SIMachineScheduler.cpp

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//===-- SIMachineScheduler.cpp - SI Scheduler Interface -------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
/// \file
/// SI Machine Scheduler interface
//
//===----------------------------------------------------------------------===//
 
#include "SIMachineScheduler.h"
#include "MCTargetDesc/AMDGPUMCTargetDesc.h"
#include "SIInstrInfo.h"
#include "llvm/CodeGen/LiveIntervals.h"
#include "llvm/CodeGen/MachineRegisterInfo.h"
 
using namespace llvm;
 
#define DEBUG_TYPE "machine-scheduler"
 
// This scheduler implements a different scheduling algorithm than
// GenericScheduler.
//
// There are several specific architecture behaviours that can't be modelled
// for GenericScheduler:
// . When accessing the result of an SGPR load instruction, you have to wait
// for all the SGPR load instructions before your current instruction to
// have finished.
// . When accessing the result of an VGPR load instruction, you have to wait
// for all the VGPR load instructions previous to the VGPR load instruction
// you are interested in to finish.
// . The less the register pressure, the best load latencies are hidden
//
// Moreover some specifities (like the fact a lot of instructions in the shader
// have few dependencies) makes the generic scheduler have some unpredictable
// behaviours. For example when register pressure becomes high, it can either
// manage to prevent register pressure from going too high, or it can
// increase register pressure even more than if it hadn't taken register
// pressure into account.
//
// Also some other bad behaviours are generated, like loading at the beginning
// of the shader a constant in VGPR you won't need until the end of the shader.
//
// The scheduling problem for SI can distinguish three main parts:
// . Hiding high latencies (texture sampling, etc)
// . Hiding low latencies (SGPR constant loading, etc)
// . Keeping register usage low for better latency hiding and general
//   performance
//
// Some other things can also affect performance, but are hard to predict
// (cache usage, the fact the HW can issue several instructions from different
// wavefronts if different types, etc)
//
// This scheduler tries to solve the scheduling problem by dividing it into
// simpler sub-problems. It divides the instructions into blocks, schedules
// locally inside the blocks where it takes care of low latencies, and then
// chooses the order of the blocks by taking care of high latencies.
// Dividing the instructions into blocks helps control keeping register
// usage low.
//
// First the instructions are put into blocks.
//   We want the blocks help control register usage and hide high latencies
//   later. To help control register usage, we typically want all local
//   computations, when for example you create a result that can be consumed
//   right away, to be contained in a block. Block inputs and outputs would
//   typically be important results that are needed in several locations of
//   the shader. Since we do want blocks to help hide high latencies, we want
//   the instructions inside the block to have a minimal set of dependencies
//   on high latencies. It will make it easy to pick blocks to hide specific
//   high latencies.
//   The block creation algorithm is divided into several steps, and several
//   variants can be tried during the scheduling process.
//
// Second the order of the instructions inside the blocks is chosen.
//   At that step we do take into account only register usage and hiding
//   low latency instructions
//
// Third the block order is chosen, there we try to hide high latencies
// and keep register usage low.
//
// After the third step, a pass is done to improve the hiding of low
// latencies.
//
// Actually when talking about 'low latency' or 'high latency' it includes
// both the latency to get the cache (or global mem) data go to the register,
// and the bandwidth limitations.
// Increasing the number of active wavefronts helps hide the former, but it
// doesn't solve the latter, thus why even if wavefront count is high, we have
// to try have as many instructions hiding high latencies as possible.
// The OpenCL doc says for example latency of 400 cycles for a global mem
// access, which is hidden by 10 instructions if the wavefront count is 10.
 
// Some figures taken from AMD docs:
// Both texture and constant L1 caches are 4-way associative with 64 bytes
// lines.
// Constant cache is shared with 4 CUs.
// For texture sampling, the address generation unit receives 4 texture
// addresses per cycle, thus we could expect texture sampling latency to be
// equivalent to 4 instructions in the very best case (a VGPR is 64 work items,
// instructions in a wavefront group are executed every 4 cycles),
// or 16 instructions if the other wavefronts associated to the 3 other VALUs
// of the CU do texture sampling too. (Don't take these figures too seriously,
// as I'm not 100% sure of the computation)
// Data exports should get similar latency.
// For constant loading, the cache is shader with 4 CUs.
// The doc says "a throughput of 16B/cycle for each of the 4 Compute Unit"
// I guess if the other CU don't read the cache, it can go up to 64B/cycle.
// It means a simple s_buffer_load should take one instruction to hide, as
// well as a s_buffer_loadx2 and potentially a s_buffer_loadx8 if on the same
// cache line.
//
// As of today the driver doesn't preload the constants in cache, thus the
// first loads get extra latency. The doc says global memory access can be
// 300-600 cycles. We do not specially take that into account when scheduling
// As we expect the driver to be able to preload the constants soon.
 
// common code //
 
#ifndef NDEBUG
 
static const char *getReasonStr(SIScheduleCandReason Reason) {
  switch (Reason) {
  case NoCand:         return "NOCAND";
  case RegUsage:       return "REGUSAGE";
  case Latency:        return "LATENCY";
  case Successor:      return "SUCCESSOR";
  case Depth:          return "DEPTH";
  case NodeOrder:      return "ORDER";
  }
  llvm_unreachable("Unknown reason!");
}
 
#endif
 
namespace llvm::SISched {
static bool tryLess(int TryVal, int CandVal,
                    SISchedulerCandidate &TryCand,
                    SISchedulerCandidate &Cand,
                    SIScheduleCandReason Reason) {
  if (TryVal < CandVal) {
    TryCand.Reason = Reason;
    return true;
  }
  if (TryVal > CandVal) {
    if (Cand.Reason > Reason)
      Cand.Reason = Reason;
    return true;
  }
  Cand.setRepeat(Reason);
  return false;
}
 
static bool tryGreater(int TryVal, int CandVal,
                       SISchedulerCandidate &TryCand,
                       SISchedulerCandidate &Cand,
                       SIScheduleCandReason Reason) {
  if (TryVal > CandVal) {
    TryCand.Reason = Reason;
    return true;
  }
  if (TryVal < CandVal) {
    if (Cand.Reason > Reason)
      Cand.Reason = Reason;
    return true;
  }
  Cand.setRepeat(Reason);
  return false;
}
} // end namespace llvm::SISched
 
// SIScheduleBlock //
 
void SIScheduleBlock::addUnit(SUnit *SU) {
  NodeNum2Index[SU->NodeNum] = SUnits.size();
  SUnits.push_back(SU);
}
 
#ifndef NDEBUG
void SIScheduleBlock::traceCandidate(const SISchedCandidate &Cand) {
 
  dbgs() << "  SU(" << Cand.SU->NodeNum << ") " << getReasonStr(Cand.Reason);
  dbgs() << '\n';
}
#endif
 
void SIScheduleBlock::tryCandidateTopDown(SISchedCandidate &Cand,
                                          SISchedCandidate &TryCand) {
  // Initialize the candidate if needed.
  if (!Cand.isValid()) {
    TryCand.Reason = NodeOrder;
    return;
  }
 
  if (Cand.SGPRUsage > 60 &&
      SISched::tryLess(TryCand.SGPRUsage, Cand.SGPRUsage,
                       TryCand, Cand, RegUsage))
    return;
 
  // Schedule low latency instructions as top as possible.
  // Order of priority is:
  // . Low latency instructions which do not depend on other low latency
  //   instructions we haven't waited for
  // . Other instructions which do not depend on low latency instructions
  //   we haven't waited for
  // . Low latencies
  // . All other instructions
  // Goal is to get: low latency instructions - independent instructions
  //     - (eventually some more low latency instructions)
  //     - instructions that depend on the first low latency instructions.
  // If in the block there is a lot of constant loads, the SGPR usage
  // could go quite high, thus above the arbitrary limit of 60 will encourage
  // use the already loaded constants (in order to release some SGPRs) before
  // loading more.
  if (SISched::tryLess(TryCand.HasLowLatencyNonWaitedParent,
                       Cand.HasLowLatencyNonWaitedParent,
                       TryCand, Cand, SIScheduleCandReason::Depth))
    return;
 
  if (SISched::tryGreater(TryCand.IsLowLatency, Cand.IsLowLatency,
                          TryCand, Cand, SIScheduleCandReason::Depth))
    return;
 
  if (TryCand.IsLowLatency &&
      SISched::tryLess(TryCand.LowLatencyOffset, Cand.LowLatencyOffset,
                       TryCand, Cand, SIScheduleCandReason::Depth))
    return;
 
  if (SISched::tryLess(TryCand.VGPRUsage, Cand.VGPRUsage,
                       TryCand, Cand, RegUsage))
    return;
 
  // Fall through to original instruction order.
  if (TryCand.SU->NodeNum < Cand.SU->NodeNum) {
    TryCand.Reason = NodeOrder;
  }
}
 
