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|
//===-- llvm/Target/TargetInstrInfo.h - Instruction Info --------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file describes the target machine instruction set to the code generator.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_TARGET_TARGETINSTRINFO_H
#define LLVM_TARGET_TARGETINSTRINFO_H
#include "llvm/ADT/SmallSet.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/CodeGen/MachineFunction.h"
#include "llvm/CodeGen/MachineCombinerPattern.h"
#include "llvm/MC/MCInstrInfo.h"
#include "llvm/Target/TargetRegisterInfo.h"
namespace llvm {
class InstrItineraryData;
class LiveVariables;
class MCAsmInfo;
class MachineMemOperand;
class MachineRegisterInfo;
class MDNode;
class MCInst;
struct MCSchedModel;
class MCSymbolRefExpr;
class SDNode;
class ScheduleHazardRecognizer;
class SelectionDAG;
class ScheduleDAG;
class TargetRegisterClass;
class TargetRegisterInfo;
class BranchProbability;
class TargetSubtargetInfo;
class DFAPacketizer;
template<class T> class SmallVectorImpl;
//---------------------------------------------------------------------------
///
/// TargetInstrInfo - Interface to description of machine instruction set
///
class TargetInstrInfo : public MCInstrInfo {
TargetInstrInfo(const TargetInstrInfo &) LLVM_DELETED_FUNCTION;
void operator=(const TargetInstrInfo &) LLVM_DELETED_FUNCTION;
public:
TargetInstrInfo(int CFSetupOpcode = -1, int CFDestroyOpcode = -1)
: CallFrameSetupOpcode(CFSetupOpcode),
CallFrameDestroyOpcode(CFDestroyOpcode) {
}
virtual ~TargetInstrInfo();
/// getRegClass - Givem a machine instruction descriptor, returns the register
/// class constraint for OpNum, or NULL.
const TargetRegisterClass *getRegClass(const MCInstrDesc &TID,
unsigned OpNum,
const TargetRegisterInfo *TRI,
const MachineFunction &MF) const;
/// isTriviallyReMaterializable - Return true if the instruction is trivially
/// rematerializable, meaning it has no side effects and requires no operands
/// that aren't always available.
bool isTriviallyReMaterializable(const MachineInstr *MI,
AliasAnalysis *AA = nullptr) const {
return MI->getOpcode() == TargetOpcode::IMPLICIT_DEF ||
(MI->getDesc().isRematerializable() &&
(isReallyTriviallyReMaterializable(MI, AA) ||
isReallyTriviallyReMaterializableGeneric(MI, AA)));
}
protected:
/// isReallyTriviallyReMaterializable - For instructions with opcodes for
/// which the M_REMATERIALIZABLE flag is set, this hook lets the target
/// specify whether the instruction is actually trivially rematerializable,
/// taking into consideration its operands. This predicate must return false
/// if the instruction has any side effects other than producing a value, or
/// if it requres any address registers that are not always available.
virtual bool isReallyTriviallyReMaterializable(const MachineInstr *MI,
AliasAnalysis *AA) const {
return false;
}
private:
/// isReallyTriviallyReMaterializableGeneric - For instructions with opcodes
/// for which the M_REMATERIALIZABLE flag is set and the target hook
/// isReallyTriviallyReMaterializable returns false, this function does
/// target-independent tests to determine if the instruction is really
/// trivially rematerializable.
bool isReallyTriviallyReMaterializableGeneric(const MachineInstr *MI,
AliasAnalysis *AA) const;
public:
/// getCallFrameSetup/DestroyOpcode - These methods return the opcode of the
/// frame setup/destroy instructions if they exist (-1 otherwise). Some
/// targets use pseudo instructions in order to abstract away the difference
/// between operating with a frame pointer and operating without, through the
/// use of these two instructions.
///
int getCallFrameSetupOpcode() const { return CallFrameSetupOpcode; }
int getCallFrameDestroyOpcode() const { return CallFrameDestroyOpcode; }
/// isCoalescableExtInstr - Return true if the instruction is a "coalescable"
/// extension instruction. That is, it's like a copy where it's legal for the
/// source to overlap the destination. e.g. X86::MOVSX64rr32. If this returns
/// true, then it's expected the pre-extension value is available as a subreg
/// of the result register. This also returns the sub-register index in
/// SubIdx.
virtual bool isCoalescableExtInstr(const MachineInstr &MI,
unsigned &SrcReg, unsigned &DstReg,
unsigned &SubIdx) const {
return false;
}
/// isLoadFromStackSlot - If the specified machine instruction is a direct
/// load from a stack slot, return the virtual or physical register number of
/// the destination along with the FrameIndex of the loaded stack slot. If
/// not, return 0. This predicate must return 0 if the instruction has
/// any side effects other than loading from the stack slot.
virtual unsigned isLoadFromStackSlot(const MachineInstr *MI,
int &FrameIndex) const {
return 0;
}
/// isLoadFromStackSlotPostFE - Check for post-frame ptr elimination
/// stack locations as well. This uses a heuristic so it isn't
/// reliable for correctness.
virtual unsigned isLoadFromStackSlotPostFE(const MachineInstr *MI,
int &FrameIndex) const {
return 0;
}
/// hasLoadFromStackSlot - If the specified machine instruction has
/// a load from a stack slot, return true along with the FrameIndex
/// of the loaded stack slot and the machine mem operand containing
/// the reference. If not, return false. Unlike
/// isLoadFromStackSlot, this returns true for any instructions that
/// loads from the stack. This is just a hint, as some cases may be
/// missed.
virtual bool hasLoadFromStackSlot(const MachineInstr *MI,
const MachineMemOperand *&MMO,
int &FrameIndex) const;
/// isStoreToStackSlot - If the specified machine instruction is a direct
/// store to a stack slot, return the virtual or physical register number of
/// the source reg along with the FrameIndex of the loaded stack slot. If
/// not, return 0. This predicate must return 0 if the instruction has
/// any side effects other than storing to the stack slot.
virtual unsigned isStoreToStackSlot(const MachineInstr *MI,
int &FrameIndex) const {
return 0;
}
/// isStoreToStackSlotPostFE - Check for post-frame ptr elimination
/// stack locations as well. This uses a heuristic so it isn't
/// reliable for correctness.
virtual unsigned isStoreToStackSlotPostFE(const MachineInstr *MI,
int &FrameIndex) const {
return 0;
}
/// hasStoreToStackSlot - If the specified machine instruction has a
/// store to a stack slot, return true along with the FrameIndex of
/// the loaded stack slot and the machine mem operand containing the
/// reference. If not, return false. Unlike isStoreToStackSlot,
/// this returns true for any instructions that stores to the
/// stack. This is just a hint, as some cases may be missed.
virtual bool hasStoreToStackSlot(const MachineInstr *MI,
const MachineMemOperand *&MMO,
int &FrameIndex) const;
/// isStackSlotCopy - Return true if the specified machine instruction
/// is a copy of one stack slot to another and has no other effect.
