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mirror of https://github.com/RPCS3/llvm-mirror.git synced 2024-11-26 04:32:44 +01:00
llvm-mirror/include/llvm/Analysis/LoopAccessAnalysis.h
Nikita Popov 94c11807a4 [LAA] Make getPointersDiff() API compatible with opaque pointers
Make getPointersDiff() and sortPtrAccesses() compatible with opaque
pointers by explicitly passing in the element type instead of
determining it from the pointer element type.

The SLPVectorizer result is slightly non-optimal in that unnecessary
pointer bitcasts are added.

Differential Revision: https://reviews.llvm.org/D104784
2021-06-23 18:44:34 +02:00

784 lines
31 KiB
C++

//===- llvm/Analysis/LoopAccessAnalysis.h -----------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines the interface for the loop memory dependence framework that
// was originally developed for the Loop Vectorizer.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_ANALYSIS_LOOPACCESSANALYSIS_H
#define LLVM_ANALYSIS_LOOPACCESSANALYSIS_H
#include "llvm/ADT/EquivalenceClasses.h"
#include "llvm/Analysis/LoopAnalysisManager.h"
#include "llvm/Analysis/ScalarEvolutionExpressions.h"
#include "llvm/IR/DiagnosticInfo.h"
#include "llvm/Pass.h"
namespace llvm {
class AAResults;
class DataLayout;
class Loop;
class LoopAccessInfo;
class OptimizationRemarkEmitter;
class raw_ostream;
class SCEV;
class SCEVUnionPredicate;
class Value;
/// Collection of parameters shared beetween the Loop Vectorizer and the
/// Loop Access Analysis.
struct VectorizerParams {
/// Maximum SIMD width.
static const unsigned MaxVectorWidth;
/// VF as overridden by the user.
static unsigned VectorizationFactor;
/// Interleave factor as overridden by the user.
static unsigned VectorizationInterleave;
/// True if force-vector-interleave was specified by the user.
static bool isInterleaveForced();
/// \When performing memory disambiguation checks at runtime do not
/// make more than this number of comparisons.
static unsigned RuntimeMemoryCheckThreshold;
};
/// Checks memory dependences among accesses to the same underlying
/// object to determine whether there vectorization is legal or not (and at
/// which vectorization factor).
///
/// Note: This class will compute a conservative dependence for access to
/// different underlying pointers. Clients, such as the loop vectorizer, will
/// sometimes deal these potential dependencies by emitting runtime checks.
///
/// We use the ScalarEvolution framework to symbolically evalutate access
/// functions pairs. Since we currently don't restructure the loop we can rely
/// on the program order of memory accesses to determine their safety.
/// At the moment we will only deem accesses as safe for:
/// * A negative constant distance assuming program order.
///
/// Safe: tmp = a[i + 1]; OR a[i + 1] = x;
/// a[i] = tmp; y = a[i];
///
/// The latter case is safe because later checks guarantuee that there can't
/// be a cycle through a phi node (that is, we check that "x" and "y" is not
/// the same variable: a header phi can only be an induction or a reduction, a
/// reduction can't have a memory sink, an induction can't have a memory
/// source). This is important and must not be violated (or we have to
/// resort to checking for cycles through memory).
///
/// * A positive constant distance assuming program order that is bigger
/// than the biggest memory access.
///
/// tmp = a[i] OR b[i] = x
/// a[i+2] = tmp y = b[i+2];
///
/// Safe distance: 2 x sizeof(a[0]), and 2 x sizeof(b[0]), respectively.
///
/// * Zero distances and all accesses have the same size.
///
class MemoryDepChecker {
public:
typedef PointerIntPair<Value *, 1, bool> MemAccessInfo;
typedef SmallVector<MemAccessInfo, 8> MemAccessInfoList;
/// Set of potential dependent memory accesses.
typedef EquivalenceClasses<MemAccessInfo> DepCandidates;
/// Type to keep track of the status of the dependence check. The order of
/// the elements is important and has to be from most permissive to least
/// permissive.
enum class VectorizationSafetyStatus {
// Can vectorize safely without RT checks. All dependences are known to be
// safe.
Safe,
// Can possibly vectorize with RT checks to overcome unknown dependencies.
PossiblySafeWithRtChecks,
// Cannot vectorize due to known unsafe dependencies.
