(Context, *i, AllowArrays))
return false;
return true;
}
/// isSingleElementStruct - Determine if a structure is a "single
/// element struct", i.e. it has exactly one non-empty field or
/// exactly one field which is itself a single element
/// struct. Structures with flexible array members are never
/// considered single element structs.
///
/// \return The field declaration for the single non-empty field, if
/// it exists.
static const Type *isSingleElementStruct(QualType T, ASTContext &Context) {
const RecordType *RT = T->getAsStructureType();
if (!RT)
return 0;
const RecordDecl *RD = RT->getDecl();
if (RD->hasFlexibleArrayMember())
return 0;
const Type *Found = 0;
// If this is a C++ record, check the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD)) {
for (CXXRecordDecl::base_class_const_iterator i = CXXRD->bases_begin(),
e = CXXRD->bases_end(); i != e; ++i) {
// Ignore empty records.
if (isEmptyRecord(Context, i->getType(), true))
continue;
// If we already found an element then this isn't a single-element struct.
if (Found)
return 0;
// If this is non-empty and not a single element struct, the composite
// cannot be a single element struct.
Found = isSingleElementStruct(i->getType(), Context);
if (!Found)
return 0;
}
}
// Check for single element.
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i) {
const FieldDecl *FD = *i;
QualType FT = FD->getType();
// Ignore empty fields.
if (isEmptyField(Context, FD, true))
continue;
// If we already found an element then this isn't a single-element
// struct.
if (Found)
return 0;
// Treat single element arrays as the element.
while (const ConstantArrayType *AT = Context.getAsConstantArrayType(FT)) {
if (AT->getSize().getZExtValue() != 1)
break;
FT = AT->getElementType();
}
if (!isAggregateTypeForABI(FT)) {
Found = FT.getTypePtr();
} else {
Found = isSingleElementStruct(FT, Context);
if (!Found)
return 0;
}
}
// We don't consider a struct a single-element struct if it has
// padding beyond the element type.
if (Found && Context.getTypeSize(Found) != Context.getTypeSize(T))
return 0;
return Found;
}
static bool is32Or64BitBasicType(QualType Ty, ASTContext &Context) {
// Treat complex types as the element type.
if (const ComplexType *CTy = Ty->getAs<ComplexType>())
Ty = CTy->getElementType();
// Check for a type which we know has a simple scalar argument-passing
// convention without any padding. (We're specifically looking for 32
// and 64-bit integer and integer-equivalents, float, and double.)
if (!Ty->getAs<BuiltinType>() && !Ty->hasPointerRepresentation() &&
!Ty->isEnumeralType() && !Ty->isBlockPointerType())
return false;
uint64_t Size = Context.getTypeSize(Ty);
return Size == 32 || Size == 64;
}
/// canExpandIndirectArgument - Test whether an argument type which is to be
/// passed indirectly (on the stack) would have the equivalent layout if it was
/// expanded into separate arguments. If so, we prefer to do the latter to avoid
/// inhibiting optimizations.
///
// FIXME: This predicate is missing many cases, currently it just follows
// llvm-gcc (checks that all fields are 32-bit or 64-bit primitive types). We
// should probably make this smarter, or better yet make the LLVM backend
// capable of handling it.
static bool canExpandIndirectArgument(QualType Ty, ASTContext &Context) {
// We can only expand structure types.
const RecordType *RT = Ty->getAs<RecordType>();
if (!RT)
return false;
// We can only expand (C) structures.
//
// FIXME: This needs to be generalized to handle classes as well.
const RecordDecl *RD = RT->getDecl();
if (!RD->isStruct() || isa<CXXRecordDecl>(RD))
return false;
uint64_t Size = 0;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i) {
const FieldDecl *FD = *i;
if (!is32Or64BitBasicType(FD->getType(), Context))
return false;
// FIXME: Reject bit-fields wholesale; there are two problems, we don't know
// how to expand them yet, and the predicate for telling if a bitfield still
// counts as "basic" is more complicated than what we were doing previously.
if (FD->isBitField())
return false;
Size += Context.getTypeSize(FD->getType());
}
// Make sure there are not any holes in the struct.
if (Size != Context.getTypeSize(Ty))
return false;
return true;
}
namespace {
/// DefaultABIInfo - The default implementation for ABI specific
/// details. This implementation provides information which results in
/// self-consistent and sensible LLVM IR generation, but does not
/// conform to any particular ABI.
class DefaultABIInfo : public ABIInfo {
public:
DefaultABIInfo(CodeGen::CodeGenTypes &CGT) : ABIInfo(CGT) {}
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType RetTy) const;
virtual void computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type);
}
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class DefaultTargetCodeGenInfo : public TargetCodeGenInfo {
public:
DefaultTargetCodeGenInfo(CodeGen::CodeGenTypes &CGT)
: TargetCodeGenInfo(new DefaultABIInfo(CGT)) {}
};
llvm::Value *DefaultABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
return 0;
}
ABIArgInfo DefaultABIInfo::classifyArgumentType(QualType Ty) const {
if (isAggregateTypeForABI(Ty)) {
// Records with non-trivial destructors/constructors should not be passed
// by value.
if (isRecordReturnIndirect(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
return ABIArgInfo::getIndirect(0);
}
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
ABIArgInfo DefaultABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
if (isAggregateTypeForABI(RetTy))
return ABIArgInfo::getIndirect(0);
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
//===----------------------------------------------------------------------===//
// le32/PNaCl bitcode ABI Implementation
//
// This is a simplified version of the x86_32 ABI. Arguments and return values
// are always passed on the stack.
//===----------------------------------------------------------------------===//
class PNaClABIInfo : public ABIInfo {
public:
PNaClABIInfo(CodeGen::CodeGenTypes &CGT) : ABIInfo(CGT) {}
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType RetTy) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class PNaClTargetCodeGenInfo : public TargetCodeGenInfo {
public:
PNaClTargetCodeGenInfo(CodeGen::CodeGenTypes &CGT)
: TargetCodeGenInfo(new PNaClABIInfo(CGT)) {}
};
void PNaClABIInfo::computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type);
}
llvm::Value *PNaClABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
return 0;
}
/// \brief Classify argument of given type \p Ty.
ABIArgInfo PNaClABIInfo::classifyArgumentType(QualType Ty) const {
if (isAggregateTypeForABI(Ty)) {
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
return ABIArgInfo::getIndirect(0);
} else if (const EnumType *EnumTy = Ty->getAs<EnumType>()) {
// Treat an enum type as its underlying type.
Ty = EnumTy->getDecl()->getIntegerType();
} else if (Ty->isFloatingType()) {
// Floating-point types don't go inreg.
return ABIArgInfo::getDirect();
}
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
ABIArgInfo PNaClABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
// In the PNaCl ABI we always return records/structures on the stack.
if (isAggregateTypeForABI(RetTy))
return ABIArgInfo::getIndirect(0);
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
/// IsX86_MMXType - Return true if this is an MMX type.
bool IsX86_MMXType(llvm::Type *IRType) {
// Return true if the type is an MMX type <2 x i32>, <4 x i16>, or <8 x i8>.
return IRType->isVectorTy() && IRType->getPrimitiveSizeInBits() == 64 &&
cast<llvm::VectorType>(IRType)->getElementType()->isIntegerTy() &&
IRType->getScalarSizeInBits() != 64;
}
static llvm::Type* X86AdjustInlineAsmType(CodeGen::CodeGenFunction &CGF,
StringRef Constraint,
llvm::Type* Ty) {
if ((Constraint == "y" || Constraint == "&y") && Ty->isVectorTy()) {
if (cast<llvm::VectorType>(Ty)->getBitWidth() != 64) {
// Invalid MMX constraint
return 0;
}
return llvm::Type::getX86_MMXTy(CGF.getLLVMContext());
}
// No operation needed
return Ty;
}
//===----------------------------------------------------------------------===//
// X86-32 ABI Implementation
//===----------------------------------------------------------------------===//
/// \brief Similar to llvm::CCState, but for Clang.
struct CCState {
CCState(unsigned CC) : CC(CC), FreeRegs(0) {}
unsigned CC;
unsigned FreeRegs;
unsigned StackOffset;
bool UseInAlloca;
};
/// X86_32ABIInfo - The X86-32 ABI information.
class X86_32ABIInfo : public ABIInfo {
enum Class {
Integer,
Float
};
static const unsigned MinABIStackAlignInBytes = 4;
bool IsDarwinVectorABI;
bool IsSmallStructInRegABI;
bool IsWin32StructABI;
unsigned DefaultNumRegisterParameters;
static bool isRegisterSize(unsigned Size) {
return (Size == 8 || Size == 16 || Size == 32 || Size == 64);
}
bool shouldReturnTypeInRegister(QualType Ty, ASTContext &Context,
bool IsInstanceMethod) const;
/// getIndirectResult - Give a source type \arg Ty, return a suitable result
/// such that the argument will be passed in memory.
ABIArgInfo getIndirectResult(QualType Ty, bool ByVal, CCState &State) const;
ABIArgInfo getIndirectReturnResult(CCState &State) const;
/// \brief Return the alignment to use for the given type on the stack.
unsigned getTypeStackAlignInBytes(QualType Ty, unsigned Align) const;
Class classify(QualType Ty) const;
ABIArgInfo classifyReturnType(QualType RetTy, CCState &State,
bool IsInstanceMethod) const;
ABIArgInfo classifyArgumentType(QualType RetTy, CCState &State) const;
bool shouldUseInReg(QualType Ty, CCState &State, bool &NeedsPadding) const;
/// \brief Rewrite the function info so that all memory arguments use
/// inalloca.
void rewriteWithInAlloca(CGFunctionInfo &FI) const;
void addFieldToArgStruct(SmallVector<llvm::Type *, 6> &FrameFields,
unsigned &StackOffset, ABIArgInfo &Info,
QualType Type) const;
public:
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
X86_32ABIInfo(CodeGen::CodeGenTypes &CGT, bool d, bool p, bool w,
unsigned r)
: ABIInfo(CGT), IsDarwinVectorABI(d), IsSmallStructInRegABI(p),
IsWin32StructABI(w), DefaultNumRegisterParameters(r) {}
};
class X86_32TargetCodeGenInfo : public TargetCodeGenInfo {
public:
X86_32TargetCodeGenInfo(CodeGen::CodeGenTypes &CGT,
bool d, bool p, bool w, unsigned r)
:TargetCodeGenInfo(new X86_32ABIInfo(CGT, d, p, w, r)) {}
static bool isStructReturnInRegABI(
const llvm::Triple &Triple, const CodeGenOptions &Opts);
void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &CGM) const;
int getDwarfEHStackPointer(CodeGen::CodeGenModule &CGM) const {
// Darwin uses different dwarf register numbers for EH.
if (CGM.getTarget().getTriple().isOSDarwin()) return 5;
return 4;
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
llvm::Type* adjustInlineAsmType(CodeGen::CodeGenFunction &CGF,
StringRef Constraint,
llvm::Type* Ty) const {
return X86AdjustInlineAsmType(CGF, Constraint, Ty);
}
llvm::Constant *getUBSanFunctionSignature(CodeGen::CodeGenModule &CGM) const {
unsigned Sig = (0xeb << 0) | // jmp rel8
(0x06 << 8) | // .+0x08
('F' << 16) |
('T' << 24);
return llvm::ConstantInt::get(CGM.Int32Ty, Sig);
}
};
}
/// shouldReturnTypeInRegister - Determine if the given type should be
/// passed in a register (for the Darwin ABI).
bool X86_32ABIInfo::shouldReturnTypeInRegister(QualType Ty, ASTContext &Context,
bool IsInstanceMethod) const {
uint64_t Size = Context.getTypeSize(Ty);
// Type must be register sized.
if (!isRegisterSize(Size))
return false;
if (Ty->isVectorType()) {
// 64- and 128- bit vectors inside structures are not returned in
// registers.
if (Size == 64 || Size == 128)
return false;
return true;
}
// If this is a builtin, pointer, enum, complex type, member pointer, or
// member function pointer it is ok.
if (Ty->getAs<BuiltinType>() || Ty->hasPointerRepresentation() ||
Ty->isAnyComplexType() || Ty->isEnumeralType() ||
Ty->isBlockPointerType() || Ty->isMemberPointerType())
return true;
// Arrays are treated like records.
if (const ConstantArrayType *AT = Context.getAsConstantArrayType(Ty))
return shouldReturnTypeInRegister(AT->getElementType(), Context,
IsInstanceMethod);
// Otherwise, it must be a record type.
const RecordType *RT = Ty->getAs<RecordType>();
if (!RT) return false;
// FIXME: Traverse bases here too.
// For thiscall conventions, structures will never be returned in
// a register. This is for compatibility with the MSVC ABI
if (IsWin32StructABI && IsInstanceMethod && RT->isStructureType())
return false;
// Structure types are passed in register if all fields would be
// passed in a register.
for (RecordDecl::field_iterator i = RT->getDecl()->field_begin(),
e = RT->getDecl()->field_end(); i != e; ++i) {
const FieldDecl *FD = *i;
// Empty fields are ignored.
if (isEmptyField(Context, FD, true))
continue;
// Check fields recursively.
if (!shouldReturnTypeInRegister(FD->getType(), Context, IsInstanceMethod))
return false;
}
return true;
}
ABIArgInfo X86_32ABIInfo::getIndirectReturnResult(CCState &State) const {
// If the return value is indirect, then the hidden argument is consuming one
// integer register.
if (State.FreeRegs) {
--State.FreeRegs;
return ABIArgInfo::getIndirectInReg(/*Align=*/0, /*ByVal=*/false);
}
return ABIArgInfo::getIndirect(/*Align=*/0, /*ByVal=*/false);
}
ABIArgInfo X86_32ABIInfo::classifyReturnType(QualType RetTy, CCState &State,
bool IsInstanceMethod) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
if (const VectorType *VT = RetTy->getAs<VectorType>()) {
// On Darwin, some vectors are returned in registers.
if (IsDarwinVectorABI) {
uint64_t Size = getContext().getTypeSize(RetTy);
// 128-bit vectors are a special case; they are returned in
// registers and we need to make sure to pick a type the LLVM
// backend will like.
if (Size == 128)
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::VectorType::get(
llvm::Type::getInt64Ty(getVMContext()), 2));
// Always return in register if it fits in a general purpose
// register, or if it is 64 bits and has a single element.
if ((Size == 8 || Size == 16 || Size == 32) ||
(Size == 64 && VT->getNumElements() == 1))
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
Size));
return getIndirectReturnResult(State);
}
return ABIArgInfo::getDirect();
}
if (isAggregateTypeForABI(RetTy)) {
if (const RecordType *RT = RetTy->getAs<RecordType>()) {
if (isRecordReturnIndirect(RT, getCXXABI()))
return getIndirectReturnResult(State);
// Structures with flexible arrays are always indirect.
if (RT->getDecl()->hasFlexibleArrayMember())
return getIndirectReturnResult(State);
}
// If specified, structs and unions are always indirect.
if (!IsSmallStructInRegABI && !RetTy->isAnyComplexType())
return getIndirectReturnResult(State);
// Small structures which are register sized are generally returned
// in a register.
if (shouldReturnTypeInRegister(RetTy, getContext(), IsInstanceMethod)) {
uint64_t Size = getContext().getTypeSize(RetTy);
// As a special-case, if the struct is a "single-element" struct, and
// the field is of type "float" or "double", return it in a
// floating-point register. (MSVC does not apply this special case.)
// We apply a similar transformation for pointer types to improve the
// quality of the generated IR.
if (const Type *SeltTy = isSingleElementStruct(RetTy, getContext()))
if ((!IsWin32StructABI && SeltTy->isRealFloatingType())
|| SeltTy->hasPointerRepresentation())
return ABIArgInfo::getDirect(CGT.ConvertType(QualType(SeltTy, 0)));
// FIXME: We should be able to narrow this integer in cases with dead
// padding.
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),Size));
}
return getIndirectReturnResult(State);
}
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
static bool isSSEVectorType(ASTContext &Context, QualType Ty) {
return Ty->getAs<VectorType>() && Context.getTypeSize(Ty) == 128;
}
static bool isRecordWithSSEVectorType(ASTContext &Context, QualType Ty) {
const RecordType *RT = Ty->getAs<RecordType>();
if (!RT)
return 0;
const RecordDecl *RD = RT->getDecl();
// If this is a C++ record, check the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD))
for (CXXRecordDecl::base_class_const_iterator i = CXXRD->bases_begin(),
e = CXXRD->bases_end(); i != e; ++i)
if (!isRecordWithSSEVectorType(Context, i->getType()))
return false;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i) {
QualType FT = i->getType();
if (isSSEVectorType(Context, FT))
return true;
if (isRecordWithSSEVectorType(Context, FT))
return true;
}
return false;
}
unsigned X86_32ABIInfo::getTypeStackAlignInBytes(QualType Ty,
unsigned Align) const {
// Otherwise, if the alignment is less than or equal to the minimum ABI
// alignment, just use the default; the backend will handle this.
if (Align <= MinABIStackAlignInBytes)
return 0; // Use default alignment.
// On non-Darwin, the stack type alignment is always 4.
if (!IsDarwinVectorABI) {
// Set explicit alignment, since we may need to realign the top.
return MinABIStackAlignInBytes;
}
// Otherwise, if the type contains an SSE vector type, the alignment is 16.
if (Align >= 16 && (isSSEVectorType(getContext(), Ty) ||
isRecordWithSSEVectorType(getContext(), Ty)))
return 16;
return MinABIStackAlignInBytes;
}
ABIArgInfo X86_32ABIInfo::getIndirectResult(QualType Ty, bool ByVal,
CCState &State) const {
if (!ByVal) {
if (State.FreeRegs) {
--State.FreeRegs; // Non-byval indirects just use one pointer.
return ABIArgInfo::getIndirectInReg(0, false);
}
return ABIArgInfo::getIndirect(0, false);
}
// Compute the byval alignment.
unsigned TypeAlign = getContext().getTypeAlign(Ty) / 8;
unsigned StackAlign = getTypeStackAlignInBytes(Ty, TypeAlign);
if (StackAlign == 0)
return ABIArgInfo::getIndirect(4, /*ByVal=*/true);
// If the stack alignment is less than the type alignment, realign the
// argument.
bool Realign = TypeAlign > StackAlign;
return ABIArgInfo::getIndirect(StackAlign, /*ByVal=*/true, Realign);
}
X86_32ABIInfo::Class X86_32ABIInfo::classify(QualType Ty) const {
const Type *T = isSingleElementStruct(Ty, getContext());
if (!T)
T = Ty.getTypePtr();
if (const BuiltinType *BT = T->getAs<BuiltinType>()) {
BuiltinType::Kind K = BT->getKind();
if (K == BuiltinType::Float || K == BuiltinType::Double)
return Float;
}
return Integer;
}
bool X86_32ABIInfo::shouldUseInReg(QualType Ty, CCState &State,
bool &NeedsPadding) const {
NeedsPadding = false;
Class C = classify(Ty);
if (C == Float)
return false;
unsigned Size = getContext().getTypeSize(Ty);
unsigned SizeInRegs = (Size + 31) / 32;
if (SizeInRegs == 0)
return false;
if (SizeInRegs > State.FreeRegs) {
State.FreeRegs = 0;
return false;
}
State.FreeRegs -= SizeInRegs;
if (State.CC == llvm::CallingConv::X86_FastCall) {
if (Size > 32)
return false;
if (Ty->isIntegralOrEnumerationType())
return true;
if (Ty->isPointerType())
return true;
if (Ty->isReferenceType())
return true;
if (State.FreeRegs)
NeedsPadding = true;
return false;
}
return true;
}
ABIArgInfo X86_32ABIInfo::classifyArgumentType(QualType Ty,
CCState &State) const {
// FIXME: Set alignment on indirect arguments.
if (isAggregateTypeForABI(Ty)) {
if (const RecordType *RT = Ty->getAs<RecordType>()) {
// Check with the C++ ABI first.
CGCXXABI::RecordArgABI RAA = getRecordArgABI(RT, getCXXABI());
if (RAA == CGCXXABI::RAA_Indirect) {
return getIndirectResult(Ty, false, State);
} else if (RAA == CGCXXABI::RAA_DirectInMemory) {
// The field index doesn't matter, we'll fix it up later.
return ABIArgInfo::getInAlloca(/*FieldIndex=*/0);
}
// Structs are always byval on win32, regardless of what they contain.
if (IsWin32StructABI)
return getIndirectResult(Ty, true, State);
// Structures with flexible arrays are always indirect.
if (RT->getDecl()->hasFlexibleArrayMember())
return getIndirectResult(Ty, true, State);
}
// Ignore empty structs/unions.
if (isEmptyRecord(getContext(), Ty, true))
return ABIArgInfo::getIgnore();
llvm::LLVMContext &LLVMContext = getVMContext();
llvm::IntegerType *Int32 = llvm::Type::getInt32Ty(LLVMContext);
bool NeedsPadding;
if (shouldUseInReg(Ty, State, NeedsPadding)) {
unsigned SizeInRegs = (getContext().getTypeSize(Ty) + 31) / 32;
SmallVector<llvm::Type*, 3> Elements(SizeInRegs, Int32);
llvm::Type *Result = llvm::StructType::get(LLVMContext, Elements);
return ABIArgInfo::getDirectInReg(Result);
}
llvm::IntegerType *PaddingType = NeedsPadding ? Int32 : 0;
// Expand small (<= 128-bit) record types when we know that the stack layout
// of those arguments will match the struct. This is important because the
// LLVM backend isn't smart enough to remove byval, which inhibits many
// optimizations.
if (getContext().getTypeSize(Ty) <= 4*32 &&
canExpandIndirectArgument(Ty, getContext()))
return ABIArgInfo::getExpandWithPadding(
State.CC == llvm::CallingConv::X86_FastCall, PaddingType);
return getIndirectResult(Ty, true, State);
}
if (const VectorType *VT = Ty->getAs<VectorType>()) {
2010-08-27 04:08:43 +08:00
// On Darwin, some vectors are passed in memory, we handle this by passing
// it as an i8/i16/i32/i64.
if (IsDarwinVectorABI) {
uint64_t Size = getContext().getTypeSize(Ty);
if ((Size == 8 || Size == 16 || Size == 32) ||
(Size == 64 && VT->getNumElements() == 1))
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
Size));
}
if (IsX86_MMXType(CGT.ConvertType(Ty)))
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(), 64));
2010-10-19 14:39:39 +08:00
return ABIArgInfo::getDirect();
}
2010-10-19 14:39:39 +08:00
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
bool NeedsPadding;
bool InReg = shouldUseInReg(Ty, State, NeedsPadding);
if (Ty->isPromotableIntegerType()) {
if (InReg)
return ABIArgInfo::getExtendInReg();
return ABIArgInfo::getExtend();
}
if (InReg)
return ABIArgInfo::getDirectInReg();
return ABIArgInfo::getDirect();
}
void X86_32ABIInfo::computeInfo(CGFunctionInfo &FI) const {
CCState State(FI.getCallingConvention());
if (State.CC == llvm::CallingConv::X86_FastCall)
State.FreeRegs = 2;
else if (FI.getHasRegParm())
State.FreeRegs = FI.getRegParm();
else
State.FreeRegs = DefaultNumRegisterParameters;
FI.getReturnInfo() =
classifyReturnType(FI.getReturnType(), State, FI.isInstanceMethod());
// On win32, use the x86_cdeclmethodcc convention for cdecl methods that use
// sret. This convention swaps the order of the first two parameters behind
// the scenes to match MSVC.
if (IsWin32StructABI && FI.isInstanceMethod() &&
FI.getCallingConvention() == llvm::CallingConv::C &&
FI.getReturnInfo().isIndirect())
FI.setEffectiveCallingConvention(llvm::CallingConv::X86_CDeclMethod);
bool UsedInAlloca = false;
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it) {
it->info = classifyArgumentType(it->type, State);
UsedInAlloca |= (it->info.getKind() == ABIArgInfo::InAlloca);
}
// If we needed to use inalloca for any argument, do a second pass and rewrite
// all the memory arguments to use inalloca.
if (UsedInAlloca)
rewriteWithInAlloca(FI);
}
void
X86_32ABIInfo::addFieldToArgStruct(SmallVector<llvm::Type *, 6> &FrameFields,
unsigned &StackOffset,
ABIArgInfo &Info, QualType Type) const {
// Insert padding bytes to respect alignment. For x86_32, each argument is 4
// byte aligned.
unsigned Align = 4U;
if (Info.getKind() == ABIArgInfo::Indirect && Info.getIndirectByVal())
Align = std::max(Align, Info.getIndirectAlign());
if (StackOffset & (Align - 1)) {
unsigned OldOffset = StackOffset;
StackOffset = llvm::RoundUpToAlignment(StackOffset, Align);
unsigned NumBytes = StackOffset - OldOffset;
assert(NumBytes);
llvm::Type *Ty = llvm::Type::getInt8Ty(getVMContext());
Ty = llvm::ArrayType::get(Ty, NumBytes);
FrameFields.push_back(Ty);
}
Info = ABIArgInfo::getInAlloca(FrameFields.size());
FrameFields.push_back(CGT.ConvertTypeForMem(Type));
StackOffset += getContext().getTypeSizeInChars(Type).getQuantity();
}
void X86_32ABIInfo::rewriteWithInAlloca(CGFunctionInfo &FI) const {
assert(IsWin32StructABI && "inalloca only supported on win32");
// Build a packed struct type for all of the arguments in memory.
SmallVector<llvm::Type *, 6> FrameFields;
unsigned StackOffset = 0;
// Put the sret parameter into the inalloca struct if it's in memory.
ABIArgInfo &Ret = FI.getReturnInfo();
if (Ret.isIndirect() && !Ret.getInReg()) {
CanQualType PtrTy = getContext().getPointerType(FI.getReturnType());
addFieldToArgStruct(FrameFields, StackOffset, Ret, PtrTy);
// On Windows, the hidden sret parameter is always returned in eax.
Ret.setInAllocaSRet(IsWin32StructABI);
}
// Skip the 'this' parameter in ecx.
