//===- LoopStrengthReduce.cpp - Strength Reduce IVs in Loops --------------===// // // 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 // //===----------------------------------------------------------------------===// // // This transformation analyzes and transforms the induction variables (and // computations derived from them) into forms suitable for efficient execution // on the target. // // This pass performs a strength reduction on array references inside loops that // have as one or more of their components the loop induction variable, it // rewrites expressions to take advantage of scaled-index addressing modes // available on the target, and it performs a variety of other optimizations // related to loop induction variables. // // Terminology note: this code has a lot of handling for "post-increment" or // "post-inc" users. This is not talking about post-increment addressing modes; // it is instead talking about code like this: // // %i = phi [ 0, %entry ], [ %i.next, %latch ] // ... // %i.next = add %i, 1 // %c = icmp eq %i.next, %n // // The SCEV for %i is {0,+,1}<%L>. The SCEV for %i.next is {1,+,1}<%L>, however // it's useful to think about these as the same register, with some uses using // the value of the register before the add and some using it after. In this // example, the icmp is a post-increment user, since it uses %i.next, which is // the value of the induction variable after the increment. The other common // case of post-increment users is users outside the loop. // // TODO: More sophistication in the way Formulae are generated and filtered. // // TODO: Handle multiple loops at a time. // // TODO: Should the addressing mode BaseGV be changed to a ConstantExpr instead // of a GlobalValue? // // TODO: When truncation is free, truncate ICmp users' operands to make it a // smaller encoding (on x86 at least). // // TODO: When a negated register is used by an add (such as in a list of // multiple base registers, or as the increment expression in an addrec), // we may not actually need both reg and (-1 * reg) in registers; the // negation can be implemented by using a sub instead of an add. The // lack of support for taking this into consideration when making // register pressure decisions is partly worked around by the "Special" // use kind. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Scalar/LoopStrengthReduce.h" #include "llvm/ADT/APInt.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/DenseSet.h" #include "llvm/ADT/Hashing.h" #include "llvm/ADT/PointerIntPair.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/SmallBitVector.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/iterator_range.h" #include "llvm/Analysis/AssumptionCache.h" #include "llvm/Analysis/IVUsers.h" #include "llvm/Analysis/LoopAnalysisManager.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/LoopPass.h" #include "llvm/Analysis/MemorySSA.h" #include "llvm/Analysis/MemorySSAUpdater.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/ScalarEvolutionExpressions.h" #include "llvm/Analysis/ScalarEvolutionNormalization.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/ValueTracking.h" #include "llvm/Config/llvm-config.h" #include "llvm/IR/BasicBlock.h" #include "llvm/IR/Constant.h" #include "llvm/IR/Constants.h" #include "llvm/IR/DebugInfoMetadata.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/Intrinsics.h" #include "llvm/IR/Module.h" #include "llvm/IR/OperandTraits.h" #include "llvm/IR/Operator.h" #include "llvm/IR/PassManager.h" #include "llvm/IR/Type.h" #include "llvm/IR/Use.h" #include "llvm/IR/User.h" #include "llvm/IR/Value.h" #include "llvm/IR/ValueHandle.h" #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Transforms/Utils.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "llvm/Transforms/Utils/Local.h" #include "llvm/Transforms/Utils/ScalarEvolutionExpander.h" #include #include #include #include #include #include #include #include #include #include using namespace llvm; #define DEBUG_TYPE "loop-reduce" /// MaxIVUsers is an arbitrary threshold that provides an early opportunity for /// bail out. This threshold is far beyond the number of users that LSR can /// conceivably solve, so it should not affect generated code, but catches the /// worst cases before LSR burns too much compile time and stack space. static const unsigned MaxIVUsers = 200; /// Limit the size of expression that SCEV-based salvaging will attempt to /// translate into a DIExpression. /// Choose a maximum size such that debuginfo is not excessively increased and /// the salvaging is not too expensive for the compiler. static const unsigned MaxSCEVSalvageExpressionSize = 64; // Temporary flag to cleanup congruent phis after LSR phi expansion. // It's currently disabled until we can determine whether it's truly useful or // not. The flag should be removed after the v3.0 release. // This is now needed for ivchains. static cl::opt EnablePhiElim( "enable-lsr-phielim", cl::Hidden, cl::init(true), cl::desc("Enable LSR phi elimination")); // The flag adds instruction count to solutions cost comparision. static cl::opt InsnsCost( "lsr-insns-cost", cl::Hidden, cl::init(true), cl::desc("Add instruction count to a LSR cost model")); // Flag to choose how to narrow complex lsr solution static cl::opt LSRExpNarrow( "lsr-exp-narrow", cl::Hidden, cl::init(false), cl::desc("Narrow LSR complex solution using" " expectation of registers number")); // Flag to narrow search space by filtering non-optimal formulae with // the same ScaledReg and Scale. static cl::opt FilterSameScaledReg( "lsr-filter-same-scaled-reg", cl::Hidden, cl::init(true), cl::desc("Narrow LSR search space by filtering non-optimal formulae" " with the same ScaledReg and Scale")); static cl::opt PreferredAddresingMode( "lsr-preferred-addressing-mode", cl::Hidden, cl::init(TTI::AMK_None), cl::desc("A flag that overrides the target's preferred addressing mode."), cl::values(clEnumValN(TTI::AMK_None, "none", "Don't prefer any addressing mode"), clEnumValN(TTI::AMK_PreIndexed, "preindexed", "Prefer pre-indexed addressing mode"), clEnumValN(TTI::AMK_PostIndexed, "postindexed", "Prefer post-indexed addressing mode"))); static cl::opt ComplexityLimit( "lsr-complexity-limit", cl::Hidden, cl::init(std::numeric_limits::max()), cl::desc("LSR search space complexity limit")); static cl::opt SetupCostDepthLimit( "lsr-setupcost-depth-limit", cl::Hidden, cl::init(7), cl::desc("The limit on recursion depth for LSRs setup cost")); #ifndef NDEBUG // Stress test IV chain generation. static cl::opt StressIVChain( "stress-ivchain", cl::Hidden, cl::init(false), cl::desc("Stress test LSR IV chains")); #else static bool StressIVChain = false; #endif namespace { struct MemAccessTy { /// Used in situations where the accessed memory type is unknown. static const unsigned UnknownAddressSpace = std::numeric_limits::max(); Type *MemTy = nullptr; unsigned AddrSpace = UnknownAddressSpace; MemAccessTy() = default; MemAccessTy(Type *Ty, unsigned AS) : MemTy(Ty), AddrSpace(AS) {} bool operator==(MemAccessTy Other) const { return MemTy == Other.MemTy && AddrSpace == Other.AddrSpace; } bool operator!=(MemAccessTy Other) const { return !(*this == Other); } static MemAccessTy getUnknown(LLVMContext &Ctx, unsigned AS = UnknownAddressSpace) { return MemAccessTy(Type::getVoidTy(Ctx), AS); } Type *getType() { return MemTy; } }; /// This class holds data which is used to order reuse candidates. class RegSortData { public: /// This represents the set of LSRUse indices which reference /// a particular register. SmallBitVector UsedByIndices; void print(raw_ostream &OS) const; void dump() const; }; } // end anonymous namespace #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void RegSortData::print(raw_ostream &OS) const { OS << "[NumUses=" << UsedByIndices.count() << ']'; } LLVM_DUMP_METHOD void RegSortData::dump() const { print(errs()); errs() << '\n'; } #endif namespace { /// Map register candidates to information about how they are used. class RegUseTracker { using RegUsesTy = DenseMap; RegUsesTy RegUsesMap; SmallVector RegSequence; public: void countRegister(const SCEV *Reg, size_t LUIdx); void dropRegister(const SCEV *Reg, size_t LUIdx); void swapAndDropUse(size_t LUIdx, size_t LastLUIdx); bool isRegUsedByUsesOtherThan(const SCEV *Reg, size_t LUIdx) const; const SmallBitVector &getUsedByIndices(const SCEV *Reg) const; void clear(); using iterator = SmallVectorImpl::iterator; using const_iterator = SmallVectorImpl::const_iterator; iterator begin() { return RegSequence.begin(); } iterator end() { return RegSequence.end(); } const_iterator begin() const { return RegSequence.begin(); } const_iterator end() const { return RegSequence.end(); } }; } // end anonymous namespace void RegUseTracker::countRegister(const SCEV *Reg, size_t LUIdx) { std::pair Pair = RegUsesMap.insert(std::make_pair(Reg, RegSortData())); RegSortData &RSD = Pair.first->second; if (Pair.second) RegSequence.push_back(Reg); RSD.UsedByIndices.resize(std::max(RSD.UsedByIndices.size(), LUIdx + 1)); RSD.UsedByIndices.set(LUIdx); } void RegUseTracker::dropRegister(const SCEV *Reg, size_t LUIdx) { RegUsesTy::iterator It = RegUsesMap.find(Reg); assert(It != RegUsesMap.end()); RegSortData &RSD = It->second; assert(RSD.UsedByIndices.size() > LUIdx); RSD.UsedByIndices.reset(LUIdx); } void RegUseTracker::swapAndDropUse(size_t LUIdx, size_t LastLUIdx) { assert(LUIdx <= LastLUIdx); // Update RegUses. The data structure is not optimized for this purpose; // we must iterate through it and update each of the bit vectors. for (auto &Pair : RegUsesMap) { SmallBitVector &UsedByIndices = Pair.second.UsedByIndices; if (LUIdx < UsedByIndices.size()) UsedByIndices[LUIdx] = LastLUIdx < UsedByIndices.size() ? UsedByIndices[LastLUIdx] : false; UsedByIndices.resize(std::min(UsedByIndices.size(), LastLUIdx)); } } bool RegUseTracker::isRegUsedByUsesOtherThan(const SCEV *Reg, size_t LUIdx) const { RegUsesTy::const_iterator I = RegUsesMap.find(Reg); if (I == RegUsesMap.end()) return false; const SmallBitVector &UsedByIndices = I->second.UsedByIndices; int i = UsedByIndices.find_first(); if (i == -1) return false; if ((size_t)i != LUIdx) return true; return UsedByIndices.find_next(i) != -1; } const SmallBitVector &RegUseTracker::getUsedByIndices(const SCEV *Reg) const { RegUsesTy::const_iterator I = RegUsesMap.find(Reg); assert(I != RegUsesMap.end() && "Unknown register!"); return I->second.UsedByIndices; } void RegUseTracker::clear() { RegUsesMap.clear(); RegSequence.clear(); } namespace { /// This class holds information that describes a formula for computing /// satisfying a use. It may include broken-out immediates and scaled registers. struct Formula { /// Global base address used for complex addressing. GlobalValue *BaseGV = nullptr; /// Base offset for complex addressing. int64_t BaseOffset = 0; /// Whether any complex addressing has a base register. bool HasBaseReg = false; /// The scale of any complex addressing. int64_t Scale = 0; /// The list of "base" registers for this use. When this is non-empty. The /// canonical representation of a formula is /// 1. BaseRegs.size > 1 implies ScaledReg != NULL and /// 2. ScaledReg != NULL implies Scale != 1 || !BaseRegs.empty(). /// 3. The reg containing recurrent expr related with currect loop in the /// formula should be put in the ScaledReg. /// #1 enforces that the scaled register is always used when at least two /// registers are needed by the formula: e.g., reg1 + reg2 is reg1 + 1 * reg2. /// #2 enforces that 1 * reg is reg. /// #3 ensures invariant regs with respect to current loop can be combined /// together in LSR codegen. /// This invariant can be temporarily broken while building a formula. /// However, every formula inserted into the LSRInstance must be in canonical /// form. SmallVector BaseRegs; /// The 'scaled' register for this use. This should be non-null when Scale is /// not zero. const SCEV *ScaledReg = nullptr; /// An additional constant offset which added near the use. This requires a /// temporary register, but the offset itself can live in an add immediate /// field rather than a register. int64_t UnfoldedOffset = 0; Formula() = default; void initialMatch(const SCEV *S, Loop *L, ScalarEvolution &SE); bool isCanonical(const Loop &L) const; void canonicalize(const Loop &L); bool unscale(); bool hasZeroEnd() const; size_t getNumRegs() const; Type *getType() const; void deleteBaseReg(const SCEV *&S); bool referencesReg(const SCEV *S) const; bool hasRegsUsedByUsesOtherThan(size_t LUIdx, const RegUseTracker &RegUses) const; void print(raw_ostream &OS) const; void dump() const; }; } // end anonymous namespace /// Recursion helper for initialMatch. static void DoInitialMatch(const SCEV *S, Loop *L, SmallVectorImpl &Good, SmallVectorImpl &Bad, ScalarEvolution &SE) { // Collect expressions which properly dominate the loop header. if (SE.properlyDominates(S, L->getHeader())) { Good.push_back(S); return; } // Look at add operands. if (const SCEVAddExpr *Add = dyn_cast(S)) { for (const SCEV *S : Add->operands()) DoInitialMatch(S, L, Good, Bad, SE); return; } // Look at addrec operands. if (const SCEVAddRecExpr *AR = dyn_cast(S)) if (!AR->getStart()->isZero() && AR->isAffine()) { DoInitialMatch(AR->getStart(), L, Good, Bad, SE); DoInitialMatch(SE.getAddRecExpr(SE.getConstant(AR->getType(), 0), AR->getStepRecurrence(SE), // FIXME: AR->getNoWrapFlags() AR->getLoop(), SCEV::FlagAnyWrap), L, Good, Bad, SE); return; } // Handle a multiplication by -1 (negation) if it didn't fold. if (const SCEVMulExpr *Mul = dyn_cast(S)) if (Mul->getOperand(0)->isAllOnesValue()) { SmallVector Ops(drop_begin(Mul->operands())); const SCEV *NewMul = SE.getMulExpr(Ops); SmallVector MyGood; SmallVector MyBad; DoInitialMatch(NewMul, L, MyGood, MyBad, SE); const SCEV *NegOne = SE.getSCEV(ConstantInt::getAllOnesValue( SE.getEffectiveSCEVType(NewMul->getType()))); for (const SCEV *S : MyGood) Good.push_back(SE.getMulExpr(NegOne, S)); for (const SCEV *S : MyBad) Bad.push_back(SE.getMulExpr(NegOne, S)); return; } // Ok, we can't do anything interesting. Just stuff the whole thing into a // register and hope for the best. Bad.push_back(S); } /// Incorporate loop-variant parts of S into this Formula, attempting to keep /// all loop-invariant and loop-computable values in a single base register. void Formula::initialMatch(const SCEV *S, Loop *L, ScalarEvolution &SE) { SmallVector Good; SmallVector Bad; DoInitialMatch(S, L, Good, Bad, SE); if (!Good.empty()) { const SCEV *Sum = SE.getAddExpr(Good); if (!Sum->isZero()) BaseRegs.push_back(Sum); HasBaseReg = true; } if (!Bad.empty()) { const SCEV *Sum = SE.getAddExpr(Bad); if (!Sum->isZero()) BaseRegs.push_back(Sum); HasBaseReg = true; } canonicalize(*L); } /// Check whether or not this formula satisfies the canonical /// representation. /// \see Formula::BaseRegs. bool Formula::isCanonical(const Loop &L) const { if (!ScaledReg) return BaseRegs.size() <= 1; if (Scale != 1) return true; if (Scale == 1 && BaseRegs.empty()) return false; const SCEVAddRecExpr *SAR = dyn_cast(ScaledReg); if (SAR && SAR->getLoop() == &L) return true; // If ScaledReg is not a recurrent expr, or it is but its loop is not current // loop, meanwhile BaseRegs contains a recurrent expr reg related with current // loop, we want to swap the reg in BaseRegs with ScaledReg. auto I = find_if(BaseRegs, [&](const SCEV *S) { return isa(S) && (cast(S)->getLoop() == &L); }); return I == BaseRegs.end(); } /// Helper method to morph a formula into its canonical representation. /// \see Formula::BaseRegs. /// Every formula having more than one base register, must use the ScaledReg /// field. Otherwise, we would have to do special cases everywhere in LSR /// to treat reg1 + reg2 + ... the same way as reg1 + 1*reg2 + ... /// On the other hand, 1*reg should be canonicalized into reg. void Formula::canonicalize(const Loop &L) { if (isCanonical(L)) return; if (BaseRegs.empty()) { // No base reg? Use scale reg with scale = 1 as such. assert(ScaledReg && "Expected 1*reg => reg"); assert(Scale == 1 && "Expected 1*reg => reg"); BaseRegs.push_back(ScaledReg); Scale = 0; ScaledReg = nullptr; return; } // Keep the invariant sum in BaseRegs and one of the variant sum in ScaledReg. if (!ScaledReg) { ScaledReg = BaseRegs.pop_back_val(); Scale = 1; } // If ScaledReg is an invariant with respect to L, find the reg from // BaseRegs containing the recurrent expr related with Loop L. Swap the // reg with ScaledReg. const SCEVAddRecExpr *SAR = dyn_cast(ScaledReg); if (!SAR || SAR->getLoop() != &L) { auto I = find_if(BaseRegs, [&](const SCEV *S) { return isa(S) && (cast(S)->getLoop() == &L); }); if (I != BaseRegs.end()) std::swap(ScaledReg, *I); } assert(isCanonical(L) && "Failed to canonicalize?"); } /// Get rid of the scale in the formula. /// In other words, this method morphes reg1 + 1*reg2 into reg1 + reg2. /// \return true if it was possible to get rid of the scale, false otherwise. /// \note After this operation the formula may not be in the canonical form. bool Formula::unscale() { if (Scale != 1) return false; Scale = 0; BaseRegs.push_back(ScaledReg); ScaledReg = nullptr; return true; } bool Formula::hasZeroEnd() const { if (UnfoldedOffset || BaseOffset) return false; if (BaseRegs.size() != 1 || ScaledReg) return false; return true; } /// Return the total number of register operands used by this formula. This does /// not include register uses implied by non-constant addrec strides. size_t Formula::getNumRegs() const { return !!ScaledReg + BaseRegs.size(); } /// Return the type of this formula, if it has one, or null otherwise. This type /// is meaningless except for the bit size. Type *Formula::getType() const { return !BaseRegs.empty() ? BaseRegs.front()->getType() : ScaledReg ? ScaledReg->getType() : BaseGV ? BaseGV->getType() : nullptr; } /// Delete the given base reg from the BaseRegs list. void Formula::deleteBaseReg(const SCEV *&S) { if (&S != &BaseRegs.back()) std::swap(S, BaseRegs.back()); BaseRegs.pop_back(); } /// Test if this formula references the given register. bool Formula::referencesReg(const SCEV *S) const { return S == ScaledReg || is_contained(BaseRegs, S); } /// Test whether this formula uses registers which are used by uses other than /// the use with the given index. bool Formula::hasRegsUsedByUsesOtherThan(size_t LUIdx, const RegUseTracker &RegUses) const { if (ScaledReg) if (RegUses.isRegUsedByUsesOtherThan(ScaledReg, LUIdx)) return true; for (const SCEV *BaseReg : BaseRegs) if (RegUses.isRegUsedByUsesOtherThan(BaseReg, LUIdx)) return true; return false; } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void Formula::print(raw_ostream &OS) const { bool First = true; if (BaseGV) { if (!First) OS << " + "; else First = false; BaseGV->printAsOperand(OS, /*PrintType=*/false); } if (BaseOffset != 0) { if (!First) OS << " + "; else First = false; OS << BaseOffset; } for (const SCEV *BaseReg : BaseRegs) { if (!First) OS << " + "; else First = false; OS << "reg(" << *BaseReg << ')'; } if (HasBaseReg && BaseRegs.empty()) { if (!First) OS << " + "; else First = false; OS << "**error: HasBaseReg**"; } else if (!HasBaseReg && !BaseRegs.empty()) { if (!First) OS << " + "; else First = false; OS << "**error: !HasBaseReg**"; } if (Scale != 0) { if (!First) OS << " + "; else First = false; OS << Scale << "*reg("; if (ScaledReg) OS << *ScaledReg; else OS << ""; OS << ')'; } if (UnfoldedOffset != 0) { if (!First) OS << " + "; OS << "imm(" << UnfoldedOffset << ')'; } } LLVM_DUMP_METHOD void Formula::dump() const { print(errs()); errs() << '\n'; } #endif /// Return true if the given addrec can be sign-extended without changing its /// value. static bool isAddRecSExtable(const SCEVAddRecExpr *AR, ScalarEvolution &SE) { Type *WideTy = IntegerType::get(SE.getContext(), SE.getTypeSizeInBits(AR->getType()) + 1); return isa(SE.getSignExtendExpr(AR, WideTy)); } /// Return true if the given add can be sign-extended without changing its /// value. static bool isAddSExtable(const SCEVAddExpr *A, ScalarEvolution &SE) { Type *WideTy = IntegerType::get(SE.getContext(), SE.getTypeSizeInBits(A->getType()) + 1); return isa(SE.getSignExtendExpr(A, WideTy)); } /// Return true if the given mul can be sign-extended without changing its /// value. static bool isMulSExtable(const SCEVMulExpr *M, ScalarEvolution &SE) { Type *WideTy = IntegerType::get(SE.getContext(), SE.getTypeSizeInBits(M->getType()) * M->getNumOperands()); return isa(SE.getSignExtendExpr(M, WideTy)); } /// Return an expression for LHS /s RHS, if it can be determined and if the /// remainder is known to be zero, or null otherwise. If IgnoreSignificantBits /// is true, expressions like (X * Y) /s Y are simplified to X, ignoring that /// the multiplication may overflow, which is useful when the result will be /// used in a context where the most significant bits are ignored. static const SCEV *getExactSDiv(const SCEV *LHS, const SCEV *RHS, ScalarEvolution &SE, bool IgnoreSignificantBits = false) { // Handle the trivial case, which works for any SCEV type. if (LHS == RHS) return SE.getConstant(LHS->getType(), 1); // Handle a few RHS special cases. const SCEVConstant *RC = dyn_cast(RHS); if (RC) { const APInt &RA = RC->getAPInt(); // Handle x /s -1 as x * -1, to give ScalarEvolution a chance to do // some folding. if (RA.isAllOnes()) { if (LHS->getType()->isPointerTy()) return nullptr; return SE.getMulExpr(LHS, RC); } // Handle x /s 1 as x. if (RA == 1) return LHS; } // Check for a division of a constant by a constant. if (const SCEVConstant *C = dyn_cast(LHS)) { if (!RC) return nullptr; const APInt &LA = C->getAPInt(); const APInt &RA = RC->getAPInt(); if (LA.srem(RA) != 0) return nullptr; return SE.getConstant(LA.sdiv(RA)); } // Distribute the sdiv over addrec operands, if the addrec doesn't overflow. if (const SCEVAddRecExpr *AR = dyn_cast(LHS)) { if ((IgnoreSignificantBits || isAddRecSExtable(AR, SE)) && AR->isAffine()) { const SCEV *Step = getExactSDiv(AR->getStepRecurrence(SE), RHS, SE, IgnoreSignificantBits); if (!Step) return nullptr; const SCEV *Start = getExactSDiv(AR->getStart(), RHS, SE, IgnoreSignificantBits); if (!Start) return nullptr; // FlagNW is independent of the start value, step direction, and is // preserved with smaller magnitude steps. // FIXME: AR->getNoWrapFlags(SCEV::FlagNW) return SE.getAddRecExpr(Start, Step, AR->getLoop(), SCEV::FlagAnyWrap); } return nullptr; } // Distribute the sdiv over add operands, if the add doesn't overflow. if (const SCEVAddExpr *Add = dyn_cast(LHS)) { if (IgnoreSignificantBits || isAddSExtable(Add, SE)) { SmallVector Ops; for (const SCEV *S : Add->operands()) { const SCEV *Op = getExactSDiv(S, RHS, SE, IgnoreSignificantBits); if (!Op) return nullptr; Ops.push_back(Op); } return SE.getAddExpr(Ops); } return nullptr; } // Check for a multiply operand that we can pull RHS out of. if (const SCEVMulExpr *Mul = dyn_cast(LHS)) { if (IgnoreSignificantBits || isMulSExtable(Mul, SE)) { // Handle special case C1*X*Y /s C2*X*Y. if (const SCEVMulExpr *MulRHS = dyn_cast(RHS)) { if (IgnoreSignificantBits || isMulSExtable(MulRHS, SE)) { const SCEVConstant *LC = dyn_cast(Mul->getOperand(0)); const SCEVConstant *RC = dyn_cast(MulRHS->getOperand(0)); if (LC && RC) { SmallVector LOps(drop_begin(Mul->operands())); SmallVector ROps(drop_begin(MulRHS->operands())); if (LOps == ROps) return getExactSDiv(LC, RC, SE, IgnoreSignificantBits); } } } SmallVector Ops; bool Found = false; for (const SCEV *S : Mul->operands()) { if (!Found) if (const SCEV *Q = getExactSDiv(S, RHS, SE, IgnoreSignificantBits)) { S = Q; Found = true; } Ops.push_back(S); } return Found ? SE.getMulExpr(Ops) : nullptr; } return nullptr; } // Otherwise we don't know. return nullptr; } /// If S involves the addition of a constant integer value, return that integer /// value, and mutate S to point to a new SCEV with that value excluded. static int64_t ExtractImmediate(const SCEV *&S, ScalarEvolution &SE) { if (const SCEVConstant *C = dyn_cast(S)) { if (C->getAPInt().getMinSignedBits() <= 64) { S = SE.getConstant(C->getType(), 0); return C->getValue()->getSExtValue(); } } else if (const SCEVAddExpr *Add = dyn_cast(S)) { SmallVector NewOps(Add->operands()); int64_t Result = ExtractImmediate(NewOps.front(), SE); if (Result != 0) S = SE.getAddExpr(NewOps); return Result; } else if (const SCEVAddRecExpr *AR = dyn_cast(S)) { SmallVector NewOps(AR->operands()); int64_t Result = ExtractImmediate(NewOps.front(), SE); if (Result != 0) S = SE.getAddRecExpr(NewOps, AR->getLoop(), // FIXME: AR->getNoWrapFlags(SCEV::FlagNW) SCEV::FlagAnyWrap); return Result; } return 0; } /// If S involves the addition of a GlobalValue address, return that symbol, and /// mutate S to point to a new SCEV with that value excluded. static GlobalValue *ExtractSymbol(const SCEV *&S, ScalarEvolution &SE) { if (const SCEVUnknown *U = dyn_cast(S)) { if (GlobalValue *GV = dyn_cast(U->getValue())) { S = SE.getConstant(GV->getType(), 0); return GV; } } else if (const SCEVAddExpr *Add = dyn_cast(S)) { SmallVector NewOps(Add->operands()); GlobalValue *Result = ExtractSymbol(NewOps.back(), SE); if (Result) S = SE.getAddExpr(NewOps); return Result; } else if (const SCEVAddRecExpr *AR = dyn_cast(S)) { SmallVector NewOps(AR->operands()); GlobalValue *Result = ExtractSymbol(NewOps.front(), SE); if (Result) S = SE.getAddRecExpr(NewOps, AR->getLoop(), // FIXME: AR->getNoWrapFlags(SCEV::FlagNW) SCEV::FlagAnyWrap); return Result; } return nullptr; } /// Returns