lib/CodeGen/TargetSchedule.cpp - llvm - Git at Google

 //===-- llvm/Target/TargetSchedule.cpp - Sched Machine Model ----*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements a wrapper around MCSchedModel that allows the interface
 // to benefit from information currently only available in TargetInstrInfo.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/CodeGen/TargetSchedule.h"
 #include "llvm/Support/CommandLine.h"
 #include "llvm/Support/raw_ostream.h"
 #include "llvm/Target/TargetInstrInfo.h"
 #include "llvm/Target/TargetMachine.h"
 #include "llvm/Target/TargetRegisterInfo.h"
 #include "llvm/Target/TargetSubtargetInfo.h"

 using namespace llvm;

 static cl::opt<bool> EnableSchedModel("schedmodel", cl::Hidden, cl::init(true),
   cl::desc("Use TargetSchedModel for latency lookup"));

 static cl::opt<bool> EnableSchedItins("scheditins", cl::Hidden, cl::init(true),
   cl::desc("Use InstrItineraryData for latency lookup"));

 bool TargetSchedModel::hasInstrSchedModel() const {
   return EnableSchedModel && SchedModel.hasInstrSchedModel();
 }

 bool TargetSchedModel::hasInstrItineraries() const {
   return EnableSchedItins && !InstrItins.isEmpty();
 }

 static unsigned gcd(unsigned Dividend, unsigned Divisor) {
   // Dividend and Divisor will be naturally swapped as needed.
   while(Divisor) {
     unsigned Rem = Dividend % Divisor;
     Dividend = Divisor;
     Divisor = Rem;
   };
   return Dividend;
 }
 static unsigned lcm(unsigned A, unsigned B) {
   unsigned LCM = (uint64_t(A) * B) / gcd(A, B);
   assert((LCM >= A && LCM >= B) && "LCM overflow");
   return LCM;
 }

 void TargetSchedModel::init(const MCSchedModel &sm,
                             const TargetSubtargetInfo *sti,
                             const TargetInstrInfo *tii) {
   SchedModel = sm;
   STI = sti;
   TII = tii;
   STI->initInstrItins(InstrItins);

   unsigned NumRes = SchedModel.getNumProcResourceKinds();
   ResourceFactors.resize(NumRes);
   ResourceLCM = SchedModel.IssueWidth;
   for (unsigned Idx = 0; Idx < NumRes; ++Idx) {
     unsigned NumUnits = SchedModel.getProcResource(Idx)->NumUnits;
     if (NumUnits > 0)
       ResourceLCM = lcm(ResourceLCM, NumUnits);
   }
   MicroOpFactor = ResourceLCM / SchedModel.IssueWidth;
   for (unsigned Idx = 0; Idx < NumRes; ++Idx) {
     unsigned NumUnits = SchedModel.getProcResource(Idx)->NumUnits;
     ResourceFactors[Idx] = NumUnits ? (ResourceLCM / NumUnits) : 0;
   }
 }

 unsigned TargetSchedModel::getNumMicroOps(const MachineInstr *MI,
                                           const MCSchedClassDesc *SC) const {
   if (hasInstrItineraries()) {
     int UOps = InstrItins.getNumMicroOps(MI->getDesc().getSchedClass());
     return (UOps >= 0) ? UOps : TII->getNumMicroOps(&InstrItins, MI);
   }
   if (hasInstrSchedModel()) {
     if (!SC)
       SC = resolveSchedClass(MI);
     if (SC->isValid())
       return SC->NumMicroOps;
   }
   return MI->isTransient() ? 0 : 1;
 }

 // The machine model may explicitly specify an invalid latency, which
 // effectively means infinite latency. Since users of the TargetSchedule API
 // don't know how to handle this, we convert it to a very large latency that is
 // easy to distinguish when debugging the DAG but won't induce overflow.
 static unsigned convertLatency(int Cycles) {
   return Cycles >= 0 ? Cycles : 1000;
 }

 /// If we can determine the operand latency from the def only, without machine
 /// model or itinerary lookup, do so. Otherwise return -1.
 int TargetSchedModel::getDefLatency(const MachineInstr *DefMI,
                                     bool FindMin) const {

