//===-- DependenceAnalysis.cpp - DA Implementation --------------*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// // // DependenceAnalysis is an LLVM pass that analyses dependences between memory // accesses. Currently, it is an (incomplete) implementation of the approach // described in // // Practical Dependence Testing // Goff, Kennedy, Tseng // PLDI 1991 // // There's a single entry point that analyzes the dependence between a pair // of memory references in a function, returning either NULL, for no dependence, // or a more-or-less detailed description of the dependence between them. // // Since Clang linearizes some array subscripts, the dependence // analysis is using SCEV->delinearize to recover the representation of multiple // subscripts, and thus avoid the more expensive and less precise MIV tests. The // delinearization is controlled by the flag -da-delinearize. // // We should pay some careful attention to the possibility of integer overflow // in the implementation of the various tests. This could happen with Add, // Subtract, or Multiply, with both APInt's and SCEV's. // // Some non-linear subscript pairs can be handled by the GCD test // (and perhaps other tests). // Should explore how often these things occur. // // Finally, it seems like certain test cases expose weaknesses in the SCEV // simplification, especially in the handling of sign and zero extensions. // It could be useful to spend time exploring these. // // Please note that this is work in progress and the interface is subject to // change. // //===----------------------------------------------------------------------===// // // // In memory of Ken Kennedy, 1945 - 2007 // // // //===----------------------------------------------------------------------===// #include "llvm/Analysis/DependenceAnalysis.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/AliasAnalysis.h" #include "llvm/Analysis/Delinearization.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/ScalarEvolutionExpressions.h" #include "llvm/Analysis/ValueTracking.h" #include "llvm/IR/InstIterator.h" #include "llvm/IR/Module.h" #include "llvm/InitializePasses.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/raw_ostream.h" using namespace llvm; #define DEBUG_TYPE "da" //===----------------------------------------------------------------------===// // statistics STATISTIC(TotalArrayPairs, "Array pairs tested"); STATISTIC(NonlinearSubscriptPairs, "Nonlinear subscript pairs"); STATISTIC(ZIVapplications, "ZIV applications"); STATISTIC(ZIVindependence, "ZIV independence"); STATISTIC(StrongSIVapplications, "Strong SIV applications"); STATISTIC(StrongSIVsuccesses, "Strong SIV successes"); STATISTIC(StrongSIVindependence, "Strong SIV independence"); STATISTIC(WeakCrossingSIVapplications, "Weak-Crossing SIV applications"); STATISTIC(WeakCrossingSIVsuccesses, "Weak-Crossing SIV successes"); STATISTIC(WeakCrossingSIVindependence, "Weak-Crossing SIV independence"); STATISTIC(ExactSIVapplications, "Exact SIV applications"); STATISTIC(ExactSIVsuccesses, "Exact SIV successes"); STATISTIC(ExactSIVindependence, "Exact SIV independence"); STATISTIC(WeakZeroSIVapplications, "Weak-Zero SIV applications"); STATISTIC(WeakZeroSIVsuccesses, "Weak-Zero SIV successes"); STATISTIC(WeakZeroSIVindependence, "Weak-Zero SIV independence"); STATISTIC(ExactRDIVapplications, "Exact RDIV applications"); STATISTIC(ExactRDIVindependence, "Exact RDIV independence"); STATISTIC(SymbolicRDIVapplications, "Symbolic RDIV applications"); STATISTIC(SymbolicRDIVindependence, "Symbolic RDIV independence"); STATISTIC(GCDapplications, "GCD applications"); STATISTIC(GCDsuccesses, "GCD successes"); STATISTIC(GCDindependence, "GCD independence"); STATISTIC(BanerjeeApplications, "Banerjee applications"); STATISTIC(BanerjeeIndependence, "Banerjee independence"); STATISTIC(BanerjeeSuccesses, "Banerjee successes"); STATISTIC(SameSDLoopsCount, "Loops with Same iteration Space and Depth"); static cl::opt Delinearize("da-delinearize", cl::init(true), cl::Hidden, cl::desc("Try to delinearize array references.")); static cl::opt DisableDelinearizationChecks( "da-disable-delinearization-checks", cl::Hidden, cl::desc( "Disable checks that try to statically verify validity of " "delinearized subscripts. Enabling this option may result in incorrect " "dependence vectors for languages that allow the subscript of one " "dimension to underflow or overflow into another dimension.")); static cl::opt MIVMaxLevelThreshold( "da-miv-max-level-threshold", cl::init(7), cl::Hidden, cl::desc("Maximum depth allowed for the recursive algorithm used to " "explore MIV direction vectors.")); namespace { /// Types of dependence test routines. enum class DependenceTestType { All, StrongSIV, WeakCrossingSIV, ExactSIV, WeakZeroSIV, ExactRDIV, SymbolicRDIV, GCDMIV, BanerjeeMIV, }; } // anonymous namespace static cl::opt EnableDependenceTest( "da-enable-dependence-test", cl::init(DependenceTestType::All), cl::ReallyHidden, cl::desc("Run only specified dependence test routine and disable others. " "The purpose is mainly to exclude the influence of other " "dependence test routines in regression tests. If set to All, all " "dependence test routines are enabled."), cl::values(clEnumValN(DependenceTestType::All, "all", "Enable all dependence test routines."), clEnumValN(DependenceTestType::StrongSIV, "strong-siv", "Enable only Strong SIV test."), clEnumValN(DependenceTestType::WeakCrossingSIV, "weak-crossing-siv", "Enable only Weak-Crossing SIV test."), clEnumValN(DependenceTestType::ExactSIV, "exact-siv", "Enable only Exact SIV test."), clEnumValN(DependenceTestType::WeakZeroSIV, "weak-zero-siv", "Enable only Weak-Zero SIV test."), clEnumValN(DependenceTestType::ExactRDIV, "exact-rdiv", "Enable only Exact RDIV test."), clEnumValN(DependenceTestType::SymbolicRDIV, "symbolic-rdiv", "Enable only Symbolic RDIV test."), clEnumValN(DependenceTestType::GCDMIV, "gcd-miv", "Enable only GCD MIV test."), clEnumValN(DependenceTestType::BanerjeeMIV, "banerjee-miv", "Enable only Banerjee MIV test."))); // TODO: This flag is disabled by default because it is still under development. // Enable it or delete this flag when the feature is ready. static cl::opt EnableMonotonicityCheck( "da-enable-monotonicity-check", cl::init(false), cl::Hidden, cl::desc("Check if the subscripts are monotonic. If it's not, dependence " "is reported as unknown.")); static cl::opt DumpMonotonicityReport( "da-dump-monotonicity-report", cl::init(false), cl::Hidden, cl::desc( "When printing analysis, dump the results of monotonicity checks.")); //===----------------------------------------------------------------------===// // basics DependenceAnalysis::Result DependenceAnalysis::run(Function &F, FunctionAnalysisManager &FAM) { auto &AA = FAM.getResult(F); auto &SE = FAM.getResult(F); auto &LI = FAM.getResult(F); return DependenceInfo(&F, &AA, &SE, &LI); } AnalysisKey DependenceAnalysis::Key; INITIALIZE_PASS_BEGIN(DependenceAnalysisWrapperPass, "da", "Dependence Analysis", true, true) INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(ScalarEvolutionWrapperPass) INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass) INITIALIZE_PASS_END(DependenceAnalysisWrapperPass, "da", "Dependence Analysis", true, true) char DependenceAnalysisWrapperPass::ID = 0; DependenceAnalysisWrapperPass::DependenceAnalysisWrapperPass() : FunctionPass(ID) {} FunctionPass *llvm::createDependenceAnalysisWrapperPass() { return new DependenceAnalysisWrapperPass(); } bool DependenceAnalysisWrapperPass::runOnFunction(Function &F) { auto &AA = getAnalysis().getAAResults(); auto &SE = getAnalysis().getSE(); auto &LI = getAnalysis().getLoopInfo(); info.reset(new DependenceInfo(&F, &AA, &SE, &LI)); return false; } DependenceInfo &DependenceAnalysisWrapperPass::getDI() const { return *info; } void DependenceAnalysisWrapperPass::releaseMemory() { info.reset(); } void DependenceAnalysisWrapperPass::getAnalysisUsage(AnalysisUsage &AU) const { AU.setPreservesAll(); AU.addRequiredTransitive(); AU.addRequiredTransitive(); AU.addRequiredTransitive(); } namespace { /// The property of monotonicity of a SCEV. To define the monotonicity, assume /// a SCEV defined within N-nested loops. Let i_k denote the iteration number /// of the k-th loop. Then we can regard the SCEV as an N-ary function: /// /// F(i_1, i_2, ..., i_N) /// /// The domain of i_k is the closed range [0, BTC_k], where BTC_k is the /// backedge-taken count of the k-th loop. /// /// A function F is said to be "monotonically increasing with respect to the /// k-th loop" if x <= y implies the following condition: /// /// F(i_1, ..., i_{k-1}, x, i_{k+1}, ..., i_N) <= /// F(i_1, ..., i_{k-1}, y, i_{k+1}, ..., i_N) /// /// where i_1, ..., i_{k-1}, i_{k+1}, ..., i_N, x, and y are elements of their /// respective domains. /// /// Likewise F is "monotonically decreasing with respect to the k-th loop" /// if x <= y implies /// /// F(i_1, ..., i_{k-1}, x, i_{k+1}, ..., i_N) >= /// F(i_1, ..., i_{k-1}, y, i_{k+1}, ..., i_N) /// /// A function F that is monotonically increasing or decreasing with respect to /// the k-th loop is simply called "monotonic with respect to k-th loop". /// /// A function F is said to be "multivariate monotonic" when it is monotonic /// with respect to all of the N loops. /// /// Since integer comparison can be either signed or unsigned, we need to /// distinguish monotonicity in the signed sense from that in the unsigned /// sense. Note that the inequality "x <= y" merely indicates loop progression /// and is not affected by the difference between signed and unsigned order. /// /// Currently we only consider monotonicity in a signed sense. enum class SCEVMonotonicityType { /// We don't know anything about the monotonicity of the SCEV. Unknown, /// The SCEV is loop-invariant with respect to the outermost loop. In other /// words, the function F corresponding to the SCEV is a constant function. Invariant, /// The function F corresponding to the SCEV is multivariate monotonic in a /// signed sense. Note that the multivariate monotonic function may also be a /// constant function. The order employed in the definition of monotonicity /// is not strict order. MultivariateSignedMonotonic, }; struct SCEVMonotonicity { SCEVMonotonicity(SCEVMonotonicityType Type, const SCEV *FailurePoint = nullptr); SCEVMonotonicityType getType() const { return Type; } const SCEV *getFailurePoint() const { return FailurePoint; } bool isUnknown() const { return Type == SCEVMonotonicityType::Unknown; } void print(raw_ostream &OS, unsigned Depth) const; private: SCEVMonotonicityType Type; /// The subexpression that caused Unknown. Mainly for debugging purpose. const SCEV *FailurePoint; }; /// Check the monotonicity of a SCEV. Since dependence tests (SIV, MIV, etc.) /// assume that subscript expressions are (multivariate) monotonic, we need to /// verify this property before applying those tests. Violating this assumption /// may cause them to produce incorrect results. struct SCEVMonotonicityChecker : public SCEVVisitor { SCEVMonotonicityChecker(ScalarEvolution *SE) : SE(SE) {} /// Check the monotonicity of \p Expr. \p Expr must be integer type. If \p /// OutermostLoop is not null, \p Expr must be defined in \p OutermostLoop or /// one of its nested loops. SCEVMonotonicity checkMonotonicity(const SCEV *Expr, const Loop *OutermostLoop); private: ScalarEvolution *SE; /// The outermost loop that DA is analyzing. const Loop *OutermostLoop; /// A helper to classify \p Expr as either Invariant or Unknown. SCEVMonotonicity invariantOrUnknown(const SCEV *Expr); /// Return true if \p Expr is loop-invariant with respect to the outermost /// loop. bool isLoopInvariant(const SCEV *Expr) const; /// A helper to create an Unknown SCEVMonotonicity. SCEVMonotonicity createUnknown(const SCEV *FailurePoint) { return SCEVMonotonicity(SCEVMonotonicityType::Unknown, FailurePoint); } SCEVMonotonicity visitAddRecExpr(const SCEVAddRecExpr *Expr); SCEVMonotonicity visitConstant(const SCEVConstant *) { return SCEVMonotonicity(SCEVMonotonicityType::Invariant); } SCEVMonotonicity visitVScale(const SCEVVScale *) { return SCEVMonotonicity(SCEVMonotonicityType::Invariant); } // TODO: Handle more cases. SCEVMonotonicity visitZeroExtendExpr(const SCEVZeroExtendExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitSignExtendExpr(const SCEVSignExtendExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitAddExpr(const SCEVAddExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitMulExpr(const SCEVMulExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitPtrToIntExpr(const SCEVPtrToIntExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitTruncateExpr(const SCEVTruncateExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitUDivExpr(const SCEVUDivExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitSMaxExpr(const SCEVSMaxExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitUMaxExpr(const SCEVUMaxExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitSMinExpr(const SCEVSMinExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitUMinExpr(const SCEVUMinExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitSequentialUMinExpr(const SCEVSequentialUMinExpr *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitUnknown(const SCEVUnknown *Expr) { return invariantOrUnknown(Expr); } SCEVMonotonicity visitCouldNotCompute(const SCEVCouldNotCompute *Expr) { return invariantOrUnknown(Expr); } friend struct SCEVVisitor; }; /// A wrapper class for std::optional that provides arithmetic operators /// with overflow checking in a signed sense. This allows us to omit inserting /// an overflow check at every arithmetic operation, which simplifies the code /// if the operations are chained like `a + b + c + ...`. /// /// If an calculation overflows, the result becomes "invalid" which is /// internally represented by std::nullopt. If any operand of an arithmetic /// operation is "invalid", the result will also be "invalid". struct OverflowSafeSignedAPInt { OverflowSafeSignedAPInt() : Value(std::nullopt) {} OverflowSafeSignedAPInt(const APInt &V) : Value(V) {} OverflowSafeSignedAPInt(const std::optional &V) : Value(V) {} OverflowSafeSignedAPInt operator+(const OverflowSafeSignedAPInt &RHS) const { if (!Value || !RHS.Value) return OverflowSafeSignedAPInt(); bool Overflow; APInt Result = Value->sadd_ov(*RHS.Value, Overflow); if (Overflow) return OverflowSafeSignedAPInt(); return OverflowSafeSignedAPInt(Result); } OverflowSafeSignedAPInt operator+(int RHS) const { if (!Value) return OverflowSafeSignedAPInt(); return *this + fromInt(RHS); } OverflowSafeSignedAPInt operator-(const OverflowSafeSignedAPInt &RHS) const { if (!Value || !RHS.Value) return OverflowSafeSignedAPInt(); bool Overflow; APInt Result = Value->ssub_ov(*RHS.Value, Overflow); if (Overflow) return OverflowSafeSignedAPInt(); return OverflowSafeSignedAPInt(Result); } OverflowSafeSignedAPInt operator-(int RHS) const { if (!Value) return OverflowSafeSignedAPInt(); return *this - fromInt(RHS); } OverflowSafeSignedAPInt operator*(const OverflowSafeSignedAPInt &RHS) const { if (!Value || !RHS.Value) return OverflowSafeSignedAPInt(); bool Overflow; APInt Result = Value->smul_ov(*RHS.Value, Overflow); if (Overflow) return OverflowSafeSignedAPInt(); return OverflowSafeSignedAPInt(Result); } OverflowSafeSignedAPInt operator-() const { if (!Value) return OverflowSafeSignedAPInt(); if (Value->isMinSignedValue()) return OverflowSafeSignedAPInt(); return OverflowSafeSignedAPInt(-*Value); } operator bool() const { return Value.has_value(); } bool operator!