CGFunctionInfo::arg_iterator I = FI.arg_begin(), E = FI.arg_end();
if (FI.getCallingConvention() == llvm::CallingConv::X86_ThisCall)
++I;
// Put arguments passed in memory into the struct.
for (; I != E; ++I) {
// Leave ignored and inreg arguments alone.
switch (I->info.getKind()) {
case ABIArgInfo::Indirect:
assert(I->info.getIndirectByVal());
break;
case ABIArgInfo::Ignore:
continue;
case ABIArgInfo::Direct:
case ABIArgInfo::Extend:
if (I->info.getInReg())
continue;
break;
default:
break;
}
addFieldToArgStruct(FrameFields, StackOffset, I->info, I->type);
}
FI.setArgStruct(llvm::StructType::get(getVMContext(), FrameFields,
/*isPacked=*/true));
}
llvm::Value *X86_32ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP,
"ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
// Compute if the address needs to be aligned
unsigned Align = CGF.getContext().getTypeAlignInChars(Ty).getQuantity();
Align = getTypeStackAlignInBytes(Ty, Align);
Align = std::max(Align, 4U);
if (Align > 4) {
// addr = (addr + align - 1) & -align;
llvm::Value *Offset =
llvm::ConstantInt::get(CGF.Int32Ty, Align - 1);
Addr = CGF.Builder.CreateGEP(Addr, Offset);
llvm::Value *AsInt = CGF.Builder.CreatePtrToInt(Addr,
CGF.Int32Ty);
llvm::Value *Mask = llvm::ConstantInt::get(CGF.Int32Ty, -Align);
Addr = CGF.Builder.CreateIntToPtr(CGF.Builder.CreateAnd(AsInt, Mask),
Addr->getType(),
"ap.cur.aligned");
}
llvm::Type *PTy =
llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
llvm::Value *AddrTyped = Builder.CreateBitCast(Addr, PTy);
uint64_t Offset =
llvm::RoundUpToAlignment(CGF.getContext().getTypeSize(Ty) / 8, Align);
llvm::Value *NextAddr =
Builder.CreateGEP(Addr, llvm::ConstantInt::get(CGF.Int32Ty, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
return AddrTyped;
}
void X86_32TargetCodeGenInfo::SetTargetAttributes(const Decl *D,
llvm::GlobalValue *GV,
CodeGen::CodeGenModule &CGM) const {
if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) {
if (FD->hasAttr<X86ForceAlignArgPointerAttr>()) {
// Get the LLVM function.
llvm::Function *Fn = cast<llvm::Function>(GV);
// Now add the 'alignstack' attribute with a value of 16.
llvm::AttrBuilder B;
B.addStackAlignmentAttr(16);
Fn->addAttributes(llvm::AttributeSet::FunctionIndex,
llvm::AttributeSet::get(CGM.getLLVMContext(),
llvm::AttributeSet::FunctionIndex,
B));
}
}
}
bool X86_32TargetCodeGenInfo::initDwarfEHRegSizeTable(
CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
CodeGen::CGBuilderTy &Builder = CGF.Builder;
llvm::Value *Four8 = llvm::ConstantInt::get(CGF.Int8Ty, 4);
// 0-7 are the eight integer registers; the order is different
// on Darwin (for EH), but the range is the same.
// 8 is %eip.
AssignToArrayRange(Builder, Address, Four8, 0, 8);
if (CGF.CGM.getTarget().getTriple().isOSDarwin()) {
// 12-16 are st(0..4). Not sure why we stop at 4.
// These have size 16, which is sizeof(long double) on
// platforms with 8-byte alignment for that type.
llvm::Value *Sixteen8 = llvm::ConstantInt::get(CGF.Int8Ty, 16);
AssignToArrayRange(Builder, Address, Sixteen8, 12, 16);
} else {
// 9 is %eflags, which doesn't get a size on Darwin for some
// reason.
Builder.CreateStore(Four8, Builder.CreateConstInBoundsGEP1_32(Address, 9));
// 11-16 are st(0..5). Not sure why we stop at 5.
// These have size 12, which is sizeof(long double) on
// platforms with 4-byte alignment for that type.
llvm::Value *Twelve8 = llvm::ConstantInt::get(CGF.Int8Ty, 12);
AssignToArrayRange(Builder, Address, Twelve8, 11, 16);
}
return false;
}
//===----------------------------------------------------------------------===//
// X86-64 ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
/// X86_64ABIInfo - The X86_64 ABI information.
class X86_64ABIInfo : public ABIInfo {
enum Class {
Integer = 0,
SSE,
SSEUp,
X87,
X87Up,
ComplexX87,
NoClass,
Memory
};
/// merge - Implement the X86_64 ABI merging algorithm.
///
/// Merge an accumulating classification \arg Accum with a field
/// classification \arg Field.
///
/// \param Accum - The accumulating classification. This should
/// always be either NoClass or the result of a previous merge
/// call. In addition, this should never be Memory (the caller
/// should just return Memory for the aggregate).
2010-06-29 05:43:59 +08:00
static Class merge(Class Accum, Class Field);
/// postMerge - Implement the X86_64 ABI post merging algorithm.
///
/// Post merger cleanup, reduces a malformed Hi and Lo pair to
/// final MEMORY or SSE classes when necessary.
///
/// \param AggregateSize - The size of the current aggregate in
/// the classification process.
///
/// \param Lo - The classification for the parts of the type
/// residing in the low word of the containing object.
///
/// \param Hi - The classification for the parts of the type
/// residing in the higher words of the containing object.
///
void postMerge(unsigned AggregateSize, Class &Lo, Class &Hi) const;
/// classify - Determine the x86_64 register classes in which the
/// given type T should be passed.
///
/// \param Lo - The classification for the parts of the type
/// residing in the low word of the containing object.
///
/// \param Hi - The classification for the parts of the type
/// residing in the high word of the containing object.
///
/// \param OffsetBase - The bit offset of this type in the
/// containing object. Some parameters are classified different
/// depending on whether they straddle an eightbyte boundary.
///
/// \param isNamedArg - Whether the argument in question is a "named"
/// argument, as used in AMD64-ABI 3.5.7.
///
/// If a word is unused its result will be NoClass; if a type should
/// be passed in Memory then at least the classification of \arg Lo
/// will be Memory.
///
/// The \arg Lo class will be NoClass iff the argument is ignored.
///
/// If the \arg Lo class is ComplexX87, then the \arg Hi class will
/// also be ComplexX87.
void classify(QualType T, uint64_t OffsetBase, Class &Lo, Class &Hi,
bool isNamedArg) const;
llvm::Type *GetByteVectorType(QualType Ty) const;
llvm::Type *GetSSETypeAtOffset(llvm::Type *IRType,
unsigned IROffset, QualType SourceTy,
unsigned SourceOffset) const;
llvm::Type *GetINTEGERTypeAtOffset(llvm::Type *IRType,
unsigned IROffset, QualType SourceTy,
unsigned SourceOffset) const;
/// getIndirectResult - Give a source type \arg Ty, return a suitable result
/// such that the argument will be returned in memory.
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
ABIArgInfo getIndirectReturnResult(QualType Ty) const;
/// getIndirectResult - Give a source type \arg Ty, return a suitable result
/// such that the argument will be passed in memory.
///
/// \param freeIntRegs - The number of free integer registers remaining
/// available.
ABIArgInfo getIndirectResult(QualType Ty, unsigned freeIntRegs) const;
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType Ty,
unsigned freeIntRegs,
unsigned &neededInt,
unsigned &neededSSE,
bool isNamedArg) const;
bool IsIllegalVectorType(QualType Ty) const;
/// The 0.98 ABI revision clarified a lot of ambiguities,
/// unfortunately in ways that were not always consistent with
/// certain previous compilers. In particular, platforms which
/// required strict binary compatibility with older versions of GCC
/// may need to exempt themselves.
bool honorsRevision0_98() const {
return !getTarget().getTriple().isOSDarwin();
}
bool HasAVX;
// Some ABIs (e.g. X32 ABI and Native Client OS) use 32 bit pointers on
// 64-bit hardware.
bool Has64BitPointers;
public:
X86_64ABIInfo(CodeGen::CodeGenTypes &CGT, bool hasavx) :
ABIInfo(CGT), HasAVX(hasavx),
Has64BitPointers(CGT.getDataLayout().getPointerSize(0) == 8) {
}
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
bool isPassedUsingAVXType(QualType type) const {
unsigned neededInt, neededSSE;
// The freeIntRegs argument doesn't matter here.
ABIArgInfo info = classifyArgumentType(type, 0, neededInt, neededSSE,
/*isNamedArg*/true);
if (info.isDirect()) {
llvm::Type *ty = info.getCoerceToType();
if (llvm::VectorType *vectorTy = dyn_cast_or_null<llvm::VectorType>(ty))
return (vectorTy->getBitWidth() > 128);
}
return false;
}
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
/// WinX86_64ABIInfo - The Windows X86_64 ABI information.
class WinX86_64ABIInfo : public ABIInfo {
ABIArgInfo classify(QualType Ty, bool IsReturnType) const;
public:
WinX86_64ABIInfo(CodeGen::CodeGenTypes &CGT) : ABIInfo(CGT) {}
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class X86_64TargetCodeGenInfo : public TargetCodeGenInfo {
public:
X86_64TargetCodeGenInfo(CodeGen::CodeGenTypes &CGT, bool HasAVX)
: TargetCodeGenInfo(new X86_64ABIInfo(CGT, HasAVX)) {}
const X86_64ABIInfo &getABIInfo() const {
return static_cast<const X86_64ABIInfo&>(TargetCodeGenInfo::getABIInfo());
}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &CGM) const {
return 7;
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
llvm::Value *Eight8 = llvm::ConstantInt::get(CGF.Int8Ty, 8);
// 0-15 are the 16 integer registers.
// 16 is %rip.
AssignToArrayRange(CGF.Builder, Address, Eight8, 0, 16);
return false;
}
llvm::Type* adjustInlineAsmType(CodeGen::CodeGenFunction &CGF,
StringRef Constraint,
llvm::Type* Ty) const {
return X86AdjustInlineAsmType(CGF, Constraint, Ty);
}
bool isNoProtoCallVariadic(const CallArgList &args,
const FunctionNoProtoType *fnType) const {
// The default CC on x86-64 sets %al to the number of SSA
// registers used, and GCC sets this when calling an unprototyped
// function, so we override the default behavior. However, don't do
2011-12-06 11:08:26 +08:00
// that when AVX types are involved: the ABI explicitly states it is
// undefined, and it doesn't work in practice because of how the ABI
// defines varargs anyway.
if (fnType->getCallConv() == CC_C) {
bool HasAVXType = false;
for (CallArgList::const_iterator
it = args.begin(), ie = args.end(); it != ie; ++it) {
if (getABIInfo().isPassedUsingAVXType(it->Ty)) {
HasAVXType = true;
break;
}
}
if (!HasAVXType)
return true;
}
return TargetCodeGenInfo::isNoProtoCallVariadic(args, fnType);
}
llvm::Constant *getUBSanFunctionSignature(CodeGen::CodeGenModule &CGM) const {
unsigned Sig = (0xeb << 0) | // jmp rel8
(0x0a << 8) | // .+0x0c
('F' << 16) |
('T' << 24);
return llvm::ConstantInt::get(CGM.Int32Ty, Sig);
}
};
static std::string qualifyWindowsLibrary(llvm::StringRef Lib) {
// If the argument does not end in .lib, automatically add the suffix. This
// matches the behavior of MSVC.
std::string ArgStr = Lib;
if (!Lib.endswith_lower(".lib"))
ArgStr += ".lib";
return ArgStr;
}
class WinX86_32TargetCodeGenInfo : public X86_32TargetCodeGenInfo {
public:
WinX86_32TargetCodeGenInfo(CodeGen::CodeGenTypes &CGT,
bool d, bool p, bool w, unsigned RegParms)
: X86_32TargetCodeGenInfo(CGT, d, p, w, RegParms) {}
void getDependentLibraryOption(llvm::StringRef Lib,
llvm::SmallString<24> &Opt) const {
Opt = "/DEFAULTLIB:";
Opt += qualifyWindowsLibrary(Lib);
}
void getDetectMismatchOption(llvm::StringRef Name,
llvm::StringRef Value,
llvm::SmallString<32> &Opt) const {
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Opt = "/FAILIFMISMATCH:\"" + Name.str() + "=" + Value.str() + "\"";
}
};
class WinX86_64TargetCodeGenInfo : public TargetCodeGenInfo {
public:
WinX86_64TargetCodeGenInfo(CodeGen::CodeGenTypes &CGT)
: TargetCodeGenInfo(new WinX86_64ABIInfo(CGT)) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &CGM) const {
return 7;
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
llvm::Value *Eight8 = llvm::ConstantInt::get(CGF.Int8Ty, 8);
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// 0-15 are the 16 integer registers.
// 16 is %rip.
AssignToArrayRange(CGF.Builder, Address, Eight8, 0, 16);
return false;
}
void getDependentLibraryOption(llvm::StringRef Lib,
llvm::SmallString<24> &Opt) const {
Opt = "/DEFAULTLIB:";
Opt += qualifyWindowsLibrary(Lib);
}
void getDetectMismatchOption(llvm::StringRef Name,
llvm::StringRef Value,
llvm::SmallString<32> &Opt) const {
2013-06-08 06:42:22 +08:00
Opt = "/FAILIFMISMATCH:\"" + Name.str() + "=" + Value.str() + "\"";
}
};
}
void X86_64ABIInfo::postMerge(unsigned AggregateSize, Class &Lo,
Class &Hi) const {
// AMD64-ABI 3.2.3p2: Rule 5. Then a post merger cleanup is done:
//
// (a) If one of the classes is Memory, the whole argument is passed in
// memory.
//
// (b) If X87UP is not preceded by X87, the whole argument is passed in
// memory.
//
// (c) If the size of the aggregate exceeds two eightbytes and the first
// eightbyte isn't SSE or any other eightbyte isn't SSEUP, the whole
// argument is passed in memory. NOTE: This is necessary to keep the
// ABI working for processors that don't support the __m256 type.
//
// (d) If SSEUP is not preceded by SSE or SSEUP, it is converted to SSE.
//
// Some of these are enforced by the merging logic. Others can arise
// only with unions; for example:
// union { _Complex double; unsigned; }
//
// Note that clauses (b) and (c) were added in 0.98.
//
if (Hi == Memory)
Lo = Memory;
if (Hi == X87Up && Lo != X87 && honorsRevision0_98())
Lo = Memory;
if (AggregateSize > 128 && (Lo != SSE || Hi != SSEUp))
Lo = Memory;
if (Hi == SSEUp && Lo != SSE)
Hi = SSE;
}
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X86_64ABIInfo::Class X86_64ABIInfo::merge(Class Accum, Class Field) {
// AMD64-ABI 3.2.3p2: Rule 4. Each field of an object is
// classified recursively so that always two fields are
// considered. The resulting class is calculated according to
// the classes of the fields in the eightbyte:
//
// (a) If both classes are equal, this is the resulting class.
//
// (b) If one of the classes is NO_CLASS, the resulting class is
// the other class.
//
// (c) If one of the classes is MEMORY, the result is the MEMORY
// class.
//
// (d) If one of the classes is INTEGER, the result is the
// INTEGER.
//
// (e) If one of the classes is X87, X87UP, COMPLEX_X87 class,
// MEMORY is used as class.
//
// (f) Otherwise class SSE is used.
// Accum should never be memory (we should have returned) or
// ComplexX87 (because this cannot be passed in a structure).
assert((Accum != Memory && Accum != ComplexX87) &&
"Invalid accumulated classification during merge.");
if (Accum == Field || Field == NoClass)
return Accum;
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if (Field == Memory)
return Memory;
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if (Accum == NoClass)
return Field;
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if (Accum == Integer || Field == Integer)
return Integer;
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if (Field == X87 || Field == X87Up || Field == ComplexX87 ||
Accum == X87 || Accum == X87Up)
return Memory;
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return SSE;
}
void X86_64ABIInfo::classify(QualType Ty, uint64_t OffsetBase,
Class &Lo, Class &Hi, bool isNamedArg) const {
// FIXME: This code can be simplified by introducing a simple value class for
// Class pairs with appropriate constructor methods for the various
// situations.
// FIXME: Some of the split computations are wrong; unaligned vectors
// shouldn't be passed in registers for example, so there is no chance they
// can straddle an eightbyte. Verify & simplify.
Lo = Hi = NoClass;
Class &Current = OffsetBase < 64 ? Lo : Hi;
Current = Memory;
if (const BuiltinType *BT = Ty->getAs<BuiltinType>()) {
BuiltinType::Kind k = BT->getKind();
if (k == BuiltinType::Void) {
Current = NoClass;
} else if (k == BuiltinType::Int128 || k == BuiltinType::UInt128) {
Lo = Integer;
Hi = Integer;
} else if (k >= BuiltinType::Bool && k <= BuiltinType::LongLong) {
Current = Integer;
} else if ((k == BuiltinType::Float || k == BuiltinType::Double) ||
(k == BuiltinType::LongDouble &&
getTarget().getTriple().isOSNaCl())) {
Current = SSE;
} else if (k == BuiltinType::LongDouble) {
Lo = X87;
Hi = X87Up;
}
// FIXME: _Decimal32 and _Decimal64 are SSE.
// FIXME: _float128 and _Decimal128 are (SSE, SSEUp).
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return;
}
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if (const EnumType *ET = Ty->getAs<EnumType>()) {
// Classify the underlying integer type.
classify(ET->getDecl()->getIntegerType(), OffsetBase, Lo, Hi, isNamedArg);
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return;
}
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if (Ty->hasPointerRepresentation()) {
Current = Integer;
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return;
}
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if (Ty->isMemberPointerType()) {
if (Ty->isMemberFunctionPointerType() && Has64BitPointers)
Lo = Hi = Integer;
else
Current = Integer;
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return;
}
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if (const VectorType *VT = Ty->getAs<VectorType>()) {
uint64_t Size = getContext().getTypeSize(VT);
if (Size == 32) {
// gcc passes all <4 x char>, <2 x short>, <1 x int>, <1 x
// float> as integer.
Current = Integer;
// If this type crosses an eightbyte boundary, it should be
// split.
uint64_t EB_Real = (OffsetBase) / 64;
uint64_t EB_Imag = (OffsetBase + Size - 1) / 64;
if (EB_Real != EB_Imag)
Hi = Lo;
} else if (Size == 64) {
// gcc passes <1 x double> in memory. :(
if (VT->getElementType()->isSpecificBuiltinType(BuiltinType::Double))
return;
// gcc passes <1 x long long> as INTEGER.
if (VT->getElementType()->isSpecificBuiltinType(BuiltinType::LongLong) ||
VT->getElementType()->isSpecificBuiltinType(BuiltinType::ULongLong) ||
VT->getElementType()->isSpecificBuiltinType(BuiltinType::Long) ||
VT->getElementType()->isSpecificBuiltinType(BuiltinType::ULong))
Current = Integer;
else
Current = SSE;
// If this type crosses an eightbyte boundary, it should be
// split.
if (OffsetBase && OffsetBase != 64)
Hi = Lo;
} else if (Size == 128 || (HasAVX && isNamedArg && Size == 256)) {
// Arguments of 256-bits are split into four eightbyte chunks. The
// least significant one belongs to class SSE and all the others to class
// SSEUP. The original Lo and Hi design considers that types can't be
// greater than 128-bits, so a 64-bit split in Hi and Lo makes sense.
// This design isn't correct for 256-bits, but since there're no cases
// where the upper parts would need to be inspected, avoid adding
// complexity and just consider Hi to match the 64-256 part.
//
// Note that per 3.5.7 of AMD64-ABI, 256-bit args are only passed in
// registers if they are "named", i.e. not part of the "..." of a
// variadic function.
Lo = SSE;
Hi = SSEUp;
}
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return;
}
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if (const ComplexType *CT = Ty->getAs<ComplexType>()) {
QualType ET = getContext().getCanonicalType(CT->getElementType());
uint64_t Size = getContext().getTypeSize(Ty);
if (ET->isIntegralOrEnumerationType()) {
if (Size <= 64)
Current = Integer;
else if (Size <= 128)
Lo = Hi = Integer;
} else if (ET == getContext().FloatTy)
Current = SSE;
else if (ET == getContext().DoubleTy ||
(ET == getContext().LongDoubleTy &&
getTarget().getTriple().isOSNaCl()))
Lo = Hi = SSE;
else if (ET == getContext().LongDoubleTy)
Current = ComplexX87;
// If this complex type crosses an eightbyte boundary then it
// should be split.
uint64_t EB_Real = (OffsetBase) / 64;
uint64_t EB_Imag = (OffsetBase + getContext().getTypeSize(ET)) / 64;
if (Hi == NoClass && EB_Real != EB_Imag)
Hi = Lo;
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return;
}
if (const ConstantArrayType *AT = getContext().getAsConstantArrayType(Ty)) {
// Arrays are treated like structures.
uint64_t Size = getContext().getTypeSize(Ty);
// AMD64-ABI 3.2.3p2: Rule 1. If the size of an object is larger
// than four eightbytes, ..., it has class MEMORY.
if (Size > 256)
return;
// AMD64-ABI 3.2.3p2: Rule 1. If ..., or it contains unaligned
// fields, it has class MEMORY.
//
// Only need to check alignment of array base.
if (OffsetBase % getContext().getTypeAlign(AT->getElementType()))
return;
// Otherwise implement simplified merge. We could be smarter about
// this, but it isn't worth it and would be harder to verify.
Current = NoClass;
uint64_t EltSize = getContext().getTypeSize(AT->getElementType());
uint64_t ArraySize = AT->getSize().getZExtValue();
// The only case a 256-bit wide vector could be used is when the array
// contains a single 256-bit element. Since Lo and Hi logic isn't extended
// to work for sizes wider than 128, early check and fallback to memory.
if (Size > 128 && EltSize != 256)
return;
for (uint64_t i=0, Offset=OffsetBase; i<ArraySize; ++i, Offset += EltSize) {
Class FieldLo, FieldHi;
classify(AT->getElementType(), Offset, FieldLo, FieldHi, isNamedArg);
Lo = merge(Lo, FieldLo);
Hi = merge(Hi, FieldHi);
if (Lo == Memory || Hi == Memory)
break;
}
postMerge(Size, Lo, Hi);
assert((Hi != SSEUp || Lo == SSE) && "Invalid SSEUp array classification.");
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return;
}
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if (const RecordType *RT = Ty->getAs<RecordType>()) {
uint64_t Size = getContext().getTypeSize(Ty);
// AMD64-ABI 3.2.3p2: Rule 1. If the size of an object is larger
// than four eightbytes, ..., it has class MEMORY.
if (Size > 256)
return;
// AMD64-ABI 3.2.3p2: Rule 2. If a C++ object has either a non-trivial
// copy constructor or a non-trivial destructor, it is passed by invisible
// reference.
if (getRecordArgABI(RT, getCXXABI()))
return;
const RecordDecl *RD = RT->getDecl();
// Assume variable sized types are passed in memory.
if (RD->hasFlexibleArrayMember())
return;
const ASTRecordLayout &Layout = getContext().getASTRecordLayout(RD);
// Reset Lo class, this will be recomputed.
Current = NoClass;
// If this is a C++ record, classify the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD)) {
for (CXXRecordDecl::base_class_const_iterator i = CXXRD->bases_begin(),
e = CXXRD->bases_end(); i != e; ++i) {
assert(!i->isVirtual() && !i->getType()->isDependentType() &&
"Unexpected base class!");
const CXXRecordDecl *Base =
cast<CXXRecordDecl>(i->getType()->getAs<RecordType>()->getDecl());
// Classify this field.
//
// AMD64-ABI 3.2.3p2: Rule 3. If the size of the aggregate exceeds a
// single eightbyte, each is classified separately. Each eightbyte gets
// initialized to class NO_CLASS.
Class FieldLo, FieldHi;
uint64_t Offset =
OffsetBase + getContext().toBits(Layout.getBaseClassOffset(Base));
classify(i->getType(), Offset, FieldLo, FieldHi, isNamedArg);
Lo = merge(Lo, FieldLo);
Hi = merge(Hi, FieldHi);
if (Lo == Memory || Hi == Memory)
break;
}
}
// Classify the fields one at a time, merging the results.
unsigned idx = 0;
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for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i, ++idx) {
uint64_t Offset = OffsetBase + Layout.getFieldOffset(idx);
bool BitField = i->isBitField();
// AMD64-ABI 3.2.3p2: Rule 1. If the size of an object is larger than
// four eightbytes, or it contains unaligned fields, it has class MEMORY.
//
// The only case a 256-bit wide vector could be used is when the struct
// contains a single 256-bit element. Since Lo and Hi logic isn't extended
// to work for sizes wider than 128, early check and fallback to memory.
//
if (Size > 128 && getContext().getTypeSize(i->getType()) != 256) {
Lo = Memory;
return;
}
// Note, skip this test for bit-fields, see below.
if (!BitField && Offset % getContext().getTypeAlign(i->getType())) {
Lo = Memory;
return;
}
// Classify this field.
//
// AMD64-ABI 3.2.3p2: Rule 3. If the size of the aggregate
// exceeds a single eightbyte, each is classified
// separately. Each eightbyte gets initialized to class
// NO_CLASS.
Class FieldLo, FieldHi;
// Bit-fields require special handling, they do not force the
// structure to be passed in memory even if unaligned, and
// therefore they can straddle an eightbyte.
if (BitField) {
// Ignore padding bit-fields.
if (i->isUnnamedBitfield())
continue;
uint64_t Offset = OffsetBase + Layout.getFieldOffset(idx);
uint64_t Size = i->getBitWidthValue(getContext());
uint64_t EB_Lo = Offset / 64;
uint64_t EB_Hi = (Offset + Size - 1) / 64;
if (EB_Lo) {
assert(EB_Hi == EB_Lo && "Invalid classification, type > 16 bytes.");
FieldLo = NoClass;
FieldHi = Integer;
} else {
FieldLo = Integer;
FieldHi = EB_Hi ? Integer : NoClass;
}
} else
classify(i->getType(), Offset, FieldLo, FieldHi, isNamedArg);
Lo = merge(Lo, FieldLo);
Hi = merge(Hi, FieldHi);
if (Lo == Memory || Hi == Memory)
break;
}
postMerge(Size, Lo, Hi);
}
}
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
ABIArgInfo X86_64ABIInfo::getIndirectReturnResult(QualType Ty) const {
// If this is a scalar LLVM value then assume LLVM will pass it in the right
// place naturally.
if (!isAggregateTypeForABI(Ty)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
return ABIArgInfo::getIndirect(0);
}
bool X86_64ABIInfo::IsIllegalVectorType(QualType Ty) const {
if (const VectorType *VecTy = Ty->getAs<VectorType>()) {
uint64_t Size = getContext().getTypeSize(VecTy);
unsigned LargestVector = HasAVX ? 256 : 128;
if (Size <= 64 || Size > LargestVector)
return true;
}
return false;
}
ABIArgInfo X86_64ABIInfo::getIndirectResult(QualType Ty,
unsigned freeIntRegs) const {
// If this is a scalar LLVM value then assume LLVM will pass it in the right
// place naturally.