/// Provide the identity of the two frame indices.
virtual bool isStackSlotCopy(const MachineInstr *MI, int &DestFrameIndex,
int &SrcFrameIndex) const {
return false;
}
/// Compute the size in bytes and offset within a stack slot of a spilled
/// register or subregister.
///
/// \param [out] Size in bytes of the spilled value.
/// \param [out] Offset in bytes within the stack slot.
/// \returns true if both Size and Offset are successfully computed.
///
/// Not all subregisters have computable spill slots. For example,
/// subregisters registers may not be byte-sized, and a pair of discontiguous
/// subregisters has no single offset.
///
/// Targets with nontrivial bigendian implementations may need to override
/// this, particularly to support spilled vector registers.
virtual bool getStackSlotRange(const TargetRegisterClass *RC, unsigned SubIdx,
unsigned &Size, unsigned &Offset,
const TargetMachine *TM) const;
/// isAsCheapAsAMove - Return true if the instruction is as cheap as a move
/// instruction.
///
/// Targets for different archs need to override this, and different
/// micro-architectures can also be finely tuned inside.
virtual bool isAsCheapAsAMove(const MachineInstr *MI) const {
return MI->isAsCheapAsAMove();
}
/// reMaterialize - Re-issue the specified 'original' instruction at the
/// specific location targeting a new destination register.
/// The register in Orig->getOperand(0).getReg() will be substituted by
/// DestReg:SubIdx. Any existing subreg index is preserved or composed with
/// SubIdx.
virtual void reMaterialize(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MI,
unsigned DestReg, unsigned SubIdx,
const MachineInstr *Orig,
const TargetRegisterInfo &TRI) const;
/// duplicate - Create a duplicate of the Orig instruction in MF. This is like
/// MachineFunction::CloneMachineInstr(), but the target may update operands
/// that are required to be unique.
///
/// The instruction must be duplicable as indicated by isNotDuplicable().
virtual MachineInstr *duplicate(MachineInstr *Orig,
MachineFunction &MF) const;
/// convertToThreeAddress - This method must be implemented by targets that
/// set the M_CONVERTIBLE_TO_3_ADDR flag. When this flag is set, the target
/// may be able to convert a two-address instruction into one or more true
/// three-address instructions on demand. This allows the X86 target (for
/// example) to convert ADD and SHL instructions into LEA instructions if they
/// would require register copies due to two-addressness.
///
/// This method returns a null pointer if the transformation cannot be
/// performed, otherwise it returns the last new instruction.
///
virtual MachineInstr *
convertToThreeAddress(MachineFunction::iterator &MFI,
MachineBasicBlock::iterator &MBBI, LiveVariables *LV) const {
return nullptr;
}
/// commuteInstruction - If a target has any instructions that are
/// commutable but require converting to different instructions or making
/// non-trivial changes to commute them, this method can overloaded to do
/// that. The default implementation simply swaps the commutable operands.
/// If NewMI is false, MI is modified in place and returned; otherwise, a
/// new machine instruction is created and returned. Do not call this
/// method for a non-commutable instruction, but there may be some cases
/// where this method fails and returns null.
virtual MachineInstr *commuteInstruction(MachineInstr *MI,
bool NewMI = false) const;
/// findCommutedOpIndices - If specified MI is commutable, return the two
/// operand indices that would swap value. Return false if the instruction
/// is not in a form which this routine understands.
virtual bool findCommutedOpIndices(MachineInstr *MI, unsigned &SrcOpIdx1,
unsigned &SrcOpIdx2) const;
/// A pair composed of a register and a sub-register index.
/// Used to give some type checking when modeling Reg:SubReg.
struct RegSubRegPair {
unsigned Reg;
unsigned SubReg;
RegSubRegPair(unsigned Reg = 0, unsigned SubReg = 0)
: Reg(Reg), SubReg(SubReg) {}
};
/// A pair composed of a pair of a register and a sub-register index,
/// and another sub-register index.
/// Used to give some type checking when modeling Reg:SubReg1, SubReg2.
struct RegSubRegPairAndIdx : RegSubRegPair {
unsigned SubIdx;
RegSubRegPairAndIdx(unsigned Reg = 0, unsigned SubReg = 0,
unsigned SubIdx = 0)
: RegSubRegPair(Reg, SubReg), SubIdx(SubIdx) {}
};
/// Build the equivalent inputs of a REG_SEQUENCE for the given \p MI
/// and \p DefIdx.
/// \p [out] InputRegs of the equivalent REG_SEQUENCE. Each element of
/// the list is modeled as <Reg:SubReg, SubIdx>.
/// E.g., REG_SEQUENCE vreg1:sub1, sub0, vreg2, sub1 would produce
/// two elements:
/// - vreg1:sub1, sub0
/// - vreg2<:0>, sub1
///
/// \returns true if it is possible to build such an input sequence
/// with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isRegSequence() or MI.isRegSequenceLike().
///
/// \note The generic implementation does not provide any support for
/// MI.isRegSequenceLike(). In other words, one has to override
/// getRegSequenceLikeInputs for target specific instructions.
bool
getRegSequenceInputs(const MachineInstr &MI, unsigned DefIdx,
SmallVectorImpl<RegSubRegPairAndIdx> &InputRegs) const;
/// Build the equivalent inputs of a EXTRACT_SUBREG for the given \p MI
/// and \p DefIdx.
/// \p [out] InputReg of the equivalent EXTRACT_SUBREG.
