本文整理汇总了C++中TargetRegisterInfo::getSubRegIdxOffset方法的典型用法代码示例。如果您正苦于以下问题:C++ TargetRegisterInfo::getSubRegIdxOffset方法的具体用法?C++ TargetRegisterInfo::getSubRegIdxOffset怎么用?C++ TargetRegisterInfo::getSubRegIdxOffset使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类TargetRegisterInfo
的用法示例。
在下文中一共展示了TargetRegisterInfo::getSubRegIdxOffset方法的2个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的C++代码示例。
示例1: addMachineReg
bool DwarfExpression::addMachineReg(const TargetRegisterInfo &TRI,
unsigned MachineReg, unsigned MaxSize) {
if (!TRI.isPhysicalRegister(MachineReg)) {
if (isFrameRegister(TRI, MachineReg)) {
DwarfRegs.push_back({-1, 0, nullptr});
return true;
}
return false;
}
int Reg = TRI.getDwarfRegNum(MachineReg, false);
// If this is a valid register number, emit it.
if (Reg >= 0) {
DwarfRegs.push_back({Reg, 0, nullptr});
return true;
}
// Walk up the super-register chain until we find a valid number.
// For example, EAX on x86_64 is a 32-bit fragment of RAX with offset 0.
for (MCSuperRegIterator SR(MachineReg, &TRI); SR.isValid(); ++SR) {
Reg = TRI.getDwarfRegNum(*SR, false);
if (Reg >= 0) {
unsigned Idx = TRI.getSubRegIndex(*SR, MachineReg);
unsigned Size = TRI.getSubRegIdxSize(Idx);
unsigned RegOffset = TRI.getSubRegIdxOffset(Idx);
DwarfRegs.push_back({Reg, 0, "super-register"});
// Use a DW_OP_bit_piece to describe the sub-register.
setSubRegisterPiece(Size, RegOffset);
return true;
}
}
// Otherwise, attempt to find a covering set of sub-register numbers.
// For example, Q0 on ARM is a composition of D0+D1.
unsigned CurPos = 0;
// The size of the register in bits, assuming 8 bits per byte.
unsigned RegSize = TRI.getMinimalPhysRegClass(MachineReg)->getSize() * 8;
// Keep track of the bits in the register we already emitted, so we
// can avoid emitting redundant aliasing subregs.
SmallBitVector Coverage(RegSize, false);
for (MCSubRegIterator SR(MachineReg, &TRI); SR.isValid(); ++SR) {
unsigned Idx = TRI.getSubRegIndex(MachineReg, *SR);
unsigned Size = TRI.getSubRegIdxSize(Idx);
unsigned Offset = TRI.getSubRegIdxOffset(Idx);
Reg = TRI.getDwarfRegNum(*SR, false);
// Intersection between the bits we already emitted and the bits
// covered by this subregister.
SmallBitVector Intersection(RegSize, false);
Intersection.set(Offset, Offset + Size);
Intersection ^= Coverage;
// If this sub-register has a DWARF number and we haven't covered
// its range, emit a DWARF piece for it.
if (Reg >= 0 && Intersection.any()) {
// Emit a piece for any gap in the coverage.
if (Offset > CurPos)
DwarfRegs.push_back({-1, Offset - CurPos, nullptr});
DwarfRegs.push_back(
{Reg, std::min<unsigned>(Size, MaxSize - Offset), "sub-register"});
if (Offset >= MaxSize)
break;
// Mark it as emitted.
Coverage.set(Offset, Offset + Size);
CurPos = Offset + Size;
}
}
return CurPos;
}
示例2: addMachineReg
bool DwarfExpression::addMachineReg(const TargetRegisterInfo &TRI,
unsigned MachineReg, unsigned MaxSize) {
if (!TRI.isPhysicalRegister(MachineReg)) {
if (isFrameRegister(TRI, MachineReg)) {
DwarfRegs.push_back({-1, 0, nullptr});
return true;
}
return false;
}
int Reg = TRI.getDwarfRegNum(MachineReg, false);
// If this is a valid register number, emit it.
if (Reg >= 0) {
DwarfRegs.push_back({Reg, 0, nullptr});
return true;
}
// Walk up the super-register chain until we find a valid number.
// For example, EAX on x86_64 is a 32-bit fragment of RAX with offset 0.
for (MCSuperRegIterator SR(MachineReg, &TRI); SR.isValid(); ++SR) {
Reg = TRI.getDwarfRegNum(*SR, false);
if (Reg >= 0) {
unsigned Idx = TRI.getSubRegIndex(*SR, MachineReg);
unsigned Size = TRI.getSubRegIdxSize(Idx);
unsigned RegOffset = TRI.getSubRegIdxOffset(Idx);
DwarfRegs.push_back({Reg, 0, "super-register"});
// Use a DW_OP_bit_piece to describe the sub-register.
setSubRegisterPiece(Size, RegOffset);
return true;
}
}
// Otherwise, attempt to find a covering set of sub-register numbers.
// For example, Q0 on ARM is a composition of D0+D1.
unsigned CurPos = 0;
// The size of the register in bits.
const TargetRegisterClass *RC = TRI.getMinimalPhysRegClass(MachineReg);
unsigned RegSize = TRI.getRegSizeInBits(*RC);
// Keep track of the bits in the register we already emitted, so we
// can avoid emitting redundant aliasing subregs. Because this is
// just doing a greedy scan of all subregisters, it is possible that
// this doesn't find a combination of subregisters that fully cover
// the register (even though one may exist).
SmallBitVector Coverage(RegSize, false);
for (MCSubRegIterator SR(MachineReg, &TRI); SR.isValid(); ++SR) {
unsigned Idx = TRI.getSubRegIndex(MachineReg, *SR);
unsigned Size = TRI.getSubRegIdxSize(Idx);
unsigned Offset = TRI.getSubRegIdxOffset(Idx);
Reg = TRI.getDwarfRegNum(*SR, false);
if (Reg < 0)
continue;
// Intersection between the bits we already emitted and the bits
// covered by this subregister.
SmallBitVector CurSubReg(RegSize, false);
CurSubReg.set(Offset, Offset + Size);
// If this sub-register has a DWARF number and we haven't covered
// its range, emit a DWARF piece for it.
if (CurSubReg.test(Coverage)) {
// Emit a piece for any gap in the coverage.
if (Offset > CurPos)
DwarfRegs.push_back({-1, Offset - CurPos, "no DWARF register encoding"});
DwarfRegs.push_back(
{Reg, std::min<unsigned>(Size, MaxSize - Offset), "sub-register"});
if (Offset >= MaxSize)
break;
// Mark it as emitted.
Coverage.set(Offset, Offset + Size);
CurPos = Offset + Size;
}
}
// Failed to find any DWARF encoding.
if (CurPos == 0)
return false;
// Found a partial or complete DWARF encoding.
if (CurPos < RegSize)
DwarfRegs.push_back({-1, RegSize - CurPos, "no DWARF register encoding"});
return true;
}