//
// This assumption is optimistic, as there could be free registers available
// when we need to pass this argument in memory, and LLVM could try to pass
// the argument in the free register. This does not seem to happen currently,
// but this code would be much safer if we could mark the argument with
// 'onstack'. See PR12193.
if (!isAggregateTypeForABI(Ty) && !IsIllegalVectorType(Ty)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
// Compute the byval alignment. We specify the alignment of the byval in all
// cases so that the mid-level optimizer knows the alignment of the byval.
unsigned Align = std::max(getContext().getTypeAlign(Ty) / 8, 8U);
// Attempt to avoid passing indirect results using byval when possible. This
// is important for good codegen.
//
// We do this by coercing the value into a scalar type which the backend can
// handle naturally (i.e., without using byval).
//
// For simplicity, we currently only do this when we have exhausted all of the
// free integer registers. Doing this when there are free integer registers
// would require more care, as we would have to ensure that the coerced value
// did not claim the unused register. That would require either reording the
// arguments to the function (so that any subsequent inreg values came first),
// or only doing this optimization when there were no following arguments that
// might be inreg.
//
// We currently expect it to be rare (particularly in well written code) for
// arguments to be passed on the stack when there are still free integer
// registers available (this would typically imply large structs being passed
// by value), so this seems like a fair tradeoff for now.
//
// We can revisit this if the backend grows support for 'onstack' parameter
// attributes. See PR12193.
if (freeIntRegs == 0) {
uint64_t Size = getContext().getTypeSize(Ty);
// If this type fits in an eightbyte, coerce it into the matching integral
// type, which will end up on the stack (with alignment 8).
if (Align == 8 && Size <= 64)
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
Size));
}
return ABIArgInfo::getIndirect(Align);
}
/// GetByteVectorType - The ABI specifies that a value should be passed in an
/// full vector XMM/YMM register. Pick an LLVM IR type that will be passed as a
/// vector register.
llvm::Type *X86_64ABIInfo::GetByteVectorType(QualType Ty) const {
llvm::Type *IRType = CGT.ConvertType(Ty);
// Wrapper structs that just contain vectors are passed just like vectors,
// strip them off if present.
llvm::StructType *STy = dyn_cast<llvm::StructType>(IRType);
while (STy && STy->getNumElements() == 1) {
IRType = STy->getElementType(0);
STy = dyn_cast<llvm::StructType>(IRType);
}
// If the preferred type is a 16-byte vector, prefer to pass it.
if (llvm::VectorType *VT = dyn_cast<llvm::VectorType>(IRType)){
llvm::Type *EltTy = VT->getElementType();
unsigned BitWidth = VT->getBitWidth();
if ((BitWidth >= 128 && BitWidth <= 256) &&
(EltTy->isFloatTy() || EltTy->isDoubleTy() ||
EltTy->isIntegerTy(8) || EltTy->isIntegerTy(16) ||
EltTy->isIntegerTy(32) || EltTy->isIntegerTy(64) ||
EltTy->isIntegerTy(128)))
return VT;
}
return llvm::VectorType::get(llvm::Type::getDoubleTy(getVMContext()), 2);
}
/// BitsContainNoUserData - Return true if the specified [start,end) bit range
/// is known to either be off the end of the specified type or being in
/// alignment padding. The user type specified is known to be at most 128 bits
/// in size, and have passed through X86_64ABIInfo::classify with a successful
/// classification that put one of the two halves in the INTEGER class.
///
/// It is conservatively correct to return false.
static bool BitsContainNoUserData(QualType Ty, unsigned StartBit,
unsigned EndBit, ASTContext &Context) {
// If the bytes being queried are off the end of the type, there is no user
// data hiding here. This handles analysis of builtins, vectors and other
// types that don't contain interesting padding.
unsigned TySize = (unsigned)Context.getTypeSize(Ty);
if (TySize <= StartBit)
return true;
if (const ConstantArrayType *AT = Context.getAsConstantArrayType(Ty)) {
unsigned EltSize = (unsigned)Context.getTypeSize(AT->getElementType());
unsigned NumElts = (unsigned)AT->getSize().getZExtValue();
// Check each element to see if the element overlaps with the queried range.
for (unsigned i = 0; i != NumElts; ++i) {
// If the element is after the span we care about, then we're done..
unsigned EltOffset = i*EltSize;
if (EltOffset >= EndBit) break;
unsigned EltStart = EltOffset < StartBit ? StartBit-EltOffset :0;
if (!BitsContainNoUserData(AT->getElementType(), EltStart,
EndBit-EltOffset, Context))
return false;
}
// If it overlaps no elements, then it is safe to process as padding.
return true;
}
if (const RecordType *RT = Ty->getAs<RecordType>()) {
const RecordDecl *RD = RT->getDecl();
const ASTRecordLayout &Layout = Context.getASTRecordLayout(RD);
// If this is a C++ record, check the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD)) {
for (CXXRecordDecl::base_class_const_iterator i = CXXRD->bases_begin(),
e = CXXRD->bases_end(); i != e; ++i) {
assert(!i->isVirtual() && !i->getType()->isDependentType() &&
"Unexpected base class!");
const CXXRecordDecl *Base =
cast<CXXRecordDecl>(i->getType()->getAs<RecordType>()->getDecl());
// If the base is after the span we care about, ignore it.
unsigned BaseOffset = Context.toBits(Layout.getBaseClassOffset(Base));
if (BaseOffset >= EndBit) continue;
unsigned BaseStart = BaseOffset < StartBit ? StartBit-BaseOffset :0;
if (!BitsContainNoUserData(i->getType(), BaseStart,
EndBit-BaseOffset, Context))
return false;
}
}
// Verify that no field has data that overlaps the region of interest. Yes
// this could be sped up a lot by being smarter about queried fields,
// however we're only looking at structs up to 16 bytes, so we don't care
// much.
unsigned idx = 0;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i, ++idx) {
unsigned FieldOffset = (unsigned)Layout.getFieldOffset(idx);
// If we found a field after the region we care about, then we're done.
if (FieldOffset >= EndBit) break;
unsigned FieldStart = FieldOffset < StartBit ? StartBit-FieldOffset :0;
if (!BitsContainNoUserData(i->getType(), FieldStart, EndBit-FieldOffset,
Context))
return false;
}
// If nothing in this record overlapped the area of interest, then we're
// clean.
return true;
}
return false;
}
/// ContainsFloatAtOffset - Return true if the specified LLVM IR type has a
/// float member at the specified offset. For example, {int,{float}} has a
/// float at offset 4. It is conservatively correct for this routine to return
/// false.
static bool ContainsFloatAtOffset(llvm::Type *IRType, unsigned IROffset,
const llvm::DataLayout &TD) {
// Base case if we find a float.
if (IROffset == 0 && IRType->isFloatTy())
return true;
// If this is a struct, recurse into the field at the specified offset.
if (llvm::StructType *STy = dyn_cast<llvm::StructType>(IRType)) {
const llvm::StructLayout *SL = TD.getStructLayout(STy);
unsigned Elt = SL->getElementContainingOffset(IROffset);
IROffset -= SL->getElementOffset(Elt);
return ContainsFloatAtOffset(STy->getElementType(Elt), IROffset, TD);
}
// If this is an array, recurse into the field at the specified offset.
if (llvm::ArrayType *ATy = dyn_cast<llvm::ArrayType>(IRType)) {
llvm::Type *EltTy = ATy->getElementType();
unsigned EltSize = TD.getTypeAllocSize(EltTy);
IROffset -= IROffset/EltSize*EltSize;
return ContainsFloatAtOffset(EltTy, IROffset, TD);
}
return false;
}
fix rdar://8251384, another case where we could access beyond the end of a struct. This improves the case when the struct being passed contains 3 floats, either due to a struct or array of 3 things. Before we'd generate this IR for the testcase: define float @bar(double %X.coerce0, double %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %1* ; <%1*> [#uses=2] %1 = getelementptr %1* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %1* %0, i32 0, i32 1 ; <double*> [#uses=1] store double %X.coerce1, double* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } which compiled (with optimization) to: _bar: ## @bar ## BB#0: ## %entry movd %xmm1, %rax movd %eax, %xmm0 ret Now we produce: define float @bar(double %X.coerce0, float %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %0* ; <%0*> [#uses=2] %1 = getelementptr %0* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %0* %0, i32 0, i32 1 ; <float*> [#uses=1] store float %X.coerce1, float* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } and: _bar: ## @bar ## BB#0: ## %entry movaps %xmm1, %xmm0 ret llvm-svn: 109776
2010-07-30 02:13:09 +08:00
/// GetSSETypeAtOffset - Return a type that will be passed by the backend in the
/// low 8 bytes of an XMM register, corresponding to the SSE class.
llvm::Type *X86_64ABIInfo::
GetSSETypeAtOffset(llvm::Type *IRType, unsigned IROffset,
fix rdar://8251384, another case where we could access beyond the end of a struct. This improves the case when the struct being passed contains 3 floats, either due to a struct or array of 3 things. Before we'd generate this IR for the testcase: define float @bar(double %X.coerce0, double %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %1* ; <%1*> [#uses=2] %1 = getelementptr %1* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %1* %0, i32 0, i32 1 ; <double*> [#uses=1] store double %X.coerce1, double* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } which compiled (with optimization) to: _bar: ## @bar ## BB#0: ## %entry movd %xmm1, %rax movd %eax, %xmm0 ret Now we produce: define float @bar(double %X.coerce0, float %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %0* ; <%0*> [#uses=2] %1 = getelementptr %0* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %0* %0, i32 0, i32 1 ; <float*> [#uses=1] store float %X.coerce1, float* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } and: _bar: ## @bar ## BB#0: ## %entry movaps %xmm1, %xmm0 ret llvm-svn: 109776
2010-07-30 02:13:09 +08:00
QualType SourceTy, unsigned SourceOffset) const {
// The only three choices we have are either double, <2 x float>, or float. We
fix rdar://8251384, another case where we could access beyond the end of a struct. This improves the case when the struct being passed contains 3 floats, either due to a struct or array of 3 things. Before we'd generate this IR for the testcase: define float @bar(double %X.coerce0, double %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %1* ; <%1*> [#uses=2] %1 = getelementptr %1* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %1* %0, i32 0, i32 1 ; <double*> [#uses=1] store double %X.coerce1, double* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } which compiled (with optimization) to: _bar: ## @bar ## BB#0: ## %entry movd %xmm1, %rax movd %eax, %xmm0 ret Now we produce: define float @bar(double %X.coerce0, float %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %0* ; <%0*> [#uses=2] %1 = getelementptr %0* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %0* %0, i32 0, i32 1 ; <float*> [#uses=1] store float %X.coerce1, float* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } and: _bar: ## @bar ## BB#0: ## %entry movaps %xmm1, %xmm0 ret llvm-svn: 109776
2010-07-30 02:13:09 +08:00
// pass as float if the last 4 bytes is just padding. This happens for
// structs that contain 3 floats.
if (BitsContainNoUserData(SourceTy, SourceOffset*8+32,
SourceOffset*8+64, getContext()))
return llvm::Type::getFloatTy(getVMContext());
// We want to pass as <2 x float> if the LLVM IR type contains a float at
// offset+0 and offset+4. Walk the LLVM IR type to find out if this is the
// case.
if (ContainsFloatAtOffset(IRType, IROffset, getDataLayout()) &&
ContainsFloatAtOffset(IRType, IROffset+4, getDataLayout()))
Finally pass "two floats in a 64-bit unit" as a <2 x float> instead of as a double in the x86-64 ABI. This allows us to generate much better code for certain things, e.g.: _Complex float f32(_Complex float A, _Complex float B) { return A+B; } Used to compile into (look at the integer silliness!): _f32: ## @f32 ## BB#0: ## %entry movd %xmm1, %rax movd %eax, %xmm1 movd %xmm0, %rcx movd %ecx, %xmm0 addss %xmm1, %xmm0 movd %xmm0, %edx shrq $32, %rax movd %eax, %xmm0 shrq $32, %rcx movd %ecx, %xmm1 addss %xmm0, %xmm1 movd %xmm1, %eax shlq $32, %rax addq %rdx, %rax movd %rax, %xmm0 ret Now we get: _f32: ## @f32 movdqa %xmm0, %xmm2 addss %xmm1, %xmm2 pshufd $16, %xmm2, %xmm2 pshufd $1, %xmm1, %xmm1 pshufd $1, %xmm0, %xmm0 addss %xmm1, %xmm0 pshufd $16, %xmm0, %xmm1 movdqa %xmm2, %xmm0 unpcklps %xmm1, %xmm0 ret and compile stuff like: extern float _Complex ccoshf( float _Complex ) ; float _Complex ccosf ( float _Complex z ) { float _Complex iz; (__real__ iz) = -(__imag__ z); (__imag__ iz) = (__real__ z); return ccoshf(iz); } into: _ccosf: ## @ccosf ## BB#0: ## %entry pshufd $1, %xmm0, %xmm1 xorps LCPI4_0(%rip), %xmm1 unpcklps %xmm0, %xmm1 movaps %xmm1, %xmm0 jmp _ccoshf ## TAILCALL instead of: _ccosf: ## @ccosf ## BB#0: ## %entry movd %xmm0, %rax movq %rax, %rcx shlq $32, %rcx shrq $32, %rax xorl $-2147483648, %eax ## imm = 0xFFFFFFFF80000000 addq %rcx, %rax movd %rax, %xmm0 jmp _ccoshf ## TAILCALL There is still "stuff to be done" here for the struct case, but this resolves rdar://6379669 - [x86-64 ABI] Pass and return _Complex float / double efficiently llvm-svn: 112111
2010-08-26 07:39:14 +08:00
return llvm::VectorType::get(llvm::Type::getFloatTy(getVMContext()), 2);
fix rdar://8251384, another case where we could access beyond the end of a struct. This improves the case when the struct being passed contains 3 floats, either due to a struct or array of 3 things. Before we'd generate this IR for the testcase: define float @bar(double %X.coerce0, double %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %1* ; <%1*> [#uses=2] %1 = getelementptr %1* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %1* %0, i32 0, i32 1 ; <double*> [#uses=1] store double %X.coerce1, double* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } which compiled (with optimization) to: _bar: ## @bar ## BB#0: ## %entry movd %xmm1, %rax movd %eax, %xmm0 ret Now we produce: define float @bar(double %X.coerce0, float %X.coerce1) nounwind { entry: %X = alloca %struct.foof, align 8 ; <%struct.foof*> [#uses=2] %0 = bitcast %struct.foof* %X to %0* ; <%0*> [#uses=2] %1 = getelementptr %0* %0, i32 0, i32 0 ; <double*> [#uses=1] store double %X.coerce0, double* %1 %2 = getelementptr %0* %0, i32 0, i32 1 ; <float*> [#uses=1] store float %X.coerce1, float* %2 %tmp = getelementptr inbounds %struct.foof* %X, i32 0, i32 2 ; <float*> [#uses=1] %tmp1 = load float* %tmp ; <float> [#uses=1] ret float %tmp1 } and: _bar: ## @bar ## BB#0: ## %entry movaps %xmm1, %xmm0 ret llvm-svn: 109776
2010-07-30 02:13:09 +08:00
return llvm::Type::getDoubleTy(getVMContext());
}
/// GetINTEGERTypeAtOffset - The ABI specifies that a value should be passed in
/// an 8-byte GPR. This means that we either have a scalar or we are talking
/// about the high or low part of an up-to-16-byte struct. This routine picks
/// the best LLVM IR type to represent this, which may be i64 or may be anything
/// else that the backend will pass in a GPR that works better (e.g. i8, %foo*,
/// etc).
///
/// PrefType is an LLVM IR type that corresponds to (part of) the IR type for
/// the source type. IROffset is an offset in bytes into the LLVM IR type that
/// the 8-byte value references. PrefType may be null.
///
/// SourceTy is the source level type for the entire argument. SourceOffset is
/// an offset into this that we're processing (which is always either 0 or 8).
///
llvm::Type *X86_64ABIInfo::
GetINTEGERTypeAtOffset(llvm::Type *IRType, unsigned IROffset,
QualType SourceTy, unsigned SourceOffset) const {
// If we're dealing with an un-offset LLVM IR type, then it means that we're
// returning an 8-byte unit starting with it. See if we can safely use it.
if (IROffset == 0) {
// Pointers and int64's always fill the 8-byte unit.
if ((isa<llvm::PointerType>(IRType) && Has64BitPointers) ||
IRType->isIntegerTy(64))
return IRType;
// If we have a 1/2/4-byte integer, we can use it only if the rest of the
// goodness in the source type is just tail padding. This is allowed to
// kick in for struct {double,int} on the int, but not on
// struct{double,int,int} because we wouldn't return the second int. We
// have to do this analysis on the source type because we can't depend on
// unions being lowered a specific way etc.
if (IRType->isIntegerTy(8) || IRType->isIntegerTy(16) ||
IRType->isIntegerTy(32) ||
(isa<llvm::PointerType>(IRType) && !Has64BitPointers)) {
unsigned BitWidth = isa<llvm::PointerType>(IRType) ? 32 :
cast<llvm::IntegerType>(IRType)->getBitWidth();
if (BitsContainNoUserData(SourceTy, SourceOffset*8+BitWidth,
SourceOffset*8+64, getContext()))
return IRType;
}
}
if (llvm::StructType *STy = dyn_cast<llvm::StructType>(IRType)) {
// If this is a struct, recurse into the field at the specified offset.
const llvm::StructLayout *SL = getDataLayout().getStructLayout(STy);
if (IROffset < SL->getSizeInBytes()) {
unsigned FieldIdx = SL->getElementContainingOffset(IROffset);
IROffset -= SL->getElementOffset(FieldIdx);
return GetINTEGERTypeAtOffset(STy->getElementType(FieldIdx), IROffset,
SourceTy, SourceOffset);
}
}
if (llvm::ArrayType *ATy = dyn_cast<llvm::ArrayType>(IRType)) {
llvm::Type *EltTy = ATy->getElementType();
unsigned EltSize = getDataLayout().getTypeAllocSize(EltTy);
unsigned EltOffset = IROffset/EltSize*EltSize;
return GetINTEGERTypeAtOffset(EltTy, IROffset-EltOffset, SourceTy,
SourceOffset);
}
// Okay, we don't have any better idea of what to pass, so we pass this in an
// integer register that isn't too big to fit the rest of the struct.
unsigned TySizeInBytes =
(unsigned)getContext().getTypeSizeInChars(SourceTy).getQuantity();
assert(TySizeInBytes != SourceOffset && "Empty field?");
// It is always safe to classify this as an integer type up to i64 that
// isn't larger than the structure.
return llvm::IntegerType::get(getVMContext(),
std::min(TySizeInBytes-SourceOffset, 8U)*8);
}
/// GetX86_64ByValArgumentPair - Given a high and low type that can ideally
/// be used as elements of a two register pair to pass or return, return a
/// first class aggregate to represent them. For example, if the low part of
/// a by-value argument should be passed as i32* and the high part as float,
/// return {i32*, float}.
static llvm::Type *
GetX86_64ByValArgumentPair(llvm::Type *Lo, llvm::Type *Hi,
const llvm::DataLayout &TD) {
// In order to correctly satisfy the ABI, we need to the high part to start
// at offset 8. If the high and low parts we inferred are both 4-byte types
// (e.g. i32 and i32) then the resultant struct type ({i32,i32}) won't have
// the second element at offset 8. Check for this:
unsigned LoSize = (unsigned)TD.getTypeAllocSize(Lo);
unsigned HiAlign = TD.getABITypeAlignment(Hi);
unsigned HiStart = llvm::DataLayout::RoundUpAlignment(LoSize, HiAlign);
assert(HiStart != 0 && HiStart <= 8 && "Invalid x86-64 argument pair!");
2010-10-19 14:39:39 +08:00
// To handle this, we have to increase the size of the low part so that the
// second element will start at an 8 byte offset. We can't increase the size
// of the second element because it might make us access off the end of the
// struct.
if (HiStart != 8) {
// There are only two sorts of types the ABI generation code can produce for
// the low part of a pair that aren't 8 bytes in size: float or i8/i16/i32.
// Promote these to a larger type.
if (Lo->isFloatTy())
Lo = llvm::Type::getDoubleTy(Lo->getContext());
else {
assert(Lo->isIntegerTy() && "Invalid/unknown lo type");
Lo = llvm::Type::getInt64Ty(Lo->getContext());
}
}
2010-10-19 14:39:39 +08:00
llvm::StructType *Result = llvm::StructType::get(Lo, Hi, NULL);
2010-10-19 14:39:39 +08:00
// Verify that the second element is at an 8-byte offset.
assert(TD.getStructLayout(Result)->getElementOffset(1) == 8 &&
"Invalid x86-64 argument pair!");
return Result;
}
2010-06-29 05:43:59 +08:00
ABIArgInfo X86_64ABIInfo::
classifyReturnType(QualType RetTy) const {
// AMD64-ABI 3.2.3p4: Rule 1. Classify the return type with the
// classification algorithm.
X86_64ABIInfo::Class Lo, Hi;
classify(RetTy, 0, Lo, Hi, /*isNamedArg*/ true);
// Check some invariants.
assert((Hi != Memory || Lo == Memory) && "Invalid memory classification.");
assert((Hi != SSEUp || Lo == SSE) && "Invalid SSEUp classification.");
llvm::Type *ResType = 0;
switch (Lo) {
case NoClass:
if (Hi == NoClass)
return ABIArgInfo::getIgnore();
// If the low part is just padding, it takes no register, leave ResType
// null.
assert((Hi == SSE || Hi == Integer || Hi == X87Up) &&
"Unknown missing lo part");
break;
case SSEUp:
case X87Up:
llvm_unreachable("Invalid classification for lo word.");
// AMD64-ABI 3.2.3p4: Rule 2. Types of class memory are returned via
// hidden argument.
case Memory:
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
return getIndirectReturnResult(RetTy);
// AMD64-ABI 3.2.3p4: Rule 3. If the class is INTEGER, the next
// available register of the sequence %rax, %rdx is used.
case Integer:
ResType = GetINTEGERTypeAtOffset(CGT.ConvertType(RetTy), 0, RetTy, 0);
// If we have a sign or zero extended integer, make sure to return Extend
// so that the parameter gets the right LLVM IR attributes.
if (Hi == NoClass && isa<llvm::IntegerType>(ResType)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
if (RetTy->isIntegralOrEnumerationType() &&
RetTy->isPromotableIntegerType())
return ABIArgInfo::getExtend();
}
break;
// AMD64-ABI 3.2.3p4: Rule 4. If the class is SSE, the next
// available SSE register of the sequence %xmm0, %xmm1 is used.
case SSE:
ResType = GetSSETypeAtOffset(CGT.ConvertType(RetTy), 0, RetTy, 0);
break;
// AMD64-ABI 3.2.3p4: Rule 6. If the class is X87, the value is
// returned on the X87 stack in %st0 as 80-bit x87 number.
case X87:
ResType = llvm::Type::getX86_FP80Ty(getVMContext());
break;
// AMD64-ABI 3.2.3p4: Rule 8. If the class is COMPLEX_X87, the real
// part of the value is returned in %st0 and the imaginary part in
// %st1.
case ComplexX87:
assert(Hi == ComplexX87 && "Unexpected ComplexX87 classification.");
ResType = llvm::StructType::get(llvm::Type::getX86_FP80Ty(getVMContext()),
llvm::Type::getX86_FP80Ty(getVMContext()),
NULL);
break;
}
llvm::Type *HighPart = 0;
switch (Hi) {
// Memory was handled previously and X87 should
// never occur as a hi class.
case Memory:
case X87:
llvm_unreachable("Invalid classification for hi word.");
case ComplexX87: // Previously handled.
case NoClass:
break;
case Integer:
HighPart = GetINTEGERTypeAtOffset(CGT.ConvertType(RetTy), 8, RetTy, 8);
if (Lo == NoClass) // Return HighPart at offset 8 in memory.
return ABIArgInfo::getDirect(HighPart, 8);
break;
case SSE:
HighPart = GetSSETypeAtOffset(CGT.ConvertType(RetTy), 8, RetTy, 8);
if (Lo == NoClass) // Return HighPart at offset 8 in memory.
return ABIArgInfo::getDirect(HighPart, 8);
break;
// AMD64-ABI 3.2.3p4: Rule 5. If the class is SSEUP, the eightbyte
// is passed in the next available eightbyte chunk if the last used
// vector register.
//
// SSEUP should always be preceded by SSE, just widen.
case SSEUp:
assert(Lo == SSE && "Unexpected SSEUp classification.");
ResType = GetByteVectorType(RetTy);
break;
// AMD64-ABI 3.2.3p4: Rule 7. If the class is X87UP, the value is
// returned together with the previous X87 value in %st0.
case X87Up:
// If X87Up is preceded by X87, we don't need to do
// anything. However, in some cases with unions it may not be
// preceded by X87. In such situations we follow gcc and pass the
// extra bits in an SSE reg.
if (Lo != X87) {
HighPart = GetSSETypeAtOffset(CGT.ConvertType(RetTy), 8, RetTy, 8);
if (Lo == NoClass) // Return HighPart at offset 8 in memory.
return ABIArgInfo::getDirect(HighPart, 8);
}
break;
}
2010-10-19 14:39:39 +08:00
// If a high part was specified, merge it together with the low part. It is
// known to pass in the high eightbyte of the result. We do this by forming a
// first class struct aggregate with the high and low part: {low, high}
if (HighPart)
ResType = GetX86_64ByValArgumentPair(ResType, HighPart, getDataLayout());
return ABIArgInfo::getDirect(ResType);
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
}
ABIArgInfo X86_64ABIInfo::classifyArgumentType(
QualType Ty, unsigned freeIntRegs, unsigned &neededInt, unsigned &neededSSE,
bool isNamedArg)
const
{
X86_64ABIInfo::Class Lo, Hi;
classify(Ty, 0, Lo, Hi, isNamedArg);
// Check some invariants.