SUnit* SIScheduleBlock::pickNode() {
  SISchedCandidate TopCand;
 
  for (SUnit* SU : TopReadySUs) {
    SISchedCandidate TryCand;
    std::vector<unsigned> pressure;
    std::vector<unsigned> MaxPressure;
    // Predict register usage after this instruction.
    TryCand.SU = SU;
    TopRPTracker.getDownwardPressure(SU->getInstr(), pressure, MaxPressure);
    TryCand.SGPRUsage = pressure[AMDGPU::RegisterPressureSets::SReg_32];
    TryCand.VGPRUsage = pressure[AMDGPU::RegisterPressureSets::VGPR_32];
    TryCand.IsLowLatency = DAG->IsLowLatencySU[SU->NodeNum];
    TryCand.LowLatencyOffset = DAG->LowLatencyOffset[SU->NodeNum];
    TryCand.HasLowLatencyNonWaitedParent =
      HasLowLatencyNonWaitedParent[NodeNum2Index[SU->NodeNum]];
    tryCandidateTopDown(TopCand, TryCand);
    if (TryCand.Reason != NoCand)
      TopCand.setBest(TryCand);
  }
 
  return TopCand.SU;
}
 
 
// Schedule something valid.
void SIScheduleBlock::fastSchedule() {
  TopReadySUs.clear();
  if (Scheduled)
    undoSchedule();
 
  for (SUnit* SU : SUnits) {
    if (!SU->NumPredsLeft)
      TopReadySUs.push_back(SU);
  }
 
  while (!TopReadySUs.empty()) {
    SUnit *SU = TopReadySUs[0];
    ScheduledSUnits.push_back(SU);
    nodeScheduled(SU);
  }
 
  Scheduled = true;
}
 
// Returns if the register was set between first and last.
static bool isDefBetween(Register Reg, SlotIndex First, SlotIndex Last,
                         const MachineRegisterInfo *MRI,
                         const LiveIntervals *LIS) {
  for (const MachineInstr &MI : MRI->def_instructions(Reg)) {
    if (MI.isDebugValue())
      continue;
    SlotIndex InstSlot = LIS->getInstructionIndex(MI).getRegSlot();
    if (InstSlot >= First && InstSlot <= Last)
      return true;
  }
  return false;
}
 
void SIScheduleBlock::initRegPressure(MachineBasicBlock::iterator BeginBlock,
                                      MachineBasicBlock::iterator EndBlock) {
  IntervalPressure Pressure, BotPressure;
  RegPressureTracker RPTracker(Pressure), BotRPTracker(BotPressure);
  LiveIntervals *LIS = DAG->getLIS();
  MachineRegisterInfo *MRI = DAG->getMRI();
  DAG->initRPTracker(TopRPTracker);
  DAG->initRPTracker(BotRPTracker);
  DAG->initRPTracker(RPTracker);
 
  // Goes though all SU. RPTracker captures what had to be alive for the SUs
  // to execute, and what is still alive at the end.
  for (SUnit* SU : ScheduledSUnits) {
    RPTracker.setPos(SU->getInstr());
    RPTracker.advance();
  }
 
  // Close the RPTracker to finalize live ins/outs.
  RPTracker.closeRegion();
 
  // Initialize the live ins and live outs.
  TopRPTracker.addLiveRegs(RPTracker.getPressure().LiveInRegs);
  BotRPTracker.addLiveRegs(RPTracker.getPressure().LiveOutRegs);
 
  // Do not Track Physical Registers, because it messes up.
  for (const auto &RegMaskPair : RPTracker.getPressure().LiveInRegs) {
    if (RegMaskPair.VRegOrUnit.isVirtualReg())
      LiveInRegs.insert(RegMaskPair.VRegOrUnit.asVirtualReg());
  }
  LiveOutRegs.clear();
  // There is several possibilities to distinguish:
  // 1) Reg is not input to any instruction in the block, but is output of one
  // 2) 1) + read in the block and not needed after it
  // 3) 1) + read in the block but needed in another block
  // 4) Reg is input of an instruction but another block will read it too
  // 5) Reg is input of an instruction and then rewritten in the block.
  //    result is not read in the block (implies used in another block)
  // 6) Reg is input of an instruction and then rewritten in the block.
  //    result is read in the block and not needed in another block
  // 7) Reg is input of an instruction and then rewritten in the block.
  //    result is read in the block but also needed in another block
  // LiveInRegs will contains all the regs in situation 4, 5, 6, 7
  // We want LiveOutRegs to contain only Regs whose content will be read after
  // in another block, and whose content was written in the current block,
  // that is we want it to get 1, 3, 5, 7
  // Since we made the MIs of a block to be packed all together before
  // scheduling, then the LiveIntervals were correct, and the RPTracker was
  // able to correctly handle 5 vs 6, 2 vs 3.
  // (Note: This is not sufficient for RPTracker to not do mistakes for case 4)
  // The RPTracker's LiveOutRegs has 1, 3, (some correct or incorrect)4, 5, 7
  // Comparing to LiveInRegs is not sufficient to differentiate 4 vs 5, 7
  // The use of findDefBetween removes the case 4.
  for (const auto &RegMaskPair : RPTracker.getPressure().LiveOutRegs) {
    VirtRegOrUnit VRegOrUnit = RegMaskPair.VRegOrUnit;
    if (VRegOrUnit.isVirtualReg() &&
        isDefBetween(VRegOrUnit.asVirtualReg(),
                     LIS->getInstructionIndex(*BeginBlock).getRegSlot(),
                     LIS->getInstructionIndex(*EndBlock).getRegSlot(), MRI,
                     LIS)) {
      LiveOutRegs.insert(VRegOrUnit.asVirtualReg());
    }
  }
 
  // Pressure = sum_alive_registers register size
  // Internally llvm will represent some registers as big 128 bits registers
  // for example, but they actually correspond to 4 actual 32 bits registers.
  // Thus Pressure is not equal to num_alive_registers * constant.
  LiveInPressure = TopPressure.MaxSetPressure;
  LiveOutPressure = BotPressure.MaxSetPressure;
 
  // Prepares TopRPTracker for top down scheduling.
  TopRPTracker.closeTop();
}
 
void SIScheduleBlock::schedule(MachineBasicBlock::iterator BeginBlock,
                               MachineBasicBlock::iterator EndBlock) {
  if (!Scheduled)
    fastSchedule();
 
  // PreScheduling phase to set LiveIn and LiveOut.
  initRegPressure(BeginBlock, EndBlock);
  undoSchedule();
 
  // Schedule for real now.
 
  TopReadySUs.clear();
 
  for (SUnit* SU : SUnits) {
    if (!SU->NumPredsLeft)
      TopReadySUs.push_back(SU);
  }
 
  while (!TopReadySUs.empty()) {
    SUnit *SU = pickNode();
    ScheduledSUnits.push_back(SU);
    TopRPTracker.setPos(SU->getInstr());
    TopRPTracker.advance();
    nodeScheduled(SU);
  }
 
  // TODO: compute InternalAdditionalPressure.
  InternalAdditionalPressure.resize(TopPressure.MaxSetPressure.size());
 
  // Check everything is right.
#ifndef NDEBUG
  assert(SUnits.size() == ScheduledSUnits.size() &&
            TopReadySUs.empty());
  for (SUnit* SU : SUnits) {
    assert(SU->isScheduled &&
              SU->NumPredsLeft == 0);
  }
#endif
 
  Scheduled = true;
}
 
void SIScheduleBlock::undoSchedule() {
  for (SUnit* SU : SUnits) {
    SU->isScheduled = false;
    for (SDep& Succ : SU->Succs) {
      if (BC->isSUInBlock(Succ.getSUnit(), ID))
        undoReleaseSucc(SU, &Succ);
    }
  }
  HasLowLatencyNonWaitedParent.assign(SUnits.size(), 0);
  ScheduledSUnits.clear();
  Scheduled = false;
}
 
void SIScheduleBlock::undoReleaseSucc(SUnit *SU, SDep *SuccEdge) {
  SUnit *SuccSU = SuccEdge->getSUnit();
 
  if (SuccEdge->isWeak()) {
    ++SuccSU->WeakPredsLeft;
    return;
  }
  ++SuccSU->NumPredsLeft;
}
 
void SIScheduleBlock::releaseSucc(SUnit *SU, SDep *SuccEdge) {
  SUnit *SuccSU = SuccEdge->getSUnit();
 
  if (SuccEdge->isWeak()) {
    --SuccSU->WeakPredsLeft;
    return;
  }
#ifndef NDEBUG
  if (SuccSU->NumPredsLeft == 0) {
    dbgs() << "*** Scheduling failed! ***\n";
    DAG->dumpNode(*SuccSU);
    dbgs() << " has been released too many times!\n";
    llvm_unreachable(nullptr);
  }
#endif
 
  --SuccSU->NumPredsLeft;
}
 
/// Release Successors of the SU that are in the block or not.
void SIScheduleBlock::releaseSuccessors(SUnit *SU, bool InOrOutBlock) {
  for (SDep& Succ : SU->Succs) {
    SUnit *SuccSU = Succ.getSUnit();
 
    if (SuccSU->NodeNum >= DAG->SUnits.size())
        continue;
 
    if (BC->isSUInBlock(SuccSU, ID) != InOrOutBlock)
      continue;
 
    releaseSucc(SU, &Succ);
    if (SuccSU->NumPredsLeft == 0 && InOrOutBlock)
      TopReadySUs.push_back(SuccSU);
  }
}
 
void SIScheduleBlock::nodeScheduled(SUnit *SU) {
  // Is in TopReadySUs
  assert (!SU->NumPredsLeft);
  std::vector<SUnit *>::iterator I = llvm::find(TopReadySUs, SU);
  if (I == TopReadySUs.end()) {
    dbgs() << "Data Structure Bug in SI Scheduler\n";
    llvm_unreachable(nullptr);
  }
  TopReadySUs.erase(I);
 
  releaseSuccessors(SU, true);
  // Scheduling this node will trigger a wait,
  // thus propagate to other instructions that they do not need to wait either.
  if (HasLowLatencyNonWaitedParent[NodeNum2Index[SU->NodeNum]])
    HasLowLatencyNonWaitedParent.assign(SUnits.size(), 0);
 
  if (DAG->IsLowLatencySU[SU->NodeNum]) {
     for (SDep& Succ : SU->Succs) {
      std::map<unsigned, unsigned>::iterator I =
        NodeNum2Index.find(Succ.getSUnit()->NodeNum);
      if (I != NodeNum2Index.end())
        HasLowLatencyNonWaitedParent[I->second] = 1;
    }
  }
  SU->isScheduled = true;
}
 
void SIScheduleBlock::finalizeUnits() {
  // We remove links from outside blocks to enable scheduling inside the block.
  for (SUnit* SU : SUnits) {
    releaseSuccessors(SU, false);
    if (DAG->IsHighLatencySU[SU->NodeNum])
      HighLatencyBlock = true;
  }
  HasLowLatencyNonWaitedParent.resize(SUnits.size(), 0);
}
 
