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llvm-project/llvm/lib/CodeGen/ExecutionDepsFix.cpp

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//===- ExecutionDepsFix.cpp - Fix execution dependecy issues ----*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains the execution dependency fix pass.
//
// Some X86 SSE instructions like mov, and, or, xor are available in different
// variants for different operand types. These variant instructions are
// equivalent, but on Nehalem and newer cpus there is extra latency
// transferring data between integer and floating point domains. ARM cores
// have similar issues when they are configured with both VFP and NEON
// pipelines.
//
// This pass changes the variant instructions to minimize domain crossings.
//
//===----------------------------------------------------------------------===//
#include "llvm/CodeGen/Passes.h"
#include "llvm/ADT/PostOrderIterator.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/CodeGen/LivePhysRegs.h"
#include "llvm/CodeGen/MachineFunctionPass.h"
#include "llvm/CodeGen/MachineRegisterInfo.h"
#include "llvm/CodeGen/RegisterClassInfo.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/Target/TargetInstrInfo.h"
#include "llvm/Target/TargetSubtargetInfo.h"
using namespace llvm;
#define DEBUG_TYPE "execution-fix"
/// A DomainValue is a bit like LiveIntervals' ValNo, but it also keeps track
/// of execution domains.
///
/// An open DomainValue represents a set of instructions that can still switch
/// execution domain. Multiple registers may refer to the same open
/// DomainValue - they will eventually be collapsed to the same execution
/// domain.
///
/// A collapsed DomainValue represents a single register that has been forced
/// into one of more execution domains. There is a separate collapsed
/// DomainValue for each register, but it may contain multiple execution
/// domains. A register value is initially created in a single execution
/// domain, but if we were forced to pay the penalty of a domain crossing, we
/// keep track of the fact that the register is now available in multiple
/// domains.
namespace {
struct DomainValue {
// Basic reference counting.
unsigned Refs;
// Bitmask of available domains. For an open DomainValue, it is the still
// possible domains for collapsing. For a collapsed DomainValue it is the
// domains where the register is available for free.
unsigned AvailableDomains;
// Pointer to the next DomainValue in a chain. When two DomainValues are
// merged, Victim.Next is set to point to Victor, so old DomainValue
// references can be updated by following the chain.
DomainValue *Next;
// Twiddleable instructions using or defining these registers.
SmallVector<MachineInstr*, 8> Instrs;
// A collapsed DomainValue has no instructions to twiddle - it simply keeps
// track of the domains where the registers are already available.
bool isCollapsed() const { return Instrs.empty(); }
// Is domain available?
bool hasDomain(unsigned domain) const {
assert(domain <
static_cast<unsigned>(std::numeric_limits<unsigned>::digits) &&
"undefined behavior");
return AvailableDomains & (1u << domain);
}
// Mark domain as available.
void addDomain(unsigned domain) {
AvailableDomains |= 1u << domain;
}
// Restrict to a single domain available.
void setSingleDomain(unsigned domain) {
AvailableDomains = 1u << domain;
}
// Return bitmask of domains that are available and in mask.
unsigned getCommonDomains(unsigned mask) const {
return AvailableDomains & mask;
}
// First domain available.
unsigned getFirstDomain() const {
return countTrailingZeros(AvailableDomains);
}
DomainValue() : Refs(0) { clear(); }
// Clear this DomainValue and point to next which has all its data.
void clear() {
AvailableDomains = 0;
Next = nullptr;
Instrs.clear();
}
};
}
namespace {
/// Information about a live register.
struct LiveReg {
/// Value currently in this register, or NULL when no value is being tracked.
/// This counts as a DomainValue reference.
DomainValue *Value;
/// Instruction that defined this register, relative to the beginning of the
/// current basic block. When a LiveReg is used to represent a live-out
/// register, this value is relative to the end of the basic block, so it
/// will be a negative number.
int Def;
};
} // anonymous namespace
namespace {
class ExeDepsFix : public MachineFunctionPass {
static char ID;
SpecificBumpPtrAllocator<DomainValue> Allocator;
SmallVector<DomainValue*,16> Avail;
const TargetRegisterClass *const RC;
MachineFunction *MF;
const TargetInstrInfo *TII;
const TargetRegisterInfo *TRI;
RegisterClassInfo RegClassInfo;
std::vector<SmallVector<int, 1>> AliasMap;
const unsigned NumRegs;
LiveReg *LiveRegs;
struct MBBInfo {
// Keeps clearance and domain information for all registers. Note that this
// is different from the usual definition notion of liveness. The CPU
// doesn't care whether or not we consider a register killed.