Unsafe,
};
/// Dependece between memory access instructions.
struct Dependence {
/// The type of the dependence.
enum DepType {
// No dependence.
NoDep,
// We couldn't determine the direction or the distance.
Unknown,
// Lexically forward.
//
// FIXME: If we only have loop-independent forward dependences (e.g. a
// read and write of A[i]), LAA will locally deem the dependence "safe"
// without querying the MemoryDepChecker. Therefore we can miss
// enumerating loop-independent forward dependences in
// getDependences. Note that as soon as there are different
// indices used to access the same array, the MemoryDepChecker *is*
// queried and the dependence list is complete.
Forward,
// Forward, but if vectorized, is likely to prevent store-to-load
// forwarding.
ForwardButPreventsForwarding,
// Lexically backward.
Backward,
// Backward, but the distance allows a vectorization factor of
// MaxSafeDepDistBytes.
BackwardVectorizable,
// Same, but may prevent store-to-load forwarding.
BackwardVectorizableButPreventsForwarding
};
/// String version of the types.
static const char *DepName[];
/// Index of the source of the dependence in the InstMap vector.
unsigned Source;
/// Index of the destination of the dependence in the InstMap vector.
unsigned Destination;
/// The type of the dependence.
DepType Type;
Dependence(unsigned Source, unsigned Destination, DepType Type)
: Source(Source), Destination(Destination), Type(Type) {}
/// Return the source instruction of the dependence.
Instruction *getSource(const LoopAccessInfo &LAI) const;
/// Return the destination instruction of the dependence.
Instruction *getDestination(const LoopAccessInfo &LAI) const;
/// Dependence types that don't prevent vectorization.
static VectorizationSafetyStatus isSafeForVectorization(DepType Type);
/// Lexically forward dependence.
bool isForward() const;
/// Lexically backward dependence.
bool isBackward() const;
/// May be a lexically backward dependence type (includes Unknown).
bool isPossiblyBackward() const;
/// Print the dependence. \p Instr is used to map the instruction
/// indices to instructions.
void print(raw_ostream &OS, unsigned Depth,
const SmallVectorImpl<Instruction *> &Instrs) const;
};
MemoryDepChecker(PredicatedScalarEvolution &PSE, const Loop *L)
: PSE(PSE), InnermostLoop(L), AccessIdx(0), MaxSafeDepDistBytes(0),
MaxSafeVectorWidthInBits(-1U),
FoundNonConstantDistanceDependence(false),
Status(VectorizationSafetyStatus::Safe), RecordDependences(true) {}
/// Register the location (instructions are given increasing numbers)
/// of a write access.
void addAccess(StoreInst *SI) {
Value *Ptr = SI->getPointerOperand();
Accesses[MemAccessInfo(Ptr, true)].push_back(AccessIdx);
InstMap.push_back(SI);
++AccessIdx;
}
/// Register the location (instructions are given increasing numbers)
/// of a write access.
void addAccess(LoadInst *LI) {
Value *Ptr = LI->getPointerOperand();
Accesses[MemAccessInfo(Ptr, false)].push_back(AccessIdx);
InstMap.push_back(LI);
++AccessIdx;
}
/// Check whether the dependencies between the accesses are safe.
///
/// Only checks sets with elements in \p CheckDeps.
bool areDepsSafe(DepCandidates &AccessSets, MemAccessInfoList &CheckDeps,
const ValueToValueMap &Strides);
/// No memory dependence was encountered that would inhibit
/// vectorization.
bool isSafeForVectorization() const {
return Status == VectorizationSafetyStatus::Safe;
}
/// Return true if the number of elements that are safe to operate on
/// simultaneously is not bounded.
bool isSafeForAnyVectorWidth() const {
return MaxSafeVectorWidthInBits == UINT_MAX;
}
/// The maximum number of bytes of a vector register we can vectorize
/// the accesses safely with.
uint64_t getMaxSafeDepDistBytes() { return MaxSafeDepDistBytes; }
/// Return the number of elements that are safe to operate on
/// simultaneously, multiplied by the size of the element in bits.
uint64_t getMaxSafeVectorWidthInBits() const {
return MaxSafeVectorWidthInBits;
}
/// In same cases when the dependency check fails we can still
/// vectorize the loop with a dynamic array access check.
