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llvm / llvm / d5c2cca72463233df77a065f201db31b140eb44d / . / lib / Target / Hexagon / MCTargetDesc / HexagonMCInstrInfo.h
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//===- HexagonMCInstrInfo.cpp - Utility functions on Hexagon MCInsts ------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Utility functions for Hexagon specific MCInst queries
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_LIB_TARGET_HEXAGON_MCTARGETDESC_HEXAGONMCINSTRINFO_H
#define LLVM_LIB_TARGET_HEXAGON_MCTARGETDESC_HEXAGONMCINSTRINFO_H
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/MC/MCInst.h"
#include "llvm/Support/MathExtras.h"
#include <cstddef>
#include <cstdint>
namespace llvm {
class HexagonMCChecker;
class MCContext;
class MCExpr;
class MCInstrDesc;
class MCInstrInfo;
class MCSubtargetInfo;
class DuplexCandidate {
public:
unsigned packetIndexI, packetIndexJ, iClass;
DuplexCandidate(unsigned i, unsigned j, unsigned iClass)
: packetIndexI(i), packetIndexJ(j), iClass(iClass) {}
};
namespace Hexagon {
class PacketIterator {
MCInstrInfo const &MCII;
MCInst::const_iterator BundleCurrent;
MCInst::const_iterator BundleEnd;
MCInst::const_iterator DuplexCurrent;
MCInst::const_iterator DuplexEnd;
public:
PacketIterator(MCInstrInfo const &MCII, MCInst const &Inst);
PacketIterator(MCInstrInfo const &MCII, MCInst const &Inst, std::nullptr_t);
PacketIterator &operator++();
MCInst const &operator*() const;
bool operator==(PacketIterator const &Other) const;
bool operator!=(PacketIterator const &Other) const {
return !(*this == Other);
}
};
} // end namespace Hexagon
namespace HexagonMCInstrInfo {
size_t const innerLoopOffset = 0;
int64_t const innerLoopMask = 1 << innerLoopOffset;
size_t const outerLoopOffset = 1;
int64_t const outerLoopMask = 1 << outerLoopOffset;
// do not reorder memory load/stores by default load/stores are re-ordered
// and by default loads can be re-ordered
size_t const memReorderDisabledOffset = 2;
int64_t const memReorderDisabledMask = 1 << memReorderDisabledOffset;
// allow re-ordering of memory stores by default stores cannot be re-ordered
size_t const memStoreReorderEnabledOffset = 3;
int64_t const memStoreReorderEnabledMask = 1 << memStoreReorderEnabledOffset;
size_t const bundleInstructionsOffset = 1;
void addConstant(MCInst &MI, uint64_t Value, MCContext &Context);
void addConstExtender(MCContext &Context, MCInstrInfo const &MCII, MCInst &MCB,
MCInst const &MCI);
// Returns a iterator range of instructions in this bundle
iterator_range<Hexagon::PacketIterator>
bundleInstructions(MCInstrInfo const &MCII, MCInst const &MCI);
iterator_range<MCInst::const_iterator> bundleInstructions(MCInst const &MCI);
// Returns the number of instructions in the bundle
size_t bundleSize(MCInst const &MCI);
// Put the packet in to canonical form, compound, duplex, pad, and shuffle
bool canonicalizePacket(MCInstrInfo const &MCII, MCSubtargetInfo const &STI,
MCContext &Context, MCInst &MCB,
HexagonMCChecker *Checker);
// Create a duplex instruction given the two subinsts
MCInst *deriveDuplex(MCContext &Context, unsigned iClass, MCInst const &inst0,
MCInst const &inst1);
MCInst deriveExtender(MCInstrInfo const &MCII, MCInst const &Inst,
MCOperand const &MO);
// Convert this instruction in to a duplex subinst
MCInst deriveSubInst(MCInst const &Inst);
// Clamp off upper 26 bits of extendable operand for emission
void clampExtended(MCInstrInfo const &MCII, MCContext &Context, MCInst &MCI);
MCInst createBundle();
// Return the extender for instruction at Index or nullptr if none
MCInst const *extenderForIndex(MCInst const &MCB, size_t Index);
void extendIfNeeded(MCContext &Context, MCInstrInfo const &MCII, MCInst &MCB,
MCInst const &MCI);
// Return memory access size in bytes
unsigned getMemAccessSize(MCInstrInfo const &MCII, MCInst const &MCI);
MCInstrDesc const &getDesc(MCInstrInfo const &MCII, MCInst const &MCI);
// Return which duplex group this instruction belongs to
unsigned getDuplexCandidateGroup(MCInst const &MI);
// Return a list of all possible instruction duplex combinations
SmallVector<DuplexCandidate, 8>
getDuplexPossibilties(MCInstrInfo const &MCII, MCSubtargetInfo const &STI,
MCInst const &MCB);
unsigned getDuplexRegisterNumbering(unsigned Reg);
MCExpr const &getExpr(MCExpr const &Expr);
// Return the index of the extendable operand
unsigned short getExtendableOp(MCInstrInfo const &MCII, MCInst const &MCI);
// Return a reference to the extendable operand
MCOperand const &getExtendableOperand(MCInstrInfo const &MCII,
MCInst const &MCI);
// Return the implicit alignment of the extendable operand
unsigned getExtentAlignment(MCInstrInfo const &MCII, MCInst const &MCI);
// Return the number of logical bits of the extendable operand
unsigned getExtentBits(MCInstrInfo const &MCII, MCInst const &MCI);
// Return the max value that a constant extendable operand can have
// without being extended.