// we maintain ascending order of IDs
void SIScheduleBlock::addPred(SIScheduleBlock *Pred) {
  unsigned PredID = Pred->getID();
 
  // Check if not already predecessor.
  for (SIScheduleBlock* P : Preds) {
    if (PredID == P->getID())
      return;
  }
  Preds.push_back(Pred);
 
  assert(none_of(Succs,
                 [=](std::pair<SIScheduleBlock*,
                     SIScheduleBlockLinkKind> S) {
                   return PredID == S.first->getID();
                    }) &&
         "Loop in the Block Graph!");
}
 
void SIScheduleBlock::addSucc(SIScheduleBlock *Succ,
                              SIScheduleBlockLinkKind Kind) {
  unsigned SuccID = Succ->getID();
 
  // Check if not already predecessor.
  for (std::pair<SIScheduleBlock*, SIScheduleBlockLinkKind> &S : Succs) {
    if (SuccID == S.first->getID()) {
      if (S.second == SIScheduleBlockLinkKind::NoData &&
          Kind == SIScheduleBlockLinkKind::Data)
        S.second = Kind;
      return;
    }
  }
  if (Succ->isHighLatencyBlock())
    ++NumHighLatencySuccessors;
  Succs.emplace_back(Succ, Kind);
 
  assert(none_of(Preds,
                 [=](SIScheduleBlock *P) { return SuccID == P->getID(); }) &&
         "Loop in the Block Graph!");
}
 
#ifndef NDEBUG
void SIScheduleBlock::printDebug(bool full) {
  dbgs() << "Block (" << ID << ")\n";
  if (!full)
    return;
 
  dbgs() << "\nContains High Latency Instruction: "
         << HighLatencyBlock << '\n';
  dbgs() << "\nDepends On:\n";
  for (SIScheduleBlock* P : Preds) {
    P->printDebug(false);
  }
 
  dbgs() << "\nSuccessors:\n";
  for (std::pair<SIScheduleBlock*, SIScheduleBlockLinkKind> S : Succs) {
    if (S.second == SIScheduleBlockLinkKind::Data)
      dbgs() << "(Data Dep) ";
    S.first->printDebug(false);
  }
 
  if (Scheduled) {
    dbgs() << "LiveInPressure "
           << LiveInPressure[AMDGPU::RegisterPressureSets::SReg_32] << ' '
           << LiveInPressure[AMDGPU::RegisterPressureSets::VGPR_32] << '\n';
    dbgs() << "LiveOutPressure "
           << LiveOutPressure[AMDGPU::RegisterPressureSets::SReg_32] << ' '
           << LiveOutPressure[AMDGPU::RegisterPressureSets::VGPR_32] << "\n\n";
    dbgs() << "LiveIns:\n";
    for (Register Reg : LiveInRegs)
      dbgs() << printReg(Reg, DAG->getTRI()) << ' ';
 
    dbgs() << "\nLiveOuts:\n";
    for (Register Reg : LiveOutRegs)
      dbgs() << printReg(Reg, DAG->getTRI()) << ' ';
  }
 
  dbgs() << "\nInstructions:\n";
  for (const SUnit* SU : SUnits)
      DAG->dumpNode(*SU);
 
  dbgs() << "///////////////////////\n";
}
#endif
 
// SIScheduleBlockCreator //
 
SIScheduleBlockCreator::SIScheduleBlockCreator(SIScheduleDAGMI *DAG)
    : DAG(DAG) {}
 
SIScheduleBlocks
SIScheduleBlockCreator::getBlocks(SISchedulerBlockCreatorVariant BlockVariant) {
  std::map<SISchedulerBlockCreatorVariant, SIScheduleBlocks>::iterator B =
    Blocks.find(BlockVariant);
  if (B == Blocks.end()) {
    SIScheduleBlocks Res;
    createBlocksForVariant(BlockVariant);
    topologicalSort();
    scheduleInsideBlocks();
    fillStats();
    Res.Blocks = CurrentBlocks;
    Res.TopDownIndex2Block = TopDownIndex2Block;
    Res.TopDownBlock2Index = TopDownBlock2Index;
    Blocks[BlockVariant] = Res;
    return Res;
  }
  return B->second;
}
 
bool SIScheduleBlockCreator::isSUInBlock(SUnit *SU, unsigned ID) {
  if (SU->NodeNum >= DAG->SUnits.size())
    return false;
  return CurrentBlocks[Node2CurrentBlock[SU->NodeNum]]->getID() == ID;
}
 
void SIScheduleBlockCreator::colorHighLatenciesAlone() {
  unsigned DAGSize = DAG->SUnits.size();
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SUnit *SU = &DAG->SUnits[i];
    if (DAG->IsHighLatencySU[SU->NodeNum]) {
      CurrentColoring[SU->NodeNum] = NextReservedID++;
    }
  }
}
 
static bool
hasDataDependencyPred(const SUnit &SU, const SUnit &FromSU) {
  for (const auto &PredDep : SU.Preds) {
    if (PredDep.getSUnit() == &FromSU &&
        PredDep.getKind() == llvm::SDep::Data)
      return true;
  }
  return false;
}
 
void SIScheduleBlockCreator::colorHighLatenciesGroups() {
  unsigned DAGSize = DAG->SUnits.size();
  unsigned NumHighLatencies = 0;
  unsigned GroupSize;
  int Color = NextReservedID;
  unsigned Count = 0;
  std::set<unsigned> FormingGroup;
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SUnit *SU = &DAG->SUnits[i];
    if (DAG->IsHighLatencySU[SU->NodeNum])
      ++NumHighLatencies;
  }
 
  if (NumHighLatencies == 0)
    return;
 
  if (NumHighLatencies <= 6)
    GroupSize = 2;
  else if (NumHighLatencies <= 12)
    GroupSize = 3;
  else
    GroupSize = 4;
 
  for (unsigned SUNum : DAG->TopDownIndex2SU) {
    const SUnit &SU = DAG->SUnits[SUNum];
    if (DAG->IsHighLatencySU[SU.NodeNum]) {
      unsigned CompatibleGroup = true;
      int ProposedColor = Color;
      std::vector<int> AdditionalElements;
 
      // We don't want to put in the same block
      // two high latency instructions that depend
      // on each other.
      // One way would be to check canAddEdge
      // in both directions, but that currently is not
      // enough because there the high latency order is
      // enforced (via links).
      // Instead, look at the dependencies between the
      // high latency instructions and deduce if it is
      // a data dependency or not.
      for (unsigned j : FormingGroup) {
        bool HasSubGraph;
        std::vector<int> SubGraph;
        // By construction (topological order), if SU and
        // DAG->SUnits[j] are linked, DAG->SUnits[j] is necessary
        // in the parent graph of SU.
#ifndef NDEBUG
        SubGraph = DAG->GetTopo()->GetSubGraph(SU, DAG->SUnits[j],
                                               HasSubGraph);
        assert(!HasSubGraph);
#endif
        SubGraph = DAG->GetTopo()->GetSubGraph(DAG->SUnits[j], SU,
                                               HasSubGraph);
        if (!HasSubGraph)
          continue; // No dependencies between each other
        if (SubGraph.size() > 5) {
          // Too many elements would be required to be added to the block.
          CompatibleGroup = false;
          break;
        }
        // Check the type of dependency
        for (unsigned k : SubGraph) {
          // If in the path to join the two instructions,
          // there is another high latency instruction,
          // or instructions colored for another block
          // abort the merge.
          if (DAG->IsHighLatencySU[k] || (CurrentColoring[k] != ProposedColor &&
                                          CurrentColoring[k] != 0)) {
            CompatibleGroup = false;
            break;
          }
          // If one of the SU in the subgraph depends on the result of SU j,
          // there'll be a data dependency.
          if (hasDataDependencyPred(DAG->SUnits[k], DAG->SUnits[j])) {
            CompatibleGroup = false;
            break;
          }
        }
        if (!CompatibleGroup)
          break;
        // Same check for the SU
        if (hasDataDependencyPred(SU, DAG->SUnits[j])) {
          CompatibleGroup = false;
          break;
        }
        // Add all the required instructions to the block
        // These cannot live in another block (because they
        // depend (order dependency) on one of the
        // instruction in the block, and are required for the
        // high latency instruction we add.
        llvm::append_range(AdditionalElements, SubGraph);
      }
      if (CompatibleGroup) {
        FormingGroup.insert(SU.NodeNum);
        for (unsigned j : AdditionalElements)
          CurrentColoring[j] = ProposedColor;
        CurrentColoring[SU.NodeNum] = ProposedColor;
        ++Count;
      }
      // Found one incompatible instruction,
      // or has filled a big enough group.
      // -> start a new one.
      if (!CompatibleGroup) {
        FormingGroup.clear();
        Color = ++NextReservedID;
        ProposedColor = Color;
        FormingGroup.insert(SU.NodeNum);
        CurrentColoring[SU.NodeNum] = ProposedColor;
        Count = 0;
      } else if (Count == GroupSize) {
        FormingGroup.clear();
        Color = ++NextReservedID;
        ProposedColor = Color;
        Count = 0;
      }
    }
  }
}
 
void SIScheduleBlockCreator::colorComputeReservedDependencies() {
  unsigned DAGSize = DAG->SUnits.size();
  std::map<std::set<unsigned>, unsigned> ColorCombinations;
 