// FIXME: Enforce these by construction.
assert((Hi != Memory || Lo == Memory) && "Invalid memory classification.");
assert((Hi != SSEUp || Lo == SSE) && "Invalid SSEUp classification.");
neededInt = 0;
neededSSE = 0;
llvm::Type *ResType = 0;
switch (Lo) {
case NoClass:
if (Hi == NoClass)
return ABIArgInfo::getIgnore();
// If the low part is just padding, it takes no register, leave ResType
// null.
assert((Hi == SSE || Hi == Integer || Hi == X87Up) &&
"Unknown missing lo part");
break;
// AMD64-ABI 3.2.3p3: Rule 1. If the class is MEMORY, pass the argument
// on the stack.
case Memory:
// AMD64-ABI 3.2.3p3: Rule 5. If the class is X87, X87UP or
// COMPLEX_X87, it is passed in memory.
case X87:
case ComplexX87:
if (getRecordArgABI(Ty, getCXXABI()) == CGCXXABI::RAA_Indirect)
++neededInt;
return getIndirectResult(Ty, freeIntRegs);
case SSEUp:
case X87Up:
llvm_unreachable("Invalid classification for lo word.");
// AMD64-ABI 3.2.3p3: Rule 2. If the class is INTEGER, the next
// available register of the sequence %rdi, %rsi, %rdx, %rcx, %r8
// and %r9 is used.
case Integer:
Change X86_64ABIInfo to have ASTContext and TargetData ivars to avoid passing ASTContext down through all the methods it has. When classifying an argument, or argument piece, as INTEGER, check to see if we have a pointer at exactly the same offset in the preferred type. If so, use that pointer type instead of i64. This allows us to compile A function taking a stringref into something like this: define i8* @foo(i64 %D.coerce0, i8* %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=4] %0 = getelementptr %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] store i64 %D.coerce0, i64* %0 %1 = getelementptr %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] store i8* %D.coerce1, i8** %1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } instead of this: define i8* @foo(i64 %D.coerce0, i64 %D.coerce1) nounwind ssp { entry: %D = alloca %struct.DeclGroup, align 8 ; <%struct.DeclGroup*> [#uses=3] %0 = insertvalue %0 undef, i64 %D.coerce0, 0 ; <%0> [#uses=1] %1 = insertvalue %0 %0, i64 %D.coerce1, 1 ; <%0> [#uses=1] %2 = bitcast %struct.DeclGroup* %D to %0* ; <%0*> [#uses=1] store %0 %1, %0* %2, align 1 %tmp = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 0 ; <i64*> [#uses=1] %tmp1 = load i64* %tmp ; <i64> [#uses=1] %tmp2 = getelementptr inbounds %struct.DeclGroup* %D, i32 0, i32 1 ; <i8**> [#uses=1] %tmp3 = load i8** %tmp2 ; <i8*> [#uses=1] %add.ptr = getelementptr inbounds i8* %tmp3, i64 %tmp1 ; <i8*> [#uses=1] ret i8* %add.ptr } This implements rdar://7375902 - [codegen quality] clang x86-64 ABI lowering code punishing StringRef llvm-svn: 107123
2010-06-29 14:01:59 +08:00
++neededInt;
// Pick an 8-byte type based on the preferred type.
ResType = GetINTEGERTypeAtOffset(CGT.ConvertType(Ty), 0, Ty, 0);
// If we have a sign or zero extended integer, make sure to return Extend
// so that the parameter gets the right LLVM IR attributes.
if (Hi == NoClass && isa<llvm::IntegerType>(ResType)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
if (Ty->isIntegralOrEnumerationType() &&
Ty->isPromotableIntegerType())
return ABIArgInfo::getExtend();
}
break;
// AMD64-ABI 3.2.3p3: Rule 3. If the class is SSE, the next
// available SSE register is used, the registers are taken in the
// order from %xmm0 to %xmm7.
case SSE: {
llvm::Type *IRType = CGT.ConvertType(Ty);
ResType = GetSSETypeAtOffset(IRType, 0, Ty, 0);
++neededSSE;
break;
}
}
llvm::Type *HighPart = 0;
switch (Hi) {
// Memory was handled previously, ComplexX87 and X87 should
// never occur as hi classes, and X87Up must be preceded by X87,
// which is passed in memory.
case Memory:
case X87:
case ComplexX87:
llvm_unreachable("Invalid classification for hi word.");
case NoClass: break;
case Integer:
++neededInt;
// Pick an 8-byte type based on the preferred type.
HighPart = GetINTEGERTypeAtOffset(CGT.ConvertType(Ty), 8, Ty, 8);
if (Lo == NoClass) // Pass HighPart at offset 8 in memory.
return ABIArgInfo::getDirect(HighPart, 8);
break;
// X87Up generally doesn't occur here (long double is passed in
// memory), except in situations involving unions.
case X87Up:
case SSE:
HighPart = GetSSETypeAtOffset(CGT.ConvertType(Ty), 8, Ty, 8);
if (Lo == NoClass) // Pass HighPart at offset 8 in memory.
return ABIArgInfo::getDirect(HighPart, 8);
++neededSSE;
break;
// AMD64-ABI 3.2.3p3: Rule 4. If the class is SSEUP, the
// eightbyte is passed in the upper half of the last used SSE
// register. This only happens when 128-bit vectors are passed.
case SSEUp:
assert(Lo == SSE && "Unexpected SSEUp classification");
ResType = GetByteVectorType(Ty);
break;
}
// If a high part was specified, merge it together with the low part. It is
// known to pass in the high eightbyte of the result. We do this by forming a
// first class struct aggregate with the high and low part: {low, high}
if (HighPart)
ResType = GetX86_64ByValArgumentPair(ResType, HighPart, getDataLayout());
2010-10-19 14:39:39 +08:00
return ABIArgInfo::getDirect(ResType);
}
void X86_64ABIInfo::computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
// Keep track of the number of assigned registers.
unsigned freeIntRegs = 6, freeSSERegs = 8;
// If the return value is indirect, then the hidden argument is consuming one
// integer register.
if (FI.getReturnInfo().isIndirect())
--freeIntRegs;
bool isVariadic = FI.isVariadic();
unsigned numRequiredArgs = 0;
if (isVariadic)
numRequiredArgs = FI.getRequiredArgs().getNumRequiredArgs();
// AMD64-ABI 3.2.3p3: Once arguments are classified, the registers
// get assigned (in left-to-right order) for passing as follows...
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it) {
bool isNamedArg = true;
if (isVariadic)
isNamedArg = (it - FI.arg_begin()) <
static_cast<signed>(numRequiredArgs);
unsigned neededInt, neededSSE;
it->info = classifyArgumentType(it->type, freeIntRegs, neededInt,
neededSSE, isNamedArg);
// AMD64-ABI 3.2.3p3: If there are no registers available for any
// eightbyte of an argument, the whole argument is passed on the
// stack. If registers have already been assigned for some
// eightbytes of such an argument, the assignments get reverted.
if (freeIntRegs >= neededInt && freeSSERegs >= neededSSE) {
freeIntRegs -= neededInt;
freeSSERegs -= neededSSE;
} else {
it->info = getIndirectResult(it->type, freeIntRegs);
}
}
}
static llvm::Value *EmitVAArgFromMemory(llvm::Value *VAListAddr,
QualType Ty,
CodeGenFunction &CGF) {
llvm::Value *overflow_arg_area_p =
CGF.Builder.CreateStructGEP(VAListAddr, 2, "overflow_arg_area_p");
llvm::Value *overflow_arg_area =
CGF.Builder.CreateLoad(overflow_arg_area_p, "overflow_arg_area");
// AMD64-ABI 3.5.7p5: Step 7. Align l->overflow_arg_area upwards to a 16
// byte boundary if alignment needed by type exceeds 8 byte boundary.
// It isn't stated explicitly in the standard, but in practice we use
// alignment greater than 16 where necessary.
uint64_t Align = CGF.getContext().getTypeAlign(Ty) / 8;
if (Align > 8) {
// overflow_arg_area = (overflow_arg_area + align - 1) & -align;
llvm::Value *Offset =
llvm::ConstantInt::get(CGF.Int64Ty, Align - 1);
overflow_arg_area = CGF.Builder.CreateGEP(overflow_arg_area, Offset);
llvm::Value *AsInt = CGF.Builder.CreatePtrToInt(overflow_arg_area,
CGF.Int64Ty);
llvm::Value *Mask = llvm::ConstantInt::get(CGF.Int64Ty, -(uint64_t)Align);
overflow_arg_area =
CGF.Builder.CreateIntToPtr(CGF.Builder.CreateAnd(AsInt, Mask),
overflow_arg_area->getType(),
"overflow_arg_area.align");
}
// AMD64-ABI 3.5.7p5: Step 8. Fetch type from l->overflow_arg_area.
llvm::Type *LTy = CGF.ConvertTypeForMem(Ty);
llvm::Value *Res =
CGF.Builder.CreateBitCast(overflow_arg_area,
llvm::PointerType::getUnqual(LTy));
// AMD64-ABI 3.5.7p5: Step 9. Set l->overflow_arg_area to:
// l->overflow_arg_area + sizeof(type).
// AMD64-ABI 3.5.7p5: Step 10. Align l->overflow_arg_area upwards to
// an 8 byte boundary.
uint64_t SizeInBytes = (CGF.getContext().getTypeSize(Ty) + 7) / 8;
llvm::Value *Offset =
llvm::ConstantInt::get(CGF.Int32Ty, (SizeInBytes + 7) & ~7);
overflow_arg_area = CGF.Builder.CreateGEP(overflow_arg_area, Offset,
"overflow_arg_area.next");
CGF.Builder.CreateStore(overflow_arg_area, overflow_arg_area_p);
// AMD64-ABI 3.5.7p5: Step 11. Return the fetched type.
return Res;
}
llvm::Value *X86_64ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// Assume that va_list type is correct; should be pointer to LLVM type:
// struct {
// i32 gp_offset;
// i32 fp_offset;
// i8* overflow_arg_area;
// i8* reg_save_area;
// };
unsigned neededInt, neededSSE;
Ty = CGF.getContext().getCanonicalType(Ty);
ABIArgInfo AI = classifyArgumentType(Ty, 0, neededInt, neededSSE,
/*isNamedArg*/false);
// AMD64-ABI 3.5.7p5: Step 1. Determine whether type may be passed
// in the registers. If not go to step 7.
if (!neededInt && !neededSSE)
return EmitVAArgFromMemory(VAListAddr, Ty, CGF);
// AMD64-ABI 3.5.7p5: Step 2. Compute num_gp to hold the number of
// general purpose registers needed to pass type and num_fp to hold
// the number of floating point registers needed.
// AMD64-ABI 3.5.7p5: Step 3. Verify whether arguments fit into
// registers. In the case: l->gp_offset > 48 - num_gp * 8 or
// l->fp_offset > 304 - num_fp * 16 go to step 7.
//
// NOTE: 304 is a typo, there are (6 * 8 + 8 * 16) = 176 bytes of
// register save space).
llvm::Value *InRegs = 0;
llvm::Value *gp_offset_p = 0, *gp_offset = 0;
llvm::Value *fp_offset_p = 0, *fp_offset = 0;
if (neededInt) {
gp_offset_p = CGF.Builder.CreateStructGEP(VAListAddr, 0, "gp_offset_p");
gp_offset = CGF.Builder.CreateLoad(gp_offset_p, "gp_offset");
2010-06-29 05:43:59 +08:00
InRegs = llvm::ConstantInt::get(CGF.Int32Ty, 48 - neededInt * 8);
InRegs = CGF.Builder.CreateICmpULE(gp_offset, InRegs, "fits_in_gp");
}
if (neededSSE) {
fp_offset_p = CGF.Builder.CreateStructGEP(VAListAddr, 1, "fp_offset_p");
fp_offset = CGF.Builder.CreateLoad(fp_offset_p, "fp_offset");
llvm::Value *FitsInFP =
2010-06-29 05:43:59 +08:00
llvm::ConstantInt::get(CGF.Int32Ty, 176 - neededSSE * 16);
FitsInFP = CGF.Builder.CreateICmpULE(fp_offset, FitsInFP, "fits_in_fp");
InRegs = InRegs ? CGF.Builder.CreateAnd(InRegs, FitsInFP) : FitsInFP;
}
llvm::BasicBlock *InRegBlock = CGF.createBasicBlock("vaarg.in_reg");
llvm::BasicBlock *InMemBlock = CGF.createBasicBlock("vaarg.in_mem");
llvm::BasicBlock *ContBlock = CGF.createBasicBlock("vaarg.end");
CGF.Builder.CreateCondBr(InRegs, InRegBlock, InMemBlock);
// Emit code to load the value if it was passed in registers.
CGF.EmitBlock(InRegBlock);
// AMD64-ABI 3.5.7p5: Step 4. Fetch type from l->reg_save_area with
// an offset of l->gp_offset and/or l->fp_offset. This may require
// copying to a temporary location in case the parameter is passed
// in different register classes or requires an alignment greater
// than 8 for general purpose registers and 16 for XMM registers.
//
// FIXME: This really results in shameful code when we end up needing to
// collect arguments from different places; often what should result in a
// simple assembling of a structure from scattered addresses has many more
// loads than necessary. Can we clean this up?
llvm::Type *LTy = CGF.ConvertTypeForMem(Ty);
llvm::Value *RegAddr =
CGF.Builder.CreateLoad(CGF.Builder.CreateStructGEP(VAListAddr, 3),
"reg_save_area");
if (neededInt && neededSSE) {
// FIXME: Cleanup.
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
assert(AI.isDirect() && "Unexpected ABI info for mixed regs");
llvm::StructType *ST = cast<llvm::StructType>(AI.getCoerceToType());
llvm::Value *Tmp = CGF.CreateMemTemp(Ty);
Tmp = CGF.Builder.CreateBitCast(Tmp, ST->getPointerTo());
assert(ST->getNumElements() == 2 && "Unexpected ABI info for mixed regs");
llvm::Type *TyLo = ST->getElementType(0);
llvm::Type *TyHi = ST->getElementType(1);
assert((TyLo->isFPOrFPVectorTy() ^ TyHi->isFPOrFPVectorTy()) &&
"Unexpected ABI info for mixed regs");
llvm::Type *PTyLo = llvm::PointerType::getUnqual(TyLo);
llvm::Type *PTyHi = llvm::PointerType::getUnqual(TyHi);
llvm::Value *GPAddr = CGF.Builder.CreateGEP(RegAddr, gp_offset);
llvm::Value *FPAddr = CGF.Builder.CreateGEP(RegAddr, fp_offset);
llvm::Value *RegLoAddr = TyLo->isFloatingPointTy() ? FPAddr : GPAddr;
llvm::Value *RegHiAddr = TyLo->isFloatingPointTy() ? GPAddr : FPAddr;
llvm::Value *V =
CGF.Builder.CreateLoad(CGF.Builder.CreateBitCast(RegLoAddr, PTyLo));
CGF.Builder.CreateStore(V, CGF.Builder.CreateStructGEP(Tmp, 0));
V = CGF.Builder.CreateLoad(CGF.Builder.CreateBitCast(RegHiAddr, PTyHi));
CGF.Builder.CreateStore(V, CGF.Builder.CreateStructGEP(Tmp, 1));
RegAddr = CGF.Builder.CreateBitCast(Tmp,
llvm::PointerType::getUnqual(LTy));
} else if (neededInt) {
RegAddr = CGF.Builder.CreateGEP(RegAddr, gp_offset);
RegAddr = CGF.Builder.CreateBitCast(RegAddr,
llvm::PointerType::getUnqual(LTy));
// Copy to a temporary if necessary to ensure the appropriate alignment.
std::pair<CharUnits, CharUnits> SizeAlign =
CGF.getContext().getTypeInfoInChars(Ty);
uint64_t TySize = SizeAlign.first.getQuantity();
unsigned TyAlign = SizeAlign.second.getQuantity();
if (TyAlign > 8) {
llvm::Value *Tmp = CGF.CreateMemTemp(Ty);
CGF.Builder.CreateMemCpy(Tmp, RegAddr, TySize, 8, false);
RegAddr = Tmp;
}
} else if (neededSSE == 1) {
RegAddr = CGF.Builder.CreateGEP(RegAddr, fp_offset);
RegAddr = CGF.Builder.CreateBitCast(RegAddr,
llvm::PointerType::getUnqual(LTy));
} else {
assert(neededSSE == 2 && "Invalid number of needed registers!");
// SSE registers are spaced 16 bytes apart in the register save
// area, we need to collect the two eightbytes together.
llvm::Value *RegAddrLo = CGF.Builder.CreateGEP(RegAddr, fp_offset);
2010-06-29 05:43:59 +08:00
llvm::Value *RegAddrHi = CGF.Builder.CreateConstGEP1_32(RegAddrLo, 16);
llvm::Type *DoubleTy = CGF.DoubleTy;
llvm::Type *DblPtrTy =
llvm::PointerType::getUnqual(DoubleTy);
llvm::StructType *ST = llvm::StructType::get(DoubleTy, DoubleTy, NULL);
llvm::Value *V, *Tmp = CGF.CreateMemTemp(Ty);
Tmp = CGF.Builder.CreateBitCast(Tmp, ST->getPointerTo());
V = CGF.Builder.CreateLoad(CGF.Builder.CreateBitCast(RegAddrLo,
DblPtrTy));
CGF.Builder.CreateStore(V, CGF.Builder.CreateStructGEP(Tmp, 0));
V = CGF.Builder.CreateLoad(CGF.Builder.CreateBitCast(RegAddrHi,
DblPtrTy));
CGF.Builder.CreateStore(V, CGF.Builder.CreateStructGEP(Tmp, 1));
RegAddr = CGF.Builder.CreateBitCast(Tmp,
llvm::PointerType::getUnqual(LTy));
}
// AMD64-ABI 3.5.7p5: Step 5. Set:
// l->gp_offset = l->gp_offset + num_gp * 8
// l->fp_offset = l->fp_offset + num_fp * 16.
if (neededInt) {
llvm::Value *Offset = llvm::ConstantInt::get(CGF.Int32Ty, neededInt * 8);
CGF.Builder.CreateStore(CGF.Builder.CreateAdd(gp_offset, Offset),
gp_offset_p);
}
if (neededSSE) {
llvm::Value *Offset = llvm::ConstantInt::get(CGF.Int32Ty, neededSSE * 16);
CGF.Builder.CreateStore(CGF.Builder.CreateAdd(fp_offset, Offset),
fp_offset_p);
}
CGF.EmitBranch(ContBlock);
// Emit code to load the value if it was passed in memory.
CGF.EmitBlock(InMemBlock);
llvm::Value *MemAddr = EmitVAArgFromMemory(VAListAddr, Ty, CGF);
// Return the appropriate result.
CGF.EmitBlock(ContBlock);
llvm::PHINode *ResAddr = CGF.Builder.CreatePHI(RegAddr->getType(), 2,
"vaarg.addr");
ResAddr->addIncoming(RegAddr, InRegBlock);
ResAddr->addIncoming(MemAddr, InMemBlock);
return ResAddr;
}
ABIArgInfo WinX86_64ABIInfo::classify(QualType Ty, bool IsReturnType) const {
if (Ty->isVoidType())
return ABIArgInfo::getIgnore();
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
uint64_t Size = getContext().getTypeSize(Ty);
if (const RecordType *RT = Ty->getAs<RecordType>()) {
if (IsReturnType) {
if (isRecordReturnIndirect(RT, getCXXABI()))
return ABIArgInfo::getIndirect(0, false);
} else {
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(RT, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
}
if (RT->getDecl()->hasFlexibleArrayMember())
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
// FIXME: mingw-w64-gcc emits 128-bit struct as i128
if (Size == 128 && getTarget().getTriple().getOS() == llvm::Triple::MinGW32)
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
Size));
// MS x64 ABI requirement: "Any argument that doesn't fit in 8 bytes, or is
// not 1, 2, 4, or 8 bytes, must be passed by reference."
if (Size <= 64 &&
(Size & (Size - 1)) == 0)
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
Size));
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
}
if (Ty->isPromotableIntegerType())
return ABIArgInfo::getExtend();
return ABIArgInfo::getDirect();
}
void WinX86_64ABIInfo::computeInfo(CGFunctionInfo &FI) const {
QualType RetTy = FI.getReturnType();
FI.getReturnInfo() = classify(RetTy, true);
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classify(it->type, false);
}
llvm::Value *WinX86_64ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP,
"ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
llvm::Type *PTy =
llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
llvm::Value *AddrTyped = Builder.CreateBitCast(Addr, PTy);
uint64_t Offset =
llvm::RoundUpToAlignment(CGF.getContext().getTypeSize(Ty) / 8, 8);
llvm::Value *NextAddr =
Builder.CreateGEP(Addr, llvm::ConstantInt::get(CGF.Int32Ty, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
return AddrTyped;
}
namespace {
class NaClX86_64ABIInfo : public ABIInfo {
public:
NaClX86_64ABIInfo(CodeGen::CodeGenTypes &CGT, bool HasAVX)
: ABIInfo(CGT), PInfo(CGT), NInfo(CGT, HasAVX) {}
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
private:
PNaClABIInfo PInfo; // Used for generating calls with pnaclcall callingconv.
X86_64ABIInfo NInfo; // Used for everything else.
};
class NaClX86_64TargetCodeGenInfo : public TargetCodeGenInfo {
public:
NaClX86_64TargetCodeGenInfo(CodeGen::CodeGenTypes &CGT, bool HasAVX)
: TargetCodeGenInfo(new NaClX86_64ABIInfo(CGT, HasAVX)) {}
};
}
void NaClX86_64ABIInfo::computeInfo(CGFunctionInfo &FI) const {
if (FI.getASTCallingConvention() == CC_PnaclCall)
PInfo.computeInfo(FI);
else
NInfo.computeInfo(FI);
}
llvm::Value *NaClX86_64ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// Always use the native convention; calling pnacl-style varargs functions
// is unuspported.
return NInfo.EmitVAArg(VAListAddr, Ty, CGF);
}
// PowerPC-32
namespace {
class PPC32TargetCodeGenInfo : public DefaultTargetCodeGenInfo {
public:
PPC32TargetCodeGenInfo(CodeGenTypes &CGT) : DefaultTargetCodeGenInfo(CGT) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
// This is recovered from gcc output.
return 1; // r1 is the dedicated stack pointer
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
};
}
bool
PPC32TargetCodeGenInfo::initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
// This is calculated from the LLVM and GCC tables and verified
// against gcc output. AFAIK all ABIs use the same encoding.
CodeGen::CGBuilderTy &Builder = CGF.Builder;
llvm::IntegerType *i8 = CGF.Int8Ty;
llvm::Value *Four8 = llvm::ConstantInt::get(i8, 4);
llvm::Value *Eight8 = llvm::ConstantInt::get(i8, 8);
llvm::Value *Sixteen8 = llvm::ConstantInt::get(i8, 16);
// 0-31: r0-31, the 4-byte general-purpose registers
AssignToArrayRange(Builder, Address, Four8, 0, 31);
// 32-63: fp0-31, the 8-byte floating-point registers
AssignToArrayRange(Builder, Address, Eight8, 32, 63);
// 64-76 are various 4-byte special-purpose registers:
// 64: mq
// 65: lr
// 66: ctr
// 67: ap
// 68-75 cr0-7
// 76: xer
AssignToArrayRange(Builder, Address, Four8, 64, 76);
// 77-108: v0-31, the 16-byte vector registers
AssignToArrayRange(Builder, Address, Sixteen8, 77, 108);
// 109: vrsave
// 110: vscr
// 111: spe_acc
// 112: spefscr
// 113: sfp
AssignToArrayRange(Builder, Address, Four8, 109, 113);
return false;
}
// PowerPC-64
namespace {
/// PPC64_SVR4_ABIInfo - The 64-bit PowerPC ELF (SVR4) ABI information.
class PPC64_SVR4_ABIInfo : public DefaultABIInfo {
public:
PPC64_SVR4_ABIInfo(CodeGen::CodeGenTypes &CGT) : DefaultABIInfo(CGT) {}
bool isPromotableTypeForABI(QualType Ty) const;
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType Ty) const;
// TODO: We can add more logic to computeInfo to improve performance.
// Example: For aggregate arguments that fit in a register, we could
// use getDirectInReg (as is done below for structs containing a single
// floating-point value) to avoid pushing them to memory on function
// entry. This would require changing the logic in PPCISelLowering
// when lowering the parameters in the caller and args in the callee.
virtual void computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it) {
// We rely on the default argument classification for the most part.