true if the specified instruction is using the specified value as an /// address. static bool isAddressUse(const TargetTransformInfo &TTI, Instruction *Inst, Value *OperandVal) { bool isAddress = isa(Inst); if (StoreInst *SI = dyn_cast(Inst)) { if (SI->getPointerOperand() == OperandVal) isAddress = true; } else if (IntrinsicInst *II = dyn_cast(Inst)) { // Addressing modes can also be folded into prefetches and a variety // of intrinsics. switch (II->getIntrinsicID()) { case Intrinsic::memset: case Intrinsic::prefetch: case Intrinsic::masked_load: if (II->getArgOperand(0) == OperandVal) isAddress = true; break; case Intrinsic::masked_store: if (II->getArgOperand(1) == OperandVal) isAddress = true; break; case Intrinsic::memmove: case Intrinsic::memcpy: if (II->getArgOperand(0) == OperandVal || II->getArgOperand(1) == OperandVal) isAddress = true; break; default: { MemIntrinsicInfo IntrInfo; if (TTI.getTgtMemIntrinsic(II, IntrInfo)) { if (IntrInfo.PtrVal == OperandVal) isAddress = true; } } } } else if (AtomicRMWInst *RMW = dyn_cast(Inst)) { if (RMW->getPointerOperand() == OperandVal) isAddress = true; } else if (AtomicCmpXchgInst *CmpX = dyn_cast(Inst)) { if (CmpX->getPointerOperand() == OperandVal) isAddress = true; } return isAddress; } /// Return the type of the memory being accessed. static MemAccessTy getAccessType(const TargetTransformInfo &TTI, Instruction *Inst, Value *OperandVal) { MemAccessTy AccessTy(Inst->getType(), MemAccessTy::UnknownAddressSpace); if (const StoreInst *SI = dyn_cast(Inst)) { AccessTy.MemTy = SI->getOperand(0)->getType(); AccessTy.AddrSpace = SI->getPointerAddressSpace(); } else if (const LoadInst *LI = dyn_cast(Inst)) { AccessTy.AddrSpace = LI->getPointerAddressSpace(); } else if (const AtomicRMWInst *RMW = dyn_cast(Inst)) { AccessTy.AddrSpace = RMW->getPointerAddressSpace(); } else if (const AtomicCmpXchgInst *CmpX = dyn_cast(Inst)) { AccessTy.AddrSpace = CmpX->getPointerAddressSpace(); } else if (IntrinsicInst *II = dyn_cast(Inst)) { switch (II->getIntrinsicID()) { case Intrinsic::prefetch: case Intrinsic::memset: AccessTy.AddrSpace = II->getArgOperand(0)->getType()->getPointerAddressSpace(); AccessTy.MemTy = OperandVal->getType(); break; case Intrinsic::memmove: case Intrinsic::memcpy: AccessTy.AddrSpace = OperandVal->getType()->getPointerAddressSpace(); AccessTy.MemTy = OperandVal->getType(); break; case Intrinsic::masked_load: AccessTy.AddrSpace = II->getArgOperand(0)->getType()->getPointerAddressSpace(); break; case Intrinsic::masked_store: AccessTy.MemTy = II->getOperand(0)->getType(); AccessTy.AddrSpace = II->getArgOperand(1)->getType()->getPointerAddressSpace(); break; default: { MemIntrinsicInfo IntrInfo; if (TTI.getTgtMemIntrinsic(II, IntrInfo) && IntrInfo.PtrVal) { AccessTy.AddrSpace = IntrInfo.PtrVal->getType()->getPointerAddressSpace(); } break; } } } // All pointers have the same requirements, so canonicalize them to an // arbitrary pointer type to minimize variation. if (PointerType *PTy = dyn_cast(AccessTy.MemTy)) AccessTy.MemTy = PointerType::get(IntegerType::get(PTy->getContext(), 1), PTy->getAddressSpace()); return AccessTy; } /// Return true if this AddRec is already a phi in its loop. static bool isExistingPhi(const SCEVAddRecExpr *AR, ScalarEvolution &SE) { for (PHINode &PN : AR->getLoop()->getHeader()->phis()) { if (SE.isSCEVable(PN.getType()) && (SE.getEffectiveSCEVType(PN.getType()) == SE.getEffectiveSCEVType(AR->getType())) && SE.getSCEV(&PN) == AR) return true; } return false; } /// Check if expanding this expression is likely to incur significant cost. This /// is tricky because SCEV doesn't track which expressions are actually computed /// by the current IR. /// /// We currently allow expansion of IV increments that involve adds, /// multiplication by constants, and AddRecs from existing phis. /// /// TODO: Allow UDivExpr if we can find an existing IV increment that is an /// obvious multiple of the UDivExpr. static bool isHighCostExpansion(const SCEV *S, SmallPtrSetImpl &Processed, ScalarEvolution &SE) { // Zero/One operand expressions switch (S->getSCEVType()) { case scUnknown: case scConstant: return false; case scTruncate: return isHighCostExpansion(cast(S)->getOperand(), Processed, SE); case scZeroExtend: return isHighCostExpansion(cast(S)->getOperand(), Processed, SE); case scSignExtend: return isHighCostExpansion(cast(S)->getOperand(), Processed, SE); default: break; } if (!Processed.insert(S).second) return false; if (const SCEVAddExpr *Add = dyn_cast(S)) { for (const SCEV *S : Add->operands()) { if (isHighCostExpansion(S, Processed, SE)) return true; } return false; } if (const SCEVMulExpr *Mul = dyn_cast(S)) { if (Mul->getNumOperands() == 2) { // Multiplication by a constant is ok if (isa(Mul->getOperand(0))) return isHighCostExpansion(Mul->getOperand(1), Processed, SE); // If we have the value of one operand, check if an existing // multiplication already generates this expression. if (const SCEVUnknown *U = dyn_cast(Mul->getOperand(1))) { Value *UVal = U->getValue(); for (User *UR : UVal->users()) { // If U is a constant, it may be used by a ConstantExpr. Instruction *UI = dyn_cast(UR); if (UI && UI->getOpcode() == Instruction::Mul && SE.isSCEVable(UI->getType())) { return SE.getSCEV(UI) == Mul; } } } } } if (const SCEVAddRecExpr *AR = dyn_cast(S)) { if (isExistingPhi(AR, SE)) return false; } // Fow now, consider any other type of expression (div/mul/min/max) high cost. return true; } namespace { class LSRUse; } // end anonymous namespace /// Check if the addressing mode defined by \p F is completely /// folded in \p LU at isel time. /// This includes address-mode folding and special icmp tricks. /// This function returns true if \p LU can accommodate what \p F /// defines and up to 1 base + 1 scaled + offset. /// In other words, if \p F has several base registers, this function may /// still return true. Therefore, users still need to account for /// additional base registers and/or unfolded offsets to derive an /// accurate cost model. static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, const LSRUse &LU, const Formula &F); // Get the cost of the scaling factor used in F for LU. static InstructionCost getScalingFactorCost(const TargetTransformInfo &TTI, const LSRUse &LU, const Formula &F, const Loop &L); namespace { /// This class is used to measure and compare candidate formulae. class Cost { const Loop *L = nullptr; ScalarEvolution *SE = nullptr; const TargetTransformInfo *TTI = nullptr; TargetTransformInfo::LSRCost C; TTI::AddressingModeKind AMK = TTI::AMK_None; public: Cost() = delete; Cost(const Loop *L, ScalarEvolution &SE, const TargetTransformInfo &TTI, TTI::AddressingModeKind AMK) : L(L), SE(&SE), TTI(&TTI), AMK(AMK) { C.Insns = 0; C.NumRegs = 0; C.AddRecCost = 0; C.NumIVMuls = 0; C.NumBaseAdds = 0; C.ImmCost = 0; C.SetupCost = 0; C.ScaleCost = 0; } bool isLess(Cost &Other); void Lose(); #ifndef NDEBUG // Once any of the metrics loses, they must all remain losers. bool isValid() { return ((C.Insns | C.NumRegs | C.AddRecCost | C.NumIVMuls | C.NumBaseAdds | C.ImmCost | C.SetupCost | C.ScaleCost) != ~0u) || ((C.Insns & C.NumRegs & C.AddRecCost & C.NumIVMuls & C.NumBaseAdds & C.ImmCost & C.SetupCost & C.ScaleCost) == ~0u); } #endif bool isLoser() { assert(isValid() && "invalid cost"); return C.NumRegs == ~0u; } void RateFormula(const Formula &F, SmallPtrSetImpl &Regs, const DenseSet &VisitedRegs, const LSRUse &LU, SmallPtrSetImpl *LoserRegs = nullptr); void print(raw_ostream &OS) const; void dump() const; private: void RateRegister(const Formula &F, const SCEV *Reg, SmallPtrSetImpl &Regs); void RatePrimaryRegister(const Formula &F, const SCEV *Reg, SmallPtrSetImpl &Regs, SmallPtrSetImpl *LoserRegs); }; /// An operand value in an instruction which is to be replaced with some /// equivalent, possibly strength-reduced, replacement. struct LSRFixup { /// The instruction which will be updated. Instruction *UserInst = nullptr; /// The operand of the instruction which will be replaced. The operand may be /// used more than once; every instance will be replaced. Value *OperandValToReplace = nullptr; /// If this user is to use the post-incremented value of an induction /// variable, this set is non-empty and holds the loops associated with the /// induction variable. PostIncLoopSet PostIncLoops; /// A constant offset to be added to the LSRUse expression. This allows /// multiple fixups to share the same LSRUse with different offsets, for /// example in an unrolled loop. int64_t Offset = 0; LSRFixup() = default; bool isUseFullyOutsideLoop(const Loop *L) const; void print(raw_ostream &OS) const; void dump() const; }; /// A DenseMapInfo implementation for holding DenseMaps and DenseSets of sorted /// SmallVectors of const SCEV*. struct UniquifierDenseMapInfo { static SmallVector getEmptyKey() { SmallVector V; V.push_back(reinterpret_cast(-1)); return V; } static SmallVector getTombstoneKey() { SmallVector V; V.push_back(reinterpret_cast(-2)); return V; } static unsigned getHashValue(const SmallVector &V) { return static_cast(hash_combine_range(V.begin(), V.end())); } static bool isEqual(const SmallVector &LHS, const SmallVector &RHS) { return LHS == RHS; } }; /// This class holds the state that LSR keeps for each use in IVUsers, as well /// as uses invented by LSR itself. It includes information about what kinds of /// things can be folded into the user, information about the user itself, and /// information about how the use may be satisfied. TODO: Represent multiple /// users of the same expression in common? class LSRUse { DenseSet, UniquifierDenseMapInfo> Uniquifier; public: /// An enum for a kind of use, indicating what types of scaled and immediate /// operands it might support. enum KindType { Basic, ///< A normal use, with no folding. Special, ///< A special case of basic, allowing -1 scales. Address, ///< An address use; folding according to TargetLowering ICmpZero ///< An equality icmp with both operands folded into one. // TODO: Add a generic icmp too? }; using SCEVUseKindPair = PointerIntPair; KindType Kind; MemAccessTy AccessTy; /// The list of operands which are to be replaced. SmallVector Fixups; /// Keep track of the min and max offsets of the fixups. int64_t MinOffset = std::numeric_limits::max(); int64_t MaxOffset = std::numeric_limits::min(); /// This records whether all of the fixups using this LSRUse are outside of /// the loop, in which case some special-case heuristics may be used. bool AllFixupsOutsideLoop = true; /// RigidFormula is set to true to guarantee that this use will be associated /// with a single formula--the one that initially matched. Some SCEV /// expressions cannot be expanded. This allows LSR to consider the registers /// used by those expressions without the need to expand them later after /// changing the formula. bool RigidFormula = false; /// This records the widest use type for any fixup using this /// LSRUse. FindUseWithSimilarFormula can't consider uses with different max /// fixup widths to be equivalent, because the narrower one may be relying on /// the implicit truncation to truncate away bogus bits. Type *WidestFixupType = nullptr; /// A list of ways to build a value that can satisfy this user. After the /// list is populated, one of these is selected heuristically and used to /// formulate a replacement for OperandValToReplace in UserInst. SmallVector Formulae; /// The set of register candidates used by all formulae in this LSRUse. SmallPtrSet Regs; LSRUse(KindType K, MemAccessTy AT) : Kind(K), AccessTy(AT) {} LSRFixup &getNewFixup() { Fixups.push_back(LSRFixup()); return Fixups.back(); } void pushFixup(LSRFixup &f) { Fixups.push_back(f); if (f.Offset > MaxOffset) MaxOffset = f.Offset; if (f.Offset < MinOffset) MinOffset = f.Offset; } bool HasFormulaWithSameRegs(const Formula &F) const; float getNotSelectedProbability(const SCEV *Reg) const; bool InsertFormula(const Formula &F, const Loop &L); void DeleteFormula(Formula &F); void RecomputeRegs(size_t LUIdx, RegUseTracker &Reguses); void print(raw_ostream &OS) const; void dump() const; }; } // end anonymous namespace static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, LSRUse::KindType Kind, MemAccessTy AccessTy, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, Instruction *Fixup = nullptr); static unsigned getSetupCost(const SCEV *Reg, unsigned Depth) { if (isa(Reg) || isa(Reg)) return 1; if (Depth == 0) return 0; if (const auto *S = dyn_cast(Reg)) return getSetupCost(S->getStart(), Depth - 1); if (auto S = dyn_cast(Reg)) return getSetupCost(S->getOperand(), Depth - 1); if (auto S = dyn_cast(Reg)) return std::accumulate(S->op_begin(), S->op_end(), 0, [&](unsigned i, const SCEV *Reg) { return i + getSetupCost(Reg, Depth - 1); }); if (auto S = dyn_cast(Reg)) return getSetupCost(S->getLHS(), Depth - 1) + getSetupCost(S->getRHS(), Depth - 1); return 0; } /// Tally up interesting quantities from the given register. void Cost::RateRegister(const Formula &F, const SCEV *Reg, SmallPtrSetImpl &Regs) { if (const SCEVAddRecExpr *AR = dyn_cast(Reg)) { // If this is an addrec for another loop, it should be an invariant // with respect to L since L is the innermost loop (at least // for now LSR only handles innermost loops). if (AR->getLoop() != L) { // If the AddRec exists, consider it's register free and leave it alone. if (isExistingPhi(AR, *SE) && AMK != TTI::AMK_PostIndexed) return; // It is bad to allow LSR for current loop to add induction variables // for its sibling loops. if (!AR->getLoop()->contains(L)) { Lose(); return; } // Otherwise, it will be an invariant with respect to Loop L. ++C.NumRegs; return; } unsigned LoopCost = 1; if (TTI->isIndexedLoadLegal(TTI->MIM_PostInc, AR->getType()) || TTI->isIndexedStoreLegal(TTI->MIM_PostInc, AR->getType())) { // If the step size matches the base offset, we could use pre-indexed // addressing. if (AMK == TTI::AMK_PreIndexed) { if (auto *Step = dyn_cast(AR->getStepRecurrence(*SE))) if (Step->getAPInt() == F.BaseOffset) LoopCost = 0; } else if (AMK == TTI::AMK_PostIndexed) { const SCEV *LoopStep = AR->getStepRecurrence(*SE); if (isa(LoopStep)) { const SCEV *LoopStart = AR->getStart(); if (!isa(LoopStart) && SE->isLoopInvariant(LoopStart, L)) LoopCost = 0; } } } C.AddRecCost += LoopCost; // Add the step value register, if it needs one. // TODO: The non-affine case isn't precisely modeled here. if (!AR->isAffine() || !isa(AR->getOperand(1))) { if (!Regs.count(AR->getOperand(1))) { RateRegister(F, AR->getOperand(1), Regs); if (isLoser()) return; } } } ++C.NumRegs; // Rough heuristic; favor registers which don't require extra setup // instructions in the preheader. C.SetupCost += getSetupCost(Reg, SetupCostDepthLimit); // Ensure we don't, even with the recusion limit, produce invalid costs. C.SetupCost = std::min(C.SetupCost, 1 << 16); C.NumIVMuls += isa(Reg) && SE->hasComputableLoopEvolution(Reg, L); } /// Record this register in the set. If we haven't seen it before, rate /// it. Optional LoserRegs provides a way to declare any formula that refers to /// one of those regs an instant loser. void Cost::RatePrimaryRegister(const Formula &F, const SCEV *Reg, SmallPtrSetImpl &Regs, SmallPtrSetImpl *LoserRegs) { if (LoserRegs && LoserRegs->count(Reg)) { Lose(); return; } if (Regs.insert(Reg).second) { RateRegister(F, Reg, Regs); if (LoserRegs && isLoser()) LoserRegs->insert(Reg); } } void Cost::RateFormula(const Formula &F, SmallPtrSetImpl &Regs, const DenseSet &VisitedRegs, const LSRUse &LU, SmallPtrSetImpl *LoserRegs) { assert(F.isCanonical(*L) && "Cost is accurate only for canonical formula"); // Tally up the registers. unsigned PrevAddRecCost = C.AddRecCost; unsigned PrevNumRegs = C.NumRegs; unsigned PrevNumBaseAdds = C.NumBaseAdds; if (const SCEV *ScaledReg = F.ScaledReg) { if (VisitedRegs.count(ScaledReg)) { Lose(); return; } RatePrimaryRegister(F, ScaledReg, Regs, LoserRegs); if (isLoser()) return; } for (const SCEV *BaseReg : F.BaseRegs) { if (VisitedRegs.count(BaseReg)) { Lose(); return; } RatePrimaryRegister(F, BaseReg, Regs, LoserRegs); if (isLoser()) return; } // Determine how many (unfolded) adds we'll need inside the loop. size_t NumBaseParts = F.getNumRegs(); if (NumBaseParts > 1) // Do not count the base and a possible second register if the target // allows to fold 2 registers. C.NumBaseAdds += NumBaseParts - (1 + (F.Scale && isAMCompletelyFolded(*TTI, LU, F))); C.NumBaseAdds += (F.UnfoldedOffset != 0); // Accumulate non-free scaling amounts. C.ScaleCost += *getScalingFactorCost(*TTI, LU, F, *L).getValue(); // Tally up the non-zero immediates. for (const LSRFixup &Fixup : LU.Fixups) { int64_t O = Fixup.Offset; int64_t Offset = (uint64_t)O + F.BaseOffset; if (F.BaseGV) C.ImmCost += 64; // Handle symbolic values conservatively. // TODO: This should probably be the pointer size. else if (Offset != 0) C.ImmCost += APInt(64, Offset, true).getMinSignedBits(); // Check with target if this offset with this instruction is // specifically not supported. if (LU.Kind == LSRUse::Address && Offset != 0 && !isAMCompletelyFolded(*TTI, LSRUse::Address, LU.AccessTy, F.BaseGV, Offset, F.HasBaseReg, F.Scale, Fixup.UserInst)) C.NumBaseAdds++; } // If we don't count instruction cost exit here. if (!InsnsCost) { assert(isValid() && "invalid cost"); return; } // Treat every new register that exceeds TTI.getNumberOfRegisters() - 1 as // additional instruction (at least fill). // TODO: Need distinguish register class? unsigned TTIRegNum = TTI->getNumberOfRegisters( TTI->getRegisterClassForType(false, F.getType())) - 1; if (C.NumRegs > TTIRegNum) { // Cost already exceeded TTIRegNum, then only newly added register can add // new instructions. if (PrevNumRegs > TTIRegNum) C.Insns += (C.NumRegs - PrevNumRegs); else C.Insns += (C.NumRegs - TTIRegNum); } // If ICmpZero formula ends with not 0, it could not be replaced by // just add or sub. We'll need to compare final result of AddRec. // That means we'll need an additional instruction. But if the target can // macro-fuse a compare with a branch, don't count this extra instruction. // For -10 + {0, +, 1}: // i = i + 1; // cmp i, 10 // // For {-10, +, 1}: // i = i + 1; if (LU.Kind == LSRUse::ICmpZero && !F.hasZeroEnd() && !TTI->canMacroFuseCmp()) C.Insns++; // Each new AddRec adds 1 instruction to calculation. C.Insns += (C.AddRecCost - PrevAddRecCost); // BaseAdds adds instructions for unfolded registers. if (LU.Kind != LSRUse::ICmpZero) C.Insns += C.NumBaseAdds - PrevNumBaseAdds; assert(isValid() && "invalid cost"); } /// Set this cost to a losing value. void Cost::Lose() { C.Insns = std::numeric_limits::max(); C.NumRegs = std::numeric_limits::max(); C.AddRecCost = std::numeric_limits::max(); C.NumIVMuls = std::numeric_limits::max(); C.NumBaseAdds = std::numeric_limits::max(); C.ImmCost = std::numeric_limits::max(); C.SetupCost = std::numeric_limits::max(); C.ScaleCost = std::numeric_limits::max(); } /// Choose the lower cost. bool Cost::isLess(Cost &Other) { if (InsnsCost.getNumOccurrences() > 0 && InsnsCost && C.Insns != Other.C.Insns) return C.Insns < Other.C.Insns; return TTI->isLSRCostLess(C, Other.C); } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void Cost::print(raw_ostream &OS) const { if (InsnsCost) OS << C.Insns << " instruction" << (C.Insns == 1 ? " " : "s "); OS << C.NumRegs << " reg" << (C.NumRegs == 1 ? "" : "s"); if (C.AddRecCost != 0) OS << ", with addrec cost " << C.AddRecCost; if (C.NumIVMuls != 0) OS << ", plus " << C.NumIVMuls << " IV mul" << (C.NumIVMuls == 1 ? "" : "s"); if (C.NumBaseAdds != 0) OS << ", plus " << C.NumBaseAdds << " base add" << (C.NumBaseAdds == 1 ? "" : "s"); if (C.ScaleCost != 0) OS << ", plus " << C.ScaleCost << " scale cost"; if (C.ImmCost != 0) OS << ", plus " << C.ImmCost << " imm cost"; if (C.SetupCost != 0) OS << ", plus " << C.SetupCost << " setup cost"; } LLVM_DUMP_METHOD void Cost::dump() const { print(errs()); errs() << '\n'; } #endif /// Test whether this fixup always uses its value outside of the given loop. bool LSRFixup::isUseFullyOutsideLoop(const Loop *L) const { // PHI nodes use their value in their incoming blocks. if (const PHINode *PN = dyn_cast(UserInst)) { for (unsigned i = 0, e = PN->getNumIncomingValues(); i != e; ++i) if (PN->getIncomingValue(i) == OperandValToReplace && L->contains(PN->getIncomingBlock(i))) return false; return true; } return !L->contains(UserInst); } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void LSRFixup::print(raw_ostream &OS) const { OS << "UserInst="; // Store is common and interesting enough to be worth special-casing. if (StoreInst *Store = dyn_cast(UserInst)) { OS << "store "; Store->getOperand(0)->printAsOperand(OS, /*PrintType=*/false); } else if (UserInst->getType()->isVoidTy()) OS << UserInst->getOpcodeName(); else UserInst->printAsOperand(OS, /*PrintType=*/false); OS << ", OperandValToReplace="; OperandValToReplace->printAsOperand(OS, /*PrintType=*/false); for (const Loop *PIL : PostIncLoops) { OS << ", PostIncLoop="; PIL->getHeader()->printAsOperand(OS, /*PrintType=*/false); } if (Offset != 0) OS << ", Offset=" << Offset; } LLVM_DUMP_METHOD void LSRFixup::dump() const { print(errs()); errs() << '\n'; } #endif /// Test whether this use as a formula which has the same registers as the given /// formula. bool LSRUse::HasFormulaWithSameRegs(const Formula &F) const { SmallVector Key = F.BaseRegs; if (F.ScaledReg) Key.push_back(F.ScaledReg); // Unstable sort by host order ok, because this is only used for uniquifying. llvm::sort(Key); return Uniquifier.count(Key); } /// The function returns a probability of selecting formula without Reg. float LSRUse::getNotSelectedProbability(const SCEV *Reg) const { unsigned FNum = 0; for (const Formula &F : Formulae) if (F.referencesReg(Reg)) FNum++; return ((float)(Formulae.size() - FNum)) / Formulae.size(); } /// If the given formula has not yet been inserted, add it to the list, and /// return true. Return false otherwise. The formula must be in canonical form. bool LSRUse::InsertFormula(const Formula &F, const Loop &L) { assert(F.isCanonical(L) && "Invalid canonical representation"); if (!Formulae.empty() && RigidFormula) return false; SmallVector Key = F.BaseRegs; if (F.ScaledReg) Key.push_back(F.ScaledReg); // Unstable sort by host order ok, because this is only used for uniquifying. llvm::sort(Key); if (!Uniquifier.insert(Key).second) return false; // Using a register to hold the value of 0 is not profitable. assert((!F.ScaledReg || !F.ScaledReg->isZero()) && "Zero allocated in a scaled register!"); #ifndef NDEBUG for (const SCEV *BaseReg : F.BaseRegs) assert(!BaseReg->isZero() && "Zero allocated in a base register!"); #endif // Add the formula to the list. Formulae.push_back(F); // Record registers now being used by this use. Regs.insert(F.BaseRegs.begin(), F.BaseRegs.end()); if (F.ScaledReg) Regs.insert(F.ScaledReg); return true; } /// Remove the given formula from this use's list. void LSRUse::DeleteFormula(Formula &F) { if (&F != &Formulae.back()) std::swap(F, Formulae.back()); Formulae.pop_back(); } /// Recompute the Regs field, and update RegUses. void LSRUse::RecomputeRegs(size_t LUIdx, RegUseTracker &RegUses) { // Now that we've filtered out some formulae, recompute the Regs set. SmallPtrSet OldRegs = std::move(Regs); Regs.clear(); for (const Formula &F : Formulae) { if (F.ScaledReg) Regs.insert(F.ScaledReg); Regs.insert(F.BaseRegs.begin(), F.BaseRegs.end()); } // Update the RegTracker. for (const SCEV *S : OldRegs) if (!Regs.count(S)) RegUses.dropRegister(S, LUIdx); } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void LSRUse::print(raw_ostream &OS) const { OS << "LSR Use: Kind="; switch (Kind) { case Basic: OS << "Basic"; break; case Special: OS << "Special"; break; case ICmpZero: OS << "ICmpZero"; break; case Address: OS << "Address of "; if (AccessTy.MemTy->isPointerTy()) OS << "pointer"; // the full pointer type could be really verbose else { OS << *AccessTy.MemTy; } OS << " in addrspace(" << AccessTy.AddrSpace << ')'; } OS << ", Offsets={"; bool NeedComma = false; for (const LSRFixup &Fixup : Fixups) { if (NeedComma) OS << ','; OS << Fixup.Offset; NeedComma = true; } OS << '}'; if (AllFixupsOutsideLoop) OS << ", all-fixups-outside-loop"; if (WidestFixupType) OS << ", widest fixup type: " << *WidestFixupType; } LLVM_DUMP_METHOD void LSRUse::dump() const { print(errs()); errs() << '\n'; } #endif static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, LSRUse::KindType Kind, MemAccessTy AccessTy, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale, Instruction *Fixup/*= nullptr*/) { switch (Kind) { case LSRUse::Address: return TTI.isLegalAddressingMode(AccessTy.MemTy, BaseGV, BaseOffset, HasBaseReg, Scale, AccessTy.AddrSpace, Fixup); case LSRUse::ICmpZero: // There's not even a target hook for querying whether it would be legal to // fold a GV into an ICmp. if (BaseGV) return false; // ICmp only has two operands; don't allow more than two non-trivial parts. if (Scale != 0 && HasBaseReg && BaseOffset != 0) return false; // ICmp only supports no scale or a -1 scale, as we can "fold" a -1 scale by // putting the scaled register in the other operand of the icmp. if (Scale != 0 && Scale != -1) return false; // If we have low-level target information, ask the target if it can fold an // integer immediate on an icmp. if (BaseOffset != 0) { // We have one of: // ICmpZero BaseReg + BaseOffset => ICmp BaseReg, -BaseOffset // ICmpZero -1*ScaleReg + BaseOffset => ICmp ScaleReg, BaseOffset // Offs is the ICmp