bool shouldRetryWithRuntimeCheck() const {
return FoundNonConstantDistanceDependence &&
Status == VectorizationSafetyStatus::PossiblySafeWithRtChecks;
}
/// Returns the memory dependences. If null is returned we exceeded
/// the MaxDependences threshold and this information is not
/// available.
const SmallVectorImpl<Dependence> *getDependences() const {
return RecordDependences ? &Dependences : nullptr;
}
void clearDependences() { Dependences.clear(); }
/// The vector of memory access instructions. The indices are used as
/// instruction identifiers in the Dependence class.
const SmallVectorImpl<Instruction *> &getMemoryInstructions() const {
return InstMap;
}
/// Generate a mapping between the memory instructions and their
/// indices according to program order.
DenseMap<Instruction *, unsigned> generateInstructionOrderMap() const {
DenseMap<Instruction *, unsigned> OrderMap;
for (unsigned I = 0; I < InstMap.size(); ++I)
OrderMap[InstMap[I]] = I;
return OrderMap;
}
/// Find the set of instructions that read or write via \p Ptr.
SmallVector<Instruction *, 4> getInstructionsForAccess(Value *Ptr,
bool isWrite) const;
private:
/// A wrapper around ScalarEvolution, used to add runtime SCEV checks, and
/// applies dynamic knowledge to simplify SCEV expressions and convert them
/// to a more usable form. We need this in case assumptions about SCEV
/// expressions need to be made in order to avoid unknown dependences. For
/// example we might assume a unit stride for a pointer in order to prove
/// that a memory access is strided and doesn't wrap.
PredicatedScalarEvolution &PSE;
const Loop *InnermostLoop;
/// Maps access locations (ptr, read/write) to program order.
DenseMap<MemAccessInfo, std::vector<unsigned> > Accesses;
/// Memory access instructions in program order.
SmallVector<Instruction *, 16> InstMap;
/// The program order index to be used for the next instruction.
unsigned AccessIdx;
// We can access this many bytes in parallel safely.
uint64_t MaxSafeDepDistBytes;
/// Number of elements (from consecutive iterations) that are safe to
/// operate on simultaneously, multiplied by the size of the element in bits.
/// The size of the element is taken from the memory access that is most
/// restrictive.
uint64_t MaxSafeVectorWidthInBits;
/// If we see a non-constant dependence distance we can still try to
/// vectorize this loop with runtime checks.
bool FoundNonConstantDistanceDependence;
/// Result of the dependence checks, indicating whether the checked
/// dependences are safe for vectorization, require RT checks or are known to
/// be unsafe.
VectorizationSafetyStatus Status;
//// True if Dependences reflects the dependences in the
//// loop. If false we exceeded MaxDependences and
//// Dependences is invalid.
bool RecordDependences;
/// Memory dependences collected during the analysis. Only valid if
/// RecordDependences is true.
SmallVector<Dependence, 8> Dependences;
/// Check whether there is a plausible dependence between the two
/// accesses.
///
/// Access \p A must happen before \p B in program order. The two indices
/// identify the index into the program order map.
///
/// This function checks whether there is a plausible dependence (or the
/// absence of such can't be proved) between the two accesses. If there is a
/// plausible dependence but the dependence distance is bigger than one
/// element access it records this distance in \p MaxSafeDepDistBytes (if this
/// distance is smaller than any other distance encountered so far).
/// Otherwise, this function returns true signaling a possible dependence.
Dependence::DepType isDependent(const MemAccessInfo &A, unsigned AIdx,
const MemAccessInfo &B, unsigned BIdx,
const ValueToValueMap &Strides);
/// Check whether the data dependence could prevent store-load
/// forwarding.
///
/// \return false if we shouldn't vectorize at all or avoid larger
/// vectorization factors by limiting MaxSafeDepDistBytes.
bool couldPreventStoreLoadForward(uint64_t Distance, uint64_t TypeByteSize);
/// Updates the current safety status with \p S. We can go from Safe to
/// either PossiblySafeWithRtChecks or Unsafe and from
/// PossiblySafeWithRtChecks to Unsafe.
void mergeInStatus(VectorizationSafetyStatus S);
};
class RuntimePointerChecking;
/// A grouping of pointers. A single memcheck is required between
/// two groups.
struct RuntimeCheckingPtrGroup {
/// Create a new pointer checking group containing a single
/// pointer, with index \p Index in RtCheck.