// One exception: An aggregate containing a single floating-point
// or vector item must be passed in a register if one is available.
const Type *T = isSingleElementStruct(it->type, getContext());
if (T) {
const BuiltinType *BT = T->getAs<BuiltinType>();
if (T->isVectorType() || (BT && BT->isFloatingPoint())) {
QualType QT(T, 0);
it->info = ABIArgInfo::getDirectInReg(CGT.ConvertType(QT));
continue;
}
}
it->info = classifyArgumentType(it->type);
}
}
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr,
QualType Ty,
CodeGenFunction &CGF) const;
};
class PPC64_SVR4_TargetCodeGenInfo : public TargetCodeGenInfo {
public:
PPC64_SVR4_TargetCodeGenInfo(CodeGenTypes &CGT)
: TargetCodeGenInfo(new PPC64_SVR4_ABIInfo(CGT)) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
// This is recovered from gcc output.
return 1; // r1 is the dedicated stack pointer
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
};
class PPC64TargetCodeGenInfo : public DefaultTargetCodeGenInfo {
public:
PPC64TargetCodeGenInfo(CodeGenTypes &CGT) : DefaultTargetCodeGenInfo(CGT) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
// This is recovered from gcc output.
return 1; // r1 is the dedicated stack pointer
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
};
}
// Return true if the ABI requires Ty to be passed sign- or zero-
// extended to 64 bits.
bool
PPC64_SVR4_ABIInfo::isPromotableTypeForABI(QualType Ty) const {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
// Promotable integer types are required to be promoted by the ABI.
if (Ty->isPromotableIntegerType())
return true;
// In addition to the usual promotable integer types, we also need to
// extend all 32-bit types, since the ABI requires promotion to 64 bits.
if (const BuiltinType *BT = Ty->getAs<BuiltinType>())
switch (BT->getKind()) {
case BuiltinType::Int:
case BuiltinType::UInt:
return true;
default:
break;
}
return false;
}
ABIArgInfo
PPC64_SVR4_ABIInfo::classifyArgumentType(QualType Ty) const {
if (Ty->isAnyComplexType())
return ABIArgInfo::getDirect();
if (isAggregateTypeForABI(Ty)) {
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
return ABIArgInfo::getIndirect(0);
}
return (isPromotableTypeForABI(Ty) ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
ABIArgInfo
PPC64_SVR4_ABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
if (RetTy->isAnyComplexType())
return ABIArgInfo::getDirect();
if (isAggregateTypeForABI(RetTy))
return ABIArgInfo::getIndirect(0);
return (isPromotableTypeForABI(RetTy) ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
// Based on ARMABIInfo::EmitVAArg, adjusted for 64-bit machine.
llvm::Value *PPC64_SVR4_ABIInfo::EmitVAArg(llvm::Value *VAListAddr,
QualType Ty,
CodeGenFunction &CGF) const {
llvm::Type *BP = CGF.Int8PtrTy;
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP, "ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
// Update the va_list pointer. The pointer should be bumped by the
// size of the object. We can trust getTypeSize() except for a complex
// type whose base type is smaller than a doubleword. For these, the
// size of the object is 16 bytes; see below for further explanation.
unsigned SizeInBytes = CGF.getContext().getTypeSize(Ty) / 8;
QualType BaseTy;
unsigned CplxBaseSize = 0;
if (const ComplexType *CTy = Ty->getAs<ComplexType>()) {
BaseTy = CTy->getElementType();
CplxBaseSize = CGF.getContext().getTypeSize(BaseTy) / 8;
if (CplxBaseSize < 8)
SizeInBytes = 16;
}
unsigned Offset = llvm::RoundUpToAlignment(SizeInBytes, 8);
llvm::Value *NextAddr =
Builder.CreateGEP(Addr, llvm::ConstantInt::get(CGF.Int64Ty, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
// If we have a complex type and the base type is smaller than 8 bytes,
// the ABI calls for the real and imaginary parts to be right-adjusted
// in separate doublewords. However, Clang expects us to produce a
// pointer to a structure with the two parts packed tightly. So generate
// loads of the real and imaginary parts relative to the va_list pointer,
// and store them to a temporary structure.
if (CplxBaseSize && CplxBaseSize < 8) {
llvm::Value *RealAddr = Builder.CreatePtrToInt(Addr, CGF.Int64Ty);
llvm::Value *ImagAddr = RealAddr;
RealAddr = Builder.CreateAdd(RealAddr, Builder.getInt64(8 - CplxBaseSize));
ImagAddr = Builder.CreateAdd(ImagAddr, Builder.getInt64(16 - CplxBaseSize));
llvm::Type *PBaseTy = llvm::PointerType::getUnqual(CGF.ConvertType(BaseTy));
RealAddr = Builder.CreateIntToPtr(RealAddr, PBaseTy);
ImagAddr = Builder.CreateIntToPtr(ImagAddr, PBaseTy);
llvm::Value *Real = Builder.CreateLoad(RealAddr, false, ".vareal");
llvm::Value *Imag = Builder.CreateLoad(ImagAddr, false, ".vaimag");
llvm::Value *Ptr = CGF.CreateTempAlloca(CGT.ConvertTypeForMem(Ty),
"vacplx");
llvm::Value *RealPtr = Builder.CreateStructGEP(Ptr, 0, ".real");
llvm::Value *ImagPtr = Builder.CreateStructGEP(Ptr, 1, ".imag");
Builder.CreateStore(Real, RealPtr, false);
Builder.CreateStore(Imag, ImagPtr, false);
return Ptr;
}
// If the argument is smaller than 8 bytes, it is right-adjusted in
// its doubleword slot. Adjust the pointer to pick it up from the
// correct offset.
if (SizeInBytes < 8) {
llvm::Value *AddrAsInt = Builder.CreatePtrToInt(Addr, CGF.Int64Ty);
AddrAsInt = Builder.CreateAdd(AddrAsInt, Builder.getInt64(8 - SizeInBytes));
Addr = Builder.CreateIntToPtr(AddrAsInt, BP);
}
llvm::Type *PTy = llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
return Builder.CreateBitCast(Addr, PTy);
}
static bool
PPC64_initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) {
// This is calculated from the LLVM and GCC tables and verified
// against gcc output. AFAIK all ABIs use the same encoding.
CodeGen::CGBuilderTy &Builder = CGF.Builder;
llvm::IntegerType *i8 = CGF.Int8Ty;
llvm::Value *Four8 = llvm::ConstantInt::get(i8, 4);
llvm::Value *Eight8 = llvm::ConstantInt::get(i8, 8);
llvm::Value *Sixteen8 = llvm::ConstantInt::get(i8, 16);
// 0-31: r0-31, the 8-byte general-purpose registers
AssignToArrayRange(Builder, Address, Eight8, 0, 31);
// 32-63: fp0-31, the 8-byte floating-point registers
AssignToArrayRange(Builder, Address, Eight8, 32, 63);
// 64-76 are various 4-byte special-purpose registers:
// 64: mq
// 65: lr
// 66: ctr
// 67: ap
// 68-75 cr0-7
// 76: xer
AssignToArrayRange(Builder, Address, Four8, 64, 76);
// 77-108: v0-31, the 16-byte vector registers
AssignToArrayRange(Builder, Address, Sixteen8, 77, 108);
// 109: vrsave
// 110: vscr
// 111: spe_acc
// 112: spefscr
// 113: sfp
AssignToArrayRange(Builder, Address, Four8, 109, 113);
return false;
}
bool
PPC64_SVR4_TargetCodeGenInfo::initDwarfEHRegSizeTable(
CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
return PPC64_initDwarfEHRegSizeTable(CGF, Address);
}
bool
PPC64TargetCodeGenInfo::initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
return PPC64_initDwarfEHRegSizeTable(CGF, Address);
}
//===----------------------------------------------------------------------===//
2009-09-12 08:59:49 +08:00
// ARM ABI Implementation
//===----------------------------------------------------------------------===//
2009-09-12 08:59:49 +08:00
namespace {
class ARMABIInfo : public ABIInfo {
public:
enum ABIKind {
APCS = 0,
AAPCS = 1,
AAPCS_VFP
};
private:
ABIKind Kind;
mutable int VFPRegs[16];
const unsigned NumVFPs;
const unsigned NumGPRs;
mutable unsigned AllocatedGPRs;
mutable unsigned AllocatedVFPs;
public:
ARMABIInfo(CodeGenTypes &CGT, ABIKind _Kind) : ABIInfo(CGT), Kind(_Kind),
NumVFPs(16), NumGPRs(4) {
setRuntimeCC();
resetAllocatedRegs();
}
bool isEABI() const {
switch (getTarget().getTriple().getEnvironment()) {
case llvm::Triple::Android:
case llvm::Triple::EABI:
case llvm::Triple::EABIHF:
case llvm::Triple::GNUEABI:
case llvm::Triple::GNUEABIHF:
return true;
default:
return false;
}
}
bool isEABIHF() const {
switch (getTarget().getTriple().getEnvironment()) {
case llvm::Triple::EABIHF:
case llvm::Triple::GNUEABIHF:
return true;
default:
return false;
}
}
ABIKind getABIKind() const { return Kind; }
private:
ABIArgInfo classifyReturnType(QualType RetTy, bool isVariadic) const;
ABIArgInfo classifyArgumentType(QualType RetTy, bool &IsHA, bool isVariadic,
bool &IsCPRC) const;
bool isIllegalVectorType(QualType Ty) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
llvm::CallingConv::ID getLLVMDefaultCC() const;
llvm::CallingConv::ID getABIDefaultCC() const;
void setRuntimeCC();
void markAllocatedGPRs(unsigned Alignment, unsigned NumRequired) const;
void markAllocatedVFPs(unsigned Alignment, unsigned NumRequired) const;
void resetAllocatedRegs(void) const;
};
class ARMTargetCodeGenInfo : public TargetCodeGenInfo {
public:
ARMTargetCodeGenInfo(CodeGenTypes &CGT, ARMABIInfo::ABIKind K)
:TargetCodeGenInfo(new ARMABIInfo(CGT, K)) {}
const ARMABIInfo &getABIInfo() const {
return static_cast<const ARMABIInfo&>(TargetCodeGenInfo::getABIInfo());
}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
return 13;
}
StringRef getARCRetainAutoreleasedReturnValueMarker() const {
return "mov\tr7, r7\t\t@ marker for objc_retainAutoreleaseReturnValue";
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
llvm::Value *Four8 = llvm::ConstantInt::get(CGF.Int8Ty, 4);
// 0-15 are the 16 integer registers.
AssignToArrayRange(CGF.Builder, Address, Four8, 0, 15);
return false;
}
unsigned getSizeOfUnwindException() const {
if (getABIInfo().isEABI()) return 88;
return TargetCodeGenInfo::getSizeOfUnwindException();
}
void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &CGM) const {
const FunctionDecl *FD = dyn_cast<FunctionDecl>(D);
if (!FD)
return;
const ARMInterruptAttr *Attr = FD->getAttr<ARMInterruptAttr>();
if (!Attr)
return;
const char *Kind;
switch (Attr->getInterrupt()) {
case ARMInterruptAttr::Generic: Kind = ""; break;
case ARMInterruptAttr::IRQ: Kind = "IRQ"; break;
case ARMInterruptAttr::FIQ: Kind = "FIQ"; break;
case ARMInterruptAttr::SWI: Kind = "SWI"; break;
case ARMInterruptAttr::ABORT: Kind = "ABORT"; break;
case ARMInterruptAttr::UNDEF: Kind = "UNDEF"; break;
}
llvm::Function *Fn = cast<llvm::Function>(GV);
Fn->addFnAttr("interrupt", Kind);
if (cast<ARMABIInfo>(getABIInfo()).getABIKind() == ARMABIInfo::APCS)
return;
// AAPCS guarantees that sp will be 8-byte aligned on any public interface,
// however this is not necessarily true on taking any interrupt. Instruct
// the backend to perform a realignment as part of the function prologue.
llvm::AttrBuilder B;
B.addStackAlignmentAttr(8);
Fn->addAttributes(llvm::AttributeSet::FunctionIndex,
llvm::AttributeSet::get(CGM.getLLVMContext(),
llvm::AttributeSet::FunctionIndex,
B));
}
};
2009-09-12 08:59:49 +08:00
}
void ARMABIInfo::computeInfo(CGFunctionInfo &FI) const {
// To correctly handle Homogeneous Aggregate, we need to keep track of the
// VFP registers allocated so far.
// C.1.vfp If the argument is a VFP CPRC and there are sufficient consecutive
// VFP registers of the appropriate type unallocated then the argument is
// allocated to the lowest-numbered sequence of such registers.
// C.2.vfp If the argument is a VFP CPRC then any VFP registers that are
// unallocated are marked as unavailable.
resetAllocatedRegs();
FI.getReturnInfo() = classifyReturnType(FI.getReturnType(), FI.isVariadic());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it) {
unsigned PreAllocationVFPs = AllocatedVFPs;
unsigned PreAllocationGPRs = AllocatedGPRs;
bool IsHA = false;
bool IsCPRC = false;
// 6.1.2.3 There is one VFP co-processor register class using registers
// s0-s15 (d0-d7) for passing arguments.
it->info = classifyArgumentType(it->type, IsHA, FI.isVariadic(), IsCPRC);
assert((IsCPRC || !IsHA) && "Homogeneous aggregates must be CPRCs");
// If we do not have enough VFP registers for the HA, any VFP registers
// that are unallocated are marked as unavailable. To achieve this, we add
// padding of (NumVFPs - PreAllocationVFP) floats.
// Note that IsHA will only be set when using the AAPCS-VFP calling convention,
// and the callee is not variadic.
if (IsHA && AllocatedVFPs > NumVFPs && PreAllocationVFPs < NumVFPs) {
llvm::Type *PaddingTy = llvm::ArrayType::get(
llvm::Type::getFloatTy(getVMContext()), NumVFPs - PreAllocationVFPs);
it->info = ABIArgInfo::getExpandWithPadding(false, PaddingTy);
}
// If we have allocated some arguments onto the stack (due to running
// out of VFP registers), we cannot split an argument between GPRs and
// the stack. If this situation occurs, we add padding to prevent the
// GPRs from being used. In this situiation, the current argument could
// only be allocated by rule C.8, so rule C.6 would mark these GPRs as
// unusable anyway.
const bool StackUsed = PreAllocationGPRs > NumGPRs || PreAllocationVFPs > NumVFPs;
if (!IsCPRC && PreAllocationGPRs < NumGPRs && AllocatedGPRs > NumGPRs && StackUsed) {
llvm::Type *PaddingTy = llvm::ArrayType::get(
llvm::Type::getInt32Ty(getVMContext()), NumGPRs - PreAllocationGPRs);
it->info = ABIArgInfo::getExpandWithPadding(false, PaddingTy);
}
}
// Always honor user-specified calling convention.
if (FI.getCallingConvention() != llvm::CallingConv::C)
return;
llvm::CallingConv::ID cc = getRuntimeCC();
if (cc != llvm::CallingConv::C)
FI.setEffectiveCallingConvention(cc);
}
/// Return the default calling convention that LLVM will use.
llvm::CallingConv::ID ARMABIInfo::getLLVMDefaultCC() const {
// The default calling convention that LLVM will infer.
if (isEABIHF())
return llvm::CallingConv::ARM_AAPCS_VFP;
else if (isEABI())
return llvm::CallingConv::ARM_AAPCS;
else
return llvm::CallingConv::ARM_APCS;
}
/// Return the calling convention that our ABI would like us to use
/// as the C calling convention.
llvm::CallingConv::ID ARMABIInfo::getABIDefaultCC() const {
switch (getABIKind()) {
case APCS: return llvm::CallingConv::ARM_APCS;
case AAPCS: return llvm::CallingConv::ARM_AAPCS;
case AAPCS_VFP: return llvm::CallingConv::ARM_AAPCS_VFP;
}
llvm_unreachable("bad ABI kind");
}
void ARMABIInfo::setRuntimeCC() {
assert(getRuntimeCC() == llvm::CallingConv::C);
// Don't muddy up the IR with a ton of explicit annotations if
// they'd just match what LLVM will infer from the triple.
llvm::CallingConv::ID abiCC = getABIDefaultCC();
if (abiCC != getLLVMDefaultCC())
RuntimeCC = abiCC;
}
/// isHomogeneousAggregate - Return true if a type is an AAPCS-VFP homogeneous
/// aggregate. If HAMembers is non-null, the number of base elements
/// contained in the type is returned through it; this is used for the
/// recursive calls that check aggregate component types.
static bool isHomogeneousAggregate(QualType Ty, const Type *&Base,
ASTContext &Context,
uint64_t *HAMembers = 0) {
uint64_t Members = 0;
if (const ConstantArrayType *AT = Context.getAsConstantArrayType(Ty)) {
if (!isHomogeneousAggregate(AT->getElementType(), Base, Context, &Members))
return false;
Members *= AT->getSize().getZExtValue();
} else if (const RecordType *RT = Ty->getAs<RecordType>()) {
const RecordDecl *RD = RT->getDecl();
if (RD->hasFlexibleArrayMember())
return false;
Members = 0;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i) {
const FieldDecl *FD = *i;
uint64_t FldMembers;
if (!isHomogeneousAggregate(FD->getType(), Base, Context, &FldMembers))
return false;
Members = (RD->isUnion() ?
std::max(Members, FldMembers) : Members + FldMembers);
}
} else {
Members = 1;
if (const ComplexType *CT = Ty->getAs<ComplexType>()) {
Members = 2;
Ty = CT->getElementType();
}
// Homogeneous aggregates for AAPCS-VFP must have base types of float,
// double, or 64-bit or 128-bit vectors.
if (const BuiltinType *BT = Ty->getAs<BuiltinType>()) {
if (BT->getKind() != BuiltinType::Float &&
BT->getKind() != BuiltinType::Double &&
BT->getKind() != BuiltinType::LongDouble)
return false;
} else if (const VectorType *VT = Ty->getAs<VectorType>()) {
unsigned VecSize = Context.getTypeSize(VT);
if (VecSize != 64 && VecSize != 128)
return false;
} else {
return false;
}
// The base type must be the same for all members. Vector types of the
// same total size are treated as being equivalent here.
const Type *TyPtr = Ty.getTypePtr();
if (!Base)
Base = TyPtr;
if (Base != TyPtr) {
// Homogeneous aggregates are defined as containing members with the
// same machine type. There are two cases in which two members have
// different TypePtrs but the same machine type:
// 1) Vectors of the same length, regardless of the type and number
// of their members.
const bool SameLengthVectors = Base->isVectorType() && TyPtr->isVectorType()
&& (Context.getTypeSize(Base) == Context.getTypeSize(TyPtr));
// 2) In the 32-bit AAPCS, `double' and `long double' have the same
// machine type. This is not the case for the 64-bit AAPCS.
const bool SameSizeDoubles =
( ( Base->isSpecificBuiltinType(BuiltinType::Double)
&& TyPtr->isSpecificBuiltinType(BuiltinType::LongDouble))
|| ( Base->isSpecificBuiltinType(BuiltinType::LongDouble)
&& TyPtr->isSpecificBuiltinType(BuiltinType::Double)))
&& (Context.getTypeSize(Base) == Context.getTypeSize(TyPtr));
if (!SameLengthVectors && !SameSizeDoubles)
return false;
}
}
// Homogeneous Aggregates can have at most 4 members of the base type.
if (HAMembers)
*HAMembers = Members;
return (Members > 0 && Members <= 4);
}
/// markAllocatedVFPs - update VFPRegs according to the alignment and
/// number of VFP registers (unit is S register) requested.
void ARMABIInfo::markAllocatedVFPs(unsigned Alignment,
unsigned NumRequired) const {
// Early Exit.
if (AllocatedVFPs >= 16) {
// We use AllocatedVFP > 16 to signal that some CPRCs were allocated on
// the stack.
AllocatedVFPs = 17;
return;
}
// C.1.vfp If the argument is a VFP CPRC and there are sufficient consecutive
// VFP registers of the appropriate type unallocated then the argument is
// allocated to the lowest-numbered sequence of such registers.
for (unsigned I = 0; I < 16; I += Alignment) {
bool FoundSlot = true;
for (unsigned J = I, JEnd = I + NumRequired; J < JEnd; J++)
if (J >= 16 || VFPRegs[J]) {
FoundSlot = false;
break;
}
if (FoundSlot) {
for (unsigned J = I, JEnd = I + NumRequired; J < JEnd; J++)
VFPRegs[J] = 1;
AllocatedVFPs += NumRequired;
return;
}
}
// C.2.vfp If the argument is a VFP CPRC then any VFP registers that are
// unallocated are marked as unavailable.
for (unsigned I = 0; I < 16; I++)
VFPRegs[I] = 1;
AllocatedVFPs = 17; // We do not have enough VFP registers.
}
/// Update AllocatedGPRs to record the number of general purpose registers
/// which have been allocated. It is valid for AllocatedGPRs to go above 4,
/// this represents arguments being stored on the stack.
void ARMABIInfo::markAllocatedGPRs(unsigned Alignment,
unsigned NumRequired) const {
assert((Alignment == 1 || Alignment == 2) && "Alignment must be 4 or 8 bytes");
if (Alignment == 2 && AllocatedGPRs & 0x1)
AllocatedGPRs += 1;
AllocatedGPRs += NumRequired;
}
void ARMABIInfo::resetAllocatedRegs(void) const {
AllocatedGPRs = 0;
AllocatedVFPs = 0;
for (unsigned i = 0; i < NumVFPs; ++i)
VFPRegs[i] = 0;
}
ABIArgInfo ARMABIInfo::classifyArgumentType(QualType Ty, bool &IsHA,
bool isVariadic,
bool &IsCPRC) const {
// We update number of allocated VFPs according to
// 6.1.2.1 The following argument types are VFP CPRCs:
// A single-precision floating-point type (including promoted
// half-precision types); A double-precision floating-point type;
// A 64-bit or 128-bit containerized vector type; Homogeneous Aggregate
// with a Base Type of a single- or double-precision floating-point type,
// 64-bit containerized vectors or 128-bit containerized vectors with one
// to four Elements.
// Handle illegal vector types here.
if (isIllegalVectorType(Ty)) {
uint64_t Size = getContext().getTypeSize(Ty);
if (Size <= 32) {
llvm::Type *ResType =
llvm::Type::getInt32Ty(getVMContext());
markAllocatedGPRs(1, 1);
return ABIArgInfo::getDirect(ResType);
}
if (Size == 64) {
llvm::Type *ResType = llvm::VectorType::get(
llvm::Type::getInt32Ty(getVMContext()), 2);
if (getABIKind() == ARMABIInfo::AAPCS || isVariadic){
markAllocatedGPRs(2, 2);
} else {
markAllocatedVFPs(2, 2);
IsCPRC = true;
}
return ABIArgInfo::getDirect(ResType);
}
if (Size == 128) {
llvm::Type *ResType = llvm::VectorType::get(
llvm::Type::getInt32Ty(getVMContext()), 4);
if (getABIKind() == ARMABIInfo::AAPCS || isVariadic) {
markAllocatedGPRs(2, 4);
} else {
markAllocatedVFPs(4, 4);
IsCPRC = true;
}
return ABIArgInfo::getDirect(ResType);
}
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
}
// Update VFPRegs for legal vector types.
if (getABIKind() == ARMABIInfo::AAPCS_VFP && !isVariadic) {
if (const VectorType *VT = Ty->getAs<VectorType>()) {
uint64_t Size = getContext().getTypeSize(VT);
// Size of a legal vector should be power of 2 and above 64.
markAllocatedVFPs(Size >= 128 ? 4 : 2, Size / 32);
IsCPRC = true;
}
}
// Update VFPRegs for floating point types.
if (getABIKind() == ARMABIInfo::AAPCS_VFP && !isVariadic) {
if (const BuiltinType *BT = Ty->getAs<BuiltinType>()) {
if (BT->getKind() == BuiltinType::Half ||
BT->getKind() == BuiltinType::Float) {
markAllocatedVFPs(1, 1);
IsCPRC = true;
}
if (BT->getKind() == BuiltinType::Double ||
BT->getKind() == BuiltinType::LongDouble) {
markAllocatedVFPs(2, 2);
IsCPRC = true;
}
}
}
if (!isAggregateTypeForABI(Ty)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>()) {
Ty = EnumTy->getDecl()->getIntegerType();
}
unsigned Size = getContext().getTypeSize(Ty);
if (!IsCPRC)
markAllocatedGPRs(Size > 32 ? 2 : 1, (Size + 31) / 32);
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI())) {
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
}
// Ignore empty records.
if (isEmptyRecord(getContext(), Ty, true))
return ABIArgInfo::getIgnore();
if (getABIKind() == ARMABIInfo::AAPCS_VFP && !isVariadic) {
// Homogeneous Aggregates need to be expanded when we can fit the aggregate
// into VFP registers.
const Type *Base = 0;
uint64_t Members = 0;
if (isHomogeneousAggregate(Ty, Base, getContext(), &Members)) {
assert(Base && "Base class should be set for homogeneous aggregate");
// Base can be a floating-point or a vector.
if (Base->isVectorType()) {
// ElementSize is in number of floats.
unsigned ElementSize = getContext().getTypeSize(Base) == 64 ? 2 : 4;
markAllocatedVFPs(ElementSize,
Members * ElementSize);
} else if (Base->isSpecificBuiltinType(BuiltinType::Float))
markAllocatedVFPs(1, Members);
else {
assert(Base->isSpecificBuiltinType(BuiltinType::Double) ||
Base->isSpecificBuiltinType(BuiltinType::LongDouble));
markAllocatedVFPs(2, Members * 2);
}
IsHA = true;
IsCPRC = true;
return ABIArgInfo::getExpand();
}
}
// Support byval for ARM.
// The ABI alignment for APCS is 4-byte and for AAPCS at least 4-byte and at
// most 8-byte. We realign the indirect argument if type alignment is bigger
// than ABI alignment.
uint64_t ABIAlign = 4;
uint64_t TyAlign = getContext().getTypeAlign(Ty) / 8;
if (getABIKind() == ARMABIInfo::AAPCS_VFP ||
getABIKind() == ARMABIInfo::AAPCS)
ABIAlign = std::min(std::max(TyAlign, (uint64_t)4), (uint64_t)8);
if (getContext().getTypeSizeInChars(Ty) > CharUnits::fromQuantity(64)) {
// Update Allocated GPRs
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0, /*ByVal=*/true,
/*Realign=*/TyAlign > ABIAlign);
}
// Otherwise, pass by coercing to a structure of the appropriate size.
llvm::Type* ElemTy;
unsigned SizeRegs;
// FIXME: Try to match the types of the arguments more accurately where
// we can.
if (getContext().getTypeAlign(Ty) <= 32) {
ElemTy = llvm::Type::getInt32Ty(getVMContext());
SizeRegs = (getContext().getTypeSize(Ty) + 31) / 32;
markAllocatedGPRs(1, SizeRegs);
} else {
ElemTy = llvm::Type::getInt64Ty(getVMContext());
SizeRegs = (getContext().getTypeSize(Ty) + 63) / 64;
markAllocatedGPRs(2, SizeRegs * 2);
}
llvm::Type *STy =
llvm::StructType::get(llvm::ArrayType::get(ElemTy, SizeRegs), NULL);
return ABIArgInfo::getDirect(STy);
}
static bool isIntegerLikeType(QualType Ty, ASTContext &Context,
llvm::LLVMContext &VMContext) {
// APCS, C Language Calling Conventions, Non-Simple Return Values: A structure
// is called integer-like if its size is less than or equal to one word, and
// the offset of each of its addressable sub-fields is zero.
uint64_t Size = Context.getTypeSize(Ty);
// Check that the type fits in a word.
if (Size > 32)
return false;
// FIXME: Handle vector types!
if (Ty->isVectorType())
return false;
// Float types are never treated as "integer like".
if (Ty->isRealFloatingType())
return false;
// If this is a builtin or pointer type then it is ok.
if (Ty->getAs<BuiltinType>() || Ty->isPointerType())
return true;
// Small complex integer types are "integer like".
if (const ComplexType *CT = Ty->getAs<ComplexType>())
return isIntegerLikeType(CT->getElementType(), Context, VMContext);
// Single element and zero sized arrays should be allowed, by the definition
// above, but they are not.