LiveReg *OutRegs;
// Whether we have gotten to this block in primary processing yet.
bool PrimaryCompleted;
// The number of predecessors for which primary processing has completed
unsigned IncomingProcessed;
// The value of `IncomingProcessed` at the start of primary processing
unsigned PrimaryIncoming;
// The number of predecessors for which all processing steps are done.
unsigned IncomingCompleted;
MBBInfo()
: OutRegs(nullptr), PrimaryCompleted(false), IncomingProcessed(0),
PrimaryIncoming(0), IncomingCompleted(0) {}
};
typedef DenseMap<MachineBasicBlock *, MBBInfo> MBBInfoMap;
MBBInfoMap MBBInfos;
/// List of undefined register reads in this block in forward order.
std::vector<std::pair<MachineInstr*, unsigned> > UndefReads;
/// Storage for register unit liveness.
LivePhysRegs LiveRegSet;
/// Current instruction number.
/// The first instruction in each basic block is 0.
int CurInstr;
public:
ExeDepsFix(const TargetRegisterClass *rc)
: MachineFunctionPass(ID), RC(rc), NumRegs(RC->getNumRegs()) {}
void getAnalysisUsage(AnalysisUsage &AU) const override {
AU.setPreservesAll();
MachineFunctionPass::getAnalysisUsage(AU);
}
bool runOnMachineFunction(MachineFunction &MF) override;
MachineFunctionProperties getRequiredProperties() const override {
return MachineFunctionProperties().set(
MachineFunctionProperties::Property::NoVRegs);
}
StringRef getPassName() const override { return "Execution dependency fix"; }
private:
iterator_range<SmallVectorImpl<int>::const_iterator>
regIndices(unsigned Reg) const;
// DomainValue allocation.
DomainValue *alloc(int domain = -1);
DomainValue *retain(DomainValue *DV) {
if (DV) ++DV->Refs;
return DV;
}
void release(DomainValue*);
DomainValue *resolve(DomainValue*&);
// LiveRegs manipulations.
void setLiveReg(int rx, DomainValue *DV);
void kill(int rx);
void force(int rx, unsigned domain);
void collapse(DomainValue *dv, unsigned domain);
bool merge(DomainValue *A, DomainValue *B);
void enterBasicBlock(MachineBasicBlock*);
void leaveBasicBlock(MachineBasicBlock*);
bool isBlockDone(MachineBasicBlock *);
void processBasicBlock(MachineBasicBlock *MBB, bool PrimaryPass);
void updateSuccessors(MachineBasicBlock *MBB, bool PrimaryPass);
bool visitInstr(MachineInstr *);
void processDefs(MachineInstr *, bool breakDependency, bool Kill);
void visitSoftInstr(MachineInstr*, unsigned mask);
void visitHardInstr(MachineInstr*, unsigned domain);
void pickBestRegisterForUndef(MachineInstr *MI, unsigned OpIdx,
unsigned Pref);
bool shouldBreakDependence(MachineInstr*, unsigned OpIdx, unsigned Pref);
void processUndefReads(MachineBasicBlock*);
};
}
char ExeDepsFix::ID = 0;
/// Translate TRI register number to a list of indices into our smaller tables
/// of interesting registers.
iterator_range<SmallVectorImpl<int>::const_iterator>
ExeDepsFix::regIndices(unsigned Reg) const {
assert(Reg < AliasMap.size() && "Invalid register");
const auto &Entry = AliasMap[Reg];
return make_range(Entry.begin(), Entry.end());
}
DomainValue *ExeDepsFix::alloc(int domain) {
DomainValue *dv = Avail.empty() ?
new(Allocator.Allocate()) DomainValue :
Avail.pop_back_val();
if (domain >= 0)
dv->addDomain(domain);
assert(dv->Refs == 0 && "Reference count wasn't cleared");
assert(!dv->Next && "Chained DomainValue shouldn't have been recycled");
return dv;
}
/// Release a reference to DV. When the last reference is released,
/// collapse if needed.
void ExeDepsFix::release(DomainValue *DV) {
while (DV) {
assert(DV->Refs && "Bad DomainValue");
if (--DV->Refs)
return;
// There are no more DV references. Collapse any contained instructions.
if (DV->AvailableDomains && !DV->isCollapsed())
collapse(DV, DV->getFirstDomain());
DomainValue *Next = DV->Next;
DV->clear();
Avail.push_back(DV);
// Also release the next DomainValue in the chain.