/// E.g., EXTRACT_SUBREG vreg1:sub1, sub0, sub1 would produce:
/// - vreg1:sub1, sub0
///
/// \returns true if it is possible to build such an input sequence
/// with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isExtractSubreg() or MI.isExtractSubregLike().
///
/// \note The generic implementation does not provide any support for
/// MI.isExtractSubregLike(). In other words, one has to override
/// getExtractSubregLikeInputs for target specific instructions.
bool
getExtractSubregInputs(const MachineInstr &MI, unsigned DefIdx,
RegSubRegPairAndIdx &InputReg) const;
/// Build the equivalent inputs of a INSERT_SUBREG for the given \p MI
/// and \p DefIdx.
/// \p [out] BaseReg and \p [out] InsertedReg contain
/// the equivalent inputs of INSERT_SUBREG.
/// E.g., INSERT_SUBREG vreg0:sub0, vreg1:sub1, sub3 would produce:
/// - BaseReg: vreg0:sub0
/// - InsertedReg: vreg1:sub1, sub3
///
/// \returns true if it is possible to build such an input sequence
/// with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isInsertSubreg() or MI.isInsertSubregLike().
///
/// \note The generic implementation does not provide any support for
/// MI.isInsertSubregLike(). In other words, one has to override
/// getInsertSubregLikeInputs for target specific instructions.
bool
getInsertSubregInputs(const MachineInstr &MI, unsigned DefIdx,
RegSubRegPair &BaseReg,
RegSubRegPairAndIdx &InsertedReg) const;
/// produceSameValue - Return true if two machine instructions would produce
/// identical values. By default, this is only true when the two instructions
/// are deemed identical except for defs. If this function is called when the
/// IR is still in SSA form, the caller can pass the MachineRegisterInfo for
/// aggressive checks.
virtual bool produceSameValue(const MachineInstr *MI0,
const MachineInstr *MI1,
const MachineRegisterInfo *MRI = nullptr) const;
/// AnalyzeBranch - Analyze the branching code at the end of MBB, returning
/// true if it cannot be understood (e.g. it's a switch dispatch or isn't
/// implemented for a target). Upon success, this returns false and returns
/// with the following information in various cases:
///
/// 1. If this block ends with no branches (it just falls through to its succ)
/// just return false, leaving TBB/FBB null.
/// 2. If this block ends with only an unconditional branch, it sets TBB to be
/// the destination block.
/// 3. If this block ends with a conditional branch and it falls through to a
/// successor block, it sets TBB to be the branch destination block and a
/// list of operands that evaluate the condition. These operands can be
/// passed to other TargetInstrInfo methods to create new branches.
/// 4. If this block ends with a conditional branch followed by an
/// unconditional branch, it returns the 'true' destination in TBB, the
/// 'false' destination in FBB, and a list of operands that evaluate the
/// condition. These operands can be passed to other TargetInstrInfo
/// methods to create new branches.
///
/// Note that RemoveBranch and InsertBranch must be implemented to support
/// cases where this method returns success.
///
/// If AllowModify is true, then this routine is allowed to modify the basic
/// block (e.g. delete instructions after the unconditional branch).
///
virtual bool AnalyzeBranch(MachineBasicBlock &MBB, MachineBasicBlock *&TBB,
MachineBasicBlock *&FBB,
SmallVectorImpl<MachineOperand> &Cond,
bool AllowModify = false) const {
return true;
}
/// RemoveBranch - Remove the branching code at the end of the specific MBB.
/// This is only invoked in cases where AnalyzeBranch returns success. It
/// returns the number of instructions that were removed.
virtual unsigned RemoveBranch(MachineBasicBlock &MBB) const {
llvm_unreachable("Target didn't implement TargetInstrInfo::RemoveBranch!");
}
/// InsertBranch - Insert branch code into the end of the specified
/// MachineBasicBlock. The operands to this method are the same as those
/// returned by AnalyzeBranch. This is only invoked in cases where
/// AnalyzeBranch returns success. It returns the number of instructions
/// inserted.
///
/// It is also invoked by tail merging to add unconditional branches in
/// cases where AnalyzeBranch doesn't apply because there was no original
/// branch to analyze. At least this much must be implemented, else tail
/// merging needs to be disabled.
virtual unsigned InsertBranch(MachineBasicBlock &MBB, MachineBasicBlock *TBB,
MachineBasicBlock *FBB,
const SmallVectorImpl<MachineOperand> &Cond,
DebugLoc DL) const {
llvm_unreachable("Target didn't implement TargetInstrInfo::InsertBranch!");
}
/// ReplaceTailWithBranchTo - Delete the instruction OldInst and everything
/// after it, replacing it with an unconditional branch to NewDest. This is
/// used by the tail merging pass.
virtual void ReplaceTailWithBranchTo(MachineBasicBlock::iterator Tail,
MachineBasicBlock *NewDest) const;
/// getUnconditionalBranch - Get an instruction that performs an unconditional
/// branch to the given symbol.
virtual void
getUnconditionalBranch(MCInst &MI,
const MCSymbolRefExpr *BranchTarget) const {
llvm_unreachable("Target didn't implement "
"TargetInstrInfo::getUnconditionalBranch!");
}
/// getTrap - Get a machine trap instruction
virtual void getTrap(MCInst &MI) const {
llvm_unreachable("Target didn't implement TargetInstrInfo::getTrap!");
}
/// getJumpInstrTableEntryBound - Get a number of bytes that suffices to hold
/// either the instruction returned by getUnconditionalBranch or the
/// instruction returned by getTrap. This only makes sense because
/// getUnconditionalBranch returns a single, specific instruction. This
/// information is needed by the jumptable construction code, since it must
/// decide how many bytes to use for a jumptable entry so it can generate the
/// right mask.
///
/// Note that if the jumptable instruction requires alignment, then that
/// alignment should be factored into this required bound so that the
/// resulting bound gives the right alignment for the instruction.
virtual unsigned getJumpInstrTableEntryBound() const {
// This method gets called by LLVMTargetMachine always, so it can't fail
// just because there happens to be no implementation for this target.