int getMaxValue(MCInstrInfo const &MCII, MCInst const &MCI);
// Return the min value that a constant extendable operand can have
// without being extended.
int getMinValue(MCInstrInfo const &MCII, MCInst const &MCI);
// Return instruction name
StringRef getName(MCInstrInfo const &MCII, MCInst const &MCI);
// Return the operand index for the new value.
unsigned short getNewValueOp(MCInstrInfo const &MCII, MCInst const &MCI);
// Return the operand that consumes or produces a new value.
MCOperand const &getNewValueOperand(MCInstrInfo const &MCII, MCInst const &MCI);
unsigned short getNewValueOp2(MCInstrInfo const &MCII, MCInst const &MCI);
MCOperand const &getNewValueOperand2(MCInstrInfo const &MCII,
MCInst const &MCI);
// Return the Hexagon ISA class for the insn.
unsigned getType(MCInstrInfo const &MCII, MCInst const &MCI);
/// Return the slots used by the insn.
unsigned getUnits(MCInstrInfo const &MCII, MCSubtargetInfo const &STI,
MCInst const &MCI);
unsigned getOtherReservedSlots(MCInstrInfo const &MCII,
MCSubtargetInfo const &STI, MCInst const &MCI);
bool hasDuplex(MCInstrInfo const &MCII, MCInst const &MCI);
// Does the packet have an extender for the instruction at Index
bool hasExtenderForIndex(MCInst const &MCB, size_t Index);
bool hasImmExt(MCInst const &MCI);
// Return whether the instruction is a legal new-value producer.
bool hasNewValue(MCInstrInfo const &MCII, MCInst const &MCI);
bool hasNewValue2(MCInstrInfo const &MCII, MCInst const &MCI);
unsigned iClassOfDuplexPair(unsigned Ga, unsigned Gb);
int64_t minConstant(MCInst const &MCI, size_t Index);
template <unsigned N, unsigned S>
bool inRange(MCInst const &MCI, size_t Index) {
return isShiftedUInt<N, S>(minConstant(MCI, Index));
}
template <unsigned N, unsigned S>
bool inSRange(MCInst const &MCI, size_t Index) {
return isShiftedInt<N, S>(minConstant(MCI, Index));
}
template <unsigned N> bool inRange(MCInst const &MCI, size_t Index) {
return isUInt<N>(minConstant(MCI, Index));
}
// Return the instruction at Index
MCInst const &instruction(MCInst const &MCB, size_t Index);
bool isAccumulator(MCInstrInfo const &MCII, MCInst const &MCI);
// Returns whether this MCInst is a wellformed bundle
bool isBundle(MCInst const &MCI);
// Return whether the insn is an actual insn.
bool isCanon(MCInstrInfo const &MCII, MCInst const &MCI);
bool isCofMax1(MCInstrInfo const &MCII, MCInst const &MCI);
bool isCompound(MCInstrInfo const &MCII, MCInst const &MCI);
// Return whether the instruction needs to be constant extended.
bool isConstExtended(MCInstrInfo const &MCII, MCInst const &MCI);
bool isCVINew(MCInstrInfo const &MCII, MCInst const &MCI);
// Is this double register suitable for use in a duplex subinst
bool isDblRegForSubInst(unsigned Reg);
// Is this a duplex instruction
bool isDuplex(MCInstrInfo const &MCII, MCInst const &MCI);
// Can these instructions be duplexed
bool isDuplexPair(MCInst const &MIa, MCInst const &MIb);
// Can these duplex classes be combine in to a duplex instruction
bool isDuplexPairMatch(unsigned Ga, unsigned Gb);
// Return true if the insn may be extended based on the operand value.
