llvm/lib/CodeGen/RDFRegisters.cpp - llvm-project - Git at Google

 //===- RDFRegisters.cpp ---------------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ADT/BitVector.h"
 #include "llvm/CodeGen/MachineFunction.h"
 #include "llvm/CodeGen/MachineInstr.h"
 #include "llvm/CodeGen/MachineOperand.h"
 #include "llvm/CodeGen/RDFRegisters.h"
 #include "llvm/CodeGen/TargetRegisterInfo.h"
 #include "llvm/MC/LaneBitmask.h"
 #include "llvm/MC/MCRegisterInfo.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/raw_ostream.h"
 #include <cassert>
 #include <cstdint>
 #include <set>
 #include <utility>

 using namespace llvm;
 using namespace rdf;

 PhysicalRegisterInfo::PhysicalRegisterInfo(const TargetRegisterInfo &tri,
       const MachineFunction &mf)
     : TRI(tri) {
   RegInfos.resize(TRI.getNumRegs());

   BitVector BadRC(TRI.getNumRegs());
   for (const TargetRegisterClass *RC : TRI.regclasses()) {
     for (MCPhysReg R : *RC) {
       RegInfo &RI = RegInfos[R];
       if (RI.RegClass != nullptr && !BadRC[R]) {
         if (RC->LaneMask != RI.RegClass->LaneMask) {
           BadRC.set(R);
           RI.RegClass = nullptr;
         }
       } else
         RI.RegClass = RC;
     }
   }

   UnitInfos.resize(TRI.getNumRegUnits());

   for (uint32_t U = 0, NU = TRI.getNumRegUnits(); U != NU; ++U) {
     if (UnitInfos[U].Reg != 0)
       continue;
     MCRegUnitRootIterator R(U, &TRI);
     assert(R.isValid());
     RegisterId F = *R;
     ++R;
     if (R.isValid()) {
       UnitInfos[U].Mask = LaneBitmask::getAll();
       UnitInfos[U].Reg = F;
     } else {
       for (MCRegUnitMaskIterator I(F, &TRI); I.isValid(); ++I) {
         std::pair<uint32_t,LaneBitmask> P = *I;
         UnitInfo &UI = UnitInfos[P.first];
         UI.Reg = F;
         if (P.second.any()) {
           UI.Mask = P.second;
         } else {
           if (const TargetRegisterClass *RC = RegInfos[F].RegClass)
             UI.Mask = RC->LaneMask;
           else
             UI.Mask = LaneBitmask::getAll();
         }
       }
     }
   }

   for (const uint32_t *RM : TRI.getRegMasks())
     RegMasks.insert(RM);
   for (const MachineBasicBlock &B : mf)
     for (const MachineInstr &In : B)
       for (const MachineOperand &Op : In.operands())
         if (Op.isRegMask())
           RegMasks.insert(Op.getRegMask());

   MaskInfos.resize(RegMasks.size()+1);
   for (uint32_t M = 1, NM = RegMasks.size(); M <= NM; ++M) {
     BitVector PU(TRI.getNumRegUnits());
     const uint32_t *MB = RegMasks.get(M);
     for (unsigned I = 1, E = TRI.getNumRegs(); I != E; ++I) {
       if (!(MB[I / 32] & (1u << (I % 32))))
         continue;
       for (MCRegUnitIterator U(MCRegister::from(I), &TRI); U.isValid(); ++U)
         PU.set(*U);
     }
     MaskInfos[M].Units = PU.flip();
   }

   AliasInfos.resize(TRI.getNumRegUnits());
   for (uint32_t U = 0, NU = TRI.getNumRegUnits(); U != NU; ++U) {
     BitVector AS(TRI.getNumRegs());
     for (MCRegUnitRootIterator R(U, &TRI); R.isValid(); ++R)
       for (MCSuperRegIterator S(*R, &TRI, true); S.isValid(); ++S)
         AS.set(*S);
     AliasInfos[U].Regs = AS;
   }
 }