   // Return a latency based on the itinerary properties and defining instruction
   // if possible. Some common subtargets don't require per-operand latency,
   // especially for minimum latencies.
   if (FindMin) {
     // If MinLatency is invalid, then use the itinerary for MinLatency. If no
     // itinerary exists either, then use single cycle latency.
     if (SchedModel.MinLatency < 0 && !hasInstrItineraries()) {
       return 1;
     }
     return SchedModel.MinLatency;
   }
   else if (!hasInstrSchedModel() && !hasInstrItineraries()) {
     return TII->defaultDefLatency(&SchedModel, DefMI);
   }
   // ...operand lookup required
   return -1;
 }

 /// Return the MCSchedClassDesc for this instruction. Some SchedClasses require
 /// evaluation of predicates that depend on instruction operands or flags.
 const MCSchedClassDesc *TargetSchedModel::
 resolveSchedClass(const MachineInstr *MI) const {

   // Get the definition's scheduling class descriptor from this machine model.
   unsigned SchedClass = MI->getDesc().getSchedClass();
   const MCSchedClassDesc *SCDesc = SchedModel.getSchedClassDesc(SchedClass);
   if (!SCDesc->isValid())
     return SCDesc;

 #ifndef NDEBUG
   unsigned NIter = 0;
 #endif
   while (SCDesc->isVariant()) {
     assert(++NIter < 6 && "Variants are nested deeper than the magic number");

     SchedClass = STI->resolveSchedClass(SchedClass, MI, this);
     SCDesc = SchedModel.getSchedClassDesc(SchedClass);
   }
   return SCDesc;
 }

 /// Find the def index of this operand. This index maps to the machine model and
 /// is independent of use operands. Def operands may be reordered with uses or
 /// merged with uses without affecting the def index (e.g. before/after
 /// regalloc). However, an instruction's def operands must never be reordered
 /// with respect to each other.
 static unsigned findDefIdx(const MachineInstr *MI, unsigned DefOperIdx) {
   unsigned DefIdx = 0;
   for (unsigned i = 0; i != DefOperIdx; ++i) {
     const MachineOperand &MO = MI->getOperand(i);
     if (MO.isReg() && MO.isDef())
       ++DefIdx;
   }
   return DefIdx;
 }

 /// Find the use index of this operand. This is independent of the instruction's
 /// def operands.
 ///
 /// Note that uses are not determined by the operand's isUse property, which
 /// is simply the inverse of isDef. Here we consider any readsReg operand to be
 /// a "use". The machine model allows an operand to be both a Def and Use.
 static unsigned findUseIdx(const MachineInstr *MI, unsigned UseOperIdx) {
   unsigned UseIdx = 0;
   for (unsigned i = 0; i != UseOperIdx; ++i) {
     const MachineOperand &MO = MI->getOperand(i);
     if (MO.isReg() && MO.readsReg())
       ++UseIdx;
   }
   return UseIdx;
 }

 // Top-level API for clients that know the operand indices.
 unsigned TargetSchedModel::computeOperandLatency(
   const MachineInstr *DefMI, unsigned DefOperIdx,
   const MachineInstr *UseMI, unsigned UseOperIdx,
   bool FindMin) const {

   int DefLatency = getDefLatency(DefMI, FindMin);
   if (DefLatency >= 0)
     return DefLatency;

   if (hasInstrItineraries()) {
     int OperLatency = 0;
     if (UseMI) {
       OperLatency =
         TII->getOperandLatency(&InstrItins, DefMI, DefOperIdx, UseMI, UseOperIdx);
     }
     else {
       unsigned DefClass = DefMI->getDesc().getSchedClass();
       OperLatency = InstrItins.getOperandCycle(DefClass, DefOperIdx);
     }
     if (OperLatency >= 0)
       return OperLatency;

     // No operand latency was found.
     unsigned InstrLatency = TII->getInstrLatency(&InstrItins, DefMI);

     // Expected latency is the max of the stage latency and itinerary props.
     // Rather than directly querying InstrItins stage latency, we call a TII
     // hook to allow subtargets to specialize latency. This hook is only
     // applicable to the InstrItins model. InstrSchedModel should model all
     // special cases without TII hooks.
     if (!FindMin)
       InstrLatency = std::max(InstrLatency,
                               TII->defaultDefLatency(&SchedModel, DefMI));
     return InstrLatency;
   }
   assert(!FindMin && hasInstrSchedModel() &&
          "Expected a SchedModel for this cpu");
   const MCSchedClassDesc *SCDesc = resolveSchedClass(DefMI);
   unsigned DefIdx = findDefIdx(DefMI, DefOperIdx);
   if (DefIdx < SCDesc->NumWriteLatencyEntries) {
     // Lookup the definition's write latency in SubtargetInfo.
     const MCWriteLatencyEntry *WLEntry =
       STI->getWriteLatencyEntry(SCDesc, DefIdx);
     unsigned WriteID = WLEntry->WriteResourceID;
     unsigned Latency = convertLatency(WLEntry->Cycles);
     if (!UseMI)
       return Latency;