DV = Next;
}
}
/// Follow the chain of dead DomainValues until a live DomainValue is reached.
/// Update the referenced pointer when necessary.
DomainValue *ExeDepsFix::resolve(DomainValue *&DVRef) {
DomainValue *DV = DVRef;
if (!DV || !DV->Next)
return DV;
// DV has a chain. Find the end.
do DV = DV->Next;
while (DV->Next);
// Update DVRef to point to DV.
retain(DV);
release(DVRef);
DVRef = DV;
return DV;
}
/// Set LiveRegs[rx] = dv, updating reference counts.
void ExeDepsFix::setLiveReg(int rx, DomainValue *dv) {
assert(unsigned(rx) < NumRegs && "Invalid index");
assert(LiveRegs && "Must enter basic block first.");
if (LiveRegs[rx].Value == dv)
return;
if (LiveRegs[rx].Value)
release(LiveRegs[rx].Value);
LiveRegs[rx].Value = retain(dv);
}
// Kill register rx, recycle or collapse any DomainValue.
void ExeDepsFix::kill(int rx) {
assert(unsigned(rx) < NumRegs && "Invalid index");
assert(LiveRegs && "Must enter basic block first.");
if (!LiveRegs[rx].Value)
return;
release(LiveRegs[rx].Value);
LiveRegs[rx].Value = nullptr;
}
/// Force register rx into domain.
void ExeDepsFix::force(int rx, unsigned domain) {
assert(unsigned(rx) < NumRegs && "Invalid index");
assert(LiveRegs && "Must enter basic block first.");
if (DomainValue *dv = LiveRegs[rx].Value) {
if (dv->isCollapsed())
dv->addDomain(domain);
else if (dv->hasDomain(domain))
collapse(dv, domain);
else {
// This is an incompatible open DomainValue. Collapse it to whatever and
// force the new value into domain. This costs a domain crossing.
collapse(dv, dv->getFirstDomain());
assert(LiveRegs[rx].Value && "Not live after collapse?");
LiveRegs[rx].Value->addDomain(domain);
}
} else {
// Set up basic collapsed DomainValue.
setLiveReg(rx, alloc(domain));
}
}
/// Collapse open DomainValue into given domain. If there are multiple
/// registers using dv, they each get a unique collapsed DomainValue.
void ExeDepsFix::collapse(DomainValue *dv, unsigned domain) {
assert(dv->hasDomain(domain) && "Cannot collapse");
// Collapse all the instructions.
while (!dv->Instrs.empty())
TII->setExecutionDomain(*dv->Instrs.pop_back_val(), domain);
dv->setSingleDomain(domain);
// If there are multiple users, give them new, unique DomainValues.
if (LiveRegs && dv->Refs > 1)
for (unsigned rx = 0; rx != NumRegs; ++rx)
if (LiveRegs[rx].Value == dv)
setLiveReg(rx, alloc(domain));
}
/// All instructions and registers in B are moved to A, and B is released.
bool ExeDepsFix::merge(DomainValue *A, DomainValue *B) {
assert(!A->isCollapsed() && "Cannot merge into collapsed");
assert(!B->isCollapsed() && "Cannot merge from collapsed");
if (A == B)
return true;
// Restrict to the domains that A and B have in common.
unsigned common = A->getCommonDomains(B->AvailableDomains);
if (!common)
return false;
A->AvailableDomains = common;
A->Instrs.append(B->Instrs.begin(), B->Instrs.end());
// Clear the old DomainValue so we won't try to swizzle instructions twice.
B->clear();
// All uses of B are referred to A.