immediate. if (Scale == 0) // The cast does the right thing with // std::numeric_limits::min(). BaseOffset = -(uint64_t)BaseOffset; return TTI.isLegalICmpImmediate(BaseOffset); } // ICmpZero BaseReg + -1*ScaleReg => ICmp BaseReg, ScaleReg return true; case LSRUse::Basic: // Only handle single-register values. return !BaseGV && Scale == 0 && BaseOffset == 0; case LSRUse::Special: // Special case Basic to handle -1 scales. return !BaseGV && (Scale == 0 || Scale == -1) && BaseOffset == 0; } llvm_unreachable("Invalid LSRUse Kind!"); } static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, int64_t MinOffset, int64_t MaxOffset, LSRUse::KindType Kind, MemAccessTy AccessTy, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale) { // Check for overflow. if (((int64_t)((uint64_t)BaseOffset + MinOffset) > BaseOffset) != (MinOffset > 0)) return false; MinOffset = (uint64_t)BaseOffset + MinOffset; if (((int64_t)((uint64_t)BaseOffset + MaxOffset) > BaseOffset) != (MaxOffset > 0)) return false; MaxOffset = (uint64_t)BaseOffset + MaxOffset; return isAMCompletelyFolded(TTI, Kind, AccessTy, BaseGV, MinOffset, HasBaseReg, Scale) && isAMCompletelyFolded(TTI, Kind, AccessTy, BaseGV, MaxOffset, HasBaseReg, Scale); } static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, int64_t MinOffset, int64_t MaxOffset, LSRUse::KindType Kind, MemAccessTy AccessTy, const Formula &F, const Loop &L) { // For the purpose of isAMCompletelyFolded either having a canonical formula // or a scale not equal to zero is correct. // Problems may arise from non canonical formulae having a scale == 0. // Strictly speaking it would best to just rely on canonical formulae. // However, when we generate the scaled formulae, we first check that the // scaling factor is profitable before computing the actual ScaledReg for // compile time sake. assert((F.isCanonical(L) || F.Scale != 0)); return isAMCompletelyFolded(TTI, MinOffset, MaxOffset, Kind, AccessTy, F.BaseGV, F.BaseOffset, F.HasBaseReg, F.Scale); } /// Test whether we know how to expand the current formula. static bool isLegalUse(const TargetTransformInfo &TTI, int64_t MinOffset, int64_t MaxOffset, LSRUse::KindType Kind, MemAccessTy AccessTy, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg, int64_t Scale) { // We know how to expand completely foldable formulae. return isAMCompletelyFolded(TTI, MinOffset, MaxOffset, Kind, AccessTy, BaseGV, BaseOffset, HasBaseReg, Scale) || // Or formulae that use a base register produced by a sum of base // registers. (Scale == 1 && isAMCompletelyFolded(TTI, MinOffset, MaxOffset, Kind, AccessTy, BaseGV, BaseOffset, true, 0)); } static bool isLegalUse(const TargetTransformInfo &TTI, int64_t MinOffset, int64_t MaxOffset, LSRUse::KindType Kind, MemAccessTy AccessTy, const Formula &F) { return isLegalUse(TTI, MinOffset, MaxOffset, Kind, AccessTy, F.BaseGV, F.BaseOffset, F.HasBaseReg, F.Scale); } static bool isAMCompletelyFolded(const TargetTransformInfo &TTI, const LSRUse &LU, const Formula &F) { // Target may want to look at the user instructions. if (LU.Kind == LSRUse::Address && TTI.LSRWithInstrQueries()) { for (const LSRFixup &Fixup : LU.Fixups) if (!isAMCompletelyFolded(TTI, LSRUse::Address, LU.AccessTy, F.BaseGV, (F.BaseOffset + Fixup.Offset), F.HasBaseReg, F.Scale, Fixup.UserInst)) return false; return true; } return isAMCompletelyFolded(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F.BaseGV, F.BaseOffset, F.HasBaseReg, F.Scale); } static InstructionCost getScalingFactorCost(const TargetTransformInfo &TTI, const LSRUse &LU, const Formula &F, const Loop &L) { if (!F.Scale) return 0; // If the use is not completely folded in that instruction, we will have to // pay an extra cost only for scale != 1. if (!isAMCompletelyFolded(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F, L)) return F.Scale != 1; switch (LU.Kind) { case LSRUse::Address: { // Check the scaling factor cost with both the min and max offsets. InstructionCost ScaleCostMinOffset = TTI.getScalingFactorCost( LU.AccessTy.MemTy, F.BaseGV, F.BaseOffset + LU.MinOffset, F.HasBaseReg, F.Scale, LU.AccessTy.AddrSpace); InstructionCost ScaleCostMaxOffset = TTI.getScalingFactorCost( LU.AccessTy.MemTy, F.BaseGV, F.BaseOffset + LU.MaxOffset, F.HasBaseReg, F.Scale, LU.AccessTy.AddrSpace); assert(ScaleCostMinOffset.isValid() && ScaleCostMaxOffset.isValid() && "Legal addressing mode has an illegal cost!"); return std::max(ScaleCostMinOffset, ScaleCostMaxOffset); } case LSRUse::ICmpZero: case LSRUse::Basic: case LSRUse::Special: // The use is completely folded, i.e., everything is folded into the // instruction. return 0; } llvm_unreachable("Invalid LSRUse Kind!"); } static bool isAlwaysFoldable(const TargetTransformInfo &TTI, LSRUse::KindType Kind, MemAccessTy AccessTy, GlobalValue *BaseGV, int64_t BaseOffset, bool HasBaseReg) { // Fast-path: zero is always foldable. if (BaseOffset == 0 && !BaseGV) return true; // Conservatively, create an address with an immediate and a // base and a scale. int64_t Scale = Kind == LSRUse::ICmpZero ? -1 : 1; // Canonicalize a scale of 1 to a base register if the formula doesn't // already have a base register. if (!HasBaseReg && Scale == 1) { Scale = 0; HasBaseReg = true; } return isAMCompletelyFolded(TTI, Kind, AccessTy, BaseGV, BaseOffset, HasBaseReg, Scale); } static bool isAlwaysFoldable(const TargetTransformInfo &TTI, ScalarEvolution &SE, int64_t MinOffset, int64_t MaxOffset, LSRUse::KindType Kind, MemAccessTy AccessTy, const SCEV *S, bool HasBaseReg) { // Fast-path: zero is always foldable. if (S->isZero()) return true; // Conservatively, create an address with an immediate and a // base and a scale. int64_t BaseOffset = ExtractImmediate(S, SE); GlobalValue *BaseGV = ExtractSymbol(S, SE); // If there's anything else involved, it's not foldable. if (!S->isZero()) return false; // Fast-path: zero is always foldable. if (BaseOffset == 0 && !BaseGV) return true; // Conservatively, create an address with an immediate and a // base and a scale. int64_t Scale = Kind == LSRUse::ICmpZero ? -1 : 1; return isAMCompletelyFolded(TTI, MinOffset, MaxOffset, Kind, AccessTy, BaseGV, BaseOffset, HasBaseReg, Scale); } namespace { /// An individual increment in a Chain of IV increments. Relate an IV user to /// an expression that computes the IV it uses from the IV used by the previous /// link in the Chain. /// /// For the head of a chain, IncExpr holds the absolute SCEV expression for the /// original IVOperand. The head of the chain's IVOperand is only valid during /// chain collection, before LSR replaces IV users. During chain generation, /// IncExpr can be used to find the new IVOperand that computes the same /// expression. struct IVInc { Instruction *UserInst; Value* IVOperand; const SCEV *IncExpr; IVInc(Instruction *U, Value *O, const SCEV *E) : UserInst(U), IVOperand(O), IncExpr(E) {} }; // The list of IV increments in program order. We typically add the head of a // chain without finding subsequent links. struct IVChain { SmallVector Incs; const SCEV *ExprBase = nullptr; IVChain() = default; IVChain(const IVInc &Head, const SCEV *Base) : Incs(1, Head), ExprBase(Base) {} using const_iterator = SmallVectorImpl::const_iterator; // Return the first increment in the chain. const_iterator begin() const { assert(!Incs.empty()); return std::next(Incs.begin()); } const_iterator end() const { return Incs.end(); } // Returns true if this chain contains any increments. bool hasIncs() const { return Incs.size() >= 2; } // Add an IVInc to the end of this chain. void add(const IVInc &X) { Incs.push_back(X); } // Returns the last UserInst in the chain. Instruction *tailUserInst() const { return Incs.back().UserInst; } // Returns true if IncExpr can be profitably added to this chain. bool isProfitableIncrement(const SCEV *OperExpr, const SCEV *IncExpr, ScalarEvolution&); }; /// Helper for CollectChains to track multiple IV increment uses. Distinguish /// between FarUsers that definitely cross IV increments and NearUsers that may /// be used between IV increments. struct ChainUsers { SmallPtrSet FarUsers; SmallPtrSet NearUsers; }; /// This class holds state for the main loop strength reduction logic. class LSRInstance { IVUsers &IU; ScalarEvolution &SE; DominatorTree &DT; LoopInfo &LI; AssumptionCache &AC; TargetLibraryInfo &TLI; const TargetTransformInfo &TTI; Loop *const L; MemorySSAUpdater *MSSAU; TTI::AddressingModeKind AMK; bool Changed = false; /// This is the insert position that the current loop's induction variable /// increment should be placed. In simple loops, this is the latch block's /// terminator. But in more complicated cases, this is a position which will /// dominate all the in-loop post-increment users. Instruction *IVIncInsertPos = nullptr; /// Interesting factors between use strides. /// /// We explicitly use a SetVector which contains a SmallSet, instead of the /// default, a SmallDenseSet, because we need to use the full range of /// int64_ts, and there's currently no good way of doing that with /// SmallDenseSet. SetVector, SmallSet> Factors; /// Interesting use types, to facilitate truncation reuse. SmallSetVector Types; /// The list of interesting uses. mutable SmallVector Uses; /// Track which uses use which register candidates. RegUseTracker RegUses; // Limit the number of chains to avoid quadratic behavior. We don't expect to // have more than a few IV increment chains in a loop. Missing a Chain falls // back to normal LSR behavior for those uses. static const unsigned MaxChains = 8; /// IV users can form a chain of IV increments. SmallVector IVChainVec; /// IV users that belong to profitable IVChains. SmallPtrSet IVIncSet; /// Induction variables that were generated and inserted by the SCEV Expander. SmallVector ScalarEvolutionIVs; void OptimizeShadowIV(); bool FindIVUserForCond(ICmpInst *Cond, IVStrideUse *&CondUse); ICmpInst *OptimizeMax(ICmpInst *Cond, IVStrideUse* &CondUse); void OptimizeLoopTermCond(); void ChainInstruction(Instruction *UserInst, Instruction *IVOper, SmallVectorImpl &ChainUsersVec); void FinalizeChain(IVChain &Chain); void CollectChains(); void GenerateIVChain(const IVChain &Chain, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts); void CollectInterestingTypesAndFactors(); void CollectFixupsAndInitialFormulae(); // Support for sharing of LSRUses between LSRFixups. using UseMapTy = DenseMap; UseMapTy UseMap; bool reconcileNewOffset(LSRUse &LU, int64_t NewOffset, bool HasBaseReg, LSRUse::KindType Kind, MemAccessTy AccessTy); std::pair getUse(const SCEV *&Expr, LSRUse::KindType Kind, MemAccessTy AccessTy); void DeleteUse(LSRUse &LU, size_t LUIdx); LSRUse *FindUseWithSimilarFormula(const Formula &F, const LSRUse &OrigLU); void InsertInitialFormula(const SCEV *S, LSRUse &LU, size_t LUIdx); void InsertSupplementalFormula(const SCEV *S, LSRUse &LU, size_t LUIdx); void CountRegisters(const Formula &F, size_t LUIdx); bool InsertFormula(LSRUse &LU, unsigned LUIdx, const Formula &F); void CollectLoopInvariantFixupsAndFormulae(); void GenerateReassociations(LSRUse &LU, unsigned LUIdx, Formula Base, unsigned Depth = 0); void GenerateReassociationsImpl(LSRUse &LU, unsigned LUIdx, const Formula &Base, unsigned Depth, size_t Idx, bool IsScaledReg = false); void GenerateCombinations(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateSymbolicOffsetsImpl(LSRUse &LU, unsigned LUIdx, const Formula &Base, size_t Idx, bool IsScaledReg = false); void GenerateSymbolicOffsets(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateConstantOffsetsImpl(LSRUse &LU, unsigned LUIdx, const Formula &Base, const SmallVectorImpl &Worklist, size_t Idx, bool IsScaledReg = false); void GenerateConstantOffsets(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateICmpZeroScales(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateScales(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateTruncates(LSRUse &LU, unsigned LUIdx, Formula Base); void GenerateCrossUseConstantOffsets(); void GenerateAllReuseFormulae(); void FilterOutUndesirableDedicatedRegisters(); size_t EstimateSearchSpaceComplexity() const; void NarrowSearchSpaceByDetectingSupersets(); void NarrowSearchSpaceByCollapsingUnrolledCode(); void NarrowSearchSpaceByRefilteringUndesirableDedicatedRegisters(); void NarrowSearchSpaceByFilterFormulaWithSameScaledReg(); void NarrowSearchSpaceByFilterPostInc(); void NarrowSearchSpaceByDeletingCostlyFormulas(); void NarrowSearchSpaceByPickingWinnerRegs(); void NarrowSearchSpaceUsingHeuristics(); void SolveRecurse(SmallVectorImpl &Solution, Cost &SolutionCost, SmallVectorImpl &Workspace, const Cost &CurCost, const SmallPtrSet &CurRegs, DenseSet &VisitedRegs) const; void Solve(SmallVectorImpl &Solution) const; BasicBlock::iterator HoistInsertPosition(BasicBlock::iterator IP, const SmallVectorImpl &Inputs) const; BasicBlock::iterator AdjustInsertPositionForExpand(BasicBlock::iterator IP, const LSRFixup &LF, const LSRUse &LU, SCEVExpander &Rewriter) const; Value *Expand(const LSRUse &LU, const LSRFixup &LF, const Formula &F, BasicBlock::iterator IP, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const; void RewriteForPHI(PHINode *PN, const LSRUse &LU, const LSRFixup &LF, const Formula &F, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const; void Rewrite(const LSRUse &LU, const LSRFixup &LF, const Formula &F, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const; void ImplementSolution(const SmallVectorImpl &Solution); public: LSRInstance(Loop *L, IVUsers &IU, ScalarEvolution &SE, DominatorTree &DT, LoopInfo &LI, const TargetTransformInfo &TTI, AssumptionCache &AC, TargetLibraryInfo &TLI, MemorySSAUpdater *MSSAU); bool getChanged() const { return Changed; } const SmallVectorImpl &getScalarEvolutionIVs() const { return ScalarEvolutionIVs; } void print_factors_and_types(raw_ostream &OS) const; void print_fixups(raw_ostream &OS) const; void print_uses(raw_ostream &OS) const; void print(raw_ostream &OS) const; void dump() const; }; } // end anonymous namespace /// If IV is used in a int-to-float cast inside the loop then try to eliminate /// the cast operation. void LSRInstance::OptimizeShadowIV() { const SCEV *BackedgeTakenCount = SE.getBackedgeTakenCount(L); if (isa(BackedgeTakenCount)) return; for (IVUsers::const_iterator UI = IU.begin(), E = IU.end(); UI != E; /* empty */) { IVUsers::const_iterator CandidateUI = UI; ++UI; Instruction *ShadowUse = CandidateUI->getUser(); Type *DestTy = nullptr; bool IsSigned = false; /* If shadow use is a int->float cast then insert a second IV to eliminate this cast. for (unsigned i = 0; i < n; ++i) foo((double)i); is transformed into double d = 0.0; for (unsigned i = 0; i < n; ++i, ++d) foo(d); */ if (UIToFPInst *UCast = dyn_cast(CandidateUI->getUser())) { IsSigned = false; DestTy = UCast->getDestTy(); } else if (SIToFPInst *SCast = dyn_cast(CandidateUI->getUser())) { IsSigned = true; DestTy = SCast->getDestTy(); } if (!DestTy) continue; // If target does not support DestTy natively then do not apply // this transformation. if (!TTI.isTypeLegal(DestTy)) continue; PHINode *PH = dyn_cast(ShadowUse->getOperand(0)); if (!PH) continue; if (PH->getNumIncomingValues() != 2) continue; // If the calculation in integers overflows, the result in FP type will // differ. So we only can do this transformation if we are guaranteed to not // deal with overflowing values const SCEVAddRecExpr *AR = dyn_cast(SE.getSCEV(PH)); if (!AR) continue; if (IsSigned && !AR->hasNoSignedWrap()) continue; if (!IsSigned && !AR->hasNoUnsignedWrap()) continue; Type *SrcTy = PH->getType(); int Mantissa = DestTy->getFPMantissaWidth(); if (Mantissa == -1) continue; if ((int)SE.getTypeSizeInBits(SrcTy) > Mantissa) continue; unsigned Entry, Latch; if (PH->getIncomingBlock(0) == L->getLoopPreheader()) { Entry = 0; Latch = 1; } else { Entry = 1; Latch = 0; } ConstantInt *Init = dyn_cast(PH->getIncomingValue(Entry)); if (!Init) continue; Constant *NewInit = ConstantFP::get(DestTy, IsSigned ? (double)Init->getSExtValue() : (double)Init->getZExtValue()); BinaryOperator *Incr = dyn_cast(PH->getIncomingValue(Latch)); if (!Incr) continue; if (Incr->getOpcode() != Instruction::Add && Incr->getOpcode() != Instruction::Sub) continue; /* Initialize new IV, double d = 0.0 in above example. */ ConstantInt *C = nullptr; if (Incr->getOperand(0) == PH) C = dyn_cast(Incr->getOperand(1)); else if (Incr->getOperand(1) == PH) C = dyn_cast(Incr->getOperand(0)); else continue; if (!C) continue; // Ignore negative constants, as the code below doesn't handle them // correctly. TODO: Remove this restriction. if (!C->getValue().isStrictlyPositive()) continue; /* Add new PHINode. */ PHINode *NewPH = PHINode::Create(DestTy, 2, "IV.S.", PH); /* create new increment. '++d' in above example. */ Constant *CFP = ConstantFP::get(DestTy, C->getZExtValue()); BinaryOperator *NewIncr = BinaryOperator::Create(Incr->getOpcode() == Instruction::Add ? Instruction::FAdd : Instruction::FSub, NewPH, CFP, "IV.S.next.", Incr); NewPH->addIncoming(NewInit, PH->getIncomingBlock(Entry)); NewPH->addIncoming(NewIncr, PH->getIncomingBlock(Latch)); /* Remove cast operation */ ShadowUse->replaceAllUsesWith(NewPH); ShadowUse->eraseFromParent(); Changed = true; break; } } /// If Cond has an operand that is an expression of an IV, set the IV user and /// stride information and return true, otherwise return false. bool LSRInstance::FindIVUserForCond(ICmpInst *Cond, IVStrideUse *&CondUse) { for (IVStrideUse &U : IU) if (U.getUser() == Cond) { // NOTE: we could handle setcc instructions with multiple uses here, but // InstCombine does it as well for simple uses, it's not clear that it // occurs enough in real life to handle. CondUse = &U; return true; } return false; } /// Rewrite the loop's terminating condition if it uses a max computation. /// /// This is a narrow solution to a specific, but acute, problem. For loops /// like this: /// /// i = 0; /// do { /// p[i] = 0.0; /// } while (++i < n); /// /// the trip count isn't just 'n', because 'n' might not be positive. And /// unfortunately this can come up even for loops where the user didn't use /// a C do-while loop. For example, seemingly well-behaved top-test loops /// will commonly be lowered like this: /// /// if (n > 0) { /// i = 0; /// do { /// p[i] = 0.0; /// } while (++i < n); /// } /// /// and then it's possible for subsequent optimization to obscure the if /// test in such a way that indvars can't find it. /// /// When indvars can't find the if test in loops like this, it creates a /// max expression, which allows it to give the loop a canonical /// induction variable: /// /// i = 0; /// max = n < 1 ? 1 : n; /// do { /// p[i] = 0.0; /// } while (++i != max); /// /// Canonical induction variables are necessary because the loop passes /// are designed around them. The most obvious example of this is the /// LoopInfo analysis, which doesn't remember trip count values. It /// expects to be able to rediscover the trip count each time it is /// needed, and it does this using a simple analysis that only succeeds if /// the loop has a canonical induction variable. /// /// However, when it comes time to generate code, the maximum operation /// can be quite costly, especially if it's inside of an outer loop. /// /// This function solves this problem by detecting this type of loop and /// rewriting their conditions from ICMP_NE back to ICMP_SLT, and deleting /// the instructions for the maximum computation. ICmpInst *LSRInstance::OptimizeMax(ICmpInst *Cond, IVStrideUse* &CondUse) { // Check that the loop matches the pattern we're looking for. if (Cond->getPredicate() != CmpInst::ICMP_EQ && Cond->getPredicate() != CmpInst::ICMP_NE) return Cond; SelectInst *Sel = dyn_cast(Cond->getOperand(1)); if (!Sel || !Sel->hasOneUse()) return Cond; const SCEV *BackedgeTakenCount = SE.getBackedgeTakenCount(L); if (isa(BackedgeTakenCount)) return Cond; const SCEV *One = SE.getConstant(BackedgeTakenCount->getType(), 1); // Add one to the backedge-taken count to get the trip count. const SCEV *IterationCount = SE.getAddExpr(One, BackedgeTakenCount); if (IterationCount != SE.getSCEV(Sel)) return Cond; // Check for a max calculation that matches the pattern. There's no check // for ICMP_ULE here because the comparison would be with zero, which // isn't interesting. CmpInst::Predicate Pred = ICmpInst::BAD_ICMP_PREDICATE; const SCEVNAryExpr *Max = nullptr; if (const SCEVSMaxExpr *S = dyn_cast(BackedgeTakenCount)) { Pred = ICmpInst::ICMP_SLE; Max = S; } else if (const SCEVSMaxExpr *S = dyn_cast(IterationCount)) { Pred = ICmpInst::ICMP_SLT; Max = S; } else if (const SCEVUMaxExpr *U = dyn_cast(IterationCount)) { Pred = ICmpInst::ICMP_ULT; Max = U; } else { // No match; bail. return Cond; } // To handle a max with more than two operands, this optimization would // require additional checking and setup. if (Max->getNumOperands() != 2) return Cond; const SCEV *MaxLHS = Max->getOperand(0); const SCEV *MaxRHS = Max->getOperand(1); // ScalarEvolution canonicalizes constants to the left. For < and >, look // for a comparison with 1. For <= and >=, a comparison with zero. if (!MaxLHS || (ICmpInst::isTrueWhenEqual(Pred) ? !MaxLHS->isZero() : (MaxLHS != One))) return Cond; // Check the relevant induction variable for conformance to // the pattern. const SCEV *IV = SE.getSCEV(Cond->getOperand(0)); const SCEVAddRecExpr *AR = dyn_cast(IV); if (!AR || !AR->isAffine() || AR->getStart() != One || AR->getStepRecurrence(SE) != One) return Cond; assert(AR->getLoop() == L && "Loop condition operand is an addrec in a different loop!"); // Check the right operand of the select, and remember it, as it will // be used in the new comparison instruction. Value *NewRHS = nullptr; if (ICmpInst::isTrueWhenEqual(Pred)) { // Look for n+1, and grab n. if (AddOperator *BO = dyn_cast(Sel->getOperand(1))) if (ConstantInt *BO1 = dyn_cast(BO->getOperand(1))) if (BO1->isOne() && SE.getSCEV(BO->getOperand(0)) == MaxRHS) NewRHS = BO->getOperand(0); if (AddOperator *BO = dyn_cast(Sel->getOperand(2))) if (ConstantInt *BO1 = dyn_cast(BO->getOperand(1))) if (BO1->isOne() && SE.getSCEV(BO->getOperand(0)) == MaxRHS) NewRHS = BO->getOperand(0); if (!NewRHS) return Cond; } else if (SE.getSCEV(Sel->getOperand(1)) == MaxRHS) NewRHS = Sel->getOperand(1); else if (SE.getSCEV(Sel->getOperand(2)) == MaxRHS) NewRHS = Sel->getOperand(2); else if (const SCEVUnknown *SU = dyn_cast(MaxRHS)) NewRHS = SU->getValue(); else // Max doesn't match expected pattern. return Cond; // Determine the new comparison opcode. It may be signed or unsigned, // and the original comparison may be either equality or inequality. if (Cond->getPredicate() == CmpInst::ICMP_EQ) Pred = CmpInst::getInversePredicate(Pred); // Ok, everything looks ok to change the condition into an SLT or SGE and // delete the max calculation. ICmpInst *NewCond = new ICmpInst(Cond, Pred, Cond->getOperand(0), NewRHS, "scmp"); // Delete the max calculation instructions. NewCond->setDebugLoc(Cond->getDebugLoc()); Cond->replaceAllUsesWith(NewCond); CondUse->setUser(NewCond); Instruction *Cmp = cast(Sel->getOperand(0)); Cond->eraseFromParent(); Sel->eraseFromParent(); if (Cmp->use_empty()) Cmp->eraseFromParent(); return NewCond; } /// Change loop terminating condition to use the postinc iv when possible. void LSRInstance::OptimizeLoopTermCond() { SmallPtrSet PostIncs; // We need a different set of heuristics for rotated and non-rotated loops. // If a loop is rotated then the latch is also the backedge, so inserting // post-inc expressions just before the latch is ideal. To reduce live ranges // it also makes sense to rewrite terminating conditions to use post-inc // expressions. // // If the loop is not rotated then the latch is not a backedge; the latch // check is done in the loop head. Adding post-inc expressions before the // latch will cause overlapping live-ranges of pre-inc and post-inc expressions // in the loop body. In this case we do *not* want to use post-inc expressions // in the latch check, and we want to insert post-inc expressions before // the backedge. BasicBlock *LatchBlock = L->getLoopLatch(); SmallVector ExitingBlocks; L->getExitingBlocks(ExitingBlocks); if (llvm::all_of(ExitingBlocks, [&LatchBlock](const BasicBlock *BB) { return LatchBlock != BB; })) { // The backedge doesn't exit the loop; treat this as a head-tested loop. IVIncInsertPos = LatchBlock->getTerminator(); return; } // Otherwise treat this as a rotated loop. for (BasicBlock *ExitingBlock : ExitingBlocks) { // Get the terminating condition for the loop if possible. If we // can, we want to change it to use a post-incremented version of its // induction variable, to allow coalescing the live ranges for the IV into // one register value. BranchInst *TermBr = dyn_cast(ExitingBlock->getTerminator()); if (!TermBr) continue; // FIXME: Overly conservative, termination condition could be an 'or' etc.. if (TermBr->isUnconditional() || !isa(TermBr->getCondition())) continue; // Search IVUsesByStride to find Cond's IVUse if there is one. IVStrideUse *CondUse = nullptr; ICmpInst *Cond = cast(TermBr->getCondition()); if (!FindIVUserForCond(Cond, CondUse)) continue; // If the trip count is computed in terms of a max (due to ScalarEvolution // being unable to find a sufficient guard, for example), change the loop // comparison to use SLT or ULT instead of NE. // One consequence of doing this now is that it disrupts the count-down // optimization. That's not always a bad thing though, because in such // cases it may still be worthwhile