RuntimeCheckingPtrGroup(unsigned Index, RuntimePointerChecking &RtCheck);
/// Tries to add the pointer recorded in RtCheck at index
/// \p Index to this pointer checking group. We can only add a pointer
/// to a checking group if we will still be able to get
/// the upper and lower bounds of the check. Returns true in case
/// of success, false otherwise.
bool addPointer(unsigned Index);
/// Constitutes the context of this pointer checking group. For each
/// pointer that is a member of this group we will retain the index
/// at which it appears in RtCheck.
RuntimePointerChecking &RtCheck;
/// The SCEV expression which represents the upper bound of all the
/// pointers in this group.
const SCEV *High;
/// The SCEV expression which represents the lower bound of all the
/// pointers in this group.
const SCEV *Low;
/// Indices of all the pointers that constitute this grouping.
SmallVector<unsigned, 2> Members;
};
/// A memcheck which made up of a pair of grouped pointers.
typedef std::pair<const RuntimeCheckingPtrGroup *,
const RuntimeCheckingPtrGroup *>
RuntimePointerCheck;
/// Holds information about the memory runtime legality checks to verify
/// that a group of pointers do not overlap.
class RuntimePointerChecking {
friend struct RuntimeCheckingPtrGroup;
public:
struct PointerInfo {
/// Holds the pointer value that we need to check.
TrackingVH<Value> PointerValue;
/// Holds the smallest byte address accessed by the pointer throughout all
/// iterations of the loop.
const SCEV *Start;
/// Holds the largest byte address accessed by the pointer throughout all
/// iterations of the loop, plus 1.
const SCEV *End;
/// Holds the information if this pointer is used for writing to memory.
bool IsWritePtr;
/// Holds the id of the set of pointers that could be dependent because of a
/// shared underlying object.
unsigned DependencySetId;
/// Holds the id of the disjoint alias set to which this pointer belongs.
unsigned AliasSetId;
/// SCEV for the access.
const SCEV *Expr;
PointerInfo(Value *PointerValue, const SCEV *Start, const SCEV *End,
bool IsWritePtr, unsigned DependencySetId, unsigned AliasSetId,
const SCEV *Expr)
: PointerValue(PointerValue), Start(Start), End(End),
IsWritePtr(IsWritePtr), DependencySetId(DependencySetId),
AliasSetId(AliasSetId), Expr(Expr) {}
};
RuntimePointerChecking(ScalarEvolution *SE) : Need(false), SE(SE) {}
/// Reset the state of the pointer runtime information.
void reset() {
Need = false;
Pointers.clear();
Checks.clear();
}
/// Insert a pointer and calculate the start and end SCEVs.
/// We need \p PSE in order to compute the SCEV expression of the pointer
/// according to the assumptions that we've made during the analysis.
/// The method might also version the pointer stride according to \p Strides,
/// and add new predicates to \p PSE.
void insert(Loop *Lp, Value *Ptr, bool WritePtr, unsigned DepSetId,
unsigned ASId, const ValueToValueMap &Strides,
PredicatedScalarEvolution &PSE);
/// No run-time memory checking is necessary.
bool empty() const { return Pointers.empty(); }
/// Generate the checks and store it. This also performs the grouping
/// of pointers to reduce the number of memchecks necessary.
void generateChecks(MemoryDepChecker::DepCandidates &DepCands,
bool UseDependencies);
/// Returns the checks that generateChecks created.
const SmallVectorImpl<RuntimePointerCheck> &getChecks() const {
return Checks;
}
/// Decide if we need to add a check between two groups of pointers,
/// according to needsChecking.
bool needsChecking(const RuntimeCheckingPtrGroup &M,
const RuntimeCheckingPtrGroup &N) const;
/// Returns the number of run-time checks required according to
/// needsChecking.
unsigned getNumberOfChecks() const { return Checks.size(); }
/// Print the list run-time memory checks necessary.
void print(raw_ostream &OS, unsigned Depth = 0) const;
/// Print \p Checks.
void printChecks(raw_ostream &OS,
const SmallVectorImpl<RuntimePointerCheck> &Checks,
unsigned Depth = 0) const;
/// This flag indicates if we need to add the runtime check.
bool Need;
/// Information about the pointers that may require checking.
SmallVector<PointerInfo, 2> Pointers;
/// Holds a partitioning of pointers into "check groups".