 std::set<RegisterId> PhysicalRegisterInfo::getAliasSet(RegisterId Reg) const {
   // Do not include RR in the alias set.
   std::set<RegisterId> AS;
   assert(isRegMaskId(Reg) || Register::isPhysicalRegister(Reg));
   if (isRegMaskId(Reg)) {
     // XXX SLOW
     const uint32_t *MB = getRegMaskBits(Reg);
     for (unsigned i = 1, e = TRI.getNumRegs(); i != e; ++i) {
       if (MB[i/32] & (1u << (i%32)))
         continue;
       AS.insert(i);
     }
     for (const uint32_t *RM : RegMasks) {
       RegisterId MI = getRegMaskId(RM);
       if (MI != Reg && aliasMM(RegisterRef(Reg), RegisterRef(MI)))
         AS.insert(MI);
     }
     return AS;
   }

   for (MCRegAliasIterator AI(Reg, &TRI, false); AI.isValid(); ++AI)
     AS.insert(*AI);
   for (const uint32_t *RM : RegMasks) {
     RegisterId MI = getRegMaskId(RM);
     if (aliasRM(RegisterRef(Reg), RegisterRef(MI)))
       AS.insert(MI);
   }
   return AS;
 }

 bool PhysicalRegisterInfo::aliasRR(RegisterRef RA, RegisterRef RB) const {
   assert(Register::isPhysicalRegister(RA.Reg));
   assert(Register::isPhysicalRegister(RB.Reg));

   MCRegUnitMaskIterator UMA(RA.Reg, &TRI);
   MCRegUnitMaskIterator UMB(RB.Reg, &TRI);
   // Reg units are returned in the numerical order.
   while (UMA.isValid() && UMB.isValid()) {
     // Skip units that are masked off in RA.
     std::pair<RegisterId,LaneBitmask> PA = *UMA;
     if (PA.second.any() && (PA.second & RA.Mask).none()) {
       ++UMA;
       continue;
     }
     // Skip units that are masked off in RB.
     std::pair<RegisterId,LaneBitmask> PB = *UMB;
     if (PB.second.any() && (PB.second & RB.Mask).none()) {
       ++UMB;
       continue;
     }

     if (PA.first == PB.first)
       return true;
     if (PA.first < PB.first)
       ++UMA;
     else if (PB.first < PA.first)
       ++UMB;
   }
   return false;
 }

 bool PhysicalRegisterInfo::aliasRM(RegisterRef RR, RegisterRef RM) const {
   assert(Register::isPhysicalRegister(RR.Reg) && isRegMaskId(RM.Reg));
   const uint32_t *MB = getRegMaskBits(RM.Reg);
   bool Preserved = MB[RR.Reg/32] & (1u << (RR.Reg%32));
   // If the lane mask information is "full", e.g. when the given lane mask
   // is a superset of the lane mask from the register class, check the regmask
   // bit directly.
   if (RR.Mask == LaneBitmask::getAll())
     return !Preserved;
   const TargetRegisterClass *RC = RegInfos[RR.Reg].RegClass;
   if (RC != nullptr && (RR.Mask & RC->LaneMask) == RC->LaneMask)
     return !Preserved;

   // Otherwise, check all subregisters whose lane mask overlaps the given
   // mask. For each such register, if it is preserved by the regmask, then
   // clear the corresponding bits in the given mask. If at the end, all
   // bits have been cleared, the register does not alias the regmask (i.e.
   // is it preserved by it).
   LaneBitmask M = RR.Mask;
   for (MCSubRegIndexIterator SI(RR.Reg, &TRI); SI.isValid(); ++SI) {
     LaneBitmask SM = TRI.getSubRegIndexLaneMask(SI.getSubRegIndex());
     if ((SM & RR.Mask).none())
       continue;
     unsigned SR = SI.getSubReg();
     if (!(MB[SR/32] & (1u << (SR%32))))
       continue;
     // The subregister SR is preserved.
     M &= ~SM;
     if (M.none())
       return false;
   }

   return true;
 }

 bool PhysicalRegisterInfo::aliasMM(RegisterRef RM, RegisterRef RN) const {
   assert(isRegMaskId(RM.Reg) && isRegMaskId(RN.Reg));
   unsigned NumRegs = TRI.getNumRegs();
   const uint32_t *BM = getRegMaskBits(RM.Reg);
   const uint32_t *BN = getRegMaskBits(RN.Reg);

   for (unsigned w = 0, nw = NumRegs/32; w != nw; ++w) {
     // Intersect the negations of both words. Disregard reg=0,
     // i.e. 0th bit in the 0th word.
     uint32_t C = ~BM[w] & ~BN[w];
     if (w == 0)
       C &= ~1;
     if (C)
       return true;
   }