     // Lookup the use's latency adjustment in SubtargetInfo.
     const MCSchedClassDesc *UseDesc = resolveSchedClass(UseMI);
     if (UseDesc->NumReadAdvanceEntries == 0)
       return Latency;
     unsigned UseIdx = findUseIdx(UseMI, UseOperIdx);
     return Latency - STI->getReadAdvanceCycles(UseDesc, UseIdx, WriteID);
   }
   // If DefIdx does not exist in the model (e.g. implicit defs), then return
   // unit latency (defaultDefLatency may be too conservative).
 #ifndef NDEBUG
   if (SCDesc->isValid() && !DefMI->getOperand(DefOperIdx).isImplicit()
       && !DefMI->getDesc().OpInfo[DefOperIdx].isOptionalDef()) {
     std::string Err;
     raw_string_ostream ss(Err);
     ss << "DefIdx " << DefIdx << " exceeds machine model writes for "
        << *DefMI;
     report_fatal_error(ss.str());
   }
 #endif
   // FIXME: Automatically giving all implicit defs defaultDefLatency is
   // undesirable. We should only do it for defs that are known to the MC
   // desc like flags. Truly implicit defs should get 1 cycle latency.
   return DefMI->isTransient() ? 0 : TII->defaultDefLatency(&SchedModel, DefMI);
 }

 unsigned TargetSchedModel::computeInstrLatency(const MachineInstr *MI) const {
   // For the itinerary model, fall back to the old subtarget hook.
   // Allow subtargets to compute Bundle latencies outside the machine model.
   if (hasInstrItineraries() || MI->isBundle())
     return TII->getInstrLatency(&InstrItins, MI);

   if (hasInstrSchedModel()) {
     const MCSchedClassDesc *SCDesc = resolveSchedClass(MI);
     if (SCDesc->isValid()) {
       unsigned Latency = 0;
       for (unsigned DefIdx = 0, DefEnd = SCDesc->NumWriteLatencyEntries;
            DefIdx != DefEnd; ++DefIdx) {
         // Lookup the definition's write latency in SubtargetInfo.
         const MCWriteLatencyEntry *WLEntry =
           STI->getWriteLatencyEntry(SCDesc, DefIdx);
         Latency = std::max(Latency, convertLatency(WLEntry->Cycles));
       }
       return Latency;
     }
   }
   return TII->defaultDefLatency(&SchedModel, MI);
 }

 unsigned TargetSchedModel::
 computeOutputLatency(const MachineInstr *DefMI, unsigned DefOperIdx,
                      const MachineInstr *DepMI) const {
   // MinLatency == -1 is for in-order processors that always have unit
   // MinLatency. MinLatency > 0 is for in-order processors with varying min
   // latencies, but since this is not a RAW dep, we always use unit latency.
   if (SchedModel.MinLatency != 0)
     return 1;

   // MinLatency == 0 indicates an out-of-order processor that can dispatch
   // WAW dependencies in the same cycle.

   // Treat predication as a data dependency for out-of-order cpus. In-order
   // cpus do not need to treat predicated writes specially.
   //
   // TODO: The following hack exists because predication passes do not
   // correctly append imp-use operands, and readsReg() strangely returns false
   // for predicated defs.
   unsigned Reg = DefMI->getOperand(DefOperIdx).getReg();
   const MachineFunction &MF = *DefMI->getParent()->getParent();
   const TargetRegisterInfo *TRI = MF.getTarget().getRegisterInfo();
   if (!DepMI->readsRegister(Reg, TRI) && TII->isPredicated(DepMI))
     return computeInstrLatency(DefMI);