() const { return !Value.has_value(); } const APInt &operator*() const { assert(Value && "Value is not available."); return *Value; } const APInt *operator->() const { assert(Value && "Value is not available."); return &*Value; } private: /// Underlying value. std::nullopt means "unknown". An arithmetic operation on /// "unknown" always produces "unknown". std::optional Value; OverflowSafeSignedAPInt fromInt(uint64_t V) const { assert(Value && "Value is not available."); return OverflowSafeSignedAPInt( APInt(Value->getBitWidth(), V, /*isSigned=*/true)); } }; } // anonymous namespace // Used to test the dependence analyzer. // Looks through the function, noting instructions that may access memory. // Calls depends() on every possible pair and prints out the result. // Ignores all other instructions. static void dumpExampleDependence(raw_ostream &OS, DependenceInfo *DA, ScalarEvolution &SE, LoopInfo &LI, bool NormalizeResults) { auto *F = DA->getFunction(); if (DumpMonotonicityReport) { SCEVMonotonicityChecker Checker(&SE); OS << "Monotonicity check:\n"; for (Instruction &Inst : instructions(F)) { if (!isa(Inst) && !isa(Inst)) continue; Value *Ptr = getLoadStorePointerOperand(&Inst); const Loop *L = LI.getLoopFor(Inst.getParent()); const Loop *OutermostLoop = L ? L->getOutermostLoop() : nullptr; const SCEV *PtrSCEV = SE.getSCEVAtScope(Ptr, L); const SCEV *AccessFn = SE.removePointerBase(PtrSCEV); SCEVMonotonicity Mon = Checker.checkMonotonicity(AccessFn, OutermostLoop); OS.indent(2) << "Inst: " << Inst << "\n"; OS.indent(4) << "Expr: " << *AccessFn << "\n"; Mon.print(OS, 4); } OS << "\n"; } for (inst_iterator SrcI = inst_begin(F), SrcE = inst_end(F); SrcI != SrcE; ++SrcI) { if (SrcI->mayReadOrWriteMemory()) { for (inst_iterator DstI = SrcI, DstE = inst_end(F); DstI != DstE; ++DstI) { if (DstI->mayReadOrWriteMemory()) { OS << "Src:" << *SrcI << " --> Dst:" << *DstI << "\n"; OS << " da analyze - "; if (auto D = DA->depends(&*SrcI, &*DstI, /*UnderRuntimeAssumptions=*/true)) { #ifndef NDEBUG // Verify that the distance being zero is equivalent to the // direction being EQ. for (unsigned Level = 1; Level <= D->getLevels(); Level++) { const SCEV *Distance = D->getDistance(Level); bool IsDistanceZero = Distance && Distance->isZero(); bool IsDirectionEQ = D->getDirection(Level) == Dependence::DVEntry::EQ; assert(IsDistanceZero == IsDirectionEQ && "Inconsistent distance and direction."); } #endif // Normalize negative direction vectors if required by clients. if (NormalizeResults && D->normalize(&SE)) OS << "normalized - "; D->dump(OS); } else OS << "none!\n"; } } } } } void DependenceAnalysisWrapperPass::print(raw_ostream &OS, const Module *) const { dumpExampleDependence( OS, info.get(), getAnalysis().getSE(), getAnalysis().getLoopInfo(), false); } PreservedAnalyses DependenceAnalysisPrinterPass::run(Function &F, FunctionAnalysisManager &FAM) { OS << "Printing analysis 'Dependence Analysis' for function '" << F.getName() << "':\n"; dumpExampleDependence(OS, &FAM.getResult(F), FAM.getResult(F), FAM.getResult(F), NormalizeResults); return PreservedAnalyses::all(); } //===----------------------------------------------------------------------===// // Dependence methods // Returns true if this is an input dependence. bool Dependence::isInput() const { return Src->mayReadFromMemory() && Dst->mayReadFromMemory(); } // Returns true if this is an output dependence. bool Dependence::isOutput() const { return Src->mayWriteToMemory() && Dst->mayWriteToMemory(); } // Returns true if this is an flow (aka true) dependence. bool Dependence::isFlow() const { return Src->mayWriteToMemory() && Dst->mayReadFromMemory(); } // Returns true if this is an anti dependence. bool Dependence::isAnti() const { return Src->mayReadFromMemory() && Dst->mayWriteToMemory(); } // Returns true if a particular level is scalar; that is, // if no subscript in the source or destination mention the induction // variable associated with the loop at this level. // Leave this out of line, so it will serve as a virtual method anchor bool Dependence::isScalar(unsigned level, bool IsSameSD) const { return false; } //===----------------------------------------------------------------------===// // FullDependence methods FullDependence::FullDependence(Instruction *Source, Instruction *Destination, const SCEVUnionPredicate &Assumes, bool PossiblyLoopIndependent, unsigned CommonLevels) : Dependence(Source, Destination, Assumes), Levels(CommonLevels), LoopIndependent(PossiblyLoopIndependent) { Consistent = true; SameSDLevels = 0; if (CommonLevels) DV = std::make_unique(CommonLevels); } // FIXME: in some cases the meaning of a negative direction vector // may not be straightforward, e.g., // for (int i = 0; i < 32; ++i) { // Src: A[i] = ...; // Dst: use(A[31 - i]); // } // The dependency is // flow { Src[i] -> Dst[31 - i] : when i >= 16 } and // anti { Dst[i] -> Src[31 - i] : when i < 16 }, // -- hence a [<>]. // As long as a dependence result contains '>' ('<>', '<=>', "*"), it // means that a reversed/normalized dependence needs to be considered // as well. Nevertheless, current isDirectionNegative() only returns // true with a '>' or '>=' dependency for ease of canonicalizing the // dependency vector, since the reverse of '<>', '<=>' and "*" is itself. bool FullDependence::isDirectionNegative() const { for (unsigned Level = 1; Level <= Levels; ++Level) { unsigned char Direction = DV[Level - 1].Direction; if (Direction == Dependence::DVEntry::EQ) continue; if (Direction == Dependence::DVEntry::GT || Direction == Dependence::DVEntry::GE) return true; return false; } return false; } bool FullDependence::normalize(ScalarEvolution *SE) { if (!isDirectionNegative()) return false; LLVM_DEBUG(dbgs() << "Before normalizing negative direction vectors:\n"; dump(dbgs());); std::swap(Src, Dst); for (unsigned Level = 1; Level <= Levels; ++Level) { unsigned char Direction = DV[Level - 1].Direction; // Reverse the direction vector, this means LT becomes GT // and GT becomes LT. unsigned char RevDirection = Direction & Dependence::DVEntry::EQ; if (Direction & Dependence::DVEntry::LT) RevDirection |= Dependence::DVEntry::GT; if (Direction & Dependence::DVEntry::GT) RevDirection |= Dependence::DVEntry::LT; DV[Level - 1].Direction = RevDirection; // Reverse the dependence distance as well. if (DV[Level - 1].Distance != nullptr) DV[Level - 1].Distance = SE->getNegativeSCEV(DV[Level - 1].Distance); } LLVM_DEBUG(dbgs() << "After normalizing negative direction vectors:\n"; dump(dbgs());); return true; } // The rest are simple getters that hide the implementation. // getDirection - Returns the direction associated with a particular common or // SameSD level. unsigned FullDependence::getDirection(unsigned Level, bool IsSameSD) const { return getDVEntry(Level, IsSameSD).Direction; } // Returns the distance (or NULL) associated with a particular common or // SameSD level. const SCEV *FullDependence::getDistance(unsigned Level, bool IsSameSD) const { return getDVEntry(Level, IsSameSD).Distance; } // Returns true if a particular regular or SameSD level is scalar; that is, // if no subscript in the source or destination mention the induction variable // associated with the loop at this level. bool FullDependence::isScalar(unsigned Level, bool IsSameSD) const { return getDVEntry(Level, IsSameSD).Scalar; } // Returns true if peeling the first iteration from this regular or SameSD // loop level will break this dependence. bool FullDependence::isPeelFirst(unsigned Level, bool IsSameSD) const { return getDVEntry(Level, IsSameSD).PeelFirst; } // Returns true if peeling the last iteration from this regular or SameSD // loop level will break this dependence. bool FullDependence::isPeelLast(unsigned Level, bool IsSameSD) const { return getDVEntry(Level, IsSameSD).PeelLast; } // inSameSDLoops - Returns true if this level is an SameSD level, i.e., // performed across two separate loop nests that have the Same iteration space // and Depth. bool FullDependence::inSameSDLoops(unsigned Level) const { assert(0 < Level && Level <= static_cast(Levels) + SameSDLevels && "Level out of range"); return Level > Levels; } //===----------------------------------------------------------------------===// // SCEVMonotonicity SCEVMonotonicity::SCEVMonotonicity(SCEVMonotonicityType Type, const SCEV *FailurePoint) : Type(Type), FailurePoint(FailurePoint) { assert( ((Type == SCEVMonotonicityType::Unknown) == (FailurePoint != nullptr)) && "FailurePoint must be provided iff Type is Unknown"); } void SCEVMonotonicity::print(raw_ostream &OS, unsigned Depth) const { OS.indent(Depth) << "Monotonicity: "; switch (Type) { case SCEVMonotonicityType::Unknown: assert(FailurePoint && "FailurePoint must be provided for Unknown"); OS << "Unknown\n"; OS.indent(Depth) << "Reason: " << *FailurePoint << "\n"; break; case SCEVMonotonicityType::Invariant: OS << "Invariant\n"; break; case SCEVMonotonicityType::MultivariateSignedMonotonic: OS << "MultivariateSignedMonotonic\n"; break; } } bool SCEVMonotonicityChecker::isLoopInvariant(const SCEV *Expr) const { return !OutermostLoop || SE->isLoopInvariant(Expr, OutermostLoop); } SCEVMonotonicity SCEVMonotonicityChecker::invariantOrUnknown(const SCEV *Expr) { if (isLoopInvariant(Expr)) return SCEVMonotonicity(SCEVMonotonicityType::Invariant); return createUnknown(Expr); } SCEVMonotonicity SCEVMonotonicityChecker::checkMonotonicity(const SCEV *Expr, const Loop *OutermostLoop) { assert((!OutermostLoop || OutermostLoop->isOutermost()) && "OutermostLoop must be outermost"); assert(Expr->getType()->isIntegerTy() && "Expr must be integer type"); this->OutermostLoop = OutermostLoop; return visit(Expr); } /// We only care about an affine AddRec at the moment. For an affine AddRec, /// the monotonicity can be inferred from its nowrap property. For example, let /// X and Y be loop-invariant, and assume Y is non-negative. An AddRec /// {X,+.Y} implies: /// /// X <=s (X + Y) <=s ((X + Y) + Y) <=s ... /// /// Thus, we can conclude that the AddRec is monotonically increasing with /// respect to the associated loop in a signed sense. The similar reasoning /// applies when Y is non-positive, leading to a monotonically decreasing /// AddRec. SCEVMonotonicity SCEVMonotonicityChecker::visitAddRecExpr(const SCEVAddRecExpr *Expr) { if (!Expr->isAffine() || !Expr->hasNoSignedWrap()) return createUnknown(Expr); const SCEV *Start = Expr->getStart(); const SCEV *Step = Expr->getStepRecurrence(*SE); SCEVMonotonicity StartMon = visit(Start); if (StartMon.isUnknown()) return StartMon; if (!isLoopInvariant(Step)) return createUnknown(Expr); return SCEVMonotonicity(SCEVMonotonicityType::MultivariateSignedMonotonic); } //===----------------------------------------------------------------------===// // DependenceInfo methods // For debugging purposes. Dumps a dependence to OS. void Dependence::dump(raw_ostream &OS) const { if (isConfused()) OS << "confused"; else { if (isConsistent()) OS << "consistent "; if (isFlow()) OS << "flow"; else if (isOutput()) OS << "output"; else if (isAnti()) OS << "anti"; else if (isInput()) OS << "input"; dumpImp(OS); unsigned SameSDLevels = getSameSDLevels(); if (SameSDLevels > 0) { OS << " / assuming " << SameSDLevels << " loop level(s) fused: "; dumpImp(OS, true); } } OS << "!\n"; SCEVUnionPredicate Assumptions = getRuntimeAssumptions(); if (!Assumptions.isAlwaysTrue()) { OS << " Runtime Assumptions:\n"; Assumptions.print(OS, 2); } } // For debugging purposes. Dumps a dependence to OS with or without considering // the SameSD levels. void Dependence::dumpImp(raw_ostream &OS, bool IsSameSD) const { unsigned Levels = getLevels(); unsigned SameSDLevels = getSameSDLevels(); bool OnSameSD = false; unsigned LevelNum = Levels; if (IsSameSD) LevelNum += SameSDLevels; OS << " ["; for (unsigned II = 1; II <= LevelNum; ++II) { if (!OnSameSD && inSameSDLoops(II)) OnSameSD = true; if (isPeelFirst(II, OnSameSD)) OS << 'p'; const SCEV *Distance = getDistance(II, OnSameSD); if (Distance) OS << *Distance; else if (isScalar(II, OnSameSD)) OS << "S"; else { unsigned Direction = getDirection(II, OnSameSD); if (Direction == DVEntry::ALL) OS << "*"; else { if (Direction & DVEntry::LT) OS << "<"; if (Direction & DVEntry::EQ) OS << "="; if (Direction & DVEntry::GT) OS << ">"; } } if (isPeelLast(II, OnSameSD)) OS << 'p'; if (II < LevelNum) OS << " "; } if (isLoopIndependent()) OS << "|<"; OS << "]"; } // Returns NoAlias/MayAliass/MustAlias for two memory locations based upon their // underlaying objects. If LocA and LocB are known to not alias (for any reason: // tbaa, non-overlapping regions etc), then it is known there is no dependecy. // Otherwise the underlying objects are checked to see if they point to // different identifiable objects. static AliasResult underlyingObjectsAlias(AAResults *AA, const DataLayout &DL, const MemoryLocation &LocA, const MemoryLocation &LocB) { // Check the original locations (minus size) for noalias, which can happen for // tbaa, incompatible underlying object locations, etc. MemoryLocation LocAS = MemoryLocation::getBeforeOrAfter(LocA.Ptr, LocA.AATags); MemoryLocation LocBS = MemoryLocation::getBeforeOrAfter(LocB.Ptr, LocB.AATags); BatchAAResults BAA(*AA); BAA.enableCrossIterationMode(); if (BAA.isNoAlias(LocAS, LocBS)) return AliasResult::NoAlias; // Check the underlying objects are the same const Value *AObj = getUnderlyingObject(LocA.Ptr); const Value *BObj = getUnderlyingObject(LocB.Ptr); // If the underlying objects are the same, they must alias if (AObj == BObj) return AliasResult::MustAlias; // We may have hit the recursion limit for underlying objects, or have // underlying objects where we don't know they will alias. if (!isIdentifiedObject(AObj) || !isIdentifiedObject(BObj)) return AliasResult::MayAlias; // Otherwise we know the objects are different and both identified objects so // must not alias. return AliasResult::NoAlias; } // Returns true if the load or store can be analyzed. Atomic and volatile // operations have properties which this analysis does not understand. static bool isLoadOrStore(const Instruction *I) { if (const LoadInst *LI = dyn_cast(I)) return LI->isUnordered(); else if (const StoreInst *SI = dyn_cast(I)) return SI->isUnordered(); return false; } // Returns true if two loops have the Same iteration Space and Depth. To be // more specific, two loops have SameSD if they are in the same nesting // depth and have the same backedge count. SameSD stands for Same iteration // Space and Depth. bool DependenceInfo::haveSameSD(const Loop *SrcLoop, const Loop *DstLoop) const { if (SrcLoop == DstLoop) return true; if (SrcLoop->getLoopDepth() != DstLoop->getLoopDepth()) return false; if (!SrcLoop || !SrcLoop->getLoopLatch() || !DstLoop || !DstLoop->getLoopLatch()) return false; const SCEV *SrcUB = nullptr, *DstUP = nullptr; if (SE->hasLoopInvariantBackedgeTakenCount(SrcLoop)) SrcUB = SE->getBackedgeTakenCount(SrcLoop); if (SE->hasLoopInvariantBackedgeTakenCount(DstLoop)) DstUP = SE->getBackedgeTakenCount(DstLoop); if (SrcUB != nullptr && DstUP != nullptr) { Type *WiderType = SE->getWiderType(SrcUB->getType(), DstUP->getType()); SrcUB = SE->getNoopOrZeroExtend(SrcUB, WiderType); DstUP = SE->getNoopOrZeroExtend(DstUP, WiderType); if (SE->isKnownPredicate(ICmpInst::ICMP_EQ, SrcUB, DstUP)) return true; } return false; } // Examines the loop nesting of the Src and Dst // instructions and establishes their shared loops. Sets the variables // CommonLevels, SrcLevels, and MaxLevels. // The source and destination instructions needn't be contained in the same // loop. The routine establishNestingLevels finds the level of most deeply // nested loop that contains them both, CommonLevels. An instruction that's // not contained in a loop is at level = 0. MaxLevels is equal to the level // of the source plus the level of the destination, minus CommonLevels. // This lets us allocate vectors MaxLevels in length, with room for every // distinct loop referenced in both the source and destination subscripts. // The variable SrcLevels is the nesting depth of the source instruction. // It's used to help calculate distinct loops referenced by the destination. // Here's the map from loops to levels: // 0 - unused // 1 - outermost common loop // ... - other common loops // CommonLevels - innermost common loop // ... - loops containing Src but not Dst // SrcLevels - innermost loop containing Src but not Dst // ... - loops containing Dst but not Src // MaxLevels - innermost loops containing Dst but not Src // Consider the follow code