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|
//===- SROA.cpp - Scalar Replacement Of Aggregates ------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
/// \file
/// This transformation implements the well known scalar replacement of
/// aggregates transformation. It tries to identify promotable elements of an
/// aggregate alloca, and promote them to registers. It will also try to
/// convert uses of an element (or set of elements) of an alloca into a vector
/// or bitfield-style integer scalar if appropriate.
///
/// It works to do this with minimal slicing of the alloca so that regions
/// which are merely transferred in and out of external memory remain unchanged
/// and are not decomposed to scalar code.
///
/// Because this also performs alloca promotion, it can be thought of as also
/// serving the purpose of SSA formation. The algorithm iterates on the
/// function until all opportunities for promotion have been realized.
///
//===----------------------------------------------------------------------===//
#define DEBUG_TYPE "sroa"
#include "llvm/Transforms/Scalar.h"
#include "llvm/Constants.h"
#include "llvm/DIBuilder.h"
#include "llvm/DebugInfo.h"
#include "llvm/DerivedTypes.h"
#include "llvm/Function.h"
#include "llvm/GlobalVariable.h"
#include "llvm/IRBuilder.h"
#include "llvm/Instructions.h"
#include "llvm/IntrinsicInst.h"
#include "llvm/LLVMContext.h"
#include "llvm/Module.h"
#include "llvm/Operator.h"
#include "llvm/Pass.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/TinyPtrVector.h"
#include "llvm/Analysis/Dominators.h"
#include "llvm/Analysis/Loads.h"
#include "llvm/Analysis/ValueTracking.h"
#include "llvm/Support/CallSite.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/GetElementPtrTypeIterator.h"
#include "llvm/Support/InstVisitor.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/ValueHandle.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/Target/TargetData.h"
#include "llvm/Transforms/Utils/Local.h"
#include "llvm/Transforms/Utils/PromoteMemToReg.h"
#include "llvm/Transforms/Utils/SSAUpdater.h"
using namespace llvm;
STATISTIC(NumAllocasAnalyzed, "Number of allocas analyzed for replacement");
STATISTIC(NumNewAllocas, "Number of new, smaller allocas introduced");
STATISTIC(NumPromoted, "Number of allocas promoted to SSA values");
STATISTIC(NumLoadsSpeculated, "Number of loads speculated to allow promotion");
STATISTIC(NumDeleted, "Number of instructions deleted");
STATISTIC(NumVectorized, "Number of vectorized aggregates");
/// Hidden option to force the pass to not use DomTree and mem2reg, instead
/// forming SSA values through the SSAUpdater infrastructure.
static cl::opt<bool>
ForceSSAUpdater("force-ssa-updater", cl::init(false), cl::Hidden);
namespace {
/// \brief Alloca partitioning representation.
///
/// This class represents a partitioning of an alloca into slices, and
/// information about the nature of uses of each slice of the alloca. The goal
/// is that this information is sufficient to decide if and how to split the
/// alloca apart and replace slices with scalars. It is also intended that this
/// structure can capture the relevant information needed both to decide about
/// and to enact these transformations.
class AllocaPartitioning {
public:
/// \brief A common base class for representing a half-open byte range.
struct ByteRange {
/// \brief The beginning offset of the range.
uint64_t BeginOffset;
/// \brief The ending offset, not included in the range.
uint64_t EndOffset;
ByteRange() : BeginOffset(), EndOffset() {}
ByteRange(uint64_t BeginOffset, uint64_t EndOffset)
: BeginOffset(BeginOffset), EndOffset(EndOffset) {}
/// \brief Support for ordering ranges.
///
/// This provides an ordering over ranges such that start offsets are
/// always increasing, and within equal start offsets, the end offsets are
/// decreasing. Thus the spanning range comes first in a cluster with the
/// same start position.
bool operator<(const ByteRange &RHS) const {
if (BeginOffset < RHS.BeginOffset) return true;
if (BeginOffset > RHS.BeginOffset) return false;
if (EndOffset > RHS.EndOffset) return true;
return false;
}
/// \brief Support comparison with a single offset to allow binary searches.
friend bool operator<(const ByteRange &LHS, uint64_t RHSOffset) {
return LHS.BeginOffset < RHSOffset;
}
friend LLVM_ATTRIBUTE_UNUSED bool operator<(uint64_t LHSOffset,
const ByteRange &RHS) {
return LHSOffset < RHS.BeginOffset;
}
bool operator==(const ByteRange &RHS) const {
return BeginOffset == RHS.BeginOffset && EndOffset == RHS.EndOffset;
}
bool operator!=(const ByteRange &RHS) const { return !operator==(RHS); }
};
/// \brief A partition of an alloca.
///
/// This structure represents a contiguous partition of the alloca. These are
/// formed by examining the uses of the alloca. During formation, they may
/// overlap but once an AllocaPartitioning is built, the Partitions within it
/// are all disjoint.
struct Partition : public ByteRange {
/// \brief Whether this partition is splittable into smaller partitions.
///
/// We flag partitions as splittable when they are formed entirely due to
/// accesses by trivially splittable operations such as memset and memcpy.