to avoid a max. Cond = OptimizeMax(Cond, CondUse); // If this exiting block dominates the latch block, it may also use // the post-inc value if it won't be shared with other uses. // Check for dominance. if (!DT.dominates(ExitingBlock, LatchBlock)) continue; // Conservatively avoid trying to use the post-inc value in non-latch // exits if there may be pre-inc users in intervening blocks. if (LatchBlock != ExitingBlock) for (IVUsers::const_iterator UI = IU.begin(), E = IU.end(); UI != E; ++UI) // Test if the use is reachable from the exiting block. This dominator // query is a conservative approximation of reachability. if (&*UI != CondUse && !DT.properlyDominates(UI->getUser()->getParent(), ExitingBlock)) { // Conservatively assume there may be reuse if the quotient of their // strides could be a legal scale. const SCEV *A = IU.getStride(*CondUse, L); const SCEV *B = IU.getStride(*UI, L); if (!A || !B) continue; if (SE.getTypeSizeInBits(A->getType()) != SE.getTypeSizeInBits(B->getType())) { if (SE.getTypeSizeInBits(A->getType()) > SE.getTypeSizeInBits(B->getType())) B = SE.getSignExtendExpr(B, A->getType()); else A = SE.getSignExtendExpr(A, B->getType()); } if (const SCEVConstant *D = dyn_cast_or_null(getExactSDiv(B, A, SE))) { const ConstantInt *C = D->getValue(); // Stride of one or negative one can have reuse with non-addresses. if (C->isOne() || C->isMinusOne()) goto decline_post_inc; // Avoid weird situations. if (C->getValue().getMinSignedBits() >= 64 || C->getValue().isMinSignedValue()) goto decline_post_inc; // Check for possible scaled-address reuse. if (isAddressUse(TTI, UI->getUser(), UI->getOperandValToReplace())) { MemAccessTy AccessTy = getAccessType( TTI, UI->getUser(), UI->getOperandValToReplace()); int64_t Scale = C->getSExtValue(); if (TTI.isLegalAddressingMode(AccessTy.MemTy, /*BaseGV=*/nullptr, /*BaseOffset=*/0, /*HasBaseReg=*/false, Scale, AccessTy.AddrSpace)) goto decline_post_inc; Scale = -Scale; if (TTI.isLegalAddressingMode(AccessTy.MemTy, /*BaseGV=*/nullptr, /*BaseOffset=*/0, /*HasBaseReg=*/false, Scale, AccessTy.AddrSpace)) goto decline_post_inc; } } } LLVM_DEBUG(dbgs() << " Change loop exiting icmp to use postinc iv: " << *Cond << '\n'); // It's possible for the setcc instruction to be anywhere in the loop, and // possible for it to have multiple users. If it is not immediately before // the exiting block branch, move it. if (Cond->getNextNonDebugInstruction() != TermBr) { if (Cond->hasOneUse()) { Cond->moveBefore(TermBr); } else { // Clone the terminating condition and insert into the loopend. ICmpInst *OldCond = Cond; Cond = cast(Cond->clone()); Cond->setName(L->getHeader()->getName() + ".termcond"); ExitingBlock->getInstList().insert(TermBr->getIterator(), Cond); // Clone the IVUse, as the old use still exists! CondUse = &IU.AddUser(Cond, CondUse->getOperandValToReplace()); TermBr->replaceUsesOfWith(OldCond, Cond); } } // If we get to here, we know that we can transform the setcc instruction to // use the post-incremented version of the IV, allowing us to coalesce the // live ranges for the IV correctly. CondUse->transformToPostInc(L); Changed = true; PostIncs.insert(Cond); decline_post_inc:; } // Determine an insertion point for the loop induction variable increment. It // must dominate all the post-inc comparisons we just set up, and it must // dominate the loop latch edge. IVIncInsertPos = L->getLoopLatch()->getTerminator(); for (Instruction *Inst : PostIncs) { BasicBlock *BB = DT.findNearestCommonDominator(IVIncInsertPos->getParent(), Inst->getParent()); if (BB == Inst->getParent()) IVIncInsertPos = Inst; else if (BB != IVIncInsertPos->getParent()) IVIncInsertPos = BB->getTerminator(); } } /// Determine if the given use can accommodate a fixup at the given offset and /// other details. If so, update the use and return true. bool LSRInstance::reconcileNewOffset(LSRUse &LU, int64_t NewOffset, bool HasBaseReg, LSRUse::KindType Kind, MemAccessTy AccessTy) { int64_t NewMinOffset = LU.MinOffset; int64_t NewMaxOffset = LU.MaxOffset; MemAccessTy NewAccessTy = AccessTy; // Check for a mismatched kind. It's tempting to collapse mismatched kinds to // something conservative, however this can pessimize in the case that one of // the uses will have all its uses outside the loop, for example. if (LU.Kind != Kind) return false; // Check for a mismatched access type, and fall back conservatively as needed. // TODO: Be less conservative when the type is similar and can use the same // addressing modes. if (Kind == LSRUse::Address) { if (AccessTy.MemTy != LU.AccessTy.MemTy) { NewAccessTy = MemAccessTy::getUnknown(AccessTy.MemTy->getContext(), AccessTy.AddrSpace); } } // Conservatively assume HasBaseReg is true for now. if (NewOffset < LU.MinOffset) { if (!isAlwaysFoldable(TTI, Kind, NewAccessTy, /*BaseGV=*/nullptr, LU.MaxOffset - NewOffset, HasBaseReg)) return false; NewMinOffset = NewOffset; } else if (NewOffset > LU.MaxOffset) { if (!isAlwaysFoldable(TTI, Kind, NewAccessTy, /*BaseGV=*/nullptr, NewOffset - LU.MinOffset, HasBaseReg)) return false; NewMaxOffset = NewOffset; } // Update the use. LU.MinOffset = NewMinOffset; LU.MaxOffset = NewMaxOffset; LU.AccessTy = NewAccessTy; return true; } /// Return an LSRUse index and an offset value for a fixup which needs the given /// expression, with the given kind and optional access type. Either reuse an /// existing use or create a new one, as needed. std::pair LSRInstance::getUse(const SCEV *&Expr, LSRUse::KindType Kind, MemAccessTy AccessTy) { const SCEV *Copy = Expr; int64_t Offset = ExtractImmediate(Expr, SE); // Basic uses can't accept any offset, for example. if (!isAlwaysFoldable(TTI, Kind, AccessTy, /*BaseGV=*/ nullptr, Offset, /*HasBaseReg=*/ true)) { Expr = Copy; Offset = 0; } std::pair P = UseMap.insert(std::make_pair(LSRUse::SCEVUseKindPair(Expr, Kind), 0)); if (!P.second) { // A use already existed with this base. size_t LUIdx = P.first->second; LSRUse &LU = Uses[LUIdx]; if (reconcileNewOffset(LU, Offset, /*HasBaseReg=*/true, Kind, AccessTy)) // Reuse this use. return std::make_pair(LUIdx, Offset); } // Create a new use. size_t LUIdx = Uses.size(); P.first->second = LUIdx; Uses.push_back(LSRUse(Kind, AccessTy)); LSRUse &LU = Uses[LUIdx]; LU.MinOffset = Offset; LU.MaxOffset = Offset; return std::make_pair(LUIdx, Offset); } /// Delete the given use from the Uses list. void LSRInstance::DeleteUse(LSRUse &LU, size_t LUIdx) { if (&LU != &Uses.back()) std::swap(LU, Uses.back()); Uses.pop_back(); // Update RegUses. RegUses.swapAndDropUse(LUIdx, Uses.size()); } /// Look for a use distinct from OrigLU which is has a formula that has the same /// registers as the given formula. LSRUse * LSRInstance::FindUseWithSimilarFormula(const Formula &OrigF, const LSRUse &OrigLU) { // Search all uses for the formula. This could be more clever. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; // Check whether this use is close enough to OrigLU, to see whether it's // worthwhile looking through its formulae. // Ignore ICmpZero uses because they may contain formulae generated by // GenerateICmpZeroScales, in which case adding fixup offsets may // be invalid. if (&LU != &OrigLU && LU.Kind != LSRUse::ICmpZero && LU.Kind == OrigLU.Kind && OrigLU.AccessTy == LU.AccessTy && LU.WidestFixupType == OrigLU.WidestFixupType && LU.HasFormulaWithSameRegs(OrigF)) { // Scan through this use's formulae. for (const Formula &F : LU.Formulae) { // Check to see if this formula has the same registers and symbols // as OrigF. if (F.BaseRegs == OrigF.BaseRegs && F.ScaledReg == OrigF.ScaledReg && F.BaseGV == OrigF.BaseGV && F.Scale == OrigF.Scale && F.UnfoldedOffset == OrigF.UnfoldedOffset) { if (F.BaseOffset == 0) return &LU; // This is the formula where all the registers and symbols matched; // there aren't going to be any others. Since we declined it, we // can skip the rest of the formulae and proceed to the next LSRUse. break; } } } } // Nothing looked good. return nullptr; } void LSRInstance::CollectInterestingTypesAndFactors() { SmallSetVector Strides; // Collect interesting types and strides. SmallVector Worklist; for (const IVStrideUse &U : IU) { const SCEV *Expr = IU.getExpr(U); // Collect interesting types. Types.insert(SE.getEffectiveSCEVType(Expr->getType())); // Add strides for mentioned loops. Worklist.push_back(Expr); do { const SCEV *S = Worklist.pop_back_val(); if (const SCEVAddRecExpr *AR = dyn_cast(S)) { if (AR->getLoop() == L) Strides.insert(AR->getStepRecurrence(SE)); Worklist.push_back(AR->getStart()); } else if (const SCEVAddExpr *Add = dyn_cast(S)) { Worklist.append(Add->op_begin(), Add->op_end()); } } while (!Worklist.empty()); } // Compute interesting factors from the set of interesting strides. for (SmallSetVector::const_iterator I = Strides.begin(), E = Strides.end(); I != E; ++I) for (SmallSetVector::const_iterator NewStrideIter = std::next(I); NewStrideIter != E; ++NewStrideIter) { const SCEV *OldStride = *I; const SCEV *NewStride = *NewStrideIter; if (SE.getTypeSizeInBits(OldStride->getType()) != SE.getTypeSizeInBits(NewStride->getType())) { if (SE.getTypeSizeInBits(OldStride->getType()) > SE.getTypeSizeInBits(NewStride->getType())) NewStride = SE.getSignExtendExpr(NewStride, OldStride->getType()); else OldStride = SE.getSignExtendExpr(OldStride, NewStride->getType()); } if (const SCEVConstant *Factor = dyn_cast_or_null(getExactSDiv(NewStride, OldStride, SE, true))) { if (Factor->getAPInt().getMinSignedBits() <= 64 && !Factor->isZero()) Factors.insert(Factor->getAPInt().getSExtValue()); } else if (const SCEVConstant *Factor = dyn_cast_or_null(getExactSDiv(OldStride, NewStride, SE, true))) { if (Factor->getAPInt().getMinSignedBits() <= 64 && !Factor->isZero()) Factors.insert(Factor->getAPInt().getSExtValue()); } } // If all uses use the same type, don't bother looking for truncation-based // reuse. if (Types.size() == 1) Types.clear(); LLVM_DEBUG(print_factors_and_types(dbgs())); } /// Helper for CollectChains that finds an IV operand (computed by an AddRec in /// this loop) within [OI,OE) or returns OE. If IVUsers mapped Instructions to /// IVStrideUses, we could partially skip this. static User::op_iterator findIVOperand(User::op_iterator OI, User::op_iterator OE, Loop *L, ScalarEvolution &SE) { for(; OI != OE; ++OI) { if (Instruction *Oper = dyn_cast(*OI)) { if (!SE.isSCEVable(Oper->getType())) continue; if (const SCEVAddRecExpr *AR = dyn_cast(SE.getSCEV(Oper))) { if (AR->getLoop() == L) break; } } } return OI; } /// IVChain logic must consistently peek base TruncInst operands, so wrap it in /// a convenient helper. static Value *getWideOperand(Value *Oper) { if (TruncInst *Trunc = dyn_cast(Oper)) return Trunc->getOperand(0); return Oper; } /// Return true if we allow an IV chain to include both types. static bool isCompatibleIVType(Value *LVal, Value *RVal) { Type *LType = LVal->getType(); Type *RType = RVal->getType(); return (LType == RType) || (LType->isPointerTy() && RType->isPointerTy() && // Different address spaces means (possibly) // different types of the pointer implementation, // e.g. i16 vs i32 so disallow that. (LType->getPointerAddressSpace() == RType->getPointerAddressSpace())); } /// Return an approximation of this SCEV expression's "base", or NULL for any /// constant. Returning the expression itself is conservative. Returning a /// deeper subexpression is more precise and valid as long as it isn't less /// complex than another subexpression. For expressions involving multiple /// unscaled values, we need to return the pointer-type SCEVUnknown. This avoids /// forming chains across objects, such as: PrevOper==a[i], IVOper==b[i], /// IVInc==b-a. /// /// Since SCEVUnknown is the rightmost type, and pointers are the rightmost /// SCEVUnknown, we simply return the rightmost SCEV operand. static const SCEV *getExprBase(const SCEV *S) { switch (S->getSCEVType()) { default: // uncluding scUnknown. return S; case scConstant: return nullptr; case scTruncate: return getExprBase(cast(S)->getOperand()); case scZeroExtend: return getExprBase(cast(S)->getOperand()); case scSignExtend: return getExprBase(cast(S)->getOperand()); case scAddExpr: { // Skip over scaled operands (scMulExpr) to follow add operands as long as // there's nothing more complex. // FIXME: not sure if we want to recognize negation. const SCEVAddExpr *Add = cast(S); for (const SCEV *SubExpr : reverse(Add->operands())) { if (SubExpr->getSCEVType() == scAddExpr) return getExprBase(SubExpr); if (SubExpr->getSCEVType() != scMulExpr) return SubExpr; } return S; // all operands are scaled, be conservative. } case scAddRecExpr: return getExprBase(cast(S)->getStart()); } llvm_unreachable("Unknown SCEV kind!"); } /// Return true if the chain increment is profitable to expand into a loop /// invariant value, which may require its own register. A profitable chain /// increment will be an offset relative to the same base. We allow such offsets /// to potentially be used as chain increment as long as it's not obviously /// expensive to expand using real instructions. bool IVChain::isProfitableIncrement(const SCEV *OperExpr, const SCEV *IncExpr, ScalarEvolution &SE) { // Aggressively form chains when -stress-ivchain. if (StressIVChain) return true; // Do not replace a constant offset from IV head with a nonconstant IV // increment. if (!isa(IncExpr)) { const SCEV *HeadExpr = SE.getSCEV(getWideOperand(Incs[0].IVOperand)); if (isa(SE.getMinusSCEV(OperExpr, HeadExpr))) return false; } SmallPtrSet Processed; return !isHighCostExpansion(IncExpr, Processed, SE); } /// Return true if the number of registers needed for the chain is estimated to /// be less than the number required for the individual IV users. First prohibit /// any IV users that keep the IV live across increments (the Users set should /// be empty). Next count the number and type of increments in the chain. /// /// Chaining IVs can lead to considerable code bloat if ISEL doesn't /// effectively use postinc addressing modes. Only consider it profitable it the /// increments can be computed in fewer registers when chained. /// /// TODO: Consider IVInc free if it's already used in another chains. static bool isProfitableChain(IVChain &Chain, SmallPtrSetImpl &Users, ScalarEvolution &SE, const TargetTransformInfo &TTI) { if (StressIVChain) return true; if (!Chain.hasIncs()) return false; if (!Users.empty()) { LLVM_DEBUG(dbgs() << "Chain: " << *Chain.Incs[0].UserInst << " users:\n"; for (Instruction *Inst : Users) { dbgs() << " " << *Inst << "\n"; }); return false; } assert(!Chain.Incs.empty() && "empty IV chains are not allowed"); // The chain itself may require a register, so intialize cost to 1. int cost = 1; // A complete chain likely eliminates the need for keeping the original IV in // a register. LSR does not currently know how to form a complete chain unless // the header phi already exists. if (isa(Chain.tailUserInst()) && SE.getSCEV(Chain.tailUserInst()) == Chain.Incs[0].IncExpr) { --cost; } const SCEV *LastIncExpr = nullptr; unsigned NumConstIncrements = 0; unsigned NumVarIncrements = 0; unsigned NumReusedIncrements = 0; if (TTI.isProfitableLSRChainElement(Chain.Incs[0].UserInst)) return true; for (const IVInc &Inc : Chain) { if (TTI.isProfitableLSRChainElement(Inc.UserInst)) return true; if (Inc.IncExpr->isZero()) continue; // Incrementing by zero or some constant is neutral. We assume constants can // be folded into an addressing mode or an add's immediate operand. if (isa(Inc.IncExpr)) { ++NumConstIncrements; continue; } if (Inc.IncExpr == LastIncExpr) ++NumReusedIncrements; else ++NumVarIncrements; LastIncExpr = Inc.IncExpr; } // An IV chain with a single increment is handled by LSR's postinc // uses. However, a chain with multiple increments requires keeping the IV's // value live longer than it needs to be if chained. if (NumConstIncrements > 1) --cost; // Materializing increment expressions in the preheader that didn't exist in // the original code may cost a register. For example, sign-extended array // indices can produce ridiculous increments like this: // IV + ((sext i32 (2 * %s) to i64) + (-1 * (sext i32 %s to i64))) cost += NumVarIncrements; // Reusing variable increments likely saves a register to hold the multiple of // the stride. cost -= NumReusedIncrements; LLVM_DEBUG(dbgs() << "Chain: " << *Chain.Incs[0].UserInst << " Cost: " << cost << "\n"); return cost < 0; } /// Add this IV user to an existing chain or make it the head of a new chain. void LSRInstance::ChainInstruction(Instruction *UserInst, Instruction *IVOper, SmallVectorImpl &ChainUsersVec) { // When IVs are used as types of varying widths, they are generally converted // to a wider type with some uses remaining narrow under a (free) trunc. Value *const NextIV = getWideOperand(IVOper); const SCEV *const OperExpr = SE.getSCEV(NextIV); const SCEV *const OperExprBase = getExprBase(OperExpr); // Visit all existing chains. Check if its IVOper can be computed as a // profitable loop invariant increment from the last link in the Chain. unsigned ChainIdx = 0, NChains = IVChainVec.size(); const SCEV *LastIncExpr = nullptr; for (; ChainIdx < NChains; ++ChainIdx) { IVChain &Chain = IVChainVec[ChainIdx]; // Prune the solution space aggressively by checking that both IV operands // are expressions that operate on the same unscaled SCEVUnknown. This // "base" will be canceled by the subsequent getMinusSCEV call. Checking // first avoids creating extra SCEV expressions. if (!StressIVChain && Chain.ExprBase != OperExprBase) continue; Value *PrevIV = getWideOperand(Chain.Incs.back().IVOperand); if (!isCompatibleIVType(PrevIV, NextIV)) continue; // A phi node terminates a chain. if (isa(UserInst) && isa(Chain.tailUserInst())) continue; // The increment must be loop-invariant so it can be kept in a register. const SCEV *PrevExpr = SE.getSCEV(PrevIV); const SCEV *IncExpr = SE.getMinusSCEV(OperExpr, PrevExpr); if (isa(IncExpr) || !SE.isLoopInvariant(IncExpr, L)) continue; if (Chain.isProfitableIncrement(OperExpr, IncExpr, SE)) { LastIncExpr = IncExpr; break; } } // If we haven't found a chain, create a new one, unless we hit the max. Don't // bother for phi nodes, because they must be last in the chain. if (ChainIdx == NChains) { if (isa(UserInst)) return; if (NChains >= MaxChains && !StressIVChain) { LLVM_DEBUG(dbgs() << "IV Chain Limit\n"); return; } LastIncExpr = OperExpr; // IVUsers may have skipped over sign/zero extensions. We don't currently // attempt to form chains involving extensions unless they can be hoisted // into this loop's AddRec. if (!isa(LastIncExpr)) return; ++NChains; IVChainVec.push_back(IVChain(IVInc(UserInst, IVOper, LastIncExpr), OperExprBase)); ChainUsersVec.resize(NChains); LLVM_DEBUG(dbgs() << "IV Chain#" << ChainIdx << " Head: (" << *UserInst << ") IV=" << *LastIncExpr << "\n"); } else { LLVM_DEBUG(dbgs() << "IV Chain#" << ChainIdx << " Inc: (" << *UserInst << ") IV+" << *LastIncExpr << "\n"); // Add this IV user to the end of the chain. IVChainVec[ChainIdx].add(IVInc(UserInst, IVOper, LastIncExpr)); } IVChain &Chain = IVChainVec[ChainIdx]; SmallPtrSet &NearUsers = ChainUsersVec[ChainIdx].NearUsers; // This chain's NearUsers become FarUsers. if (!LastIncExpr->isZero()) { ChainUsersVec[ChainIdx].FarUsers.insert(NearUsers.begin(), NearUsers.end()); NearUsers.clear(); } // All other uses of IVOperand become near uses of the chain. // We currently ignore intermediate values within SCEV expressions, assuming // they will eventually be used be the current chain, or can be computed // from one of the chain increments. To be more precise we could // transitively follow its user and only add leaf IV users to the set. for (User *U : IVOper->users()) { Instruction *OtherUse = dyn_cast(U); if (!OtherUse) continue; // Uses in the chain will no longer be uses if the chain is formed. // Include the head of the chain in this iteration (not Chain.begin()). IVChain::const_iterator IncIter = Chain.Incs.begin(); IVChain::const_iterator IncEnd = Chain.Incs.end(); for( ; IncIter != IncEnd; ++IncIter) { if (IncIter->UserInst == OtherUse) break; } if (IncIter != IncEnd) continue; if (SE.isSCEVable(OtherUse->getType()) && !isa(SE.getSCEV(OtherUse)) && IU.isIVUserOrOperand(OtherUse)) { continue; } NearUsers.insert(OtherUse); } // Since this user is part of the chain, it's no longer considered a use // of the chain. ChainUsersVec[ChainIdx].FarUsers.erase(UserInst); } /// Populate the vector of Chains. /// /// This decreases ILP at the architecture level. Targets with ample registers, /// multiple memory ports, and no register renaming probably don't want /// this. However, such targets should probably disable LSR altogether. /// /// The job of LSR is to make a reasonable choice of induction variables across /// the loop. Subsequent passes can easily "unchain" computation exposing more /// ILP *within the loop* if the target wants it. /// /// Finding the best IV chain is potentially a scheduling problem. Since LSR /// will not reorder memory operations, it will recognize this as a chain, but /// will generate redundant IV increments. Ideally this would be corrected later /// by a smart scheduler: /// = A[i] /// = A[i+x] /// A[i] = /// A[i+x] = /// /// TODO: Walk the entire domtree within this loop, not just the path to the /// loop latch. This will discover chains on side paths, but requires /// maintaining multiple copies of the Chains state. void LSRInstance::CollectChains() { LLVM_DEBUG(dbgs() << "Collecting IV Chains.\n"); SmallVector ChainUsersVec; SmallVector LatchPath; BasicBlock *LoopHeader = L->getHeader(); for (DomTreeNode *Rung = DT.getNode(L->getLoopLatch()); Rung->getBlock() != LoopHeader; Rung = Rung->getIDom()) { LatchPath.push_back(Rung->getBlock()); } LatchPath.push_back(LoopHeader); // Walk the instruction stream from the loop header to the loop latch. for (BasicBlock *BB : reverse(LatchPath)) { for (Instruction &I : *BB) { // Skip instructions that weren't seen by IVUsers analysis. if (isa(I) || !IU.isIVUserOrOperand(&I)) continue; // Ignore users that are part of a SCEV expression. This way we only // consider leaf IV Users. This effectively rediscovers a portion of // IVUsers analysis but in program order this time. if (SE.isSCEVable(I.getType()) && !isa(SE.getSCEV(&I))) continue; // Remove this instruction from any NearUsers set it may be in. for (unsigned ChainIdx = 0, NChains = IVChainVec.size(); ChainIdx < NChains; ++ChainIdx) { ChainUsersVec[ChainIdx].NearUsers.erase(&I); } // Search for operands that can be chained. SmallPtrSet UniqueOperands; User::op_iterator IVOpEnd = I.op_end(); User::op_iterator IVOpIter = findIVOperand(I.op_begin(), IVOpEnd, L, SE); while (IVOpIter != IVOpEnd) { Instruction *IVOpInst = cast(*IVOpIter); if (UniqueOperands.insert(IVOpInst).second) ChainInstruction(&I, IVOpInst, ChainUsersVec); IVOpIter = findIVOperand(std::next(IVOpIter), IVOpEnd, L, SE); } } // Continue walking down the instructions. } // Continue walking down the domtree. // Visit phi backedges to determine if the chain can generate the IV postinc. for (PHINode &PN : L->getHeader()->phis()) { if (!SE.isSCEVable(PN.getType())) continue; Instruction *IncV = dyn_cast(PN.getIncomingValueForBlock(L->getLoopLatch())); if (IncV) ChainInstruction(&PN, IncV, ChainUsersVec); } // Remove any unprofitable chains. unsigned ChainIdx = 0; for (unsigned UsersIdx = 0, NChains = IVChainVec.size(); UsersIdx < NChains; ++UsersIdx) { if (!isProfitableChain(IVChainVec[UsersIdx], ChainUsersVec[UsersIdx].FarUsers, SE, TTI)) continue; // Preserve the chain at UsesIdx. if (ChainIdx != UsersIdx) IVChainVec[ChainIdx] = IVChainVec[UsersIdx]; FinalizeChain(IVChainVec[ChainIdx]); ++ChainIdx; } IVChainVec.resize(ChainIdx); } void LSRInstance::FinalizeChain(IVChain &Chain) { assert(!Chain.Incs.empty() && "empty IV chains are not allowed"); LLVM_DEBUG(dbgs() << "Final Chain: " << *Chain.Incs[0].UserInst << "\n"); for (const IVInc &Inc : Chain) { LLVM_DEBUG(dbgs() << " Inc: " << *Inc.UserInst << "\n"); auto UseI = find(Inc.UserInst->operands(), Inc.IVOperand); assert(UseI != Inc.UserInst->op_end() && "cannot find IV operand"); IVIncSet.insert(UseI); } } /// Return true if the IVInc can be folded into an addressing mode. static bool canFoldIVIncExpr(const SCEV *IncExpr, Instruction *UserInst, Value *Operand, const TargetTransformInfo &TTI) { const SCEVConstant *IncConst = dyn_cast(IncExpr); if (!IncConst || !isAddressUse(TTI, UserInst, Operand)) return false; if (IncConst->getAPInt().getMinSignedBits() > 64) return false; MemAccessTy AccessTy = getAccessType(TTI, UserInst, Operand); int64_t IncOffset = IncConst->getValue()->getSExtValue(); if (!isAlwaysFoldable(TTI, LSRUse::Address, AccessTy, /*BaseGV=*/nullptr, IncOffset, /*HasBaseReg=*/false)) return false; return true; } /// Generate an add or subtract for each IVInc in a chain to materialize the IV /// user's operand from the previous IV user's operand. void LSRInstance::GenerateIVChain(const IVChain &Chain, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) { // Find the new IVOperand for the head of the chain. It may have been replaced // by LSR. const IVInc &Head = Chain.Incs[0]; User::op_iterator IVOpEnd = Head.UserInst->op_end(); // findIVOperand returns IVOpEnd if it can no longer find a valid IV user. User::op_iterator IVOpIter = findIVOperand(Head.UserInst->op_begin(), IVOpEnd, L, SE); Value *IVSrc = nullptr; while (IVOpIter != IVOpEnd) { IVSrc = getWideOperand(*IVOpIter); // If this operand computes the expression that the chain