  CurrentTopDownReservedDependencyColoring.clear();
  CurrentBottomUpReservedDependencyColoring.clear();
 
  CurrentTopDownReservedDependencyColoring.resize(DAGSize, 0);
  CurrentBottomUpReservedDependencyColoring.resize(DAGSize, 0);
 
  // Traverse TopDown, and give different colors to SUs depending
  // on which combination of High Latencies they depend on.
 
  for (unsigned SUNum : DAG->TopDownIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
 
    // Already given.
    if (CurrentColoring[SU->NodeNum]) {
      CurrentTopDownReservedDependencyColoring[SU->NodeNum] =
        CurrentColoring[SU->NodeNum];
      continue;
    }
 
   for (SDep& PredDep : SU->Preds) {
      SUnit *Pred = PredDep.getSUnit();
      if (PredDep.isWeak() || Pred->NodeNum >= DAGSize)
        continue;
      if (CurrentTopDownReservedDependencyColoring[Pred->NodeNum] > 0)
        SUColors.insert(CurrentTopDownReservedDependencyColoring[Pred->NodeNum]);
    }
    // Color 0 by default.
    if (SUColors.empty())
      continue;
    // Same color than parents.
    if (SUColors.size() == 1 && *SUColors.begin() > DAGSize)
      CurrentTopDownReservedDependencyColoring[SU->NodeNum] =
        *SUColors.begin();
    else {
      auto [Pos, Inserted] =
          ColorCombinations.try_emplace(SUColors, NextNonReservedID);
      if (Inserted)
        ++NextNonReservedID;
      CurrentTopDownReservedDependencyColoring[SU->NodeNum] = Pos->second;
    }
  }
 
  ColorCombinations.clear();
 
  // Same as before, but BottomUp.
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
 
    // Already given.
    if (CurrentColoring[SU->NodeNum]) {
      CurrentBottomUpReservedDependencyColoring[SU->NodeNum] =
        CurrentColoring[SU->NodeNum];
      continue;
    }
 
    for (SDep& SuccDep : SU->Succs) {
      SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      if (CurrentBottomUpReservedDependencyColoring[Succ->NodeNum] > 0)
        SUColors.insert(CurrentBottomUpReservedDependencyColoring[Succ->NodeNum]);
    }
    // Keep color 0.
    if (SUColors.empty())
      continue;
    // Same color than parents.
    if (SUColors.size() == 1 && *SUColors.begin() > DAGSize)
      CurrentBottomUpReservedDependencyColoring[SU->NodeNum] =
        *SUColors.begin();
    else {
      std::map<std::set<unsigned>, unsigned>::iterator Pos =
        ColorCombinations.find(SUColors);
      if (Pos != ColorCombinations.end()) {
        CurrentBottomUpReservedDependencyColoring[SU->NodeNum] = Pos->second;
      } else {
        CurrentBottomUpReservedDependencyColoring[SU->NodeNum] =
          NextNonReservedID;
        ColorCombinations[SUColors] = NextNonReservedID++;
      }
    }
  }
}
 
void SIScheduleBlockCreator::colorAccordingToReservedDependencies() {
  std::map<std::pair<unsigned, unsigned>, unsigned> ColorCombinations;
 
  // Every combination of colors given by the top down
  // and bottom up Reserved node dependency
 
  for (const SUnit &SU : DAG->SUnits) {
    std::pair<unsigned, unsigned> SUColors;
 
    // High latency instructions: already given.
    if (CurrentColoring[SU.NodeNum])
      continue;
 
    SUColors.first = CurrentTopDownReservedDependencyColoring[SU.NodeNum];
    SUColors.second = CurrentBottomUpReservedDependencyColoring[SU.NodeNum];
 
    auto [Pos, Inserted] =
        ColorCombinations.try_emplace(SUColors, NextNonReservedID);
    CurrentColoring[SU.NodeNum] = Pos->second;
    if (Inserted)
      NextNonReservedID++;
  }
}
 
void SIScheduleBlockCreator::colorEndsAccordingToDependencies() {
  unsigned DAGSize = DAG->SUnits.size();
  std::vector<int> PendingColoring = CurrentColoring;
 
  assert(DAGSize >= 1 &&
         CurrentBottomUpReservedDependencyColoring.size() == DAGSize &&
         CurrentTopDownReservedDependencyColoring.size() == DAGSize);
  // If there is no reserved block at all, do nothing. We don't want
  // everything in one block.
  if (*llvm::max_element(CurrentBottomUpReservedDependencyColoring) == 0 &&
      *llvm::max_element(CurrentTopDownReservedDependencyColoring) == 0)
    return;
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
    std::set<unsigned> SUColorsPending;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    if (CurrentBottomUpReservedDependencyColoring[SU->NodeNum] > 0 ||
        CurrentTopDownReservedDependencyColoring[SU->NodeNum] > 0)
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
      SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      if (CurrentBottomUpReservedDependencyColoring[Succ->NodeNum] > 0 ||
          CurrentTopDownReservedDependencyColoring[Succ->NodeNum] > 0)
        SUColors.insert(CurrentColoring[Succ->NodeNum]);
      SUColorsPending.insert(PendingColoring[Succ->NodeNum]);
    }
    // If there is only one child/parent block, and that block
    // is not among the ones we are removing in this path, then
    // merge the instruction to that block
    if (SUColors.size() == 1 && SUColorsPending.size() == 1)
      PendingColoring[SU->NodeNum] = *SUColors.begin();
    else // TODO: Attribute new colors depending on color
         // combination of children.
      PendingColoring[SU->NodeNum] = NextNonReservedID++;
  }
  CurrentColoring = PendingColoring;
}
 
 
void SIScheduleBlockCreator::colorForceConsecutiveOrderInGroup() {
  unsigned DAGSize = DAG->SUnits.size();
  unsigned PreviousColor;
  std::set<unsigned> SeenColors;
 
  if (DAGSize <= 1)
    return;
 
  PreviousColor = CurrentColoring[0];
 
  for (unsigned i = 1, e = DAGSize; i != e; ++i) {
    SUnit *SU = &DAG->SUnits[i];
    unsigned CurrentColor = CurrentColoring[i];
    unsigned PreviousColorSave = PreviousColor;
    assert(i == SU->NodeNum);
 
    if (CurrentColor != PreviousColor)
      SeenColors.insert(PreviousColor);
    PreviousColor = CurrentColor;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    if (SeenColors.find(CurrentColor) == SeenColors.end())
      continue;
 
    if (PreviousColorSave != CurrentColor)
      CurrentColoring[i] = NextNonReservedID++;
    else
      CurrentColoring[i] = CurrentColoring[i-1];
  }
}
 
void SIScheduleBlockCreator::colorMergeConstantLoadsNextGroup() {
  unsigned DAGSize = DAG->SUnits.size();
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    // No predecessor: Vgpr constant loading.
    // Low latency instructions usually have a predecessor (the address)
    if (SU->Preds.size() > 0 && !DAG->IsLowLatencySU[SU->NodeNum])
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
      SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      SUColors.insert(CurrentColoring[Succ->NodeNum]);
    }
    if (SUColors.size() == 1)
      CurrentColoring[SU->NodeNum] = *SUColors.begin();
  }
}
 
void SIScheduleBlockCreator::colorMergeIfPossibleNextGroup() {
  unsigned DAGSize = DAG->SUnits.size();
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
       SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      SUColors.insert(CurrentColoring[Succ->NodeNum]);
    }
    if (SUColors.size() == 1)
      CurrentColoring[SU->NodeNum] = *SUColors.begin();
  }
}
 
void SIScheduleBlockCreator::colorMergeIfPossibleNextGroupOnlyForReserved() {
  unsigned DAGSize = DAG->SUnits.size();
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    std::set<unsigned> SUColors;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
       SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      SUColors.insert(CurrentColoring[Succ->NodeNum]);
    }
    if (SUColors.size() == 1 && *SUColors.begin() <= DAGSize)
      CurrentColoring[SU->NodeNum] = *SUColors.begin();
  }
}
 
void SIScheduleBlockCreator::colorMergeIfPossibleSmallGroupsToNextGroup() {
  unsigned DAGSize = DAG->SUnits.size();
  std::map<unsigned, unsigned> ColorCount;
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    unsigned color = CurrentColoring[SU->NodeNum];
     ++ColorCount[color];
  }
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    unsigned color = CurrentColoring[SU->NodeNum];
    std::set<unsigned> SUColors;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    if (ColorCount[color] > 1)
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
       SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      SUColors.insert(CurrentColoring[Succ->NodeNum]);
    }
    if (SUColors.size() == 1 && *SUColors.begin() != color) {
      --ColorCount[color];
      CurrentColoring[SU->NodeNum] = *SUColors.begin();
      ++ColorCount[*SUColors.begin()];
    }
  }
}
 
void SIScheduleBlockCreator::cutHugeBlocks() {
  // TODO
}
 
void SIScheduleBlockCreator::regroupNoUserInstructions() {
  unsigned DAGSize = DAG->SUnits.size();
  int GroupID = NextNonReservedID++;
 
  for (unsigned SUNum : DAG->BottomUpIndex2SU) {
    SUnit *SU = &DAG->SUnits[SUNum];
    bool hasSuccessor = false;
 
    if (CurrentColoring[SU->NodeNum] <= (int)DAGSize)
      continue;
 
    for (SDep& SuccDep : SU->Succs) {
       SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      hasSuccessor = true;
    }
    if (!hasSuccessor)
      CurrentColoring[SU->NodeNum] = GroupID;
  }
}
 
void SIScheduleBlockCreator::colorExports() {
  unsigned ExportColor = NextNonReservedID++;
  SmallVector<unsigned, 8> ExpGroup;
 