   // Check the remaining registers in the last word.
   unsigned TailRegs = NumRegs % 32;
   if (TailRegs == 0)
     return false;
   unsigned TW = NumRegs / 32;
   uint32_t TailMask = (1u << TailRegs) - 1;
   if (~BM[TW] & ~BN[TW] & TailMask)
     return true;

   return false;
 }

 RegisterRef PhysicalRegisterInfo::mapTo(RegisterRef RR, unsigned R) const {
   if (RR.Reg == R)
     return RR;
   if (unsigned Idx = TRI.getSubRegIndex(R, RR.Reg))
     return RegisterRef(R, TRI.composeSubRegIndexLaneMask(Idx, RR.Mask));
   if (unsigned Idx = TRI.getSubRegIndex(RR.Reg, R)) {
     const RegInfo &RI = RegInfos[R];
     LaneBitmask RCM = RI.RegClass ? RI.RegClass->LaneMask
                                   : LaneBitmask::getAll();
     LaneBitmask M = TRI.reverseComposeSubRegIndexLaneMask(Idx, RR.Mask);
     return RegisterRef(R, M & RCM);
   }
   llvm_unreachable("Invalid arguments: unrelated registers?");
 }

 bool RegisterAggr::hasAliasOf(RegisterRef RR) const {
   if (PhysicalRegisterInfo::isRegMaskId(RR.Reg))
     return Units.anyCommon(PRI.getMaskUnits(RR.Reg));

   for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
     std::pair<uint32_t,LaneBitmask> P = *U;
     if (P.second.none() || (P.second & RR.Mask).any())
       if (Units.test(P.first))
         return true;
   }
   return false;
 }

 bool RegisterAggr::hasCoverOf(RegisterRef RR) const {
   if (PhysicalRegisterInfo::isRegMaskId(RR.Reg)) {
     BitVector T(PRI.getMaskUnits(RR.Reg));
     return T.reset(Units).none();
   }

   for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
     std::pair<uint32_t,LaneBitmask> P = *U;
     if (P.second.none() || (P.second & RR.Mask).any())
       if (!Units.test(P.first))
         return false;
   }
   return true;
 }

 RegisterAggr &RegisterAggr::insert(RegisterRef RR) {
   if (PhysicalRegisterInfo::isRegMaskId(RR.Reg)) {
     Units |= PRI.getMaskUnits(RR.Reg);
     return *this;
   }

   for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
     std::pair<uint32_t,LaneBitmask> P = *U;
     if (P.second.none() || (P.second & RR.Mask).any())
       Units.set(P.first);
   }
   return *this;
 }

 RegisterAggr &RegisterAggr::insert(const RegisterAggr &RG) {
   Units |= RG.Units;
   return *this;
 }

 RegisterAggr &RegisterAggr::intersect(RegisterRef RR) {
   return intersect(RegisterAggr(PRI).insert(RR));
 }

 RegisterAggr &RegisterAggr::intersect(const RegisterAggr &RG) {
   Units &= RG.Units;
   return *this;
 }

 RegisterAggr &RegisterAggr::clear(RegisterRef RR) {
   return clear(RegisterAggr(PRI).insert(RR));
 }

 RegisterAggr &RegisterAggr::clear(const RegisterAggr &RG) {
   Units.reset(RG.Units);
   return *this;
 }

 RegisterRef RegisterAggr::intersectWith(RegisterRef RR) const {
   RegisterAggr T(PRI);
   T.insert(RR).intersect(*this);
   if (T.empty())
     return RegisterRef();
   RegisterRef NR = T.makeRegRef();
   assert(NR);
   return NR;
 }

 RegisterRef RegisterAggr::clearIn(RegisterRef RR) const {
   return RegisterAggr(PRI).insert(RR).clear(*this).makeRegRef();
 }

 RegisterRef RegisterAggr::makeRegRef() const {
   int U = Units.find_first();
   if (U < 0)
     return RegisterRef();

   // Find the set of all registers that are aliased to all the units
   // in this aggregate.