needs, we may use // it. (Check this after setting IVSrc which is used below.) // // Note that if Head.IncExpr is wider than IVSrc, then this phi is too // narrow for the chain, so we can no longer use it. We do allow using a // wider phi, assuming the LSR checked for free truncation. In that case we // should already have a truncate on this operand such that // getSCEV(IVSrc) == IncExpr. if (SE.getSCEV(*IVOpIter) == Head.IncExpr || SE.getSCEV(IVSrc) == Head.IncExpr) { break; } IVOpIter = findIVOperand(std::next(IVOpIter), IVOpEnd, L, SE); } if (IVOpIter == IVOpEnd) { // Gracefully give up on this chain. LLVM_DEBUG(dbgs() << "Concealed chain head: " << *Head.UserInst << "\n"); return; } assert(IVSrc && "Failed to find IV chain source"); LLVM_DEBUG(dbgs() << "Generate chain at: " << *IVSrc << "\n"); Type *IVTy = IVSrc->getType(); Type *IntTy = SE.getEffectiveSCEVType(IVTy); const SCEV *LeftOverExpr = nullptr; for (const IVInc &Inc : Chain) { Instruction *InsertPt = Inc.UserInst; if (isa(InsertPt)) InsertPt = L->getLoopLatch()->getTerminator(); // IVOper will replace the current IV User's operand. IVSrc is the IV // value currently held in a register. Value *IVOper = IVSrc; if (!Inc.IncExpr->isZero()) { // IncExpr was the result of subtraction of two narrow values, so must // be signed. const SCEV *IncExpr = SE.getNoopOrSignExtend(Inc.IncExpr, IntTy); LeftOverExpr = LeftOverExpr ? SE.getAddExpr(LeftOverExpr, IncExpr) : IncExpr; } if (LeftOverExpr && !LeftOverExpr->isZero()) { // Expand the IV increment. Rewriter.clearPostInc(); Value *IncV = Rewriter.expandCodeFor(LeftOverExpr, IntTy, InsertPt); const SCEV *IVOperExpr = SE.getAddExpr(SE.getUnknown(IVSrc), SE.getUnknown(IncV)); IVOper = Rewriter.expandCodeFor(IVOperExpr, IVTy, InsertPt); // If an IV increment can't be folded, use it as the next IV value. if (!canFoldIVIncExpr(LeftOverExpr, Inc.UserInst, Inc.IVOperand, TTI)) { assert(IVTy == IVOper->getType() && "inconsistent IV increment type"); IVSrc = IVOper; LeftOverExpr = nullptr; } } Type *OperTy = Inc.IVOperand->getType(); if (IVTy != OperTy) { assert(SE.getTypeSizeInBits(IVTy) >= SE.getTypeSizeInBits(OperTy) && "cannot extend a chained IV"); IRBuilder<> Builder(InsertPt); IVOper = Builder.CreateTruncOrBitCast(IVOper, OperTy, "lsr.chain"); } Inc.UserInst->replaceUsesOfWith(Inc.IVOperand, IVOper); if (auto *OperandIsInstr = dyn_cast(Inc.IVOperand)) DeadInsts.emplace_back(OperandIsInstr); } // If LSR created a new, wider phi, we may also replace its postinc. We only // do this if we also found a wide value for the head of the chain. if (isa(Chain.tailUserInst())) { for (PHINode &Phi : L->getHeader()->phis()) { if (!isCompatibleIVType(&Phi, IVSrc)) continue; Instruction *PostIncV = dyn_cast( Phi.getIncomingValueForBlock(L->getLoopLatch())); if (!PostIncV || (SE.getSCEV(PostIncV) != SE.getSCEV(IVSrc))) continue; Value *IVOper = IVSrc; Type *PostIncTy = PostIncV->getType(); if (IVTy != PostIncTy) { assert(PostIncTy->isPointerTy() && "mixing int/ptr IV types"); IRBuilder<> Builder(L->getLoopLatch()->getTerminator()); Builder.SetCurrentDebugLocation(PostIncV->getDebugLoc()); IVOper = Builder.CreatePointerCast(IVSrc, PostIncTy, "lsr.chain"); } Phi.replaceUsesOfWith(PostIncV, IVOper); DeadInsts.emplace_back(PostIncV); } } } void LSRInstance::CollectFixupsAndInitialFormulae() { BranchInst *ExitBranch = nullptr; bool SaveCmp = TTI.canSaveCmp(L, &ExitBranch, &SE, &LI, &DT, &AC, &TLI); for (const IVStrideUse &U : IU) { Instruction *UserInst = U.getUser(); // Skip IV users that are part of profitable IV Chains. User::op_iterator UseI = find(UserInst->operands(), U.getOperandValToReplace()); assert(UseI != UserInst->op_end() && "cannot find IV operand"); if (IVIncSet.count(UseI)) { LLVM_DEBUG(dbgs() << "Use is in profitable chain: " << **UseI << '\n'); continue; } LSRUse::KindType Kind = LSRUse::Basic; MemAccessTy AccessTy; if (isAddressUse(TTI, UserInst, U.getOperandValToReplace())) { Kind = LSRUse::Address; AccessTy = getAccessType(TTI, UserInst, U.getOperandValToReplace()); } const SCEV *S = IU.getExpr(U); PostIncLoopSet TmpPostIncLoops = U.getPostIncLoops(); // Equality (== and !=) ICmps are special. We can rewrite (i == N) as // (N - i == 0), and this allows (N - i) to be the expression that we work // with rather than just N or i, so we can consider the register // requirements for both N and i at the same time. Limiting this code to // equality icmps is not a problem because all interesting loops use // equality icmps, thanks to IndVarSimplify. if (ICmpInst *CI = dyn_cast(UserInst)) { // If CI can be saved in some target, like replaced inside hardware loop // in PowerPC, no need to generate initial formulae for it. if (SaveCmp && CI == dyn_cast(ExitBranch->getCondition())) continue; if (CI->isEquality()) { // Swap the operands if needed to put the OperandValToReplace on the // left, for consistency. Value *NV = CI->getOperand(1); if (NV == U.getOperandValToReplace()) { CI->setOperand(1, CI->getOperand(0)); CI->setOperand(0, NV); NV = CI->getOperand(1); Changed = true; } // x == y --> x - y == 0 const SCEV *N = SE.getSCEV(NV); if (SE.isLoopInvariant(N, L) && isSafeToExpand(N, SE) && (!NV->getType()->isPointerTy() || SE.getPointerBase(N) == SE.getPointerBase(S))) { // S is normalized, so normalize N before folding it into S // to keep the result normalized. N = normalizeForPostIncUse(N, TmpPostIncLoops, SE); Kind = LSRUse::ICmpZero; S = SE.getMinusSCEV(N, S); } // -1 and the negations of all interesting strides (except the negation // of -1) are now also interesting. for (size_t i = 0, e = Factors.size(); i != e; ++i) if (Factors[i] != -1) Factors.insert(-(uint64_t)Factors[i]); Factors.insert(-1); } } // Get or create an LSRUse. std::pair P = getUse(S, Kind, AccessTy); size_t LUIdx = P.first; int64_t Offset = P.second; LSRUse &LU = Uses[LUIdx]; // Record the fixup. LSRFixup &LF = LU.getNewFixup(); LF.UserInst = UserInst; LF.OperandValToReplace = U.getOperandValToReplace(); LF.PostIncLoops = TmpPostIncLoops; LF.Offset = Offset; LU.AllFixupsOutsideLoop &= LF.isUseFullyOutsideLoop(L); if (!LU.WidestFixupType || SE.getTypeSizeInBits(LU.WidestFixupType) < SE.getTypeSizeInBits(LF.OperandValToReplace->getType())) LU.WidestFixupType = LF.OperandValToReplace->getType(); // If this is the first use of this LSRUse, give it a formula. if (LU.Formulae.empty()) { InsertInitialFormula(S, LU, LUIdx); CountRegisters(LU.Formulae.back(), LUIdx); } } LLVM_DEBUG(print_fixups(dbgs())); } /// Insert a formula for the given expression into the given use, separating out /// loop-variant portions from loop-invariant and loop-computable portions. void LSRInstance::InsertInitialFormula(const SCEV *S, LSRUse &LU, size_t LUIdx) { // Mark uses whose expressions cannot be expanded. if (!isSafeToExpand(S, SE, /*CanonicalMode*/ false)) LU.RigidFormula = true; Formula F; F.initialMatch(S, L, SE); bool Inserted = InsertFormula(LU, LUIdx, F); assert(Inserted && "Initial formula already exists!"); (void)Inserted; } /// Insert a simple single-register formula for the given expression into the /// given use. void LSRInstance::InsertSupplementalFormula(const SCEV *S, LSRUse &LU, size_t LUIdx) { Formula F; F.BaseRegs.push_back(S); F.HasBaseReg = true; bool Inserted = InsertFormula(LU, LUIdx, F); assert(Inserted && "Supplemental formula already exists!"); (void)Inserted; } /// Note which registers are used by the given formula, updating RegUses. void LSRInstance::CountRegisters(const Formula &F, size_t LUIdx) { if (F.ScaledReg) RegUses.countRegister(F.ScaledReg, LUIdx); for (const SCEV *BaseReg : F.BaseRegs) RegUses.countRegister(BaseReg, LUIdx); } /// If the given formula has not yet been inserted, add it to the list, and /// return true. Return false otherwise. bool LSRInstance::InsertFormula(LSRUse &LU, unsigned LUIdx, const Formula &F) { // Do not insert formula that we will not be able to expand. assert(isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F) && "Formula is illegal"); if (!LU.InsertFormula(F, *L)) return false; CountRegisters(F, LUIdx); return true; } /// Check for other uses of loop-invariant values which we're tracking. These /// other uses will pin these values in registers, making them less profitable /// for elimination. /// TODO: This currently misses non-constant addrec step registers. /// TODO: Should this give more weight to users inside the loop? void LSRInstance::CollectLoopInvariantFixupsAndFormulae() { SmallVector Worklist(RegUses.begin(), RegUses.end()); SmallPtrSet Visited; while (!Worklist.empty()) { const SCEV *S = Worklist.pop_back_val(); // Don't process the same SCEV twice if (!Visited.insert(S).second) continue; if (const SCEVNAryExpr *N = dyn_cast(S)) Worklist.append(N->op_begin(), N->op_end()); else if (const SCEVIntegralCastExpr *C = dyn_cast(S)) Worklist.push_back(C->getOperand()); else if (const SCEVUDivExpr *D = dyn_cast(S)) { Worklist.push_back(D->getLHS()); Worklist.push_back(D->getRHS()); } else if (const SCEVUnknown *US = dyn_cast(S)) { const Value *V = US->getValue(); if (const Instruction *Inst = dyn_cast(V)) { // Look for instructions defined outside the loop. if (L->contains(Inst)) continue; } else if (isa(V)) // Undef doesn't have a live range, so it doesn't matter. continue; for (const Use &U : V->uses()) { const Instruction *UserInst = dyn_cast(U.getUser()); // Ignore non-instructions. if (!UserInst) continue; // Don't bother if the instruction is an EHPad. if (UserInst->isEHPad()) continue; // Ignore instructions in other functions (as can happen with // Constants). if (UserInst->getParent()->getParent() != L->getHeader()->getParent()) continue; // Ignore instructions not dominated by the loop. const BasicBlock *UseBB = !isa(UserInst) ? UserInst->getParent() : cast(UserInst)->getIncomingBlock( PHINode::getIncomingValueNumForOperand(U.getOperandNo())); if (!DT.dominates(L->getHeader(), UseBB)) continue; // Don't bother if the instruction is in a BB which ends in an EHPad. if (UseBB->getTerminator()->isEHPad()) continue; // Ignore cases in which the currently-examined value could come from // a basic block terminated with an EHPad. This checks all incoming // blocks of the phi node since it is possible that the same incoming // value comes from multiple basic blocks, only some of which may end // in an EHPad. If any of them do, a subsequent rewrite attempt by this // pass would try to insert instructions into an EHPad, hitting an // assertion. if (isa(UserInst)) { const auto *PhiNode = cast(UserInst); bool HasIncompatibleEHPTerminatedBlock = false; llvm::Value *ExpectedValue = U; for (unsigned int I = 0; I < PhiNode->getNumIncomingValues(); I++) { if (PhiNode->getIncomingValue(I) == ExpectedValue) { if (PhiNode->getIncomingBlock(I)->getTerminator()->isEHPad()) { HasIncompatibleEHPTerminatedBlock = true; break; } } } if (HasIncompatibleEHPTerminatedBlock) { continue; } } // Don't bother rewriting PHIs in catchswitch blocks. if (isa(UserInst->getParent()->getTerminator())) continue; // Ignore uses which are part of other SCEV expressions, to avoid // analyzing them multiple times. if (SE.isSCEVable(UserInst->getType())) { const SCEV *UserS = SE.getSCEV(const_cast(UserInst)); // If the user is a no-op, look through to its uses. if (!isa(UserS)) continue; if (UserS == US) { Worklist.push_back( SE.getUnknown(const_cast(UserInst))); continue; } } // Ignore icmp instructions which are already being analyzed. if (const ICmpInst *ICI = dyn_cast(UserInst)) { unsigned OtherIdx = !U.getOperandNo(); Value *OtherOp = const_cast(ICI->getOperand(OtherIdx)); if (SE.hasComputableLoopEvolution(SE.getSCEV(OtherOp), L)) continue; } std::pair P = getUse( S, LSRUse::Basic, MemAccessTy()); size_t LUIdx = P.first; int64_t Offset = P.second; LSRUse &LU = Uses[LUIdx]; LSRFixup &LF = LU.getNewFixup(); LF.UserInst = const_cast(UserInst); LF.OperandValToReplace = U; LF.Offset = Offset; LU.AllFixupsOutsideLoop &= LF.isUseFullyOutsideLoop(L); if (!LU.WidestFixupType || SE.getTypeSizeInBits(LU.WidestFixupType) < SE.getTypeSizeInBits(LF.OperandValToReplace->getType())) LU.WidestFixupType = LF.OperandValToReplace->getType(); InsertSupplementalFormula(US, LU, LUIdx); CountRegisters(LU.Formulae.back(), Uses.size() - 1); break; } } } } /// Split S into subexpressions which can be pulled out into separate /// registers. If C is non-null, multiply each subexpression by C. /// /// Return remainder expression after factoring the subexpressions captured by /// Ops. If Ops is complete, return NULL. static const SCEV *CollectSubexprs(const SCEV *S, const SCEVConstant *C, SmallVectorImpl &Ops, const Loop *L, ScalarEvolution &SE, unsigned Depth = 0) { // Arbitrarily cap recursion to protect compile time. if (Depth >= 3) return S; if (const SCEVAddExpr *Add = dyn_cast(S)) { // Break out add operands. for (const SCEV *S : Add->operands()) { const SCEV *Remainder = CollectSubexprs(S, C, Ops, L, SE, Depth+1); if (Remainder) Ops.push_back(C ? SE.getMulExpr(C, Remainder) : Remainder); } return nullptr; } else if (const SCEVAddRecExpr *AR = dyn_cast(S)) { // Split a non-zero base out of an addrec. if (AR->getStart()->isZero() || !AR->isAffine()) return S; const SCEV *Remainder = CollectSubexprs(AR->getStart(), C, Ops, L, SE, Depth+1); // Split the non-zero AddRec unless it is part of a nested recurrence that // does not pertain to this loop. if (Remainder && (AR->getLoop() == L || !isa(Remainder))) { Ops.push_back(C ? SE.getMulExpr(C, Remainder) : Remainder); Remainder = nullptr; } if (Remainder != AR->getStart()) { if (!Remainder) Remainder = SE.getConstant(AR->getType(), 0); return SE.getAddRecExpr(Remainder, AR->getStepRecurrence(SE), AR->getLoop(), //FIXME: AR->getNoWrapFlags(SCEV::FlagNW) SCEV::FlagAnyWrap); } } else if (const SCEVMulExpr *Mul = dyn_cast(S)) { // Break (C * (a + b + c)) into C*a + C*b + C*c. if (Mul->getNumOperands() != 2) return S; if (const SCEVConstant *Op0 = dyn_cast(Mul->getOperand(0))) { C = C ? cast(SE.getMulExpr(C, Op0)) : Op0; const SCEV *Remainder = CollectSubexprs(Mul->getOperand(1), C, Ops, L, SE, Depth+1); if (Remainder) Ops.push_back(SE.getMulExpr(C, Remainder)); return nullptr; } } return S; } /// Return true if the SCEV represents a value that may end up as a /// post-increment operation. static bool mayUsePostIncMode(const TargetTransformInfo &TTI, LSRUse &LU, const SCEV *S, const Loop *L, ScalarEvolution &SE) { if (LU.Kind != LSRUse::Address || !LU.AccessTy.getType()->isIntOrIntVectorTy()) return false; const SCEVAddRecExpr *AR = dyn_cast(S); if (!AR) return false; const SCEV *LoopStep = AR->getStepRecurrence(SE); if (!isa(LoopStep)) return false; // Check if a post-indexed load/store can be used. if (TTI.isIndexedLoadLegal(TTI.MIM_PostInc, AR->getType()) || TTI.isIndexedStoreLegal(TTI.MIM_PostInc, AR->getType())) { const SCEV *LoopStart = AR->getStart(); if (!isa(LoopStart) && SE.isLoopInvariant(LoopStart, L)) return true; } return false; } /// Helper function for LSRInstance::GenerateReassociations. void LSRInstance::GenerateReassociationsImpl(LSRUse &LU, unsigned LUIdx, const Formula &Base, unsigned Depth, size_t Idx, bool IsScaledReg) { const SCEV *BaseReg = IsScaledReg ? Base.ScaledReg : Base.BaseRegs[Idx]; // Don't generate reassociations for the base register of a value that // may generate a post-increment operator. The reason is that the // reassociations cause extra base+register formula to be created, // and possibly chosen, but the post-increment is more efficient. if (AMK == TTI::AMK_PostIndexed && mayUsePostIncMode(TTI, LU, BaseReg, L, SE)) return; SmallVector AddOps; const SCEV *Remainder = CollectSubexprs(BaseReg, nullptr, AddOps, L, SE); if (Remainder) AddOps.push_back(Remainder); if (AddOps.size() == 1) return; for (SmallVectorImpl::const_iterator J = AddOps.begin(), JE = AddOps.end(); J != JE; ++J) { // Loop-variant "unknown" values are uninteresting; we won't be able to // do anything meaningful with them. if (isa(*J) && !SE.isLoopInvariant(*J, L)) continue; // Don't pull a constant into a register if the constant could be folded // into an immediate field. if (isAlwaysFoldable(TTI, SE, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, *J, Base.getNumRegs() > 1)) continue; // Collect all operands except *J. SmallVector InnerAddOps( ((const SmallVector &)AddOps).begin(), J); InnerAddOps.append(std::next(J), ((const SmallVector &)AddOps).end()); // Don't leave just a constant behind in a register if the constant could // be folded into an immediate field. if (InnerAddOps.size() == 1 && isAlwaysFoldable(TTI, SE, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, InnerAddOps[0], Base.getNumRegs() > 1)) continue; const SCEV *InnerSum = SE.getAddExpr(InnerAddOps); if (InnerSum->isZero()) continue; Formula F = Base; // Add the remaining pieces of the add back into the new formula. const SCEVConstant *InnerSumSC = dyn_cast(InnerSum); if (InnerSumSC && SE.getTypeSizeInBits(InnerSumSC->getType()) <= 64 && TTI.isLegalAddImmediate((uint64_t)F.UnfoldedOffset + InnerSumSC->getValue()->getZExtValue())) { F.UnfoldedOffset = (uint64_t)F.UnfoldedOffset + InnerSumSC->getValue()->getZExtValue(); if (IsScaledReg) F.ScaledReg = nullptr; else F.BaseRegs.erase(F.BaseRegs.begin() + Idx); } else if (IsScaledReg) F.ScaledReg = InnerSum; else F.BaseRegs[Idx] = InnerSum; // Add J as its own register, or an unfolded immediate. const SCEVConstant *SC = dyn_cast(*J); if (SC && SE.getTypeSizeInBits(SC->getType()) <= 64 && TTI.isLegalAddImmediate((uint64_t)F.UnfoldedOffset + SC->getValue()->getZExtValue())) F.UnfoldedOffset = (uint64_t)F.UnfoldedOffset + SC->getValue()->getZExtValue(); else F.BaseRegs.push_back(*J); // We may have changed the number of register in base regs, adjust the // formula accordingly. F.canonicalize(*L); if (InsertFormula(LU, LUIdx, F)) // If that formula hadn't been seen before, recurse to find more like // it. // Add check on Log16(AddOps.size()) - same as Log2_32(AddOps.size()) >> 2) // Because just Depth is not enough to bound compile time. // This means that every time AddOps.size() is greater 16^x we will add // x to Depth. GenerateReassociations(LU, LUIdx, LU.Formulae.back(), Depth + 1 + (Log2_32(AddOps.size()) >> 2)); } } /// Split out subexpressions from adds and the bases of addrecs. void LSRInstance::GenerateReassociations(LSRUse &LU, unsigned LUIdx, Formula Base, unsigned Depth) { assert(Base.isCanonical(*L) && "Input must be in the canonical form"); // Arbitrarily cap recursion to protect compile time. if (Depth >= 3) return; for (size_t i = 0, e = Base.BaseRegs.size(); i != e; ++i) GenerateReassociationsImpl(LU, LUIdx, Base, Depth, i); if (Base.Scale == 1) GenerateReassociationsImpl(LU, LUIdx, Base, Depth, /* Idx */ -1, /* IsScaledReg */ true); } /// Generate a formula consisting of all of the loop-dominating registers added /// into a single register. void LSRInstance::GenerateCombinations(LSRUse &LU, unsigned LUIdx, Formula Base) { // This method is only interesting on a plurality of registers. if (Base.BaseRegs.size() + (Base.Scale == 1) + (Base.UnfoldedOffset != 0) <= 1) return; // Flatten the representation, i.e., reg1 + 1*reg2 => reg1 + reg2, before // processing the formula. Base.unscale(); SmallVector Ops; Formula NewBase = Base; NewBase.BaseRegs.clear(); Type *CombinedIntegerType = nullptr; for (const SCEV *BaseReg : Base.BaseRegs) { if (SE.properlyDominates(BaseReg, L->getHeader()) && !SE.hasComputableLoopEvolution(BaseReg, L)) { if (!CombinedIntegerType) CombinedIntegerType = SE.getEffectiveSCEVType(BaseReg->getType()); Ops.push_back(BaseReg); } else NewBase.BaseRegs.push_back(BaseReg); } // If no register is relevant, we're done. if (Ops.size() == 0) return; // Utility function for generating the required variants of the combined // registers. auto GenerateFormula = [&](const SCEV *Sum) { Formula F = NewBase; // TODO: If Sum is zero, it probably means ScalarEvolution missed an // opportunity to fold something. For now, just ignore such cases // rather than proceed with zero in a register. if (Sum->isZero()) return; F.BaseRegs.push_back(Sum); F.canonicalize(*L); (void)InsertFormula(LU, LUIdx, F); }; // If we collected at least two registers, generate a formula combining them. if (Ops.size() > 1) { SmallVector OpsCopy(Ops); // Don't let SE modify Ops. GenerateFormula(SE.getAddExpr(OpsCopy)); } // If we have an unfolded offset, generate a formula combining it with the // registers collected. if (NewBase.UnfoldedOffset) { assert(CombinedIntegerType && "Missing a type for the unfolded offset"); Ops.push_back(SE.getConstant(CombinedIntegerType, NewBase.UnfoldedOffset, true)); NewBase.UnfoldedOffset = 0; GenerateFormula(SE.getAddExpr(Ops)); } } /// Helper function for LSRInstance::GenerateSymbolicOffsets. void LSRInstance::GenerateSymbolicOffsetsImpl(LSRUse &LU, unsigned LUIdx, const Formula &Base, size_t Idx, bool IsScaledReg) { const SCEV *G = IsScaledReg ? Base.ScaledReg : Base.BaseRegs[Idx]; GlobalValue *GV = ExtractSymbol(G, SE); if (G->isZero() || !GV) return; Formula F = Base; F.BaseGV = GV; if (!isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F)) return; if (IsScaledReg) F.ScaledReg = G; else F.BaseRegs[Idx] = G; (void)InsertFormula(LU, LUIdx, F); } /// Generate reuse formulae using symbolic offsets. void LSRInstance::GenerateSymbolicOffsets(LSRUse &LU, unsigned LUIdx, Formula Base) { // We can't add a symbolic offset if the address already contains one. if (Base.BaseGV) return; for (size_t i = 0, e = Base.BaseRegs.size(); i != e; ++i) GenerateSymbolicOffsetsImpl(LU, LUIdx, Base, i); if (Base.Scale == 1) GenerateSymbolicOffsetsImpl(LU, LUIdx, Base, /* Idx */ -1, /* IsScaledReg */ true); } /// Helper function for LSRInstance::GenerateConstantOffsets. void LSRInstance::GenerateConstantOffsetsImpl( LSRUse &LU, unsigned LUIdx, const Formula &Base, const SmallVectorImpl &Worklist, size_t Idx, bool IsScaledReg) { auto GenerateOffset = [&](const SCEV *G, int64_t Offset) { Formula F = Base; F.BaseOffset = (uint64_t)Base.BaseOffset - Offset; if (isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F)) { // Add the offset to the base register. const SCEV *NewG = SE.getAddExpr(SE.getConstant(G->getType(), Offset), G); // If it cancelled out, drop the base register, otherwise update it. if (NewG->isZero()) { if (IsScaledReg) { F.Scale = 0; F.ScaledReg = nullptr; } else F.deleteBaseReg(F.BaseRegs[Idx]); F.canonicalize(*L); } else if (IsScaledReg) F.ScaledReg = NewG; else F.BaseRegs[Idx] = NewG; (void)InsertFormula(LU, LUIdx, F); } }; const SCEV *G = IsScaledReg ? Base.ScaledReg : Base.BaseRegs[Idx]; // With constant offsets and constant steps, we can generate pre-inc // accesses by having the offset equal the step. So, for access #0 with a // step of 8, we generate a G - 8 base which would require the first access // to be ((G - 8) + 8),+,8. The pre-indexed access then updates the pointer // for itself and hopefully becomes the base for other accesses. This means // means that a single pre-indexed access can be generated to become the new // base pointer for each iteration of the loop, resulting in no extra add/sub // instructions for pointer updating. if (AMK == TTI::AMK_PreIndexed && LU.Kind == LSRUse::Address) { if (auto *GAR = dyn_cast(G)) { if (auto *StepRec = dyn_cast(GAR->getStepRecurrence(SE))) { const APInt &StepInt = StepRec->getAPInt(); int64_t Step = StepInt.isNegative() ? StepInt.getSExtValue() : StepInt.getZExtValue(); for (int64_t Offset : Worklist) { Offset -= Step; GenerateOffset(G, Offset); } } } } for (int64_t Offset : Worklist) GenerateOffset(G, Offset); int64_t Imm = ExtractImmediate(G, SE); if (G->isZero() || Imm == 0) return; Formula F = Base; F.BaseOffset = (uint64_t)F.BaseOffset + Imm; if (!isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F)) return; if (IsScaledReg) { F.ScaledReg = G; } else { F.BaseRegs[Idx] = G; // We may generate non canonical Formula if G is a recurrent expr reg // related with current loop while F.ScaledReg is not. F.canonicalize(*L); } (void)InsertFormula(LU, LUIdx, F); } /// GenerateConstantOffsets - Generate reuse formulae using symbolic offsets. void LSRInstance::GenerateConstantOffsets(LSRUse &LU, unsigned LUIdx, Formula Base) { // TODO: For now, just add the min and max offset, because it usually isn't // worthwhile looking at everything inbetween. SmallVector Worklist; Worklist.push_back(LU.MinOffset); if (LU.MaxOffset != LU.MinOffset) Worklist.push_back(LU.MaxOffset); for (size_t i = 0, e = Base.BaseRegs.size(); i != e; ++i) GenerateConstantOffsetsImpl(LU, LUIdx, Base, Worklist, i); if (Base.Scale == 1) GenerateConstantOffsetsImpl(LU, LUIdx, Base, Worklist, /* Idx */ -1, /* IsScaledReg */ true); } /// For ICmpZero, check to see if we can scale up the comparison. For example, x /// == y -> x*c == y*c. void LSRInstance::GenerateICmpZeroScales(LSRUse &LU, unsigned LUIdx, Formula Base) { if (LU.Kind != LSRUse::ICmpZero) return; // Determine the integer type for the base formula. Type *IntTy = Base.getType(); if (!IntTy) return; if (SE.getTypeSizeInBits(IntTy) > 64) return; // Don't do this if there is more than one offset. if (LU.MinOffset != LU.MaxOffset) return; // Check if transformation is valid. It is illegal to multiply pointer. if (Base.ScaledReg && Base.ScaledReg->getType()->isPointerTy()) return; for (const SCEV *BaseReg : Base.BaseRegs) if (BaseReg->getType()->isPointerTy()) return; assert(!Base.BaseGV && "ICmpZero use is not legal!"); // Check each interesting stride. for (int64_t Factor : Factors) { // Check that Factor