//===- VPlanHelpers.h - VPlan-related auxiliary helpers -------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // /// \file /// This file contains the declarations of different VPlan-related auxiliary /// helpers. // //===----------------------------------------------------------------------===// #ifndef LLVM_TRANSFORMS_VECTORIZE_VPLANHELPERS_H #define LLVM_TRANSFORMS_VECTORIZE_VPLANHELPERS_H #include "VPlanAnalysis.h" #include "VPlanDominatorTree.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Analysis/DomTreeUpdater.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/IR/DebugLoc.h" #include "llvm/IR/ModuleSlotTracker.h" #include "llvm/Support/InstructionCost.h" namespace llvm { class AssumptionCache; class BasicBlock; class DominatorTree; class InnerLoopVectorizer; class IRBuilderBase; class LoopInfo; class SCEV; class Type; class VPBasicBlock; class VPRegionBlock; class VPlan; class Value; /// Returns a calculation for the total number of elements for a given \p VF. /// For fixed width vectors this value is a constant, whereas for scalable /// vectors it is an expression determined at runtime. Value *getRuntimeVF(IRBuilderBase &B, Type *Ty, ElementCount VF); /// Return a value for Step multiplied by VF. Value *createStepForVF(IRBuilderBase &B, Type *Ty, ElementCount VF, int64_t Step); /// A helper function that returns how much we should divide the cost of a /// predicated block by. Typically this is the reciprocal of the block /// probability, i.e. if we return X we are assuming the predicated block will /// execute once for every X iterations of the loop header so the block should /// only contribute 1/X of its cost to the total cost calculation, but when /// optimizing for code size it will just be 1 as code size costs don't depend /// on execution probabilities. /// /// TODO: We should use actual block probability here, if available. Currently, /// we always assume predicated blocks have a 50% chance of executing. inline unsigned getPredBlockCostDivisor(TargetTransformInfo::TargetCostKind CostKind) { return CostKind == TTI::TCK_CodeSize ? 1 : 2; } /// A range of powers-of-2 vectorization factors with fixed start and /// adjustable end. The range includes start and excludes end, e.g.,: /// [1, 16) = {1, 2, 4, 8} struct VFRange { // A power of 2. const ElementCount Start; // A power of 2. If End <= Start range is empty. ElementCount End; bool isEmpty() const { return End.getKnownMinValue() <= Start.getKnownMinValue(); } VFRange(const ElementCount &Start, const ElementCount &End) : Start(Start), End(End) { assert(Start.isScalable() == End.isScalable() && "Both Start and End should have the same scalable flag"); assert(isPowerOf2_32(Start.getKnownMinValue()) && "Expected Start to be a power of 2"); assert(isPowerOf2_32(End.getKnownMinValue()) && "Expected End to be a power of 2"); } /// Iterator to iterate over vectorization factors in a VFRange. class iterator : public iterator_facade_base { ElementCount VF; public: iterator(ElementCount VF) : VF(VF) {} bool operator==(const iterator &Other) const { return VF == Other.VF; } ElementCount operator*() const { return VF; } iterator &operator++() { VF *= 2; return *this; } }; iterator begin() { return iterator(Start); } iterator end() { assert(isPowerOf2_32(End.getKnownMinValue())); return iterator(End); } }; /// In what follows, the term "input IR" refers to code that is fed into the /// vectorizer whereas the term "output IR" refers to code that is generated by /// the vectorizer. /// VPLane provides a way to access lanes in both fixed width and scalable /// vectors, where for the latter the lane index sometimes needs calculating /// as a runtime expression. class VPLane { public: /// Kind describes