SmallVector<RuntimeCheckingPtrGroup, 2> CheckingGroups;
/// Check if pointers are in the same partition
///
/// \p PtrToPartition contains the partition number for pointers (-1 if the
/// pointer belongs to multiple partitions).
static bool
arePointersInSamePartition(const SmallVectorImpl<int> &PtrToPartition,
unsigned PtrIdx1, unsigned PtrIdx2);
/// Decide whether we need to issue a run-time check for pointer at
/// index \p I and \p J to prove their independence.
bool needsChecking(unsigned I, unsigned J) const;
/// Return PointerInfo for pointer at index \p PtrIdx.
const PointerInfo &getPointerInfo(unsigned PtrIdx) const {
return Pointers[PtrIdx];
}
ScalarEvolution *getSE() const { return SE; }
private:
/// Groups pointers such that a single memcheck is required
/// between two different groups. This will clear the CheckingGroups vector
/// and re-compute it. We will only group dependecies if \p UseDependencies
/// is true, otherwise we will create a separate group for each pointer.
void groupChecks(MemoryDepChecker::DepCandidates &DepCands,
bool UseDependencies);
/// Generate the checks and return them.
SmallVector<RuntimePointerCheck, 4> generateChecks() const;
/// Holds a pointer to the ScalarEvolution analysis.
ScalarEvolution *SE;
/// Set of run-time checks required to establish independence of
/// otherwise may-aliasing pointers in the loop.
SmallVector<RuntimePointerCheck, 4> Checks;
};
/// Drive the analysis of memory accesses in the loop
///
/// This class is responsible for analyzing the memory accesses of a loop. It
/// collects the accesses and then its main helper the AccessAnalysis class
/// finds and categorizes the dependences in buildDependenceSets.
///
/// For memory dependences that can be analyzed at compile time, it determines
/// whether the dependence is part of cycle inhibiting vectorization. This work
/// is delegated to the MemoryDepChecker class.
///
/// For memory dependences that cannot be determined at compile time, it
/// generates run-time checks to prove independence. This is done by
/// AccessAnalysis::canCheckPtrAtRT and the checks are maintained by the
/// RuntimePointerCheck class.
///
/// If pointers can wrap or can't be expressed as affine AddRec expressions by
/// ScalarEvolution, we will generate run-time checks by emitting a
/// SCEVUnionPredicate.
///
/// Checks for both memory dependences and the SCEV predicates contained in the
/// PSE must be emitted in order for the results of this analysis to be valid.
class LoopAccessInfo {
public:
LoopAccessInfo(Loop *L, ScalarEvolution *SE, const TargetLibraryInfo *TLI,
AAResults *AA, DominatorTree *DT, LoopInfo *LI);
/// Return true we can analyze the memory accesses in the loop and there are
/// no memory dependence cycles.
bool canVectorizeMemory() const { return CanVecMem; }
/// Return true if there is a convergent operation in the loop. There may
/// still be reported runtime pointer checks that would be required, but it is
/// not legal to insert them.
bool hasConvergentOp() const { return HasConvergentOp; }
const RuntimePointerChecking *getRuntimePointerChecking() const {
return PtrRtChecking.get();
}
/// Number of memchecks required to prove independence of otherwise
/// may-alias pointers.
unsigned getNumRuntimePointerChecks() const {
return PtrRtChecking->getNumberOfChecks();
}
/// Return true if the block BB needs to be predicated in order for the loop
/// to be vectorized.
static bool blockNeedsPredication(BasicBlock *BB, Loop *TheLoop,
DominatorTree *DT);
/// Returns true if the value V is uniform within the loop.
bool isUniform(Value *V) const;
uint64_t getMaxSafeDepDistBytes() const { return MaxSafeDepDistBytes; }
unsigned getNumStores() const { return NumStores; }
unsigned getNumLoads() const { return NumLoads;}
/// The diagnostics report generated for the analysis. E.g. why we
/// couldn't analyze the loop.
const OptimizationRemarkAnalysis *getReport() const { return Report.get(); }
/// the Memory Dependence Checker which can determine the
/// loop-independent and loop-carried dependences between memory accesses.
const MemoryDepChecker &getDepChecker() const { return *DepChecker; }
/// Return the list of instructions that use \p Ptr to read or write
/// memory.