fragment: // for (a = ...) { // for (b = ...) { // for (c = ...) { // for (d = ...) { // A[] = ...; // } // } // for (e = ...) { // for (f = ...) { // for (g = ...) { // ... = A[]; // } // } // } // } // } // If we're looking at the possibility of a dependence between the store // to A (the Src) and the load from A (the Dst), we'll note that they // have 2 loops in common, so CommonLevels will equal 2 and the direction // vector for Result will have 2 entries. SrcLevels = 4 and MaxLevels = 7. // A map from loop names to loop numbers would look like // a - 1 // b - 2 = CommonLevels // c - 3 // d - 4 = SrcLevels // e - 5 // f - 6 // g - 7 = MaxLevels // SameSDLevels counts the number of levels after common levels that are // not common but have the same iteration space and depth. Internally this // is checked using haveSameSD. Assume that in this code fragment, levels c and // e have the same iteration space and depth, but levels d and f does not. Then // SameSDLevels is set to 1. In that case the level numbers for the previous // code look like // a - 1 // b - 2 // c,e - 3 = CommonLevels // d - 4 = SrcLevels // f - 5 // g - 6 = MaxLevels void DependenceInfo::establishNestingLevels(const Instruction *Src, const Instruction *Dst) { const BasicBlock *SrcBlock = Src->getParent(); const BasicBlock *DstBlock = Dst->getParent(); unsigned SrcLevel = LI->getLoopDepth(SrcBlock); unsigned DstLevel = LI->getLoopDepth(DstBlock); const Loop *SrcLoop = LI->getLoopFor(SrcBlock); const Loop *DstLoop = LI->getLoopFor(DstBlock); SrcLevels = SrcLevel; MaxLevels = SrcLevel + DstLevel; SameSDLevels = 0; while (SrcLevel > DstLevel) { SrcLoop = SrcLoop->getParentLoop(); SrcLevel--; } while (DstLevel > SrcLevel) { DstLoop = DstLoop->getParentLoop(); DstLevel--; } // find the first common level and count the SameSD levels leading to it while (SrcLoop != DstLoop) { SameSDLevels++; if (!haveSameSD(SrcLoop, DstLoop)) SameSDLevels = 0; SrcLoop = SrcLoop->getParentLoop(); DstLoop = DstLoop->getParentLoop(); SrcLevel--; } CommonLevels = SrcLevel; MaxLevels -= CommonLevels; } // Given one of the loops containing the source, return // its level index in our numbering scheme. unsigned DependenceInfo::mapSrcLoop(const Loop *SrcLoop) const { return SrcLoop->getLoopDepth(); } // Given one of the loops containing the destination, // return its level index in our numbering scheme. unsigned DependenceInfo::mapDstLoop(const Loop *DstLoop) const { unsigned D = DstLoop->getLoopDepth(); if (D > CommonLevels) // This tries to make sure that we assign unique numbers to src and dst when // the memory accesses reside in different loops that have the same depth. return D - CommonLevels + SrcLevels; else return D; } // Returns true if Expression is loop invariant in LoopNest. bool DependenceInfo::isLoopInvariant(const SCEV *Expression, const Loop *LoopNest) const { // Unlike ScalarEvolution::isLoopInvariant() we consider an access outside of // any loop as invariant, because we only consier expression evaluation at a // specific position (where the array access takes place), and not across the // entire function. if (!LoopNest) return true; // If the expression is invariant in the outermost loop of the loop nest, it // is invariant anywhere in the loop nest. return SE->isLoopInvariant(Expression, LoopNest->getOutermostLoop()); } // Finds the set of loops from the LoopNest that // have a level <= CommonLevels and are referred to by the SCEV Expression. void DependenceInfo::collectCommonLoops(const SCEV *Expression, const Loop *LoopNest, SmallBitVector &Loops) const { while (LoopNest) { unsigned Level = LoopNest->getLoopDepth(); if (Level <= CommonLevels && !SE->isLoopInvariant(Expression, LoopNest)) Loops.set(Level); LoopNest = LoopNest->getParentLoop(); } } void DependenceInfo::unifySubscriptType(ArrayRef Pairs) { unsigned widestWidthSeen = 0; Type *widestType; // Go through each pair and find the widest bit to which we need // to extend all of them. for (Subscript *Pair : Pairs) { const SCEV *Src = Pair->Src; const SCEV *Dst = Pair->Dst; IntegerType *SrcTy = dyn_cast(Src->getType()); IntegerType *DstTy = dyn_cast(Dst->getType()); if (SrcTy == nullptr || DstTy == nullptr) { assert(SrcTy == DstTy && "This function only unify integer types and " "expect Src and Dst share the same type otherwise."); continue; } if (SrcTy->getBitWidth() > widestWidthSeen) { widestWidthSeen = SrcTy->getBitWidth(); widestType = SrcTy; } if (DstTy->getBitWidth() > widestWidthSeen) { widestWidthSeen = DstTy->getBitWidth(); widestType = DstTy; } } assert(widestWidthSeen > 0); // Now extend each pair to the widest seen. for (Subscript *Pair : Pairs) { const SCEV *Src = Pair->Src; const SCEV *Dst = Pair->Dst; IntegerType *SrcTy = dyn_cast(Src->getType()); IntegerType *DstTy = dyn_cast(Dst->getType()); if (SrcTy == nullptr || DstTy == nullptr) { assert(SrcTy == DstTy && "This function only unify integer types and " "expect Src and Dst share the same type otherwise."); continue; } if (SrcTy->getBitWidth() < widestWidthSeen) // Sign-extend Src to widestType Pair->Src = SE->getSignExtendExpr(Src, widestType); if (DstTy->getBitWidth() < widestWidthSeen) { // Sign-extend Dst to widestType Pair->Dst = SE->getSignExtendExpr(Dst, widestType); } } } // removeMatchingExtensions - Examines a subscript pair. // If the source and destination are identically sign (or zero) // extended, it strips off the extension in an effect to simplify // the actual analysis. void DependenceInfo::removeMatchingExtensions(Subscript *Pair) { const SCEV *Src = Pair->Src; const SCEV *Dst = Pair->Dst; if ((isa(Src) && isa(Dst)) || (isa(Src) && isa(Dst))) { const SCEVIntegralCastExpr *SrcCast = cast(Src); const SCEVIntegralCastExpr *DstCast = cast(Dst); const SCEV *SrcCastOp = SrcCast->getOperand(); const SCEV *DstCastOp = DstCast->getOperand(); if (SrcCastOp->getType() == DstCastOp->getType()) { Pair->Src = SrcCastOp; Pair->Dst = DstCastOp; } } } // Examine the scev and return true iff it's affine. // Collect any loops mentioned in the set of "Loops". bool DependenceInfo::checkSubscript(const SCEV *Expr, const Loop *LoopNest, SmallBitVector &Loops, bool IsSrc) { const SCEVAddRecExpr *AddRec = dyn_cast(Expr); if (!AddRec) return isLoopInvariant(Expr, LoopNest); // The AddRec must depend on one of the containing loops. Otherwise, // mapSrcLoop and mapDstLoop return indices outside the intended range. This // can happen when a subscript in one loop references an IV from a sibling // loop that could not be replaced with a concrete exit value by // getSCEVAtScope. const Loop *L = LoopNest; while (L && AddRec->getLoop() != L) L = L->getParentLoop(); if (!L) return false; const SCEV *Start = AddRec->getStart(); const SCEV *Step = AddRec->getStepRecurrence(*SE); if (!isLoopInvariant(Step, LoopNest)) return false; if (IsSrc) Loops.set(mapSrcLoop(AddRec->getLoop())); else Loops.set(mapDstLoop(AddRec->getLoop())); return checkSubscript(Start, LoopNest, Loops, IsSrc); } // Examine the scev and return true iff it's linear. // Collect any loops mentioned in the set of "Loops". bool DependenceInfo::checkSrcSubscript(const SCEV *Src, const Loop *LoopNest, SmallBitVector &Loops) { return checkSubscript(Src, LoopNest, Loops, true); } // Examine the scev and return true iff it's linear. // Collect any loops mentioned in the set of "Loops". bool DependenceInfo::checkDstSubscript(const SCEV *Dst, const Loop *LoopNest, SmallBitVector &Loops) { return checkSubscript(Dst, LoopNest, Loops, false); } // Examines the subscript pair (the Src and Dst SCEVs) // and classifies it as either ZIV, SIV, RDIV, MIV, or Nonlinear. // Collects the associated loops in a set. DependenceInfo::Subscript::ClassificationKind DependenceInfo::classifyPair(const SCEV *Src, const Loop *SrcLoopNest, const SCEV *Dst, const Loop *DstLoopNest, SmallBitVector &Loops) { SmallBitVector SrcLoops(MaxLevels + 1); SmallBitVector DstLoops(MaxLevels + 1); if (!checkSrcSubscript(Src, SrcLoopNest, SrcLoops)) return Subscript::NonLinear; if (!checkDstSubscript(Dst, DstLoopNest, DstLoops)) return Subscript::NonLinear; Loops = SrcLoops; Loops |= DstLoops; unsigned N = Loops.count(); if (N == 0) return Subscript::ZIV; if (N == 1) return Subscript::SIV; if (N == 2 && (SrcLoops.count() == 0 || DstLoops.count() == 0 || (SrcLoops.count() == 1 && DstLoops.count() == 1))) return Subscript::RDIV; return Subscript::MIV; } // A wrapper around SCEV::isKnownPredicate. // Looks for cases where we're interested in comparing for equality. // If both X and Y have been identically sign or zero extended, // it strips off the (confusing) extensions before invoking // SCEV::isKnownPredicate. Perhaps, someday, the ScalarEvolution package // will be similarly updated. // // If SCEV::isKnownPredicate can't prove the predicate, // we try simple subtraction, which seems to help in some cases // involving symbolics. bool DependenceInfo::isKnownPredicate(ICmpInst::Predicate Pred, const SCEV *X, const SCEV *Y) const { if (Pred == CmpInst::ICMP_EQ || Pred == CmpInst::ICMP_NE) { if ((isa(X) && isa(Y)) || (isa(X) && isa(Y))) { const SCEVIntegralCastExpr *CX = cast(X); const SCEVIntegralCastExpr *CY = cast(Y); const SCEV *Xop = CX->getOperand(); const SCEV *Yop = CY->getOperand(); if (Xop->getType() == Yop->getType()) { X = Xop; Y = Yop; } } } if (SE->isKnownPredicate(Pred, X, Y)) return true; // If SE->isKnownPredicate can't prove the condition, // we try the brute-force approach of subtracting // and testing the difference. // By testing with SE->isKnownPredicate first, we avoid // the possibility of overflow when the arguments are constants. const SCEV *Delta = SE->getMinusSCEV(X, Y); switch (Pred) { case CmpInst::ICMP_EQ: return Delta->isZero(); case CmpInst::ICMP_NE: return SE->isKnownNonZero(Delta); case CmpInst::ICMP_SGE: return SE->isKnownNonNegative(Delta); case CmpInst::ICMP_SLE: return SE->isKnownNonPositive(Delta); case CmpInst::ICMP_SGT: return SE->isKnownPositive(Delta); case CmpInst::ICMP_SLT: return SE->isKnownNegative(Delta); default: llvm_unreachable("unexpected predicate in isKnownPredicate"); } } // All subscripts are all the same type. // Loop bound may be smaller (e.g., a char). // Should zero extend loop bound, since it's always >= 0. // This routine collects upper bound and extends or truncates if needed. // Truncating is safe when subscripts are known not to wrap. Cases without // nowrap flags should have been rejected earlier. // Return null if no bound available. const SCEV *DependenceInfo::collectUpperBound(const Loop *L, Type *T) const { if (SE->hasLoopInvariantBackedgeTakenCount(L)) { const SCEV *UB = SE->getBackedgeTakenCount(L); return SE->getTruncateOrZeroExtend(UB, T); } return nullptr; } // Calls collectUpperBound(), then attempts to cast it to SCEVConstant. // If the cast fails, returns NULL. const SCEVConstant *DependenceInfo::collectConstantUpperBound(const Loop *L, Type *T) const { if (const SCEV *UB = collectUpperBound(L, T)) return dyn_cast(UB); return nullptr; } /// Returns \p A - \p B if it guaranteed not to signed wrap. Otherwise returns /// nullptr. \p A and \p B must have the same integer type. static const SCEV *minusSCEVNoSignedOverflow(const SCEV *A, const SCEV *B, ScalarEvolution &SE) { if (SE.willNotOverflow(Instruction::Sub, /*Signed=*/true, A, B)) return SE.getMinusSCEV(A, B); return nullptr; } /// Returns \p A * \p B if it guaranteed not to signed wrap. Otherwise returns /// nullptr. \p A and \p B must have the same integer type. static const SCEV *mulSCEVNoSignedOverflow(const SCEV *A, const SCEV *B, ScalarEvolution &SE) { if (SE.willNotOverflow(Instruction::Mul, /*Signed=*/true, A, B)) return SE.getMulExpr(A, B); return nullptr; } /// Returns the absolute value of \p A. In the context of dependence analysis, /// we need an absolute value in a mathematical sense. If \p A is the signed /// minimum value, we cannot represent it unless extending the original type. /// Thus if we cannot prove that \p A is not the signed minimum value, returns /// nullptr. static const SCEV *absSCEVNoSignedOverflow(const SCEV *A, ScalarEvolution &SE) { IntegerType *Ty = cast(A->getType()); if (!Ty) return nullptr; const SCEV *SMin = SE.getConstant(APInt::getSignedMinValue(Ty->getBitWidth())); if (!SE.isKnownPredicate(CmpInst::ICMP_NE, A, SMin)) return nullptr; return SE.getAbsExpr(A, /*IsNSW=*/true); } /// Returns true iff \p Test is enabled. static bool isDependenceTestEnabled(DependenceTestType Test) { if (EnableDependenceTest == DependenceTestType::All) return true; return EnableDependenceTest == Test; } // testZIV - // When we have a pair of subscripts of the form [c1] and [c2], // where c1 and c2 are both loop invariant, we attack it using // the ZIV test. Basically, we test by comparing the two values, // but there are actually three possible results: // 1) the values are equal, so there's a dependence // 2) the values are different, so there's no dependence // 3) the values might be equal, so we have to assume a dependence. // // Return true if dependence disproved. bool DependenceInfo::testZIV(const SCEV *Src, const SCEV *Dst, FullDependence &Result) const { LLVM_DEBUG(dbgs() << " src = " << *Src << "\n"); LLVM_DEBUG(dbgs() << " dst = " << *Dst << "\n"); ++ZIVapplications; if (isKnownPredicate(CmpInst::ICMP_EQ, Src, Dst)) { LLVM_DEBUG(dbgs() << " provably dependent\n"); return false; // provably dependent } if (isKnownPredicate(CmpInst::ICMP_NE, Src, Dst)) { LLVM_DEBUG(dbgs() << " provably independent\n"); ++ZIVindependence; return true; // provably independent } LLVM_DEBUG(dbgs() << " possibly dependent\n"); Result.Consistent = false; return false; // possibly dependent } // strongSIVtest - // From the paper, Practical Dependence Testing, Section 4.2.1 // // When we have a pair of subscripts of the form [c1 + a*i] and [c2 + a*i], // where i is an induction variable, c1 and c2 are loop invariant, // and a is a constant, we can solve it exactly using the Strong SIV test. // // Can prove independence. Failing that, can compute distance (and direction). // In the presence of symbolic terms, we can sometimes make progress. // // If there's a dependence, // // c1 + a*i = c2 + a*i' // // The dependence distance is // // d = i' - i = (c1 - c2)/a // // A dependence only exists if d is an integer and abs(d) <= U, where U is the // loop's upper bound. If a dependence exists, the dependence direction is // defined as // // { < if d > 0 // direction = { = if d = 0 // { > if d < 0 // // Return true if dependence disproved. bool DependenceInfo::strongSIVtest(const SCEV *Coeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *CurSrcLoop, const Loop *CurDstLoop, unsigned Level, FullDependence &Result, bool UnderRuntimeAssumptions) { if (!isDependenceTestEnabled(DependenceTestType::StrongSIV)) return false; LLVM_DEBUG(dbgs() << "\tStrong SIV test\n"); LLVM_DEBUG(dbgs() << "\t Coeff = " << *Coeff); LLVM_DEBUG(dbgs() << ", " << *Coeff->getType() << "\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst); LLVM_DEBUG(dbgs() << ", " << *SrcConst->getType() << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst); LLVM_DEBUG(dbgs() << ", " << *DstConst->getType() << "\n"); ++StrongSIVapplications; assert(0 < Level && Level <= CommonLevels && "level out of range"); Level--; const SCEV *Delta = minusSCEVNoSignedOverflow(SrcConst, DstConst, *SE); if (!Delta) { Result.Consistent = false; return false; } LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta); LLVM_DEBUG(dbgs() << ", " << *Delta->getType() << "\n"); // check that |Delta| < iteration count bool IsDeltaLarge = [&] { const SCEV *UpperBound = collectUpperBound(CurSrcLoop, Delta->getType()); if (!UpperBound) return false; LLVM_DEBUG(dbgs() << "\t UpperBound = " << *UpperBound); LLVM_DEBUG(dbgs() << ", " << *UpperBound->getType() << "\n"); const SCEV *AbsDelta = absSCEVNoSignedOverflow(Delta, *SE); const SCEV *AbsCoeff = absSCEVNoSignedOverflow(Coeff, *SE); if (!AbsDelta || !AbsCoeff) return false; const SCEV *Product = mulSCEVNoSignedOverflow(UpperBound, AbsCoeff, *SE); if (!Product) return false; return isKnownPredicate(CmpInst::ICMP_SGT, AbsDelta, Product); }(); if (IsDeltaLarge) { // Distance greater than trip count - no dependence ++StrongSIVindependence; ++StrongSIVsuccesses; return true; } // Can we compute distance? if (isa(Delta) && isa(Coeff)) { APInt ConstDelta = cast(Delta)->getAPInt(); APInt ConstCoeff = cast(Coeff)->getAPInt(); APInt Distance = ConstDelta; // these need to be initialized APInt Remainder = ConstDelta; APInt::sdivrem(ConstDelta, ConstCoeff, Distance, Remainder); LLVM_DEBUG(dbgs() << "\t Distance = " << Distance << "\n"); LLVM_DEBUG(dbgs() << "\t Remainder = " << Remainder << "\n"); // Make sure Coeff divides Delta exactly if (Remainder != 0) { // Coeff doesn't divide Distance, no dependence ++StrongSIVindependence; ++StrongSIVsuccesses; return true; } Result.DV[Level].Distance = SE->getConstant(Distance); if (Distance.sgt(0)) Result.DV[Level].Direction &= Dependence::DVEntry::LT; else if (Distance.slt(0)) Result.DV[Level].Direction &= Dependence::DVEntry::GT; else Result.DV[Level].Direction &= Dependence::DVEntry::EQ; ++StrongSIVsuccesses; } else if (Delta->isZero()) { // Check if coefficient could be zero. If so, 0/0 is undefined and we // cannot conclude that only same-iteration dependencies exist. // When coeff=0, all iterations access the same location. if (SE->isKnownNonZero(Coeff)) { LLVM_DEBUG( dbgs() << "\t Coefficient proven non-zero by SCEV analysis\n"); } else { // Cannot prove at compile time, would need runtime assumption. if (UnderRuntimeAssumptions) { const SCEVPredicate *Pred = SE->getComparePredicate( ICmpInst::ICMP_NE, Coeff, SE->getZero(Coeff->getType())); Result.Assumptions = Result.Assumptions.getUnionWith(Pred, *SE); LLVM_DEBUG(dbgs() << "\t Added runtime assumption: " << *Coeff << " != 0\n"); } else { // Cannot add runtime assumptions, this test cannot handle this case. // Let more complex tests try. LLVM_DEBUG(dbgs() << "\t Would need runtime assumption " << *Coeff << " != 0, but not allowed. Failing this test.