// Any code that tries to use a jumptable annotation without defining
// getUnconditionalBranch on the appropriate Target will fail anyway, and
// the value returned here won't matter in that case.
return 0;
}
/// isLegalToSplitMBBAt - Return true if it's legal to split the given basic
/// block at the specified instruction (i.e. instruction would be the start
/// of a new basic block).
virtual bool isLegalToSplitMBBAt(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MBBI) const {
return true;
}
/// isProfitableToIfCvt - Return true if it's profitable to predicate
/// instructions with accumulated instruction latency of "NumCycles"
/// of the specified basic block, where the probability of the instructions
/// being executed is given by Probability, and Confidence is a measure
/// of our confidence that it will be properly predicted.
virtual
bool isProfitableToIfCvt(MachineBasicBlock &MBB, unsigned NumCycles,
unsigned ExtraPredCycles,
const BranchProbability &Probability) const {
return false;
}
/// isProfitableToIfCvt - Second variant of isProfitableToIfCvt, this one
/// checks for the case where two basic blocks from true and false path
/// of a if-then-else (diamond) are predicated on mutally exclusive
/// predicates, where the probability of the true path being taken is given
/// by Probability, and Confidence is a measure of our confidence that it
/// will be properly predicted.
virtual bool
isProfitableToIfCvt(MachineBasicBlock &TMBB,
unsigned NumTCycles, unsigned ExtraTCycles,
MachineBasicBlock &FMBB,
unsigned NumFCycles, unsigned ExtraFCycles,
const BranchProbability &Probability) const {
return false;
}
/// isProfitableToDupForIfCvt - Return true if it's profitable for
/// if-converter to duplicate instructions of specified accumulated
/// instruction latencies in the specified MBB to enable if-conversion.
/// The probability of the instructions being executed is given by
/// Probability, and Confidence is a measure of our confidence that it
/// will be properly predicted.
virtual bool
isProfitableToDupForIfCvt(MachineBasicBlock &MBB, unsigned NumCycles,
const BranchProbability &Probability) const {
return false;
}
/// isProfitableToUnpredicate - Return true if it's profitable to unpredicate
/// one side of a 'diamond', i.e. two sides of if-else predicated on mutually
/// exclusive predicates.
/// e.g.
/// subeq r0, r1, #1
/// addne r0, r1, #1
/// =>
/// sub r0, r1, #1
/// addne r0, r1, #1
///
/// This may be profitable is conditional instructions are always executed.
virtual bool isProfitableToUnpredicate(MachineBasicBlock &TMBB,
MachineBasicBlock &FMBB) const {
return false;
}
/// canInsertSelect - Return true if it is possible to insert a select
/// instruction that chooses between TrueReg and FalseReg based on the
/// condition code in Cond.
///
/// When successful, also return the latency in cycles from TrueReg,
/// FalseReg, and Cond to the destination register. In most cases, a select
/// instruction will be 1 cycle, so CondCycles = TrueCycles = FalseCycles = 1
///
/// Some x86 implementations have 2-cycle cmov instructions.
///
/// @param MBB Block where select instruction would be inserted.
/// @param Cond Condition returned by AnalyzeBranch.
/// @param TrueReg Virtual register to select when Cond is true.
/// @param FalseReg Virtual register to select when Cond is false.
/// @param CondCycles Latency from Cond+Branch to select output.
/// @param TrueCycles Latency from TrueReg to select output.
/// @param FalseCycles Latency from FalseReg to select output.
virtual bool canInsertSelect(const MachineBasicBlock &MBB,
const SmallVectorImpl<MachineOperand> &Cond,
unsigned TrueReg, unsigned FalseReg,
int &CondCycles,
int &TrueCycles, int &FalseCycles) const {
return false;
}
/// insertSelect - Insert a select instruction into MBB before I that will
/// copy TrueReg to DstReg when Cond is true, and FalseReg to DstReg when
/// Cond is false.
///
/// This function can only be called after canInsertSelect() returned true.
/// The condition in Cond comes from AnalyzeBranch, and it can be assumed
/// that the same flags or registers required by Cond are available at the
/// insertion point.
///
/// @param MBB Block where select instruction should be inserted.
/// @param I Insertion point.
/// @param DL Source location for debugging.
/// @param DstReg Virtual register to be defined by select instruction.
/// @param Cond Condition as computed by AnalyzeBranch.
/// @param TrueReg Virtual register to copy when Cond is true.
/// @param FalseReg Virtual register to copy when Cons is false.
virtual void insertSelect(MachineBasicBlock &MBB,
MachineBasicBlock::iterator I, DebugLoc DL,
unsigned DstReg,
const SmallVectorImpl<MachineOperand> &Cond,
unsigned TrueReg, unsigned FalseReg) const {
llvm_unreachable("Target didn't implement TargetInstrInfo::insertSelect!");
}
/// analyzeSelect - Analyze the given select instruction, returning true if
/// it cannot be understood. It is assumed that MI->isSelect() is true.
///
/// When successful, return the controlling condition and the operands that
/// determine the true and false result values.
///
/// Result = SELECT Cond, TrueOp, FalseOp
///
/// Some targets can optimize select instructions, for example by predicating
/// the instruction defining one of the operands. Such targets should set
/// Optimizable.
///
/// @param MI Select instruction to analyze.
/// @param Cond Condition controlling the select.
/// @param TrueOp Operand number of the value selected when Cond is true.
/// @param FalseOp Operand number of the value selected when Cond is false.
/// @param Optimizable Returned as true if MI is optimizable.
/// @returns False on success.
virtual bool analyzeSelect(const MachineInstr *MI,
SmallVectorImpl<MachineOperand> &Cond,
unsigned &TrueOp, unsigned &FalseOp,
bool &Optimizable) const {
assert(MI && MI->getDesc().isSelect() && "MI must be a select instruction");
return true;
}
/// optimizeSelect - Given a select instruction that was understood by
/// analyzeSelect and returned Optimizable = true, attempt to optimize MI by
/// merging it with one of its operands. Returns NULL on failure.
///
/// When successful, returns the new select instruction. The client is
/// responsible for deleting MI.
///
/// If both sides of the select can be optimized, PreferFalse is used to pick
/// a side.
///
/// @param MI Optimizable select instruction.
/// @param PreferFalse Try to optimize FalseOp instead of TrueOp.
