//===------ DeLICM.cpp -----------------------------------------*- 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 // //===----------------------------------------------------------------------===// // // Undo the effect of Loop Invariant Code Motion (LICM) and // GVN Partial Redundancy Elimination (PRE) on SCoP-level. // // Namely, remove register/scalar dependencies by mapping them back to array // elements. // //===----------------------------------------------------------------------===// #include "polly/DeLICM.h" #include "polly/LinkAllPasses.h" #include "polly/Options.h" #include "polly/ScopInfo.h" #include "polly/ScopPass.h" #include "polly/Support/GICHelper.h" #include "polly/Support/ISLOStream.h" #include "polly/Support/ISLTools.h" #include "polly/ZoneAlgo.h" #include "llvm/ADT/Statistic.h" #include "llvm/InitializePasses.h" #define DEBUG_TYPE "polly-delicm" using namespace polly; using namespace llvm; namespace { cl::opt DelicmMaxOps("polly-delicm-max-ops", cl::desc("Maximum number of isl operations to invest for " "lifetime analysis; 0=no limit"), cl::init(1000000), cl::cat(PollyCategory)); cl::opt DelicmOverapproximateWrites( "polly-delicm-overapproximate-writes", cl::desc( "Do more PHI writes than necessary in order to avoid partial accesses"), cl::init(false), cl::Hidden, cl::cat(PollyCategory)); cl::opt DelicmPartialWrites("polly-delicm-partial-writes", cl::desc("Allow partial writes"), cl::init(true), cl::Hidden, cl::cat(PollyCategory)); cl::opt DelicmComputeKnown("polly-delicm-compute-known", cl::desc("Compute known content of array elements"), cl::init(true), cl::Hidden, cl::cat(PollyCategory)); STATISTIC(DeLICMAnalyzed, "Number of successfully analyzed SCoPs"); STATISTIC(DeLICMOutOfQuota, "Analyses aborted because max_operations was reached"); STATISTIC(MappedValueScalars, "Number of mapped Value scalars"); STATISTIC(MappedPHIScalars, "Number of mapped PHI scalars"); STATISTIC(TargetsMapped, "Number of stores used for at least one mapping"); STATISTIC(DeLICMScopsModified, "Number of SCoPs optimized"); STATISTIC(NumValueWrites, "Number of scalar value writes after DeLICM"); STATISTIC(NumValueWritesInLoops, "Number of scalar value writes nested in affine loops after DeLICM"); STATISTIC(NumPHIWrites, "Number of scalar phi writes after DeLICM"); STATISTIC(NumPHIWritesInLoops, "Number of scalar phi writes nested in affine loops after DeLICM"); STATISTIC(NumSingletonWrites, "Number of singleton writes after DeLICM"); STATISTIC(NumSingletonWritesInLoops, "Number of singleton writes nested in affine loops after DeLICM"); isl::union_map computeReachingOverwrite(isl::union_map Schedule, isl::union_map Writes, bool InclPrevWrite, bool InclOverwrite) { return computeReachingWrite(Schedule, Writes, true, InclPrevWrite, InclOverwrite); } /// Compute the next overwrite for a scalar. /// /// @param Schedule { DomainWrite[] -> Scatter[] } /// Schedule of (at least) all writes. Instances not in @p /// Writes are ignored. /// @param Writes { DomainWrite[] } /// The element instances that write to the scalar. /// @param InclPrevWrite Whether to extend the timepoints to include /// the timepoint where the previous write happens. /// @param InclOverwrite Whether the reaching overwrite includes the timepoint /// of the overwrite itself. /// /// @return { Scatter[] -> DomainDef[] } isl::union_map computeScalarReachingOverwrite(isl::union_map Schedule, isl::union_set Writes, bool InclPrevWrite, bool InclOverwrite) { // { DomainWrite[] } auto WritesMap = isl::union_map::from_domain(Writes); // { [Element[] -> Scatter[]] -> DomainWrite[] } auto Result = computeReachingOverwrite( std::move(Schedule), std::move(WritesMap), InclPrevWrite, InclOverwrite); return Result.domain_factor_range(); } /// Overload of computeScalarReachingOverwrite, with only one writing statement. /// Consequently, the result consists of only one map space. /// /// @param Schedule { DomainWrite[] -> Scatter[] } /// @param Writes { DomainWrite[] } /// @param InclPrevWrite Include the previous write to result. /// @param InclOverwrite Include the overwrite to the result. /// /// @return { Scatter[] -> DomainWrite[] } isl::map computeScalarReachingOverwrite(isl::union_map Schedule, isl::set Writes, bool InclPrevWrite, bool InclOverwrite) { isl::space ScatterSpace = getScatterSpace(Schedule); isl::space DomSpace = Writes.get_space(); isl::union_map ReachOverwrite = computeScalarReachingOverwrite( Schedule, isl::union_set(Writes), InclPrevWrite, InclOverwrite); isl::space ResultSpace = ScatterSpace.map_from_domain_and_range(DomSpace); return singleton(std::move(ReachOverwrite), ResultSpace); } /// Try to find a 'natural' extension of a mapped to elements outside its /// domain. /// /// @param Relevant The map with mapping that may not be modified. /// @param Universe The domain to which @p Relevant needs to be extended. /// /// @return A map with that associates the domain elements of @p Relevant to the /// same elements and in addition the elements of @p Universe to some /// undefined elements. The function prefers to return simple maps. isl::union_map expandMapping(isl::union_map Relevant, isl::union_set Universe) { Relevant = Relevant.coalesce(); isl::union_set RelevantDomain = Relevant.domain(); isl::union_map Simplified = Relevant.gist_domain(RelevantDomain); Simplified = Simplified.coalesce(); return Simplified.intersect_domain(Universe); } /// Represent the knowledge of the contents of any array elements in any zone or /// the knowledge we would add when mapping a scalar to an array element. /// /// Every array element at every zone unit has one of two states: /// /// - Unused: Not occupied by any value so a transformation can change it to /// other values. /// /// - Occupied: The element contains a value that is still needed. /// /// The union of Unused and Unknown zones forms the universe, the set of all /// elements at every timepoint. The universe can easily be derived from the /// array elements that are accessed someway. Arrays that are never accessed /// also never play a role in any computation and can hence be ignored. With