   // If we have a per operand scheduling model, check if this def is writing
   // an unbuffered resource. If so, it treated like an in-order cpu.
   if (hasInstrSchedModel()) {
     const MCSchedClassDesc *SCDesc = resolveSchedClass(DefMI);
     if (SCDesc->isValid()) {
       for (const MCWriteProcResEntry *PRI = STI->getWriteProcResBegin(SCDesc),
              *PRE = STI->getWriteProcResEnd(SCDesc); PRI != PRE; ++PRI) {
         if (!SchedModel.getProcResource(PRI->ProcResourceIdx)->IsBuffered)
           return 1;
       }
     }
   }
   return 0;
 }
	//===-- llvm/Target/TargetSchedule.cpp - Sched Machine Model ----- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements a wrapper around MCSchedModel that allows the interface
	// to benefit from information currently only available in TargetInstrInfo.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/CodeGen/TargetSchedule.h"
	#include "llvm/Support/CommandLine.h"
	#include "llvm/Support/raw_ostream.h"
	#include "llvm/Target/TargetInstrInfo.h"
	#include "llvm/Target/TargetMachine.h"
	#include "llvm/Target/TargetRegisterInfo.h"
	#include "llvm/Target/TargetSubtargetInfo.h"

	using namespace llvm;

	static cl::opt<bool> EnableSchedModel("schedmodel", cl::Hidden, cl::init(true),
	cl::desc("Use TargetSchedModel for latency lookup"));

	static cl::opt<bool> EnableSchedItins("scheditins", cl::Hidden, cl::init(true),
	cl::desc("Use InstrItineraryData for latency lookup"));

	bool TargetSchedModel::hasInstrSchedModel() const {
	return EnableSchedModel && SchedModel.hasInstrSchedModel();
	}

	bool TargetSchedModel::hasInstrItineraries() const {
	return EnableSchedItins && !InstrItins.isEmpty();
	}

	static unsigned gcd(unsigned Dividend, unsigned Divisor) {
	// Dividend and Divisor will be naturally swapped as needed.
	while(Divisor) {
	unsigned Rem = Dividend % Divisor;
	Dividend = Divisor;
	Divisor = Rem;
	};
	return Dividend;
	}
	static unsigned lcm(unsigned A, unsigned B) {
	unsigned LCM = (uint64_t(A) * B) / gcd(A, B);
	assert((LCM >= A && LCM >= B) && "LCM overflow");
	return LCM;
	}

	void TargetSchedModel::init(const MCSchedModel &sm,
	const TargetSubtargetInfo *sti,
	const TargetInstrInfo *tii) {
	SchedModel = sm;
	STI = sti;
	TII = tii;
	STI->initInstrItins(InstrItins);

	unsigned NumRes = SchedModel.getNumProcResourceKinds();
	ResourceFactors.resize(NumRes);
	ResourceLCM = SchedModel.IssueWidth;
	for (unsigned Idx = 0; Idx < NumRes; ++Idx) {
	unsigned NumUnits = SchedModel.getProcResource(Idx)->NumUnits;
	if (NumUnits > 0)
	ResourceLCM = lcm(ResourceLCM, NumUnits);
	}
	MicroOpFactor = ResourceLCM / SchedModel.IssueWidth;
	for (unsigned Idx = 0; Idx < NumRes; ++Idx) {
	unsigned NumUnits = SchedModel.getProcResource(Idx)->NumUnits;
	ResourceFactors[Idx] = NumUnits ? (ResourceLCM / NumUnits) : 0;
	}
	}

	unsigned TargetSchedModel::getNumMicroOps(const MachineInstr *MI,
	const MCSchedClassDesc *SC) const {
	if (hasInstrItineraries()) {
	int UOps = InstrItins.getNumMicroOps(MI->getDesc().getSchedClass());
	return (UOps >= 0) ? UOps : TII->getNumMicroOps(&InstrItins, MI);
	}
	if (hasInstrSchedModel()) {
	if (!SC)
	SC = resolveSchedClass(MI);
	if (SC->isValid())
	return SC->NumMicroOps;
	}
	return MI->isTransient() ? 0 : 1;
	}

	// The machine model may explicitly specify an invalid latency, which
	// effectively means infinite latency. Since users of the TargetSchedule API
	// don't know how to handle this, we convert it to a very large latency that is
	// easy to distinguish when debugging the DAG but won't induce overflow.
	static unsigned convertLatency(int Cycles) {
	return Cycles >= 0 ? Cycles : 1000;
	}

	/// If we can determine the operand latency from the def only, without machine
	/// model or itinerary lookup, do so. Otherwise return -1.
	int TargetSchedModel::getDefLatency(const MachineInstr *DefMI,
	bool FindMin) const {

	// Return a latency based on the itinerary properties and defining instruction
	// if possible. Some common subtargets don't require per-operand latency,
	// especially for minimum latencies.
	if (FindMin) {
	// If MinLatency is invalid, then use the itinerary for MinLatency. If no
	// itinerary exists either, then use single cycle latency.
	if (SchedModel.MinLatency < 0 && !hasInstrItineraries()) {
	return 1;
	}
	return SchedModel.MinLatency;
	}
	else if (!hasInstrSchedModel() && !hasInstrItineraries()) {
	return TII->defaultDefLatency(&SchedModel, DefMI);
	}
	// ...operand lookup required
	return -1;
	}