/// @returns Optimized instruction or NULL.
virtual MachineInstr *optimizeSelect(MachineInstr *MI,
bool PreferFalse = false) const {
// This function must be implemented if Optimizable is ever set.
llvm_unreachable("Target must implement TargetInstrInfo::optimizeSelect!");
}
/// copyPhysReg - Emit instructions to copy a pair of physical registers.
///
/// This function should support copies within any legal register class as
/// well as any cross-class copies created during instruction selection.
///
/// The source and destination registers may overlap, which may require a
/// careful implementation when multiple copy instructions are required for
/// large registers. See for example the ARM target.
virtual void copyPhysReg(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MI, DebugLoc DL,
unsigned DestReg, unsigned SrcReg,
bool KillSrc) const {
llvm_unreachable("Target didn't implement TargetInstrInfo::copyPhysReg!");
}
/// storeRegToStackSlot - Store the specified register of the given register
/// class to the specified stack frame index. The store instruction is to be
/// added to the given machine basic block before the specified machine
/// instruction. If isKill is true, the register operand is the last use and
/// must be marked kill.
virtual void storeRegToStackSlot(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MI,
unsigned SrcReg, bool isKill, int FrameIndex,
const TargetRegisterClass *RC,
const TargetRegisterInfo *TRI) const {
llvm_unreachable("Target didn't implement "
"TargetInstrInfo::storeRegToStackSlot!");
}
/// loadRegFromStackSlot - Load the specified register of the given register
/// class from the specified stack frame index. The load instruction is to be
/// added to the given machine basic block before the specified machine
/// instruction.
virtual void loadRegFromStackSlot(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MI,
unsigned DestReg, int FrameIndex,
const TargetRegisterClass *RC,
const TargetRegisterInfo *TRI) const {
llvm_unreachable("Target didn't implement "
"TargetInstrInfo::loadRegFromStackSlot!");
}
/// expandPostRAPseudo - This function is called for all pseudo instructions
/// that remain after register allocation. Many pseudo instructions are
/// created to help register allocation. This is the place to convert them
/// into real instructions. The target can edit MI in place, or it can insert
/// new instructions and erase MI. The function should return true if
/// anything was changed.
virtual bool expandPostRAPseudo(MachineBasicBlock::iterator MI) const {
return false;
}
/// foldMemoryOperand - Attempt to fold a load or store of the specified stack
/// slot into the specified machine instruction for the specified operand(s).
/// If this is possible, a new instruction is returned with the specified
/// operand folded, otherwise NULL is returned.
/// The new instruction is inserted before MI, and the client is responsible
/// for removing the old instruction.
MachineInstr* foldMemoryOperand(MachineBasicBlock::iterator MI,
const SmallVectorImpl<unsigned> &Ops,
int FrameIndex) const;
/// foldMemoryOperand - Same as the previous version except it allows folding
/// of any load and store from / to any address, not just from a specific
/// stack slot.
MachineInstr* foldMemoryOperand(MachineBasicBlock::iterator MI,
const SmallVectorImpl<unsigned> &Ops,
MachineInstr* LoadMI) const;
/// hasPattern - return true when there is potentially a faster code sequence
/// for an instruction chain ending in \p Root. All potential pattern are
/// returned in the \p Pattern vector. Pattern should be sorted in priority
/// order since the pattern evaluator stops checking as soon as it finds a
/// faster sequence.
/// \param Root - Instruction that could be combined with one of its operands
/// \param Pattern - Vector of possible combination pattern
virtual bool hasPattern(
MachineInstr &Root,
SmallVectorImpl<MachineCombinerPattern::MC_PATTERN> &Pattern) const {
return false;
}
/// genAlternativeCodeSequence - when hasPattern() finds a pattern this
/// function generates the instructions that could replace the original code
/// sequence. The client has to decide whether the actual replacementment is
/// beneficial or not.
/// \param Root - Instruction that could be combined with one of its operands
/// \param P - Combination pattern for Root
/// \param InsInstrs - Vector of new instructions that implement P
/// \param DelInstrs - Old instructions, including Root, that could be replaced
/// by InsInstr
/// \param InstrIdxForVirtReg - map of virtual register to instruction in
/// InsInstr that defines it
virtual void genAlternativeCodeSequence(
MachineInstr &Root, MachineCombinerPattern::MC_PATTERN P,
SmallVectorImpl<MachineInstr *> &InsInstrs,
SmallVectorImpl<MachineInstr *> &DelInstrs,
DenseMap<unsigned, unsigned> &InstrIdxForVirtReg) const {
return;
}
/// useMachineCombiner - return true when a target supports MachineCombiner
virtual bool useMachineCombiner() const { return false; }
protected:
/// foldMemoryOperandImpl - Target-dependent implementation for
/// foldMemoryOperand. Target-independent code in foldMemoryOperand will
/// take care of adding a MachineMemOperand to the newly created instruction.
virtual MachineInstr* foldMemoryOperandImpl(MachineFunction &MF,
MachineInstr* MI,
const SmallVectorImpl<unsigned> &Ops,
int FrameIndex) const {
return nullptr;
}
/// foldMemoryOperandImpl - Target-dependent implementation for
/// foldMemoryOperand. Target-independent code in foldMemoryOperand will
/// take care of adding a MachineMemOperand to the newly created instruction.
virtual MachineInstr* foldMemoryOperandImpl(MachineFunction &MF,
MachineInstr* MI,
const SmallVectorImpl<unsigned> &Ops,
MachineInstr* LoadMI) const {
return nullptr;
}
/// \brief Target-dependent implementation of getRegSequenceInputs.
///
/// \returns true if it is possible to build the equivalent
/// REG_SEQUENCE inputs with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isRegSequenceLike().
///
/// \see TargetInstrInfo::getRegSequenceInputs.
virtual bool getRegSequenceLikeInputs(
const MachineInstr &MI, unsigned DefIdx,
SmallVectorImpl<RegSubRegPairAndIdx> &InputRegs) const {
return false;
}
/// \brief Target-dependent implementation of getExtractSubregInputs.
///
/// \returns true if it is possible to build the equivalent
/// EXTRACT_SUBREG inputs with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isExtractSubregLike().
///
/// \see TargetInstrInfo::getExtractSubregInputs.
virtual bool getExtractSubregLikeInputs(
const MachineInstr &MI, unsigned DefIdx,
RegSubRegPairAndIdx &InputReg) const {
return false;
}
/// \brief Target-dependent implementation of getInsertSubregInputs.