a /// given universe, only one of the sets needs to stored implicitly. Computing /// the complement is also an expensive operation, hence this class has been /// designed that only one of sets is needed while the other is assumed to be /// implicit. It can still be given, but is mostly ignored. /// /// There are two use cases for the Knowledge class: /// /// 1) To represent the knowledge of the current state of ScopInfo. The unused /// state means that an element is currently unused: there is no read of it /// before the next overwrite. Also called 'Existing'. /// /// 2) To represent the requirements for mapping a scalar to array elements. The /// unused state means that there is no change/requirement. Also called /// 'Proposed'. /// /// In addition to these states at unit zones, Knowledge needs to know when /// values are written. This is because written values may have no lifetime (one /// reason is that the value is never read). Such writes would therefore never /// conflict, but overwrite values that might still be required. Another source /// of problems are multiple writes to the same element at the same timepoint, /// because their order is undefined. class Knowledge { private: /// { [Element[] -> Zone[]] } /// Set of array elements and when they are alive. /// Can contain a nullptr; in this case the set is implicitly defined as the /// complement of #Unused. /// /// The set of alive array elements is represented as zone, as the set of live /// values can differ depending on how the elements are interpreted. /// Assuming a value X is written at timestep [0] and read at timestep [1] /// without being used at any later point, then the value is alive in the /// interval ]0,1[. This interval cannot be represented by an integer set, as /// it does not contain any integer point. Zones allow us to represent this /// interval and can be converted to sets of timepoints when needed (e.g., in /// isConflicting when comparing to the write sets). /// @see convertZoneToTimepoints and this file's comment for more details. isl::union_set Occupied; /// { [Element[] -> Zone[]] } /// Set of array elements when they are not alive, i.e. their memory can be /// used for other purposed. Can contain a nullptr; in this case the set is /// implicitly defined as the complement of #Occupied. isl::union_set Unused; /// { [Element[] -> Zone[]] -> ValInst[] } /// Maps to the known content for each array element at any interval. /// /// Any element/interval can map to multiple known elements. This is due to /// multiple llvm::Value referring to the same content. Examples are /// /// - A value stored and loaded again. The LoadInst represents the same value /// as the StoreInst's value operand. /// /// - A PHINode is equal to any one of the incoming values. In case of /// LCSSA-form, it is always equal to its single incoming value. /// /// Two Knowledges are considered not conflicting if at least one of the known /// values match. Not known values are not stored as an unnamed tuple (as /// #Written does), but maps to nothing. /// /// Known values are usually just defined for #Occupied elements. Knowing /// #Unused contents has no advantage as it can be overwritten. isl::union_map Known; /// { [Element[] -> Scatter[]] -> ValInst[] } /// The write actions currently in the scop or that would be added when /// mapping a scalar. Maps to the value that is written. /// /// Written values that cannot be identified are represented by an unknown /// ValInst[] (an unnamed tuple of 0 dimension). It conflicts with itself. isl::union_map Written; /// Check whether this Knowledge object is well-formed. void checkConsistency() const { #ifndef NDEBUG // Default-initialized object if (Occupied.is_null() && Unused.is_null() && Known.is_null() && Written.is_null()) return; assert(!Occupied.is_null() || !Unused.is_null()); assert(!Known.is_null()); assert(!Written.is_null()); // If not all fields are defined, we cannot derived the universe. if (Occupied.is_null() || Unused.is_null()) return; assert(Occupied.is_disjoint(Unused)); auto Universe = Occupied.unite(Unused); assert(!Known.domain().is_subset(Universe).is_false()); assert(!Written.domain().is_subset(Universe).is_false()); #endif } public: /// Initialize a nullptr-Knowledge. This is only provided for convenience; do /// not use such an object. Knowledge() {} /// Create a new object with the given members. Knowledge(isl::union_set Occupied, isl::union_set Unused, isl::union_map Known, isl::union_map Written) : Occupied(std::move(Occupied)), Unused(std::move(Unused)), Known(std::move(Known)), Written(std::move(Written)) { checkConsistency(); } /// Return whether this object was not default-constructed. bool isUsable() const { return (Occupied.is_null() || Unused.is_null()) && !Known.is_null() && !Written.is_null(); } /// Print the content of this object to @p OS. void print(llvm::raw_ostream &OS, unsigned Indent = 0) const { if (isUsable()) { if (!Occupied.is_null()) OS.indent(Indent) << "Occupied: " << Occupied << "\n"; else OS.indent(Indent) << "Occupied: \n"; if (!Unused.is_null()) OS.indent(Indent) << "Unused: " << Unused << "\n"; else OS.indent(Indent) << "Unused: \n"; OS.indent(Indent) << "Known: " << Known << "\n"; OS.indent(Indent) << "Written : " << Written << '\n'; } else { OS.indent(Indent) << "Invalid knowledge\n"; } } /// Combine two knowledges, this and @p That. void learnFrom(Knowledge That) { assert(!isConflicting(*this, That)); assert(!Unused.is_null() && !That.Occupied.is_null()); assert( That.Unused.is_null() && "This function is only prepared to learn occupied elements from That"); assert(Occupied.is_null() && "This function does not implement " "`this->Occupied = " "this->Occupied.unite(That.Occupied);`"); Unused = Unused.subtract(That.Occupied); Known = Known.unite(That.Known); Written = Written.unite(That.Written); checkConsistency(); } /// Determine whether two Knowledges conflict with each other. /// /// In theory @p Existing and @p Proposed are symmetric, but the /// implementation is constrained by the implicit interpretation. That is, @p /// Existing must have #Unused