// Otherwise, it must be a record type.
const RecordType *RT = Ty->getAs<RecordType>();
if (!RT) return false;
// Ignore records with flexible arrays.
const RecordDecl *RD = RT->getDecl();
if (RD->hasFlexibleArrayMember())
return false;
// Check that all sub-fields are at offset 0, and are themselves "integer
// like".
const ASTRecordLayout &Layout = Context.getASTRecordLayout(RD);
bool HadField = false;
unsigned idx = 0;
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i, ++idx) {
const FieldDecl *FD = *i;
// Bit-fields are not addressable, we only need to verify they are "integer
// like". We still have to disallow a subsequent non-bitfield, for example:
// struct { int : 0; int x }
// is non-integer like according to gcc.
if (FD->isBitField()) {
if (!RD->isUnion())
HadField = true;
if (!isIntegerLikeType(FD->getType(), Context, VMContext))
return false;
continue;
}
// Check if this field is at offset 0.
if (Layout.getFieldOffset(idx) != 0)
return false;
if (!isIntegerLikeType(FD->getType(), Context, VMContext))
return false;
// Only allow at most one field in a structure. This doesn't match the
// wording above, but follows gcc in situations with a field following an
// empty structure.
if (!RD->isUnion()) {
if (HadField)
return false;
HadField = true;
}
}
return true;
}
ABIArgInfo ARMABIInfo::classifyReturnType(QualType RetTy,
bool isVariadic) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
// Large vector types should be returned via memory.
if (RetTy->isVectorType() && getContext().getTypeSize(RetTy) > 128) {
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0);
}
if (!isAggregateTypeForABI(RetTy)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
// Structures with either a non-trivial destructor or a non-trivial
// copy constructor are always indirect.
if (isRecordReturnIndirect(RetTy, getCXXABI())) {
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
}
// Are we following APCS?
if (getABIKind() == APCS) {
if (isEmptyRecord(getContext(), RetTy, false))
return ABIArgInfo::getIgnore();
// Complex types are all returned as packed integers.
//
// FIXME: Consider using 2 x vector types if the back end handles them
// correctly.
if (RetTy->isAnyComplexType())
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::IntegerType::get(getVMContext(),
getContext().getTypeSize(RetTy)));
// Integer like structures are returned in r0.
if (isIntegerLikeType(RetTy, getContext(), getVMContext())) {
// Return in the smallest viable integer type.
uint64_t Size = getContext().getTypeSize(RetTy);
if (Size <= 8)
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::Type::getInt8Ty(getVMContext()));
if (Size <= 16)
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::Type::getInt16Ty(getVMContext()));
return ABIArgInfo::getDirect(llvm::Type::getInt32Ty(getVMContext()));
}
// Otherwise return in memory.
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0);
}
// Otherwise this is an AAPCS variant.
if (isEmptyRecord(getContext(), RetTy, true))
return ABIArgInfo::getIgnore();
// Check for homogeneous aggregates with AAPCS-VFP.
if (getABIKind() == AAPCS_VFP && !isVariadic) {
const Type *Base = 0;
if (isHomogeneousAggregate(RetTy, Base, getContext())) {
assert(Base && "Base class should be set for homogeneous aggregate");
// Homogeneous Aggregates are returned directly.
return ABIArgInfo::getDirect();
}
}
// Aggregates <= 4 bytes are returned in r0; other aggregates
// are returned indirectly.
uint64_t Size = getContext().getTypeSize(RetTy);
if (Size <= 32) {
// Return in the smallest viable integer type.
if (Size <= 8)
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::Type::getInt8Ty(getVMContext()));
if (Size <= 16)
Kill off the 'coerce' ABI passing form. Now 'direct' and 'extend' always have a "coerce to" type which often matches the default lowering of Clang type to LLVM IR type, but the coerce case can be handled by making them not be the same. This simplifies things and fixes issues where X86-64 abi lowering would return coerce after making preferred types exactly match up. This caused us to compile: typedef float v4f32 __attribute__((__vector_size__(16))); v4f32 foo(v4f32 X) { return X+X; } into this code at -O0: define <4 x float> @foo(<4 x float> %X.coerce) nounwind { entry: %retval = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %coerce = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=2] %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X.coerce, <4 x float>* %coerce %X = load <4 x float>* %coerce ; <<4 x float>> [#uses=1] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] store <4 x float> %add, <4 x float>* %retval %0 = load <4 x float>* %retval ; <<4 x float>> [#uses=1] ret <4 x float> %0 } Now we get: define <4 x float> @foo(<4 x float> %X) nounwind { entry: %X.addr = alloca <4 x float>, align 16 ; <<4 x float>*> [#uses=3] store <4 x float> %X, <4 x float>* %X.addr %tmp = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %tmp1 = load <4 x float>* %X.addr ; <<4 x float>> [#uses=1] %add = fadd <4 x float> %tmp, %tmp1 ; <<4 x float>> [#uses=1] ret <4 x float> %add } This implements rdar://8248065 llvm-svn: 109733
2010-07-29 14:26:06 +08:00
return ABIArgInfo::getDirect(llvm::Type::getInt16Ty(getVMContext()));
return ABIArgInfo::getDirect(llvm::Type::getInt32Ty(getVMContext()));
}
markAllocatedGPRs(1, 1);
return ABIArgInfo::getIndirect(0);
}
/// isIllegalVector - check whether Ty is an illegal vector type.
bool ARMABIInfo::isIllegalVectorType(QualType Ty) const {
if (const VectorType *VT = Ty->getAs<VectorType>()) {
// Check whether VT is legal.
unsigned NumElements = VT->getNumElements();
uint64_t Size = getContext().getTypeSize(VT);
// NumElements should be power of 2.
if ((NumElements & (NumElements - 1)) != 0)
return true;
// Size should be greater than 32 bits.
return Size <= 32;
}
return false;
}
llvm::Value *ARMABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
llvm::Type *BP = CGF.Int8PtrTy;
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP, "ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
if (isEmptyRecord(getContext(), Ty, true)) {
// These are ignored for parameter passing purposes.
llvm::Type *PTy = llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
return Builder.CreateBitCast(Addr, PTy);
}
uint64_t Size = CGF.getContext().getTypeSize(Ty) / 8;
uint64_t TyAlign = CGF.getContext().getTypeAlign(Ty) / 8;
bool IsIndirect = false;
// The ABI alignment for 64-bit or 128-bit vectors is 8 for AAPCS and 4 for
// APCS. For AAPCS, the ABI alignment is at least 4-byte and at most 8-byte.
if (getABIKind() == ARMABIInfo::AAPCS_VFP ||
getABIKind() == ARMABIInfo::AAPCS)
TyAlign = std::min(std::max(TyAlign, (uint64_t)4), (uint64_t)8);
else
TyAlign = 4;
// Use indirect if size of the illegal vector is bigger than 16 bytes.
if (isIllegalVectorType(Ty) && Size > 16) {
IsIndirect = true;
Size = 4;
TyAlign = 4;
}
// Handle address alignment for ABI alignment > 4 bytes.
if (TyAlign > 4) {
assert((TyAlign & (TyAlign - 1)) == 0 &&
"Alignment is not power of 2!");
llvm::Value *AddrAsInt = Builder.CreatePtrToInt(Addr, CGF.Int32Ty);
AddrAsInt = Builder.CreateAdd(AddrAsInt, Builder.getInt32(TyAlign - 1));
AddrAsInt = Builder.CreateAnd(AddrAsInt, Builder.getInt32(~(TyAlign - 1)));
Addr = Builder.CreateIntToPtr(AddrAsInt, BP, "ap.align");
}
uint64_t Offset =
llvm::RoundUpToAlignment(Size, 4);
llvm::Value *NextAddr =
Builder.CreateGEP(Addr, llvm::ConstantInt::get(CGF.Int32Ty, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
if (IsIndirect)
Addr = Builder.CreateLoad(Builder.CreateBitCast(Addr, BPP));
else if (TyAlign < CGF.getContext().getTypeAlign(Ty) / 8) {
// We can't directly cast ap.cur to pointer to a vector type, since ap.cur
// may not be correctly aligned for the vector type. We create an aligned
// temporary space and copy the content over from ap.cur to the temporary
// space. This is necessary if the natural alignment of the type is greater
// than the ABI alignment.
llvm::Type *I8PtrTy = Builder.getInt8PtrTy();
CharUnits CharSize = getContext().getTypeSizeInChars(Ty);
llvm::Value *AlignedTemp = CGF.CreateTempAlloca(CGF.ConvertType(Ty),
"var.align");
llvm::Value *Dst = Builder.CreateBitCast(AlignedTemp, I8PtrTy);
llvm::Value *Src = Builder.CreateBitCast(Addr, I8PtrTy);
Builder.CreateMemCpy(Dst, Src,
llvm::ConstantInt::get(CGF.IntPtrTy, CharSize.getQuantity()),
TyAlign, false);
Addr = AlignedTemp; //The content is in aligned location.
}
llvm::Type *PTy =
llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
llvm::Value *AddrTyped = Builder.CreateBitCast(Addr, PTy);
return AddrTyped;
}
namespace {
class NaClARMABIInfo : public ABIInfo {
public:
NaClARMABIInfo(CodeGen::CodeGenTypes &CGT, ARMABIInfo::ABIKind Kind)
: ABIInfo(CGT), PInfo(CGT), NInfo(CGT, Kind) {}
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
private:
PNaClABIInfo PInfo; // Used for generating calls with pnaclcall callingconv.
ARMABIInfo NInfo; // Used for everything else.
};
class NaClARMTargetCodeGenInfo : public TargetCodeGenInfo {
public:
NaClARMTargetCodeGenInfo(CodeGen::CodeGenTypes &CGT, ARMABIInfo::ABIKind Kind)
: TargetCodeGenInfo(new NaClARMABIInfo(CGT, Kind)) {}
};
}
void NaClARMABIInfo::computeInfo(CGFunctionInfo &FI) const {
if (FI.getASTCallingConvention() == CC_PnaclCall)
PInfo.computeInfo(FI);
else
static_cast<const ABIInfo&>(NInfo).computeInfo(FI);
}
llvm::Value *NaClARMABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// Always use the native convention; calling pnacl-style varargs functions
// is unsupported.
return static_cast<const ABIInfo&>(NInfo).EmitVAArg(VAListAddr, Ty, CGF);
}
//===----------------------------------------------------------------------===//
// AArch64 ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class AArch64ABIInfo : public ABIInfo {
public:
AArch64ABIInfo(CodeGenTypes &CGT) : ABIInfo(CGT) {}
private:
// The AArch64 PCS is explicit about return types and argument types being
// handled identically, so we don't need to draw a distinction between
// Argument and Return classification.
ABIArgInfo classifyGenericType(QualType Ty, int &FreeIntRegs,
int &FreeVFPRegs) const;
ABIArgInfo tryUseRegs(QualType Ty, int &FreeRegs, int RegsNeeded, bool IsInt,
llvm::Type *DirectTy = 0) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class AArch64TargetCodeGenInfo : public TargetCodeGenInfo {
public:
AArch64TargetCodeGenInfo(CodeGenTypes &CGT)
:TargetCodeGenInfo(new AArch64ABIInfo(CGT)) {}
const AArch64ABIInfo &getABIInfo() const {
return static_cast<const AArch64ABIInfo&>(TargetCodeGenInfo::getABIInfo());
}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
return 31;
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
// 0-31 are x0-x30 and sp: 8 bytes each
llvm::Value *Eight8 = llvm::ConstantInt::get(CGF.Int8Ty, 8);
AssignToArrayRange(CGF.Builder, Address, Eight8, 0, 31);
// 64-95 are v0-v31: 16 bytes each
llvm::Value *Sixteen8 = llvm::ConstantInt::get(CGF.Int8Ty, 16);
AssignToArrayRange(CGF.Builder, Address, Sixteen8, 64, 95);
return false;
}
};
}
void AArch64ABIInfo::computeInfo(CGFunctionInfo &FI) const {
int FreeIntRegs = 8, FreeVFPRegs = 8;
FI.getReturnInfo() = classifyGenericType(FI.getReturnType(),
FreeIntRegs, FreeVFPRegs);
FreeIntRegs = FreeVFPRegs = 8;
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it) {
it->info = classifyGenericType(it->type, FreeIntRegs, FreeVFPRegs);
}
}
ABIArgInfo
AArch64ABIInfo::tryUseRegs(QualType Ty, int &FreeRegs, int RegsNeeded,
bool IsInt, llvm::Type *DirectTy) const {
if (FreeRegs >= RegsNeeded) {
FreeRegs -= RegsNeeded;
return ABIArgInfo::getDirect(DirectTy);
}
llvm::Type *Padding = 0;
// We need padding so that later arguments don't get filled in anyway. That
// wouldn't happen if only ByVal arguments followed in the same category, but
// a large structure will simply seem to be a pointer as far as LLVM is
// concerned.
if (FreeRegs > 0) {
if (IsInt)
Padding = llvm::Type::getInt64Ty(getVMContext());
else
Padding = llvm::Type::getFloatTy(getVMContext());
// Either [N x i64] or [N x float].
Padding = llvm::ArrayType::get(Padding, FreeRegs);
FreeRegs = 0;
}
return ABIArgInfo::getIndirect(getContext().getTypeAlign(Ty) / 8,
/*IsByVal=*/ true, /*Realign=*/ false,
Padding);
}
ABIArgInfo AArch64ABIInfo::classifyGenericType(QualType Ty,
int &FreeIntRegs,
int &FreeVFPRegs) const {
// Can only occurs for return, but harmless otherwise.
if (Ty->isVoidType())
return ABIArgInfo::getIgnore();
// Large vector types should be returned via memory. There's no such concept
// in the ABI, but they'd be over 16 bytes anyway so no matter how they're
// classified they'd go into memory (see B.3).
if (Ty->isVectorType() && getContext().getTypeSize(Ty) > 128) {
if (FreeIntRegs > 0)
--FreeIntRegs;
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
}
// All non-aggregate LLVM types have a concrete ABI representation so they can
// be passed directly. After this block we're guaranteed to be in a
// complicated case.
if (!isAggregateTypeForABI(Ty)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
if (Ty->isFloatingType() || Ty->isVectorType())
return tryUseRegs(Ty, FreeVFPRegs, /*RegsNeeded=*/ 1, /*IsInt=*/ false);
assert(getContext().getTypeSize(Ty) <= 128 &&
"unexpectedly large scalar type");
int RegsNeeded = getContext().getTypeSize(Ty) > 64 ? 2 : 1;
// If the type may need padding registers to ensure "alignment", we must be
// careful when this is accounted for. Increasing the effective size covers
// all cases.
if (getContext().getTypeAlign(Ty) == 128)
RegsNeeded += FreeIntRegs % 2 != 0;
return tryUseRegs(Ty, FreeIntRegs, RegsNeeded, /*IsInt=*/ true);
}
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI())) {
if (FreeIntRegs > 0 && RAA == CGCXXABI::RAA_Indirect)
--FreeIntRegs;
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
}
if (isEmptyRecord(getContext(), Ty, true)) {
if (!getContext().getLangOpts().CPlusPlus) {
// Empty structs outside C++ mode are a GNU extension, so no ABI can
// possibly tell us what to do. It turns out (I believe) that GCC ignores
// the object for parameter-passsing purposes.
return ABIArgInfo::getIgnore();
}
// The combination of C++98 9p5 (sizeof(struct) != 0) and the pseudocode
// description of va_arg in the PCS require that an empty struct does
// actually occupy space for parameter-passing. I'm hoping for a
// clarification giving an explicit paragraph to point to in future.
return tryUseRegs(Ty, FreeIntRegs, /*RegsNeeded=*/ 1, /*IsInt=*/ true,
llvm::Type::getInt8Ty(getVMContext()));
}
// Homogeneous vector aggregates get passed in registers or on the stack.
const Type *Base = 0;
uint64_t NumMembers = 0;
if (isHomogeneousAggregate(Ty, Base, getContext(), &NumMembers)) {
assert(Base && "Base class should be set for homogeneous aggregate");
// Homogeneous aggregates are passed and returned directly.
return tryUseRegs(Ty, FreeVFPRegs, /*RegsNeeded=*/ NumMembers,
/*IsInt=*/ false);
}
uint64_t Size = getContext().getTypeSize(Ty);
if (Size <= 128) {
// Small structs can use the same direct type whether they're in registers
// or on the stack.
llvm::Type *BaseTy;
unsigned NumBases;
int SizeInRegs = (Size + 63) / 64;
if (getContext().getTypeAlign(Ty) == 128) {
BaseTy = llvm::Type::getIntNTy(getVMContext(), 128);
NumBases = 1;
// If the type may need padding registers to ensure "alignment", we must
// be careful when this is accounted for. Increasing the effective size
// covers all cases.
SizeInRegs += FreeIntRegs % 2 != 0;
} else {
BaseTy = llvm::Type::getInt64Ty(getVMContext());
NumBases = SizeInRegs;
}
llvm::Type *DirectTy = llvm::ArrayType::get(BaseTy, NumBases);
return tryUseRegs(Ty, FreeIntRegs, /*RegsNeeded=*/ SizeInRegs,
/*IsInt=*/ true, DirectTy);
}
// If the aggregate is > 16 bytes, it's passed and returned indirectly. In
// LLVM terms the return uses an "sret" pointer, but that's handled elsewhere.
--FreeIntRegs;
return ABIArgInfo::getIndirect(0, /* byVal = */ false);
}
llvm::Value *AArch64ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// The AArch64 va_list type and handling is specified in the Procedure Call
// Standard, section B.4:
//
// struct {
// void *__stack;
// void *__gr_top;
// void *__vr_top;
// int __gr_offs;
// int __vr_offs;
// };
assert(!CGF.CGM.getDataLayout().isBigEndian()
&& "va_arg not implemented for big-endian AArch64");
int FreeIntRegs = 8, FreeVFPRegs = 8;
Ty = CGF.getContext().getCanonicalType(Ty);
ABIArgInfo AI = classifyGenericType(Ty, FreeIntRegs, FreeVFPRegs);
llvm::BasicBlock *MaybeRegBlock = CGF.createBasicBlock("vaarg.maybe_reg");
llvm::BasicBlock *InRegBlock = CGF.createBasicBlock("vaarg.in_reg");
llvm::BasicBlock *OnStackBlock = CGF.createBasicBlock("vaarg.on_stack");
llvm::BasicBlock *ContBlock = CGF.createBasicBlock("vaarg.end");
llvm::Value *reg_offs_p = 0, *reg_offs = 0;
int reg_top_index;
int RegSize;
if (FreeIntRegs < 8) {
assert(FreeVFPRegs == 8 && "Arguments never split between int & VFP regs");
// 3 is the field number of __gr_offs
reg_offs_p = CGF.Builder.CreateStructGEP(VAListAddr, 3, "gr_offs_p");
reg_offs = CGF.Builder.CreateLoad(reg_offs_p, "gr_offs");
reg_top_index = 1; // field number for __gr_top
RegSize = 8 * (8 - FreeIntRegs);
} else {
assert(FreeVFPRegs < 8 && "Argument must go in VFP or int regs");
// 4 is the field number of __vr_offs.
reg_offs_p = CGF.Builder.CreateStructGEP(VAListAddr, 4, "vr_offs_p");
reg_offs = CGF.Builder.CreateLoad(reg_offs_p, "vr_offs");
reg_top_index = 2; // field number for __vr_top
RegSize = 16 * (8 - FreeVFPRegs);
}
//=======================================
// Find out where argument was passed
//=======================================
// If reg_offs >= 0 we're already using the stack for this type of
// argument. We don't want to keep updating reg_offs (in case it overflows,
// though anyone passing 2GB of arguments, each at most 16 bytes, deserves
// whatever they get).
llvm::Value *UsingStack = 0;
UsingStack = CGF.Builder.CreateICmpSGE(reg_offs,
llvm::ConstantInt::get(CGF.Int32Ty, 0));
CGF.Builder.CreateCondBr(UsingStack, OnStackBlock, MaybeRegBlock);
// Otherwise, at least some kind of argument could go in these registers, the
// quesiton is whether this particular type is too big.
CGF.EmitBlock(MaybeRegBlock);
// Integer arguments may need to correct register alignment (for example a
// "struct { __int128 a; };" gets passed in x_2N, x_{2N+1}). In this case we
// align __gr_offs to calculate the potential address.
if (FreeIntRegs < 8 && AI.isDirect() && getContext().getTypeAlign(Ty) > 64) {
int Align = getContext().getTypeAlign(Ty) / 8;
reg_offs = CGF.Builder.CreateAdd(reg_offs,
llvm::ConstantInt::get(CGF.Int32Ty, Align - 1),
"align_regoffs");
reg_offs = CGF.Builder.CreateAnd(reg_offs,
llvm::ConstantInt::get(CGF.Int32Ty, -Align),
"aligned_regoffs");
}
// Update the gr_offs/vr_offs pointer for next call to va_arg on this va_list.
llvm::Value *NewOffset = 0;
NewOffset = CGF.Builder.CreateAdd(reg_offs,
llvm::ConstantInt::get(CGF.Int32Ty, RegSize),
"new_reg_offs");
CGF.Builder.CreateStore(NewOffset, reg_offs_p);
// Now we're in a position to decide whether this argument really was in
// registers or not.
llvm::Value *InRegs = 0;
InRegs = CGF.Builder.CreateICmpSLE(NewOffset,
llvm::ConstantInt::get(CGF.Int32Ty, 0),
"inreg");
CGF.Builder.CreateCondBr(InRegs, InRegBlock, OnStackBlock);
//=======================================
// Argument was in registers
//=======================================
// Now we emit the code for if the argument was originally passed in
// registers. First start the appropriate block:
CGF.EmitBlock(InRegBlock);
llvm::Value *reg_top_p = 0, *reg_top = 0;
reg_top_p = CGF.Builder.CreateStructGEP(VAListAddr, reg_top_index, "reg_top_p");
reg_top = CGF.Builder.CreateLoad(reg_top_p, "reg_top");
llvm::Value *BaseAddr = CGF.Builder.CreateGEP(reg_top, reg_offs);
llvm::Value *RegAddr = 0;
llvm::Type *MemTy = llvm::PointerType::getUnqual(CGF.ConvertTypeForMem(Ty));
if (!AI.isDirect()) {
// If it's been passed indirectly (actually a struct), whatever we find from
// stored registers or on the stack will actually be a struct **.