B->Next = retain(A);
for (unsigned rx = 0; rx != NumRegs; ++rx) {
assert(LiveRegs && "no space allocated for live registers");
if (LiveRegs[rx].Value == B)
setLiveReg(rx, A);
}
return true;
}
/// Set up LiveRegs by merging predecessor live-out values.
void ExeDepsFix::enterBasicBlock(MachineBasicBlock *MBB) {
// Reset instruction counter in each basic block.
CurInstr = 0;
// Set up UndefReads to track undefined register reads.
UndefReads.clear();
LiveRegSet.clear();
// Set up LiveRegs to represent registers entering MBB.
if (!LiveRegs)
LiveRegs = new LiveReg[NumRegs];
// Default values are 'nothing happened a long time ago'.
for (unsigned rx = 0; rx != NumRegs; ++rx) {
LiveRegs[rx].Value = nullptr;
LiveRegs[rx].Def = -(1 << 20);
}
// This is the entry block.
if (MBB->pred_empty()) {
for (const auto &LI : MBB->liveins()) {
for (int rx : regIndices(LI.PhysReg)) {
// Treat function live-ins as if they were defined just before the first
// instruction. Usually, function arguments are set up immediately
// before the call.
LiveRegs[rx].Def = -1;
}
}
DEBUG(dbgs() << "BB#" << MBB->getNumber() << ": entry\n");
return;
}
// Try to coalesce live-out registers from predecessors.
for (MachineBasicBlock::const_pred_iterator pi = MBB->pred_begin(),
pe = MBB->pred_end(); pi != pe; ++pi) {
auto fi = MBBInfos.find(*pi);
assert(fi != MBBInfos.end() &&
"Should have pre-allocated MBBInfos for all MBBs");
LiveReg *Incoming = fi->second.OutRegs;
// Incoming is null if this is a backedge from a BB
// we haven't processed yet
if (Incoming == nullptr) {
continue;
}
for (unsigned rx = 0; rx != NumRegs; ++rx) {
// Use the most recent predecessor def for each register.
LiveRegs[rx].Def = std::max(LiveRegs[rx].Def, Incoming[rx].Def);
DomainValue *pdv = resolve(Incoming[rx].Value);
if (!pdv)
continue;
if (!LiveRegs[rx].Value) {
setLiveReg(rx, pdv);
continue;
}
// We have a live DomainValue from more than one predecessor.
if (LiveRegs[rx].Value->isCollapsed()) {
// We are already collapsed, but predecessor is not. Force it.
unsigned Domain = LiveRegs[rx].Value->getFirstDomain();
if (!pdv->isCollapsed() && pdv->hasDomain(Domain))
collapse(pdv, Domain);
continue;
}
// Currently open, merge in predecessor.
if (!pdv->isCollapsed())
merge(LiveRegs[rx].Value, pdv);
else
force(rx, pdv->getFirstDomain());
}
}
DEBUG(
dbgs() << "BB#" << MBB->getNumber()
<< (!isBlockDone(MBB) ? ": incomplete\n" : ": all preds known\n"));
}
void ExeDepsFix::leaveBasicBlock(MachineBasicBlock *MBB) {
assert(LiveRegs && "Must enter basic block first.");
LiveReg *OldOutRegs = MBBInfos[MBB].OutRegs;
// Save register clearances at end of MBB - used by enterBasicBlock().
MBBInfos[MBB].OutRegs = LiveRegs;
// While processing the basic block, we kept `Def` relative to the start
// of the basic block for convenience. However, future use of this information
// only cares about the clearance from the end of the block, so adjust
// everything to be relative to the end of the basic block.
for (unsigned i = 0, e = NumRegs; i != e; ++i)
LiveRegs[i].Def -= CurInstr;
if (OldOutRegs) {
// This must be the second pass.
// Release all the DomainValues instead of keeping them.
for (unsigned i = 0, e = NumRegs; i != e; ++i)
release(OldOutRegs[i].Value);
delete[] OldOutRegs;
}
LiveRegs = nullptr;
}
bool ExeDepsFix::visitInstr(MachineInstr *MI) {
// Update instructions with explicit execution domains.
std::pair<uint16_t, uint16_t> DomP = TII->getExecutionDomain(*MI);
if (DomP.first) {
if (DomP.second)
visitSoftInstr(MI, DomP.second);
else
visitHardInstr(MI, DomP.first);
}
return !DomP.first;
}
/// \brief Helps avoid false dependencies on undef registers by updating the
/// machine instructions' undef operand to use a register that the instruction
/// is truly dependent on, or use a register with clearance higher than Pref.