bool isExtendable(MCInstrInfo const &MCII, MCInst const &MCI);
// Return whether the instruction must be always extended.
bool isExtended(MCInstrInfo const &MCII, MCInst const &MCI);
/// Return whether it is a floating-point insn.
bool isFloat(MCInstrInfo const &MCII, MCInst const &MCI);
// Returns whether this instruction is an immediate extender
bool isImmext(MCInst const &MCI);
// Returns whether this bundle is an endloop0
bool isInnerLoop(MCInst const &MCI);
// Is this an integer register
bool isIntReg(unsigned Reg);
// Is this register suitable for use in a duplex subinst
bool isIntRegForSubInst(unsigned Reg);
bool isMemReorderDisabled(MCInst const &MCI);
bool isMemStoreReorderEnabled(MCInst const &MCI);
// Return whether the insn is a new-value consumer.
bool isNewValue(MCInstrInfo const &MCII, MCInst const &MCI);
bool isOpExtendable(MCInstrInfo const &MCII, MCInst const &MCI, unsigned short);
// Can these two instructions be duplexed
bool isOrderedDuplexPair(MCInstrInfo const &MCII, MCInst const &MIa,
bool ExtendedA, MCInst const &MIb, bool ExtendedB,
bool bisReversable, MCSubtargetInfo const &STI);
// Returns whether this bundle is an endloop1
bool isOuterLoop(MCInst const &MCI);
// Return whether this instruction is predicated
bool isPredicated(MCInstrInfo const &MCII, MCInst const &MCI);
bool isPredicateLate(MCInstrInfo const &MCII, MCInst const &MCI);
bool isPredicatedNew(MCInstrInfo const &MCII, MCInst const &MCI);
// Return whether the predicate sense is true
bool isPredicatedTrue(MCInstrInfo const &MCII, MCInst const &MCI);
// Is this a predicate register
bool isPredReg(unsigned Reg);
// Return whether the insn is a prefix.
bool isPrefix(MCInstrInfo const &MCII, MCInst const &MCI);
// Return whether the insn is solo, i.e., cannot be in a packet.
bool isSolo(MCInstrInfo const &MCII, MCInst const &MCI);
/// Return whether the insn can be packaged only with A and X-type insns.
bool isSoloAX(MCInstrInfo const &MCII, MCInst const &MCI);
/// Return whether the insn can be packaged only with an A-type insn in slot #1.
bool isSoloAin1(MCInstrInfo const &MCII, MCInst const &MCI);
bool isSubInstruction(MCInst const &MCI);
bool isVector(MCInstrInfo const &MCII, MCInst const &MCI);
bool mustExtend(MCExpr const &Expr);
bool mustNotExtend(MCExpr const &Expr);
// Pad the bundle with nops to satisfy endloop requirements
void padEndloop(MCInst &MCI, MCContext &Context);
bool prefersSlot3(MCInstrInfo const &MCII, MCInst const &MCI);
// Replace the instructions inside MCB, represented by Candidate
void replaceDuplex(MCContext &Context, MCInst &MCI, DuplexCandidate Candidate);
bool s27_2_reloc(MCExpr const &Expr);
// Marks a bundle as endloop0
void setInnerLoop(MCInst &MCI);
void setMemReorderDisabled(MCInst &MCI);
void setMemStoreReorderEnabled(MCInst &MCI);
void setMustExtend(MCExpr const &Expr, bool Val = true);
void setMustNotExtend(MCExpr const &Expr, bool Val = true);
void setS27_2_reloc(MCExpr const &Expr, bool Val = true);
// Marks a bundle as endloop1
void setOuterLoop(MCInst &MCI);
// Would duplexing this instruction create a requirement to extend
bool subInstWouldBeExtended(MCInst const &potentialDuplex);
unsigned SubregisterBit(unsigned Consumer, unsigned Producer,
unsigned Producer2);
// Attempt to find and replace compound pairs
void tryCompound(MCInstrInfo const &MCII, MCSubtargetInfo const &STI,
MCContext &Context, MCInst &MCI);
} // end namespace HexagonMCInstrInfo
} // end namespace llvm
#endif // LLVM_LIB_TARGET_HEXAGON_MCTARGETDESC_HEXAGONMCINSTRINFO_H