defined (use case 1) and @p Proposed must have /// #Occupied defined (use case 1). /// /// A conflict is defined as non-preserved semantics when they are merged. For /// instance, when for the same array and zone they assume different /// llvm::Values. /// /// @param Existing One of the knowledges with #Unused defined. /// @param Proposed One of the knowledges with #Occupied defined. /// @param OS Dump the conflict reason to this output stream; use /// nullptr to not output anything. /// @param Indent Indention for the conflict reason. /// /// @return True, iff the two knowledges are conflicting. static bool isConflicting(const Knowledge &Existing, const Knowledge &Proposed, llvm::raw_ostream *OS = nullptr, unsigned Indent = 0) { assert(!Existing.Unused.is_null()); assert(!Proposed.Occupied.is_null()); #ifndef NDEBUG if (!Existing.Occupied.is_null() && !Proposed.Unused.is_null()) { auto ExistingUniverse = Existing.Occupied.unite(Existing.Unused); auto ProposedUniverse = Proposed.Occupied.unite(Proposed.Unused); assert(ExistingUniverse.is_equal(ProposedUniverse) && "Both inputs' Knowledges must be over the same universe"); } #endif // Do the Existing and Proposed lifetimes conflict? // // Lifetimes are described as the cross-product of array elements and zone // intervals in which they are alive (the space { [Element[] -> Zone[]] }). // In the following we call this "element/lifetime interval". // // In order to not conflict, one of the following conditions must apply for // each element/lifetime interval: // // 1. If occupied in one of the knowledges, it is unused in the other. // // - or - // // 2. Both contain the same value. // // Instead of partitioning the element/lifetime intervals into a part that // both Knowledges occupy (which requires an expensive subtraction) and for // these to check whether they are known to be the same value, we check only // the second condition and ensure that it also applies when then first // condition is true. This is done by adding a wildcard value to // Proposed.Known and Existing.Unused such that they match as a common known // value. We use the "unknown ValInst" for this purpose. Every // Existing.Unused may match with an unknown Proposed.Occupied because these // never are in conflict with each other. auto ProposedOccupiedAnyVal = makeUnknownForDomain(Proposed.Occupied); auto ProposedValues = Proposed.Known.unite(ProposedOccupiedAnyVal); auto ExistingUnusedAnyVal = makeUnknownForDomain(Existing.Unused); auto ExistingValues = Existing.Known.unite(ExistingUnusedAnyVal); auto MatchingVals = ExistingValues.intersect(ProposedValues); auto Matches = MatchingVals.domain(); // Any Proposed.Occupied must either have a match between the known values // of Existing and Occupied, or be in Existing.Unused. In the latter case, // the previously added "AnyVal" will match each other. if (!Proposed.Occupied.is_subset(Matches)) { if (OS) { auto Conflicting = Proposed.Occupied.subtract(Matches); auto ExistingConflictingKnown = Existing.Known.intersect_domain(Conflicting); auto ProposedConflictingKnown = Proposed.Known.intersect_domain(Conflicting); OS->indent(Indent) << "Proposed lifetime conflicting with Existing's\n"; OS->indent(Indent) << "Conflicting occupied: " << Conflicting << "\n"; if (!ExistingConflictingKnown.is_empty()) OS->indent(Indent) << "Existing Known: " << ExistingConflictingKnown << "\n"; if (!ProposedConflictingKnown.is_empty()) OS->indent(Indent) << "Proposed Known: " << ProposedConflictingKnown << "\n"; } return true; } // Do the writes in Existing conflict with occupied values in Proposed? // // In order to not conflict, it must either write to unused lifetime or // write the same value. To check, we remove the writes that write into // Proposed.Unused (they never conflict) and then see whether the written // value is already in Proposed.Known. If there are multiple known values // and a written value is known under different names, it is enough when one // of the written values (assuming that they are the same value under // different names, e.g. a PHINode and one of the incoming values) matches // one of the known names. // // We convert here the set of lifetimes to actual timepoints. A lifetime is // in conflict with a set of write timepoints, if either a live timepoint is // clearly within the lifetime or if a write happens at the beginning of the // lifetime (where it would conflict with the value that actually writes the // value alive). There is no conflict at the end of a lifetime, as the alive // value will always be read, before it is overwritten again. The last // property holds in Polly for all scalar values and we expect all users of // Knowledge to check this property also for accesses to MemoryKind::Array. auto ProposedFixedDefs = convertZoneToTimepoints(Proposed.Occupied, true, false); auto ProposedFixedKnown = convertZoneToTimepoints(Proposed.Known, isl::dim::in, true, false); auto ExistingConflictingWrites = Existing.Written.intersect_domain(ProposedFixedDefs); auto ExistingConflictingWritesDomain = ExistingConflictingWrites.domain(); auto CommonWrittenVal = ProposedFixedKnown.intersect(ExistingConflictingWrites); auto CommonWrittenValDomain = CommonWrittenVal.domain(); if (!ExistingConflictingWritesDomain.is_subset(CommonWrittenValDomain)) { if (OS) { auto ExistingConflictingWritten = ExistingConflictingWrites.subtract_domain(CommonWrittenValDomain); auto ProposedConflictingKnown = ProposedFixedKnown.subtract_domain( ExistingConflictingWritten.domain()); OS->indent(Indent) << "Proposed a lifetime where there is an Existing write into it\n"; OS->indent(Indent) << "Existing conflicting writes: " << ExistingConflictingWritten << "\n"; if (!ProposedConflictingKnown.is_empty()) OS->indent(Indent) << "Proposed conflicting known: " << ProposedConflictingKnown << "\n"; } return true; } // Do the writes in Proposed conflict with occupied values in Existing? auto ExistingAvailableDefs = convertZoneToTimepoints(Existing.Unused, true, false); auto ExistingKnownDefs = convertZoneToTimepoints(Existing.Known, isl::dim::in, true, false); auto ProposedWrittenDomain = Proposed.Written.domain(); auto KnownIdentical = ExistingKnownDefs.intersect(Proposed.Written); auto IdenticalOrUnused = ExistingAvailableDefs.unite(KnownIdentical.domain()); if (!ProposedWrittenDomain.is_subset(IdenticalOrUnused)) { if (OS) { auto Conflicting = ProposedWrittenDomain.subtract(IdenticalOrUnused); auto ExistingConflictingKnown = ExistingKnownDefs.intersect_domain(Conflicting); auto ProposedConflictingWritten = Proposed.Written.intersect_domain(Conflicting); OS->indent(Indent) << "Proposed writes into range used by Existing\n"; OS->indent(Indent) << "Proposed conflicting writes: " << ProposedConflictingWritten << "\n"; if (!ExistingConflictingKnown.is_empty()) OS->indent(Indent) << "Existing conflicting known: " << ExistingConflictingKnown << "\n"; } return true; } // Does Proposed write at the same time as Existing already does (order of // writes is undefined)? Writing the same value is permitted. auto ExistingWrittenDomain = Existing.Written.domain(); auto BothWritten = Existing.Written.domain().intersect(Proposed.Written.domain()); auto ExistingKnownWritten = filterKnownValInst(Existing.Written); auto ProposedKnownWritten = filterKnownValInst(Proposed.Written); auto CommonWritten = ExistingKnownWritten.intersect(ProposedKnownWritten).domain(); if (!BothWritten.is_subset(CommonWritten)) { if (OS) { auto Conflicting = BothWritten.subtract(CommonWritten); auto ExistingConflictingWritten = Existing.Written.intersect_domain(Conflicting); auto ProposedConflictingWritten = Proposed.Written.intersect_domain(Conflicting); OS->indent(Indent) << "Proposed writes at the same time as an already " "Existing write\n"; OS->indent(Indent) << "Conflicting writes: " << Conflicting << "\n"; if (!ExistingConflictingWritten.is_empty()) OS->indent(Indent) << "Exiting write: " << ExistingConflictingWritten << "\n"; if (!ProposedConflictingWritten.is_empty()) OS->indent(Indent) << "Proposed write: " << ProposedConflictingWritten << "\n"; } return true; } return false; } }; /// Implementation of the DeLICM/DePRE transformation. class DeLICMImpl : public ZoneAlgorithm { private: /// Knowledge before any transformation took place. Knowledge OriginalZone; /// Current knowledge of the SCoP including all already applied /// transformations. Knowledge Zone; /// Number of StoreInsts something can be mapped to. int NumberOfCompatibleTargets = 0; /// The number of StoreInsts to which at least one value or PHI has been /// mapped to. int NumberOfTargetsMapped = 0; /// The number of llvm::Value mapped to some array element. int NumberOfMappedValueScalars = 0; /// The number of PHIs mapped to some array element. int NumberOfMappedPHIScalars = 0; /// Determine whether two knowledges are conflicting with each other. /// /// @see Knowledge::isConflicting bool isConflicting(const Knowledge &Proposed) { raw_ostream *OS = nullptr; LLVM_DEBUG(OS = &llvm::dbgs()); return Knowledge::isConflicting(Zone, Proposed, OS, 4); } /// Determine whether @p SAI is a scalar that can be mapped to an array /// element. bool isMappable(const ScopArrayInfo *SAI) { assert(SAI); if (SAI->isValueKind()) { auto *MA = S->getValueDef(SAI); if (!MA) { LLVM_DEBUG( dbgs() << " Reject because value is read-only within the scop\n"); return false; } // Mapping if value is used after scop is not supported. The code // generator would need to reload the scalar after the scop, but it // does not have the information to where it is mapped to. Only the // MemoryAccesses have that information, not the ScopArrayInfo. auto Inst = MA->getAccessInstruction(); for (auto User : Inst->users()) { if (!isa(User)) return false; auto UserInst = cast(User); if (!S->contains(UserInst)) { LLVM_DEBUG(dbgs() << " Reject because value is escaping\n"); return false; } } return true; } if (SAI->isPHIKind()) { auto *MA = S->getPHIRead(SAI); assert(MA); // Mapping of an incoming block from before the SCoP is not supported by // the code generator. auto PHI = cast(MA->getAccessInstruction()); for (auto Incoming : PHI->blocks()) { if (!S->contains(Incoming)) { LLVM_DEBUG(dbgs() << " Reject because at least one incoming block is " "not in the scop region\n"); return false; } } return true; } LLVM_DEBUG(dbgs() << " Reject ExitPHI or other non-value\n"); return false; } /// Compute the uses of a MemoryKind::Value and its lifetime (from its /// definition to the last use). /// /// @param SAI The ScopArrayInfo representing the value's storage. /// /// @return { DomainDef[] -> DomainUse[] }, { DomainDef[] -> Zone[] } /// First element is the set of uses for each definition. /// The second is the lifetime of each definition. std::tuple computeValueUses(const ScopArrayInfo *SAI) { assert(SAI->isValueKind()); // { DomainRead[] } auto Reads = makeEmptyUnionSet(); // Find all uses. for (auto *MA : S->getValueUses(SAI)) Reads = Reads.unite(getDomainFor(MA)); // { DomainRead[] -> Scatter[] } auto ReadSchedule = getScatterFor(Reads); auto *DefMA = S->getValueDef(SAI); assert(DefMA); // { DomainDef[] } auto Writes = getDomainFor(DefMA); // { DomainDef[] -> Scatter[] } auto WriteScatter = getScatterFor(Writes); // { Scatter[] -> DomainDef[] } auto ReachDef = getScalarReachingDefinition(DefMA->getStatement()); // { [DomainDef[] -> Scatter[]] -> DomainUse[] } auto Uses = isl::union_map(ReachDef.reverse().range_map()) .apply_range(ReadSchedule.reverse()); // { DomainDef[] -> Scatter[] } auto UseScatter = singleton(Uses.domain().unwrap(), Writes.get_space().map_from_domain_and_range(ScatterSpace)); // { DomainDef[] -> Zone[] } auto Lifetime = betweenScatter(WriteScatter, UseScatter, false, true); // { DomainDef[] -> DomainRead[] } auto DefUses = Uses.domain_factor_domain(); return std::make_pair(DefUses, Lifetime); } /// Try to map a MemoryKind::Value to a given array element. /// /// @param SAI Representation of the scalar's memory to map. /// @param TargetElt { Scatter[] -> Element[] } /// Suggestion where to map a scalar to when at a timepoint. /// /// @return true if the scalar was successfully mapped. bool tryMapValue(const ScopArrayInfo *SAI, isl::map TargetElt) { assert(SAI->isValueKind()); auto *DefMA = S->getValueDef(SAI); assert(DefMA->isValueKind()); assert(DefMA->isMustWrite()); auto *V = DefMA->getAccessValue(); auto *DefInst = DefMA->getAccessInstruction(); // Stop if the scalar has already been mapped. if (!DefMA->getLatestScopArrayInfo()->isValueKind()) return false; // { DomainDef[] -> Scatter[] } auto DefSched = getScatterFor(DefMA); // Where each write is mapped to, according to the suggestion. // { DomainDef[] -> Element[] } auto DefTarget = TargetElt.apply_domain(DefSched.reverse()); simplify(DefTarget); LLVM_DEBUG(dbgs() << " Def Mapping: " << DefTarget << '\n'); auto OrigDomain = getDomainFor(DefMA); auto MappedDomain = DefTarget.domain(); if (!OrigDomain.is_subset(MappedDomain)) { LLVM_DEBUG( dbgs() << " Reject because mapping does not encompass all instances\n"); return false; } // { DomainDef[] -> Zone[] } isl::map Lifetime; // { DomainDef[] -> DomainUse[] } isl::union_map DefUses; std::tie(DefUses, Lifetime) = computeValueUses(SAI); LLVM_DEBUG(dbgs() << " Lifetime: " << Lifetime << '\n'); /// { [Element[] -> Zone[]] } auto EltZone = Lifetime.apply_domain(DefTarget).wrap(); simplify(EltZone); // When known knowledge is disabled, just return the unknown value. It will // either get filtered out or conflict with itself. // { DomainDef[] -> ValInst[] } isl::map ValInst; if (DelicmComputeKnown) ValInst = makeValInst(V, DefMA->getStatement(), LI->getLoopFor(DefInst->getParent())); else ValInst = makeUnknownForDomain(DefMA->getStatement()); // { DomainDef[] -> [Element[] -> Zone[]] } auto EltKnownTranslator = DefTarget.range_product(Lifetime); // { [Element[] -> Zone[]] -> ValInst[] } auto EltKnown = ValInst.apply_domain(EltKnownTranslator); simplify(EltKnown); // { DomainDef[] -> [Element[] -> Scatter[]] } auto WrittenTranslator = DefTarget.range_product(DefSched); // { [Element[] -> Scatter[]] -> ValInst[] } auto DefEltSched = ValInst.apply_domain(WrittenTranslator); simplify(DefEltSched); Knowledge Proposed(EltZone, {}, filterKnownValInst(EltKnown), DefEltSched); if (isConflicting(Proposed)) return false; // { DomainUse[] -> Element[] } auto UseTarget = DefUses.reverse().apply_range(DefTarget); mapValue(SAI, std::move(DefTarget), std::move(UseTarget), std::move(Lifetime), std::move(Proposed)); return true; } /// After a scalar has been mapped, update the global knowledge. void applyLifetime(Knowledge Proposed) { Zone.learnFrom(std::move(Proposed)); } /// Map a MemoryKind::Value scalar to an array element. /// /// Callers must have ensured that the mapping is valid and not conflicting. /// /// @param SAI The ScopArrayInfo representing the scalar's memory to /// map. /// @param DefTarget { DomainDef[] -> Element[] } /// The array element to map the scalar to. /// @param UseTarget { DomainUse[] -> Element[] } /// The array elements the uses are mapped to. /// @param Lifetime { DomainDef[] -> Zone[] } /// The lifetime of each llvm::Value definition for /// reporting. /// @param Proposed Mapping constraints for reporting. void mapValue(const ScopArrayInfo *SAI, isl::map DefTarget, isl::union_map UseTarget, isl::map Lifetime, Knowledge Proposed) { // Redirect the read accesses. for (auto *MA : S->getValueUses(SAI)) { // { DomainUse[] } auto Domain = getDomainFor(MA); // { DomainUse[] -> Element[] } auto NewAccRel = UseTarget.intersect_domain(Domain); simplify(NewAccRel); assert(isl_union_map_n_map(NewAccRel.get()) == 1); MA->setNewAccessRelation(isl::map::from_union_map(NewAccRel)); } auto *WA = S->getValueDef(SAI); WA->setNewAccessRelation(DefTarget); applyLifetime(Proposed); MappedValueScalars++; NumberOfMappedValueScalars += 1; } isl::map makeValInst(Value *Val, ScopStmt *UserStmt, Loop *Scope, bool IsCertain = true) { // When known knowledge is disabled, just return the unknown value. It will // either get filtered out or conflict with itself. if (!DelicmComputeKnown) return makeUnknownForDomain(UserStmt); return ZoneAlgorithm::makeValInst(Val, UserStmt, Scope, IsCertain); } /// Express the incoming values of a PHI for each incoming statement in an /// isl::union_map. /// /// @param SAI The PHI scalar represented by a ScopArrayInfo. /// /// @return { PHIWriteDomain[] -> ValInst[] } isl::union_map determinePHIWrittenValues(const ScopArrayInfo *SAI) { auto Result = makeEmptyUnionMap(); // Collect the incoming values. for (auto *MA : S->getPHIIncomings(SAI)) { // { DomainWrite[] -> ValInst[] } isl::union_map ValInst; auto *WriteStmt = MA->getStatement(); auto Incoming = MA->getIncoming(); assert(!Incoming.empty()); if (Incoming.size() == 1) { ValInst = makeValInst(Incoming[0].second, WriteStmt, LI->getLoopFor(Incoming[0].first)); } else { // If the PHI is in a subregion's exit node it can have multiple // incoming values (+ maybe another incoming edge from an unrelated // block). We cannot directly represent it as a single llvm::Value. // We currently model it as unknown value, but modeling as the PHIInst // itself could be OK, too. ValInst = makeUnknownForDomain(WriteStmt); } Result = Result.unite(ValInst); } assert(Result.is_single_valued() && "Cannot have multiple incoming values for same incoming statement"); return Result; } /// Try to map a MemoryKind::PHI scalar to a given array element. /// /// @param SAI Representation of the scalar's memory to map. /// @param TargetElt { Scatter[] -> Element[] } /// Suggestion where to map the scalar to when at a /// timepoint. /// /// @return true if the PHI scalar has been mapped. bool tryMapPHI(const ScopArrayInfo *SAI, isl::map TargetElt) { auto *PHIRead = S->getPHIRead(SAI); assert(PHIRead->isPHIKind()); assert(PHIRead->isRead()); // Skip if already been mapped. if (!PHIRead->getLatestScopArrayInfo()->isPHIKind()) return false; // { DomainRead[] -> Scatter[] } auto PHISched = getScatterFor(PHIRead); // { DomainRead[] -> Element[] } auto PHITarget = PHISched.apply_range(TargetElt); simplify(PHITarget); LLVM_DEBUG(dbgs() << " Mapping: " << PHITarget << '\n'); auto OrigDomain = getDomainFor(PHIRead); auto MappedDomain = PHITarget.domain(); if (!OrigDomain.is_subset(MappedDomain)) { LLVM_DEBUG( dbgs() << " Reject because mapping does