///
/// \returns true if it is possible to build the equivalent
/// INSERT_SUBREG inputs with the pair \p MI, \p DefIdx. False otherwise.
///
/// \pre MI.isInsertSubregLike().
///
/// \see TargetInstrInfo::getInsertSubregInputs.
virtual bool
getInsertSubregLikeInputs(const MachineInstr &MI, unsigned DefIdx,
RegSubRegPair &BaseReg,
RegSubRegPairAndIdx &InsertedReg) const {
return false;
}
public:
/// canFoldMemoryOperand - Returns true for the specified load / store if
/// folding is possible.
virtual
bool canFoldMemoryOperand(const MachineInstr *MI,
const SmallVectorImpl<unsigned> &Ops) const;
/// unfoldMemoryOperand - Separate a single instruction which folded a load or
/// a store or a load and a store into two or more instruction. If this is
/// possible, returns true as well as the new instructions by reference.
virtual bool unfoldMemoryOperand(MachineFunction &MF, MachineInstr *MI,
unsigned Reg, bool UnfoldLoad, bool UnfoldStore,
SmallVectorImpl<MachineInstr*> &NewMIs) const{
return false;
}
virtual bool unfoldMemoryOperand(SelectionDAG &DAG, SDNode *N,
SmallVectorImpl<SDNode*> &NewNodes) const {
return false;
}
/// getOpcodeAfterMemoryUnfold - Returns the opcode of the would be new
/// instruction after load / store are unfolded from an instruction of the
/// specified opcode. It returns zero if the specified unfolding is not
/// possible. If LoadRegIndex is non-null, it is filled in with the operand
/// index of the operand which will hold the register holding the loaded
/// value.
virtual unsigned getOpcodeAfterMemoryUnfold(unsigned Opc,
bool UnfoldLoad, bool UnfoldStore,
unsigned *LoadRegIndex = nullptr) const {
return 0;
}
/// areLoadsFromSameBasePtr - This is used by the pre-regalloc scheduler
/// to determine if two loads are loading from the same base address. It
/// should only return true if the base pointers are the same and the
/// only differences between the two addresses are the offset. It also returns
/// the offsets by reference.
virtual bool areLoadsFromSameBasePtr(SDNode *Load1, SDNode *Load2,
int64_t &Offset1, int64_t &Offset2) const {
return false;
}
/// shouldScheduleLoadsNear - This is a used by the pre-regalloc scheduler to
/// determine (in conjunction with areLoadsFromSameBasePtr) if two loads should
/// be scheduled togther. On some targets if two loads are loading from
/// addresses in the same cache line, it's better if they are scheduled
/// together. This function takes two integers that represent the load offsets
/// from the common base address. It returns true if it decides it's desirable
/// to schedule the two loads together. "NumLoads" is the number of loads that
/// have already been scheduled after Load1.
virtual bool shouldScheduleLoadsNear(SDNode *Load1, SDNode *Load2,
int64_t Offset1, int64_t Offset2,
unsigned NumLoads) const {
return false;
}
/// \brief Get the base register and byte offset of a load/store instr.
virtual bool getLdStBaseRegImmOfs(MachineInstr *LdSt,
unsigned &BaseReg, unsigned &Offset,
const TargetRegisterInfo *TRI) const {
return false;
}
virtual bool enableClusterLoads() const { return false; }
virtual bool shouldClusterLoads(MachineInstr *FirstLdSt,
MachineInstr *SecondLdSt,
unsigned NumLoads) const {
return false;
}
/// \brief Can this target fuse the given instructions if they are scheduled
/// adjacent.
virtual bool shouldScheduleAdjacent(MachineInstr* First,
MachineInstr *Second) const {
return false;
}
/// ReverseBranchCondition - Reverses the branch condition of the specified
/// condition list, returning false on success and true if it cannot be
/// reversed.
virtual
bool ReverseBranchCondition(SmallVectorImpl<MachineOperand> &Cond) const {
return true;
}
/// insertNoop - Insert a noop into the instruction stream at the specified
/// point.
virtual void insertNoop(MachineBasicBlock &MBB,
MachineBasicBlock::iterator MI) const;
/// Return the noop instruction to use for a noop.
virtual void getNoopForMachoTarget(MCInst &NopInst) const;
/// isPredicated - Returns true if the instruction is already predicated.
///
virtual bool isPredicated(const MachineInstr *MI) const {
return false;
}
/// isUnpredicatedTerminator - Returns true if the instruction is a
/// terminator instruction that has not been predicated.
virtual bool isUnpredicatedTerminator(const MachineInstr *MI) const;
/// PredicateInstruction - Convert the instruction into a predicated
/// instruction. It returns true if the operation was successful.
virtual
bool PredicateInstruction(MachineInstr *MI,
const SmallVectorImpl<MachineOperand> &Pred) const;
/// SubsumesPredicate - Returns true if the first specified predicate
/// subsumes the second, e.g. GE subsumes GT.
virtual
bool SubsumesPredicate(const SmallVectorImpl<MachineOperand> &Pred1,
const SmallVectorImpl<MachineOperand> &Pred2) const {
return false;
}
/// DefinesPredicate - If the specified instruction defines any predicate
/// or condition code register(s) used for predication, returns true as well
/// as the definition predicate(s) by reference.
virtual bool DefinesPredicate(MachineInstr *MI,
std::vector<MachineOperand> &Pred) const {
return false;
}
/// isPredicable - Return true if the specified instruction can be predicated.