void ExeDepsFix::pickBestRegisterForUndef(MachineInstr *MI, unsigned OpIdx,
unsigned Pref) {
MachineOperand &MO = MI->getOperand(OpIdx);
assert(MO.isUndef() && "Expected undef machine operand");
unsigned OriginalReg = MO.getReg();
// Update only undef operands that are mapped to one register.
if (AliasMap[OriginalReg].size() != 1)
return;
// Get the undef operand's register class
const TargetRegisterClass *OpRC =
TII->getRegClass(MI->getDesc(), OpIdx, TRI, *MF);
// If the instruction has a true dependency, we can hide the false depdency
// behind it.
for (MachineOperand &CurrMO : MI->operands()) {
if (!CurrMO.isReg() || CurrMO.isDef() || CurrMO.isUndef() ||
!OpRC->contains(CurrMO.getReg()))
continue;
// We found a true dependency - replace the undef register with the true
// dependency.
MO.setReg(CurrMO.getReg());
return;
}
// Go over all registers in the register class and find the register with
// max clearance or clearance higher than Pref.
unsigned MaxClearance = 0;
unsigned MaxClearanceReg = OriginalReg;
ArrayRef<MCPhysReg> Order = RegClassInfo.getOrder(OpRC);
for (auto Reg : Order) {
assert(AliasMap[Reg].size() == 1 &&
"Reg is expected to be mapped to a single index");
int RCrx = *regIndices(Reg).begin();
unsigned Clearance = CurInstr - LiveRegs[RCrx].Def;
if (Clearance <= MaxClearance)
continue;
MaxClearance = Clearance;
MaxClearanceReg = Reg;
if (MaxClearance > Pref)
break;
}
// Update the operand if we found a register with better clearance.
if (MaxClearanceReg != OriginalReg)
MO.setReg(MaxClearanceReg);
}
/// \brief Return true to if it makes sense to break dependence on a partial def
/// or undef use.
bool ExeDepsFix::shouldBreakDependence(MachineInstr *MI, unsigned OpIdx,
unsigned Pref) {
unsigned reg = MI->getOperand(OpIdx).getReg();
for (int rx : regIndices(reg)) {
unsigned Clearance = CurInstr - LiveRegs[rx].Def;
DEBUG(dbgs() << "Clearance: " << Clearance << ", want " << Pref);
if (Pref > Clearance) {
DEBUG(dbgs() << ": Break dependency.\n");
continue;
}
DEBUG(dbgs() << ": OK .\n");
return false;
}
return true;
}
// Update def-ages for registers defined by MI.
// If Kill is set, also kill off DomainValues clobbered by the defs.
//
// Also break dependencies on partial defs and undef uses.
void ExeDepsFix::processDefs(MachineInstr *MI, bool breakDependency,
bool Kill) {
assert(!MI->isDebugValue() && "Won't process debug values");
// Break dependence on undef uses. Do this before updating LiveRegs below.
unsigned OpNum;
if (breakDependency) {
unsigned Pref = TII->getUndefRegClearance(*MI, OpNum, TRI);
if (Pref) {
pickBestRegisterForUndef(MI, OpNum, Pref);
if (shouldBreakDependence(MI, OpNum, Pref))
UndefReads.push_back(std::make_pair(MI, OpNum));
}
}
const MCInstrDesc &MCID = MI->getDesc();
for (unsigned i = 0,
e = MI->isVariadic() ? MI->getNumOperands() : MCID.getNumDefs();
i != e; ++i) {
MachineOperand &MO = MI->getOperand(i);
if (!MO.isReg())
continue;
if (MO.isUse())
continue;
for (int rx : regIndices(MO.getReg())) {
// This instruction explicitly defines rx.
DEBUG(dbgs() << TRI->getName(RC->getRegister(rx)) << ":\t" << CurInstr
<< '\t' << *MI);
if (breakDependency) {
// Check clearance before partial register updates.
// Call breakDependence before setting LiveRegs[rx].Def.
unsigned Pref = TII->getPartialRegUpdateClearance(*MI, i, TRI);
if (Pref && shouldBreakDependence(MI, i, Pref))
TII->breakPartialRegDependency(*MI, i, TRI);
}
// How many instructions since rx was last written?