can be represented by IntTy if (!ConstantInt::isValueValidForType(IntTy, Factor)) continue; // Check that the multiplication doesn't overflow. if (Base.BaseOffset == std::numeric_limits::min() && Factor == -1) continue; int64_t NewBaseOffset = (uint64_t)Base.BaseOffset * Factor; assert(Factor != 0 && "Zero factor not expected!"); if (NewBaseOffset / Factor != Base.BaseOffset) continue; // If the offset will be truncated at this use, check that it is in bounds. if (!IntTy->isPointerTy() && !ConstantInt::isValueValidForType(IntTy, NewBaseOffset)) continue; // Check that multiplying with the use offset doesn't overflow. int64_t Offset = LU.MinOffset; if (Offset == std::numeric_limits::min() && Factor == -1) continue; Offset = (uint64_t)Offset * Factor; if (Offset / Factor != LU.MinOffset) continue; // If the offset will be truncated at this use, check that it is in bounds. if (!IntTy->isPointerTy() && !ConstantInt::isValueValidForType(IntTy, Offset)) continue; Formula F = Base; F.BaseOffset = NewBaseOffset; // Check that this scale is legal. if (!isLegalUse(TTI, Offset, Offset, LU.Kind, LU.AccessTy, F)) continue; // Compensate for the use having MinOffset built into it. F.BaseOffset = (uint64_t)F.BaseOffset + Offset - LU.MinOffset; const SCEV *FactorS = SE.getConstant(IntTy, Factor); // Check that multiplying with each base register doesn't overflow. for (size_t i = 0, e = F.BaseRegs.size(); i != e; ++i) { F.BaseRegs[i] = SE.getMulExpr(F.BaseRegs[i], FactorS); if (getExactSDiv(F.BaseRegs[i], FactorS, SE) != Base.BaseRegs[i]) goto next; } // Check that multiplying with the scaled register doesn't overflow. if (F.ScaledReg) { F.ScaledReg = SE.getMulExpr(F.ScaledReg, FactorS); if (getExactSDiv(F.ScaledReg, FactorS, SE) != Base.ScaledReg) continue; } // Check that multiplying with the unfolded offset doesn't overflow. if (F.UnfoldedOffset != 0) { if (F.UnfoldedOffset == std::numeric_limits::min() && Factor == -1) continue; F.UnfoldedOffset = (uint64_t)F.UnfoldedOffset * Factor; if (F.UnfoldedOffset / Factor != Base.UnfoldedOffset) continue; // If the offset will be truncated, check that it is in bounds. if (!IntTy->isPointerTy() && !ConstantInt::isValueValidForType(IntTy, F.UnfoldedOffset)) continue; } // If we make it here and it's legal, add it. (void)InsertFormula(LU, LUIdx, F); next:; } } /// Generate stride factor reuse formulae by making use of scaled-offset address /// modes, for example. void LSRInstance::GenerateScales(LSRUse &LU, unsigned LUIdx, Formula Base) { // Determine the integer type for the base formula. Type *IntTy = Base.getType(); if (!IntTy) return; // If this Formula already has a scaled register, we can't add another one. // Try to unscale the formula to generate a better scale. if (Base.Scale != 0 && !Base.unscale()) return; assert(Base.Scale == 0 && "unscale did not did its job!"); // Check each interesting stride. for (int64_t Factor : Factors) { Base.Scale = Factor; Base.HasBaseReg = Base.BaseRegs.size() > 1; // Check whether this scale is going to be legal. if (!isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, Base)) { // As a special-case, handle special out-of-loop Basic users specially. // TODO: Reconsider this special case. if (LU.Kind == LSRUse::Basic && isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LSRUse::Special, LU.AccessTy, Base) && LU.AllFixupsOutsideLoop) LU.Kind = LSRUse::Special; else continue; } // For an ICmpZero, negating a solitary base register won't lead to // new solutions. if (LU.Kind == LSRUse::ICmpZero && !Base.HasBaseReg && Base.BaseOffset == 0 && !Base.BaseGV) continue; // For each addrec base reg, if its loop is current loop, apply the scale. for (size_t i = 0, e = Base.BaseRegs.size(); i != e; ++i) { const SCEVAddRecExpr *AR = dyn_cast(Base.BaseRegs[i]); if (AR && (AR->getLoop() == L || LU.AllFixupsOutsideLoop)) { const SCEV *FactorS = SE.getConstant(IntTy, Factor); if (FactorS->isZero()) continue; // Divide out the factor, ignoring high bits, since we'll be // scaling the value back up in the end. if (const SCEV *Quotient = getExactSDiv(AR, FactorS, SE, true)) { // TODO: This could be optimized to avoid all the copying. Formula F = Base; F.ScaledReg = Quotient; F.deleteBaseReg(F.BaseRegs[i]); // The canonical representation of 1*reg is reg, which is already in // Base. In that case, do not try to insert the formula, it will be // rejected anyway. if (F.Scale == 1 && (F.BaseRegs.empty() || (AR->getLoop() != L && LU.AllFixupsOutsideLoop))) continue; // If AllFixupsOutsideLoop is true and F.Scale is 1, we may generate // non canonical Formula with ScaledReg's loop not being L. if (F.Scale == 1 && LU.AllFixupsOutsideLoop) F.canonicalize(*L); (void)InsertFormula(LU, LUIdx, F); } } } } } /// Generate reuse formulae from different IV types. void LSRInstance::GenerateTruncates(LSRUse &LU, unsigned LUIdx, Formula Base) { // Don't bother truncating symbolic values. if (Base.BaseGV) return; // Determine the integer type for the base formula. Type *DstTy = Base.getType(); if (!DstTy) return; if (DstTy->isPointerTy()) return; // It is invalid to extend a pointer type so exit early if ScaledReg or // any of the BaseRegs are pointers. if (Base.ScaledReg && Base.ScaledReg->getType()->isPointerTy()) return; if (any_of(Base.BaseRegs, [](const SCEV *S) { return S->getType()->isPointerTy(); })) return; for (Type *SrcTy : Types) { if (SrcTy != DstTy && TTI.isTruncateFree(SrcTy, DstTy)) { Formula F = Base; // Sometimes SCEV is able to prove zero during ext transform. It may // happen if SCEV did not do all possible transforms while creating the // initial node (maybe due to depth limitations), but it can do them while // taking ext. if (F.ScaledReg) { const SCEV *NewScaledReg = SE.getAnyExtendExpr(F.ScaledReg, SrcTy); if (NewScaledReg->isZero()) continue; F.ScaledReg = NewScaledReg; } bool HasZeroBaseReg = false; for (const SCEV *&BaseReg : F.BaseRegs) { const SCEV *NewBaseReg = SE.getAnyExtendExpr(BaseReg, SrcTy); if (NewBaseReg->isZero()) { HasZeroBaseReg = true; break; } BaseReg = NewBaseReg; } if (HasZeroBaseReg) continue; // TODO: This assumes we've done basic processing on all uses and // have an idea what the register usage is. if (!F.hasRegsUsedByUsesOtherThan(LUIdx, RegUses)) continue; F.canonicalize(*L); (void)InsertFormula(LU, LUIdx, F); } } } namespace { /// Helper class for GenerateCrossUseConstantOffsets. It's used to defer /// modifications so that the search phase doesn't have to worry about the data /// structures moving underneath it. struct WorkItem { size_t LUIdx; int64_t Imm; const SCEV *OrigReg; WorkItem(size_t LI, int64_t I, const SCEV *R) : LUIdx(LI), Imm(I), OrigReg(R) {} void print(raw_ostream &OS) const; void dump() const; }; } // end anonymous namespace #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void WorkItem::print(raw_ostream &OS) const { OS << "in formulae referencing " << *OrigReg << " in use " << LUIdx << " , add offset " << Imm; } LLVM_DUMP_METHOD void WorkItem::dump() const { print(errs()); errs() << '\n'; } #endif /// Look for registers which are a constant distance apart and try to form reuse /// opportunities between them. void LSRInstance::GenerateCrossUseConstantOffsets() { // Group the registers by their value without any added constant offset. using ImmMapTy = std::map; DenseMap Map; DenseMap UsedByIndicesMap; SmallVector Sequence; for (const SCEV *Use : RegUses) { const SCEV *Reg = Use; // Make a copy for ExtractImmediate to modify. int64_t Imm = ExtractImmediate(Reg, SE); auto Pair = Map.insert(std::make_pair(Reg, ImmMapTy())); if (Pair.second) Sequence.push_back(Reg); Pair.first->second.insert(std::make_pair(Imm, Use)); UsedByIndicesMap[Reg] |= RegUses.getUsedByIndices(Use); } // Now examine each set of registers with the same base value. Build up // a list of work to do and do the work in a separate step so that we're // not adding formulae and register counts while we're searching. SmallVector WorkItems; SmallSet, 32> UniqueItems; for (const SCEV *Reg : Sequence) { const ImmMapTy &Imms = Map.find(Reg)->second; // It's not worthwhile looking for reuse if there's only one offset. if (Imms.size() == 1) continue; LLVM_DEBUG(dbgs() << "Generating cross-use offsets for " << *Reg << ':'; for (const auto &Entry : Imms) dbgs() << ' ' << Entry.first; dbgs() << '\n'); // Examine each offset. for (ImmMapTy::const_iterator J = Imms.begin(), JE = Imms.end(); J != JE; ++J) { const SCEV *OrigReg = J->second; int64_t JImm = J->first; const SmallBitVector &UsedByIndices = RegUses.getUsedByIndices(OrigReg); if (!isa(OrigReg) && UsedByIndicesMap[Reg].count() == 1) { LLVM_DEBUG(dbgs() << "Skipping cross-use reuse for " << *OrigReg << '\n'); continue; } // Conservatively examine offsets between this orig reg a few selected // other orig regs. int64_t First = Imms.begin()->first; int64_t Last = std::prev(Imms.end())->first; // Compute (First + Last) / 2 without overflow using the fact that // First + Last = 2 * (First + Last) + (First ^ Last). int64_t Avg = (First & Last) + ((First ^ Last) >> 1); // If the result is negative and First is odd and Last even (or vice versa), // we rounded towards -inf. Add 1 in that case, to round towards 0. Avg = Avg + ((First ^ Last) & ((uint64_t)Avg >> 63)); ImmMapTy::const_iterator OtherImms[] = { Imms.begin(), std::prev(Imms.end()), Imms.lower_bound(Avg)}; for (size_t i = 0, e = array_lengthof(OtherImms); i != e; ++i) { ImmMapTy::const_iterator M = OtherImms[i]; if (M == J || M == JE) continue; // Compute the difference between the two. int64_t Imm = (uint64_t)JImm - M->first; for (unsigned LUIdx : UsedByIndices.set_bits()) // Make a memo of this use, offset, and register tuple. if (UniqueItems.insert(std::make_pair(LUIdx, Imm)).second) WorkItems.push_back(WorkItem(LUIdx, Imm, OrigReg)); } } } Map.clear(); Sequence.clear(); UsedByIndicesMap.clear(); UniqueItems.clear(); // Now iterate through the worklist and add new formulae. for (const WorkItem &WI : WorkItems) { size_t LUIdx = WI.LUIdx; LSRUse &LU = Uses[LUIdx]; int64_t Imm = WI.Imm; const SCEV *OrigReg = WI.OrigReg; Type *IntTy = SE.getEffectiveSCEVType(OrigReg->getType()); const SCEV *NegImmS = SE.getSCEV(ConstantInt::get(IntTy, -(uint64_t)Imm)); unsigned BitWidth = SE.getTypeSizeInBits(IntTy); // TODO: Use a more targeted data structure. for (size_t L = 0, LE = LU.Formulae.size(); L != LE; ++L) { Formula F = LU.Formulae[L]; // FIXME: The code for the scaled and unscaled registers looks // very similar but slightly different. Investigate if they // could be merged. That way, we would not have to unscale the // Formula. F.unscale(); // Use the immediate in the scaled register. if (F.ScaledReg == OrigReg) { int64_t Offset = (uint64_t)F.BaseOffset + Imm * (uint64_t)F.Scale; // Don't create 50 + reg(-50). if (F.referencesReg(SE.getSCEV( ConstantInt::get(IntTy, -(uint64_t)Offset)))) continue; Formula NewF = F; NewF.BaseOffset = Offset; if (!isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, NewF)) continue; NewF.ScaledReg = SE.getAddExpr(NegImmS, NewF.ScaledReg); // If the new scale is a constant in a register, and adding the constant // value to the immediate would produce a value closer to zero than the // immediate itself, then the formula isn't worthwhile. if (const SCEVConstant *C = dyn_cast(NewF.ScaledReg)) if (C->getValue()->isNegative() != (NewF.BaseOffset < 0) && (C->getAPInt().abs() * APInt(BitWidth, F.Scale)) .ule(std::abs(NewF.BaseOffset))) continue; // OK, looks good. NewF.canonicalize(*this->L); (void)InsertFormula(LU, LUIdx, NewF); } else { // Use the immediate in a base register. for (size_t N = 0, NE = F.BaseRegs.size(); N != NE; ++N) { const SCEV *BaseReg = F.BaseRegs[N]; if (BaseReg != OrigReg) continue; Formula NewF = F; NewF.BaseOffset = (uint64_t)NewF.BaseOffset + Imm; if (!isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, NewF)) { if (AMK == TTI::AMK_PostIndexed && mayUsePostIncMode(TTI, LU, OrigReg, this->L, SE)) continue; if (!TTI.isLegalAddImmediate((uint64_t)NewF.UnfoldedOffset + Imm)) continue; NewF = F; NewF.UnfoldedOffset = (uint64_t)NewF.UnfoldedOffset + Imm; } NewF.BaseRegs[N] = SE.getAddExpr(NegImmS, BaseReg); // If the new formula has a constant in a register, and adding the // constant value to the immediate would produce a value closer to // zero than the immediate itself, then the formula isn't worthwhile. for (const SCEV *NewReg : NewF.BaseRegs) if (const SCEVConstant *C = dyn_cast(NewReg)) if ((C->getAPInt() + NewF.BaseOffset) .abs() .slt(std::abs(NewF.BaseOffset)) && (C->getAPInt() + NewF.BaseOffset).countTrailingZeros() >= countTrailingZeros(NewF.BaseOffset)) goto skip_formula; // Ok, looks good. NewF.canonicalize(*this->L); (void)InsertFormula(LU, LUIdx, NewF); break; skip_formula:; } } } } } /// Generate formulae for each use. void LSRInstance::GenerateAllReuseFormulae() { // This is split into multiple loops so that hasRegsUsedByUsesOtherThan // queries are more precise. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateReassociations(LU, LUIdx, LU.Formulae[i]); for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateCombinations(LU, LUIdx, LU.Formulae[i]); } for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateSymbolicOffsets(LU, LUIdx, LU.Formulae[i]); for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateConstantOffsets(LU, LUIdx, LU.Formulae[i]); for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateICmpZeroScales(LU, LUIdx, LU.Formulae[i]); for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateScales(LU, LUIdx, LU.Formulae[i]); } for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; for (size_t i = 0, f = LU.Formulae.size(); i != f; ++i) GenerateTruncates(LU, LUIdx, LU.Formulae[i]); } GenerateCrossUseConstantOffsets(); LLVM_DEBUG(dbgs() << "\n" "After generating reuse formulae:\n"; print_uses(dbgs())); } /// If there are multiple formulae with the same set of registers used /// by other uses, pick the best one and delete the others. void LSRInstance::FilterOutUndesirableDedicatedRegisters() { DenseSet VisitedRegs; SmallPtrSet Regs; SmallPtrSet LoserRegs; #ifndef NDEBUG bool ChangedFormulae = false; #endif // Collect the best formula for each unique set of shared registers. This // is reset for each use. using BestFormulaeTy = DenseMap, size_t, UniquifierDenseMapInfo>; BestFormulaeTy BestFormulae; for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; LLVM_DEBUG(dbgs() << "Filtering for use "; LU.print(dbgs()); dbgs() << '\n'); bool Any = false; for (size_t FIdx = 0, NumForms = LU.Formulae.size(); FIdx != NumForms; ++FIdx) { Formula &F = LU.Formulae[FIdx]; // Some formulas are instant losers. For example, they may depend on // nonexistent AddRecs from other loops. These need to be filtered // immediately, otherwise heuristics could choose them over others leading // to an unsatisfactory solution. Passing LoserRegs into RateFormula here // avoids the need to recompute this information across formulae using the // same bad AddRec. Passing LoserRegs is also essential unless we remove // the corresponding bad register from the Regs set. Cost CostF(L, SE, TTI, AMK); Regs.clear(); CostF.RateFormula(F, Regs, VisitedRegs, LU, &LoserRegs); if (CostF.isLoser()) { // During initial formula generation, undesirable formulae are generated // by uses within other loops that have some non-trivial address mode or // use the postinc form of the IV. LSR needs to provide these formulae // as the basis of rediscovering the desired formula that uses an AddRec // corresponding to the existing phi. Once all formulae have been // generated, these initial losers may be pruned. LLVM_DEBUG(dbgs() << " Filtering loser "; F.print(dbgs()); dbgs() << "\n"); } else { SmallVector Key; for (const SCEV *Reg : F.BaseRegs) { if (RegUses.isRegUsedByUsesOtherThan(Reg, LUIdx)) Key.push_back(Reg); } if (F.ScaledReg && RegUses.isRegUsedByUsesOtherThan(F.ScaledReg, LUIdx)) Key.push_back(F.ScaledReg); // Unstable sort by host order ok, because this is only used for // uniquifying. llvm::sort(Key); std::pair P = BestFormulae.insert(std::make_pair(Key, FIdx)); if (P.second) continue; Formula &Best = LU.Formulae[P.first->second]; Cost CostBest(L, SE, TTI, AMK); Regs.clear(); CostBest.RateFormula(Best, Regs, VisitedRegs, LU); if (CostF.isLess(CostBest)) std::swap(F, Best); LLVM_DEBUG(dbgs() << " Filtering out formula "; F.print(dbgs()); dbgs() << "\n" " in favor of formula "; Best.print(dbgs()); dbgs() << '\n'); } #ifndef NDEBUG ChangedFormulae = true; #endif LU.DeleteFormula(F); --FIdx; --NumForms; Any = true; } // Now that we've filtered out some formulae, recompute the Regs set. if (Any) LU.RecomputeRegs(LUIdx, RegUses); // Reset this to prepare for the next use. BestFormulae.clear(); } LLVM_DEBUG(if (ChangedFormulae) { dbgs() << "\n" "After filtering out undesirable candidates:\n"; print_uses(dbgs()); }); } /// Estimate the worst-case number of solutions the solver might have to /// consider. It almost never considers this many solutions because it prune the /// search space, but the pruning isn't always sufficient. size_t LSRInstance::EstimateSearchSpaceComplexity() const { size_t Power = 1; for (const LSRUse &LU : Uses) { size_t FSize = LU.Formulae.size(); if (FSize >= ComplexityLimit) { Power = ComplexityLimit; break; } Power *= FSize; if (Power >= ComplexityLimit) break; } return Power; } /// When one formula uses a superset of the registers of another formula, it /// won't help reduce register pressure (though it may not necessarily hurt /// register pressure); remove it to simplify the system. void LSRInstance::NarrowSearchSpaceByDetectingSupersets() { if (EstimateSearchSpaceComplexity() >= ComplexityLimit) { LLVM_DEBUG(dbgs() << "The search space is too complex.\n"); LLVM_DEBUG(dbgs() << "Narrowing the search space by eliminating formulae " "which use a superset of registers used by other " "formulae.\n"); for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; bool Any = false; for (size_t i = 0, e = LU.Formulae.size(); i != e; ++i) { Formula &F = LU.Formulae[i]; // Look for a formula with a constant or GV in a register. If the use // also has a formula with that same value in an immediate field, // delete the one that uses a register. for (SmallVectorImpl::const_iterator I = F.BaseRegs.begin(), E = F.BaseRegs.end(); I != E; ++I) { if (const SCEVConstant *C = dyn_cast(*I)) { Formula NewF = F; //FIXME: Formulas should store bitwidth to do wrapping properly. // See PR41034. NewF.BaseOffset += (uint64_t)C->getValue()->getSExtValue(); NewF.BaseRegs.erase(NewF.BaseRegs.begin() + (I - F.BaseRegs.begin())); if (LU.HasFormulaWithSameRegs(NewF)) { LLVM_DEBUG(dbgs() << " Deleting "; F.print(dbgs()); dbgs() << '\n'); LU.DeleteFormula(F); --i; --e; Any = true; break; } } else if (const SCEVUnknown *U = dyn_cast(*I)) { if (GlobalValue *GV = dyn_cast(U->getValue())) if (!F.BaseGV) { Formula NewF = F; NewF.BaseGV = GV; NewF.BaseRegs.erase(NewF.BaseRegs.begin() + (I - F.BaseRegs.begin())); if (LU.HasFormulaWithSameRegs(NewF)) { LLVM_DEBUG(dbgs() << " Deleting "; F.print(dbgs()); dbgs() << '\n'); LU.DeleteFormula(F); --i; --e; Any = true; break; } } } } } if (Any) LU.RecomputeRegs(LUIdx, RegUses); } LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } } /// When there are many registers for expressions like A, A+1, A+2, etc., /// allocate a single register for them. void LSRInstance::NarrowSearchSpaceByCollapsingUnrolledCode() { if (EstimateSearchSpaceComplexity() < ComplexityLimit) return; LLVM_DEBUG( dbgs() << "The search space is too complex.\n" "Narrowing the search space by assuming that uses separated " "by a constant offset will use the same registers.\n"); // This is especially useful for unrolled loops. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; for (const Formula &F : LU.Formulae) { if (F.BaseOffset == 0 || (F.Scale != 0 && F.Scale != 1)) continue; LSRUse *LUThatHas = FindUseWithSimilarFormula(F, LU); if (!LUThatHas) continue; if (!reconcileNewOffset(*LUThatHas, F.BaseOffset, /*HasBaseReg=*/ false, LU.Kind, LU.AccessTy)) continue; LLVM_DEBUG(dbgs() << " Deleting use "; LU.print(dbgs()); dbgs() << '\n'); LUThatHas->AllFixupsOutsideLoop &= LU.AllFixupsOutsideLoop; // Transfer the fixups of LU to LUThatHas. for (LSRFixup &Fixup : LU.Fixups) { Fixup.Offset += F.BaseOffset; LUThatHas->pushFixup(Fixup); LLVM_DEBUG(dbgs() << "New fixup has offset " << Fixup.Offset << '\n'); } // Delete formulae from the new use which are no longer legal. bool Any = false; for (size_t i = 0, e = LUThatHas->Formulae.size(); i != e; ++i) { Formula &F = LUThatHas->Formulae[i]; if (!isLegalUse(TTI, LUThatHas->MinOffset, LUThatHas->MaxOffset, LUThatHas->Kind, LUThatHas->AccessTy, F)) { LLVM_DEBUG(dbgs() << " Deleting "; F.print(dbgs()); dbgs() << '\n'); LUThatHas->DeleteFormula(F); --i; --e; Any = true; } } if (Any) LUThatHas->RecomputeRegs(LUThatHas - &Uses.front(), RegUses); // Delete the old use. DeleteUse(LU, LUIdx); --LUIdx; --NumUses; break; } } LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } /// Call FilterOutUndesirableDedicatedRegisters again, if necessary, now that /// we've done more filtering, as it may be able to find more formulae to /// eliminate. void LSRInstance::NarrowSearchSpaceByRefilteringUndesirableDedicatedRegisters(){ if (EstimateSearchSpaceComplexity() >= ComplexityLimit) { LLVM_DEBUG(dbgs() << "The search space is too complex.\n"); LLVM_DEBUG(dbgs() << "Narrowing the search space by re-filtering out " "undesirable dedicated registers.\n"); FilterOutUndesirableDedicatedRegisters(); LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } } /// If a LSRUse has multiple formulae with the same ScaledReg and Scale. /// Pick the best one and delete the others. /// This narrowing heuristic is to keep as many formulae with different /// Scale and ScaledReg pair as possible while narrowing the search space. /// The benefit is that it is more likely to find out a better solution /// from a formulae set with more Scale and ScaledReg variations than /// a formulae set with the same Scale and ScaledReg. The picking winner /// reg heuristic will often keep the formulae with the same Scale and /// ScaledReg and filter others, and we want to avoid that if possible. void LSRInstance::NarrowSearchSpaceByFilterFormulaWithSameScaledReg() { if (EstimateSearchSpaceComplexity() < ComplexityLimit) return; LLVM_DEBUG( dbgs() << "The search space is too complex.\n" "Narrowing the search space by choosing the best Formula " "from the Formulae with the same Scale and ScaledReg.\n"); // Map the "Scale * ScaledReg" pair to the best formula of current LSRUse. using BestFormulaeTy = DenseMap, size_t>; BestFormulaeTy BestFormulae; #ifndef NDEBUG bool ChangedFormulae = false; #endif DenseSet VisitedRegs; SmallPtrSet Regs; for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; LLVM_DEBUG(dbgs() << "Filtering for use "; LU.print(dbgs()); dbgs() << '\n'); // Return true if Formula FA is better than Formula FB. auto IsBetterThan = [&](Formula &FA, Formula &FB) { // First we will try to choose the Formula with fewer new registers. // For a register used by current Formula, the more the register is // shared among LSRUses, the less we increase the register number // counter of the formula. size_t FARegNum = 0; for (const SCEV *Reg : FA.BaseRegs) { const SmallBitVector &UsedByIndices = RegUses.getUsedByIndices(Reg); FARegNum += (NumUses - UsedByIndices.count() + 1); } size_t FBRegNum = 0; for (const SCEV *Reg : FB.BaseRegs) { const SmallBitVector &UsedByIndices = RegUses.getUsedByIndices(Reg); FBRegNum += (NumUses - UsedByIndices.count() + 1); } if (FARegNum != FBRegNum) return FARegNum < FBRegNum; // If the new register numbers are the same, choose the Formula with // less Cost. Cost CostFA(L, SE, TTI, AMK); Cost CostFB(L, SE, TTI, AMK); Regs.clear(); CostFA.RateFormula(FA, Regs, VisitedRegs, LU); Regs.clear(); CostFB.RateFormula(FB, Regs, VisitedRegs, LU); return CostFA.isLess(CostFB); }; bool Any = false; for (size_t FIdx = 0, NumForms = LU.Formulae.size(); FIdx != NumForms; ++FIdx) { Formula &F = LU.Formulae[FIdx]; if (!F.ScaledReg) continue; auto P = BestFormulae.insert({{F.ScaledReg, F.Scale}, FIdx}); if (P.second) continue; Formula &Best = LU.Formulae[P.first->second]; if (IsBetterThan(F, Best)) std::swap(F, Best); LLVM_DEBUG(dbgs() << " Filtering out formula "; F.print(dbgs()); dbgs() << "\n" " in favor of formula "; Best.print(dbgs()); dbgs() << '\n'); #ifndef NDEBUG ChangedFormulae = true; #endif LU.DeleteFormula(F); --FIdx; --NumForms; Any = true; } if (Any) LU.RecomputeRegs(LUIdx, RegUses); // Reset this to prepare for the next use. BestFormulae.clear(); } LLVM_DEBUG(if (ChangedFormulae) { dbgs() << "\n" "After filtering out undesirable candidates:\n"; print_uses(dbgs()); }); } /// If we are over the complexity limit, filter out any post-inc prefering /// variables to only post-inc values. void LSRInstance::NarrowSearchSpaceByFilterPostInc() { if (AMK != TTI::AMK_PostIndexed) return; if (EstimateSearchSpaceComplexity() < ComplexityLimit) return; LLVM_DEBUG(dbgs() << "The search space is too complex.\n" "Narrowing the search space by choosing the lowest " "register Formula for PostInc Uses.