   // Get all the registers aliased to the first unit in the bit vector.
   BitVector Regs = PRI.getUnitAliases(U);
   U = Units.find_next(U);

   // For each other unit, intersect it with the set of all registers
   // aliased that unit.
   while (U >= 0) {
     Regs &= PRI.getUnitAliases(U);
     U = Units.find_next(U);
   }

   // If there is at least one register remaining, pick the first one,
   // and consolidate the masks of all of its units contained in this
   // aggregate.

   int F = Regs.find_first();
   if (F <= 0)
     return RegisterRef();

   LaneBitmask M;
   for (MCRegUnitMaskIterator I(F, &PRI.getTRI()); I.isValid(); ++I) {
     std::pair<uint32_t,LaneBitmask> P = *I;
     if (Units.test(P.first))
       M |= P.second.none() ? LaneBitmask::getAll() : P.second;
   }
   return RegisterRef(F, M);
 }

 void RegisterAggr::print(raw_ostream &OS) const {
   OS << '{';
   for (int U = Units.find_first(); U >= 0; U = Units.find_next(U))
     OS << ' ' << printRegUnit(U, &PRI.getTRI());
   OS << " }";
 }

 RegisterAggr::rr_iterator::rr_iterator(const RegisterAggr &RG,
       bool End)
     : Owner(&RG) {
   for (int U = RG.Units.find_first(); U >= 0; U = RG.Units.find_next(U)) {
     RegisterRef R = RG.PRI.getRefForUnit(U);
     Masks[R.Reg] |= R.Mask;
   }
   Pos = End ? Masks.end() : Masks.begin();
   Index = End ? Masks.size() : 0;
 }

 raw_ostream &rdf::operator<<(raw_ostream &OS, const RegisterAggr &A) {
   A.print(OS);
   return OS;
 }
	//===- RDFRegisters.cpp ---------------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ADT/BitVector.h"
	#include "llvm/CodeGen/MachineFunction.h"
	#include "llvm/CodeGen/MachineInstr.h"
	#include "llvm/CodeGen/MachineOperand.h"
	#include "llvm/CodeGen/RDFRegisters.h"
	#include "llvm/CodeGen/TargetRegisterInfo.h"
	#include "llvm/MC/LaneBitmask.h"
	#include "llvm/MC/MCRegisterInfo.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/raw_ostream.h"
	#include <cassert>
	#include <cstdint>
	#include <set>
	#include <utility>

	using namespace llvm;
	using namespace rdf;

	PhysicalRegisterInfo::PhysicalRegisterInfo(const TargetRegisterInfo &tri,
	const MachineFunction &mf)
	: TRI(tri) {
	RegInfos.resize(TRI.getNumRegs());

	BitVector BadRC(TRI.getNumRegs());
	for (const TargetRegisterClass *RC : TRI.regclasses()) {
	for (MCPhysReg R : *RC) {
	RegInfo &RI = RegInfos[R];
	if (RI.RegClass != nullptr && !BadRC[R]) {
	if (RC->LaneMask != RI.RegClass->LaneMask) {
	BadRC.set(R);
	RI.RegClass = nullptr;
	}
	} else
	RI.RegClass = RC;
	}
	}

	UnitInfos.resize(TRI.getNumRegUnits());

	for (uint32_t U = 0, NU = TRI.getNumRegUnits(); U != NU; ++U) {
	if (UnitInfos[U].Reg != 0)
	continue;
	MCRegUnitRootIterator R(U, &TRI);
	assert(R.isValid());
	RegisterId F = *R;
	++R;
	if (R.isValid()) {
	UnitInfos[U].Mask = LaneBitmask::getAll();
	UnitInfos[U].Reg = F;
	} else {
	for (MCRegUnitMaskIterator I(F, &TRI); I.isValid(); ++I) {
	std::pair<uint32_t,LaneBitmask> P = *I;
	UnitInfo &UI = UnitInfos[P.first];
	UI.Reg = F;
	if (P.second.any()) {
	UI.Mask = P.second;
	} else {
	if (const TargetRegisterClass *RC = RegInfos[F].RegClass)
	UI.Mask = RC->LaneMask;
	else
	UI.Mask = LaneBitmask::getAll();
	}
	}
	}
	}