LiveRegs[rx].Def = CurInstr;
// Kill off domains redefined by generic instructions.
if (Kill)
kill(rx);
}
}
++CurInstr;
}
/// \break Break false dependencies on undefined register reads.
///
/// Walk the block backward computing precise liveness. This is expensive, so we
/// only do it on demand. Note that the occurrence of undefined register reads
/// that should be broken is very rare, but when they occur we may have many in
/// a single block.
void ExeDepsFix::processUndefReads(MachineBasicBlock *MBB) {
if (UndefReads.empty())
return;
// Collect this block's live out register units.
LiveRegSet.init(*TRI);
// We do not need to care about pristine registers as they are just preserved
// but not actually used in the function.
LiveRegSet.addLiveOutsNoPristines(*MBB);
MachineInstr *UndefMI = UndefReads.back().first;
unsigned OpIdx = UndefReads.back().second;
for (MachineInstr &I : make_range(MBB->rbegin(), MBB->rend())) {
// Update liveness, including the current instruction's defs.
LiveRegSet.stepBackward(I);
if (UndefMI == &I) {
if (!LiveRegSet.contains(UndefMI->getOperand(OpIdx).getReg()))
TII->breakPartialRegDependency(*UndefMI, OpIdx, TRI);
UndefReads.pop_back();
if (UndefReads.empty())
return;
UndefMI = UndefReads.back().first;
OpIdx = UndefReads.back().second;
}
}
}
// A hard instruction only works in one domain. All input registers will be
// forced into that domain.
void ExeDepsFix::visitHardInstr(MachineInstr *mi, unsigned domain) {
// Collapse all uses.
for (unsigned i = mi->getDesc().getNumDefs(),
e = mi->getDesc().getNumOperands(); i != e; ++i) {
MachineOperand &mo = mi->getOperand(i);
if (!mo.isReg()) continue;
for (int rx : regIndices(mo.getReg())) {
force(rx, domain);
}
}
// Kill all defs and force them.
for (unsigned i = 0, e = mi->getDesc().getNumDefs(); i != e; ++i) {
MachineOperand &mo = mi->getOperand(i);
if (!mo.isReg()) continue;
for (int rx : regIndices(mo.getReg())) {
kill(rx);
force(rx, domain);
}
}
}
// A soft instruction can be changed to work in other domains given by mask.
void ExeDepsFix::visitSoftInstr(MachineInstr *mi, unsigned mask) {
// Bitmask of available domains for this instruction after taking collapsed
// operands into account.
unsigned available = mask;
// Scan the explicit use operands for incoming domains.
SmallVector<int, 4> used;
if (LiveRegs)
for (unsigned i = mi->getDesc().getNumDefs(),
e = mi->getDesc().getNumOperands(); i != e; ++i) {
MachineOperand &mo = mi->getOperand(i);
if (!mo.isReg()) continue;
for (int rx : regIndices(mo.getReg())) {
DomainValue *dv = LiveRegs[rx].Value;
if (dv == nullptr)
continue;
// Bitmask of domains that dv and available have in common.
unsigned common = dv->getCommonDomains(available);
// Is it possible to use this collapsed register for free?
if (dv->isCollapsed()) {
// Restrict available domains to the ones in common with the operand.
// If there are no common domains, we must pay the cross-domain
// penalty for this operand.
if (common) available = common;
} else if (common)
// Open DomainValue is compatible, save it for merging.
used.push_back(rx);
else
// Open DomainValue is not compatible with instruction. It is useless
// now.
kill(rx);
}
}
// If the collapsed operands force a single domain, propagate the collapse.
if (isPowerOf2_32(available)) {
unsigned domain = countTrailingZeros(available);
TII->setExecutionDomain(*mi, domain);
visitHardInstr(mi, domain);
return;
}
// Kill off any remaining uses that don't match available, and build a list of
// incoming DomainValues that we want to merge.