MemTy = llvm::PointerType::getUnqual(MemTy);
}
const Type *Base = 0;
uint64_t NumMembers;
if (isHomogeneousAggregate(Ty, Base, getContext(), &NumMembers)
&& NumMembers > 1) {
// Homogeneous aggregates passed in registers will have their elements split
// and stored 16-bytes apart regardless of size (they're notionally in qN,
// qN+1, ...). We reload and store into a temporary local variable
// contiguously.
assert(AI.isDirect() && "Homogeneous aggregates should be passed directly");
llvm::Type *BaseTy = CGF.ConvertType(QualType(Base, 0));
llvm::Type *HFATy = llvm::ArrayType::get(BaseTy, NumMembers);
llvm::Value *Tmp = CGF.CreateTempAlloca(HFATy);
for (unsigned i = 0; i < NumMembers; ++i) {
llvm::Value *BaseOffset = llvm::ConstantInt::get(CGF.Int32Ty, 16 * i);
llvm::Value *LoadAddr = CGF.Builder.CreateGEP(BaseAddr, BaseOffset);
LoadAddr = CGF.Builder.CreateBitCast(LoadAddr,
llvm::PointerType::getUnqual(BaseTy));
llvm::Value *StoreAddr = CGF.Builder.CreateStructGEP(Tmp, i);
llvm::Value *Elem = CGF.Builder.CreateLoad(LoadAddr);
CGF.Builder.CreateStore(Elem, StoreAddr);
}
RegAddr = CGF.Builder.CreateBitCast(Tmp, MemTy);
} else {
// Otherwise the object is contiguous in memory
RegAddr = CGF.Builder.CreateBitCast(BaseAddr, MemTy);
}
CGF.EmitBranch(ContBlock);
//=======================================
// Argument was on the stack
//=======================================
CGF.EmitBlock(OnStackBlock);
llvm::Value *stack_p = 0, *OnStackAddr = 0;
stack_p = CGF.Builder.CreateStructGEP(VAListAddr, 0, "stack_p");
OnStackAddr = CGF.Builder.CreateLoad(stack_p, "stack");
// Again, stack arguments may need realigmnent. In this case both integer and
// floating-point ones might be affected.
if (AI.isDirect() && getContext().getTypeAlign(Ty) > 64) {
int Align = getContext().getTypeAlign(Ty) / 8;
OnStackAddr = CGF.Builder.CreatePtrToInt(OnStackAddr, CGF.Int64Ty);
OnStackAddr = CGF.Builder.CreateAdd(OnStackAddr,
llvm::ConstantInt::get(CGF.Int64Ty, Align - 1),
"align_stack");
OnStackAddr = CGF.Builder.CreateAnd(OnStackAddr,
llvm::ConstantInt::get(CGF.Int64Ty, -Align),
"align_stack");
OnStackAddr = CGF.Builder.CreateIntToPtr(OnStackAddr, CGF.Int8PtrTy);
}
uint64_t StackSize;
if (AI.isDirect())
StackSize = getContext().getTypeSize(Ty) / 8;
else
StackSize = 8;
// All stack slots are 8 bytes
StackSize = llvm::RoundUpToAlignment(StackSize, 8);
llvm::Value *StackSizeC = llvm::ConstantInt::get(CGF.Int32Ty, StackSize);
llvm::Value *NewStack = CGF.Builder.CreateGEP(OnStackAddr, StackSizeC,
"new_stack");
// Write the new value of __stack for the next call to va_arg
CGF.Builder.CreateStore(NewStack, stack_p);
OnStackAddr = CGF.Builder.CreateBitCast(OnStackAddr, MemTy);
CGF.EmitBranch(ContBlock);
//=======================================
// Tidy up
//=======================================
CGF.EmitBlock(ContBlock);
llvm::PHINode *ResAddr = CGF.Builder.CreatePHI(MemTy, 2, "vaarg.addr");
ResAddr->addIncoming(RegAddr, InRegBlock);
ResAddr->addIncoming(OnStackAddr, OnStackBlock);
if (AI.isDirect())
return ResAddr;
return CGF.Builder.CreateLoad(ResAddr, "vaarg.addr");
}
//===----------------------------------------------------------------------===//
// NVPTX ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class NVPTXABIInfo : public ABIInfo {
public:
NVPTXABIInfo(CodeGenTypes &CGT) : ABIInfo(CGT) {}
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType Ty) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CFG) const;
};
class NVPTXTargetCodeGenInfo : public TargetCodeGenInfo {
public:
NVPTXTargetCodeGenInfo(CodeGenTypes &CGT)
: TargetCodeGenInfo(new NVPTXABIInfo(CGT)) {}
virtual void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const;
private:
static void addKernelMetadata(llvm::Function *F);
};
ABIArgInfo NVPTXABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
// note: this is different from default ABI
if (!RetTy->isScalarType())
return ABIArgInfo::getDirect();
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
ABIArgInfo NVPTXABIInfo::classifyArgumentType(QualType Ty) const {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
void NVPTXABIInfo::computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type);
// Always honor user-specified calling convention.
if (FI.getCallingConvention() != llvm::CallingConv::C)
return;
FI.setEffectiveCallingConvention(getRuntimeCC());
}
llvm::Value *NVPTXABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CFG) const {
llvm_unreachable("NVPTX does not support varargs");
}
void NVPTXTargetCodeGenInfo::
SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const{
const FunctionDecl *FD = dyn_cast<FunctionDecl>(D);
if (!FD) return;
llvm::Function *F = cast<llvm::Function>(GV);
// Perform special handling in OpenCL mode
if (M.getLangOpts().OpenCL) {
// Use OpenCL function attributes to check for kernel functions
// By default, all functions are device functions
if (FD->hasAttr<OpenCLKernelAttr>()) {
// OpenCL __kernel functions get kernel metadata
addKernelMetadata(F);
// And kernel functions are not subject to inlining
F->addFnAttr(llvm::Attribute::NoInline);
}
}
// Perform special handling in CUDA mode.
if (M.getLangOpts().CUDA) {
// CUDA __global__ functions get a kernel metadata entry. Since
// __global__ functions cannot be called from the device, we do not
// need to set the noinline attribute.
if (FD->hasAttr<CUDAGlobalAttr>())
addKernelMetadata(F);
}
}
void NVPTXTargetCodeGenInfo::addKernelMetadata(llvm::Function *F) {
llvm::Module *M = F->getParent();
llvm::LLVMContext &Ctx = M->getContext();
// Get "nvvm.annotations" metadata node
llvm::NamedMDNode *MD = M->getOrInsertNamedMetadata("nvvm.annotations");
// Create !{<func-ref>, metadata !"kernel", i32 1} node
llvm::SmallVector<llvm::Value *, 3> MDVals;
MDVals.push_back(F);
MDVals.push_back(llvm::MDString::get(Ctx, "kernel"));
MDVals.push_back(llvm::ConstantInt::get(llvm::Type::getInt32Ty(Ctx), 1));
// Append metadata to nvvm.annotations
MD->addOperand(llvm::MDNode::get(Ctx, MDVals));
}
}
//===----------------------------------------------------------------------===//
// SystemZ ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class SystemZABIInfo : public ABIInfo {
public:
SystemZABIInfo(CodeGenTypes &CGT) : ABIInfo(CGT) {}
bool isPromotableIntegerType(QualType Ty) const;
bool isCompoundType(QualType Ty) const;
bool isFPArgumentType(QualType Ty) const;
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType ArgTy) const;
virtual void computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type);
}
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class SystemZTargetCodeGenInfo : public TargetCodeGenInfo {
public:
SystemZTargetCodeGenInfo(CodeGenTypes &CGT)
: TargetCodeGenInfo(new SystemZABIInfo(CGT)) {}
};
}
bool SystemZABIInfo::isPromotableIntegerType(QualType Ty) const {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
// Promotable integer types are required to be promoted by the ABI.
if (Ty->isPromotableIntegerType())
return true;
// 32-bit values must also be promoted.
if (const BuiltinType *BT = Ty->getAs<BuiltinType>())
switch (BT->getKind()) {
case BuiltinType::Int:
case BuiltinType::UInt:
return true;
default:
return false;
}
return false;
}
bool SystemZABIInfo::isCompoundType(QualType Ty) const {
return Ty->isAnyComplexType() || isAggregateTypeForABI(Ty);
}
bool SystemZABIInfo::isFPArgumentType(QualType Ty) const {
if (const BuiltinType *BT = Ty->getAs<BuiltinType>())
switch (BT->getKind()) {
case BuiltinType::Float:
case BuiltinType::Double:
return true;
default:
return false;
}
if (const RecordType *RT = Ty->getAsStructureType()) {
const RecordDecl *RD = RT->getDecl();
bool Found = false;
// If this is a C++ record, check the bases first.
if (const CXXRecordDecl *CXXRD = dyn_cast<CXXRecordDecl>(RD))
for (CXXRecordDecl::base_class_const_iterator I = CXXRD->bases_begin(),
E = CXXRD->bases_end(); I != E; ++I) {
QualType Base = I->getType();
// Empty bases don't affect things either way.
if (isEmptyRecord(getContext(), Base, true))
continue;
if (Found)
return false;
Found = isFPArgumentType(Base);
if (!Found)
return false;
}
// Check the fields.
for (RecordDecl::field_iterator I = RD->field_begin(),
E = RD->field_end(); I != E; ++I) {
const FieldDecl *FD = *I;
// Empty bitfields don't affect things either way.
// Unlike isSingleElementStruct(), empty structure and array fields
// do count. So do anonymous bitfields that aren't zero-sized.
if (FD->isBitField() && FD->getBitWidthValue(getContext()) == 0)
return true;
// Unlike isSingleElementStruct(), arrays do not count.
// Nested isFPArgumentType structures still do though.
if (Found)
return false;
Found = isFPArgumentType(FD->getType());
if (!Found)
return false;
}
// Unlike isSingleElementStruct(), trailing padding is allowed.
// An 8-byte aligned struct s { float f; } is passed as a double.
return Found;
}
return false;
}
llvm::Value *SystemZABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// Assume that va_list type is correct; should be pointer to LLVM type:
// struct {
// i64 __gpr;
// i64 __fpr;
// i8 *__overflow_arg_area;
// i8 *__reg_save_area;
// };
// Every argument occupies 8 bytes and is passed by preference in either
// GPRs or FPRs.
Ty = CGF.getContext().getCanonicalType(Ty);
ABIArgInfo AI = classifyArgumentType(Ty);
bool InFPRs = isFPArgumentType(Ty);
llvm::Type *APTy = llvm::PointerType::getUnqual(CGF.ConvertTypeForMem(Ty));
bool IsIndirect = AI.isIndirect();
unsigned UnpaddedBitSize;
if (IsIndirect) {
APTy = llvm::PointerType::getUnqual(APTy);
UnpaddedBitSize = 64;
} else
UnpaddedBitSize = getContext().getTypeSize(Ty);
unsigned PaddedBitSize = 64;
assert((UnpaddedBitSize <= PaddedBitSize) && "Invalid argument size.");
unsigned PaddedSize = PaddedBitSize / 8;
unsigned Padding = (PaddedBitSize - UnpaddedBitSize) / 8;
unsigned MaxRegs, RegCountField, RegSaveIndex, RegPadding;
if (InFPRs) {
MaxRegs = 4; // Maximum of 4 FPR arguments
RegCountField = 1; // __fpr
RegSaveIndex = 16; // save offset for f0
RegPadding = 0; // floats are passed in the high bits of an FPR
} else {
MaxRegs = 5; // Maximum of 5 GPR arguments
RegCountField = 0; // __gpr
RegSaveIndex = 2; // save offset for r2
RegPadding = Padding; // values are passed in the low bits of a GPR
}
llvm::Value *RegCountPtr =
CGF.Builder.CreateStructGEP(VAListAddr, RegCountField, "reg_count_ptr");
llvm::Value *RegCount = CGF.Builder.CreateLoad(RegCountPtr, "reg_count");
llvm::Type *IndexTy = RegCount->getType();
llvm::Value *MaxRegsV = llvm::ConstantInt::get(IndexTy, MaxRegs);
llvm::Value *InRegs = CGF.Builder.CreateICmpULT(RegCount, MaxRegsV,
"fits_in_regs");
llvm::BasicBlock *InRegBlock = CGF.createBasicBlock("vaarg.in_reg");
llvm::BasicBlock *InMemBlock = CGF.createBasicBlock("vaarg.in_mem");
llvm::BasicBlock *ContBlock = CGF.createBasicBlock("vaarg.end");
CGF.Builder.CreateCondBr(InRegs, InRegBlock, InMemBlock);
// Emit code to load the value if it was passed in registers.
CGF.EmitBlock(InRegBlock);
// Work out the address of an argument register.
llvm::Value *PaddedSizeV = llvm::ConstantInt::get(IndexTy, PaddedSize);
llvm::Value *ScaledRegCount =
CGF.Builder.CreateMul(RegCount, PaddedSizeV, "scaled_reg_count");
llvm::Value *RegBase =
llvm::ConstantInt::get(IndexTy, RegSaveIndex * PaddedSize + RegPadding);
llvm::Value *RegOffset =
CGF.Builder.CreateAdd(ScaledRegCount, RegBase, "reg_offset");
llvm::Value *RegSaveAreaPtr =
CGF.Builder.CreateStructGEP(VAListAddr, 3, "reg_save_area_ptr");
llvm::Value *RegSaveArea =
CGF.Builder.CreateLoad(RegSaveAreaPtr, "reg_save_area");
llvm::Value *RawRegAddr =
CGF.Builder.CreateGEP(RegSaveArea, RegOffset, "raw_reg_addr");
llvm::Value *RegAddr =
CGF.Builder.CreateBitCast(RawRegAddr, APTy, "reg_addr");
// Update the register count
llvm::Value *One = llvm::ConstantInt::get(IndexTy, 1);
llvm::Value *NewRegCount =
CGF.Builder.CreateAdd(RegCount, One, "reg_count");
CGF.Builder.CreateStore(NewRegCount, RegCountPtr);
CGF.EmitBranch(ContBlock);
// Emit code to load the value if it was passed in memory.
CGF.EmitBlock(InMemBlock);
// Work out the address of a stack argument.
llvm::Value *OverflowArgAreaPtr =
CGF.Builder.CreateStructGEP(VAListAddr, 2, "overflow_arg_area_ptr");
llvm::Value *OverflowArgArea =
CGF.Builder.CreateLoad(OverflowArgAreaPtr, "overflow_arg_area");
llvm::Value *PaddingV = llvm::ConstantInt::get(IndexTy, Padding);
llvm::Value *RawMemAddr =
CGF.Builder.CreateGEP(OverflowArgArea, PaddingV, "raw_mem_addr");
llvm::Value *MemAddr =
CGF.Builder.CreateBitCast(RawMemAddr, APTy, "mem_addr");
// Update overflow_arg_area_ptr pointer
llvm::Value *NewOverflowArgArea =
CGF.Builder.CreateGEP(OverflowArgArea, PaddedSizeV, "overflow_arg_area");
CGF.Builder.CreateStore(NewOverflowArgArea, OverflowArgAreaPtr);
CGF.EmitBranch(ContBlock);
// Return the appropriate result.
CGF.EmitBlock(ContBlock);
llvm::PHINode *ResAddr = CGF.Builder.CreatePHI(APTy, 2, "va_arg.addr");
ResAddr->addIncoming(RegAddr, InRegBlock);
ResAddr->addIncoming(MemAddr, InMemBlock);
if (IsIndirect)
return CGF.Builder.CreateLoad(ResAddr, "indirect_arg");
return ResAddr;
}
bool X86_32TargetCodeGenInfo::isStructReturnInRegABI(
const llvm::Triple &Triple, const CodeGenOptions &Opts) {
assert(Triple.getArch() == llvm::Triple::x86);
switch (Opts.getStructReturnConvention()) {
case CodeGenOptions::SRCK_Default:
break;
case CodeGenOptions::SRCK_OnStack: // -fpcc-struct-return
return false;
case CodeGenOptions::SRCK_InRegs: // -freg-struct-return
return true;
}
if (Triple.isOSDarwin())
return true;
switch (Triple.getOS()) {
case llvm::Triple::Cygwin:
case llvm::Triple::MinGW32:
case llvm::Triple::AuroraUX:
case llvm::Triple::DragonFly:
case llvm::Triple::FreeBSD:
case llvm::Triple::OpenBSD:
case llvm::Triple::Bitrig:
case llvm::Triple::Win32:
return true;
default:
return false;
}
}
ABIArgInfo SystemZABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
if (isCompoundType(RetTy) || getContext().getTypeSize(RetTy) > 64)
return ABIArgInfo::getIndirect(0);
return (isPromotableIntegerType(RetTy) ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
ABIArgInfo SystemZABIInfo::classifyArgumentType(QualType Ty) const {
// Handle the generic C++ ABI.
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
// Integers and enums are extended to full register width.
if (isPromotableIntegerType(Ty))
return ABIArgInfo::getExtend();
// Values that are not 1, 2, 4 or 8 bytes in size are passed indirectly.
uint64_t Size = getContext().getTypeSize(Ty);
if (Size != 8 && Size != 16 && Size != 32 && Size != 64)
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
// Handle small structures.
if (const RecordType *RT = Ty->getAs<RecordType>()) {
// Structures with flexible arrays have variable length, so really
// fail the size test above.
const RecordDecl *RD = RT->getDecl();
if (RD->hasFlexibleArrayMember())
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
// The structure is passed as an unextended integer, a float, or a double.
llvm::Type *PassTy;
if (isFPArgumentType(Ty)) {
assert(Size == 32 || Size == 64);
if (Size == 32)
PassTy = llvm::Type::getFloatTy(getVMContext());
else
PassTy = llvm::Type::getDoubleTy(getVMContext());
} else
PassTy = llvm::IntegerType::get(getVMContext(), Size);
return ABIArgInfo::getDirect(PassTy);
}
// Non-structure compounds are passed indirectly.
if (isCompoundType(Ty))
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
return ABIArgInfo::getDirect(0);
}
//===----------------------------------------------------------------------===//
// MSP430 ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class MSP430TargetCodeGenInfo : public TargetCodeGenInfo {
public:
MSP430TargetCodeGenInfo(CodeGenTypes &CGT)
: TargetCodeGenInfo(new DefaultABIInfo(CGT)) {}
void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const;
};
}
void MSP430TargetCodeGenInfo::SetTargetAttributes(const Decl *D,
llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const {
if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) {
if (const MSP430InterruptAttr *attr = FD->getAttr<MSP430InterruptAttr>()) {
// Handle 'interrupt' attribute:
llvm::Function *F = cast<llvm::Function>(GV);
// Step 1: Set ISR calling convention.
F->setCallingConv(llvm::CallingConv::MSP430_INTR);
// Step 2: Add attributes goodness.
F->addFnAttr(llvm::Attribute::NoInline);
// Step 3: Emit ISR vector alias.
unsigned Num = attr->getNumber() / 2;
new llvm::GlobalAlias(GV->getType(), llvm::Function::ExternalLinkage,
"__isr_" + Twine(Num),
GV, &M.getModule());
}
}
}
//===----------------------------------------------------------------------===//
// MIPS ABI Implementation. This works for both little-endian and
// big-endian variants.
//===----------------------------------------------------------------------===//
namespace {
class MipsABIInfo : public ABIInfo {
bool IsO32;
unsigned MinABIStackAlignInBytes, StackAlignInBytes;
void CoerceToIntArgs(uint64_t TySize,
SmallVectorImpl<llvm::Type *> &ArgList) const;
llvm::Type* HandleAggregates(QualType Ty, uint64_t TySize) const;
llvm::Type* returnAggregateInRegs(QualType RetTy, uint64_t Size) const;
llvm::Type* getPaddingType(uint64_t Align, uint64_t Offset) const;
public:
MipsABIInfo(CodeGenTypes &CGT, bool _IsO32) :
ABIInfo(CGT), IsO32(_IsO32), MinABIStackAlignInBytes(IsO32 ? 4 : 8),
StackAlignInBytes(IsO32 ? 8 : 16) {}
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType RetTy, uint64_t &Offset) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class MIPSTargetCodeGenInfo : public TargetCodeGenInfo {
unsigned SizeOfUnwindException;
public:
MIPSTargetCodeGenInfo(CodeGenTypes &CGT, bool IsO32)
: TargetCodeGenInfo(new MipsABIInfo(CGT, IsO32)),
SizeOfUnwindException(IsO32 ? 24 : 32) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &CGM) const {
return 29;
}
void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &CGM) const {
const FunctionDecl *FD = dyn_cast<FunctionDecl>(D);
if (!FD) return;
llvm::Function *Fn = cast<llvm::Function>(GV);
if (FD->hasAttr<Mips16Attr>()) {
Fn->addFnAttr("mips16");
}
else if (FD->hasAttr<NoMips16Attr>()) {
Fn->addFnAttr("nomips16");
}
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
unsigned getSizeOfUnwindException() const {
return SizeOfUnwindException;
}
};
}
void MipsABIInfo::CoerceToIntArgs(uint64_t TySize,
SmallVectorImpl<llvm::Type *> &ArgList) const {
llvm::IntegerType *IntTy =
llvm::IntegerType::get(getVMContext(), MinABIStackAlignInBytes * 8);
// Add (TySize / MinABIStackAlignInBytes) args of IntTy.
for (unsigned N = TySize / (MinABIStackAlignInBytes * 8); N; --N)
ArgList.push_back(IntTy);
// If necessary, add one more integer type to ArgList.
unsigned R = TySize % (MinABIStackAlignInBytes * 8);
if (R)
ArgList.push_back(llvm::IntegerType::get(getVMContext(), R));
}
// In N32/64, an aligned double precision floating point field is passed in
// a register.
llvm::Type* MipsABIInfo::HandleAggregates(QualType Ty, uint64_t TySize) const {
SmallVector<llvm::Type*, 8> ArgList, IntArgList;
if (IsO32) {
CoerceToIntArgs(TySize, ArgList);
return llvm::StructType::get(getVMContext(), ArgList);
}
if (Ty->isComplexType())
return CGT.ConvertType(Ty);
const RecordType *RT = Ty->getAs<RecordType>();
// Unions/vectors are passed in integer registers.
if (!RT || !RT->isStructureOrClassType()) {
CoerceToIntArgs(TySize, ArgList);
return llvm::StructType::get(getVMContext(), ArgList);
}
const RecordDecl *RD = RT->getDecl();
const ASTRecordLayout &Layout = getContext().getASTRecordLayout(RD);
assert(!(TySize % 8) && "Size of structure must be multiple of 8.");
uint64_t LastOffset = 0;
unsigned idx = 0;
llvm::IntegerType *I64 = llvm::IntegerType::get(getVMContext(), 64);
// Iterate over fields in the struct/class and check if there are any aligned
// double fields.
for (RecordDecl::field_iterator i = RD->field_begin(), e = RD->field_end();
i != e; ++i, ++idx) {
const QualType Ty = i->getType();
const BuiltinType *BT = Ty->getAs<BuiltinType>();
if (!BT || BT->getKind() != BuiltinType::Double)
continue;
uint64_t Offset = Layout.getFieldOffset(idx);
if (Offset % 64) // Ignore doubles that are not aligned.
continue;
// Add ((Offset - LastOffset) / 64) args of type i64.
for (unsigned j = (Offset - LastOffset) / 64; j > 0; --j)
ArgList.push_back(I64);
// Add double type.
ArgList.push_back(llvm::Type::getDoubleTy(getVMContext()));
LastOffset = Offset + 64;
}
CoerceToIntArgs(TySize - LastOffset, IntArgList);
ArgList.append(IntArgList.begin(), IntArgList.end());
return llvm::StructType::get(getVMContext(), ArgList);
}
llvm::Type *MipsABIInfo::getPaddingType(uint64_t OrigOffset,
uint64_t Offset) const {
if (OrigOffset + MinABIStackAlignInBytes > Offset)
return 0;
return llvm::IntegerType::get(getVMContext(), (Offset - OrigOffset) * 8);
}
2012-01-11 06:44:52 +08:00
ABIArgInfo
MipsABIInfo::classifyArgumentType(QualType Ty, uint64_t &Offset) const {
uint64_t OrigOffset = Offset;
uint64_t TySize = getContext().getTypeSize(Ty);
uint64_t Align = getContext().getTypeAlign(Ty) / 8;
Align = std::min(std::max(Align, (uint64_t)MinABIStackAlignInBytes),
(uint64_t)StackAlignInBytes);
unsigned CurrOffset = llvm::RoundUpToAlignment(Offset, Align);
Offset = CurrOffset + llvm::RoundUpToAlignment(TySize, Align * 8) / 8;
if (isAggregateTypeForABI(Ty) || Ty->isVectorType()) {
// Ignore empty aggregates.
if (TySize == 0)
return ABIArgInfo::getIgnore();
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI())) {
Offset = OrigOffset + MinABIStackAlignInBytes;
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
}
// If we have reached here, aggregates are passed directly by coercing to
// another structure type. Padding is inserted if the offset of the
// aggregate is unaligned.
return ABIArgInfo::getDirect(HandleAggregates(Ty, TySize), 0,
getPaddingType(OrigOffset, CurrOffset));
}
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
if (Ty->isPromotableIntegerType())
return ABIArgInfo::getExtend();
return ABIArgInfo::getDirect(
0, 0, IsO32 ? 0 : getPaddingType(OrigOffset, CurrOffset));
}
llvm::Type*
MipsABIInfo::returnAggregateInRegs(QualType RetTy, uint64_t Size) const {
const RecordType *RT = RetTy->getAs<RecordType>();
SmallVector<llvm::Type*, 8> RTList;
if (RT && RT->isStructureOrClassType()) {
const RecordDecl *RD = RT->getDecl();
const ASTRecordLayout &Layout = getContext().getASTRecordLayout(RD);
unsigned FieldCnt = Layout.getFieldCount();
// N32/64 returns struct/classes in floating point registers if the
// following conditions are met:
// 1. The size of the struct/class is no larger than 128-bit.
// 2. The struct/class has one or two fields all of which are floating
// point types.
// 3. The offset of the first field is zero (this follows what gcc does).
//
// Any other composite results are returned in integer registers.
//
if (FieldCnt && (FieldCnt <= 2) && !Layout.getFieldOffset(0)) {
RecordDecl::field_iterator b = RD->field_begin(), e = RD->field_end();
for (; b != e; ++b) {
const BuiltinType *BT = b->getType()->getAs<BuiltinType>();
if (!BT || !BT->isFloatingPoint())
break;
RTList.push_back(CGT.ConvertType(b->getType()));
}
if (b == e)
return llvm::StructType::get(getVMContext(), RTList,
RD->hasAttr<PackedAttr>());
RTList.clear();
}
}
CoerceToIntArgs(Size, RTList);
return llvm::StructType::get(getVMContext(), RTList);
}
ABIArgInfo MipsABIInfo::classifyReturnType(QualType RetTy) const {
uint64_t Size = getContext().getTypeSize(RetTy);
if (RetTy->isVoidType() || Size == 0)
return ABIArgInfo::getIgnore();
if (isAggregateTypeForABI(RetTy) || RetTy->isVectorType()) {
if (isRecordReturnIndirect(RetTy, getCXXABI()))
return ABIArgInfo::getIndirect(0);
if (Size <= 128) {
if (RetTy->isAnyComplexType())
return ABIArgInfo::getDirect();
// O32 returns integer vectors in registers.
if (IsO32 && RetTy->isVectorType() && !RetTy->hasFloatingRepresentation())
return ABIArgInfo::getDirect(returnAggregateInRegs(RetTy, Size));
if (!IsO32)
return ABIArgInfo::getDirect(returnAggregateInRegs(RetTy, Size));
}
return ABIArgInfo::getIndirect(0);
}
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
void MipsABIInfo::computeInfo(CGFunctionInfo &FI) const {
ABIArgInfo &RetInfo = FI.getReturnInfo();
RetInfo = classifyReturnType(FI.getReturnType());
// Check if a pointer to an aggregate is passed as a hidden argument.
uint64_t Offset = RetInfo.isIndirect() ? MinABIStackAlignInBytes : 0;
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type, Offset);
}
llvm::Value* MipsABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
llvm::Type *BP = CGF.Int8PtrTy;
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP, "ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
int64_t TypeAlign = getContext().getTypeAlign(Ty) / 8;
llvm::Type *PTy = llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
llvm::Value *AddrTyped;
unsigned PtrWidth = getTarget().getPointerWidth(0);
llvm::IntegerType *IntTy = (PtrWidth == 32) ? CGF.Int32Ty : CGF.Int64Ty;
if (TypeAlign > MinABIStackAlignInBytes) {
llvm::Value *AddrAsInt = CGF.Builder.CreatePtrToInt(Addr, IntTy);
llvm::Value *Inc = llvm::ConstantInt::get(IntTy, TypeAlign - 1);
llvm::Value *Mask = llvm::ConstantInt::get(IntTy, -TypeAlign);
llvm::Value *Add = CGF.Builder.CreateAdd(AddrAsInt, Inc);
llvm::Value *And = CGF.Builder.CreateAnd(Add, Mask);
AddrTyped = CGF.Builder.CreateIntToPtr(And, PTy);
}
else
AddrTyped = Builder.CreateBitCast(Addr, PTy);
llvm::Value *AlignedAddr = Builder.CreateBitCast(AddrTyped, BP);
TypeAlign = std::max((unsigned)TypeAlign, MinABIStackAlignInBytes);
uint64_t Offset =
llvm::RoundUpToAlignment(CGF.getContext().getTypeSize(Ty) / 8, TypeAlign);
llvm::Value *NextAddr =
Builder.CreateGEP(AlignedAddr, llvm::ConstantInt::get(IntTy, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
return AddrTyped;
}
bool
MIPSTargetCodeGenInfo::initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
// This information comes from gcc's implementation, which seems to
// as canonical as it gets.