\n"); return false; } } // Since 0/X == 0 (where X is known non-zero or assumed non-zero). Result.DV[Level].Distance = Delta; Result.DV[Level].Direction &= Dependence::DVEntry::EQ; ++StrongSIVsuccesses; } else { if (Coeff->isOne()) { LLVM_DEBUG(dbgs() << "\t Distance = " << *Delta << "\n"); Result.DV[Level].Distance = Delta; // since X/1 == X } else { Result.Consistent = false; } // maybe we can get a useful direction bool DeltaMaybeZero = !SE->isKnownNonZero(Delta); bool DeltaMaybePositive = !SE->isKnownNonPositive(Delta); bool DeltaMaybeNegative = !SE->isKnownNonNegative(Delta); bool CoeffMaybePositive = !SE->isKnownNonPositive(Coeff); bool CoeffMaybeNegative = !SE->isKnownNonNegative(Coeff); // The double negatives above are confusing. // It helps to read !SE->isKnownNonZero(Delta) // as "Delta might be Zero" unsigned NewDirection = Dependence::DVEntry::NONE; if ((DeltaMaybePositive && CoeffMaybePositive) || (DeltaMaybeNegative && CoeffMaybeNegative)) NewDirection = Dependence::DVEntry::LT; if (DeltaMaybeZero) NewDirection |= Dependence::DVEntry::EQ; if ((DeltaMaybeNegative && CoeffMaybePositive) || (DeltaMaybePositive && CoeffMaybeNegative)) NewDirection |= Dependence::DVEntry::GT; if (NewDirection < Result.DV[Level].Direction) ++StrongSIVsuccesses; Result.DV[Level].Direction &= NewDirection; } return false; } // weakCrossingSIVtest - // From the paper, Practical Dependence Testing, Section 4.2.2 // // When we have a pair of subscripts of the form [c1 + a*i] and [c2 - a*i], // where i is an induction variable, c1 and c2 are loop invariant, // and a is a constant, we can solve it exactly using the // Weak-Crossing SIV test. // // Given c1 + a*i = c2 - a*i', we can look for the intersection of // the two lines, where i = i', yielding // // c1 + a*i = c2 - a*i // 2a*i = c2 - c1 // i = (c2 - c1)/2a // // If i < 0, there is no dependence. // If i > upperbound, there is no dependence. // If i = 0 (i.e., if c1 = c2), there's a dependence with distance = 0. // If i = upperbound, there's a dependence with distance = 0. // If i is integral, there's a dependence (all directions). // If the non-integer part = 1/2, there's a dependence (<> directions). // Otherwise, there's no dependence. // // Can prove independence. Failing that, // can sometimes refine the directions. // Can determine iteration for splitting. // // Return true if dependence disproved. bool DependenceInfo::weakCrossingSIVtest(const SCEV *Coeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *CurSrcLoop, const Loop *CurDstLoop, unsigned Level, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::WeakCrossingSIV)) return false; LLVM_DEBUG(dbgs() << "\tWeak-Crossing SIV test\n"); LLVM_DEBUG(dbgs() << "\t Coeff = " << *Coeff << "\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst << "\n"); ++WeakCrossingSIVapplications; assert(0 < Level && Level <= CommonLevels && "Level out of range"); Level--; Result.Consistent = false; const SCEV *Delta = SE->getMinusSCEV(DstConst, SrcConst); LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); if (Delta->isZero()) { Result.DV[Level].Direction &= ~Dependence::DVEntry::LT; Result.DV[Level].Direction &= ~Dependence::DVEntry::GT; ++WeakCrossingSIVsuccesses; if (!Result.DV[Level].Direction) { ++WeakCrossingSIVindependence; return true; } Result.DV[Level].Distance = Delta; // = 0 return false; } const SCEVConstant *ConstCoeff = dyn_cast(Coeff); if (!ConstCoeff) return false; if (SE->isKnownNegative(ConstCoeff)) { ConstCoeff = dyn_cast(SE->getNegativeSCEV(ConstCoeff)); assert(ConstCoeff && "dynamic cast of negative of ConstCoeff should yield constant"); Delta = SE->getNegativeSCEV(Delta); } assert(SE->isKnownPositive(ConstCoeff) && "ConstCoeff should be positive"); const SCEVConstant *ConstDelta = dyn_cast(Delta); if (!ConstDelta) return false; // We're certain that ConstCoeff > 0; therefore, // if Delta < 0, then no dependence. LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); LLVM_DEBUG(dbgs() << "\t ConstCoeff = " << *ConstCoeff << "\n"); if (SE->isKnownNegative(Delta)) { // No dependence, Delta < 0 ++WeakCrossingSIVindependence; ++WeakCrossingSIVsuccesses; return true; } // We're certain that Delta > 0 and ConstCoeff > 0. // Check Delta/(2*ConstCoeff) against upper loop bound if (const SCEV *UpperBound = collectUpperBound(CurSrcLoop, Delta->getType())) { LLVM_DEBUG(dbgs() << "\t UpperBound = " << *UpperBound << "\n"); const SCEV *ConstantTwo = SE->getConstant(UpperBound->getType(), 2); const SCEV *ML = SE->getMulExpr(SE->getMulExpr(ConstCoeff, UpperBound), ConstantTwo); LLVM_DEBUG(dbgs() << "\t ML = " << *ML << "\n"); if (isKnownPredicate(CmpInst::ICMP_SGT, Delta, ML)) { // Delta too big, no dependence ++WeakCrossingSIVindependence; ++WeakCrossingSIVsuccesses; return true; } if (isKnownPredicate(CmpInst::ICMP_EQ, Delta, ML)) { // i = i' = UB Result.DV[Level].Direction &= ~Dependence::DVEntry::LT; Result.DV[Level].Direction &= ~Dependence::DVEntry::GT; ++WeakCrossingSIVsuccesses; if (!Result.DV[Level].Direction) { ++WeakCrossingSIVindependence; return true; } Result.DV[Level].Distance = SE->getZero(Delta->getType()); return false; } } // check that Coeff divides Delta APInt APDelta = ConstDelta->getAPInt(); APInt APCoeff = ConstCoeff->getAPInt(); APInt Distance = APDelta; // these need to be initialzed APInt Remainder = APDelta; APInt::sdivrem(APDelta, APCoeff, Distance, Remainder); LLVM_DEBUG(dbgs() << "\t Remainder = " << Remainder << "\n"); if (Remainder != 0) { // Coeff doesn't divide Delta, no dependence ++WeakCrossingSIVindependence; ++WeakCrossingSIVsuccesses; return true; } LLVM_DEBUG(dbgs() << "\t Distance = " << Distance << "\n"); // if 2*Coeff doesn't divide Delta, then the equal direction isn't possible APInt Two = APInt(Distance.getBitWidth(), 2, true); Remainder = Distance.srem(Two); LLVM_DEBUG(dbgs() << "\t Remainder = " << Remainder << "\n"); if (Remainder != 0) { // Equal direction isn't possible Result.DV[Level].Direction &= ~Dependence::DVEntry::EQ; ++WeakCrossingSIVsuccesses; } return false; } // Kirch's algorithm, from // // Optimizing Supercompilers for Supercomputers // Michael Wolfe // MIT Press, 1989 // // Program 2.1, page 29. // Computes the GCD of AM and BM. // Also finds a solution to the equation ax - by = gcd(a, b). // Returns true if dependence disproved; i.e., gcd does not divide Delta. // // We don't use OverflowSafeSignedAPInt here because it's known that this // algorithm doesn't overflow. static bool findGCD(unsigned Bits, const APInt &AM, const APInt &BM, const APInt &Delta, APInt &G, APInt &X, APInt &Y) { APInt A0(Bits, 1, true), A1(Bits, 0, true); APInt B0(Bits, 0, true), B1(Bits, 1, true); APInt G0 = AM.abs(); APInt G1 = BM.abs(); APInt Q = G0; // these need to be initialized APInt R = G0; APInt::sdivrem(G0, G1, Q, R); while (R != 0) { // clang-format off APInt A2 = A0 - Q*A1; A0 = A1; A1 = A2; APInt B2 = B0 - Q*B1; B0 = B1; B1 = B2; G0 = G1; G1 = R; // clang-format on APInt::sdivrem(G0, G1, Q, R); } G = G1; LLVM_DEBUG(dbgs() << "\t GCD = " << G << "\n"); X = AM.slt(0) ? -A1 : A1; Y = BM.slt(0) ? B1 : -B1; // make sure gcd divides Delta R = Delta.srem(G); if (R != 0) return true; // gcd doesn't divide Delta, no dependence Q = Delta.sdiv(G); return false; } static OverflowSafeSignedAPInt floorOfQuotient(const OverflowSafeSignedAPInt &OA, const OverflowSafeSignedAPInt &OB) { if (!OA || !OB) return OverflowSafeSignedAPInt(); APInt A = *OA; APInt B = *OB; APInt Q = A; // these need to be initialized APInt R = A; APInt::sdivrem(A, B, Q, R); if (R == 0) return Q; if ((A.sgt(0) && B.sgt(0)) || (A.slt(0) && B.slt(0))) return Q; return OverflowSafeSignedAPInt(Q) - 1; } static OverflowSafeSignedAPInt ceilingOfQuotient(const OverflowSafeSignedAPInt &OA, const OverflowSafeSignedAPInt &OB) { if (!OA || !OB) return OverflowSafeSignedAPInt(); APInt A = *OA; APInt B = *OB; APInt Q = A; // these need to be initialized APInt R = A; APInt::sdivrem(A, B, Q, R); if (R == 0) return Q; if ((A.sgt(0) && B.sgt(0)) || (A.slt(0) && B.slt(0))) return OverflowSafeSignedAPInt(Q) + 1; return Q; } /// Given an affine expression of the form A*k + B, where k is an arbitrary /// integer, infer the possible range of k based on the known range of the /// affine expression. If we know A*k + B is non-negative, i.e., /// /// A*k + B >= 0 /// /// we can derive the following inequalities for k when A is positive: /// /// k >= -B / A /// /// Since k is an integer, it means k is greater than or equal to the /// ceil(-B / A). /// /// If the upper bound of the affine expression \p UB is passed, the following /// inequality can be derived as well: /// /// A*k + B <= UB /// /// which leads to: /// /// k <= (UB - B) / A /// /// Again, as k is an integer, it means k is less than or equal to the /// floor((UB - B) / A). /// /// The similar logic applies when A is negative, but the inequalities sign flip /// while working with them. /// /// Preconditions: \p A is non-zero, and we know A*k + B is non-negative. static std::pair inferDomainOfAffine(OverflowSafeSignedAPInt A, OverflowSafeSignedAPInt B, OverflowSafeSignedAPInt UB) { assert(A && B && "A and B must be available"); assert(*A != 0 && "A must be non-zero"); OverflowSafeSignedAPInt TL, TU; if (A->sgt(0)) { TL = ceilingOfQuotient(-B, A); LLVM_DEBUG(if (TL) dbgs() << "\t Possible TL = " << *TL << "\n"); // New bound check - modification to Banerjee's e3 check TU = floorOfQuotient(UB - B, A); LLVM_DEBUG(if (TU) dbgs() << "\t Possible TU = " << *TU << "\n"); } else { TU = floorOfQuotient(-B, A); LLVM_DEBUG(if (TU) dbgs() << "\t Possible TU = " << *TU << "\n"); // New bound check - modification to Banerjee's e3 check TL = ceilingOfQuotient(UB - B, A); LLVM_DEBUG(if (TL) dbgs() << "\t Possible TL = " << *TL << "\n"); } return std::make_pair(TL, TU); } // exactSIVtest - // When we have a pair of subscripts of the form [c1 + a1*i] and [c2 + a2*i], // where i is an induction variable, c1 and c2 are loop invariant, and a1 // and a2 are constant, we can solve it exactly using an algorithm developed // by Banerjee and Wolfe. See Algorithm 6.2.1 (case 2.5) in: // // Dependence Analysis for Supercomputing // Utpal Banerjee // Kluwer Academic Publishers, 1988 // // It's slower than the specialized tests (strong SIV, weak-zero SIV, etc), // so use them if possible. They're also a bit better with symbolics and, // in the case of the strong SIV test, can compute Distances. // // Return true if dependence disproved. // // This is a modified version of the original Banerjee algorithm. The original // only tested whether Dst depends on Src. This algorithm extends that and // returns all the dependencies that exist between Dst and Src. bool DependenceInfo::exactSIVtest(const SCEV *SrcCoeff, const SCEV *DstCoeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *CurSrcLoop, const Loop *CurDstLoop, unsigned Level, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::ExactSIV)) return false; LLVM_DEBUG(dbgs() << "\tExact SIV test\n"); LLVM_DEBUG(dbgs() << "\t SrcCoeff = " << *SrcCoeff << " = AM\n"); LLVM_DEBUG(dbgs() << "\t DstCoeff = " << *DstCoeff << " = BM\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst << "\n"); ++ExactSIVapplications; assert(0 < Level && Level <= CommonLevels && "Level out of range"); Level--; Result.Consistent = false; const SCEV *Delta = minusSCEVNoSignedOverflow(DstConst, SrcConst, *SE); if (!Delta) return false; LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); const SCEVConstant *ConstDelta = dyn_cast(Delta); const SCEVConstant *ConstSrcCoeff = dyn_cast(SrcCoeff); const SCEVConstant *ConstDstCoeff = dyn_cast(DstCoeff); if (!ConstDelta || !ConstSrcCoeff || !ConstDstCoeff) return false; // find gcd APInt G, X, Y; APInt AM = ConstSrcCoeff->getAPInt(); APInt BM = ConstDstCoeff->getAPInt(); APInt CM = ConstDelta->getAPInt(); unsigned Bits = AM.getBitWidth(); if (findGCD(Bits, AM, BM, CM, G, X, Y)) { // gcd doesn't divide Delta, no dependence ++ExactSIVindependence; ++ExactSIVsuccesses; return true; } LLVM_DEBUG(dbgs() << "\t X = " << X << ", Y = " << Y << "\n"); // since SCEV construction normalizes, LM = 0 std::optional UM; // UM is perhaps unavailable, let's check if (const SCEVConstant *CUB = collectConstantUpperBound(CurSrcLoop, Delta->getType())) { UM = CUB->getAPInt(); LLVM_DEBUG(dbgs() << "\t UM = " << *UM << "\n"); } APInt TU(APInt::getSignedMaxValue(Bits)); APInt TL(APInt::getSignedMinValue(Bits)); APInt TC = CM.sdiv(G); APInt TX = X * TC; APInt TY = Y * TC; LLVM_DEBUG(dbgs() << "\t TC = " << TC << "\n"); LLVM_DEBUG(dbgs() << "\t TX = " << TX << "\n"); LLVM_DEBUG(dbgs() << "\t TY = " << TY << "\n"); APInt TB = BM.sdiv(G); APInt TA = AM.sdiv(G); // At this point, we have the following equations: // // TA*i0 - TB*i1 = TC // // Also, we know that the all pairs of (i0, i1) can be expressed as: // // (TX + k*TB, TY + k*TA) // // where k is an arbitrary integer. auto [TL0, TU0] = inferDomainOfAffine(TB, TX, UM); auto [TL1, TU1] = inferDomainOfAffine(TA, TY, UM); auto CreateVec = [](const OverflowSafeSignedAPInt &V0, const OverflowSafeSignedAPInt &V1) { SmallVector Vec; if (V0) Vec.push_back(*V0); if (V1) Vec.push_back(*V1); return Vec; }; SmallVector TLVec = CreateVec(TL0, TL1); SmallVector TUVec = CreateVec(TU0, TU1); LLVM_DEBUG(dbgs() << "\t TA = " << TA << "\n"); LLVM_DEBUG(dbgs() << "\t TB = " << TB << "\n"); if (TLVec.empty() || TUVec.empty()) return false; TL = APIntOps::smax(TLVec.front(), TLVec.back()); TU = APIntOps::smin(TUVec.front(), TUVec.back()); LLVM_DEBUG(dbgs() << "\t TL = " << TL << "\n"); LLVM_DEBUG(dbgs() << "\t TU = " << TU << "\n"); if (TL.sgt(TU)) { ++ExactSIVindependence; ++ExactSIVsuccesses; return true; } // explore directions unsigned NewDirection = Dependence::DVEntry::NONE; OverflowSafeSignedAPInt LowerDistance, UpperDistance; OverflowSafeSignedAPInt OTY(TY), OTX(TX), OTA(TA), OTB(TB), OTL(TL), OTU(TU); // NOTE: It's unclear whether these calculations can overflow. At the moment, // we conservatively assume they can. if (TA.sgt(TB)) { LowerDistance = (OTY - OTX) + (OTA - OTB) * OTL; UpperDistance = (OTY - OTX) + (OTA - OTB) * OTU; } else { LowerDistance = (OTY - OTX) + (OTA - OTB) * OTU; UpperDistance = (OTY - OTX) + (OTA - OTB) * OTL; } if (!LowerDistance || !UpperDistance) return false; LLVM_DEBUG(dbgs() << "\t LowerDistance = " << *LowerDistance << "\n"); LLVM_DEBUG(dbgs() << "\t UpperDistance = " << *UpperDistance << "\n"); if (LowerDistance->sle(0) && UpperDistance->sge(0)) { NewDirection |= Dependence::DVEntry::EQ; ++ExactSIVsuccesses; } if (LowerDistance->slt(0)) { NewDirection |= Dependence::DVEntry::GT; ++ExactSIVsuccesses; } if (UpperDistance->sgt(0)) { NewDirection |= Dependence::DVEntry::LT; ++ExactSIVsuccesses; } // finished Result.DV[Level].Direction &= NewDirection; if (Result.DV[Level].Direction == Dependence::DVEntry::NONE) ++ExactSIVindependence; LLVM_DEBUG(dbgs() << "\t Result = "); LLVM_DEBUG(Result.dump(dbgs())); return Result.DV[Level].Direction == Dependence::DVEntry::NONE; } // Return true if the divisor evenly divides the dividend. static bool isRemainderZero(const SCEVConstant *Dividend, const SCEVConstant *Divisor) { const APInt &ConstDividend = Dividend->getAPInt(); const APInt &ConstDivisor = Divisor->getAPInt(); return ConstDividend.srem(ConstDivisor) == 0; } // weakZeroSrcSIVtest - // From the paper, Practical Dependence Testing, Section 4.2.2 // // When we have a pair of subscripts of the form [c1] and [c2 + a*i], // where i is an induction variable, c1 and c2 are loop invariant, // and a is a constant, we can solve it exactly using the // Weak-Zero SIV test. // // Given // // c1 = c2 + a*i // // we get // // (c1 - c2)/a = i // // If i is not an integer, there's no dependence. // If i < 0 or > UB, there's no dependence. // If i = 0, the direction is >= and peeling the // 1st iteration will break the dependence. // If i = UB, the direction is <= and peeling the // last iteration will break the dependence. // Otherwise, the direction is *. // // Can prove independence. Failing that, we can sometimes refine // the directions. Can sometimes show that first or last // iteration carries all the dependences (so worth peeling). // // (see also weakZeroDstSIVtest) // // Return true if dependence disproved. bool DependenceInfo::weakZeroSrcSIVtest(const SCEV *DstCoeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *CurSrcLoop, const Loop *CurDstLoop, unsigned Level, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::WeakZeroSIV)) return false; // For the WeakSIV test, it's possible the loop isn't common to // the Src and Dst loops. If it isn't, then there's no need to // record a direction. LLVM_DEBUG(dbgs() << "\tWeak-Zero (src) SIV test\n"); LLVM_DEBUG(dbgs() << "\t DstCoeff = " << *DstCoeff << "\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst << "\n"); ++WeakZeroSIVapplications; assert(0 < Level && Level <= MaxLevels && "Level out of range"); Level--; Result.Consistent = false; const SCEV *Delta = SE->getMinusSCEV(SrcConst, DstConst); LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); if (isKnownPredicate(CmpInst::ICMP_EQ, SrcConst, DstConst)) { if (Level < CommonLevels) { Result.DV[Level].Direction &= Dependence::DVEntry::GE; Result.DV[Level].PeelFirst = true; ++WeakZeroSIVsuccesses; } return false; // dependences caused by first iteration } const SCEVConstant *ConstCoeff = dyn_cast(DstCoeff); if (!ConstCoeff) return false; // Since ConstCoeff is constant, !isKnownNegative means it's non-negative. // TODO: Bail out if it's a signed minimum value. const SCEV *AbsCoeff = SE->isKnownNegative(ConstCoeff) ? SE->getNegativeSCEV(ConstCoeff) : ConstCoeff; const SCEV *NewDelta = SE->isKnownNegative(ConstCoeff) ? SE->getNegativeSCEV(Delta) : Delta; // check that Delta/SrcCoeff < iteration count // really check NewDelta < count*AbsCoeff if (const SCEV *UpperBound = collectUpperBound(CurSrcLoop, Delta->getType())) { LLVM_DEBUG(dbgs() << "\t UpperBound = " << *UpperBound << "\n"); const SCEV *Product = SE->getMulExpr(AbsCoeff, UpperBound); if (isKnownPredicate(CmpInst::ICMP_SGT, NewDelta, Product)) { ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } if (isKnownPredicate(CmpInst::ICMP_EQ, NewDelta, Product)) { // dependences caused by last iteration if (Level < CommonLevels) { Result.DV[Level].Direction &= Dependence::DVEntry::LE; Result.DV[Level].PeelLast = true; ++WeakZeroSIVsuccesses; } return false; } } // check that Delta/SrcCoeff >= 0 // really check that NewDelta >= 0 if (SE->isKnownNegative(NewDelta)) { // No dependence, newDelta < 0 ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } // if SrcCoeff doesn't divide Delta, then no dependence if (isa(Delta) && !isRemainderZero(cast(Delta), ConstCoeff)) { ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } return false; } // weakZeroDstSIVtest - // From the paper, Practical Dependence Testing, Section 4.2.2 // // When we have a pair of subscripts of the form [c1 + a*i] and [c2], // where i is an induction variable, c1 and c2 are loop invariant, // and a is a constant, we can solve it exactly using the // Weak-Zero SIV test. // // Given // // c1 + a*i = c2 // // we get // // i = (c2 - c1)/a // // If i is not an integer, there's no dependence. // If i < 0 or > UB, there's no dependence. // If i = 0, the direction is <= and peeling the // 1st iteration will break the dependence. // If i = UB, the direction is >= and peeling the // last iteration will break the dependence. // Otherwise, the direction is *. // // Can prove independence. Failing that, we can sometimes refine // the directions. Can sometimes show that first or last // iteration carries all the dependences (so worth peeling). // // (see also weakZeroSrcSIVtest) // // Return true if dependence disproved. bool DependenceInfo::weakZeroDstSIVtest(const SCEV *SrcCoeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *CurSrcLoop, const Loop *CurDstLoop, unsigned Level, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::WeakZeroSIV)) return false; // For the WeakSIV test, it's possible the loop isn't common to the // Src and Dst loops. If it isn't, then there's no need to record a direction. LLVM_DEBUG(dbgs() << "\tWeak-Zero (dst) SIV test\n"); LLVM_DEBUG(dbgs() << "\t SrcCoeff = " << *SrcCoeff << "\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst << "\n"); ++WeakZeroSIVapplications; assert(0 < Level && Level <= SrcLevels && "Level out of range"); Level--; Result.Consistent = false; const SCEV *Delta = SE->getMinusSCEV(DstConst, SrcConst); LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); if (isKnownPredicate(CmpInst::ICMP_EQ, DstConst, SrcConst)) { if (Level < CommonLevels) { Result.DV[Level].Direction &= Dependence::DVEntry::LE; Result.DV[Level].PeelFirst = true; ++WeakZeroSIVsuccesses; } return false; // dependences caused by first iteration } const SCEVConstant *ConstCoeff = dyn_cast(SrcCoeff); if (!ConstCoeff) return false; // Since ConstCoeff is constant, !isKnownNegative means it's non-negative. // TODO: Bail out if it's a signed minimum value. const SCEV *AbsCoeff = SE->isKnownNegative(ConstCoeff) ? SE->getNegativeSCEV(ConstCoeff) : ConstCoeff; const SCEV *NewDelta = SE->isKnownNegative(ConstCoeff) ? SE->getNegativeSCEV(Delta) : Delta; // check that Delta/SrcCoeff < iteration count // really check NewDelta < count*AbsCoeff if (const SCEV *UpperBound = collectUpperBound(CurSrcLoop, Delta->getType())) { LLVM_DEBUG(dbgs() << "\t UpperBound = " << *UpperBound << "\n"); const SCEV *Product = SE->getMulExpr(AbsCoeff, UpperBound); if (isKnownPredicate(CmpInst::ICMP_SGT, NewDelta, Product)) { ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } if (isKnownPredicate(CmpInst::ICMP_EQ, NewDelta, Product)) { // dependences caused by last iteration if (Level < CommonLevels) { Result.DV[Level].Direction &= Dependence::DVEntry::GE; Result.DV[Level].PeelLast = true; ++WeakZeroSIVsuccesses; } return false; } } // check that Delta/SrcCoeff >= 0 // really check that NewDelta >= 0 if (SE->isKnownNegative(NewDelta)) { // No dependence, newDelta < 0 ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } // if SrcCoeff doesn't divide Delta, then no dependence if (isa(Delta) && !isRemainderZero(cast(Delta), ConstCoeff)) { ++WeakZeroSIVindependence; ++WeakZeroSIVsuccesses; return true; } return false; } // exactRDIVtest - Tests the RDIV subscript pair for dependence. // Things of the form [c1 + a*i] and [c2 + b*j], // where i and j are induction variable, c1 and c2 are loop invariant, // and a and b are constants. // Returns true if any possible dependence is disproved. // Marks the result as inconsistent. // Works in some cases that symbolicRDIVtest doesn't, and vice versa. bool DependenceInfo::exactRDIVtest(const SCEV *SrcCoeff, const SCEV *DstCoeff, const SCEV *SrcConst, const SCEV *DstConst, const Loop *SrcLoop, const Loop *DstLoop, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::ExactRDIV)) return false; LLVM_DEBUG(dbgs() << "\tExact RDIV test\n"); LLVM_DEBUG(dbgs() << "\t SrcCoeff = " << *SrcCoeff << " = AM\n"); LLVM_DEBUG(dbgs() << "\t DstCoeff = " << *DstCoeff << " = BM\n"); LLVM_DEBUG(dbgs() << "\t SrcConst = " << *SrcConst << "\n"); LLVM_DEBUG(dbgs() << "\t DstConst = " << *DstConst << "\n"); ++ExactRDIVapplications; Result.Consistent = false; const SCEV *Delta = SE->getMinusSCEV(DstConst, SrcConst); LLVM_DEBUG(dbgs() << "\t Delta = " << *Delta << "\n"); const SCEVConstant *ConstDelta = dyn_cast(Delta); const SCEVConstant *ConstSrcCoeff = dyn_cast(SrcCoeff); const SCEVConstant *ConstDstCoeff = dyn_cast(DstCoeff); if (!ConstDelta || !ConstSrcCoeff || !ConstDstCoeff) return false; // find gcd APInt G, X, Y; APInt AM = ConstSrcCoeff->getAPInt(); APInt BM = ConstDstCoeff->getAPInt(); APInt CM = ConstDelta->getAPInt(); unsigned Bits = AM.getBitWidth(); if (findGCD(Bits, AM, BM, CM, G, X, Y)) { // gcd doesn't divide Delta, no dependence ++ExactRDIVindependence; return true; } LLVM_DEBUG(dbgs() << "\t X = " << X << ", Y = " << Y << "\n"); // since SCEV construction seems to normalize, LM = 0 std::optional SrcUM; // SrcUM is perhaps unavailable, let's check if (const SCEVConstant *UpperBound = collectConstantUpperBound(SrcLoop, Delta->getType())) { SrcUM = UpperBound->getAPInt(); LLVM_DEBUG(dbgs() << "\t SrcUM = " << *SrcUM << "\n"); } std::optional DstUM; // UM is perhaps unavailable, let's check if (const SCEVConstant *UpperBound = collectConstantUpperBound(DstLoop, Delta->getType())) { DstUM = UpperBound->getAPInt(); LLVM_DEBUG(dbgs() << "\t DstUM = " << *DstUM << "\n"); } APInt TU(APInt::getSignedMaxValue(Bits)); APInt TL(APInt::getSignedMinValue(Bits)); APInt TC = CM.sdiv(G); APInt TX = X * TC; APInt TY = Y * TC; LLVM_DEBUG(dbgs() << "\t TC = " << TC << "\n"); LLVM_DEBUG(dbgs() << "\t TX = " << TX << "\n"); LLVM_DEBUG(dbgs() << "\t TY = " << TY << "\n"); APInt TB = BM.sdiv(G); APInt TA = AM.sdiv(G); // At this point, we have the following equations: // // TA*i - TB*j = TC // // Also, we know that the all pairs of (i, j) can be expressed as: // // (TX + k*TB, TY + k*TA) // // where k is an arbitrary integer. auto [TL0, TU0] = inferDomainOfAffine(TB, TX, SrcUM); auto [TL1, TU1] = inferDomainOfAffine(TA, TY, DstUM); LLVM_DEBUG(dbgs() << "\t TA = " << TA << "\n"); LLVM_DEBUG(dbgs() << "\t TB = " << TB << "\n"); auto CreateVec = [](const OverflowSafeSignedAPInt &V0, const OverflowSafeSignedAPInt &V1) { SmallVector Vec; if (V0) Vec.push_back(*V0); if (V1) Vec.push_back(*V1); return Vec; }; SmallVector TLVec = CreateVec(TL0, TL1); SmallVector TUVec = CreateVec(TU0, TU1); if (TLVec.empty() || TUVec.empty()) return false; TL = APIntOps::smax(TLVec.front(), TLVec.back()); TU = APIntOps::smin(TUVec.front(), TUVec.back()); LLVM_DEBUG(dbgs() << "\t TL = " << TL << "\n"); LLVM_DEBUG(dbgs() << "\t TU = " << TU << "\n"); if (TL.sgt(TU)) ++ExactRDIVindependence; return TL.sgt(TU); } // symbolicRDIVtest - // In Section 4.5 of the Practical Dependence Testing paper,the authors // introduce a special case of Banerjee's Inequalities (also called the // Extreme-Value Test) that can handle some of the SIV and RDIV cases, // particularly cases with symbolics. Since it's only able to disprove // dependence (not compute distances or directions), we'll use it as a // fall back for the other tests. // // When we have a pair of subscripts of the form [c1 + a1*i] and [c2 + a2*j] // where i and j are induction variables and c1 and c2 are loop invariants, // we can use the symbolic tests to disprove some dependences, serving as a // backup for the RDIV test. Note that i and j can be the same variable, // letting this test serve as a backup for the various SIV tests. // // For a dependence to exist, c1 + a1*i must equal c2 + a2*j for some // 0 <= i <= N1 and some 0 <= j <= N2, where N1 and N2 are the (normalized) // loop bounds for the i and j loops, respectively. So, ... // // c1 + a1*i = c2 + a2*j // a1*i - a2*j = c2 - c1 // // To test for a dependence, we compute c2 - c1 and make sure it's in the // range of the maximum and minimum possible values of a1*i - a2*j. // Considering the signs of a1 and a2, we have 4 possible cases: // // 1) If a1 >= 0 and a2 >= 0, then // a1*0 - a2*N2 <= c2 - c1 <= a1*N1 - a2*0 // -a2*N2 <= c2 - c1 <= a1*N1 // // 2) If a1 >= 0 and a2 <= 0, then // a1*0 - a2*0 <= c2 - c1 <= a1*N1 - a2*N2 // 0 <= c2 - c1 <= a1*N1 - a2*N2 // // 3) If a1 <= 0 and a2 >= 0, then // a1*N1 - a2*N2 <= c2 - c1 <= a1*0 - a2*0 // a1*N1 - a2*N2 <= c2 - c1 <= 0 // // 4) If a1 <= 0 and a2 <= 0, then // a1*N1 - a2*0 <= c2 - c1 <= a1*0 - a2*N2 // a1*N1 <= c2 - c1 <= -a2*N2 // // return true if dependence disproved bool DependenceInfo::symbolicRDIVtest(const SCEV *A1, const SCEV *A2, const SCEV *C1, const SCEV *C2, const Loop *Loop1, const Loop *Loop2) const { if (!isDependenceTestEnabled(DependenceTestType::SymbolicRDIV)) return false; ++SymbolicRDIVapplications; LLVM_DEBUG(dbgs() << "\ttry symbolic RDIV test\n"); LLVM_DEBUG(dbgs() << "\t A1 = " << *A1); LLVM_DEBUG(dbgs() << ", type = " << *A1->getType() << "\n"); LLVM_DEBUG(dbgs() << "\t A2 = " << *A2 << "\n"); LLVM_DEBUG(dbgs() << "\t C1 = " << *C1 << "\n"); LLVM_DEBUG(dbgs() << "\t C2 = " << *C2 << "\n"); const SCEV *N1 = collectUpperBound(Loop1, A1->getType()); const SCEV *N2 = collectUpperBound(Loop2, A1->getType()); LLVM_DEBUG(if (N1) dbgs() << "\t N1 = " << *N1 << "\n"); LLVM_DEBUG(if (N2) dbgs() << "\t N2 = " << *N2 << "\n"); const SCEV *C2_C1 = SE->getMinusSCEV(C2, C1); const SCEV *C1_C2 = SE->getMinusSCEV(C1, C2); LLVM_DEBUG(dbgs() << "\t C2 - C1 = " << *C2_C1 << "\n"); LLVM_DEBUG(dbgs() << "\t C1 - C2 = " << *C1_C2 << "\n"); if (SE->isKnownNonNegative(A1)) { if (SE->isKnownNonNegative(A2)) { // A1 >= 0 && A2 >= 0 if (N1) { // make sure that c2 - c1 <= a1*N1 const SCEV *A1N1 = SE->getMulExpr(A1, N1); LLVM_DEBUG(dbgs() << "\t A1*N1 = " << *A1N1 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SGT, C2_C1, A1N1)) { ++SymbolicRDIVindependence; return true; } } if (N2) { // make sure that -a2*N2 <= c2 - c1, or a2*N2 >= c1 - c2 const SCEV *A2N2 = SE->getMulExpr(A2, N2); LLVM_DEBUG(dbgs() << "\t A2*N2 = " << *A2N2 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SLT, A2N2, C1_C2)) { ++SymbolicRDIVindependence; return true; } } } else if (SE->isKnownNonPositive(A2)) { // a1 >= 0 && a2 <= 0 if (N1 && N2) { // make sure that c2 - c1 <= a1*N1 - a2*N2 const SCEV *A1N1 = SE->getMulExpr(A1, N1); const SCEV *A2N2 = SE->getMulExpr(A2, N2); const SCEV *A1N1_A2N2 = SE->getMinusSCEV(A1N1, A2N2); LLVM_DEBUG(dbgs() << "\t A1*N1 - A2*N2 = " << *A1N1_A2N2 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SGT, C2_C1, A1N1_A2N2)) { ++SymbolicRDIVindependence; return true; } } // make sure that 0 <= c2 - c1 if (SE->isKnownNegative(C2_C1)) { ++SymbolicRDIVindependence; return true; } } } else if (SE->isKnownNonPositive(A1)) { if (SE->isKnownNonNegative(A2)) { // a1 <= 0 && a2 >= 0 if (N1 && N2) { // make sure that a1*N1 - a2*N2 <= c2 - c1 const SCEV *A1N1 = SE->getMulExpr(A1, N1); const SCEV *A2N2 = SE->getMulExpr(A2, N2); const SCEV *A1N1_A2N2 = SE->getMinusSCEV(A1N1, A2N2); LLVM_DEBUG(dbgs() << "\t A1*N1 - A2*N2 = " << *A1N1_A2N2 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SGT, A1N1_A2N2, C2_C1)) { ++SymbolicRDIVindependence; return