/// By default, this returns true for every instruction with a
/// PredicateOperand.
virtual bool isPredicable(MachineInstr *MI) const {
return MI->getDesc().isPredicable();
}
/// isSafeToMoveRegClassDefs - Return true if it's safe to move a machine
/// instruction that defines the specified register class.
virtual bool isSafeToMoveRegClassDefs(const TargetRegisterClass *RC) const {
return true;
}
/// isSchedulingBoundary - Test if the given instruction should be
/// considered a scheduling boundary. This primarily includes labels and
/// terminators.
virtual bool isSchedulingBoundary(const MachineInstr *MI,
const MachineBasicBlock *MBB,
const MachineFunction &MF) const;
/// Measure the specified inline asm to determine an approximation of its
/// length.
virtual unsigned getInlineAsmLength(const char *Str,
const MCAsmInfo &MAI) const;
/// CreateTargetHazardRecognizer - Allocate and return a hazard recognizer to
/// use for this target when scheduling the machine instructions before
/// register allocation.
virtual ScheduleHazardRecognizer*
CreateTargetHazardRecognizer(const TargetSubtargetInfo *STI,
const ScheduleDAG *DAG) const;
/// CreateTargetMIHazardRecognizer - Allocate and return a hazard recognizer
/// to use for this target when scheduling the machine instructions before
/// register allocation.
virtual ScheduleHazardRecognizer*
CreateTargetMIHazardRecognizer(const InstrItineraryData*,
const ScheduleDAG *DAG) const;
/// CreateTargetPostRAHazardRecognizer - Allocate and return a hazard
/// recognizer to use for this target when scheduling the machine instructions
/// after register allocation.
virtual ScheduleHazardRecognizer*
CreateTargetPostRAHazardRecognizer(const InstrItineraryData*,
const ScheduleDAG *DAG) const;
/// Provide a global flag for disabling the PreRA hazard recognizer that
/// targets may choose to honor.
bool usePreRAHazardRecognizer() const;
/// analyzeCompare - For a comparison instruction, return the source registers
/// in SrcReg and SrcReg2 if having two register operands, and the value it
/// compares against in CmpValue. Return true if the comparison instruction
/// can be analyzed.
virtual bool analyzeCompare(const MachineInstr *MI,
unsigned &SrcReg, unsigned &SrcReg2,
int &Mask, int &Value) const {
return false;
}
/// optimizeCompareInstr - See if the comparison instruction can be converted
/// into something more efficient. E.g., on ARM most instructions can set the
/// flags register, obviating the need for a separate CMP.
virtual bool optimizeCompareInstr(MachineInstr *CmpInstr,
unsigned SrcReg, unsigned SrcReg2,
int Mask, int Value,
const MachineRegisterInfo *MRI) const {
return false;
}
virtual bool optimizeCondBranch(MachineInstr *MI) const { return false; }
/// optimizeLoadInstr - Try to remove the load by folding it to a register
/// operand at the use. We fold the load instructions if and only if the
/// def and use are in the same BB. We only look at one load and see
/// whether it can be folded into MI. FoldAsLoadDefReg is the virtual register
/// defined by the load we are trying to fold. DefMI returns the machine
/// instruction that defines FoldAsLoadDefReg, and the function returns
/// the machine instruction generated due to folding.
virtual MachineInstr* optimizeLoadInstr(MachineInstr *MI,
const MachineRegisterInfo *MRI,
unsigned &FoldAsLoadDefReg,
MachineInstr *&DefMI) const {
return nullptr;
}
/// FoldImmediate - 'Reg' is known to be defined by a move immediate
/// instruction, try to fold the immediate into the use instruction.
/// If MRI->hasOneNonDBGUse(Reg) is true, and this function returns true,
/// then the caller may assume that DefMI has been erased from its parent
/// block. The caller may assume that it will not be erased by this
/// function otherwise.
virtual bool FoldImmediate(MachineInstr *UseMI, MachineInstr *DefMI,
unsigned Reg, MachineRegisterInfo *MRI) const {
return false;
}
/// getNumMicroOps - Return the number of u-operations the given machine
/// instruction will be decoded to on the target cpu. The itinerary's
/// IssueWidth is the number of microops that can be dispatched each
/// cycle. An instruction with zero microops takes no dispatch resources.
virtual unsigned getNumMicroOps(const InstrItineraryData *ItinData,
const MachineInstr *MI) const;
/// isZeroCost - Return true for pseudo instructions that don't consume any
/// machine resources in their current form. These are common cases that the
/// scheduler should consider free, rather than conservatively handling them
/// as instructions with no itinerary.
bool isZeroCost(unsigned Opcode) const {
return Opcode <= TargetOpcode::COPY;
}
virtual int getOperandLatency(const InstrItineraryData *ItinData,
SDNode *DefNode, unsigned DefIdx,
SDNode *UseNode, unsigned UseIdx) const;
/// getOperandLatency - Compute and return the use operand latency of a given
/// pair of def and use.
/// In most cases, the static scheduling itinerary was enough to determine the
/// operand latency. But it may not be possible for instructions with variable
/// number of defs / uses.
///
/// This is a raw interface to the itinerary that may be directly overriden by
/// a target. Use computeOperandLatency to get the best estimate of latency.
virtual int getOperandLatency(const InstrItineraryData *ItinData,
const MachineInstr *DefMI, unsigned DefIdx,
const MachineInstr *UseMI,
unsigned UseIdx) const;
/// computeOperandLatency - Compute and return the latency of the given data
/// dependent def and use when the operand indices are already known.
unsigned computeOperandLatency(const InstrItineraryData *ItinData,
const MachineInstr *DefMI, unsigned DefIdx,
const MachineInstr *UseMI, unsigned UseIdx)
const;
/// getInstrLatency - Compute the instruction latency of a given instruction.
/// If the instruction has higher cost when predicated, it's returned via
/// PredCost.
virtual unsigned getInstrLatency(const InstrItineraryData *ItinData,
const MachineInstr *MI,
unsigned *PredCost = nullptr) const;
virtual unsigned getPredicationCost(const MachineInstr *MI) const;
virtual int getInstrLatency(const InstrItineraryData *ItinData,
SDNode *Node) const;
/// Return the default expected latency for a def based on it's opcode.
unsigned defaultDefLatency(const MCSchedModel &SchedModel,
const MachineInstr *DefMI) const;
int computeDefOperandLatency(const InstrItineraryData *ItinData,
const MachineInstr *DefMI) const;
/// isHighLatencyDef - Return true if this opcode has high latency to its
/// result.
virtual bool isHighLatencyDef(int opc) const { return false; }
/// hasHighOperandLatency - Compute operand latency between a def of 'Reg'
/// and an use in the current loop, return true if the target considered
/// it 'high'. This is used by optimization passes such as machine LICM to
/// determine whether it makes sense to hoist an instruction out even in
/// high register pressure situation.
virtual
bool hasHighOperandLatency(const InstrItineraryData *ItinData,
const MachineRegisterInfo *MRI,
const MachineInstr *DefMI, unsigned DefIdx,
const MachineInstr *UseMI, unsigned UseIdx) const {
return false;
}
/// hasLowDefLatency - Compute operand latency of a def of 'Reg', return true
/// if the target considered it 'low'.
virtual
bool hasLowDefLatency(const InstrItineraryData *ItinData,
const MachineInstr *DefMI, unsigned DefIdx) const;
/// verifyInstruction - Perform target specific instruction verification.
virtual
bool verifyInstruction(const MachineInstr *MI, StringRef &ErrInfo) const {
return true;
}
/// getExecutionDomain - Return the current execution domain and bit mask of
/// possible domains for instruction.