  // Put all exports together in a block.
  // The block will naturally end up being scheduled last,
  // thus putting exports at the end of the schedule, which
  // is better for performance.
  // However we must ensure, for safety, the exports can be put
  // together in the same block without any other instruction.
  // This could happen, for example, when scheduling after regalloc
  // if reloading a spilled register from memory using the same
  // register than used in a previous export.
  // If that happens, do not regroup the exports.
  for (unsigned SUNum : DAG->TopDownIndex2SU) {
    const SUnit &SU = DAG->SUnits[SUNum];
    if (SIInstrInfo::isEXP(*SU.getInstr())) {
      // SU is an export instruction. Check whether one of its successor
      // dependencies is a non-export, in which case we skip export grouping.
      for (const SDep &SuccDep : SU.Succs) {
        const SUnit *SuccSU = SuccDep.getSUnit();
        if (SuccDep.isWeak() || SuccSU->NodeNum >= DAG->SUnits.size()) {
          // Ignore these dependencies.
          continue;
        }
        assert(SuccSU->isInstr() &&
               "SUnit unexpectedly not representing an instruction!");
 
        if (!SIInstrInfo::isEXP(*SuccSU->getInstr())) {
          // A non-export depends on us. Skip export grouping.
          // Note that this is a bit pessimistic: We could still group all other
          // exports that are not depended on by non-exports, directly or
          // indirectly. Simply skipping this particular export but grouping all
          // others would not account for indirect dependencies.
          return;
        }
      }
      ExpGroup.push_back(SUNum);
    }
  }
 
  // The group can be formed. Give the color.
  for (unsigned j : ExpGroup)
    CurrentColoring[j] = ExportColor;
}
 
void SIScheduleBlockCreator::createBlocksForVariant(SISchedulerBlockCreatorVariant BlockVariant) {
  unsigned DAGSize = DAG->SUnits.size();
  std::map<unsigned,unsigned> RealID;
 
  CurrentBlocks.clear();
  CurrentColoring.clear();
  CurrentColoring.resize(DAGSize, 0);
  Node2CurrentBlock.clear();
 
  // Restore links previous scheduling variant has overridden.
  DAG->restoreSULinksLeft();
 
  NextReservedID = 1;
  NextNonReservedID = DAGSize + 1;
 
  LLVM_DEBUG(dbgs() << "Coloring the graph\n");
 
  if (BlockVariant == SISchedulerBlockCreatorVariant::LatenciesGrouped)
    colorHighLatenciesGroups();
  else
    colorHighLatenciesAlone();
  colorComputeReservedDependencies();
  colorAccordingToReservedDependencies();
  colorEndsAccordingToDependencies();
  if (BlockVariant == SISchedulerBlockCreatorVariant::LatenciesAlonePlusConsecutive)
    colorForceConsecutiveOrderInGroup();
  regroupNoUserInstructions();
  colorMergeConstantLoadsNextGroup();
  colorMergeIfPossibleNextGroupOnlyForReserved();
  colorExports();
 
  // Put SUs of same color into same block
  Node2CurrentBlock.resize(DAGSize, -1);
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SUnit *SU = &DAG->SUnits[i];
    unsigned Color = CurrentColoring[SU->NodeNum];
    auto [It, Inserted] = RealID.try_emplace(Color);
    if (Inserted) {
      int ID = CurrentBlocks.size();
      BlockPtrs.push_back(std::make_unique<SIScheduleBlock>(DAG, this, ID));
      CurrentBlocks.push_back(BlockPtrs.rbegin()->get());
      It->second = ID;
    }
    CurrentBlocks[It->second]->addUnit(SU);
    Node2CurrentBlock[SU->NodeNum] = It->second;
  }
 
  // Build dependencies between blocks.
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SUnit *SU = &DAG->SUnits[i];
    int SUID = Node2CurrentBlock[i];
     for (SDep& SuccDep : SU->Succs) {
       SUnit *Succ = SuccDep.getSUnit();
      if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
        continue;
      if (Node2CurrentBlock[Succ->NodeNum] != SUID)
        CurrentBlocks[SUID]->addSucc(CurrentBlocks[Node2CurrentBlock[Succ->NodeNum]],
                                     SuccDep.isCtrl() ? NoData : Data);
    }
    for (SDep& PredDep : SU->Preds) {
      SUnit *Pred = PredDep.getSUnit();
      if (PredDep.isWeak() || Pred->NodeNum >= DAGSize)
        continue;
      if (Node2CurrentBlock[Pred->NodeNum] != SUID)
        CurrentBlocks[SUID]->addPred(CurrentBlocks[Node2CurrentBlock[Pred->NodeNum]]);
    }
  }
 
  // Free root and leafs of all blocks to enable scheduling inside them.
  for (SIScheduleBlock *Block : CurrentBlocks)
    Block->finalizeUnits();
  LLVM_DEBUG({
    dbgs() << "Blocks created:\n\n";
    for (SIScheduleBlock *Block : CurrentBlocks)
      Block->printDebug(true);
  });
}
 
// Two functions taken from Codegen/MachineScheduler.cpp
 
/// Non-const version.
static MachineBasicBlock::iterator
nextIfDebug(MachineBasicBlock::iterator I,
            MachineBasicBlock::const_iterator End) {
  for (; I != End; ++I) {
    if (!I->isDebugInstr())
      break;
  }
  return I;
}
 
void SIScheduleBlockCreator::topologicalSort() {
  unsigned DAGSize = CurrentBlocks.size();
  std::vector<int> WorkList;
 
  LLVM_DEBUG(dbgs() << "Topological Sort\n");
 
  WorkList.reserve(DAGSize);
  TopDownIndex2Block.resize(DAGSize);
  TopDownBlock2Index.resize(DAGSize);
  BottomUpIndex2Block.resize(DAGSize);
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SIScheduleBlock *Block = CurrentBlocks[i];
    unsigned Degree = Block->getSuccs().size();
    TopDownBlock2Index[i] = Degree;
    if (Degree == 0) {
      WorkList.push_back(i);
    }
  }
 
  int Id = DAGSize;
  while (!WorkList.empty()) {
    int i = WorkList.back();
    SIScheduleBlock *Block = CurrentBlocks[i];
    WorkList.pop_back();
    TopDownBlock2Index[i] = --Id;
    TopDownIndex2Block[Id] = i;
    for (SIScheduleBlock* Pred : Block->getPreds()) {
      if (!--TopDownBlock2Index[Pred->getID()])
        WorkList.push_back(Pred->getID());
    }
  }
 
#ifndef NDEBUG
  // Check correctness of the ordering.
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SIScheduleBlock *Block = CurrentBlocks[i];
    for (SIScheduleBlock* Pred : Block->getPreds()) {
      assert(TopDownBlock2Index[i] > TopDownBlock2Index[Pred->getID()] &&
      "Wrong Top Down topological sorting");
    }
  }
#endif
 
  BottomUpIndex2Block = std::vector<int>(TopDownIndex2Block.rbegin(),
                                         TopDownIndex2Block.rend());
}
 
void SIScheduleBlockCreator::scheduleInsideBlocks() {
  unsigned DAGSize = CurrentBlocks.size();
 
  LLVM_DEBUG(dbgs() << "\nScheduling Blocks\n\n");
 
  // We do schedule a valid scheduling such that a Block corresponds
  // to a range of instructions.
  LLVM_DEBUG(dbgs() << "First phase: Fast scheduling for Reg Liveness\n");
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SIScheduleBlock *Block = CurrentBlocks[i];
    Block->fastSchedule();
  }
 
  // Note: the following code, and the part restoring previous position
  // is by far the most expensive operation of the Scheduler.
 
  // Do not update CurrentTop.
  MachineBasicBlock::iterator CurrentTopFastSched = DAG->getCurrentTop();
  std::vector<MachineBasicBlock::iterator> PosOld;
  std::vector<MachineBasicBlock::iterator> PosNew;
  PosOld.reserve(DAG->SUnits.size());
  PosNew.reserve(DAG->SUnits.size());
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    int BlockIndice = TopDownIndex2Block[i];
    SIScheduleBlock *Block = CurrentBlocks[BlockIndice];
    std::vector<SUnit*> SUs = Block->getScheduledUnits();
 
    for (SUnit* SU : SUs) {
      MachineInstr *MI = SU->getInstr();
      MachineBasicBlock::iterator Pos = MI;
      PosOld.push_back(Pos);
      if (&*CurrentTopFastSched == MI) {
        PosNew.push_back(Pos);
        CurrentTopFastSched = nextIfDebug(++CurrentTopFastSched,
                                          DAG->getCurrentBottom());
      } else {
        // Update the instruction stream.
        DAG->getBB()->splice(CurrentTopFastSched, DAG->getBB(), MI);
 
        // Update LiveIntervals.
        // Note: Moving all instructions and calling handleMove every time
        // is the most cpu intensive operation of the scheduler.
        // It would gain a lot if there was a way to recompute the
        // LiveIntervals for the entire scheduling region.
        DAG->getLIS()->handleMove(*MI, /*UpdateFlags=*/true);
        PosNew.push_back(CurrentTopFastSched);
      }
    }
  }
 