	/// Return the MCSchedClassDesc for this instruction. Some SchedClasses require
	/// evaluation of predicates that depend on instruction operands or flags.
	const MCSchedClassDesc *TargetSchedModel::
	resolveSchedClass(const MachineInstr *MI) const {

	// Get the definition's scheduling class descriptor from this machine model.
	unsigned SchedClass = MI->getDesc().getSchedClass();
	const MCSchedClassDesc *SCDesc = SchedModel.getSchedClassDesc(SchedClass);
	if (!SCDesc->isValid())
	return SCDesc;

	#ifndef NDEBUG
	unsigned NIter = 0;
	#endif
	while (SCDesc->isVariant()) {
	assert(++NIter < 6 && "Variants are nested deeper than the magic number");

	SchedClass = STI->resolveSchedClass(SchedClass, MI, this);
	SCDesc = SchedModel.getSchedClassDesc(SchedClass);
	}
	return SCDesc;
	}

	/// Find the def index of this operand. This index maps to the machine model and
	/// is independent of use operands. Def operands may be reordered with uses or
	/// merged with uses without affecting the def index (e.g. before/after
	/// regalloc). However, an instruction's def operands must never be reordered
	/// with respect to each other.
	static unsigned findDefIdx(const MachineInstr *MI, unsigned DefOperIdx) {
	unsigned DefIdx = 0;
	for (unsigned i = 0; i != DefOperIdx; ++i) {
	const MachineOperand &MO = MI->getOperand(i);
	if (MO.isReg() && MO.isDef())
	++DefIdx;
	}
	return DefIdx;
	}

	/// Find the use index of this operand. This is independent of the instruction's
	/// def operands.
	///
	/// Note that uses are not determined by the operand's isUse property, which
	/// is simply the inverse of isDef. Here we consider any readsReg operand to be
	/// a "use". The machine model allows an operand to be both a Def and Use.
	static unsigned findUseIdx(const MachineInstr *MI, unsigned UseOperIdx) {
	unsigned UseIdx = 0;
	for (unsigned i = 0; i != UseOperIdx; ++i) {
	const MachineOperand &MO = MI->getOperand(i);
	if (MO.isReg() && MO.readsReg())
	++UseIdx;
	}
	return UseIdx;
	}

	// Top-level API for clients that know the operand indices.
	unsigned TargetSchedModel::computeOperandLatency(
	const MachineInstr *DefMI, unsigned DefOperIdx,
	const MachineInstr *UseMI, unsigned UseOperIdx,
	bool FindMin) const {

	int DefLatency = getDefLatency(DefMI, FindMin);
	if (DefLatency >= 0)
	return DefLatency;

	if (hasInstrItineraries()) {
	int OperLatency = 0;
	if (UseMI) {
	OperLatency =
	TII->getOperandLatency(&InstrItins, DefMI, DefOperIdx, UseMI, UseOperIdx);
	}
	else {
	unsigned DefClass = DefMI->getDesc().getSchedClass();
	OperLatency = InstrItins.getOperandCycle(DefClass, DefOperIdx);
	}
	if (OperLatency >= 0)
	return OperLatency;

	// No operand latency was found.
	unsigned InstrLatency = TII->getInstrLatency(&InstrItins, DefMI);

	// Expected latency is the max of the stage latency and itinerary props.
	// Rather than directly querying InstrItins stage latency, we call a TII
	// hook to allow subtargets to specialize latency. This hook is only
	// applicable to the InstrItins model. InstrSchedModel should model all
	// special cases without TII hooks.
	if (!FindMin)
	InstrLatency = std::max(InstrLatency,
	TII->defaultDefLatency(&SchedModel, DefMI));
	return InstrLatency;
	}
	assert(!FindMin && hasInstrSchedModel() &&
	"Expected a SchedModel for this cpu");
	const MCSchedClassDesc *SCDesc = resolveSchedClass(DefMI);
	unsigned DefIdx = findDefIdx(DefMI, DefOperIdx);
	if (DefIdx < SCDesc->NumWriteLatencyEntries) {
	// Lookup the definition's write latency in SubtargetInfo.
	const MCWriteLatencyEntry *WLEntry =
	STI->getWriteLatencyEntry(SCDesc, DefIdx);
	unsigned WriteID = WLEntry->WriteResourceID;
	unsigned Latency = convertLatency(WLEntry->Cycles);
	if (!UseMI)
	return Latency;