	for (const uint32_t *RM : TRI.getRegMasks())
	RegMasks.insert(RM);
	for (const MachineBasicBlock &B : mf)
	for (const MachineInstr &In : B)
	for (const MachineOperand &Op : In.operands())
	if (Op.isRegMask())
	RegMasks.insert(Op.getRegMask());

	MaskInfos.resize(RegMasks.size()+1);
	for (uint32_t M = 1, NM = RegMasks.size(); M <= NM; ++M) {
	BitVector PU(TRI.getNumRegUnits());
	const uint32_t *MB = RegMasks.get(M);
	for (unsigned I = 1, E = TRI.getNumRegs(); I != E; ++I) {
	if (!(MB[I / 32] & (1u << (I % 32))))
	continue;
	for (MCRegUnitIterator U(MCRegister::from(I), &TRI); U.isValid(); ++U)
	PU.set(*U);
	}
	MaskInfos[M].Units = PU.flip();
	}

	AliasInfos.resize(TRI.getNumRegUnits());
	for (uint32_t U = 0, NU = TRI.getNumRegUnits(); U != NU; ++U) {
	BitVector AS(TRI.getNumRegs());
	for (MCRegUnitRootIterator R(U, &TRI); R.isValid(); ++R)
	for (MCSuperRegIterator S(*R, &TRI, true); S.isValid(); ++S)
	AS.set(*S);
	AliasInfos[U].Regs = AS;
	}
	}

	std::set<RegisterId> PhysicalRegisterInfo::getAliasSet(RegisterId Reg) const {
	// Do not include RR in the alias set.
	std::set<RegisterId> AS;
	assert(isRegMaskId(Reg) \|\| Register::isPhysicalRegister(Reg));
	if (isRegMaskId(Reg)) {
	// XXX SLOW
	const uint32_t *MB = getRegMaskBits(Reg);
	for (unsigned i = 1, e = TRI.getNumRegs(); i != e; ++i) {
	if (MB[i/32] & (1u << (i%32)))
	continue;
	AS.insert(i);
	}
	for (const uint32_t *RM : RegMasks) {
	RegisterId MI = getRegMaskId(RM);
	if (MI != Reg && aliasMM(RegisterRef(Reg), RegisterRef(MI)))
	AS.insert(MI);
	}
	return AS;
	}

	for (MCRegAliasIterator AI(Reg, &TRI, false); AI.isValid(); ++AI)
	AS.insert(*AI);
	for (const uint32_t *RM : RegMasks) {
	RegisterId MI = getRegMaskId(RM);
	if (aliasRM(RegisterRef(Reg), RegisterRef(MI)))
	AS.insert(MI);
	}
	return AS;
	}

	bool PhysicalRegisterInfo::aliasRR(RegisterRef RA, RegisterRef RB) const {
	assert(Register::isPhysicalRegister(RA.Reg));
	assert(Register::isPhysicalRegister(RB.Reg));

	MCRegUnitMaskIterator UMA(RA.Reg, &TRI);
	MCRegUnitMaskIterator UMB(RB.Reg, &TRI);
	// Reg units are returned in the numerical order.
	while (UMA.isValid() && UMB.isValid()) {
	// Skip units that are masked off in RA.
	std::pair<RegisterId,LaneBitmask> PA = *UMA;
	if (PA.second.any() && (PA.second & RA.Mask).none()) {
	++UMA;
	continue;
	}
	// Skip units that are masked off in RB.
	std::pair<RegisterId,LaneBitmask> PB = *UMB;
	if (PB.second.any() && (PB.second & RB.Mask).none()) {
	++UMB;
	continue;
	}

	if (PA.first == PB.first)
	return true;
	if (PA.first < PB.first)
	++UMA;
	else if (PB.first < PA.first)
	++UMB;
	}
	return false;
	}