true; } } // make sure that c2 - c1 <= 0 if (SE->isKnownPositive(C2_C1)) { ++SymbolicRDIVindependence; return true; } } else if (SE->isKnownNonPositive(A2)) { // a1 <= 0 && a2 <= 0 if (N1) { // make sure that a1*N1 <= c2 - c1 const SCEV *A1N1 = SE->getMulExpr(A1, N1); LLVM_DEBUG(dbgs() << "\t A1*N1 = " << *A1N1 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SGT, A1N1, C2_C1)) { ++SymbolicRDIVindependence; return true; } } if (N2) { // make sure that c2 - c1 <= -a2*N2, or c1 - c2 >= a2*N2 const SCEV *A2N2 = SE->getMulExpr(A2, N2); LLVM_DEBUG(dbgs() << "\t A2*N2 = " << *A2N2 << "\n"); if (isKnownPredicate(CmpInst::ICMP_SLT, C1_C2, A2N2)) { ++SymbolicRDIVindependence; return true; } } } } return false; } // testSIV - // When we have a pair of subscripts of the form [c1 + a1*i] and [c2 - a2*i] // where i is an induction variable, c1 and c2 are loop invariant, and a1 and // a2 are constant, we attack it with an SIV test. While they can all be // solved with the Exact SIV test, it's worthwhile to use simpler tests when // they apply; they're cheaper and sometimes more precise. // // Return true if dependence disproved. bool DependenceInfo::testSIV(const SCEV *Src, const SCEV *Dst, unsigned &Level, FullDependence &Result, bool UnderRuntimeAssumptions) { LLVM_DEBUG(dbgs() << " src = " << *Src << "\n"); LLVM_DEBUG(dbgs() << " dst = " << *Dst << "\n"); const SCEVAddRecExpr *SrcAddRec = dyn_cast(Src); const SCEVAddRecExpr *DstAddRec = dyn_cast(Dst); if (SrcAddRec && DstAddRec) { const SCEV *SrcConst = SrcAddRec->getStart(); const SCEV *DstConst = DstAddRec->getStart(); const SCEV *SrcCoeff = SrcAddRec->getStepRecurrence(*SE); const SCEV *DstCoeff = DstAddRec->getStepRecurrence(*SE); const Loop *CurSrcLoop = SrcAddRec->getLoop(); const Loop *CurDstLoop = DstAddRec->getLoop(); assert(haveSameSD(CurSrcLoop, CurDstLoop) && "Loops in the SIV test should have the same iteration space and " "depth"); Level = mapSrcLoop(CurSrcLoop); bool disproven; if (SrcCoeff == DstCoeff) disproven = strongSIVtest(SrcCoeff, SrcConst, DstConst, CurSrcLoop, CurDstLoop, Level, Result, UnderRuntimeAssumptions); else if (SrcCoeff == SE->getNegativeSCEV(DstCoeff)) disproven = weakCrossingSIVtest(SrcCoeff, SrcConst, DstConst, CurSrcLoop, CurDstLoop, Level, Result); else disproven = exactSIVtest(SrcCoeff, DstCoeff, SrcConst, DstConst, CurSrcLoop, CurDstLoop, Level, Result); return disproven || gcdMIVtest(Src, Dst, Result) || symbolicRDIVtest(SrcCoeff, DstCoeff, SrcConst, DstConst, CurSrcLoop, CurDstLoop); } if (SrcAddRec) { const SCEV *SrcConst = SrcAddRec->getStart(); const SCEV *SrcCoeff = SrcAddRec->getStepRecurrence(*SE); const SCEV *DstConst = Dst; const Loop *CurSrcLoop = SrcAddRec->getLoop(); Level = mapSrcLoop(CurSrcLoop); return weakZeroDstSIVtest(SrcCoeff, SrcConst, DstConst, CurSrcLoop, CurSrcLoop, Level, Result) || gcdMIVtest(Src, Dst, Result); } if (DstAddRec) { const SCEV *DstConst = DstAddRec->getStart(); const SCEV *DstCoeff = DstAddRec->getStepRecurrence(*SE); const SCEV *SrcConst = Src; const Loop *CurDstLoop = DstAddRec->getLoop(); Level = mapDstLoop(CurDstLoop); return weakZeroSrcSIVtest(DstCoeff, SrcConst, DstConst, CurDstLoop, CurDstLoop, Level, Result) || gcdMIVtest(Src, Dst, Result); } llvm_unreachable("SIV test expected at least one AddRec"); return false; } // testRDIV - // When we have a pair of subscripts of the form [c1 + a1*i] and [c2 + a2*j] // where i and j are induction variables, c1 and c2 are loop invariant, // and a1 and a2 are constant, we can solve it exactly with an easy adaptation // of the Exact SIV test, the Restricted Double Index Variable (RDIV) test. // It doesn't make sense to talk about distance or direction in this case, // so there's no point in making special versions of the Strong SIV test or // the Weak-crossing SIV test. // // With minor algebra, this test can also be used for things like // [c1 + a1*i + a2*j][c2]. // // Return true if dependence disproved. bool DependenceInfo::testRDIV(const SCEV *Src, const SCEV *Dst, FullDependence &Result) const { // we have 3 possible situations here: // 1) [a*i + b] and [c*j + d] // 2) [a*i + c*j + b] and [d] // 3) [b] and [a*i + c*j + d] // We need to find what we've got and get organized const SCEV *SrcConst, *DstConst; const SCEV *SrcCoeff, *DstCoeff; const Loop *SrcLoop, *DstLoop; LLVM_DEBUG(dbgs() << " src = " << *Src << "\n"); LLVM_DEBUG(dbgs() << " dst = " << *Dst << "\n"); const SCEVAddRecExpr *SrcAddRec = dyn_cast(Src); const SCEVAddRecExpr *DstAddRec = dyn_cast(Dst); if (SrcAddRec && DstAddRec) { SrcConst = SrcAddRec->getStart(); SrcCoeff = SrcAddRec->getStepRecurrence(*SE); SrcLoop = SrcAddRec->getLoop(); DstConst = DstAddRec->getStart(); DstCoeff = DstAddRec->getStepRecurrence(*SE); DstLoop = DstAddRec->getLoop(); } else if (SrcAddRec) { if (const SCEVAddRecExpr *tmpAddRec = dyn_cast(SrcAddRec->getStart())) { SrcConst = tmpAddRec->getStart(); SrcCoeff = tmpAddRec->getStepRecurrence(*SE); SrcLoop = tmpAddRec->getLoop(); DstConst = Dst; DstCoeff = SE->getNegativeSCEV(SrcAddRec->getStepRecurrence(*SE)); DstLoop = SrcAddRec->getLoop(); } else llvm_unreachable("RDIV reached by surprising SCEVs"); } else if (DstAddRec) { if (const SCEVAddRecExpr *tmpAddRec = dyn_cast(DstAddRec->getStart())) { DstConst = tmpAddRec->getStart(); DstCoeff = tmpAddRec->getStepRecurrence(*SE); DstLoop = tmpAddRec->getLoop(); SrcConst = Src; SrcCoeff = SE->getNegativeSCEV(DstAddRec->getStepRecurrence(*SE)); SrcLoop = DstAddRec->getLoop(); } else llvm_unreachable("RDIV reached by surprising SCEVs"); } else llvm_unreachable("RDIV expected at least one AddRec"); return exactRDIVtest(SrcCoeff, DstCoeff, SrcConst, DstConst, SrcLoop, DstLoop, Result) || gcdMIVtest(Src, Dst, Result) || symbolicRDIVtest(SrcCoeff, DstCoeff, SrcConst, DstConst, SrcLoop, DstLoop); } // Tests the single-subscript MIV pair (Src and Dst) for dependence. // Return true if dependence disproved. // Can sometimes refine direction vectors. bool DependenceInfo::testMIV(const SCEV *Src, const SCEV *Dst, const SmallBitVector &Loops, FullDependence &Result) const { LLVM_DEBUG(dbgs() << " src = " << *Src << "\n"); LLVM_DEBUG(dbgs() << " dst = " << *Dst << "\n"); Result.Consistent = false; return gcdMIVtest(Src, Dst, Result) || banerjeeMIVtest(Src, Dst, Loops, Result); } /// Given a SCEVMulExpr, returns its first operand if its first operand is a /// constant and the product doesn't overflow in a signed sense. Otherwise, /// returns std::nullopt. For example, given (10 * X * Y), it returns 10. /// Notably, if it doesn't have nsw, the multiplication may overflow, and if /// so, it may not a multiple of 10. static std::optional getConstantCoefficient(const SCEV *Expr) { if (const auto *Constant = dyn_cast(Expr)) return Constant->getAPInt(); if (const auto *Product = dyn_cast(Expr)) if (const auto *Constant = dyn_cast(Product->getOperand(0))) if (Product->hasNoSignedWrap()) return Constant->getAPInt(); return std::nullopt; } bool DependenceInfo::accumulateCoefficientsGCD(const SCEV *Expr, const Loop *CurLoop, const SCEV *&CurLoopCoeff, APInt &RunningGCD) const { // If RunningGCD is already 1, exit early. // TODO: It might be better to continue the recursion to find CurLoopCoeff. if (RunningGCD == 1) return true; const SCEVAddRecExpr *AddRec = dyn_cast(Expr); if (!AddRec) { assert(isLoopInvariant(Expr, CurLoop) && "Expected loop invariant expression"); return true; } assert(AddRec->isAffine() && "Unexpected Expr"); const SCEV *Start = AddRec->getStart(); const SCEV *Step = AddRec->getStepRecurrence(*SE); if (AddRec->getLoop() == CurLoop) { CurLoopCoeff = Step; } else { std::optional ConstCoeff = getConstantCoefficient(Step); // If the coefficient is the product of a constant and other stuff, we can // use the constant in the GCD computation. if (!ConstCoeff) return false; // TODO: What happens if ConstCoeff is the "most negative" signed number // (e.g. -128 for 8 bit wide APInt)? RunningGCD = APIntOps::GreatestCommonDivisor(RunningGCD, ConstCoeff->abs()); } return accumulateCoefficientsGCD(Start, CurLoop, CurLoopCoeff, RunningGCD); } //===----------------------------------------------------------------------===// // gcdMIVtest - // Tests an MIV subscript pair for dependence. // Returns true if any possible dependence is disproved. // Marks the result as inconsistent. // Can sometimes disprove the equal direction for 1 or more loops, // as discussed in Michael Wolfe's book, // High Performance Compilers for Parallel Computing, page 235. // // We spend some effort (code!) to handle cases like // [10*i + 5*N*j + 15*M + 6], where i and j are induction variables, // but M and N are just loop-invariant variables. // This should help us handle linearized subscripts; // also makes this test a useful backup to the various SIV tests. // // It occurs to me that the presence of loop-invariant variables // changes the nature of the test from "greatest common divisor" // to "a common divisor". bool DependenceInfo::gcdMIVtest(const SCEV *Src, const SCEV *Dst, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::GCDMIV)) return false; LLVM_DEBUG(dbgs() << "starting gcd\n"); ++GCDapplications; unsigned BitWidth = SE->getTypeSizeInBits(Src->getType()); APInt RunningGCD = APInt::getZero(BitWidth); // Examine Src coefficients. // Compute running GCD and record source constant. // Because we're looking for the constant at the end of the chain, // we can't quit the loop just because the GCD == 1. const SCEV *Coefficients = Src; while (const SCEVAddRecExpr *AddRec = dyn_cast(Coefficients)) { const SCEV *Coeff = AddRec->getStepRecurrence(*SE); // If the coefficient is the product of a constant and other stuff, // we can use the constant in the GCD computation. std::optional ConstCoeff = getConstantCoefficient(Coeff); if (!ConstCoeff) return false; RunningGCD = APIntOps::GreatestCommonDivisor(RunningGCD, ConstCoeff->abs()); Coefficients = AddRec->getStart(); } const SCEV *SrcConst = Coefficients; // Examine Dst coefficients. // Compute running GCD and record destination constant. // Because we're looking for the constant at the end of the chain, // we can't quit the loop just because the GCD == 1. Coefficients = Dst; while (const SCEVAddRecExpr *AddRec = dyn_cast(Coefficients)) { const SCEV *Coeff = AddRec->getStepRecurrence(*SE); // If the coefficient is the product of a constant and other stuff, // we can use the constant in the GCD computation. std::optional ConstCoeff = getConstantCoefficient(Coeff); if (!ConstCoeff) return false; RunningGCD = APIntOps::GreatestCommonDivisor(RunningGCD, ConstCoeff->abs()); Coefficients = AddRec->getStart(); } const SCEV *DstConst = Coefficients; APInt ExtraGCD = APInt::getZero(BitWidth); const SCEV *Delta = minusSCEVNoSignedOverflow(DstConst, SrcConst, *SE); if (!Delta) return false; LLVM_DEBUG(dbgs() << " Delta = " << *Delta << "\n"); const SCEVConstant *Constant = dyn_cast(Delta); if (!Constant) return false; APInt ConstDelta = cast(Constant)->getAPInt(); LLVM_DEBUG(dbgs() << " ConstDelta = " << ConstDelta << "\n"); if (ConstDelta == 0) return false; LLVM_DEBUG(dbgs() << " RunningGCD = " << RunningGCD << "\n"); APInt Remainder = ConstDelta.srem(RunningGCD); if (Remainder != 0) { ++GCDindependence; return true; } // Try to disprove equal directions. // For example, given a subscript pair [3*i + 2*j] and [i' + 2*j' - 1], // the code above can't disprove the dependence because the GCD = 1. // So we consider what happen if i = i' and what happens if j = j'. // If i = i', we can simplify the subscript to [2*i + 2*j] and [2*j' - 1], // which is infeasible, so we can disallow the = direction for the i level. // Setting j = j' doesn't help matters, so we end up with a direction vector // of [<>, *] // // Given A[5*i + 10*j*M + 9*M*N] and A[15*i + 20*j*M - 21*N*M + 5], // we need to remember that the constant part is 5 and the RunningGCD should // be initialized to ExtraGCD = 30. LLVM_DEBUG(dbgs() << " ExtraGCD = " << ExtraGCD << '\n'); bool Improved = false; Coefficients = Src; while (const SCEVAddRecExpr *AddRec = dyn_cast(Coefficients)) { Coefficients = AddRec->getStart(); const Loop *CurLoop = AddRec->getLoop(); RunningGCD = ExtraGCD; const SCEV *SrcCoeff = AddRec->getStepRecurrence(*SE); const SCEV *DstCoeff = SE->getMinusSCEV(SrcCoeff, SrcCoeff); if (!accumulateCoefficientsGCD(Src, CurLoop, SrcCoeff, RunningGCD) || !accumulateCoefficientsGCD(Dst, CurLoop, DstCoeff, RunningGCD)) return false; Delta = SE->getMinusSCEV(SrcCoeff, DstCoeff); // If the coefficient is the product of a constant and other stuff, // we can use the constant in the GCD computation. std::optional ConstCoeff = getConstantCoefficient(Delta); if (!ConstCoeff) // The difference of the two coefficients might not be a product // or constant, in which case we give up on this direction. continue; RunningGCD = APIntOps::GreatestCommonDivisor(RunningGCD, ConstCoeff->abs()); LLVM_DEBUG(dbgs() << "\tRunningGCD = " << RunningGCD << "\n"); if (RunningGCD != 0) { Remainder = ConstDelta.srem(RunningGCD); LLVM_DEBUG(dbgs() << "\tRemainder = " << Remainder << "\n"); if (Remainder != 0) { unsigned Level = mapSrcLoop(CurLoop); Result.DV[Level - 1].Direction &= ~Dependence::DVEntry::EQ; Improved = true; } } } if (Improved) ++GCDsuccesses; LLVM_DEBUG(dbgs() << "all done\n"); return false; } //===----------------------------------------------------------------------===// // banerjeeMIVtest - // Use Banerjee's Inequalities to test an MIV subscript pair. // (Wolfe, in the race-car book, calls this the Extreme Value Test.) // Generally follows the discussion in Section 2.5.2 of // // Optimizing Supercompilers for Supercomputers // Michael Wolfe // // The inequalities given on page 25 are simplified in that loops are // normalized so that the lower bound is always 0 and the stride is always 1. // For example, Wolfe gives // // LB^<_k = (A^-_k - B_k)^- (U_k - L_k - N_k) + (A_k - B_k)L_k - B_k N_k // // where A_k is the coefficient of the kth index in the source subscript, // B_k is the coefficient of the kth index in the destination subscript, // U_k is the upper bound of the kth index, L_k is the lower bound of the Kth // index, and N_k is the stride of the kth index. Since all loops are normalized // by the SCEV package, N_k = 1 and L_k = 0, allowing us to simplify the // equation to // // LB^<_k = (A^-_k - B_k)^- (U_k - 0 - 1) + (A_k - B_k)0 - B_k 1 // = (A^-_k - B_k)^- (U_k - 1) - B_k // // Similar simplifications are possible for the other equations. // // When we can't determine the number of iterations for a loop, // we use NULL as an indicator for the worst case, infinity. // When computing the upper bound, NULL denotes +inf; // for the lower bound, NULL denotes -inf. // // Return true if dependence disproved. bool DependenceInfo::banerjeeMIVtest(const SCEV *Src, const SCEV *Dst, const SmallBitVector &Loops, FullDependence &Result) const { if (!isDependenceTestEnabled(DependenceTestType::BanerjeeMIV)) return false; LLVM_DEBUG(dbgs() << "starting Banerjee\n"); ++BanerjeeApplications; LLVM_DEBUG(dbgs() << " Src = " << *Src << '\n'); const SCEV *A0; CoefficientInfo *A = collectCoeffInfo(Src, true, A0); LLVM_DEBUG(dbgs() << " Dst = " << *Dst << '\n'); const SCEV *B0; CoefficientInfo *B = collectCoeffInfo(Dst, false, B0); BoundInfo *Bound = new BoundInfo[MaxLevels + 1]; const SCEV *Delta = SE->getMinusSCEV(B0, A0); LLVM_DEBUG(dbgs() << "\tDelta = " << *Delta << '\n'); // Compute bounds for all the * directions. LLVM_DEBUG(dbgs() << "\tBounds[*]\n"); for (unsigned K = 1; K <= MaxLevels; ++K) { Bound[K].Iterations = A[K].Iterations ? A[K].Iterations : B[K].Iterations; Bound[K].Direction = Dependence::DVEntry::ALL; Bound[K].DirSet = Dependence::DVEntry::NONE; findBoundsALL(A, B, Bound, K); #ifndef NDEBUG LLVM_DEBUG(dbgs() << "\t " << K << '\t'); if (Bound[K].Lower[Dependence::DVEntry::ALL]) LLVM_DEBUG(dbgs() << *Bound[K].Lower[Dependence::DVEntry::ALL] << '\t'); else LLVM_DEBUG(dbgs() << "-inf\t"); if (Bound[K].Upper[Dependence::DVEntry::ALL]) LLVM_DEBUG(dbgs() << *Bound[K].Upper[Dependence::DVEntry::ALL] << '\n'); else LLVM_DEBUG(dbgs() << "+inf\n"); #endif } // Test the *, *, *, ... case. bool Disproved = false; if (testBounds(Dependence::DVEntry::ALL, 0, Bound, Delta)) { // Explore the direction vector hierarchy. unsigned DepthExpanded = 0; unsigned NewDeps = exploreDirections(1, A, B, Bound, Loops, DepthExpanded, Delta); if (NewDeps > 0) { bool Improved = false; for (unsigned K = 1; K <= CommonLevels; ++K) { if (Loops[K]) { unsigned Old = Result.DV[K - 1].Direction; Result.DV[K - 1].Direction = Old & Bound[K].DirSet; Improved |= Old != Result.DV[K - 1].Direction; if (!Result.DV[K - 1].Direction) { Improved = false; Disproved = true; break; } } } if (Improved) ++BanerjeeSuccesses; } else { ++BanerjeeIndependence; Disproved = true; } } else { ++BanerjeeIndependence; Disproved = true; } delete[] Bound; delete[] A; delete[] B; return Disproved; } // Hierarchically expands the direction vector // search space, combining the directions of discovered dependences // in the DirSet field of Bound. Returns the number of distinct // dependences discovered. If the dependence is disproved, // it will return 0. unsigned DependenceInfo::exploreDirections(unsigned Level, CoefficientInfo *A, CoefficientInfo *B, BoundInfo *Bound, const SmallBitVector &Loops, unsigned &DepthExpanded, const SCEV *Delta) const { // This algorithm has worst case complexity of O(3^n), where 'n' is the number // of common loop levels. To avoid excessive compile-time, pessimize all the // results and immediately return when the number of common levels is beyond // the given threshold. if (CommonLevels > MIVMaxLevelThreshold) { LLVM_DEBUG(dbgs() << "Number of common levels exceeded the threshold. MIV " "direction exploration is terminated.