  // Now we have Block of SUs == Block of MI.
  // We do the final schedule for the instructions inside the block.
  // The property that all the SUs of the Block are grouped together as MI
  // is used for correct reg usage tracking.
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    SIScheduleBlock *Block = CurrentBlocks[i];
    std::vector<SUnit*> SUs = Block->getScheduledUnits();
    Block->schedule((*SUs.begin())->getInstr(), (*SUs.rbegin())->getInstr());
  }
 
  LLVM_DEBUG(dbgs() << "Restoring MI Pos\n");
  // Restore old ordering (which prevents a LIS->handleMove bug).
  for (unsigned i = PosOld.size(), e = 0; i != e; --i) {
    MachineBasicBlock::iterator POld = PosOld[i-1];
    MachineBasicBlock::iterator PNew = PosNew[i-1];
    if (PNew != POld) {
      // Update the instruction stream.
      DAG->getBB()->splice(POld, DAG->getBB(), PNew);
 
      // Update LiveIntervals.
      DAG->getLIS()->handleMove(*POld, /*UpdateFlags=*/true);
    }
  }
 
  LLVM_DEBUG({
    for (SIScheduleBlock *Block : CurrentBlocks)
      Block->printDebug(true);
  });
}
 
void SIScheduleBlockCreator::fillStats() {
  unsigned DAGSize = CurrentBlocks.size();
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    int BlockIndice = TopDownIndex2Block[i];
    SIScheduleBlock *Block = CurrentBlocks[BlockIndice];
    if (Block->getPreds().empty())
      Block->Depth = 0;
    else {
      unsigned Depth = 0;
      for (SIScheduleBlock *Pred : Block->getPreds()) {
        if (Depth < Pred->Depth + Pred->getCost())
          Depth = Pred->Depth + Pred->getCost();
      }
      Block->Depth = Depth;
    }
  }
 
  for (unsigned i = 0, e = DAGSize; i != e; ++i) {
    int BlockIndice = BottomUpIndex2Block[i];
    SIScheduleBlock *Block = CurrentBlocks[BlockIndice];
    if (Block->getSuccs().empty())
      Block->Height = 0;
    else {
      unsigned Height = 0;
      for (const auto &Succ : Block->getSuccs())
        Height = std::max(Height, Succ.first->Height + Succ.first->getCost());
      Block->Height = Height;
    }
  }
}
 
// SIScheduleBlockScheduler //
 
SIScheduleBlockScheduler::SIScheduleBlockScheduler(SIScheduleDAGMI *DAG,
                                                   SISchedulerBlockSchedulerVariant Variant,
                                                   SIScheduleBlocks  BlocksStruct) :
  DAG(DAG), Variant(Variant), Blocks(BlocksStruct.Blocks),
  LastPosWaitedHighLatency(0), NumBlockScheduled(0), VregCurrentUsage(0),
  SregCurrentUsage(0), maxVregUsage(0), maxSregUsage(0) {
 
  // Fill the usage of every output
  // Warning: while by construction we always have a link between two blocks
  // when one needs a result from the other, the number of users of an output
  // is not the sum of child blocks having as input the same virtual register.
  // Here is an example. A produces x and y. B eats x and produces x'.
  // C eats x' and y. The register coalescer may have attributed the same
  // virtual register to x and x'.
  // To count accurately, we do a topological sort. In case the register is
  // found for several parents, we increment the usage of the one with the
  // highest topological index.
  LiveOutRegsNumUsages.resize(Blocks.size());
  for (SIScheduleBlock *Block : Blocks) {
    for (Register Reg : Block->getInRegs()) {
      bool Found = false;
      int topoInd = -1;
      for (SIScheduleBlock* Pred: Block->getPreds()) {
        std::set<Register> PredOutRegs = Pred->getOutRegs();
        std::set<Register>::iterator RegPos = PredOutRegs.find(Reg);
 
        if (RegPos != PredOutRegs.end()) {
          Found = true;
          if (topoInd < BlocksStruct.TopDownBlock2Index[Pred->getID()]) {
            topoInd = BlocksStruct.TopDownBlock2Index[Pred->getID()];
          }
        }
      }
 
      if (!Found)
        continue;
 
      int PredID = BlocksStruct.TopDownIndex2Block[topoInd];
      ++LiveOutRegsNumUsages[PredID][Reg];
    }
  }
 
  LastPosHighLatencyParentScheduled.resize(Blocks.size(), 0);
  BlockNumPredsLeft.resize(Blocks.size());
  BlockNumSuccsLeft.resize(Blocks.size());
 
  for (unsigned i = 0, e = Blocks.size(); i != e; ++i) {
    SIScheduleBlock *Block = Blocks[i];
    BlockNumPredsLeft[i] = Block->getPreds().size();
    BlockNumSuccsLeft[i] = Block->getSuccs().size();
  }
 
#ifndef NDEBUG
  for (unsigned i = 0, e = Blocks.size(); i != e; ++i) {
    SIScheduleBlock *Block = Blocks[i];
    assert(Block->getID() == i);
  }
#endif
 
  std::set<VirtRegOrUnit> InRegs = DAG->getInRegs();
  addLiveRegs(InRegs);
 
  // Increase LiveOutRegsNumUsages for blocks
  // producing registers consumed in another
  // scheduling region.
  for (VirtRegOrUnit VRegOrUnit : DAG->getOutRegs()) {
    for (unsigned i = 0, e = Blocks.size(); i != e; ++i) {
      // Do reverse traversal
      int ID = BlocksStruct.TopDownIndex2Block[Blocks.size()-1-i];
      SIScheduleBlock *Block = Blocks[ID];
      const std::set<Register> &OutRegs = Block->getOutRegs();
 
      if (!VRegOrUnit.isVirtualReg() ||
          OutRegs.find(VRegOrUnit.asVirtualReg()) == OutRegs.end())
        continue;
 
      ++LiveOutRegsNumUsages[ID][VRegOrUnit.asVirtualReg()];
      break;
    }
  }
 
  // Fill LiveRegsConsumers for regs that were already
  // defined before scheduling.
  for (SIScheduleBlock *Block : Blocks) {
    for (Register Reg : Block->getInRegs()) {
      bool Found = false;
      for (SIScheduleBlock* Pred: Block->getPreds()) {
        std::set<Register> PredOutRegs = Pred->getOutRegs();
        std::set<Register>::iterator RegPos = PredOutRegs.find(Reg);
 
        if (RegPos != PredOutRegs.end()) {
          Found = true;
          break;
        }
      }
 
      if (!Found)
        ++LiveRegsConsumers[Reg];
    }
  }
 
  for (unsigned i = 0, e = Blocks.size(); i != e; ++i) {
    SIScheduleBlock *Block = Blocks[i];
    if (BlockNumPredsLeft[i] == 0) {
      ReadyBlocks.push_back(Block);
    }
  }
 
  while (SIScheduleBlock *Block = pickBlock()) {
    BlocksScheduled.push_back(Block);
    blockScheduled(Block);
  }
 
  LLVM_DEBUG(dbgs() << "Block Order:"; for (SIScheduleBlock *Block
                                            : BlocksScheduled) {
    dbgs() << ' ' << Block->getID();
  } dbgs() << '\n';);
}
 
bool SIScheduleBlockScheduler::tryCandidateLatency(SIBlockSchedCandidate &Cand,
                                                   SIBlockSchedCandidate &TryCand) {
  if (!Cand.isValid()) {
    TryCand.Reason = NodeOrder;
    return true;
  }
 
  // Try to hide high latencies.
  if (SISched::tryLess(TryCand.LastPosHighLatParentScheduled,
                 Cand.LastPosHighLatParentScheduled, TryCand, Cand, Latency))
    return true;
  // Schedule high latencies early so you can hide them better.
  if (SISched::tryGreater(TryCand.IsHighLatency, Cand.IsHighLatency,
                          TryCand, Cand, Latency))
    return true;
  if (TryCand.IsHighLatency && SISched::tryGreater(TryCand.Height, Cand.Height,
                                                   TryCand, Cand, Depth))
    return true;
  if (SISched::tryGreater(TryCand.NumHighLatencySuccessors,
                          Cand.NumHighLatencySuccessors,
                          TryCand, Cand, Successor))
    return true;
  return false;
}
 
bool SIScheduleBlockScheduler::tryCandidateRegUsage(SIBlockSchedCandidate &Cand,
                                                    SIBlockSchedCandidate &TryCand) {
  if (!Cand.isValid()) {
    TryCand.Reason = NodeOrder;
    return true;
  }
 
  if (SISched::tryLess(TryCand.VGPRUsageDiff > 0, Cand.VGPRUsageDiff > 0,
                       TryCand, Cand, RegUsage))
    return true;
  if (SISched::tryGreater(TryCand.NumSuccessors > 0,
                          Cand.NumSuccessors > 0,
                          TryCand, Cand, Successor))
    return true;
  if (SISched::tryGreater(TryCand.Height, Cand.Height, TryCand, Cand, Depth))
    return true;
  if (SISched::tryLess(TryCand.VGPRUsageDiff, Cand.VGPRUsageDiff,
                       TryCand, Cand, RegUsage))
    return true;
  return false;
}
 
SIScheduleBlock *SIScheduleBlockScheduler::pickBlock() {
  SIBlockSchedCandidate Cand;
  std::vector<SIScheduleBlock*>::iterator Best;
  SIScheduleBlock *Block;
  if (ReadyBlocks.empty())
    return nullptr;
 