SmallVector<LiveReg, 4> Regs;
for (SmallVectorImpl<int>::iterator i=used.begin(), e=used.end(); i!=e; ++i) {
int rx = *i;
assert(LiveRegs && "no space allocated for live registers");
const LiveReg &LR = LiveRegs[rx];
// This useless DomainValue could have been missed above.
if (!LR.Value->getCommonDomains(available)) {
kill(rx);
continue;
}
// Sorted insertion.
bool Inserted = false;
for (SmallVectorImpl<LiveReg>::iterator i = Regs.begin(), e = Regs.end();
i != e && !Inserted; ++i) {
if (LR.Def < i->Def) {
Inserted = true;
Regs.insert(i, LR);
}
}
if (!Inserted)
Regs.push_back(LR);
}
// doms are now sorted in order of appearance. Try to merge them all, giving
// priority to the latest ones.
DomainValue *dv = nullptr;
while (!Regs.empty()) {
if (!dv) {
dv = Regs.pop_back_val().Value;
// Force the first dv to match the current instruction.
dv->AvailableDomains = dv->getCommonDomains(available);
assert(dv->AvailableDomains && "Domain should have been filtered");
continue;
}
DomainValue *Latest = Regs.pop_back_val().Value;
// Skip already merged values.
if (Latest == dv || Latest->Next)
continue;
if (merge(dv, Latest))
continue;
// If latest didn't merge, it is useless now. Kill all registers using it.
for (int i : used) {
assert(LiveRegs && "no space allocated for live registers");
if (LiveRegs[i].Value == Latest)
kill(i);
}
}
// dv is the DomainValue we are going to use for this instruction.
if (!dv) {
dv = alloc();
dv->AvailableDomains = available;
}
dv->Instrs.push_back(mi);
// Finally set all defs and non-collapsed uses to dv. We must iterate through
// all the operators, including imp-def ones.
for (MachineInstr::mop_iterator ii = mi->operands_begin(),
ee = mi->operands_end();
ii != ee; ++ii) {
MachineOperand &mo = *ii;
if (!mo.isReg()) continue;
for (int rx : regIndices(mo.getReg())) {
if (!LiveRegs[rx].Value || (mo.isDef() && LiveRegs[rx].Value != dv)) {
kill(rx);
setLiveReg(rx, dv);
}
}
}
}
void ExeDepsFix::processBasicBlock(MachineBasicBlock *MBB, bool PrimaryPass) {
enterBasicBlock(MBB);
// If this block is not done, it makes little sense to make any decisions
// based on clearance information. We need to make a second pass anyway,
// and by then we'll have better information, so we can avoid doing the work
// to try and break dependencies now.
bool breakDependency = isBlockDone(MBB);
for (MachineInstr &MI : *MBB) {
if (!MI.isDebugValue()) {
bool Kill = false;
if (PrimaryPass)
Kill = visitInstr(&MI);
processDefs(&MI, breakDependency, Kill);
}
}
if (breakDependency)
processUndefReads(MBB);
leaveBasicBlock(MBB);
}
bool ExeDepsFix::isBlockDone(MachineBasicBlock *MBB) {
return MBBInfos[MBB].PrimaryCompleted &&
MBBInfos[MBB].IncomingCompleted == MBBInfos[MBB].PrimaryIncoming &&
MBBInfos[MBB].IncomingProcessed == MBB->pred_size();
}
void ExeDepsFix::updateSuccessors(MachineBasicBlock *MBB, bool Primary) {
bool Done = isBlockDone(MBB);
for (auto *Succ : MBB->successors()) {
if (!isBlockDone(Succ)) {
if (Primary) {
MBBInfos[Succ].IncomingProcessed++;
}
if (Done) {
MBBInfos[Succ].IncomingCompleted++;
}
if (isBlockDone(Succ)) {
// Perform secondary processing for this successor. See the big comment
// in runOnMachineFunction, for an explanation of the iteration order.
processBasicBlock(Succ, false);
updateSuccessors(Succ, false);
}
}
}
}
bool ExeDepsFix::runOnMachineFunction(MachineFunction &mf) {
if (skipFunction(*mf.getFunction()))
return false;
MF = &mf;
TII = MF->getSubtarget().getInstrInfo();
TRI = MF->getSubtarget().getRegisterInfo();
RegClassInfo.runOnMachineFunction(mf);
LiveRegs = nullptr;
assert(NumRegs == RC->getNumRegs() && "Bad regclass");
DEBUG(dbgs() << "********** FIX EXECUTION DEPENDENCIES: "
<< TRI->getRegClassName(RC) << " **********\n");
// If no relevant registers are used in the function, we can skip it
// completely.
bool anyregs = false;
const MachineRegisterInfo &MRI = mf.getRegInfo();
for (unsigned Reg : *RC) {
if (MRI.isPhysRegUsed(Reg)) {
anyregs = true;
break;
}
}
if (!anyregs) return false;
// Initialize the AliasMap on the first use.
if (AliasMap.empty()) {
// Given a PhysReg, AliasMap[PhysReg] returns a list of indices into RC and
// therefore the LiveRegs array.