\n"); for (unsigned K = 1; K <= CommonLevels; ++K) if (Loops[K]) Bound[K].DirSet = Dependence::DVEntry::ALL; return 1; } if (Level > CommonLevels) { // record result LLVM_DEBUG(dbgs() << "\t["); for (unsigned K = 1; K <= CommonLevels; ++K) { if (Loops[K]) { Bound[K].DirSet |= Bound[K].Direction; #ifndef NDEBUG switch (Bound[K].Direction) { case Dependence::DVEntry::LT: LLVM_DEBUG(dbgs() << " <"); break; case Dependence::DVEntry::EQ: LLVM_DEBUG(dbgs() << " ="); break; case Dependence::DVEntry::GT: LLVM_DEBUG(dbgs() << " >"); break; case Dependence::DVEntry::ALL: LLVM_DEBUG(dbgs() << " *"); break; default: llvm_unreachable("unexpected Bound[K].Direction"); } #endif } } LLVM_DEBUG(dbgs() << " ]\n"); return 1; } if (Loops[Level]) { if (Level > DepthExpanded) { DepthExpanded = Level; // compute bounds for <, =, > at current level findBoundsLT(A, B, Bound, Level); findBoundsGT(A, B, Bound, Level); findBoundsEQ(A, B, Bound, Level); #ifndef NDEBUG LLVM_DEBUG(dbgs() << "\tBound for level = " << Level << '\n'); LLVM_DEBUG(dbgs() << "\t <\t"); if (Bound[Level].Lower[Dependence::DVEntry::LT]) LLVM_DEBUG(dbgs() << *Bound[Level].Lower[Dependence::DVEntry::LT] << '\t'); else LLVM_DEBUG(dbgs() << "-inf\t"); if (Bound[Level].Upper[Dependence::DVEntry::LT]) LLVM_DEBUG(dbgs() << *Bound[Level].Upper[Dependence::DVEntry::LT] << '\n'); else LLVM_DEBUG(dbgs() << "+inf\n"); LLVM_DEBUG(dbgs() << "\t =\t"); if (Bound[Level].Lower[Dependence::DVEntry::EQ]) LLVM_DEBUG(dbgs() << *Bound[Level].Lower[Dependence::DVEntry::EQ] << '\t'); else LLVM_DEBUG(dbgs() << "-inf\t"); if (Bound[Level].Upper[Dependence::DVEntry::EQ]) LLVM_DEBUG(dbgs() << *Bound[Level].Upper[Dependence::DVEntry::EQ] << '\n'); else LLVM_DEBUG(dbgs() << "+inf\n"); LLVM_DEBUG(dbgs() << "\t >\t"); if (Bound[Level].Lower[Dependence::DVEntry::GT]) LLVM_DEBUG(dbgs() << *Bound[Level].Lower[Dependence::DVEntry::GT] << '\t'); else LLVM_DEBUG(dbgs() << "-inf\t"); if (Bound[Level].Upper[Dependence::DVEntry::GT]) LLVM_DEBUG(dbgs() << *Bound[Level].Upper[Dependence::DVEntry::GT] << '\n'); else LLVM_DEBUG(dbgs() << "+inf\n"); #endif } unsigned NewDeps = 0; // test bounds for <, *, *, ... if (testBounds(Dependence::DVEntry::LT, Level, Bound, Delta)) NewDeps += exploreDirections(Level + 1, A, B, Bound, Loops, DepthExpanded, Delta); // Test bounds for =, *, *, ... if (testBounds(Dependence::DVEntry::EQ, Level, Bound, Delta)) NewDeps += exploreDirections(Level + 1, A, B, Bound, Loops, DepthExpanded, Delta); // test bounds for >, *, *, ... if (testBounds(Dependence::DVEntry::GT, Level, Bound, Delta)) NewDeps += exploreDirections(Level + 1, A, B, Bound, Loops, DepthExpanded, Delta); Bound[Level].Direction = Dependence::DVEntry::ALL; return NewDeps; } else return exploreDirections(Level + 1, A, B, Bound, Loops, DepthExpanded, Delta); } // Returns true iff the current bounds are plausible. bool DependenceInfo::testBounds(unsigned char DirKind, unsigned Level, BoundInfo *Bound, const SCEV *Delta) const { Bound[Level].Direction = DirKind; if (const SCEV *LowerBound = getLowerBound(Bound)) if (isKnownPredicate(CmpInst::ICMP_SGT, LowerBound, Delta)) return false; if (const SCEV *UpperBound = getUpperBound(Bound)) if (isKnownPredicate(CmpInst::ICMP_SGT, Delta, UpperBound)) return false; return true; } // Computes the upper and lower bounds for level K // using the * direction. Records them in Bound. // Wolfe gives the equations // // LB^*_k = (A^-_k - B^+_k)(U_k - L_k) + (A_k - B_k)L_k // UB^*_k = (A^+_k - B^-_k)(U_k - L_k) + (A_k - B_k)L_k // // Since we normalize loops, we can simplify these equations to // // LB^*_k = (A^-_k - B^+_k)U_k // UB^*_k = (A^+_k - B^-_k)U_k // // We must be careful to handle the case where the upper bound is unknown. // Note that the lower bound is always <= 0 // and the upper bound is always >= 0. void DependenceInfo::findBoundsALL(CoefficientInfo *A, CoefficientInfo *B, BoundInfo *Bound, unsigned K) const { Bound[K].Lower[Dependence::DVEntry::ALL] = nullptr; // Default value = -infinity. Bound[K].Upper[Dependence::DVEntry::ALL] = nullptr; // Default value = +infinity. if (Bound[K].Iterations) { Bound[K].Lower[Dependence::DVEntry::ALL] = SE->getMulExpr( SE->getMinusSCEV(A[K].NegPart, B[K].PosPart), Bound[K].Iterations); Bound[K].Upper[Dependence::DVEntry::ALL] = SE->getMulExpr( SE->getMinusSCEV(A[K].PosPart, B[K].NegPart), Bound[K].Iterations); } else { // If the difference is 0, we won't need to know the number of iterations. if (isKnownPredicate(CmpInst::ICMP_EQ, A[K].NegPart, B[K].PosPart)) Bound[K].Lower[Dependence::DVEntry::ALL] = SE->getZero(A[K].Coeff->getType()); if (isKnownPredicate(CmpInst::ICMP_EQ, A[K].PosPart, B[K].NegPart)) Bound[K].Upper[Dependence::DVEntry::ALL] = SE->getZero(A[K].Coeff->getType()); } } // Computes the upper and lower bounds for level K // using the = direction. Records them in Bound. // Wolfe gives the equations // // LB^=_k = (A_k - B_k)^- (U_k - L_k) + (A_k - B_k)L_k // UB^=_k = (A_k - B_k)^+ (U_k - L_k) + (A_k - B_k)L_k // // Since we normalize loops, we can simplify these equations to // // LB^=_k = (A_k - B_k)^- U_k // UB^=_k = (A_k - B_k)^+ U_k // // We must be careful to handle the case where the upper bound is unknown. // Note that the lower bound is always <= 0 // and the upper bound is always >= 0. void DependenceInfo::findBoundsEQ(CoefficientInfo *A, CoefficientInfo *B, BoundInfo *Bound, unsigned K) const { Bound[K].Lower[Dependence::DVEntry::EQ] = nullptr; // Default value = -infinity. Bound[K].Upper[Dependence::DVEntry::EQ] = nullptr; // Default value = +infinity. if (Bound[K].Iterations) { const SCEV *Delta = SE->getMinusSCEV(A[K].Coeff, B[K].Coeff); const SCEV *NegativePart = getNegativePart(Delta); Bound[K].Lower[Dependence::DVEntry::EQ] = SE->getMulExpr(NegativePart, Bound[K].Iterations); const SCEV *PositivePart = getPositivePart(Delta); Bound[K].Upper[Dependence::DVEntry::EQ] = SE->getMulExpr(PositivePart, Bound[K].Iterations); } else { // If the positive/negative part of the difference is 0, // we won't need to know the number of iterations. const SCEV *Delta = SE->getMinusSCEV(A[K].Coeff, B[K].Coeff); const SCEV *NegativePart = getNegativePart(Delta); if (NegativePart->isZero()) Bound[K].Lower[Dependence::DVEntry::EQ] = NegativePart; // Zero const SCEV *PositivePart = getPositivePart(Delta); if (PositivePart->isZero()) Bound[K].Upper[Dependence::DVEntry::EQ] = PositivePart; // Zero } } // Computes the upper and lower bounds for level K // using the < direction. Records them in Bound. // Wolfe gives the equations // // LB^<_k = (A^-_k - B_k)^- (U_k - L_k - N_k) + (A_k - B_k)L_k - B_k N_k // UB^<_k = (A^+_k - B_k)^+ (U_k - L_k - N_k) + (A_k - B_k)L_k - B_k N_k // // Since we normalize loops, we can simplify these equations to // // LB^<_k = (A^-_k - B_k)^- (U_k - 1) - B_k // UB^<_k = (A^+_k - B_k)^+ (U_k - 1) - B_k // // We must be careful to handle the case where the upper bound is unknown. void DependenceInfo::findBoundsLT(CoefficientInfo *A, CoefficientInfo *B, BoundInfo *Bound, unsigned K) const { Bound[K].Lower[Dependence::DVEntry::LT] = nullptr; // Default value = -infinity. Bound[K].Upper[Dependence::DVEntry::LT] = nullptr; // Default value = +infinity. if (Bound[K].Iterations) { const SCEV *Iter_1 = SE->getMinusSCEV( Bound[K].Iterations, SE->getOne(Bound[K].Iterations->getType())); const SCEV *NegPart = getNegativePart(SE->getMinusSCEV(A[K].NegPart, B[K].Coeff)); Bound[K].Lower[Dependence::DVEntry::LT] = SE->getMinusSCEV(SE->getMulExpr(NegPart, Iter_1), B[K].Coeff); const SCEV *PosPart = getPositivePart(SE->getMinusSCEV(A[K].PosPart, B[K].Coeff)); Bound[K].Upper[Dependence::DVEntry::LT] = SE->getMinusSCEV(SE->getMulExpr(PosPart, Iter_1), B[K].Coeff); } else { // If the positive/negative part of the difference is 0, // we won't need to know the number of iterations. const SCEV *NegPart = getNegativePart(SE->getMinusSCEV(A[K].NegPart, B[K].Coeff)); if (NegPart->isZero()) Bound[K].Lower[Dependence::DVEntry::LT] = SE->getNegativeSCEV(B[K].Coeff); const SCEV *PosPart = getPositivePart(SE->getMinusSCEV(A[K].PosPart, B[K].Coeff)); if (PosPart->isZero()) Bound[K].Upper[Dependence::DVEntry::LT] = SE->getNegativeSCEV(B[K].Coeff); } } // Computes the upper and lower bounds for level K // using the > direction. Records them in Bound. // Wolfe gives the equations // // LB^>_k = (A_k - B^+_k)^- (U_k - L_k - N_k) + (A_k - B_k)L_k + A_k N_k // UB^>_k = (A_k - B^-_k)^+ (U_k - L_k - N_k) + (A_k - B_k)L_k + A_k N_k // // Since we normalize loops, we can simplify these equations to // // LB^>_k = (A_k - B^+_k)^- (U_k - 1) + A_k // UB^>_k = (A_k - B^-_k)^+ (U_k - 1) + A_k // // We must be careful to handle the case where the upper bound is unknown. void DependenceInfo::findBoundsGT(CoefficientInfo *A, CoefficientInfo *B, BoundInfo *Bound, unsigned K) const { Bound[K].Lower[Dependence::DVEntry::GT] = nullptr; // Default value = -infinity. Bound[K].Upper[Dependence::DVEntry::GT] = nullptr; // Default value = +infinity. if (Bound[K].Iterations) { const SCEV *Iter_1 = SE->getMinusSCEV( Bound[K].Iterations, SE->getOne(Bound[K].Iterations->getType())); const SCEV *NegPart = getNegativePart(SE->getMinusSCEV(A[K].Coeff, B[K].PosPart)); Bound[K].Lower[Dependence::DVEntry::GT] = SE->getAddExpr(SE->getMulExpr(NegPart, Iter_1), A[K].Coeff); const SCEV *PosPart = getPositivePart(SE->getMinusSCEV(A[K].Coeff, B[K].NegPart)); Bound[K].Upper[Dependence::DVEntry::GT] = SE->getAddExpr(SE->getMulExpr(PosPart, Iter_1), A[K].Coeff); } else { // If the positive/negative part of the difference is 0, // we won't need to know the number of iterations. const SCEV *NegPart = getNegativePart(SE->getMinusSCEV(A[K].Coeff, B[K].PosPart)); if (NegPart->isZero()) Bound[K].Lower[Dependence::DVEntry::GT] = A[K].Coeff; const SCEV *PosPart = getPositivePart(SE->getMinusSCEV(A[K].Coeff, B[K].NegPart)); if (PosPart->isZero()) Bound[K].Upper[Dependence::DVEntry::GT] = A[K].Coeff; } } // X^+ = max(X, 0) const SCEV *DependenceInfo::getPositivePart(const SCEV *X) const { return SE->getSMaxExpr(X, SE->getZero(X->getType())); } // X^- = min(X, 0) const SCEV *DependenceInfo::getNegativePart(const SCEV *X) const { return SE->getSMinExpr(X, SE->getZero(X->getType())); } // Walks through the subscript, // collecting each coefficient, the associated loop bounds, // and recording its positive and negative parts for later use. DependenceInfo::CoefficientInfo * DependenceInfo::collectCoeffInfo(const SCEV *Subscript, bool SrcFlag, const SCEV *&Constant) const { const SCEV *Zero = SE->getZero(Subscript->getType()); CoefficientInfo *CI = new CoefficientInfo[MaxLevels + 1]; for (unsigned K = 1; K <= MaxLevels; ++K) { CI[K].Coeff = Zero; CI[K].PosPart = Zero; CI[K].NegPart = Zero; CI[K].Iterations = nullptr; } while (const SCEVAddRecExpr *AddRec = dyn_cast(Subscript)) { const Loop *L = AddRec->getLoop(); unsigned K = SrcFlag ? mapSrcLoop(L) : mapDstLoop(L); CI[K].Coeff = AddRec->getStepRecurrence(*SE); CI[K].PosPart = getPositivePart(CI[K].Coeff); CI[K].NegPart = getNegativePart(CI[K].Coeff); CI[K].Iterations = collectUpperBound(L, Subscript->getType()); Subscript = AddRec->getStart(); } Constant = Subscript; #ifndef NDEBUG LLVM_DEBUG(dbgs() << "\tCoefficient Info\n"); for (unsigned K = 1; K <= MaxLevels; ++K) { LLVM_DEBUG(dbgs() << "\t " << K << "\t" << *CI[K].Coeff); LLVM_DEBUG(dbgs() << "\tPos Part = "); LLVM_DEBUG(dbgs() << *CI[K].PosPart); LLVM_DEBUG(dbgs() << "\tNeg Part = "); LLVM_DEBUG(dbgs() << *CI[K].NegPart); LLVM_DEBUG(dbgs() << "\tUpper Bound = "); if (CI[K].Iterations) LLVM_DEBUG(dbgs() << *CI[K].Iterations); else LLVM_DEBUG(dbgs() << "+inf"); LLVM_DEBUG(dbgs() << '\n'); } LLVM_DEBUG(dbgs() << "\t Constant = " << *Subscript << '\n'); #endif return CI; } // Looks through all the bounds info and // computes the lower bound given the current direction settings // at each level. If the lower bound for any level is -inf, // the result is -inf. const SCEV *DependenceInfo::getLowerBound(BoundInfo *Bound) const { const SCEV *Sum = Bound[1].Lower[Bound[1].Direction]; for (unsigned K = 2; Sum && K <= MaxLevels; ++K) { if (Bound[K].Lower[Bound[K].Direction]) Sum = SE->getAddExpr(Sum, Bound[K].Lower[Bound[K].Direction]); else Sum = nullptr; } return Sum; } // Looks through all the bounds info and // computes the upper bound given the current direction settings // at each level. If the upper bound at any level is +inf, // the result is +inf. const SCEV *DependenceInfo::getUpperBound(BoundInfo *Bound) const { const SCEV *Sum = Bound[1].Upper[Bound[1].Direction]; for (unsigned K = 2; Sum && K <= MaxLevels; ++K) { if (Bound[K].Upper[Bound[K].Direction]) Sum = SE->getAddExpr(Sum, Bound[K].Upper[Bound[K].Direction]); else Sum = nullptr; } return Sum; } /// Check if we can delinearize the subscripts. If the SCEVs representing the /// source and destination array references are recurrences on a nested loop, /// this function flattens the nested recurrences into separate recurrences /// for each loop level. bool DependenceInfo::tryDelinearize(Instruction *Src, Instruction *Dst, SmallVectorImpl &Pair) { assert(isLoadOrStore(Src) && "instruction is not load or store"); assert(isLoadOrStore(Dst) && "instruction is not load or store"); Value *SrcPtr = getLoadStorePointerOperand(Src); Value *DstPtr = getLoadStorePointerOperand(Dst); Loop *SrcLoop = LI->getLoopFor(Src->getParent()); Loop *DstLoop = LI->getLoopFor(Dst->getParent()); const SCEV *SrcAccessFn = SE->getSCEVAtScope(SrcPtr, SrcLoop); const SCEV *DstAccessFn = SE->getSCEVAtScope(DstPtr, DstLoop); const SCEVUnknown *SrcBase = dyn_cast(SE->getPointerBase(SrcAccessFn)); const SCEVUnknown *DstBase = dyn_cast(SE->getPointerBase(DstAccessFn)); if (!SrcBase || !DstBase || SrcBase != DstBase) return false; SmallVector SrcSubscripts, DstSubscripts; if (!tryDelinearizeFixedSize(Src, Dst, SrcAccessFn, DstAccessFn, SrcSubscripts, DstSubscripts) && !tryDelinearizeParametricSize(Src, Dst, SrcAccessFn, DstAccessFn, SrcSubscripts, DstSubscripts)) return false; assert(isLoopInvariant(SrcBase, SrcLoop) && isLoopInvariant(DstBase, DstLoop) && "Expected SrcBase and DstBase to be loop invariant"); int Size = SrcSubscripts.size(); LLVM_DEBUG({ dbgs() << "\nSrcSubscripts: "; for (int I = 0; I < Size; I++) dbgs() << *SrcSubscripts[I]; dbgs() << "\nDstSubscripts: "; for (int I = 0; I < Size; I++) dbgs() << *DstSubscripts[I]; }); // The