SmallVector<Instruction *, 4> getInstructionsForAccess(Value *Ptr,
bool isWrite) const {
return DepChecker->getInstructionsForAccess(Ptr, isWrite);
}
/// If an access has a symbolic strides, this maps the pointer value to
/// the stride symbol.
const ValueToValueMap &getSymbolicStrides() const { return SymbolicStrides; }
/// Pointer has a symbolic stride.
bool hasStride(Value *V) const { return StrideSet.count(V); }
/// Print the information about the memory accesses in the loop.
void print(raw_ostream &OS, unsigned Depth = 0) const;
/// If the loop has memory dependence involving an invariant address, i.e. two
/// stores or a store and a load, then return true, else return false.
bool hasDependenceInvolvingLoopInvariantAddress() const {
return HasDependenceInvolvingLoopInvariantAddress;
}
/// Used to add runtime SCEV checks. Simplifies SCEV expressions and converts
/// them to a more usable form. All SCEV expressions during the analysis
/// should be re-written (and therefore simplified) according to PSE.
/// A user of LoopAccessAnalysis will need to emit the runtime checks
/// associated with this predicate.
const PredicatedScalarEvolution &getPSE() const { return *PSE; }
private:
/// Analyze the loop.
void analyzeLoop(AAResults *AA, LoopInfo *LI,
const TargetLibraryInfo *TLI, DominatorTree *DT);
/// Check if the structure of the loop allows it to be analyzed by this
/// pass.
bool canAnalyzeLoop();
/// Save the analysis remark.
///
/// LAA does not directly emits the remarks. Instead it stores it which the
/// client can retrieve and presents as its own analysis
/// (e.g. -Rpass-analysis=loop-vectorize).
OptimizationRemarkAnalysis &recordAnalysis(StringRef RemarkName,
Instruction *Instr = nullptr);
/// Collect memory access with loop invariant strides.
///
/// Looks for accesses like "a[i * StrideA]" where "StrideA" is loop
/// invariant.
void collectStridedAccess(Value *LoadOrStoreInst);
std::unique_ptr<PredicatedScalarEvolution> PSE;
/// We need to check that all of the pointers in this list are disjoint
/// at runtime. Using std::unique_ptr to make using move ctor simpler.
std::unique_ptr<RuntimePointerChecking> PtrRtChecking;
/// the Memory Dependence Checker which can determine the
/// loop-independent and loop-carried dependences between memory accesses.
std::unique_ptr<MemoryDepChecker> DepChecker;
Loop *TheLoop;
unsigned NumLoads;
unsigned NumStores;
uint64_t MaxSafeDepDistBytes;
/// Cache the result of analyzeLoop.
bool CanVecMem;
bool HasConvergentOp;
/// Indicator that there are non vectorizable stores to a uniform address.
bool HasDependenceInvolvingLoopInvariantAddress;
/// The diagnostics report generated for the analysis. E.g. why we
/// couldn't analyze the loop.
std::unique_ptr<OptimizationRemarkAnalysis> Report;
/// If an access has a symbolic strides, this maps the pointer value to
/// the stride symbol.
ValueToValueMap SymbolicStrides;
/// Set of symbolic strides values.
SmallPtrSet<Value *, 8> StrideSet;
};
Value *stripIntegerCast(Value *V);
/// Return the SCEV corresponding to a pointer with the symbolic stride
/// replaced with constant one, assuming the SCEV predicate associated with
/// \p PSE is true.
///
/// If necessary this method will version the stride of the pointer according
/// to \p PtrToStride and therefore add further predicates to \p PSE.
///
/// If \p OrigPtr is not null, use it to look up the stride value instead of \p
/// Ptr. \p PtrToStride provides the mapping between the pointer value and its
/// stride as collected by LoopVectorizationLegality::collectStridedAccess.
const SCEV *replaceSymbolicStrideSCEV(PredicatedScalarEvolution &PSE,
const ValueToValueMap &PtrToStride,
Value *Ptr, Value *OrigPtr = nullptr);
/// If the pointer has a constant stride return it in units of its
/// element size. Otherwise return zero.
///
/// Ensure that it does not wrap in the address space, assuming the predicate
/// associated with \p PSE is true.
///
/// If necessary this method will version the stride of the pointer according
/// to \p PtrToStride and therefore add further predicates to \p PSE.
