//===- TargetRegisterInfo.cpp - Target Register Information Implementation ===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the TargetRegisterInfo interface. // //===----------------------------------------------------------------------===// #include "llvm/Target/TargetMachine.h" #include "llvm/Target/TargetRegisterInfo.h" #include "llvm/ADT/BitVector.h" #include "llvm/Support/raw_ostream.h" using namespace llvm; TargetRegisterInfo::TargetRegisterInfo(const TargetRegisterInfoDesc *ID, regclass_iterator RCB, regclass_iterator RCE, const char *const *subregindexnames) : InfoDesc(ID), SubRegIndexNames(subregindexnames), RegClassBegin(RCB), RegClassEnd(RCE) { } TargetRegisterInfo::~TargetRegisterInfo() {} void PrintReg::print(raw_ostream &OS) const { if (!Reg) OS << "%noreg"; else if (TargetRegisterInfo::isStackSlot(Reg)) OS << "SS#" << TargetRegisterInfo::stackSlot2Index(Reg); else if (TargetRegisterInfo::isVirtualRegister(Reg)) OS << "%vreg" << TargetRegisterInfo::virtReg2Index(Reg); else if (TRI && Reg < TRI->getNumRegs()) OS << '%' << TRI->getName(Reg); else OS << "%physreg" << Reg; if (SubIdx) { if (TRI) OS << ':' << TRI->getSubRegIndexName(SubIdx); else OS << ":sub(" << SubIdx << ')'; } } void PrintRegUnit::print(raw_ostream &OS) const { // Generic printout when TRI is missing. if (!TRI) { OS << "Unit~" << Unit; return; } // Check for invalid register units. if (Unit >= TRI->getNumRegUnits()) { OS << "BadUnit~" << Unit; return; } // Normal units have at least one root. MCRegUnitRootIterator Roots(Unit, TRI); assert(Roots.isValid() && "Unit has no roots."); OS << TRI->getName(*Roots); for (++Roots; Roots.isValid(); ++Roots) OS << '~' << TRI->getName(*Roots); } /// getAllocatableClass - Return the maximal subclass of the given register /// class that is alloctable, or NULL. const TargetRegisterClass * TargetRegisterInfo::getAllocatableClass(const TargetRegisterClass *RC) const { if (!RC || RC->isAllocatable()) return RC; const unsigned *SubClass = RC->getSubClassMask(); for (unsigned Base = 0, BaseE = getNumRegClasses(); Base < BaseE; Base += 32) { unsigned Idx = Base; for (unsigned Mask = *SubClass++; Mask; Mask >>= 1) { unsigned Offset = CountTrailingZeros_32(Mask); const TargetRegisterClass *SubRC = getRegClass(Idx + Offset); if (SubRC->isAllocatable()) return SubRC; Mask >>= Offset; Idx += Offset + 1; } } return NULL; } /// getMinimalPhysRegClass - Returns the Register Class of a physical /// register of the given type, picking the most sub register class of /// the right type that contains this physreg. const TargetRegisterClass * TargetRegisterInfo::getMinimalPhysRegClass(unsigned reg, EVT VT) const { assert(isPhysicalRegister(reg) && "reg must be a physical register"); // Pick the most sub register class of the right type that contains // this physreg. const TargetRegisterClass* BestRC = 0; for (regclass_iterator I = regclass_begin(), E = regclass_end(); I != E; ++I){ const TargetRegisterClass* RC = *I; if ((VT == MVT::Other || RC->hasType(VT)) && RC->contains(reg) && (!BestRC || BestRC->hasSubClass(RC))) BestRC = RC; } assert(BestRC && "Couldn't find the register class"); return BestRC; } /// getAllocatableSetForRC - Toggle the bits that represent allocatable /// registers for the specific register class. static void getAllocatableSetForRC(const MachineFunction &MF, const TargetRegisterClass *RC, BitVector &R){ assert(RC->isAllocatable() && "invalid for nonallocatable sets"); ArrayRef<uint16_t> Order = RC->getRawAllocationOrder(MF); for (unsigned i = 0; i != Order.size(); ++i) R.set(Order[i]); } BitVector TargetRegisterInfo::getAllocatableSet(const MachineFunction &MF, const TargetRegisterClass *RC) const { BitVector Allocatable(getNumRegs()); if (RC) { // A register class with no allocatable subclass returns an empty set. const TargetRegisterClass *SubClass = getAllocatableClass(RC); if (SubClass) getAllocatableSetForRC(MF, SubClass, Allocatable); } else { for (TargetRegisterInfo::regclass_iterator I = regclass_begin(), E = regclass_end(); I != E; ++I) if ((*I)->isAllocatable()) getAllocatableSetForRC(MF, *I, Allocatable); } // Mask out the reserved registers BitVector Reserved = getReservedRegs(MF); Allocatable &= Reserved.flip(); return Allocatable; } static inline const TargetRegisterClass *firstCommonClass(const uint32_t *A, const uint32_t *B, const TargetRegisterInfo *TRI) { for (unsigned I = 0, E = TRI->getNumRegClasses(); I < E; I += 32) if (unsigned Common = *A++ & *B++) return TRI->getRegClass(I + CountTrailingZeros_32(Common)); return 0; } const TargetRegisterClass * TargetRegisterInfo::getCommonSubClass(const TargetRegisterClass *A, const TargetRegisterClass *B) const { // First take care of the trivial cases. if (A == B) return A; if (!A || !B) return 0; // Register classes are ordered topologically, so the largest common // sub-class it the common sub-class with the smallest ID. return firstCommonClass(A->getSubClassMask(), B->getSubClassMask(), this); } const TargetRegisterClass * TargetRegisterInfo::getMatchingSuperRegClass(const TargetRegisterClass *A, const TargetRegisterClass *B, unsigned Idx) const { assert(A && B && "Missing register class"); assert(Idx && "Bad sub-register index"); // Find Idx in the list of super-register indices. for (SuperRegClassIterator RCI(B, this); RCI.isValid(); ++RCI) if (RCI.getSubReg() == Idx) // The bit mask contains all register classes that are projected into B // by Idx. Find a class that is also a sub-class of A. return firstCommonClass(RCI.getMask(), A->getSubClassMask(), this); return 0; } const TargetRegisterClass *TargetRegisterInfo:: getCommonSuperRegClass(const TargetRegisterClass *RCA, unsigned SubA, const TargetRegisterClass *RCB, unsigned SubB, unsigned &PreA, unsigned &PreB) const { assert(RCA && SubA && RCB && SubB && "Invalid arguments"); // Search all pairs of sub-register indices that project into RCA and RCB // respectively. This is quadratic, but usually the sets are very small. On // most targets like X86, there will only be a single sub-register index // (e.g., sub_16bit projecting into GR16). // // The worst case is a register class like DPR on ARM. // We have indices dsub_0..dsub_7 projecting into that class. // // It is very common that one register class is a sub-register of the other. // Arrange for RCA to be the larger register so the answer will be found in // the first iteration. This makes the search linear for the most common // case. const TargetRegisterClass *BestRC = 0; unsigned *BestPreA = &PreA; unsigned *BestPreB = &PreB; if (RCA->getSize() < RCB->getSize()) { std::swap(RCA, RCB); std::swap(SubA, SubB); std::swap(BestPreA, BestPreB); } // Also terminate the search one we have found a register class as small as // RCA. unsigned MinSize = RCA->getSize(); for (SuperRegClassIterator IA(RCA, this, true); IA.isValid(); ++IA) { unsigned FinalA = composeSubRegIndices(IA.getSubReg(), SubA); for (SuperRegClassIterator IB(RCB, this, true); IB.isValid(); ++IB) { // Check if a common super-register class exists for this index pair. const TargetRegisterClass *RC = firstCommonClass(IA.getMask(), IB.getMask(), this); if (!RC || RC->getSize() < MinSize) continue; // The indexes must compose identically: PreA+SubA == PreB+SubB. unsigned FinalB = composeSubRegIndices(IB.getSubReg(), SubB); if (FinalA != FinalB) continue; // Is RC a better candidate than BestRC? if (BestRC && RC->getSize() >= BestRC->getSize()) continue; // Yes, RC is the smallest super-register seen so far. BestRC = RC; *BestPreA = IA.getSubReg(); *BestPreB = IB.getSubReg(); // Bail early if we reached MinSize. We won't find a better candidate. if (BestRC->getSize() == MinSize) return BestRC; } } return BestRC; }