	bool PhysicalRegisterInfo::aliasRM(RegisterRef RR, RegisterRef RM) const {
	assert(Register::isPhysicalRegister(RR.Reg) && isRegMaskId(RM.Reg));
	const uint32_t *MB = getRegMaskBits(RM.Reg);
	bool Preserved = MB[RR.Reg/32] & (1u << (RR.Reg%32));
	// If the lane mask information is "full", e.g. when the given lane mask
	// is a superset of the lane mask from the register class, check the regmask
	// bit directly.
	if (RR.Mask == LaneBitmask::getAll())
	return !Preserved;
	const TargetRegisterClass *RC = RegInfos[RR.Reg].RegClass;
	if (RC != nullptr && (RR.Mask & RC->LaneMask) == RC->LaneMask)
	return !Preserved;

	// Otherwise, check all subregisters whose lane mask overlaps the given
	// mask. For each such register, if it is preserved by the regmask, then
	// clear the corresponding bits in the given mask. If at the end, all
	// bits have been cleared, the register does not alias the regmask (i.e.
	// is it preserved by it).
	LaneBitmask M = RR.Mask;
	for (MCSubRegIndexIterator SI(RR.Reg, &TRI); SI.isValid(); ++SI) {
	LaneBitmask SM = TRI.getSubRegIndexLaneMask(SI.getSubRegIndex());
	if ((SM & RR.Mask).none())
	continue;
	unsigned SR = SI.getSubReg();
	if (!(MB[SR/32] & (1u << (SR%32))))
	continue;
	// The subregister SR is preserved.
	M &= ~SM;
	if (M.none())
	return false;
	}

	return true;
	}

	bool PhysicalRegisterInfo::aliasMM(RegisterRef RM, RegisterRef RN) const {
	assert(isRegMaskId(RM.Reg) && isRegMaskId(RN.Reg));
	unsigned NumRegs = TRI.getNumRegs();
	const uint32_t *BM = getRegMaskBits(RM.Reg);
	const uint32_t *BN = getRegMaskBits(RN.Reg);

	for (unsigned w = 0, nw = NumRegs/32; w != nw; ++w) {
	// Intersect the negations of both words. Disregard reg=0,
	// i.e. 0th bit in the 0th word.
	uint32_t C = ~BM[w] & ~BN[w];
	if (w == 0)
	C &= ~1;
	if (C)
	return true;
	}

	// Check the remaining registers in the last word.
	unsigned TailRegs = NumRegs % 32;
	if (TailRegs == 0)
	return false;
	unsigned TW = NumRegs / 32;
	uint32_t TailMask = (1u << TailRegs) - 1;
	if (~BM[TW] & ~BN[TW] & TailMask)
	return true;

	return false;
	}

	RegisterRef PhysicalRegisterInfo::mapTo(RegisterRef RR, unsigned R) const {
	if (RR.Reg == R)
	return RR;
	if (unsigned Idx = TRI.getSubRegIndex(R, RR.Reg))
	return RegisterRef(R, TRI.composeSubRegIndexLaneMask(Idx, RR.Mask));
	if (unsigned Idx = TRI.getSubRegIndex(RR.Reg, R)) {
	const RegInfo &RI = RegInfos[R];
	LaneBitmask RCM = RI.RegClass ? RI.RegClass->LaneMask
	: LaneBitmask::getAll();
	LaneBitmask M = TRI.reverseComposeSubRegIndexLaneMask(Idx, RR.Mask);
	return RegisterRef(R, M & RCM);
	}
	llvm_unreachable("Invalid arguments: unrelated registers?");
	}

	bool RegisterAggr::hasAliasOf(RegisterRef RR) const {
	if (PhysicalRegisterInfo::isRegMaskId(RR.Reg))
	return Units.anyCommon(PRI.getMaskUnits(RR.Reg));

	for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
	std::pair<uint32_t,LaneBitmask> P = *U;
	if (P.second.none() \|\| (P.second & RR.Mask).any())
	if (Units.test(P.first))
	return true;
	}
	return false;
	}

	bool RegisterAggr::hasCoverOf(RegisterRef RR) const {
	if (PhysicalRegisterInfo::isRegMaskId(RR.Reg)) {
	BitVector T(PRI.getMaskUnits(RR.Reg));
	return T.reset(Units).none();
	}

	for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
	std::pair<uint32_t,LaneBitmask> P = *U;
	if (P.second.none() \|\| (P.second & RR.Mask).any())
	if (!Units.test(P.first))
	return false;
	}
	return true;
	}