///
/// Some micro-architectures have multiple execution domains, and multiple
/// opcodes that perform the same operation in different domains. For
/// example, the x86 architecture provides the por, orps, and orpd
/// instructions that all do the same thing. There is a latency penalty if a
/// register is written in one domain and read in another.
///
/// This function returns a pair (domain, mask) containing the execution
/// domain of MI, and a bit mask of possible domains. The setExecutionDomain
/// function can be used to change the opcode to one of the domains in the
/// bit mask. Instructions whose execution domain can't be changed should
/// return a 0 mask.
///
/// The execution domain numbers don't have any special meaning except domain
/// 0 is used for instructions that are not associated with any interesting
/// execution domain.
///
virtual std::pair<uint16_t, uint16_t>
getExecutionDomain(const MachineInstr *MI) const {
return std::make_pair(0, 0);
}
/// setExecutionDomain - Change the opcode of MI to execute in Domain.
///
/// The bit (1 << Domain) must be set in the mask returned from
/// getExecutionDomain(MI).
///
virtual void setExecutionDomain(MachineInstr *MI, unsigned Domain) const {}
/// getPartialRegUpdateClearance - Returns the preferred minimum clearance
/// before an instruction with an unwanted partial register update.
///
/// Some instructions only write part of a register, and implicitly need to
/// read the other parts of the register. This may cause unwanted stalls
/// preventing otherwise unrelated instructions from executing in parallel in
/// an out-of-order CPU.
///
/// For example, the x86 instruction cvtsi2ss writes its result to bits
/// [31:0] of the destination xmm register. Bits [127:32] are unaffected, so
/// the instruction needs to wait for the old value of the register to become
/// available:
///
/// addps %xmm1, %xmm0
/// movaps %xmm0, (%rax)
/// cvtsi2ss %rbx, %xmm0
///
/// In the code above, the cvtsi2ss instruction needs to wait for the addps
/// instruction before it can issue, even though the high bits of %xmm0
/// probably aren't needed.
///
/// This hook returns the preferred clearance before MI, measured in
/// instructions. Other defs of MI's operand OpNum are avoided in the last N
/// instructions before MI. It should only return a positive value for
/// unwanted dependencies. If the old bits of the defined register have
/// useful values, or if MI is determined to otherwise read the dependency,
/// the hook should return 0.
///
/// The unwanted dependency may be handled by:
///
/// 1. Allocating the same register for an MI def and use. That makes the
/// unwanted dependency identical to a required dependency.
///
/// 2. Allocating a register for the def that has no defs in the previous N
/// instructions.
///
/// 3. Calling breakPartialRegDependency() with the same arguments. This
/// allows the target to insert a dependency breaking instruction.
///
virtual unsigned
getPartialRegUpdateClearance(const MachineInstr *MI, unsigned OpNum,
const TargetRegisterInfo *TRI) const {
// The default implementation returns 0 for no partial register dependency.
return 0;
}
/// \brief Return the minimum clearance before an instruction that reads an
/// unused register.
///
/// For example, AVX instructions may copy part of an register operand into
/// the unused high bits of the destination register.
///
/// vcvtsi2sdq %rax, %xmm0<undef>, %xmm14
///
/// In the code above, vcvtsi2sdq copies %xmm0[127:64] into %xmm14 creating a
/// false dependence on any previous write to %xmm0.
///
/// This hook works similarly to getPartialRegUpdateClearance, except that it
/// does not take an operand index. Instead sets \p OpNum to the index of the
/// unused register.
virtual unsigned getUndefRegClearance(const MachineInstr *MI, unsigned &OpNum,
const TargetRegisterInfo *TRI) const {
// The default implementation returns 0 for no undef register dependency.
return 0;
}
/// breakPartialRegDependency - Insert a dependency-breaking instruction
/// before MI to eliminate an unwanted dependency on OpNum.
///
/// If it wasn't possible to avoid a def in the last N instructions before MI
/// (see getPartialRegUpdateClearance), this hook will be called to break the
/// unwanted dependency.
///
/// On x86, an xorps instruction can be used as a dependency breaker:
///
/// addps %xmm1, %xmm0
/// movaps %xmm0, (%rax)
/// xorps %xmm0, %xmm0
/// cvtsi2ss %rbx, %xmm0
///
/// An <imp-kill> operand should be added to MI if an instruction was
/// inserted. This ties the instructions together in the post-ra scheduler.
///
virtual void
breakPartialRegDependency(MachineBasicBlock::iterator MI, unsigned OpNum,
const TargetRegisterInfo *TRI) const {}
/// Create machine specific model for scheduling.
virtual DFAPacketizer *
CreateTargetScheduleState(const TargetSubtargetInfo &) const {
return nullptr;
}
// areMemAccessesTriviallyDisjoint - Sometimes, it is possible for the target
// to tell, even without aliasing information, that two MIs access different
// memory addresses. This function returns true if two MIs access different
// memory addresses, and false otherwise.
virtual bool
areMemAccessesTriviallyDisjoint(MachineInstr *MIa, MachineInstr *MIb,
AliasAnalysis *AA = nullptr) const {
assert(MIa && (MIa->mayLoad() || MIa->mayStore()) &&
"MIa must load from or modify a memory location");
assert(MIb && (MIb->mayLoad() || MIb->mayStore()) &&
"MIb must load from or modify a memory location");
return false;
}
private:
int CallFrameSetupOpcode, CallFrameDestroyOpcode;
};
} // End llvm namespace
#endif
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