  DAG->fillVgprSgprCost(LiveRegs.begin(), LiveRegs.end(),
                        VregCurrentUsage, SregCurrentUsage);
  if (VregCurrentUsage > maxVregUsage)
    maxVregUsage = VregCurrentUsage;
  if (SregCurrentUsage > maxSregUsage)
    maxSregUsage = SregCurrentUsage;
  LLVM_DEBUG({
    dbgs() << "Picking New Blocks\n";
    dbgs() << "Available: ";
    for (SIScheduleBlock *Block : ReadyBlocks)
      dbgs() << Block->getID() << ' ';
    dbgs() << "\nCurrent Live:\n";
    for (Register Reg : LiveRegs)
      dbgs() << printReg(Reg, DAG->getTRI()) << ' ';
    dbgs() << '\n';
    dbgs() << "Current VGPRs: " << VregCurrentUsage << '\n';
    dbgs() << "Current SGPRs: " << SregCurrentUsage << '\n';
  });
 
  Cand.Block = nullptr;
  for (std::vector<SIScheduleBlock*>::iterator I = ReadyBlocks.begin(),
       E = ReadyBlocks.end(); I != E; ++I) {
    SIBlockSchedCandidate TryCand;
    TryCand.Block = *I;
    TryCand.IsHighLatency = TryCand.Block->isHighLatencyBlock();
    TryCand.VGPRUsageDiff =
      checkRegUsageImpact(TryCand.Block->getInRegs(),
          TryCand.Block->getOutRegs())[AMDGPU::RegisterPressureSets::VGPR_32];
    TryCand.NumSuccessors = TryCand.Block->getSuccs().size();
    TryCand.NumHighLatencySuccessors =
      TryCand.Block->getNumHighLatencySuccessors();
    TryCand.LastPosHighLatParentScheduled =
      (unsigned int) std::max<int> (0,
         LastPosHighLatencyParentScheduled[TryCand.Block->getID()] -
           LastPosWaitedHighLatency);
    TryCand.Height = TryCand.Block->Height;
    // Try not to increase VGPR usage too much, else we may spill.
    if (VregCurrentUsage > 120 ||
        Variant != SISchedulerBlockSchedulerVariant::BlockLatencyRegUsage) {
      if (!tryCandidateRegUsage(Cand, TryCand) &&
          Variant != SISchedulerBlockSchedulerVariant::BlockRegUsage)
        tryCandidateLatency(Cand, TryCand);
    } else {
      if (!tryCandidateLatency(Cand, TryCand))
        tryCandidateRegUsage(Cand, TryCand);
    }
    if (TryCand.Reason != NoCand) {
      Cand.setBest(TryCand);
      Best = I;
      LLVM_DEBUG(dbgs() << "Best Current Choice: " << Cand.Block->getID() << ' '
                        << getReasonStr(Cand.Reason) << '\n');
    }
  }
 
  LLVM_DEBUG(dbgs() << "Picking: " << Cand.Block->getID() << '\n';
             dbgs() << "Is a block with high latency instruction: "
                    << (Cand.IsHighLatency ? "yes\n" : "no\n");
             dbgs() << "Position of last high latency dependency: "
                    << Cand.LastPosHighLatParentScheduled << '\n';
             dbgs() << "VGPRUsageDiff: " << Cand.VGPRUsageDiff << '\n';
             dbgs() << '\n';);
 
  Block = Cand.Block;
  ReadyBlocks.erase(Best);
  return Block;
}
 
// Tracking of currently alive registers to determine VGPR Usage.
 
void SIScheduleBlockScheduler::addLiveRegs(std::set<VirtRegOrUnit> &Regs) {
  for (VirtRegOrUnit VRegOrUnit : Regs) {
    // For now only track virtual registers.
    if (!VRegOrUnit.isVirtualReg())
      continue;
    // If not already in the live set, then add it.
    (void)LiveRegs.insert(VRegOrUnit.asVirtualReg());
  }
}
 
void SIScheduleBlockScheduler::decreaseLiveRegs(SIScheduleBlock *Block,
                                                std::set<Register> &Regs) {
  for (Register Reg : Regs) {
    // For now only track virtual registers.
    std::set<Register>::iterator Pos = LiveRegs.find(Reg);
    assert (Pos != LiveRegs.end() && // Reg must be live.
               LiveRegsConsumers.find(Reg) != LiveRegsConsumers.end() &&
               LiveRegsConsumers[Reg] >= 1);
    --LiveRegsConsumers[Reg];
    if (LiveRegsConsumers[Reg] == 0)
      LiveRegs.erase(Pos);
  }
}
 
void SIScheduleBlockScheduler::releaseBlockSuccs(SIScheduleBlock *Parent) {
  for (const auto &Block : Parent->getSuccs()) {
    if (--BlockNumPredsLeft[Block.first->getID()] == 0)
      ReadyBlocks.push_back(Block.first);
 
    if (Parent->isHighLatencyBlock() &&
        Block.second == SIScheduleBlockLinkKind::Data)
      LastPosHighLatencyParentScheduled[Block.first->getID()] = NumBlockScheduled;
  }
}
 
void SIScheduleBlockScheduler::blockScheduled(SIScheduleBlock *Block) {
  decreaseLiveRegs(Block, Block->getInRegs());
  LiveRegs.insert(Block->getOutRegs().begin(), Block->getOutRegs().end());
  releaseBlockSuccs(Block);
  for (const auto &RegP : LiveOutRegsNumUsages[Block->getID()]) {
    // We produce this register, thus it must not be previously alive.
    assert(LiveRegsConsumers.find(RegP.first) == LiveRegsConsumers.end() ||
           LiveRegsConsumers[RegP.first] == 0);
    LiveRegsConsumers[RegP.first] += RegP.second;
  }
  if (LastPosHighLatencyParentScheduled[Block->getID()] >
        (unsigned)LastPosWaitedHighLatency)
    LastPosWaitedHighLatency =
      LastPosHighLatencyParentScheduled[Block->getID()];
  ++NumBlockScheduled;
}
 
std::vector<int>
SIScheduleBlockScheduler::checkRegUsageImpact(std::set<Register> &InRegs,
                                              std::set<Register> &OutRegs) {
  std::vector<int> DiffSetPressure;
  DiffSetPressure.assign(DAG->getTRI()->getNumRegPressureSets(), 0);
 
  for (Register Reg : InRegs) {
    // For now only track virtual registers.
    if (!Reg.isVirtual())
      continue;
    if (LiveRegsConsumers[Reg] > 1)
      continue;
    PSetIterator PSetI = DAG->getMRI()->getPressureSets(VirtRegOrUnit(Reg));
    for (; PSetI.isValid(); ++PSetI) {
      DiffSetPressure[*PSetI] -= PSetI.getWeight();
    }
  }
 
  for (Register Reg : OutRegs) {
    // For now only track virtual registers.
    if (!Reg.isVirtual())
      continue;
    PSetIterator PSetI = DAG->getMRI()->getPressureSets(VirtRegOrUnit(Reg));
    for (; PSetI.isValid(); ++PSetI) {
      DiffSetPressure[*PSetI] += PSetI.getWeight();
    }
  }
 
  return DiffSetPressure;
}
 
// SIScheduler //
 
struct SIScheduleBlockResult
SIScheduler::scheduleVariant(SISchedulerBlockCreatorVariant BlockVariant,
                             SISchedulerBlockSchedulerVariant ScheduleVariant) {
  SIScheduleBlocks Blocks = BlockCreator.getBlocks(BlockVariant);
  SIScheduleBlockScheduler Scheduler(DAG, ScheduleVariant, Blocks);
  std::vector<SIScheduleBlock*> ScheduledBlocks;
  struct SIScheduleBlockResult Res;
 
  ScheduledBlocks = Scheduler.getBlocks();
 
  for (SIScheduleBlock *Block : ScheduledBlocks) {
    std::vector<SUnit*> SUs = Block->getScheduledUnits();
 
    for (SUnit* SU : SUs)
      Res.SUs.push_back(SU->NodeNum);
  }
 
  Res.MaxSGPRUsage = Scheduler.getSGPRUsage();
  Res.MaxVGPRUsage = Scheduler.getVGPRUsage();
  return Res;
}
 
// SIScheduleDAGMI //
 
SIScheduleDAGMI::SIScheduleDAGMI(MachineSchedContext *C) :
  ScheduleDAGMILive(C, std::make_unique<GenericScheduler>(C)) {
  SITII = static_cast<const SIInstrInfo*>(TII);
  SITRI = static_cast<const SIRegisterInfo*>(TRI);
}
 
SIScheduleDAGMI::~SIScheduleDAGMI() = default;
 
// Code adapted from scheduleDAG.cpp
// Does a topological sort over the SUs.
// Both TopDown and BottomUp
void SIScheduleDAGMI::topologicalSort() {
  Topo.InitDAGTopologicalSorting();
 
  TopDownIndex2SU = std::vector<int>(Topo.begin(), Topo.end());
  BottomUpIndex2SU = std::vector<int>(Topo.rbegin(), Topo.rend());
}
 