\n"); for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; if (LU.Kind != LSRUse::Address) continue; if (!TTI.isIndexedLoadLegal(TTI.MIM_PostInc, LU.AccessTy.getType()) && !TTI.isIndexedStoreLegal(TTI.MIM_PostInc, LU.AccessTy.getType())) continue; size_t MinRegs = std::numeric_limits::max(); for (const Formula &F : LU.Formulae) MinRegs = std::min(F.getNumRegs(), MinRegs); bool Any = false; for (size_t FIdx = 0, NumForms = LU.Formulae.size(); FIdx != NumForms; ++FIdx) { Formula &F = LU.Formulae[FIdx]; if (F.getNumRegs() > MinRegs) { LLVM_DEBUG(dbgs() << " Filtering out formula "; F.print(dbgs()); dbgs() << "\n"); LU.DeleteFormula(F); --FIdx; --NumForms; Any = true; } } if (Any) LU.RecomputeRegs(LUIdx, RegUses); if (EstimateSearchSpaceComplexity() < ComplexityLimit) break; } LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } /// The function delete formulas with high registers number expectation. /// Assuming we don't know the value of each formula (already delete /// all inefficient), generate probability of not selecting for each /// register. /// For example, /// Use1: /// reg(a) + reg({0,+,1}) /// reg(a) + reg({-1,+,1}) + 1 /// reg({a,+,1}) /// Use2: /// reg(b) + reg({0,+,1}) /// reg(b) + reg({-1,+,1}) + 1 /// reg({b,+,1}) /// Use3: /// reg(c) + reg(b) + reg({0,+,1}) /// reg(c) + reg({b,+,1}) /// /// Probability of not selecting /// Use1 Use2 Use3 /// reg(a) (1/3) * 1 * 1 /// reg(b) 1 * (1/3) * (1/2) /// reg({0,+,1}) (2/3) * (2/3) * (1/2) /// reg({-1,+,1}) (2/3) * (2/3) * 1 /// reg({a,+,1}) (2/3) * 1 * 1 /// reg({b,+,1}) 1 * (2/3) * (2/3) /// reg(c) 1 * 1 * 0 /// /// Now count registers number mathematical expectation for each formula: /// Note that for each use we exclude probability if not selecting for the use. /// For example for Use1 probability for reg(a) would be just 1 * 1 (excluding /// probabilty 1/3 of not selecting for Use1). /// Use1: /// reg(a) + reg({0,+,1}) 1 + 1/3 -- to be deleted /// reg(a) + reg({-1,+,1}) + 1 1 + 4/9 -- to be deleted /// reg({a,+,1}) 1 /// Use2: /// reg(b) + reg({0,+,1}) 1/2 + 1/3 -- to be deleted /// reg(b) + reg({-1,+,1}) + 1 1/2 + 2/3 -- to be deleted /// reg({b,+,1}) 2/3 /// Use3: /// reg(c) + reg(b) + reg({0,+,1}) 1 + 1/3 + 4/9 -- to be deleted /// reg(c) + reg({b,+,1}) 1 + 2/3 void LSRInstance::NarrowSearchSpaceByDeletingCostlyFormulas() { if (EstimateSearchSpaceComplexity() < ComplexityLimit) return; // Ok, we have too many of formulae on our hands to conveniently handle. // Use a rough heuristic to thin out the list. // Set of Regs wich will be 100% used in final solution. // Used in each formula of a solution (in example above this is reg(c)). // We can skip them in calculations. SmallPtrSet UniqRegs; LLVM_DEBUG(dbgs() << "The search space is too complex.\n"); // Map each register to probability of not selecting DenseMap RegNumMap; for (const SCEV *Reg : RegUses) { if (UniqRegs.count(Reg)) continue; float PNotSel = 1; for (const LSRUse &LU : Uses) { if (!LU.Regs.count(Reg)) continue; float P = LU.getNotSelectedProbability(Reg); if (P != 0.0) PNotSel *= P; else UniqRegs.insert(Reg); } RegNumMap.insert(std::make_pair(Reg, PNotSel)); } LLVM_DEBUG( dbgs() << "Narrowing the search space by deleting costly formulas\n"); // Delete formulas where registers number expectation is high. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; // If nothing to delete - continue. if (LU.Formulae.size() < 2) continue; // This is temporary solution to test performance. Float should be // replaced with round independent type (based on integers) to avoid // different results for different target builds. float FMinRegNum = LU.Formulae[0].getNumRegs(); float FMinARegNum = LU.Formulae[0].getNumRegs(); size_t MinIdx = 0; for (size_t i = 0, e = LU.Formulae.size(); i != e; ++i) { Formula &F = LU.Formulae[i]; float FRegNum = 0; float FARegNum = 0; for (const SCEV *BaseReg : F.BaseRegs) { if (UniqRegs.count(BaseReg)) continue; FRegNum += RegNumMap[BaseReg] / LU.getNotSelectedProbability(BaseReg); if (isa(BaseReg)) FARegNum += RegNumMap[BaseReg] / LU.getNotSelectedProbability(BaseReg); } if (const SCEV *ScaledReg = F.ScaledReg) { if (!UniqRegs.count(ScaledReg)) { FRegNum += RegNumMap[ScaledReg] / LU.getNotSelectedProbability(ScaledReg); if (isa(ScaledReg)) FARegNum += RegNumMap[ScaledReg] / LU.getNotSelectedProbability(ScaledReg); } } if (FMinRegNum > FRegNum || (FMinRegNum == FRegNum && FMinARegNum > FARegNum)) { FMinRegNum = FRegNum; FMinARegNum = FARegNum; MinIdx = i; } } LLVM_DEBUG(dbgs() << " The formula "; LU.Formulae[MinIdx].print(dbgs()); dbgs() << " with min reg num " << FMinRegNum << '\n'); if (MinIdx != 0) std::swap(LU.Formulae[MinIdx], LU.Formulae[0]); while (LU.Formulae.size() != 1) { LLVM_DEBUG(dbgs() << " Deleting "; LU.Formulae.back().print(dbgs()); dbgs() << '\n'); LU.Formulae.pop_back(); } LU.RecomputeRegs(LUIdx, RegUses); assert(LU.Formulae.size() == 1 && "Should be exactly 1 min regs formula"); Formula &F = LU.Formulae[0]; LLVM_DEBUG(dbgs() << " Leaving only "; F.print(dbgs()); dbgs() << '\n'); // When we choose the formula, the regs become unique. UniqRegs.insert(F.BaseRegs.begin(), F.BaseRegs.end()); if (F.ScaledReg) UniqRegs.insert(F.ScaledReg); } LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } /// Pick a register which seems likely to be profitable, and then in any use /// which has any reference to that register, delete all formulae which do not /// reference that register. void LSRInstance::NarrowSearchSpaceByPickingWinnerRegs() { // With all other options exhausted, loop until the system is simple // enough to handle. SmallPtrSet Taken; while (EstimateSearchSpaceComplexity() >= ComplexityLimit) { // Ok, we have too many of formulae on our hands to conveniently handle. // Use a rough heuristic to thin out the list. LLVM_DEBUG(dbgs() << "The search space is too complex.\n"); // Pick the register which is used by the most LSRUses, which is likely // to be a good reuse register candidate. const SCEV *Best = nullptr; unsigned BestNum = 0; for (const SCEV *Reg : RegUses) { if (Taken.count(Reg)) continue; if (!Best) { Best = Reg; BestNum = RegUses.getUsedByIndices(Reg).count(); } else { unsigned Count = RegUses.getUsedByIndices(Reg).count(); if (Count > BestNum) { Best = Reg; BestNum = Count; } } } assert(Best && "Failed to find best LSRUse candidate"); LLVM_DEBUG(dbgs() << "Narrowing the search space by assuming " << *Best << " will yield profitable reuse.\n"); Taken.insert(Best); // In any use with formulae which references this register, delete formulae // which don't reference it. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) { LSRUse &LU = Uses[LUIdx]; if (!LU.Regs.count(Best)) continue; bool Any = false; for (size_t i = 0, e = LU.Formulae.size(); i != e; ++i) { Formula &F = LU.Formulae[i]; if (!F.referencesReg(Best)) { LLVM_DEBUG(dbgs() << " Deleting "; F.print(dbgs()); dbgs() << '\n'); LU.DeleteFormula(F); --e; --i; Any = true; assert(e != 0 && "Use has no formulae left! Is Regs inconsistent?"); continue; } } if (Any) LU.RecomputeRegs(LUIdx, RegUses); } LLVM_DEBUG(dbgs() << "After pre-selection:\n"; print_uses(dbgs())); } } /// If there are an extraordinary number of formulae to choose from, use some /// rough heuristics to prune down the number of formulae. This keeps the main /// solver from taking an extraordinary amount of time in some worst-case /// scenarios. void LSRInstance::NarrowSearchSpaceUsingHeuristics() { NarrowSearchSpaceByDetectingSupersets(); NarrowSearchSpaceByCollapsingUnrolledCode(); NarrowSearchSpaceByRefilteringUndesirableDedicatedRegisters(); if (FilterSameScaledReg) NarrowSearchSpaceByFilterFormulaWithSameScaledReg(); NarrowSearchSpaceByFilterPostInc(); if (LSRExpNarrow) NarrowSearchSpaceByDeletingCostlyFormulas(); else NarrowSearchSpaceByPickingWinnerRegs(); } /// This is the recursive solver. void LSRInstance::SolveRecurse(SmallVectorImpl &Solution, Cost &SolutionCost, SmallVectorImpl &Workspace, const Cost &CurCost, const SmallPtrSet &CurRegs, DenseSet &VisitedRegs) const { // Some ideas: // - prune more: // - use more aggressive filtering // - sort the formula so that the most profitable solutions are found first // - sort the uses too // - search faster: // - don't compute a cost, and then compare. compare while computing a cost // and bail early. // - track register sets with SmallBitVector const LSRUse &LU = Uses[Workspace.size()]; // If this use references any register that's already a part of the // in-progress solution, consider it a requirement that a formula must // reference that register in order to be considered. This prunes out // unprofitable searching. SmallSetVector ReqRegs; for (const SCEV *S : CurRegs) if (LU.Regs.count(S)) ReqRegs.insert(S); SmallPtrSet NewRegs; Cost NewCost(L, SE, TTI, AMK); for (const Formula &F : LU.Formulae) { // Ignore formulae which may not be ideal in terms of register reuse of // ReqRegs. The formula should use all required registers before // introducing new ones. // This can sometimes (notably when trying to favour postinc) lead to // sub-optimial decisions. There it is best left to the cost modelling to // get correct. if (AMK != TTI::AMK_PostIndexed || LU.Kind != LSRUse::Address) { int NumReqRegsToFind = std::min(F.getNumRegs(), ReqRegs.size()); for (const SCEV *Reg : ReqRegs) { if ((F.ScaledReg && F.ScaledReg == Reg) || is_contained(F.BaseRegs, Reg)) { --NumReqRegsToFind; if (NumReqRegsToFind == 0) break; } } if (NumReqRegsToFind != 0) { // If none of the formulae satisfied the required registers, then we could // clear ReqRegs and try again. Currently, we simply give up in this case. continue; } } // Evaluate the cost of the current formula. If it's already worse than // the current best, prune the search at that point. NewCost = CurCost; NewRegs = CurRegs; NewCost.RateFormula(F, NewRegs, VisitedRegs, LU); if (NewCost.isLess(SolutionCost)) { Workspace.push_back(&F); if (Workspace.size() != Uses.size()) { SolveRecurse(Solution, SolutionCost, Workspace, NewCost, NewRegs, VisitedRegs); if (F.getNumRegs() == 1 && Workspace.size() == 1) VisitedRegs.insert(F.ScaledReg ? F.ScaledReg : F.BaseRegs[0]); } else { LLVM_DEBUG(dbgs() << "New best at "; NewCost.print(dbgs()); dbgs() << ".\nRegs:\n"; for (const SCEV *S : NewRegs) dbgs() << "- " << *S << "\n"; dbgs() << '\n'); SolutionCost = NewCost; Solution = Workspace; } Workspace.pop_back(); } } } /// Choose one formula from each use. Return the results in the given Solution /// vector. void LSRInstance::Solve(SmallVectorImpl &Solution) const { SmallVector Workspace; Cost SolutionCost(L, SE, TTI, AMK); SolutionCost.Lose(); Cost CurCost(L, SE, TTI, AMK); SmallPtrSet CurRegs; DenseSet VisitedRegs; Workspace.reserve(Uses.size()); // SolveRecurse does all the work. SolveRecurse(Solution, SolutionCost, Workspace, CurCost, CurRegs, VisitedRegs); if (Solution.empty()) { LLVM_DEBUG(dbgs() << "\nNo Satisfactory Solution\n"); return; } // Ok, we've now made all our decisions. LLVM_DEBUG(dbgs() << "\n" "The chosen solution requires "; SolutionCost.print(dbgs()); dbgs() << ":\n"; for (size_t i = 0, e = Uses.size(); i != e; ++i) { dbgs() << " "; Uses[i].print(dbgs()); dbgs() << "\n" " "; Solution[i]->print(dbgs()); dbgs() << '\n'; }); assert(Solution.size() == Uses.size() && "Malformed solution!"); } /// Helper for AdjustInsertPositionForExpand. Climb up the dominator tree far as /// we can go while still being dominated by the input positions. This helps /// canonicalize the insert position, which encourages sharing. BasicBlock::iterator LSRInstance::HoistInsertPosition(BasicBlock::iterator IP, const SmallVectorImpl &Inputs) const { Instruction *Tentative = &*IP; while (true) { bool AllDominate = true; Instruction *BetterPos = nullptr; // Don't bother attempting to insert before a catchswitch, their basic block // cannot have other non-PHI instructions. if (isa(Tentative)) return IP; for (Instruction *Inst : Inputs) { if (Inst == Tentative || !DT.dominates(Inst, Tentative)) { AllDominate = false; break; } // Attempt to find an insert position in the middle of the block, // instead of at the end, so that it can be used for other expansions. if (Tentative->getParent() == Inst->getParent() && (!BetterPos || !DT.dominates(Inst, BetterPos))) BetterPos = &*std::next(BasicBlock::iterator(Inst)); } if (!AllDominate) break; if (BetterPos) IP = BetterPos->getIterator(); else IP = Tentative->getIterator(); const Loop *IPLoop = LI.getLoopFor(IP->getParent()); unsigned IPLoopDepth = IPLoop ? IPLoop->getLoopDepth() : 0; BasicBlock *IDom; for (DomTreeNode *Rung = DT.getNode(IP->getParent()); ; ) { if (!Rung) return IP; Rung = Rung->getIDom(); if (!Rung) return IP; IDom = Rung->getBlock(); // Don't climb into a loop though. const Loop *IDomLoop = LI.getLoopFor(IDom); unsigned IDomDepth = IDomLoop ? IDomLoop->getLoopDepth() : 0; if (IDomDepth <= IPLoopDepth && (IDomDepth != IPLoopDepth || IDomLoop == IPLoop)) break; } Tentative = IDom->getTerminator(); } return IP; } /// Determine an input position which will be dominated by the operands and /// which will dominate the result. BasicBlock::iterator LSRInstance::AdjustInsertPositionForExpand(BasicBlock::iterator LowestIP, const LSRFixup &LF, const LSRUse &LU, SCEVExpander &Rewriter) const { // Collect some instructions which must be dominated by the // expanding replacement. These must be dominated by any operands that // will be required in the expansion. SmallVector Inputs; if (Instruction *I = dyn_cast(LF.OperandValToReplace)) Inputs.push_back(I); if (LU.Kind == LSRUse::ICmpZero) if (Instruction *I = dyn_cast(cast(LF.UserInst)->getOperand(1))) Inputs.push_back(I); if (LF.PostIncLoops.count(L)) { if (LF.isUseFullyOutsideLoop(L)) Inputs.push_back(L->getLoopLatch()->getTerminator()); else Inputs.push_back(IVIncInsertPos); } // The expansion must also be dominated by the increment positions of any // loops it for which it is using post-inc mode. for (const Loop *PIL : LF.PostIncLoops) { if (PIL == L) continue; // Be dominated by the loop exit. SmallVector ExitingBlocks; PIL->getExitingBlocks(ExitingBlocks); if (!ExitingBlocks.empty()) { BasicBlock *BB = ExitingBlocks[0]; for (unsigned i = 1, e = ExitingBlocks.size(); i != e; ++i) BB = DT.findNearestCommonDominator(BB, ExitingBlocks[i]); Inputs.push_back(BB->getTerminator()); } } assert(!isa(LowestIP) && !LowestIP->isEHPad() && !isa(LowestIP) && "Insertion point must be a normal instruction"); // Then, climb up the immediate dominator tree as far as we can go while // still being dominated by the input positions. BasicBlock::iterator IP = HoistInsertPosition(LowestIP, Inputs); // Don't insert instructions before PHI nodes. while (isa(IP)) ++IP; // Ignore landingpad instructions. while (IP->isEHPad()) ++IP; // Ignore debug intrinsics. while (isa(IP)) ++IP; // Set IP below instructions recently inserted by SCEVExpander. This keeps the // IP consistent across expansions and allows the previously inserted // instructions to be reused by subsequent expansion. while (Rewriter.isInsertedInstruction(&*IP) && IP != LowestIP) ++IP; return IP; } /// Emit instructions for the leading candidate expression for this LSRUse (this /// is called "expanding"). Value *LSRInstance::Expand(const LSRUse &LU, const LSRFixup &LF, const Formula &F, BasicBlock::iterator IP, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const { if (LU.RigidFormula) return LF.OperandValToReplace; // Determine an input position which will be dominated by the operands and // which will dominate the result. IP = AdjustInsertPositionForExpand(IP, LF, LU, Rewriter); Rewriter.setInsertPoint(&*IP); // Inform the Rewriter if we have a post-increment use, so that it can // perform an advantageous expansion. Rewriter.setPostInc(LF.PostIncLoops); // This is the type that the user actually needs. Type *OpTy = LF.OperandValToReplace->getType(); // This will be the type that we'll initially expand to. Type *Ty = F.getType(); if (!Ty) // No type known; just expand directly to the ultimate type. Ty = OpTy; else if (SE.getEffectiveSCEVType(Ty) == SE.getEffectiveSCEVType(OpTy)) // Expand directly to the ultimate type if it's the right size. Ty = OpTy; // This is the type to do integer arithmetic in. Type *IntTy = SE.getEffectiveSCEVType(Ty); // Build up a list of operands to add together to form the full base. SmallVector Ops; // Expand the BaseRegs portion. for (const SCEV *Reg : F.BaseRegs) { assert(!Reg->isZero() && "Zero allocated in a base register!"); // If we're expanding for a post-inc user, make the post-inc adjustment. Reg = denormalizeForPostIncUse(Reg, LF.PostIncLoops, SE); Ops.push_back(SE.getUnknown(Rewriter.expandCodeFor(Reg, nullptr))); } // Expand the ScaledReg portion. Value *ICmpScaledV = nullptr; if (F.Scale != 0) { const SCEV *ScaledS = F.ScaledReg; // If we're expanding for a post-inc user, make the post-inc adjustment. PostIncLoopSet &Loops = const_cast(LF.PostIncLoops); ScaledS = denormalizeForPostIncUse(ScaledS, Loops, SE); if (LU.Kind == LSRUse::ICmpZero) { // Expand ScaleReg as if it was part of the base regs. if (F.Scale == 1) Ops.push_back( SE.getUnknown(Rewriter.expandCodeFor(ScaledS, nullptr))); else { // An interesting way of "folding" with an icmp is to use a negated // scale, which we'll implement by inserting it into the other operand // of the icmp. assert(F.Scale == -1 && "The only scale supported by ICmpZero uses is -1!"); ICmpScaledV = Rewriter.expandCodeFor(ScaledS, nullptr); } } else { // Otherwise just expand the scaled register and an explicit scale, // which is expected to be matched as part of the address. // Flush the operand list to suppress SCEVExpander hoisting address modes. // Unless the addressing mode will not be folded. if (!Ops.empty() && LU.Kind == LSRUse::Address && isAMCompletelyFolded(TTI, LU, F)) { Value *FullV = Rewriter.expandCodeFor(SE.getAddExpr(Ops), nullptr); Ops.clear(); Ops.push_back(SE.getUnknown(FullV)); } ScaledS = SE.getUnknown(Rewriter.expandCodeFor(ScaledS, nullptr)); if (F.Scale != 1) ScaledS = SE.getMulExpr(ScaledS, SE.getConstant(ScaledS->getType(), F.Scale)); Ops.push_back(ScaledS); } } // Expand the GV portion. if (F.BaseGV) { // Flush the operand list to suppress SCEVExpander hoisting. if (!Ops.empty()) { Value *FullV = Rewriter.expandCodeFor(SE.getAddExpr(Ops), IntTy); Ops.clear(); Ops.push_back(SE.getUnknown(FullV)); } Ops.push_back(SE.getUnknown(F.BaseGV)); } // Flush the operand list to suppress SCEVExpander hoisting of both folded and // unfolded offsets. LSR assumes they both live next to their uses. if (!Ops.empty()) { Value *FullV = Rewriter.expandCodeFor(SE.getAddExpr(Ops), Ty); Ops.clear(); Ops.push_back(SE.getUnknown(FullV)); } // Expand the immediate portion. int64_t Offset = (uint64_t)F.BaseOffset + LF.Offset; if (Offset != 0) { if (LU.Kind == LSRUse::ICmpZero) { // The other interesting way of "folding" with an ICmpZero is to use a // negated immediate. if (!ICmpScaledV) ICmpScaledV = ConstantInt::get(IntTy, -(uint64_t)Offset); else { Ops.push_back(SE.getUnknown(ICmpScaledV)); ICmpScaledV = ConstantInt::get(IntTy, Offset); } } else { // Just add the immediate values. These again are expected to be matched // as part of the address. Ops.push_back(SE.getUnknown(ConstantInt::getSigned(IntTy, Offset))); } } // Expand the unfolded offset portion. int64_t UnfoldedOffset = F.UnfoldedOffset; if (UnfoldedOffset != 0) { // Just add the immediate values. Ops.push_back(SE.getUnknown(ConstantInt::getSigned(IntTy, UnfoldedOffset))); } // Emit instructions summing all the operands. const SCEV *FullS = Ops.empty() ? SE.getConstant(IntTy, 0) : SE.getAddExpr(Ops); Value *FullV = Rewriter.expandCodeFor(FullS, Ty); // We're done expanding now, so reset the rewriter. Rewriter.clearPostInc(); // An ICmpZero Formula represents an ICmp which we're handling as a // comparison against zero. Now that we've expanded an expression for that // form, update the ICmp's other operand. if (LU.Kind == LSRUse::ICmpZero) { ICmpInst *CI = cast(LF.UserInst); if (auto *OperandIsInstr = dyn_cast(CI->getOperand(1))) DeadInsts.emplace_back(OperandIsInstr); assert(!F.BaseGV && "ICmp does not support folding a global value and " "a scale at the same time!"); if (F.Scale == -1) { if (ICmpScaledV->getType() != OpTy) { Instruction *Cast = CastInst::Create(CastInst::getCastOpcode(ICmpScaledV, false, OpTy, false), ICmpScaledV, OpTy, "tmp", CI); ICmpScaledV = Cast; } CI->setOperand(1, ICmpScaledV); } else { // A scale of 1 means that the scale has been expanded as part of the // base regs. assert((F.Scale == 0 || F.Scale == 1) && "ICmp does not support folding a global value and " "a scale at the same time!"); Constant *C = ConstantInt::getSigned(SE.getEffectiveSCEVType(OpTy), -(uint64_t)Offset); if (C->getType() != OpTy) C = ConstantExpr::getCast(CastInst::getCastOpcode(C, false, OpTy, false), C, OpTy); CI->setOperand(1, C); } } return FullV; } /// Helper for Rewrite. PHI nodes are special because the use of their operands /// effectively happens in their predecessor blocks, so the expression may need /// to be expanded in multiple places. void LSRInstance::RewriteForPHI( PHINode *PN, const LSRUse &LU, const LSRFixup &LF, const Formula &F, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const { DenseMap Inserted; for (unsigned i = 0, e = PN->getNumIncomingValues(); i != e; ++i) if (PN->getIncomingValue(i) == LF.OperandValToReplace) { bool needUpdateFixups = false; BasicBlock *BB = PN->getIncomingBlock(i); // If this is a critical edge, split the edge so that we do not insert // the code on all predecessor/successor paths. We do this unless this // is the canonical backedge for this loop, which complicates post-inc // users. if (e != 1 && BB->getTerminator()->getNumSuccessors() > 1 && !isa(BB->getTerminator()) && !isa(BB->getTerminator())) { BasicBlock *Parent = PN->getParent(); Loop *PNLoop = LI.getLoopFor(Parent); if (!PNLoop || Parent != PNLoop->getHeader()) { // Split the critical edge. BasicBlock *NewBB = nullptr; if (!Parent->isLandingPad()) { NewBB = SplitCriticalEdge(BB, Parent, CriticalEdgeSplittingOptions(&DT, &LI, MSSAU) .setMergeIdenticalEdges() .setKeepOneInputPHIs()); } else { SmallVector NewBBs; SplitLandingPadPredecessors(Parent, BB, "", "", NewBBs, &DT, &LI); NewBB = NewBBs[0]; } // If NewBB==NULL, then SplitCriticalEdge refused to split because all // phi predecessors are identical. The simple thing to do is skip // splitting in this case rather than complicate the API. if (NewBB) { // If PN is outside of the loop and BB is in the loop, we want to // move the block to be immediately before the PHI block, not // immediately after BB. if (L->contains(BB) && !L->contains(PN)) NewBB->moveBefore(PN->getParent()); // Splitting the edge can reduce the number of PHI entries we have. e = PN->getNumIncomingValues(); BB = NewBB; i = PN->getBasicBlockIndex(BB); needUpdateFixups = true; } } } std::pair::iterator, bool> Pair = Inserted.insert(std::make_pair(BB, static_cast(nullptr))); if (!Pair.second) PN->setIncomingValue(i, Pair.first->second); else { Value *FullV = Expand(LU, LF, F, BB->getTerminator()->getIterator(), Rewriter, DeadInsts); // If this is reuse-by-noop-cast, insert the noop cast. Type *OpTy = LF.OperandValToReplace->getType(); if (FullV->getType() != OpTy) FullV = CastInst::Create(CastInst::getCastOpcode(FullV, false, OpTy, false), FullV, LF.OperandValToReplace->getType(), "tmp", BB->getTerminator()); PN->setIncomingValue(i, FullV); Pair.first->second = FullV; } // If LSR splits critical edge and phi node has other pending // fixup operands, we need to update those pending fixups. Otherwise // formulae will not be implemented completely and some instructions // will not be eliminated. if (needUpdateFixups) { for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) for (LSRFixup &Fixup : Uses[LUIdx].Fixups) // If fixup is supposed to rewrite some operand in the phi // that was just updated, it may be already moved to // another phi node. Such fixup requires update. if (Fixup.UserInst == PN) { // Check if the operand we try to replace still exists in the // original phi. bool foundInOriginalPHI = false; for (const auto &val : PN->incoming_values()) if (val == Fixup.OperandValToReplace) { foundInOriginalPHI = true; break; } // If fixup operand found in original PHI - nothing to do. if (foundInOriginalPHI) continue; // Otherwise it might be moved to another PHI and requires update. // If fixup operand not found in any of the incoming blocks that // means we have already rewritten it - nothing to do. for (const auto &Block : PN->blocks()) for (BasicBlock::iterator I = Block->begin(); isa(I); ++I) { PHINode *NewPN = cast(I); for (const auto &val : NewPN->incoming_values()) if (val == Fixup.OperandValToReplace) Fixup.UserInst = NewPN; } } } } } /// Emit instructions for the leading candidate expression for this LSRUse (this /// is called "expanding"), and update the UserInst to reference the newly /// expanded value. void LSRInstance::Rewrite(const LSRUse &LU, const LSRFixup &LF, const Formula &F, SCEVExpander &Rewriter, SmallVectorImpl &DeadInsts) const { // First, find an insertion point that dominates UserInst. For PHI nodes, // find the nearest block which dominates all the relevant uses. if (PHINode *PN = dyn_cast(LF.UserInst)) { RewriteForPHI(PN, LU, LF, F, Rewriter, DeadInsts); } else { Value *FullV = Expand(LU, LF, F, LF.UserInst->getIterator(), Rewriter, DeadInsts); // If this is reuse-by-noop-cast, insert the noop cast. Type *OpTy = LF.OperandValToReplace->getType(); if (FullV->getType() != OpTy) { Instruction *Cast = CastInst::Create(CastInst::getCastOpcode(FullV, false, OpTy, false), FullV, OpTy, "tmp", LF.UserInst); FullV = Cast; } // Update the user. ICmpZero is handled specially here (for now) because // Expand may have updated one of the operands of the icmp already, and // its