delinearization transforms a single-subscript MIV dependence test into // a multi-subscript SIV dependence test that is easier to compute. So we // resize Pair to contain as many pairs of subscripts as the delinearization // has found, and then initialize the pairs following the delinearization. Pair.resize(Size); SCEVMonotonicityChecker MonChecker(SE); const Loop *OutermostLoop = SrcLoop ? SrcLoop->getOutermostLoop() : nullptr; for (int I = 0; I < Size; ++I) { Pair[I].Src = SrcSubscripts[I]; Pair[I].Dst = DstSubscripts[I]; unifySubscriptType(&Pair[I]); if (EnableMonotonicityCheck) { if (MonChecker.checkMonotonicity(Pair[I].Src, OutermostLoop).isUnknown()) return false; if (MonChecker.checkMonotonicity(Pair[I].Dst, OutermostLoop).isUnknown()) return false; } } return true; } /// Try to delinearize \p SrcAccessFn and \p DstAccessFn if the underlying /// arrays accessed are fixed-size arrays. Return true if delinearization was /// successful. bool DependenceInfo::tryDelinearizeFixedSize( Instruction *Src, Instruction *Dst, const SCEV *SrcAccessFn, const SCEV *DstAccessFn, SmallVectorImpl &SrcSubscripts, SmallVectorImpl &DstSubscripts) { LLVM_DEBUG({ const SCEVUnknown *SrcBase = dyn_cast(SE->getPointerBase(SrcAccessFn)); const SCEVUnknown *DstBase = dyn_cast(SE->getPointerBase(DstAccessFn)); assert(SrcBase && DstBase && SrcBase == DstBase && "expected src and dst scev unknowns to be equal"); }); const SCEV *ElemSize = SE->getElementSize(Src); assert(ElemSize == SE->getElementSize(Dst) && "Different element sizes"); SmallVector SrcSizes, DstSizes; if (!delinearizeFixedSizeArray(*SE, SE->removePointerBase(SrcAccessFn), SrcSubscripts, SrcSizes, ElemSize) || !delinearizeFixedSizeArray(*SE, SE->removePointerBase(DstAccessFn), DstSubscripts, DstSizes, ElemSize)) return false; // Check that the two size arrays are non-empty and equal in length and // value. SCEV expressions are uniqued, so we can compare pointers. if (SrcSizes.size() != DstSizes.size() || !std::equal(SrcSizes.begin(), SrcSizes.end(), DstSizes.begin())) { SrcSubscripts.clear(); DstSubscripts.clear(); return false; } assert(SrcSubscripts.size() == DstSubscripts.size() && "Expected equal number of entries in the list of SrcSubscripts and " "DstSubscripts."); // In general we cannot safely assume that the subscripts recovered from GEPs // are in the range of values defined for their corresponding array // dimensions. For example some C language usage/interpretation make it // impossible to verify this at compile-time. As such we can only delinearize // iff the subscripts are positive and are less than the range of the // dimension. if (!DisableDelinearizationChecks) { if (!validateDelinearizationResult(*SE, SrcSizes, SrcSubscripts) || !validateDelinearizationResult(*SE, DstSizes, DstSubscripts)) { SrcSubscripts.clear(); DstSubscripts.clear(); return false; } } LLVM_DEBUG({ dbgs() << "Delinearized subscripts of fixed-size array\n" << "SrcGEP:" << *getLoadStorePointerOperand(Src) << "\n" << "DstGEP:" << *getLoadStorePointerOperand(Dst) << "\n"; }); return true; } bool DependenceInfo::tryDelinearizeParametricSize( Instruction *Src, Instruction *Dst, const SCEV *SrcAccessFn, const SCEV *DstAccessFn, SmallVectorImpl &SrcSubscripts, SmallVectorImpl &DstSubscripts) { const SCEVUnknown *SrcBase = dyn_cast(SE->getPointerBase(SrcAccessFn)); const SCEVUnknown *DstBase = dyn_cast(SE->getPointerBase(DstAccessFn)); assert(SrcBase && DstBase && SrcBase == DstBase && "expected src and dst scev unknowns to be equal"); const SCEV *ElementSize = SE->getElementSize(Src); if (ElementSize != SE->getElementSize(Dst)) return false; const SCEV *SrcSCEV = SE->getMinusSCEV(SrcAccessFn, SrcBase); const SCEV *DstSCEV = SE->getMinusSCEV(DstAccessFn, DstBase); const SCEVAddRecExpr *SrcAR = dyn_cast(SrcSCEV); const SCEVAddRecExpr *DstAR = dyn_cast(DstSCEV); if (!SrcAR || !DstAR || !SrcAR->isAffine() || !DstAR->isAffine()) return false; // First step: collect parametric terms in both array references. SmallVector Terms; collectParametricTerms(*SE, SrcAR, Terms); collectParametricTerms(*SE, DstAR, Terms); // Second step: find subscript sizes. SmallVector Sizes; findArrayDimensions(*SE, Terms, Sizes, ElementSize); // Third step: compute the access functions for each subscript. computeAccessFunctions(*SE, SrcAR, SrcSubscripts, Sizes); computeAccessFunctions(*SE, DstAR, DstSubscripts, Sizes); // Fail when there is only a subscript: that's a linearized access function. if (SrcSubscripts.size() < 2 || DstSubscripts.size() < 2 || SrcSubscripts.size() != DstSubscripts.size()) return false; // Statically check that the array bounds are in-range. The first subscript we // don't have a size for and it cannot overflow into another subscript, so is // always safe. The others need to be 0 <= subscript[i] < bound, for both src // and dst. // FIXME: It may be better to record these sizes and add them as constraints // to the dependency checks. if (!DisableDelinearizationChecks) if (!validateDelinearizationResult(*SE, Sizes, SrcSubscripts) || !validateDelinearizationResult(*SE, Sizes, DstSubscripts)) return false; return true; } //===----------------------------------------------------------------------===// #ifndef NDEBUG // For debugging purposes, dump a small bit vector to dbgs(). static void dumpSmallBitVector(SmallBitVector &BV) { dbgs() << "{"; for (unsigned VI : BV.set_bits()) { dbgs() << VI; if (BV.find_next(VI) >= 0) dbgs() << ' '; } dbgs() << "}\n"; } #endif bool DependenceInfo::invalidate(Function &F, const PreservedAnalyses &PA, FunctionAnalysisManager::Invalidator &Inv) { // Check if the analysis itself has been invalidated. auto PAC = PA.getChecker(); if (!PAC.preserved() && !PAC.preservedSet>()) return true; // Check transitive dependencies. return Inv.invalidate(F, PA) || Inv.invalidate(F, PA) || Inv.invalidate(F, PA); } // depends - // Returns NULL if there is no dependence. // Otherwise, return a Dependence with as many details as possible. // Corresponds to Section 3.1 in the paper // // Practical Dependence Testing // Goff, Kennedy, Tseng // PLDI 1991 // std::unique_ptr DependenceInfo::depends(Instruction *Src, Instruction *Dst, bool UnderRuntimeAssumptions) { SmallVector Assume; bool PossiblyLoopIndependent = true; if (Src == Dst) PossiblyLoopIndependent = false; if (!(Src->mayReadOrWriteMemory() && Dst->mayReadOrWriteMemory())) // if both instructions don't reference memory, there's no dependence return nullptr; if (!isLoadOrStore(Src) || !isLoadOrStore(Dst)) { // can only analyze simple loads and stores, i.e., no calls, invokes, etc. LLVM_DEBUG(dbgs() << "can only handle simple loads and stores\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); } const MemoryLocation &DstLoc = MemoryLocation::get(Dst); const MemoryLocation &SrcLoc = MemoryLocation::get(Src); switch (underlyingObjectsAlias(AA, F->getDataLayout(), DstLoc, SrcLoc)) { case AliasResult::MayAlias: case AliasResult::PartialAlias: // cannot analyse objects if we don't understand their aliasing. LLVM_DEBUG(dbgs() << "can't analyze may or partial alias\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); case AliasResult::NoAlias: // If the objects noalias, they are distinct, accesses are independent. LLVM_DEBUG(dbgs() << "no alias\n"); return nullptr; case AliasResult::MustAlias: break; // The underlying objects alias; test accesses for dependence. } if (DstLoc.Size != SrcLoc.Size || !DstLoc.Size.isPrecise() || !SrcLoc.Size.isPrecise()) { // The dependence test gets confused if the size of the memory accesses // differ. LLVM_DEBUG(dbgs() << "can't analyze must alias with different sizes\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); } Value *SrcPtr = getLoadStorePointerOperand(Src); Value *DstPtr = getLoadStorePointerOperand(Dst); const SCEV *SrcSCEV = SE->getSCEV(SrcPtr); const SCEV *DstSCEV = SE->getSCEV(DstPtr); LLVM_DEBUG(dbgs() << " SrcSCEV = " << *SrcSCEV << "\n"); LLVM_DEBUG(dbgs() << " DstSCEV = " << *DstSCEV << "\n"); const SCEV *SrcBase = SE->getPointerBase(SrcSCEV); const SCEV *DstBase = SE->getPointerBase(DstSCEV); if (SrcBase != DstBase) { // If two pointers have different bases, trying to analyze indexes won't // work; we can't compare them to each other. This can happen, for example, // if one is produced by an LCSSA PHI node. // // We check this upfront so we don't crash in cases where getMinusSCEV() // returns a SCEVCouldNotCompute. LLVM_DEBUG(dbgs() << "can't analyze SCEV with different pointer base\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); } // Even if the base pointers are the same, they may not be loop-invariant. It // could lead to incorrect results, as we're analyzing loop-carried // dependencies. Src and Dst can be in different loops, so we need to check // the base pointer is invariant in both loops. Loop *SrcLoop = LI->getLoopFor(Src->getParent()); Loop *DstLoop = LI->getLoopFor(Dst->getParent()); if (!isLoopInvariant(SrcBase, SrcLoop) || !isLoopInvariant(DstBase, DstLoop)) { LLVM_DEBUG(dbgs() << "The base pointer is not loop invariant.\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); } uint64_t EltSize = SrcLoc.Size.toRaw(); const SCEV *SrcEv = SE->getMinusSCEV(SrcSCEV, SrcBase); const SCEV *DstEv = SE->getMinusSCEV(DstSCEV, DstBase); // Check that memory access offsets are multiples of element sizes. if (!SE->isKnownMultipleOf(SrcEv, EltSize, Assume) || !SE->isKnownMultipleOf(DstEv, EltSize, Assume)) { LLVM_DEBUG(dbgs() << "can't analyze SCEV with different offsets\n"); return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); } // Runtime assumptions needed but not allowed. if (!Assume.empty() && !UnderRuntimeAssumptions) return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); unsigned Pairs = 1; SmallVector Pair(Pairs); Pair[0].Src = SrcEv; Pair[0].Dst = DstEv; SCEVMonotonicityChecker MonChecker(SE); const Loop *OutermostLoop = SrcLoop ? SrcLoop->getOutermostLoop() : nullptr; if (EnableMonotonicityCheck) if (MonChecker.checkMonotonicity(Pair[0].Src, OutermostLoop).isUnknown() || MonChecker.checkMonotonicity(Pair[0].Dst, OutermostLoop).isUnknown()) return std::make_unique(Src, Dst, SCEVUnionPredicate(Assume, *SE)); if (Delinearize) { if (tryDelinearize(Src, Dst, Pair)) { LLVM_DEBUG(dbgs() << " delinearized\n"); Pairs = Pair.size(); } } // Establish loop nesting levels considering SameSD loops as common establishNestingLevels(Src, Dst); LLVM_DEBUG(dbgs() << " common nesting levels = " << CommonLevels << "\n"); LLVM_DEBUG(dbgs() << " maximum nesting levels = " << MaxLevels << "\n"); LLVM_DEBUG(dbgs() << " SameSD nesting levels = " << SameSDLevels << "\n"); // Modify common levels to consider the SameSD levels in the tests CommonLevels += SameSDLevels; MaxLevels -= SameSDLevels; if (SameSDLevels > 0) { // Not all tests are handled yet over SameSD loops // Revoke if there are any tests other than ZIV, SIV or RDIV for (unsigned P = 0; P < Pairs; ++P) { SmallBitVector Loops; Subscript::ClassificationKind TestClass = classifyPair(Pair[P].Src, LI->getLoopFor(Src->getParent()), Pair[P].Dst, LI->getLoopFor(Dst->getParent()), Loops); if (TestClass != Subscript::ZIV && TestClass != Subscript::SIV && TestClass != Subscript::RDIV) { // Revert the levels to not consider the SameSD levels CommonLevels -= SameSDLevels; MaxLevels += SameSDLevels; SameSDLevels = 0; break; } } } if (SameSDLevels > 0) SameSDLoopsCount++; FullDependence Result(Src, Dst, SCEVUnionPredicate(Assume, *SE), PossiblyLoopIndependent, CommonLevels); ++TotalArrayPairs; for (unsigned P = 0; P < Pairs; ++P) { assert(Pair[P].Src->getType()->isIntegerTy() && "Src must be an integer"); assert(Pair[P].Dst->getType()->isIntegerTy() && "Dst must be an integer"); Pair[P].Loops.resize(MaxLevels + 1); Pair[P].GroupLoops.resize(MaxLevels + 1); Pair[P].Group.resize(Pairs); removeMatchingExtensions(&Pair[P]); Pair[P].Classification = classifyPair(Pair[P].Src, LI->getLoopFor(Src->getParent()), Pair[P].Dst, LI->getLoopFor(Dst->getParent()), Pair[P].Loops); Pair[P].GroupLoops = Pair[P].Loops; Pair[P].Group.set(P); LLVM_DEBUG(dbgs() << " subscript " << P << "\n"); LLVM_DEBUG(dbgs() << "\tsrc = " << *Pair[P].Src << "\n"); LLVM_DEBUG(dbgs() << "\tdst = " << *Pair[P].Dst << "\n"); LLVM_DEBUG(dbgs() << "\tclass = " << Pair[P].Classification << "\n"); LLVM_DEBUG(dbgs() << "\tloops = "); LLVM_DEBUG(dumpSmallBitVector(Pair[P].Loops)); } // Test each subscript individually for (unsigned SI = 0; SI < Pairs; ++SI) { LLVM_DEBUG(dbgs() << "testing subscript " << SI); switch (Pair[SI].Classification) { case Subscript::NonLinear: // ignore these, but collect loops for later ++NonlinearSubscriptPairs; collectCommonLoops(Pair[SI].Src, LI->getLoopFor(Src->getParent()), Pair[SI].Loops); collectCommonLoops(Pair[SI].Dst, LI->getLoopFor(Dst->getParent()), Pair[SI].Loops); Result.Consistent = false; break; case Subscript::ZIV: LLVM_DEBUG(dbgs() << ", ZIV\n"); if (testZIV(Pair[SI].Src, Pair[SI].Dst, Result)) return nullptr; break; case Subscript::SIV: { LLVM_DEBUG(dbgs() << ", SIV\n"); unsigned Level; if (testSIV(Pair[SI].Src, Pair[SI].Dst, Level, Result, UnderRuntimeAssumptions)) return nullptr; break; } case Subscript::RDIV: LLVM_DEBUG(dbgs() << ", RDIV\n"); if (testRDIV(Pair[SI].Src, Pair[SI].Dst, Result)) return nullptr; break; case Subscript::MIV: LLVM_DEBUG(dbgs() << ", MIV\n"); if (testMIV(Pair[SI].Src, Pair[SI].Dst, Pair[SI].Loops, Result)) return nullptr; break; } } // Make sure the Scalar flags are set correctly. SmallBitVector CompleteLoops(MaxLevels + 1); for (unsigned SI = 0; SI < Pairs; ++SI) CompleteLoops |= Pair[SI].Loops; for (unsigned II = 1; II <= CommonLevels; ++II) if (CompleteLoops[II]) Result.DV[II - 1].Scalar = false; // Set the distance to zero if the direction is EQ. // TODO: Ideally, the distance should be set to 0 immediately simultaneously // with the corresponding direction being set to EQ. for (unsigned II = 1; II <= Result.getLevels(); ++II) { if (Result.getDirection(II) == Dependence::DVEntry::EQ) { if (Result.DV[II - 1].Distance == nullptr) Result.DV[II - 1].Distance = SE->getZero(SrcSCEV->getType()); else assert(Result.DV[II - 1].Distance->isZero() && "Inconsistency between distance and direction"); } #ifndef NDEBUG // Check that the converse (i.e., if the distance is zero, then the // direction is EQ) holds. const SCEV *Distance = Result.getDistance(II); if (Distance && Distance->isZero()) assert(Result.getDirection(II) == Dependence::DVEntry::EQ && "Distance is zero, but direction is not EQ"); #endif } if (SameSDLevels > 0) { // Extracting SameSD levels from the common levels // Reverting CommonLevels and MaxLevels to their original values assert(CommonLevels >= SameSDLevels); CommonLevels -= SameSDLevels; MaxLevels += SameSDLevels; std::unique_ptr DV, DVSameSD; DV = std::make_unique(CommonLevels); DVSameSD = std::make_unique(SameSDLevels); for (unsigned Level = 0; Level < CommonLevels; ++Level) DV[Level] = Result.DV[Level]; for (unsigned Level = 0; Level < SameSDLevels; ++Level) DVSameSD[Level] = Result.DV[CommonLevels + Level]; Result.DV = std::move(DV); Result.DVSameSD = std::move(DVSameSD); Result.Levels = CommonLevels; Result.SameSDLevels = SameSDLevels; // Result is not consistent if it considers SameSD levels Result.Consistent = false; } if (PossiblyLoopIndependent) { // Make sure the LoopIndependent flag is set correctly. // All directions must include equal, otherwise no // loop-independent dependence is possible. for (unsigned II = 1; II <= CommonLevels; ++II) { if (!(Result.getDirection(II) & Dependence::DVEntry::EQ)) { Result.LoopIndependent = false; break; } } } else { // On the other hand, if all directions are equal and there's no // loop-independent dependence possible, then no dependence exists. // However, if there are runtime assumptions, we must return the result. bool AllEqual = true; for (unsigned II = 1; II <= CommonLevels; ++II) { if (Result.getDirection(II) != Dependence::DVEntry::EQ) { AllEqual = false; break; } } if (AllEqual && Result.Assumptions.getPredicates().empty()) return nullptr; } return std::make_unique(std::move(Result)); }