how to interpret Lane. enum class Kind : uint8_t { /// For First, Lane is the index into the first N elements of a /// fixed-vector > or a scalable vector >. First, /// For ScalableLast, Lane is the offset from the start of the last /// N-element subvector in a scalable vector >. For /// example, a Lane of 0 corresponds to lane `(vscale - 1) * N`, a Lane of /// 1 corresponds to `((vscale - 1) * N) + 1`, etc. ScalableLast }; private: /// in [0..VF) unsigned Lane; /// Indicates how the Lane should be interpreted, as described above. Kind LaneKind = Kind::First; public: VPLane(unsigned Lane) : Lane(Lane) {} VPLane(unsigned Lane, Kind LaneKind) : Lane(Lane), LaneKind(LaneKind) {} static VPLane getFirstLane() { return VPLane(0, VPLane::Kind::First); } static VPLane getLaneFromEnd(const ElementCount &VF, unsigned Offset) { assert(Offset > 0 && Offset <= VF.getKnownMinValue() && "trying to extract with invalid offset"); unsigned LaneOffset = VF.getKnownMinValue() - Offset; Kind LaneKind; if (VF.isScalable()) // In this case 'LaneOffset' refers to the offset from the start of the // last subvector with VF.getKnownMinValue() elements. LaneKind = VPLane::Kind::ScalableLast; else LaneKind = VPLane::Kind::First; return VPLane(LaneOffset, LaneKind); } static VPLane getLastLaneForVF(const ElementCount &VF) { return getLaneFromEnd(VF, 1); } /// Returns a compile-time known value for the lane index and asserts if the /// lane can only be calculated at runtime. unsigned getKnownLane() const { assert(LaneKind == Kind::First && "can only get known lane from the beginning"); return Lane; } /// Returns an expression describing the lane index that can be used at /// runtime. Value *getAsRuntimeExpr(IRBuilderBase &Builder, const ElementCount &VF) const; /// Returns the Kind of lane offset. Kind getKind() const { return LaneKind; } /// Returns true if this is the first lane of the whole vector. bool isFirstLane() const { return Lane == 0 && LaneKind == Kind::First; } /// Maps the lane to a cache index based on \p VF. unsigned mapToCacheIndex(const ElementCount &VF) const { switch (LaneKind) { case VPLane::Kind::ScalableLast: assert(VF.isScalable() && Lane < VF.getKnownMinValue() && "ScalableLast can only be used with scalable VFs"); return VF.getKnownMinValue() + Lane; default: assert(Lane < VF.getKnownMinValue() && "Cannot extract lane larger than VF"); return Lane; } } }; /// VPTransformState holds information passed down when "executing" a VPlan, /// needed for generating the output IR. struct VPTransformState { VPTransformState(const TargetTransformInfo *TTI, ElementCount VF, LoopInfo *LI, DominatorTree *DT, AssumptionCache *AC, IRBuilderBase &Builder, VPlan *Plan, Loop *CurrentParentLoop, Type *CanonicalIVTy); /// Target Transform Info. const TargetTransformInfo *TTI; /// The chosen Vectorization Factor of the loop being vectorized. ElementCount VF; /// Hold the index to generate specific scalar instructions. Null indicates /// that all instances are to be generated, using either scalar or vector /// instructions. std::optional Lane; struct DataState { // Each value from the original loop, when vectorized, is represented by a // vector value in the map. DenseMap VPV2Vector; DenseMap> VPV2Scalars; } Data; /// Get the generated vector Value for a given VPValue \p Def if \p IsScalar /// is false, otherwise return the generated scalar. \See set. Value *get(const VPValue *Def, bool IsScalar = false); /// Get the generated Value for a given VPValue and given Part and Lane. Value *get(const VPValue *Def, const VPLane &Lane); bool hasVectorValue(const VPValue *Def) { return Data.VPV2Vector.contains(Def); } bool hasScalarValue(const VPValue *Def, VPLane Lane) { auto I = Data.VPV2Scalars.find(Def); if (I == Data.VPV2Scalars.end()) return false; unsigned CacheIdx = Lane.mapToCacheIndex(VF); return CacheIdx < I->second.size() && I->second[CacheIdx]; } /// Set the generated vector Value for a given VPValue, if \p /// IsScalar is false. If \p IsScalar is true, set the scalar in lane 0. void set(const VPValue *Def, Value *V, bool IsScalar = false) { if (IsScalar) { set(Def, V, VPLane(0)); return; } assert((VF.isScalar() || isVectorizedTy(V->getType())) && "scalar values must be stored as (0, 0)"); Data.VPV2Vector[Def] = V; } /// Reset an existing vector value for \p Def and a given \p Part. void reset(const VPValue *Def, Value *V) { assert(Data.VPV2Vector.contains(Def) && "need to overwrite existing value"); Data.VPV2Vector[Def] = V; } /// Set the generated scalar \p V for \p Def and the given \p Lane. void set(const VPValue *Def, Value *V, const VPLane &Lane) { auto &Scalars = Data.VPV2Scalars[Def]; unsigned CacheIdx = Lane.mapToCacheIndex(VF); if (Scalars.size() <= CacheIdx) Scalars.resize(CacheIdx + 1); assert(!Scalars[CacheIdx] && "should overwrite existing value"); Scalars[CacheIdx] = V; } /// Reset an existing scalar value for \p Def and a given \p Lane. void reset(const VPValue *Def, Value *V, const VPLane &Lane) { auto Iter = Data.VPV2Scalars.find(Def); assert(Iter != Data.VPV2Scalars.end() && "need to overwrite existing value"); unsigned CacheIdx = Lane.mapToCacheIndex(VF); assert(CacheIdx < Iter->second.size() && "need to overwrite existing value"); Iter->second[CacheIdx] = V; } /// Set the debug location in the builder using the debug location \p DL. void setDebugLocFrom(DebugLoc DL); /// Insert the scalar value of \p Def at \p Lane into \p Lane of \p WideValue /// and return the resulting value. Value *packScalarIntoVectorizedValue(const VPValue *Def, Value *WideValue, const VPLane &Lane); /// Hold state information used when constructing the CFG of the output IR, /// traversing the VPBasicBlocks and generating corresponding IR BasicBlocks. struct CFGState { /// The previous VPBasicBlock visited. Initially set to null. VPBasicBlock *PrevVPBB = nullptr; /// The previous IR BasicBlock created or used. Initially set to the new /// header BasicBlock. BasicBlock *PrevBB = nullptr; /// The last IR BasicBlock in the output IR. Set to the exit block of the /// vector loop. BasicBlock *ExitBB = nullptr; /// A mapping of each VPBasicBlock to the corresponding BasicBlock. In case /// of replication, maps the BasicBlock of the last replica created. SmallDenseMap VPBB2IRBB; /// Updater for the DominatorTree. DomTreeUpdater DTU; CFGState(DominatorTree *DT) : DTU(DT, DomTreeUpdater::UpdateStrategy::Lazy) {} } CFG; /// Hold a pointer to LoopInfo to register new basic blocks in the loop. LoopInfo *LI; /// Hold a pointer to AssumptionCache to register new assumptions after /// replicating assume calls. AssumptionCache *AC; /// Hold a reference to the IRBuilder used to generate output IR code. IRBuilderBase &Builder; /// Pointer to the VPlan code is generated for. VPlan *Plan; /// The parent loop object for the current scope, or nullptr. Loop *CurrentParentLoop = nullptr; /// VPlan-based type analysis. VPTypeAnalysis TypeAnalysis; /// VPlan-based dominator tree. VPDominatorTree VPDT; }; /// Struct to hold various analysis needed for cost computations. struct VPCostContext { const TargetTransformInfo &TTI; const TargetLibraryInfo &TLI; VPTypeAnalysis Types; LLVMContext &LLVMCtx; LoopVectorizationCostModel &CM; SmallPtrSet SkipCostComputation; TargetTransformInfo::TargetCostKind CostKind; VPCostContext(const TargetTransformInfo &TTI, const TargetLibraryInfo &TLI, Type *CanIVTy, LoopVectorizationCostModel &CM, TargetTransformInfo::TargetCostKind