new value may happen to be equal to LF.OperandValToReplace, in // which case doing replaceUsesOfWith leads to replacing both operands // with the same value. TODO: Reorganize this. if (LU.Kind == LSRUse::ICmpZero) LF.UserInst->setOperand(0, FullV); else LF.UserInst->replaceUsesOfWith(LF.OperandValToReplace, FullV); } if (auto *OperandIsInstr = dyn_cast(LF.OperandValToReplace)) DeadInsts.emplace_back(OperandIsInstr); } /// Rewrite all the fixup locations with new values, following the chosen /// solution. void LSRInstance::ImplementSolution( const SmallVectorImpl &Solution) { // Keep track of instructions we may have made dead, so that // we can remove them after we are done working. SmallVector DeadInsts; SCEVExpander Rewriter(SE, L->getHeader()->getModule()->getDataLayout(), "lsr", false); #ifndef NDEBUG Rewriter.setDebugType(DEBUG_TYPE); #endif Rewriter.disableCanonicalMode(); Rewriter.enableLSRMode(); Rewriter.setIVIncInsertPos(L, IVIncInsertPos); // Mark phi nodes that terminate chains so the expander tries to reuse them. for (const IVChain &Chain : IVChainVec) { if (PHINode *PN = dyn_cast(Chain.tailUserInst())) Rewriter.setChainedPhi(PN); } // Expand the new value definitions and update the users. for (size_t LUIdx = 0, NumUses = Uses.size(); LUIdx != NumUses; ++LUIdx) for (const LSRFixup &Fixup : Uses[LUIdx].Fixups) { Rewrite(Uses[LUIdx], Fixup, *Solution[LUIdx], Rewriter, DeadInsts); Changed = true; } for (const IVChain &Chain : IVChainVec) { GenerateIVChain(Chain, Rewriter, DeadInsts); Changed = true; } for (const WeakVH &IV : Rewriter.getInsertedIVs()) if (IV && dyn_cast(&*IV)->getParent()) ScalarEvolutionIVs.push_back(IV); // Clean up after ourselves. This must be done before deleting any // instructions. Rewriter.clear(); Changed |= RecursivelyDeleteTriviallyDeadInstructionsPermissive(DeadInsts, &TLI, MSSAU); // In our cost analysis above, we assume that each addrec consumes exactly // one register, and arrange to have increments inserted just before the // latch to maximimize the chance this is true. However, if we reused // existing IVs, we now need to move the increments to match our // expectations. Otherwise, our cost modeling results in us having a // chosen a non-optimal result for the actual schedule. (And yes, this // scheduling decision does impact later codegen.) for (PHINode &PN : L->getHeader()->phis()) { BinaryOperator *BO = nullptr; Value *Start = nullptr, *Step = nullptr; if (!matchSimpleRecurrence(&PN, BO, Start, Step)) continue; switch (BO->getOpcode()) { case Instruction::Sub: if (BO->getOperand(0) != &PN) // sub is non-commutative - match handling elsewhere in LSR continue; break; case Instruction::Add: break; default: continue; }; if (!isa(Step)) // If not a constant step, might increase register pressure // (We assume constants have been canonicalized to RHS) continue; if (BO->getParent() == IVIncInsertPos->getParent()) // Only bother moving across blocks. Isel can handle block local case. continue; // Can we legally schedule inc at the desired point? if (!llvm::all_of(BO->uses(), [&](Use &U) {return DT.dominates(IVIncInsertPos, U);})) continue; BO->moveBefore(IVIncInsertPos); Changed = true; } } LSRInstance::LSRInstance(Loop *L, IVUsers &IU, ScalarEvolution &SE, DominatorTree &DT, LoopInfo &LI, const TargetTransformInfo &TTI, AssumptionCache &AC, TargetLibraryInfo &TLI, MemorySSAUpdater *MSSAU) : IU(IU), SE(SE), DT(DT), LI(LI), AC(AC), TLI(TLI), TTI(TTI), L(L), MSSAU(MSSAU), AMK(PreferredAddresingMode.getNumOccurrences() > 0 ? PreferredAddresingMode : TTI.getPreferredAddressingMode(L, &SE)) { // If LoopSimplify form is not available, stay out of trouble. if (!L->isLoopSimplifyForm()) return; // If there's no interesting work to be done, bail early. if (IU.empty()) return; // If there's too much analysis to be done, bail early. We won't be able to // model the problem anyway. unsigned NumUsers = 0; for (const IVStrideUse &U : IU) { if (++NumUsers > MaxIVUsers) { (void)U; LLVM_DEBUG(dbgs() << "LSR skipping loop, too many IV Users in " << U << "\n"); return; } // Bail out if we have a PHI on an EHPad that gets a value from a // CatchSwitchInst. Because the CatchSwitchInst cannot be split, there is // no good place to stick any instructions. if (auto *PN = dyn_cast(U.getUser())) { auto *FirstNonPHI = PN->getParent()->getFirstNonPHI(); if (isa(FirstNonPHI) || isa(FirstNonPHI)) for (BasicBlock *PredBB : PN->blocks()) if (isa(PredBB->getFirstNonPHI())) return; } } LLVM_DEBUG(dbgs() << "\nLSR on loop "; L->getHeader()->printAsOperand(dbgs(), /*PrintType=*/false); dbgs() << ":\n"); // First, perform some low-level loop optimizations. OptimizeShadowIV(); OptimizeLoopTermCond(); // If loop preparation eliminates all interesting IV users, bail. if (IU.empty()) return; // Skip nested loops until we can model them better with formulae. if (!L->isInnermost()) { LLVM_DEBUG(dbgs() << "LSR skipping outer loop " << *L << "\n"); return; } // Start collecting data and preparing for the solver. // If number of registers is not the major cost, we cannot benefit from the // current profitable chain optimization which is based on number of // registers. // FIXME: add profitable chain optimization for other kinds major cost, for // example number of instructions. if (TTI.isNumRegsMajorCostOfLSR() || StressIVChain) CollectChains(); CollectInterestingTypesAndFactors(); CollectFixupsAndInitialFormulae(); CollectLoopInvariantFixupsAndFormulae(); if (Uses.empty()) return; LLVM_DEBUG(dbgs() << "LSR found " << Uses.size() << " uses:\n"; print_uses(dbgs())); // Now use the reuse data to generate a bunch of interesting ways // to formulate the values needed for the uses. GenerateAllReuseFormulae(); FilterOutUndesirableDedicatedRegisters(); NarrowSearchSpaceUsingHeuristics(); SmallVector Solution; Solve(Solution); // Release memory that is no longer needed. Factors.clear(); Types.clear(); RegUses.clear(); if (Solution.empty()) return; #ifndef NDEBUG // Formulae should be legal. for (const LSRUse &LU : Uses) { for (const Formula &F : LU.Formulae) assert(isLegalUse(TTI, LU.MinOffset, LU.MaxOffset, LU.Kind, LU.AccessTy, F) && "Illegal formula generated!"); }; #endif // Now that we've decided what we want, make it so. ImplementSolution(Solution); } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) void LSRInstance::print_factors_and_types(raw_ostream &OS) const { if (Factors.empty() && Types.empty()) return; OS << "LSR has identified the following interesting factors and types: "; bool First = true; for (int64_t Factor : Factors) { if (!First) OS << ", "; First = false; OS << '*' << Factor; } for (Type *Ty : Types) { if (!First) OS << ", "; First = false; OS << '(' << *Ty << ')'; } OS << '\n'; } void LSRInstance::print_fixups(raw_ostream &OS) const { OS << "LSR is examining the following fixup sites:\n"; for (const LSRUse &LU : Uses) for (const LSRFixup &LF : LU.Fixups) { dbgs() << " "; LF.print(OS); OS << '\n'; } } void LSRInstance::print_uses(raw_ostream &OS) const { OS << "LSR is examining the following uses:\n"; for (const LSRUse &LU : Uses) { dbgs() << " "; LU.print(OS); OS << '\n'; for (const Formula &F : LU.Formulae) { OS << " "; F.print(OS); OS << '\n'; } } } void LSRInstance::print(raw_ostream &OS) const { print_factors_and_types(OS); print_fixups(OS); print_uses(OS); } LLVM_DUMP_METHOD void LSRInstance::dump() const { print(errs()); errs() << '\n'; } #endif namespace { class LoopStrengthReduce : public LoopPass { public: static char ID; // Pass ID, replacement for typeid LoopStrengthReduce(); private: bool runOnLoop(Loop *L, LPPassManager &LPM) override; void getAnalysisUsage(AnalysisUsage &AU) const override; }; } // end anonymous namespace LoopStrengthReduce::LoopStrengthReduce() : LoopPass(ID) { initializeLoopStrengthReducePass(*PassRegistry::getPassRegistry()); } void LoopStrengthReduce::getAnalysisUsage(AnalysisUsage &AU) const { // We split critical edges, so we change the CFG. However, we do update // many analyses if they are around. AU.addPreservedID(LoopSimplifyID); AU.addRequired(); AU.addPreserved(); AU.addRequiredID(LoopSimplifyID); AU.addRequired(); AU.addPreserved(); AU.addRequired(); AU.addPreserved(); AU.addRequired(); AU.addRequired(); // Requiring LoopSimplify a second time here prevents IVUsers from running // twice, since LoopSimplify was invalidated by running ScalarEvolution. AU.addRequiredID(LoopSimplifyID); AU.addRequired(); AU.addPreserved(); AU.addRequired(); AU.addPreserved(); } namespace { struct SCEVDbgValueBuilder { SCEVDbgValueBuilder() = default; SCEVDbgValueBuilder(const SCEVDbgValueBuilder &Base) { Values = Base.Values; Expr = Base.Expr; } /// The DIExpression as we translate the SCEV. SmallVector Expr; /// The location ops of the DIExpression. SmallVector Values; void pushOperator(uint64_t Op) { Expr.push_back(Op); } void pushUInt(uint64_t Operand) { Expr.push_back(Operand); } /// Add a DW_OP_LLVM_arg to the expression, followed by the index of the value /// in the set of values referenced by the expression. void pushValue(llvm::Value *V) { Expr.push_back(llvm::dwarf::DW_OP_LLVM_arg); auto *It = std::find(Values.begin(), Values.end(), llvm::ValueAsMetadata::get(V)); unsigned ArgIndex = 0; if (It != Values.end()) { ArgIndex = std::distance(Values.begin(), It); } else { ArgIndex = Values.size(); Values.push_back(llvm::ValueAsMetadata::get(V)); } Expr.push_back(ArgIndex); } void pushValue(const SCEVUnknown *U) { llvm::Value *V = cast(U)->getValue(); pushValue(V); } bool pushConst(const SCEVConstant *C) { if (C->getAPInt().getMinSignedBits() > 64) return false; Expr.push_back(llvm::dwarf::DW_OP_consts); Expr.push_back(C->getAPInt().getSExtValue()); return true; } /// Several SCEV types are sequences of the same arithmetic operator applied /// to constants and values that may be extended or truncated. bool pushArithmeticExpr(const llvm::SCEVCommutativeExpr *CommExpr, uint64_t DwarfOp) { assert((isa(CommExpr) || isa(CommExpr)) && "Expected arithmetic SCEV type"); bool Success = true; unsigned EmitOperator = 0; for (auto &Op : CommExpr->operands()) { Success &= pushSCEV(Op); if (EmitOperator >= 1) pushOperator(DwarfOp); ++EmitOperator; } return Success; } // TODO: Identify and omit noop casts. bool pushCast(const llvm::SCEVCastExpr *C, bool IsSigned) { const llvm::SCEV *Inner = C->getOperand(0); const llvm::Type *Type = C->getType(); uint64_t ToWidth = Type->getIntegerBitWidth(); bool Success = pushSCEV(Inner); uint64_t CastOps[] = {dwarf::DW_OP_LLVM_convert, ToWidth, IsSigned ? llvm::dwarf::DW_ATE_signed : llvm::dwarf::DW_ATE_unsigned}; for (const auto &Op : CastOps) pushOperator(Op); return Success; } // TODO: MinMax - although these haven't been encountered in the test suite. bool pushSCEV(const llvm::SCEV *S) { bool Success = true; if (const SCEVConstant *StartInt = dyn_cast(S)) { Success &= pushConst(StartInt); } else if (const SCEVUnknown *U = dyn_cast(S)) { if (!U->getValue()) return false; pushValue(U->getValue()); } else if (const SCEVMulExpr *MulRec = dyn_cast(S)) { Success &= pushArithmeticExpr(MulRec, llvm::dwarf::DW_OP_mul); } else if (const SCEVUDivExpr *UDiv = dyn_cast(S)) { Success &= pushSCEV(UDiv->getLHS()); Success &= pushSCEV(UDiv->getRHS()); pushOperator(llvm::dwarf::DW_OP_div); } else if (const SCEVCastExpr *Cast = dyn_cast(S)) { // Assert if a new and unknown SCEVCastEXpr type is encountered. assert((isa(Cast) || isa(Cast) || isa(Cast) || isa(Cast)) && "Unexpected cast type in SCEV."); Success &= pushCast(Cast, (isa(Cast))); } else if (const SCEVAddExpr *AddExpr = dyn_cast(S)) { Success &= pushArithmeticExpr(AddExpr, llvm::dwarf::DW_OP_plus); } else if (isa(S)) { // Nested SCEVAddRecExpr are generated by nested loops and are currently // unsupported. return false; } else { return false; } return Success; } void setFinalExpression(llvm::DbgValueInst &DI, const DIExpression *OldExpr) { // Re-state assumption that this dbg.value is not variadic. Any remaining // opcodes in its expression operate on a single value already on the // expression stack. Prepend our operations, which will re-compute and // place that value on the expression stack. assert(!DI.hasArgList()); auto *NewExpr = DIExpression::prependOpcodes(OldExpr, Expr, /*StackValue*/ true); DI.setExpression(NewExpr); auto ValArrayRef = llvm::ArrayRef(Values); DI.setRawLocation(llvm::DIArgList::get(DI.getContext(), ValArrayRef)); } /// If a DVI can be emitted without a DIArgList, omit DW_OP_llvm_arg and the /// location op index 0. void setShortFinalExpression(llvm::DbgValueInst &DI, const DIExpression *OldExpr) { assert((Expr[0] == llvm::dwarf::DW_OP_LLVM_arg && Expr[1] == 0) && "Expected DW_OP_llvm_arg and 0."); DI.replaceVariableLocationOp( 0u, llvm::MetadataAsValue::get(DI.getContext(), Values[0])); // See setFinalExpression: prepend our opcodes on the start of any old // expression opcodes. assert(!DI.hasArgList()); llvm::SmallVector FinalExpr(llvm::drop_begin(Expr, 2)); auto *NewExpr = DIExpression::prependOpcodes(OldExpr, FinalExpr, /*StackValue*/ true); DI.setExpression(NewExpr); } /// Once the IV and variable SCEV translation is complete, write it to the /// source DVI. void applyExprToDbgValue(llvm::DbgValueInst &DI, const DIExpression *OldExpr) { assert(!Expr.empty() && "Unexpected empty expression."); // Emit a simpler form if only a single location is referenced. if (Values.size() == 1 && Expr[0] == llvm::dwarf::DW_OP_LLVM_arg && Expr[1] == 0) { setShortFinalExpression(DI, OldExpr); } else { setFinalExpression(DI, OldExpr); } } /// Return true if the combination of arithmetic operator and underlying /// SCEV constant value is an identity function. bool isIdentityFunction(uint64_t Op, const SCEV *S) { if (const SCEVConstant *C = dyn_cast(S)) { if (C->getAPInt().getMinSignedBits() > 64) return false; int64_t I = C->getAPInt().getSExtValue(); switch (Op) { case llvm::dwarf::DW_OP_plus: case llvm::dwarf::DW_OP_minus: return I == 0; case llvm::dwarf::DW_OP_mul: case llvm::dwarf::DW_OP_div: return I == 1; } } return false; } /// Convert a SCEV of a value to a DIExpression that is pushed onto the /// builder's expression stack. The stack should already contain an /// expression for the iteration count, so that it can be multiplied by /// the stride and added to the start. /// Components of the expression are omitted if they are an identity function. /// Chain (non-affine) SCEVs are not supported. bool SCEVToValueExpr(const llvm::SCEVAddRecExpr &SAR, ScalarEvolution &SE) { assert(SAR.isAffine() && "Expected affine SCEV"); // TODO: Is this check needed? if (isa(SAR.getStart())) return false; const SCEV *Start = SAR.getStart(); const SCEV *Stride = SAR.getStepRecurrence(SE); // Skip pushing arithmetic noops. if (!isIdentityFunction(llvm::dwarf::DW_OP_mul, Stride)) { if (!pushSCEV(Stride)) return false; pushOperator(llvm::dwarf::DW_OP_mul); } if (!isIdentityFunction(llvm::dwarf::DW_OP_plus, Start)) { if (!pushSCEV(Start)) return false; pushOperator(llvm::dwarf::DW_OP_plus); } return true; } /// Convert a SCEV of a value to a DIExpression that is pushed onto the /// builder's expression stack. The stack should already contain an /// expression for the iteration count, so that it can be multiplied by /// the stride and added to the start. /// Components of the expression are omitted if they are an identity function. bool SCEVToIterCountExpr(const llvm::SCEVAddRecExpr &SAR, ScalarEvolution &SE) { assert(SAR.isAffine() && "Expected affine SCEV"); if (isa(SAR.getStart())) { LLVM_DEBUG(dbgs() << "scev-salvage: IV SCEV. Unsupported nested AddRec: " << SAR << '\n'); return false; } const SCEV *Start = SAR.getStart(); const SCEV *Stride = SAR.getStepRecurrence(SE); // Skip pushing arithmetic noops. if (!isIdentityFunction(llvm::dwarf::DW_OP_minus, Start)) { if (!pushSCEV(Start)) return false; pushOperator(llvm::dwarf::DW_OP_minus); } if (!isIdentityFunction(llvm::dwarf::DW_OP_div, Stride)) { if (!pushSCEV(Stride)) return false; pushOperator(llvm::dwarf::DW_OP_div); } return true; } }; struct DVIRecoveryRec { DbgValueInst *DVI; DIExpression *Expr; Metadata *LocationOp; const llvm::SCEV *SCEV; }; } // namespace static void RewriteDVIUsingIterCount(DVIRecoveryRec CachedDVI, const SCEVDbgValueBuilder &IterationCount, ScalarEvolution &SE) { // LSR may add locations to previously single location-op DVIs which // are currently not supported. if (CachedDVI.DVI->getNumVariableLocationOps() != 1) return; // SCEVs for SSA values are most frquently of the form // {start,+,stride}, but sometimes they are ({start,+,stride} + %a + ..). // This is because %a is a PHI node that is not the IV. However, these // SCEVs have not been observed to result in debuginfo-lossy optimisations, // so its not expected this point will be reached. if (!isa(CachedDVI.SCEV)) return; LLVM_DEBUG(dbgs() << "scev-salvage: Value to salvage SCEV: " << *CachedDVI.SCEV << '\n'); const auto *Rec = cast(CachedDVI.SCEV); if (!Rec->isAffine()) return; if (CachedDVI.SCEV->getExpressionSize() > MaxSCEVSalvageExpressionSize) return; // Initialise a new builder with the iteration count expression. In // combination with the value's SCEV this enables recovery. SCEVDbgValueBuilder RecoverValue(IterationCount); if (!RecoverValue.SCEVToValueExpr(*Rec, SE)) return; LLVM_DEBUG(dbgs() << "scev-salvage: Updating: " << *CachedDVI.DVI << '\n'); RecoverValue.applyExprToDbgValue(*CachedDVI.DVI, CachedDVI.Expr); LLVM_DEBUG(dbgs() << "scev-salvage: to: " << *CachedDVI.DVI << '\n'); } static void RewriteDVIUsingOffset(DVIRecoveryRec &DVIRec, llvm::PHINode &IV, int64_t Offset) { assert(!DVIRec.DVI->hasArgList() && "Expected single location-op dbg.value."); DbgValueInst *DVI = DVIRec.DVI; SmallVector Ops; DIExpression::appendOffset(Ops, Offset); DIExpression *Expr = DIExpression::prependOpcodes(DVIRec.Expr, Ops, true); LLVM_DEBUG(dbgs() << "scev-salvage: Updating: " << *DVIRec.DVI << '\n'); DVI->setExpression(Expr); llvm::Value *ValIV = dyn_cast(&IV); DVI->replaceVariableLocationOp( 0u, llvm::MetadataAsValue::get(DVI->getContext(), llvm::ValueAsMetadata::get(ValIV))); LLVM_DEBUG(dbgs() << "scev-salvage: updated with offset to IV: " << *DVIRec.DVI << '\n'); } static void DbgRewriteSalvageableDVIs(llvm::Loop *L, ScalarEvolution &SE, llvm::PHINode *LSRInductionVar, SmallVector &DVIToUpdate) { if (DVIToUpdate.empty()) return; const llvm::SCEV *SCEVInductionVar = SE.getSCEV(LSRInductionVar); assert(SCEVInductionVar && "Anticipated a SCEV for the post-LSR induction variable"); if (const SCEVAddRecExpr *IVAddRec = dyn_cast(SCEVInductionVar)) { if (!IVAddRec->isAffine()) return; if (IVAddRec->getExpressionSize() > MaxSCEVSalvageExpressionSize) return; // The iteration count is required to recover location values. SCEVDbgValueBuilder IterCountExpr; IterCountExpr.pushValue(LSRInductionVar); if (!IterCountExpr.SCEVToIterCountExpr(*IVAddRec, SE)) return; LLVM_DEBUG(dbgs() << "scev-salvage: IV SCEV: " << *SCEVInductionVar << '\n'); // Needn't salvage if the location op hasn't been undef'd by LSR. for (auto &DVIRec : DVIToUpdate) { if (!DVIRec.DVI->isUndef()) continue; // Some DVIs that were single location-op when cached are now multi-op, // due to LSR optimisations. However, multi-op salvaging is not yet // supported by SCEV salvaging. But, we can attempt a salvage by restoring // the pre-LSR single-op expression. if (DVIRec.DVI->hasArgList()) { if (!DVIRec.DVI->getVariableLocationOp(0)) continue; llvm::Type *Ty = DVIRec.DVI->getVariableLocationOp(0)->getType(); DVIRec.DVI->setRawLocation( llvm::ValueAsMetadata::get(UndefValue::get(Ty))); DVIRec.DVI->setExpression(DVIRec.Expr); } LLVM_DEBUG(dbgs() << "scev-salvage: value to recover SCEV: " << *DVIRec.SCEV << '\n'); // Create a simple expression if the IV and value to salvage SCEVs // start values differ by only a constant value. if (Optional Offset = SE.computeConstantDifference(DVIRec.SCEV, SCEVInductionVar)) { if (Offset.getValue().getMinSignedBits() <= 64) RewriteDVIUsingOffset(DVIRec, *LSRInductionVar, Offset.getValue().getSExtValue()); } else { RewriteDVIUsingIterCount(DVIRec, IterCountExpr, SE); } } } } /// Identify and cache salvageable DVI locations and expressions along with the /// corresponding SCEV(s). Also ensure that the DVI is not deleted between /// cacheing and salvaging. static void DbgGatherSalvagableDVI(Loop *L, ScalarEvolution &SE, SmallVector &SalvageableDVISCEVs, SmallSet, 2> &DVIHandles) { for (auto &B : L->getBlocks()) { for (auto &I : *B) { auto DVI = dyn_cast(&I); if (!DVI) continue; if (DVI->isUndef()) continue; if (DVI->hasArgList()) continue; if (!DVI->getVariableLocationOp(0) || !SE.isSCEVable(DVI->getVariableLocationOp(0)->getType())) continue; // SCEVUnknown wraps an llvm::Value, it does not have a start and stride. // Therefore no translation to DIExpression is performed. const SCEV *S = SE.getSCEV(DVI->getVariableLocationOp(0)); if (isa(S)) continue; // Avoid wasting resources generating an expression containing undef. if (SE.containsUndefs(S)) continue; SalvageableDVISCEVs.push_back( {DVI, DVI->getExpression(), DVI->getRawLocation(), SE.getSCEV(DVI->getVariableLocationOp(0))}); DVIHandles.insert(DVI); } } } /// Ideally pick the PHI IV inserted by ScalarEvolutionExpander. As a fallback /// any PHi from the loop header is usable, but may have less chance of /// surviving subsequent transforms. static llvm::PHINode *GetInductionVariable(const Loop &L, ScalarEvolution &SE, const LSRInstance &LSR) { auto IsSuitableIV = [&](PHINode *P) { if (!SE.isSCEVable(P->getType())) return false; if (const SCEVAddRecExpr *Rec = dyn_cast(SE.getSCEV(P))) return Rec->isAffine() && !SE.containsUndefs(SE.getSCEV(P)); return false; }; // For now, just pick the first IV that was generated and inserted by // ScalarEvolution. Ideally pick an IV that is unlikely to be optimised away // by subsequent transforms. for (const WeakVH &IV : LSR.getScalarEvolutionIVs()) { if (!IV) continue; // There should only be PHI node IVs. PHINode *P = cast(&*IV); if (IsSuitableIV(P)) return P; } for (PHINode &P : L.getHeader()->phis()) { if (IsSuitableIV(&P)) return &P; } return nullptr; } static bool ReduceLoopStrength(Loop *L, IVUsers &IU, ScalarEvolution &SE, DominatorTree &DT, LoopInfo &LI, const TargetTransformInfo &TTI, AssumptionCache &AC, TargetLibraryInfo &TLI, MemorySSA *MSSA) { // Debug preservation - before we start removing anything identify which DVI // meet the salvageable criteria and store their DIExpression and SCEVs. SmallVector SalvageableDVI; SmallSet, 2> DVIHandles; DbgGatherSalvagableDVI(L, SE, SalvageableDVI, DVIHandles); bool Changed = false; std::unique_ptr MSSAU; if (MSSA) MSSAU = std::make_unique(MSSA); // Run the main LSR transformation. const LSRInstance &Reducer = LSRInstance(L, IU, SE, DT, LI, TTI, AC, TLI, MSSAU.get()); Changed |= Reducer.getChanged(); // Remove any extra phis created by processing inner loops. Changed |= DeleteDeadPHIs(L->getHeader(), &TLI, MSSAU.get()); if (EnablePhiElim && L->isLoopSimplifyForm()) { SmallVector DeadInsts; const DataLayout &DL = L->getHeader()->getModule()->getDataLayout(); SCEVExpander Rewriter(SE, DL, "lsr", false); #ifndef NDEBUG Rewriter.setDebugType(DEBUG_TYPE); #endif unsigned numFolded = Rewriter.replaceCongruentIVs(L, &DT, DeadInsts, &TTI); if (numFolded) { Changed = true; RecursivelyDeleteTriviallyDeadInstructionsPermissive(DeadInsts, &TLI, MSSAU.get()); DeleteDeadPHIs(L->getHeader(), &TLI, MSSAU.get()); } } if (SalvageableDVI.empty()) return Changed; // Obtain relevant IVs and attempt to rewrite the salvageable DVIs with // expressions composed using the derived iteration count. // TODO: Allow for multiple IV references for nested AddRecSCEVs for (auto &L : LI) { if (llvm::PHINode *IV = GetInductionVariable(*L, SE, Reducer)) DbgRewriteSalvageableDVIs(L, SE, IV, SalvageableDVI); else { LLVM_DEBUG(dbgs() << "scev-salvage: SCEV salvaging not possible. An IV " "could not be identified.\n"); } } DVIHandles.clear(); return Changed; } bool LoopStrengthReduce::runOnLoop(Loop *L, LPPassManager & /*LPM*/) { if (skipLoop(L)) return false; auto &IU = getAnalysis().getIU(); auto &SE = getAnalysis().getSE(); auto &DT = getAnalysis().getDomTree(); auto &LI = getAnalysis().getLoopInfo(); const auto &TTI = getAnalysis().getTTI( *L->getHeader()->getParent()); auto &AC = getAnalysis().getAssumptionCache( *L->getHeader()->getParent()); auto &TLI = getAnalysis().getTLI( *L->getHeader()->getParent()); auto *MSSAAnalysis = getAnalysisIfAvailable(); MemorySSA *MSSA = nullptr; if (MSSAAnalysis) MSSA = &MSSAAnalysis->getMSSA(); return ReduceLoopStrength(L, IU, SE, DT, LI, TTI, AC, TLI, MSSA); } PreservedAnalyses LoopStrengthReducePass::run(Loop &L, LoopAnalysisManager &AM, LoopStandardAnalysisResults &AR, LPMUpdater &) { if (!ReduceLoopStrength(&L, AM.getResult(L, AR), AR.SE, AR.DT, AR.LI, AR.TTI, AR.AC, AR.TLI, AR.MSSA)) return PreservedAnalyses::all(); auto PA = getLoopPassPreservedAnalyses(); if (AR.MSSA) PA.preserve(); return PA; } char LoopStrengthReduce::ID = 0; INITIALIZE_PASS_BEGIN(LoopStrengthReduce, "loop-reduce", "Loop Strength Reduction", false, false) INITIALIZE_PASS_DEPENDENCY(TargetTransformInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) INITIALIZE_PASS_DEPENDENCY(ScalarEvolutionWrapperPass) INITIALIZE_PASS_DEPENDENCY(IVUsersWrapperPass) INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(LoopSimplify) INITIALIZE_PASS_END(LoopStrengthReduce, "loop-reduce", "Loop Strength Reduction", false, false) Pass *llvm::createLoopStrengthReducePass() { return new LoopStrengthReduce(); }