	// Lookup the use's latency adjustment in SubtargetInfo.
	const MCSchedClassDesc *UseDesc = resolveSchedClass(UseMI);
	if (UseDesc->NumReadAdvanceEntries == 0)
	return Latency;
	unsigned UseIdx = findUseIdx(UseMI, UseOperIdx);
	return Latency - STI->getReadAdvanceCycles(UseDesc, UseIdx, WriteID);
	}
	// If DefIdx does not exist in the model (e.g. implicit defs), then return
	// unit latency (defaultDefLatency may be too conservative).
	#ifndef NDEBUG
	if (SCDesc->isValid() && !DefMI->getOperand(DefOperIdx).isImplicit()
	&& !DefMI->getDesc().OpInfo[DefOperIdx].isOptionalDef()) {
	std::string Err;
	raw_string_ostream ss(Err);
	ss << "DefIdx " << DefIdx << " exceeds machine model writes for "
	<< *DefMI;
	report_fatal_error(ss.str());
	}
	#endif
	// FIXME: Automatically giving all implicit defs defaultDefLatency is
	// undesirable. We should only do it for defs that are known to the MC
	// desc like flags. Truly implicit defs should get 1 cycle latency.
	return DefMI->isTransient() ? 0 : TII->defaultDefLatency(&SchedModel, DefMI);
	}

	unsigned TargetSchedModel::computeInstrLatency(const MachineInstr *MI) const {
	// For the itinerary model, fall back to the old subtarget hook.
	// Allow subtargets to compute Bundle latencies outside the machine model.
	if (hasInstrItineraries() \|\| MI->isBundle())
	return TII->getInstrLatency(&InstrItins, MI);

	if (hasInstrSchedModel()) {
	const MCSchedClassDesc *SCDesc = resolveSchedClass(MI);
	if (SCDesc->isValid()) {
	unsigned Latency = 0;
	for (unsigned DefIdx = 0, DefEnd = SCDesc->NumWriteLatencyEntries;
	DefIdx != DefEnd; ++DefIdx) {
	// Lookup the definition's write latency in SubtargetInfo.
	const MCWriteLatencyEntry *WLEntry =
	STI->getWriteLatencyEntry(SCDesc, DefIdx);
	Latency = std::max(Latency, convertLatency(WLEntry->Cycles));
	}
	return Latency;
	}
	}
	return TII->defaultDefLatency(&SchedModel, MI);
	}

	unsigned TargetSchedModel::
	computeOutputLatency(const MachineInstr *DefMI, unsigned DefOperIdx,
	const MachineInstr *DepMI) const {
	// MinLatency == -1 is for in-order processors that always have unit
	// MinLatency. MinLatency > 0 is for in-order processors with varying min
	// latencies, but since this is not a RAW dep, we always use unit latency.
	if (SchedModel.MinLatency != 0)
	return 1;

	// MinLatency == 0 indicates an out-of-order processor that can dispatch
	// WAW dependencies in the same cycle.

	// Treat predication as a data dependency for out-of-order cpus. In-order
	// cpus do not need to treat predicated writes specially.
	//
	// TODO: The following hack exists because predication passes do not
	// correctly append imp-use operands, and readsReg() strangely returns false
	// for predicated defs.
	unsigned Reg = DefMI->getOperand(DefOperIdx).getReg();
	const MachineFunction &MF = *DefMI->getParent()->getParent();
	const TargetRegisterInfo *TRI = MF.getTarget().getRegisterInfo();
	if (!DepMI->readsRegister(Reg, TRI) && TII->isPredicated(DepMI))
	return computeInstrLatency(DefMI);

	// If we have a per operand scheduling model, check if this def is writing
	// an unbuffered resource. If so, it treated like an in-order cpu.
	if (hasInstrSchedModel()) {
	const MCSchedClassDesc *SCDesc = resolveSchedClass(DefMI);
	if (SCDesc->isValid()) {
	for (const MCWriteProcResEntry *PRI = STI->getWriteProcResBegin(SCDesc),
	*PRE = STI->getWriteProcResEnd(SCDesc); PRI != PRE; ++PRI) {
	if (!SchedModel.getProcResource(PRI->ProcResourceIdx)->IsBuffered)
	return 1;
	}
	}
	}
	return 0;
	}