not encompass all instances\n"); return false; } // { DomainRead[] -> DomainWrite[] } auto PerPHIWrites = computePerPHI(SAI); if (PerPHIWrites.is_null()) { LLVM_DEBUG( dbgs() << " Reject because cannot determine incoming values\n"); return false; } // { DomainWrite[] -> Element[] } auto WritesTarget = PerPHIWrites.apply_domain(PHITarget).reverse(); simplify(WritesTarget); // { DomainWrite[] } auto UniverseWritesDom = isl::union_set::empty(ParamSpace.ctx()); for (auto *MA : S->getPHIIncomings(SAI)) UniverseWritesDom = UniverseWritesDom.unite(getDomainFor(MA)); auto RelevantWritesTarget = WritesTarget; if (DelicmOverapproximateWrites) WritesTarget = expandMapping(WritesTarget, UniverseWritesDom); auto ExpandedWritesDom = WritesTarget.domain(); if (!DelicmPartialWrites && !UniverseWritesDom.is_subset(ExpandedWritesDom)) { LLVM_DEBUG( dbgs() << " Reject because did not find PHI write mapping for " "all instances\n"); if (DelicmOverapproximateWrites) LLVM_DEBUG(dbgs() << " Relevant Mapping: " << RelevantWritesTarget << '\n'); LLVM_DEBUG(dbgs() << " Deduced Mapping: " << WritesTarget << '\n'); LLVM_DEBUG(dbgs() << " Missing instances: " << UniverseWritesDom.subtract(ExpandedWritesDom) << '\n'); return false; } // { DomainRead[] -> Scatter[] } isl::union_map PerPHIWriteScatterUmap = PerPHIWrites.apply_range(Schedule); isl::map PerPHIWriteScatter = singleton(PerPHIWriteScatterUmap, PHISched.get_space()); // { DomainRead[] -> Zone[] } auto Lifetime = betweenScatter(PerPHIWriteScatter, PHISched, false, true); simplify(Lifetime); LLVM_DEBUG(dbgs() << " Lifetime: " << Lifetime << "\n"); // { DomainWrite[] -> Zone[] } auto WriteLifetime = isl::union_map(Lifetime).apply_domain(PerPHIWrites); // { DomainWrite[] -> ValInst[] } auto WrittenValue = determinePHIWrittenValues(SAI); // { DomainWrite[] -> [Element[] -> Scatter[]] } auto WrittenTranslator = WritesTarget.range_product(Schedule); // { [Element[] -> Scatter[]] -> ValInst[] } auto Written = WrittenValue.apply_domain(WrittenTranslator); simplify(Written); // { DomainWrite[] -> [Element[] -> Zone[]] } auto LifetimeTranslator = WritesTarget.range_product(WriteLifetime); // { DomainWrite[] -> ValInst[] } auto WrittenKnownValue = filterKnownValInst(WrittenValue); // { [Element[] -> Zone[]] -> ValInst[] } auto EltLifetimeInst = WrittenKnownValue.apply_domain(LifetimeTranslator); simplify(EltLifetimeInst); // { [Element[] -> Zone[] } auto Occupied = LifetimeTranslator.range(); simplify(Occupied); Knowledge Proposed(Occupied, {}, EltLifetimeInst, Written); if (isConflicting(Proposed)) return false; mapPHI(SAI, std::move(PHITarget), std::move(WritesTarget), std::move(Lifetime), std::move(Proposed)); return true; } /// Map a MemoryKind::PHI scalar to an array element. /// /// Callers must have ensured that the mapping is valid and not conflicting /// with the common knowledge. /// /// @param SAI The ScopArrayInfo representing the scalar's memory to /// map. /// @param ReadTarget { DomainRead[] -> Element[] } /// The array element to map the scalar to. /// @param WriteTarget { DomainWrite[] -> Element[] } /// New access target for each PHI incoming write. /// @param Lifetime { DomainRead[] -> Zone[] } /// The lifetime of each PHI for reporting. /// @param Proposed Mapping constraints for reporting. void mapPHI(const ScopArrayInfo *SAI, isl::map ReadTarget, isl::union_map WriteTarget, isl::map Lifetime, Knowledge Proposed) { // { Element[] } isl::space ElementSpace = ReadTarget.get_space().range(); // Redirect the PHI incoming writes. for (auto *MA : S->getPHIIncomings(SAI)) { // { DomainWrite[] } auto Domain = getDomainFor(MA); // { DomainWrite[] -> Element[] } auto NewAccRel = WriteTarget.intersect_domain(Domain); simplify(NewAccRel); isl::space NewAccRelSpace = Domain.get_space().map_from_domain_and_range(ElementSpace); isl::map NewAccRelMap = singleton(NewAccRel, NewAccRelSpace); MA->setNewAccessRelation(NewAccRelMap); } // Redirect the PHI read. auto *PHIRead = S->getPHIRead(SAI); PHIRead->setNewAccessRelation(ReadTarget); applyLifetime(Proposed); MappedPHIScalars++; NumberOfMappedPHIScalars++; } /// Search and map scalars to memory overwritten by @p TargetStoreMA. /// /// Start trying to map scalars that are used in the same statement as the /// store. For every successful mapping, try to also map scalars of the /// statements where those are written. Repeat, until no more mapping /// opportunity is found. /// /// There is currently no preference in which order scalars are tried. /// Ideally, we would direct it towards a load instruction of the same array /// element. bool collapseScalarsToStore(MemoryAccess *TargetStoreMA) { assert(TargetStoreMA->isLatestArrayKind()); assert(TargetStoreMA->isMustWrite()); auto TargetStmt = TargetStoreMA->getStatement(); // { DomTarget[] } auto TargetDom = getDomainFor(TargetStmt); // { DomTarget[] -> Element[] } auto TargetAccRel = getAccessRelationFor(TargetStoreMA); // { Zone[] -> DomTarget[] } // For each point in time, find the next target store instance. auto Target = computeScalarReachingOverwrite(Schedule, TargetDom, false, true); // { Zone[] -> Element[] } // Use the target store's write location as a suggestion to map scalars to. auto EltTarget = Target.apply_range(TargetAccRel); simplify(EltTarget); LLVM_DEBUG(dbgs() << " Target mapping is " << EltTarget << '\n'); // Stack of elements not yet processed. SmallVector Worklist; // Set of scalars already tested. SmallPtrSet Closed; // Lambda to add all scalar reads to the work list. auto ProcessAllIncoming = [&](ScopStmt *Stmt) { for (auto *MA : *Stmt) { if (!MA->isLatestScalarKind()) continue; if (!MA->isRead()) continue; Worklist.push_back(MA); } }; auto *WrittenVal = TargetStoreMA->getAccessInstruction()->getOperand(0); if (auto *WrittenValInputMA = TargetStmt->lookupInputAccessOf(WrittenVal)) Worklist.push_back(WrittenValInputMA); else ProcessAllIncoming(TargetStmt); auto AnyMapped = false; auto &DL = S->getRegion().getEntry()->getModule()->getDataLayout(); auto StoreSize = DL.getTypeAllocSize(TargetStoreMA->getAccessValue()->getType()); while (!Worklist.empty()) { auto *MA = Worklist.pop_back_val(); auto *SAI = MA->getScopArrayInfo(); if (Closed.count(SAI)) continue; Closed.insert(SAI); LLVM_DEBUG(dbgs() << "\n Trying to map " << MA << " (SAI: " << SAI << ")\n"); // Skip non-mappable scalars. if (!isMappable(SAI)) continue; auto MASize = DL.getTypeAllocSize(MA->getAccessValue()->getType()); if (MASize > StoreSize) { LLVM_DEBUG( dbgs() << " Reject because storage size is insufficient\n"); continue; } // Try to map MemoryKind::Value scalars. if (SAI->isValueKind()) { if (!tryMapValue(SAI, EltTarget)) continue; auto *DefAcc = S->getValueDef(SAI); ProcessAllIncoming(DefAcc->getStatement()); AnyMapped = true; continue; } // Try to map MemoryKind::PHI scalars. if (SAI->isPHIKind()) { if (!tryMapPHI(SAI, EltTarget)) continue; // Add inputs of all incoming statements to the worklist. Prefer the // input accesses of the incoming blocks. for (auto *PHIWrite : S->getPHIIncomings(SAI)) { auto *PHIWriteStmt = PHIWrite->getStatement(); bool FoundAny = false; for (auto Incoming : PHIWrite->getIncoming()) { auto *IncomingInputMA = PHIWriteStmt->lookupInputAccessOf(Incoming.second); if (!IncomingInputMA) continue; Worklist.push_back(IncomingInputMA); FoundAny = true; } if (!FoundAny) ProcessAllIncoming(PHIWrite->getStatement()); } AnyMapped = true; continue; } } if (AnyMapped) { TargetsMapped++; NumberOfTargetsMapped++; } return AnyMapped; } /// Compute when an array element is unused. /// /// @return { [Element[] -> Zone[]] } isl::union_set computeLifetime() const { // { Element[] -> Zone[] } auto ArrayUnused = computeArrayUnused(Schedule, AllMustWrites, AllReads, false, false, true); auto Result = ArrayUnused.wrap(); simplify(Result); return Result; } /// Determine when an array element is written to, and which value instance is /// written. /// /// @return { [Element[] -> Scatter[]] -> ValInst[] } isl::union_map computeWritten() const { // { [Element[] -> Scatter[]] -> ValInst[] } auto EltWritten = applyDomainRange(AllWriteValInst, Schedule); simplify(EltWritten); return EltWritten; } /// Determine whether an access touches at most one element. /// /// The accessed element could be a scalar or accessing an array with constant /// subscript, such that all instances access only that element. /// /// @param MA The access to test. /// /// @return True, if zero or one elements are accessed; False if at least two /// different elements are accessed. bool isScalarAccess(MemoryAccess *MA) { auto Map = getAccessRelationFor(MA); auto Set = Map.range(); return Set.is_singleton(); } /// Print mapping statistics to @p OS. void printStatistics(llvm::raw_ostream &OS, int Indent = 0) const { OS.indent(Indent) << "Statistics {\n"; OS.indent(Indent + 4) << "Compatible overwrites: " << NumberOfCompatibleTargets << "\n"; OS.indent(Indent + 4) << "Overwrites mapped to: " << NumberOfTargetsMapped << '\n'; OS.indent(Indent + 4) << "Value scalars mapped: " << NumberOfMappedValueScalars << '\n'; OS.indent(Indent + 4) << "PHI scalars mapped: " << NumberOfMappedPHIScalars << '\n'; OS.indent(Indent) << "}\n"; } public: DeLICMImpl(Scop *S, LoopInfo *LI) : ZoneAlgorithm("polly-delicm", S, LI) {} /// Calculate the lifetime (definition to last use) of every array element. /// /// @return True if the computed lifetimes (#Zone) is usable. bool computeZone() { // Check that nothing strange occurs. collectCompatibleElts(); isl::union_set EltUnused; isl::union_map EltKnown, EltWritten; { IslMaxOperationsGuard MaxOpGuard(IslCtx.get(), DelicmMaxOps); computeCommon(); EltUnused = computeLifetime(); EltKnown = computeKnown(true, false); EltWritten = computeWritten(); } DeLICMAnalyzed++; if (EltUnused.is_null() || EltKnown.is_null() || EltWritten.is_null()) { assert(isl_ctx_last_error(IslCtx.get()) == isl_error_quota && "The only reason that these things have not been computed should " "be if the max-operations limit hit"); DeLICMOutOfQuota++; LLVM_DEBUG(dbgs() << "DeLICM analysis exceeded max_operations\n"); DebugLoc Begin, End; getDebugLocations(getBBPairForRegion(&S->getRegion()), Begin, End); OptimizationRemarkAnalysis R(DEBUG_TYPE, "OutOfQuota", Begin, S->getEntry()); R << "maximal number of operations exceeded during zone analysis"; S->getFunction().getContext().diagnose(R); return false; } Zone = OriginalZone = Knowledge({}, EltUnused, EltKnown, EltWritten); LLVM_DEBUG(dbgs() << "Computed Zone:\n"; OriginalZone.print(dbgs(), 4)); assert(Zone.isUsable() && OriginalZone.isUsable()); return true; } /// Try to map as many scalars to unused array elements as possible. /// /// Multiple scalars might be mappable to intersecting unused array element /// zones, but we can only chose one. This is a greedy algorithm, therefore /// the first processed element claims it. void greedyCollapse() { bool Modified = false; for (auto &Stmt : *S) { for (auto *MA : Stmt) { if (!MA->isLatestArrayKind()) continue; if (!MA->isWrite()) continue; if (MA->isMayWrite()) { LLVM_DEBUG(dbgs() << "Access " << MA << " pruned because it is a MAY_WRITE\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "TargetMayWrite", MA->getAccessInstruction()); R << "Skipped possible mapping target because it is not an " "unconditional overwrite"; S->getFunction().getContext().diagnose(R); continue; } if (Stmt.getNumIterators() == 0) { LLVM_DEBUG(dbgs() << "Access " << MA << " pruned because it is not in a loop\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "WriteNotInLoop", MA->getAccessInstruction()); R << "skipped possible mapping target because it is not in a loop"; S->getFunction().getContext().diagnose(R); continue; } if (isScalarAccess(MA)) { LLVM_DEBUG(dbgs() << "Access " << MA << " pruned because it writes only a single element\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "ScalarWrite", MA->getAccessInstruction()); R << "skipped possible mapping target because the memory location " "written to does not depend on its outer loop"; S->getFunction().getContext().diagnose(R); continue; } if (!isa(MA->getAccessInstruction())) { LLVM_DEBUG(dbgs() << "Access " << MA << " pruned because it is not a StoreInst\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "NotAStore", MA->getAccessInstruction()); R << "skipped possible mapping target because non-store instructions " "are not supported"; S->getFunction().getContext().diagnose(R); continue; } // Check for more than one element acces per statement instance. // Currently we expect write accesses to be functional, eg. disallow // // { Stmt[0] -> [i] : 0 <= i < 2 } // // This may occur when some accesses to the element write/read only // parts of the element, eg. a single byte. Polly then divides each // element into subelements of the smallest access length, normal access // then touch multiple of such subelements. It is very common when the // array is accesses with memset, memcpy or memmove which take i8* // arguments. isl::union_map AccRel = MA->getLatestAccessRelation(); if (!AccRel.is_single_valued().is_true()) { LLVM_DEBUG(dbgs() << "Access " << MA << " is incompatible because it writes multiple " "elements per instance\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "NonFunctionalAccRel", MA->getAccessInstruction()); R << "skipped possible mapping target because it writes more than " "one element"; S->getFunction().getContext().diagnose(R); continue; } isl::union_set TouchedElts = AccRel.range(); if (!TouchedElts.is_subset(CompatibleElts)) { LLVM_DEBUG( dbgs() << "Access " << MA << " is incompatible because it touches incompatible elements\n"); OptimizationRemarkMissed R(DEBUG_TYPE, "IncompatibleElts", MA->getAccessInstruction()); R << "skipped possible mapping target because a target location " "cannot be reliably analyzed"; S->getFunction().getContext().diagnose(R); continue; } assert(isCompatibleAccess(MA)); NumberOfCompatibleTargets++; LLVM_DEBUG(dbgs() << "Analyzing target access " << MA << "\n"); if (collapseScalarsToStore(MA)) Modified = true; } } if (Modified) DeLICMScopsModified++; } /// Dump the internal information about a performed DeLICM to @p OS. void print(llvm::raw_ostream &OS, int Indent = 0) { if (!Zone.isUsable()) { OS.indent(Indent) << "Zone not computed\n"; return; } printStatistics(OS, Indent); if (!isModified()) { OS.indent(Indent) << "No modification has been made\n"; return; } printAccesses(OS, Indent); } /// Return whether at least one transformation been applied. bool isModified() const { return NumberOfTargetsMapped > 0; } }; static std::unique_ptr collapseToUnused(Scop &S, LoopInfo &LI) { std::unique_ptr Impl = std::make_unique(&S, &LI); if (!Impl->computeZone()) { LLVM_DEBUG(dbgs() << "Abort because cannot reliably compute lifetimes\n"); return Impl; } LLVM_DEBUG(dbgs() << "Collapsing scalars to unused array elements...\n"); Impl->greedyCollapse(); LLVM_DEBUG(dbgs() << "\nFinal Scop:\n"); LLVM_DEBUG(dbgs() << S); return Impl; } static std::unique_ptr runDeLICM(Scop &S, LoopInfo &LI) { std::unique_ptr Impl = collapseToUnused(S, LI); Scop::ScopStatistics ScopStats = S.getStatistics(); NumValueWrites += ScopStats.NumValueWrites; NumValueWritesInLoops += ScopStats.NumValueWritesInLoops; NumPHIWrites += ScopStats.NumPHIWrites; NumPHIWritesInLoops += ScopStats.NumPHIWritesInLoops; NumSingletonWrites += ScopStats.NumSingletonWrites; NumSingletonWritesInLoops += ScopStats.NumSingletonWritesInLoops; return Impl; } static PreservedAnalyses runDeLICMUsingNPM(Scop &S, ScopAnalysisManager &SAM, ScopStandardAnalysisResults &SAR, SPMUpdater &U, raw_ostream *OS) { LoopInfo &LI = SAR.LI; std::unique_ptr Impl = runDeLICM(S, LI); if (OS) { *OS << "Printing analysis 'Polly - DeLICM/DePRE' for region: '" << S.getName() << "' in function '" << S.getFunction().getName() << "':\n"; if (Impl) { assert(Impl->getScop() == &S); *OS << "DeLICM result:\n"; Impl->print(*OS); } } if (!Impl->isModified()) return PreservedAnalyses::all(); PreservedAnalyses PA; PA.preserveSet>(); PA.preserveSet>(); PA.preserveSet>(); return PA; } class DeLICMWrapperPass : public ScopPass { private: DeLICMWrapperPass(const DeLICMWrapperPass &) = delete; const DeLICMWrapperPass &operator=(const DeLICMWrapperPass &) = delete; /// The pass implementation, also holding per-scop data. std::unique_ptr Impl; public: static char ID; explicit DeLICMWrapperPass() : ScopPass(ID) {} virtual void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequiredTransitive(); AU.addRequired(); AU.setPreservesAll(); } virtual bool runOnScop(Scop &S) override { // Free resources for previous scop's computation, if not yet done. releaseMemory(); auto &LI = getAnalysis().getLoopInfo(); Impl = runDeLICM(S, LI); return Impl->isModified(); } virtual void printScop(raw_ostream &OS, Scop &S) const override { if (!Impl) return; assert(Impl->getScop() == &S); OS << "DeLICM result:\n"; Impl->print(OS); } virtual void releaseMemory() override { Impl.reset(); } }; char DeLICMWrapperPass::ID; } // anonymous namespace Pass *polly::createDeLICMWrapperPass() { return new DeLICMWrapperPass(); } INITIALIZE_PASS_BEGIN(DeLICMWrapperPass, "polly-delicm", "Polly - DeLICM/DePRE", false, false) INITIALIZE_PASS_DEPENDENCY(ScopInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass) INITIALIZE_PASS_END(DeLICMWrapperPass, "polly-delicm", "Polly - DeLICM/DePRE", false, false) llvm::PreservedAnalyses DeLICMPass::run(Scop &S, ScopAnalysisManager &SAM, ScopStandardAnalysisResults &SAR, SPMUpdater &U) { return runDeLICMUsingNPM(S, SAM, SAR, U, nullptr); } llvm::PreservedAnalyses DeLICMPrinterPass::run(Scop &S, ScopAnalysisManager &SAM, ScopStandardAnalysisResults &SAR, SPMUpdater &U) { return runDeLICMUsingNPM(S, SAM, SAR, U, &OS); } bool polly::isConflicting( isl::union_set ExistingOccupied, isl::union_set ExistingUnused, isl::union_map ExistingKnown, isl::union_map ExistingWrites, isl::union_set ProposedOccupied, isl::union_set ProposedUnused, isl::union_map ProposedKnown, isl::union_map ProposedWrites, llvm::raw_ostream *OS, unsigned Indent) { Knowledge Existing(std::move(ExistingOccupied), std::move(ExistingUnused), std::move(ExistingKnown), std::move(ExistingWrites)); Knowledge Proposed(std::move(ProposedOccupied), std::move(ProposedUnused), std::move(ProposedKnown), std::move(ProposedWrites)); return Knowledge::isConflicting(Existing, Proposed, OS, Indent); }