	RegisterAggr &RegisterAggr::insert(RegisterRef RR) {
	if (PhysicalRegisterInfo::isRegMaskId(RR.Reg)) {
	Units \|= PRI.getMaskUnits(RR.Reg);
	return *this;
	}

	for (MCRegUnitMaskIterator U(RR.Reg, &PRI.getTRI()); U.isValid(); ++U) {
	std::pair<uint32_t,LaneBitmask> P = *U;
	if (P.second.none() \|\| (P.second & RR.Mask).any())
	Units.set(P.first);
	}
	return *this;
	}

	RegisterAggr &RegisterAggr::insert(const RegisterAggr &RG) {
	Units \|= RG.Units;
	return *this;
	}

	RegisterAggr &RegisterAggr::intersect(RegisterRef RR) {
	return intersect(RegisterAggr(PRI).insert(RR));
	}

	RegisterAggr &RegisterAggr::intersect(const RegisterAggr &RG) {
	Units &= RG.Units;
	return *this;
	}

	RegisterAggr &RegisterAggr::clear(RegisterRef RR) {
	return clear(RegisterAggr(PRI).insert(RR));
	}

	RegisterAggr &RegisterAggr::clear(const RegisterAggr &RG) {
	Units.reset(RG.Units);
	return *this;
	}

	RegisterRef RegisterAggr::intersectWith(RegisterRef RR) const {
	RegisterAggr T(PRI);
	T.insert(RR).intersect(*this);
	if (T.empty())
	return RegisterRef();
	RegisterRef NR = T.makeRegRef();
	assert(NR);
	return NR;
	}

	RegisterRef RegisterAggr::clearIn(RegisterRef RR) const {
	return RegisterAggr(PRI).insert(RR).clear(*this).makeRegRef();
	}

	RegisterRef RegisterAggr::makeRegRef() const {
	int U = Units.find_first();
	if (U < 0)
	return RegisterRef();

	// Find the set of all registers that are aliased to all the units
	// in this aggregate.

	// Get all the registers aliased to the first unit in the bit vector.
	BitVector Regs = PRI.getUnitAliases(U);
	U = Units.find_next(U);

	// For each other unit, intersect it with the set of all registers
	// aliased that unit.
	while (U >= 0) {
	Regs &= PRI.getUnitAliases(U);
	U = Units.find_next(U);
	}

	// If there is at least one register remaining, pick the first one,
	// and consolidate the masks of all of its units contained in this
	// aggregate.

	int F = Regs.find_first();
	if (F <= 0)
	return RegisterRef();

	LaneBitmask M;
	for (MCRegUnitMaskIterator I(F, &PRI.getTRI()); I.isValid(); ++I) {
	std::pair<uint32_t,LaneBitmask> P = *I;
	if (Units.test(P.first))
	M \|= P.second.none() ? LaneBitmask::getAll() : P.second;
	}
	return RegisterRef(F, M);
	}

	void RegisterAggr::print(raw_ostream &OS) const {
	OS << '{';
	for (int U = Units.find_first(); U >= 0; U = Units.find_next(U))
	OS << ' ' << printRegUnit(U, &PRI.getTRI());
	OS << " }";
	}

	RegisterAggr::rr_iterator::rr_iterator(const RegisterAggr &RG,
	bool End)
	: Owner(&RG) {
	for (int U = RG.Units.find_first(); U >= 0; U = RG.Units.find_next(U)) {
	RegisterRef R = RG.PRI.getRefForUnit(U);
	Masks[R.Reg] \|= R.Mask;
	}
	Pos = End ? Masks.end() : Masks.begin();
	Index = End ? Masks.size() : 0;
	}

	raw_ostream &rdf::operator<<(raw_ostream &OS, const RegisterAggr &A) {
	A.print(OS);
	return OS;
	}