CostKind) : TTI(TTI), TLI(TLI), Types(CanIVTy), LLVMCtx(CanIVTy->getContext()), CM(CM), CostKind(CostKind) {} /// Return the cost for \p UI with \p VF using the legacy cost model as /// fallback until computing the cost of all recipes migrates to VPlan. InstructionCost getLegacyCost(Instruction *UI, ElementCount VF) const; /// Return true if the cost for \p UI shouldn't be computed, e.g. because it /// has already been pre-computed. bool skipCostComputation(Instruction *UI, bool IsVector) const; /// Returns the OperandInfo for \p V, if it is a live-in. TargetTransformInfo::OperandValueInfo getOperandInfo(VPValue *V) const; /// Return true if \p I is considered uniform-after-vectorization in the /// legacy cost model for \p VF. Only used to check for additional VPlan /// simplifications. bool isLegacyUniformAfterVectorization(Instruction *I, ElementCount VF) const; }; /// This class can be used to assign names to VPValues. For VPValues without /// underlying value, assign consecutive numbers and use those as names (wrapped /// in vp<>). Otherwise, use the name from the underlying value (wrapped in /// ir<>), appending a .V version number if there are multiple uses of the same /// name. Allows querying names for VPValues for printing, similar to the /// ModuleSlotTracker for IR values. class VPSlotTracker { /// Keep track of versioned names assigned to VPValues with underlying IR /// values. DenseMap VPValue2Name; /// Keep track of the next number to use to version the base name. StringMap BaseName2Version; /// Number to assign to the next VPValue without underlying value. unsigned NextSlot = 0; /// Lazily created ModuleSlotTracker, used only when unnamed IR instructions /// require slot tracking. std::unique_ptr MST; void assignName(const VPValue *V); void assignNames(const VPlan &Plan); void assignNames(const VPBasicBlock *VPBB); std::string getName(const Value *V); public: VPSlotTracker(const VPlan *Plan = nullptr) { if (Plan) assignNames(*Plan); } /// Returns the name assigned to \p V, if there is one, otherwise try to /// construct one from the underlying value, if there's one; else return /// . std::string getOrCreateName(const VPValue *V) const; }; #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) /// VPlanPrinter prints a given VPlan to a given output stream. The printing is /// indented and follows the dot format. class VPlanPrinter { raw_ostream &OS; const VPlan &Plan; unsigned Depth = 0; unsigned TabWidth = 2; std::string Indent; unsigned BID = 0; SmallDenseMap BlockID; VPSlotTracker SlotTracker; /// Handle indentation. void bumpIndent(int b) { Indent = std::string((Depth += b) * TabWidth, ' '); } /// Print a given \p Block of the Plan. void dumpBlock(const VPBlockBase *Block); /// Print the information related to the CFG edges going out of a given /// \p Block, followed by printing the successor blocks themselves. void dumpEdges(const VPBlockBase *Block); /// Print a given \p BasicBlock, including its VPRecipes, followed by printing /// its successor blocks. void dumpBasicBlock(const VPBasicBlock *BasicBlock); /// Print a given \p Region of the Plan. void dumpRegion(const VPRegionBlock *Region); unsigned getOrCreateBID(const VPBlockBase *Block) { return BlockID.count(Block) ? BlockID[Block] : BlockID[Block] = BID++; } Twine getOrCreateName(const VPBlockBase *Block); Twine getUID(const VPBlockBase *Block); /// Print the information related to a CFG edge between two VPBlockBases. void drawEdge(const VPBlockBase *From, const VPBlockBase *To, bool Hidden, const Twine &Label); public: VPlanPrinter(raw_ostream &O, const VPlan &P) : OS(O), Plan(P), SlotTracker(&P) {} LLVM_DUMP_METHOD void dump(); }; #endif } // end namespace llvm #endif // LLVM_TRANSFORMS_VECTORIZE_VPLAN_H