// Everything on MIPS is 4 bytes. Double-precision FP registers
// are aliased to pairs of single-precision FP registers.
llvm::Value *Four8 = llvm::ConstantInt::get(CGF.Int8Ty, 4);
// 0-31 are the general purpose registers, $0 - $31.
// 32-63 are the floating-point registers, $f0 - $f31.
// 64 and 65 are the multiply/divide registers, $hi and $lo.
// 66 is the (notional, I think) register for signal-handler return.
AssignToArrayRange(CGF.Builder, Address, Four8, 0, 65);
// 67-74 are the floating-point status registers, $fcc0 - $fcc7.
// They are one bit wide and ignored here.
// 80-111 are the coprocessor 0 registers, $c0r0 - $c0r31.
// (coprocessor 1 is the FP unit)
// 112-143 are the coprocessor 2 registers, $c2r0 - $c2r31.
// 144-175 are the coprocessor 3 registers, $c3r0 - $c3r31.
// 176-181 are the DSP accumulator registers.
AssignToArrayRange(CGF.Builder, Address, Four8, 80, 181);
return false;
}
//===----------------------------------------------------------------------===//
// TCE ABI Implementation (see http://tce.cs.tut.fi). Uses mostly the defaults.
// Currently subclassed only to implement custom OpenCL C function attribute
// handling.
//===----------------------------------------------------------------------===//
namespace {
class TCETargetCodeGenInfo : public DefaultTargetCodeGenInfo {
public:
TCETargetCodeGenInfo(CodeGenTypes &CGT)
: DefaultTargetCodeGenInfo(CGT) {}
virtual void SetTargetAttributes(const Decl *D, llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const;
};
void TCETargetCodeGenInfo::SetTargetAttributes(const Decl *D,
llvm::GlobalValue *GV,
CodeGen::CodeGenModule &M) const {
const FunctionDecl *FD = dyn_cast<FunctionDecl>(D);
if (!FD) return;
llvm::Function *F = cast<llvm::Function>(GV);
if (M.getLangOpts().OpenCL) {
if (FD->hasAttr<OpenCLKernelAttr>()) {
// OpenCL C Kernel functions are not subject to inlining
F->addFnAttr(llvm::Attribute::NoInline);
const ReqdWorkGroupSizeAttr *Attr = FD->getAttr<ReqdWorkGroupSizeAttr>();
if (Attr) {
// Convert the reqd_work_group_size() attributes to metadata.
llvm::LLVMContext &Context = F->getContext();
llvm::NamedMDNode *OpenCLMetadata =
M.getModule().getOrInsertNamedMetadata("opencl.kernel_wg_size_info");
SmallVector<llvm::Value*, 5> Operands;
Operands.push_back(F);
Operands.push_back(llvm::Constant::getIntegerValue(M.Int32Ty,
llvm::APInt(32, Attr->getXDim())));
Operands.push_back(llvm::Constant::getIntegerValue(M.Int32Ty,
llvm::APInt(32, Attr->getYDim())));
Operands.push_back(llvm::Constant::getIntegerValue(M.Int32Ty,
llvm::APInt(32, Attr->getZDim())));
// Add a boolean constant operand for "required" (true) or "hint" (false)
// for implementing the work_group_size_hint attr later. Currently
// always true as the hint is not yet implemented.
Operands.push_back(llvm::ConstantInt::getTrue(Context));
OpenCLMetadata->addOperand(llvm::MDNode::get(Context, Operands));
}
}
}
}
}
//===----------------------------------------------------------------------===//
// Hexagon ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class HexagonABIInfo : public ABIInfo {
public:
HexagonABIInfo(CodeGenTypes &CGT) : ABIInfo(CGT) {}
private:
ABIArgInfo classifyReturnType(QualType RetTy) const;
ABIArgInfo classifyArgumentType(QualType RetTy) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
class HexagonTargetCodeGenInfo : public TargetCodeGenInfo {
public:
HexagonTargetCodeGenInfo(CodeGenTypes &CGT)
:TargetCodeGenInfo(new HexagonABIInfo(CGT)) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
return 29;
}
};
}
void HexagonABIInfo::computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyReturnType(FI.getReturnType());
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyArgumentType(it->type);
}
ABIArgInfo HexagonABIInfo::classifyArgumentType(QualType Ty) const {
if (!isAggregateTypeForABI(Ty)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
return (Ty->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
// Ignore empty records.
if (isEmptyRecord(getContext(), Ty, true))
return ABIArgInfo::getIgnore();
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
uint64_t Size = getContext().getTypeSize(Ty);
if (Size > 64)
return ABIArgInfo::getIndirect(0, /*ByVal=*/true);
// Pass in the smallest viable integer type.
else if (Size > 32)
return ABIArgInfo::getDirect(llvm::Type::getInt64Ty(getVMContext()));
else if (Size > 16)
return ABIArgInfo::getDirect(llvm::Type::getInt32Ty(getVMContext()));
else if (Size > 8)
return ABIArgInfo::getDirect(llvm::Type::getInt16Ty(getVMContext()));
else
return ABIArgInfo::getDirect(llvm::Type::getInt8Ty(getVMContext()));
}
ABIArgInfo HexagonABIInfo::classifyReturnType(QualType RetTy) const {
if (RetTy->isVoidType())
return ABIArgInfo::getIgnore();
// Large vector types should be returned via memory.
if (RetTy->isVectorType() && getContext().getTypeSize(RetTy) > 64)
return ABIArgInfo::getIndirect(0);
if (!isAggregateTypeForABI(RetTy)) {
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = RetTy->getAs<EnumType>())
RetTy = EnumTy->getDecl()->getIntegerType();
return (RetTy->isPromotableIntegerType() ?
ABIArgInfo::getExtend() : ABIArgInfo::getDirect());
}
// Structures with either a non-trivial destructor or a non-trivial
// copy constructor are always indirect.
if (isRecordReturnIndirect(RetTy, getCXXABI()))
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
if (isEmptyRecord(getContext(), RetTy, true))
return ABIArgInfo::getIgnore();
// Aggregates <= 8 bytes are returned in r0; other aggregates
// are returned indirectly.
uint64_t Size = getContext().getTypeSize(RetTy);
if (Size <= 64) {
// Return in the smallest viable integer type.
if (Size <= 8)
return ABIArgInfo::getDirect(llvm::Type::getInt8Ty(getVMContext()));
if (Size <= 16)
return ABIArgInfo::getDirect(llvm::Type::getInt16Ty(getVMContext()));
if (Size <= 32)
return ABIArgInfo::getDirect(llvm::Type::getInt32Ty(getVMContext()));
return ABIArgInfo::getDirect(llvm::Type::getInt64Ty(getVMContext()));
}
return ABIArgInfo::getIndirect(0, /*ByVal=*/true);
}
llvm::Value *HexagonABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
// FIXME: Need to handle alignment
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP,
"ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
llvm::Type *PTy =
llvm::PointerType::getUnqual(CGF.ConvertType(Ty));
llvm::Value *AddrTyped = Builder.CreateBitCast(Addr, PTy);
uint64_t Offset =
llvm::RoundUpToAlignment(CGF.getContext().getTypeSize(Ty) / 8, 4);
llvm::Value *NextAddr =
Builder.CreateGEP(Addr, llvm::ConstantInt::get(CGF.Int32Ty, Offset),
"ap.next");
Builder.CreateStore(NextAddr, VAListAddrAsBPP);
return AddrTyped;
}
//===----------------------------------------------------------------------===//
// SPARC v9 ABI Implementation.
// Based on the SPARC Compliance Definition version 2.4.1.
//
// Function arguments a mapped to a nominal "parameter array" and promoted to
// registers depending on their type. Each argument occupies 8 or 16 bytes in
// the array, structs larger than 16 bytes are passed indirectly.
//
// One case requires special care:
//
// struct mixed {
// int i;
// float f;
// };
//
// When a struct mixed is passed by value, it only occupies 8 bytes in the
// parameter array, but the int is passed in an integer register, and the float
// is passed in a floating point register. This is represented as two arguments
// with the LLVM IR inreg attribute:
//
// declare void f(i32 inreg %i, float inreg %f)
//
// The code generator will only allocate 4 bytes from the parameter array for
// the inreg arguments. All other arguments are allocated a multiple of 8
// bytes.
//
namespace {
class SparcV9ABIInfo : public ABIInfo {
public:
SparcV9ABIInfo(CodeGenTypes &CGT) : ABIInfo(CGT) {}
private:
ABIArgInfo classifyType(QualType RetTy, unsigned SizeLimit) const;
virtual void computeInfo(CGFunctionInfo &FI) const;
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
// Coercion type builder for structs passed in registers. The coercion type
// serves two purposes:
//
// 1. Pad structs to a multiple of 64 bits, so they are passed 'left-aligned'
// in registers.
// 2. Expose aligned floating point elements as first-level elements, so the
// code generator knows to pass them in floating point registers.
//
// We also compute the InReg flag which indicates that the struct contains
// aligned 32-bit floats.
//
struct CoerceBuilder {
llvm::LLVMContext &Context;
const llvm::DataLayout &DL;
SmallVector<llvm::Type*, 8> Elems;
uint64_t Size;
bool InReg;
CoerceBuilder(llvm::LLVMContext &c, const llvm::DataLayout &dl)
: Context(c), DL(dl), Size(0), InReg(false) {}
// Pad Elems with integers until Size is ToSize.
void pad(uint64_t ToSize) {
assert(ToSize >= Size && "Cannot remove elements");
if (ToSize == Size)
return;
// Finish the current 64-bit word.
uint64_t Aligned = llvm::RoundUpToAlignment(Size, 64);
if (Aligned > Size && Aligned <= ToSize) {
Elems.push_back(llvm::IntegerType::get(Context, Aligned - Size));
Size = Aligned;
}
// Add whole 64-bit words.
while (Size + 64 <= ToSize) {
Elems.push_back(llvm::Type::getInt64Ty(Context));
Size += 64;
}
// Final in-word padding.
if (Size < ToSize) {
Elems.push_back(llvm::IntegerType::get(Context, ToSize - Size));
Size = ToSize;
}
}
// Add a floating point element at Offset.
void addFloat(uint64_t Offset, llvm::Type *Ty, unsigned Bits) {
// Unaligned floats are treated as integers.
if (Offset % Bits)
return;
// The InReg flag is only required if there are any floats < 64 bits.
if (Bits < 64)
InReg = true;
pad(Offset);
Elems.push_back(Ty);
Size = Offset + Bits;
}
// Add a struct type to the coercion type, starting at Offset (in bits).
void addStruct(uint64_t Offset, llvm::StructType *StrTy) {
const llvm::StructLayout *Layout = DL.getStructLayout(StrTy);
for (unsigned i = 0, e = StrTy->getNumElements(); i != e; ++i) {
llvm::Type *ElemTy = StrTy->getElementType(i);
uint64_t ElemOffset = Offset + Layout->getElementOffsetInBits(i);
switch (ElemTy->getTypeID()) {
case llvm::Type::StructTyID:
addStruct(ElemOffset, cast<llvm::StructType>(ElemTy));
break;
case llvm::Type::FloatTyID:
addFloat(ElemOffset, ElemTy, 32);
break;
case llvm::Type::DoubleTyID:
addFloat(ElemOffset, ElemTy, 64);
break;
case llvm::Type::FP128TyID:
addFloat(ElemOffset, ElemTy, 128);
break;
case llvm::Type::PointerTyID:
if (ElemOffset % 64 == 0) {
pad(ElemOffset);
Elems.push_back(ElemTy);
Size += 64;
}
break;
default:
break;
}
}
}
// Check if Ty is a usable substitute for the coercion type.
bool isUsableType(llvm::StructType *Ty) const {
if (Ty->getNumElements() != Elems.size())
return false;
for (unsigned i = 0, e = Elems.size(); i != e; ++i)
if (Elems[i] != Ty->getElementType(i))
return false;
return true;
}
// Get the coercion type as a literal struct type.
llvm::Type *getType() const {
if (Elems.size() == 1)
return Elems.front();
else
return llvm::StructType::get(Context, Elems);
}
};
};
} // end anonymous namespace
ABIArgInfo
SparcV9ABIInfo::classifyType(QualType Ty, unsigned SizeLimit) const {
if (Ty->isVoidType())
return ABIArgInfo::getIgnore();
uint64_t Size = getContext().getTypeSize(Ty);
// Anything too big to fit in registers is passed with an explicit indirect
// pointer / sret pointer.
if (Size > SizeLimit)
return ABIArgInfo::getIndirect(0, /*ByVal=*/false);
// Treat an enum type as its underlying type.
if (const EnumType *EnumTy = Ty->getAs<EnumType>())
Ty = EnumTy->getDecl()->getIntegerType();
// Integer types smaller than a register are extended.
if (Size < 64 && Ty->isIntegerType())
return ABIArgInfo::getExtend();
// Other non-aggregates go in registers.
if (!isAggregateTypeForABI(Ty))
return ABIArgInfo::getDirect();
// If a C++ object has either a non-trivial copy constructor or a non-trivial
// destructor, it is passed with an explicit indirect pointer / sret pointer.
if (CGCXXABI::RecordArgABI RAA = getRecordArgABI(Ty, getCXXABI()))
return ABIArgInfo::getIndirect(0, RAA == CGCXXABI::RAA_DirectInMemory);
// This is a small aggregate type that should be passed in registers.
// Build a coercion type from the LLVM struct type.
llvm::StructType *StrTy = dyn_cast<llvm::StructType>(CGT.ConvertType(Ty));
if (!StrTy)
return ABIArgInfo::getDirect();
CoerceBuilder CB(getVMContext(), getDataLayout());
CB.addStruct(0, StrTy);
CB.pad(llvm::RoundUpToAlignment(CB.DL.getTypeSizeInBits(StrTy), 64));
// Try to use the original type for coercion.
llvm::Type *CoerceTy = CB.isUsableType(StrTy) ? StrTy : CB.getType();
if (CB.InReg)
return ABIArgInfo::getDirectInReg(CoerceTy);
else
return ABIArgInfo::getDirect(CoerceTy);
}
llvm::Value *SparcV9ABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
ABIArgInfo AI = classifyType(Ty, 16 * 8);
llvm::Type *ArgTy = CGT.ConvertType(Ty);
if (AI.canHaveCoerceToType() && !AI.getCoerceToType())
AI.setCoerceToType(ArgTy);
llvm::Type *BPP = CGF.Int8PtrPtrTy;
CGBuilderTy &Builder = CGF.Builder;
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr, BPP, "ap");
llvm::Value *Addr = Builder.CreateLoad(VAListAddrAsBPP, "ap.cur");
llvm::Type *ArgPtrTy = llvm::PointerType::getUnqual(ArgTy);
llvm::Value *ArgAddr;
unsigned Stride;
switch (AI.getKind()) {
case ABIArgInfo::Expand:
case ABIArgInfo::InAlloca:
llvm_unreachable("Unsupported ABI kind for va_arg");
case ABIArgInfo::Extend:
Stride = 8;
ArgAddr = Builder
.CreateConstGEP1_32(Addr, 8 - getDataLayout().getTypeAllocSize(ArgTy),
"extend");
break;
case ABIArgInfo::Direct:
Stride = getDataLayout().getTypeAllocSize(AI.getCoerceToType());
ArgAddr = Addr;
break;
case ABIArgInfo::Indirect:
Stride = 8;
ArgAddr = Builder.CreateBitCast(Addr,
llvm::PointerType::getUnqual(ArgPtrTy),
"indirect");
ArgAddr = Builder.CreateLoad(ArgAddr, "indirect.arg");
break;
case ABIArgInfo::Ignore:
return llvm::UndefValue::get(ArgPtrTy);
}
// Update VAList.
Addr = Builder.CreateConstGEP1_32(Addr, Stride, "ap.next");
Builder.CreateStore(Addr, VAListAddrAsBPP);
return Builder.CreatePointerCast(ArgAddr, ArgPtrTy, "arg.addr");
}
void SparcV9ABIInfo::computeInfo(CGFunctionInfo &FI) const {
FI.getReturnInfo() = classifyType(FI.getReturnType(), 32 * 8);
for (CGFunctionInfo::arg_iterator it = FI.arg_begin(), ie = FI.arg_end();
it != ie; ++it)
it->info = classifyType(it->type, 16 * 8);
}
namespace {
class SparcV9TargetCodeGenInfo : public TargetCodeGenInfo {
public:
SparcV9TargetCodeGenInfo(CodeGenTypes &CGT)
: TargetCodeGenInfo(new SparcV9ABIInfo(CGT)) {}
int getDwarfEHStackPointer(CodeGen::CodeGenModule &M) const {
return 14;
}
bool initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const;
};
} // end anonymous namespace
bool
SparcV9TargetCodeGenInfo::initDwarfEHRegSizeTable(CodeGen::CodeGenFunction &CGF,
llvm::Value *Address) const {
// This is calculated from the LLVM and GCC tables and verified
// against gcc output. AFAIK all ABIs use the same encoding.
CodeGen::CGBuilderTy &Builder = CGF.Builder;
llvm::IntegerType *i8 = CGF.Int8Ty;
llvm::Value *Four8 = llvm::ConstantInt::get(i8, 4);
llvm::Value *Eight8 = llvm::ConstantInt::get(i8, 8);
// 0-31: the 8-byte general-purpose registers
AssignToArrayRange(Builder, Address, Eight8, 0, 31);
// 32-63: f0-31, the 4-byte floating-point registers
AssignToArrayRange(Builder, Address, Four8, 32, 63);
// Y = 64
// PSR = 65
// WIM = 66
// TBR = 67
// PC = 68
// NPC = 69
// FSR = 70
// CSR = 71
AssignToArrayRange(Builder, Address, Eight8, 64, 71);
// 72-87: d0-15, the 8-byte floating-point registers
AssignToArrayRange(Builder, Address, Eight8, 72, 87);
return false;
}
2013-08-13 17:43:10 +08:00
//===----------------------------------------------------------------------===//
// Xcore ABI Implementation
//===----------------------------------------------------------------------===//
namespace {
class XCoreABIInfo : public DefaultABIInfo {
public:
XCoreABIInfo(CodeGen::CodeGenTypes &CGT) : DefaultABIInfo(CGT) {}
virtual llvm::Value *EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const;
};
2013-08-13 17:43:10 +08:00
class XcoreTargetCodeGenInfo : public TargetCodeGenInfo {
public:
XcoreTargetCodeGenInfo(CodeGenTypes &CGT)
:TargetCodeGenInfo(new XCoreABIInfo(CGT)) {}
2013-08-13 17:43:10 +08:00
};
} // End anonymous namespace.
2013-08-13 17:43:10 +08:00
llvm::Value *XCoreABIInfo::EmitVAArg(llvm::Value *VAListAddr, QualType Ty,
CodeGenFunction &CGF) const {
CGBuilderTy &Builder = CGF.Builder;
// Get the VAList.
llvm::Value *VAListAddrAsBPP = Builder.CreateBitCast(VAListAddr,
CGF.Int8PtrPtrTy);
llvm::Value *AP = Builder.CreateLoad(VAListAddrAsBPP);
// Handle the argument.
ABIArgInfo AI = classifyArgumentType(Ty);
llvm::Type *ArgTy = CGT.ConvertType(Ty);
if (AI.canHaveCoerceToType() && !AI.getCoerceToType())
AI.setCoerceToType(ArgTy);
llvm::Type *ArgPtrTy = llvm::PointerType::getUnqual(ArgTy);
llvm::Value *Val;
uint64_t ArgSize = 0;
switch (AI.getKind()) {
case ABIArgInfo::Expand:
case ABIArgInfo::InAlloca:
llvm_unreachable("Unsupported ABI kind for va_arg");
case ABIArgInfo::Ignore:
Val = llvm::UndefValue::get(ArgPtrTy);
ArgSize = 0;
break;
case ABIArgInfo::Extend:
case ABIArgInfo::Direct:
Val = Builder.CreatePointerCast(AP, ArgPtrTy);
ArgSize = getDataLayout().getTypeAllocSize(AI.getCoerceToType());
if (ArgSize < 4)
ArgSize = 4;
break;
case ABIArgInfo::Indirect:
llvm::Value *ArgAddr;
ArgAddr = Builder.CreateBitCast(AP, llvm::PointerType::getUnqual(ArgPtrTy));
ArgAddr = Builder.CreateLoad(ArgAddr);
Val = Builder.CreatePointerCast(ArgAddr, ArgPtrTy);
ArgSize = 4;
break;
}
// Increment the VAList.
if (ArgSize) {
llvm::Value *APN = Builder.CreateConstGEP1_32(AP, ArgSize);
Builder.CreateStore(APN, VAListAddrAsBPP);
}
return Val;
}
2013-08-13 17:43:10 +08:00
//===----------------------------------------------------------------------===//
// Driver code
//===----------------------------------------------------------------------===//
const TargetCodeGenInfo &CodeGenModule::getTargetCodeGenInfo() {
if (TheTargetCodeGenInfo)
return *TheTargetCodeGenInfo;
const llvm::Triple &Triple = getTarget().getTriple();
switch (Triple.getArch()) {
default:
return *(TheTargetCodeGenInfo = new DefaultTargetCodeGenInfo(Types));
case llvm::Triple::le32:
return *(TheTargetCodeGenInfo = new PNaClTargetCodeGenInfo(Types));
case llvm::Triple::mips:
case llvm::Triple::mipsel:
return *(TheTargetCodeGenInfo = new MIPSTargetCodeGenInfo(Types, true));
case llvm::Triple::mips64:
case llvm::Triple::mips64el:
return *(TheTargetCodeGenInfo = new MIPSTargetCodeGenInfo(Types, false));
case llvm::Triple::aarch64:
return *(TheTargetCodeGenInfo = new AArch64TargetCodeGenInfo(Types));
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case llvm::Triple::arm:
case llvm::Triple::thumb:
{
ARMABIInfo::ABIKind Kind = ARMABIInfo::AAPCS;
if (strcmp(getTarget().getABI(), "apcs-gnu") == 0)
Kind = ARMABIInfo::APCS;
else if (CodeGenOpts.FloatABI == "hard" ||
(CodeGenOpts.FloatABI != "soft" &&
Triple.getEnvironment() == llvm::Triple::GNUEABIHF))
Kind = ARMABIInfo::AAPCS_VFP;
switch (Triple.getOS()) {
case llvm::Triple::NaCl:
return *(TheTargetCodeGenInfo =
new NaClARMTargetCodeGenInfo(Types, Kind));
default:
return *(TheTargetCodeGenInfo =
new ARMTargetCodeGenInfo(Types, Kind));
}
}
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case llvm::Triple::ppc:
return *(TheTargetCodeGenInfo = new PPC32TargetCodeGenInfo(Types));
case llvm::Triple::ppc64:
if (Triple.isOSBinFormatELF())
return *(TheTargetCodeGenInfo = new PPC64_SVR4_TargetCodeGenInfo(Types));
else
return *(TheTargetCodeGenInfo = new PPC64TargetCodeGenInfo(Types));
case llvm::Triple::ppc64le:
assert(Triple.isOSBinFormatELF() && "PPC64 LE non-ELF not supported!");
return *(TheTargetCodeGenInfo = new PPC64_SVR4_TargetCodeGenInfo(Types));
case llvm::Triple::nvptx:
case llvm::Triple::nvptx64:
return *(TheTargetCodeGenInfo = new NVPTXTargetCodeGenInfo(Types));
case llvm::Triple::msp430:
return *(TheTargetCodeGenInfo = new MSP430TargetCodeGenInfo(Types));
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case llvm::Triple::systemz:
return *(TheTargetCodeGenInfo = new SystemZTargetCodeGenInfo(Types));
case llvm::Triple::tce:
return *(TheTargetCodeGenInfo = new TCETargetCodeGenInfo(Types));
case llvm::Triple::x86: {
bool IsDarwinVectorABI = Triple.isOSDarwin();
bool IsSmallStructInRegABI =
X86_32TargetCodeGenInfo::isStructReturnInRegABI(Triple, CodeGenOpts);
bool IsWin32FloatStructABI = (Triple.getOS() == llvm::Triple::Win32);
if (Triple.getOS() == llvm::Triple::Win32) {
return *(TheTargetCodeGenInfo =
new WinX86_32TargetCodeGenInfo(Types,
IsDarwinVectorABI, IsSmallStructInRegABI,
IsWin32FloatStructABI,
CodeGenOpts.NumRegisterParameters));
} else {
return *(TheTargetCodeGenInfo =
new X86_32TargetCodeGenInfo(Types,
IsDarwinVectorABI, IsSmallStructInRegABI,
IsWin32FloatStructABI,
CodeGenOpts.NumRegisterParameters));
}
}
case llvm::Triple::x86_64: {
bool HasAVX = strcmp(getTarget().getABI(), "avx") == 0;
switch (Triple.getOS()) {
case llvm::Triple::Win32:
case llvm::Triple::MinGW32:
case llvm::Triple::Cygwin:
return *(TheTargetCodeGenInfo = new WinX86_64TargetCodeGenInfo(Types));
case llvm::Triple::NaCl:
return *(TheTargetCodeGenInfo = new NaClX86_64TargetCodeGenInfo(Types,
HasAVX));
default:
return *(TheTargetCodeGenInfo = new X86_64TargetCodeGenInfo(Types,
HasAVX));
}
}
case llvm::Triple::hexagon:
return *(TheTargetCodeGenInfo = new HexagonTargetCodeGenInfo(Types));
case llvm::Triple::sparcv9:
return *(TheTargetCodeGenInfo = new SparcV9TargetCodeGenInfo(Types));
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case llvm::Triple::xcore:
return *(TheTargetCodeGenInfo = new XcoreTargetCodeGenInfo(Types));
}
}