/// The \p Assume parameter indicates if we are allowed to make additional
/// run-time assumptions.
int64_t getPtrStride(PredicatedScalarEvolution &PSE, Value *Ptr, const Loop *Lp,
const ValueToValueMap &StridesMap = ValueToValueMap(),
bool Assume = false, bool ShouldCheckWrap = true);
/// Returns the distance between the pointers \p PtrA and \p PtrB iff they are
/// compatible and it is possible to calculate the distance between them. This
/// is a simple API that does not depend on the analysis pass.
/// \param StrictCheck Ensure that the calculated distance matches the
/// type-based one after all the bitcasts removal in the provided pointers.
Optional<int> getPointersDiff(Type *ElemTyA, Value *PtrA, Type *ElemTyB,
Value *PtrB, const DataLayout &DL,
ScalarEvolution &SE, bool StrictCheck = false,
bool CheckType = true);
/// Attempt to sort the pointers in \p VL and return the sorted indices
/// in \p SortedIndices, if reordering is required.
///
/// Returns 'true' if sorting is legal, otherwise returns 'false'.
///
/// For example, for a given \p VL of memory accesses in program order, a[i+4],
/// a[i+0], a[i+1] and a[i+7], this function will sort the \p VL and save the
/// sorted indices in \p SortedIndices as a[i+0], a[i+1], a[i+4], a[i+7] and
/// saves the mask for actual memory accesses in program order in
/// \p SortedIndices as <1,2,0,3>
bool sortPtrAccesses(ArrayRef<Value *> VL, Type *ElemTy, const DataLayout &DL,
ScalarEvolution &SE,
SmallVectorImpl<unsigned> &SortedIndices);
/// Returns true if the memory operations \p A and \p B are consecutive.
/// This is a simple API that does not depend on the analysis pass.
bool isConsecutiveAccess(Value *A, Value *B, const DataLayout &DL,
ScalarEvolution &SE, bool CheckType = true);
/// This analysis provides dependence information for the memory accesses
/// of a loop.
///
/// It runs the analysis for a loop on demand. This can be initiated by
/// querying the loop access info via LAA::getInfo. getInfo return a
/// LoopAccessInfo object. See this class for the specifics of what information
/// is provided.
class LoopAccessLegacyAnalysis : public FunctionPass {
public:
static char ID;
LoopAccessLegacyAnalysis();
bool runOnFunction(Function &F) override;
void getAnalysisUsage(AnalysisUsage &AU) const override;
/// Query the result of the loop access information for the loop \p L.
///
/// If there is no cached result available run the analysis.
const LoopAccessInfo &getInfo(Loop *L);
void releaseMemory() override {
// Invalidate the cache when the pass is freed.
LoopAccessInfoMap.clear();
}
/// Print the result of the analysis when invoked with -analyze.
void print(raw_ostream &OS, const Module *M = nullptr) const override;
private:
/// The cache.
DenseMap<Loop *, std::unique_ptr<LoopAccessInfo>> LoopAccessInfoMap;
// The used analysis passes.
ScalarEvolution *SE = nullptr;
const TargetLibraryInfo *TLI = nullptr;
AAResults *AA = nullptr;
DominatorTree *DT = nullptr;
LoopInfo *LI = nullptr;
};
/// This analysis provides dependence information for the memory
/// accesses of a loop.
///
/// It runs the analysis for a loop on demand. This can be initiated by
/// querying the loop access info via AM.getResult<LoopAccessAnalysis>.
/// getResult return a LoopAccessInfo object. See this class for the
/// specifics of what information is provided.
class LoopAccessAnalysis
: public AnalysisInfoMixin<LoopAccessAnalysis> {
friend AnalysisInfoMixin<LoopAccessAnalysis>;
static AnalysisKey Key;
public:
typedef LoopAccessInfo Result;
Result run(Loop &L, LoopAnalysisManager &AM, LoopStandardAnalysisResults &AR);
};
inline Instruction *MemoryDepChecker::Dependence::getSource(
const LoopAccessInfo &LAI) const {
return LAI.getDepChecker().getMemoryInstructions()[Source];
}
inline Instruction *MemoryDepChecker::Dependence::getDestination(
const LoopAccessInfo &LAI) const {
return LAI.getDepChecker().getMemoryInstructions()[Destination];
}
} // End llvm namespace
#endif