AliasMap.resize(TRI->getNumRegs());
for (unsigned i = 0, e = RC->getNumRegs(); i != e; ++i)
for (MCRegAliasIterator AI(RC->getRegister(i), TRI, true);
AI.isValid(); ++AI)
AliasMap[*AI].push_back(i);
}
// Initialize the MMBInfos
for (auto &MBB : mf) {
MBBInfo InitialInfo;
MBBInfos.insert(std::make_pair(&MBB, InitialInfo));
}
/*
* We want to visit every instruction in every basic block in order to update
* it's execution domain or break any false dependencies. However, for the
* dependency breaking, we need to know clearances from all predecessors
* (including any backedges). One way to do so would be to do two complete
* passes over all basic blocks/instructions, the first for recording
* clearances, the second to break the dependencies. However, for functions
* without backedges, or functions with a lot of straight-line code, and
* a small loop, that would be a lot of unnecessary work (since only the
* BBs that are part of the loop require two passes). As an example,
* consider the following loop.
*
*
* PH -> A -> B (xmm<Undef> -> xmm<Def>) -> C -> D -> EXIT
* ^ |
* +----------------------------------+
*
* The iteration order is as follows:
* Naive: PH A B C D A' B' C' D'
* Optimized: PH A B C A' B' C' D
*
* Note that we avoid processing D twice, because we can entirely process
* the predecessors before getting to D. We call a block that is ready
* for its second round of processing `done` (isBlockDone). Once we finish
* processing some block, we update the counters in MBBInfos and re-process
* any successors that are now done.
*/
MachineBasicBlock *Entry = &*MF->begin();
ReversePostOrderTraversal<MachineBasicBlock*> RPOT(Entry);
for (ReversePostOrderTraversal<MachineBasicBlock*>::rpo_iterator
MBBI = RPOT.begin(), MBBE = RPOT.end(); MBBI != MBBE; ++MBBI) {
MachineBasicBlock *MBB = *MBBI;
// N.B: IncomingProcessed and IncomingCompleted were already updated while
// processing this block's predecessors.
MBBInfos[MBB].PrimaryCompleted = true;
MBBInfos[MBB].PrimaryIncoming = MBBInfos[MBB].IncomingProcessed;
processBasicBlock(MBB, true);
updateSuccessors(MBB, true);
}
// We need to go through again and finalize any blocks that are not done yet.
// This is possible if blocks have dead predecessors, so we didn't visit them
// above.
for (ReversePostOrderTraversal<MachineBasicBlock *>::rpo_iterator
MBBI = RPOT.begin(),
MBBE = RPOT.end();
MBBI != MBBE; ++MBBI) {
MachineBasicBlock *MBB = *MBBI;
if (!isBlockDone(MBB)) {
processBasicBlock(MBB, false);
// Don't update successors here. We'll get to them anyway through this
// loop.
}
}
// Clear the LiveOuts vectors and collapse any remaining DomainValues.
for (ReversePostOrderTraversal<MachineBasicBlock*>::rpo_iterator
MBBI = RPOT.begin(), MBBE = RPOT.end(); MBBI != MBBE; ++MBBI) {
auto FI = MBBInfos.find(*MBBI);
if (FI == MBBInfos.end() || !FI->second.OutRegs)
continue;
for (unsigned i = 0, e = NumRegs; i != e; ++i)
if (FI->second.OutRegs[i].Value)
release(FI->second.OutRegs[i].Value);
delete[] FI->second.OutRegs;
}
MBBInfos.clear();
UndefReads.clear();
Avail.clear();
Allocator.DestroyAll();
return false;
}
FunctionPass *
llvm::createExecutionDependencyFixPass(const TargetRegisterClass *RC) {
return new ExeDepsFix(RC);
}
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