// Move low latencies further from their user without
// increasing SGPR usage (in general)
// This is to be replaced by a better pass that would
// take into account SGPR usage (based on VGPR Usage
// and the corresponding wavefront count), that would
// try to merge groups of loads if it make sense, etc
void SIScheduleDAGMI::moveLowLatencies() {
   unsigned DAGSize = SUnits.size();
   int LastLowLatencyUser = -1;
   int LastLowLatencyPos = -1;
 
   for (unsigned i = 0, e = ScheduledSUnits.size(); i != e; ++i) {
    SUnit *SU = &SUnits[ScheduledSUnits[i]];
    bool IsLowLatencyUser = false;
    unsigned MinPos = 0;
 
    for (SDep& PredDep : SU->Preds) {
      SUnit *Pred = PredDep.getSUnit();
      if (SITII->isLowLatencyInstruction(*Pred->getInstr())) {
        IsLowLatencyUser = true;
      }
      if (Pred->NodeNum >= DAGSize)
        continue;
      unsigned PredPos = ScheduledSUnitsInv[Pred->NodeNum];
      if (PredPos >= MinPos)
        MinPos = PredPos + 1;
    }
 
    if (SITII->isLowLatencyInstruction(*SU->getInstr())) {
      unsigned BestPos = LastLowLatencyUser + 1;
      if ((int)BestPos <= LastLowLatencyPos)
        BestPos = LastLowLatencyPos + 1;
      if (BestPos < MinPos)
        BestPos = MinPos;
      if (BestPos < i) {
        for (unsigned u = i; u > BestPos; --u) {
          ++ScheduledSUnitsInv[ScheduledSUnits[u-1]];
          ScheduledSUnits[u] = ScheduledSUnits[u-1];
        }
        ScheduledSUnits[BestPos] = SU->NodeNum;
        ScheduledSUnitsInv[SU->NodeNum] = BestPos;
      }
      LastLowLatencyPos = BestPos;
      if (IsLowLatencyUser)
        LastLowLatencyUser = BestPos;
    } else if (IsLowLatencyUser) {
      LastLowLatencyUser = i;
    // Moves COPY instructions on which depends
    // the low latency instructions too.
    } else if (SU->getInstr()->getOpcode() == AMDGPU::COPY) {
      bool CopyForLowLat = false;
      for (SDep& SuccDep : SU->Succs) {
        SUnit *Succ = SuccDep.getSUnit();
        if (SuccDep.isWeak() || Succ->NodeNum >= DAGSize)
          continue;
        if (SITII->isLowLatencyInstruction(*Succ->getInstr())) {
          CopyForLowLat = true;
        }
      }
      if (!CopyForLowLat)
        continue;
      if (MinPos < i) {
        for (unsigned u = i; u > MinPos; --u) {
          ++ScheduledSUnitsInv[ScheduledSUnits[u-1]];
          ScheduledSUnits[u] = ScheduledSUnits[u-1];
        }
        ScheduledSUnits[MinPos] = SU->NodeNum;
        ScheduledSUnitsInv[SU->NodeNum] = MinPos;
      }
    }
  }
}
 
void SIScheduleDAGMI::restoreSULinksLeft() {
  for (unsigned i = 0, e = SUnits.size(); i != e; ++i) {
    SUnits[i].isScheduled = false;
    SUnits[i].WeakPredsLeft = SUnitsLinksBackup[i].WeakPredsLeft;
    SUnits[i].NumPredsLeft = SUnitsLinksBackup[i].NumPredsLeft;
    SUnits[i].WeakSuccsLeft = SUnitsLinksBackup[i].WeakSuccsLeft;
    SUnits[i].NumSuccsLeft = SUnitsLinksBackup[i].NumSuccsLeft;
  }
}
 
// Return the Vgpr and Sgpr usage corresponding to some virtual registers.
template<typename _Iterator> void
SIScheduleDAGMI::fillVgprSgprCost(_Iterator First, _Iterator End,
                                  unsigned &VgprUsage, unsigned &SgprUsage) {
  VgprUsage = 0;
  SgprUsage = 0;
  for (_Iterator RegI = First; RegI != End; ++RegI) {
    Register Reg = *RegI;
    // For now only track virtual registers
    if (!Reg.isVirtual())
      continue;
    PSetIterator PSetI = MRI.getPressureSets(VirtRegOrUnit(Reg));
    for (; PSetI.isValid(); ++PSetI) {
      if (*PSetI == AMDGPU::RegisterPressureSets::VGPR_32)
        VgprUsage += PSetI.getWeight();
      else if (*PSetI == AMDGPU::RegisterPressureSets::SReg_32)
        SgprUsage += PSetI.getWeight();
    }
  }
}
 
void SIScheduleDAGMI::schedule()
{
  SmallVector<SUnit*, 8> TopRoots, BotRoots;
  SIScheduleBlockResult Best, Temp;
  LLVM_DEBUG(dbgs() << "Preparing Scheduling\n");
 
  buildDAGWithRegPressure();
  postProcessDAG();
 
  LLVM_DEBUG(dump());
  if (PrintDAGs)
    dump();
  if (ViewMISchedDAGs)
    viewGraph();
 
  topologicalSort();
  findRootsAndBiasEdges(TopRoots, BotRoots);
  // We reuse several ScheduleDAGMI and ScheduleDAGMILive
  // functions, but to make them happy we must initialize
  // the default Scheduler implementation (even if we do not
  // run it)
  SchedImpl->initialize(this);
  initQueues(TopRoots, BotRoots);
 
  // Fill some stats to help scheduling.
 
  SUnitsLinksBackup = SUnits;
  IsLowLatencySU.clear();
  LowLatencyOffset.clear();
  IsHighLatencySU.clear();
 
  IsLowLatencySU.resize(SUnits.size(), 0);
  LowLatencyOffset.resize(SUnits.size(), 0);
  IsHighLatencySU.resize(SUnits.size(), 0);
 
  for (unsigned i = 0, e = (unsigned)SUnits.size(); i != e; ++i) {
    SUnit *SU = &SUnits[i];
    const MachineOperand *BaseLatOp;
    int64_t OffLatReg;
    if (SITII->isLowLatencyInstruction(*SU->getInstr())) {
      IsLowLatencySU[i] = 1;
      bool OffsetIsScalable;
      if (SITII->getMemOperandWithOffset(*SU->getInstr(), BaseLatOp, OffLatReg,
                                         OffsetIsScalable, TRI))
        LowLatencyOffset[i] = OffLatReg;
    } else if (SITII->isHighLatencyDef(SU->getInstr()->getOpcode()))
      IsHighLatencySU[i] = 1;
  }
 
  SIScheduler Scheduler(this);
  Best = Scheduler.scheduleVariant(SISchedulerBlockCreatorVariant::LatenciesAlone,
                                   SISchedulerBlockSchedulerVariant::BlockLatencyRegUsage);
 
  // if VGPR usage is extremely high, try other good performing variants
  // which could lead to lower VGPR usage
  if (Best.MaxVGPRUsage > 180) {
    static const std::pair<SISchedulerBlockCreatorVariant,
                           SISchedulerBlockSchedulerVariant>
        Variants[] = {
      { LatenciesAlone, BlockRegUsageLatency },
//      { LatenciesAlone, BlockRegUsage },
      { LatenciesGrouped, BlockLatencyRegUsage },
//      { LatenciesGrouped, BlockRegUsageLatency },
//      { LatenciesGrouped, BlockRegUsage },
      { LatenciesAlonePlusConsecutive, BlockLatencyRegUsage },
//      { LatenciesAlonePlusConsecutive, BlockRegUsageLatency },
//      { LatenciesAlonePlusConsecutive, BlockRegUsage }
    };
    for (std::pair<SISchedulerBlockCreatorVariant, SISchedulerBlockSchedulerVariant> v : Variants) {
      Temp = Scheduler.scheduleVariant(v.first, v.second);
      if (Temp.MaxVGPRUsage < Best.MaxVGPRUsage)
        Best = Temp;
    }
  }
  // if VGPR usage is still extremely high, we may spill. Try other variants
  // which are less performing, but that could lead to lower VGPR usage.
  if (Best.MaxVGPRUsage > 200) {
    static const std::pair<SISchedulerBlockCreatorVariant,
                           SISchedulerBlockSchedulerVariant>
        Variants[] = {
//      { LatenciesAlone, BlockRegUsageLatency },
      { LatenciesAlone, BlockRegUsage },
//      { LatenciesGrouped, BlockLatencyRegUsage },
      { LatenciesGrouped, BlockRegUsageLatency },
      { LatenciesGrouped, BlockRegUsage },
//      { LatenciesAlonePlusConsecutive, BlockLatencyRegUsage },
      { LatenciesAlonePlusConsecutive, BlockRegUsageLatency },
      { LatenciesAlonePlusConsecutive, BlockRegUsage }
    };
    for (std::pair<SISchedulerBlockCreatorVariant, SISchedulerBlockSchedulerVariant> v : Variants) {
      Temp = Scheduler.scheduleVariant(v.first, v.second);
      if (Temp.MaxVGPRUsage < Best.MaxVGPRUsage)
        Best = Temp;
    }
  }
 
  ScheduledSUnits = Best.SUs;
  ScheduledSUnitsInv.resize(SUnits.size());
 
  for (unsigned i = 0, e = (unsigned)SUnits.size(); i != e; ++i) {
    ScheduledSUnitsInv[ScheduledSUnits[i]] = i;
  }
 
  moveLowLatencies();
 
  // Tell the outside world about the result of the scheduling.
 
  assert(TopRPTracker.getPos() == RegionBegin && "bad initial Top tracker");
  TopRPTracker.setPos(CurrentTop);
 
  for (unsigned I : ScheduledSUnits) {
    SUnit *SU = &SUnits[I];
 
    scheduleMI(SU, true);
 
    LLVM_DEBUG(dbgs() << "Scheduling SU(" << SU->NodeNum << ") "
                      << *SU->getInstr());
  }
 
  assert(CurrentTop == CurrentBottom && "Nonempty unscheduled zone.");
 
  placeDebugValues();
 
  LLVM_DEBUG({
    dbgs() << "*** Final schedule for "
           << printMBBReference(*begin()->getParent()) << " ***\n";
    dumpSchedule();
    dbgs() << '\n';
  });
}