///
/// FIXME: At some point we should consider loads and stores of FCAs to be
/// splittable and eagerly split them into scalar values.
bool IsSplittable;
Partition() : ByteRange(), IsSplittable() {}
Partition(uint64_t BeginOffset, uint64_t EndOffset, bool IsSplittable)
: ByteRange(BeginOffset, EndOffset), IsSplittable(IsSplittable) {}
};
/// \brief A particular use of a partition of the alloca.
///
/// This structure is used to associate uses of a partition with it. They
/// mark the range of bytes which are referenced by a particular instruction,
/// and includes a handle to the user itself and the pointer value in use.
/// The bounds of these uses are determined by intersecting the bounds of the
/// memory use itself with a particular partition. As a consequence there is
/// intentionally overlap between various uses of the same partition.
struct PartitionUse : public ByteRange {
/// \brief The user of this range of the alloca.
AssertingVH<Instruction> User;
/// \brief The particular pointer value derived from this alloca in use.
AssertingVH<Instruction> Ptr;
PartitionUse() : ByteRange(), User(), Ptr() {}
PartitionUse(uint64_t BeginOffset, uint64_t EndOffset,
Instruction *User, Instruction *Ptr)
: ByteRange(BeginOffset, EndOffset), User(User), Ptr(Ptr) {}
};
/// \brief Construct a partitioning of a particular alloca.
///
/// Construction does most of the work for partitioning the alloca. This
/// performs the necessary walks of users and builds a partitioning from it.
AllocaPartitioning(const TargetData &TD, AllocaInst &AI);
/// \brief Test whether a pointer to the allocation escapes our analysis.
///
/// If this is true, the partitioning is never fully built and should be
/// ignored.
bool isEscaped() const { return PointerEscapingInstr; }
/// \brief Support for iterating over the partitions.
/// @{
typedef SmallVectorImpl<Partition>::iterator iterator;
iterator begin() { return Partitions.begin(); }
iterator end() { return Partitions.end(); }
typedef SmallVectorImpl<Partition>::const_iterator const_iterator;
const_iterator begin() const { return Partitions.begin(); }
const_iterator end() const { return Partitions.end(); }
/// @}
/// \brief Support for iterating over and manipulating a particular
/// partition's uses.
///
/// The iteration support provided for uses is more limited, but also
/// includes some manipulation routines to support rewriting the uses of
/// partitions during SROA.
/// @{
typedef SmallVectorImpl<PartitionUse>::iterator use_iterator;
use_iterator use_begin(unsigned Idx) { return Uses[Idx].begin(); }
use_iterator use_begin(const_iterator I) { return Uses[I - begin()].begin(); }
use_iterator use_end(unsigned Idx) { return Uses[Idx].end(); }
use_iterator use_end(const_iterator I) { return Uses[I - begin()].end(); }
void use_push_back(unsigned Idx, const PartitionUse &U) {
Uses[Idx].push_back(U);
}
void use_push_back(const_iterator I, const PartitionUse &U) {
Uses[I - begin()].push_back(U);
}
void use_erase(unsigned Idx, use_iterator UI) { Uses[Idx].erase(UI); }
void use_erase(const_iterator I, use_iterator UI) {
Uses[I - begin()].erase(UI);
}
typedef SmallVectorImpl<PartitionUse>::const_iterator const_use_iterator;
const_use_iterator use_begin(unsigned Idx) const { return Uses[Idx].begin(); }
const_use_iterator use_begin(const_iterator I) const {
return Uses[I - begin()].begin();
}
const_use_iterator use_end(unsigned Idx) const { return Uses[Idx].end(); }
const_use_iterator use_end(const_iterator I) const {
return Uses[I - begin()].end();
}
/// @}
/// \brief Allow iterating the dead users for this alloca.
///
/// These are instructions which will never actually use the alloca as they
/// are outside the allocated range. They are safe to replace with undef and
/// delete.
/// @{
typedef SmallVectorImpl<Instruction *>::const_iterator dead_user_iterator;
dead_user_iterator dead_user_begin() const { return DeadUsers.begin(); }
dead_user_iterator dead_user_end() const { return DeadUsers.end(); }
/// @}
/// \brief Allow iterating the dead expressions referring to this alloca.
///
/// These are operands which have cannot actually be used to refer to the
/// alloca as they are outside its range and the user doesn't correct for
/// that. These mostly consist of PHI node inputs and the like which we just
/// need to replace with undef.
/// @{
typedef SmallVectorImpl<Use *>::const_iterator dead_op_iterator;
dead_op_iterator dead_op_begin() const { return DeadOperands.begin(); }
dead_op_iterator dead_op_end() const { return DeadOperands.end(); }
/// @}
/// \brief MemTransferInst auxiliary data.
/// This struct provides some auxiliary data about memory transfer
/// intrinsics such as memcpy and memmove. These intrinsics can use two
/// different ranges within the same alloca, and provide other challenges to
/// correctly represent. We stash extra data to help us untangle this
/// after the partitioning is complete.
struct MemTransferOffsets {
uint64_t DestBegin, DestEnd;
uint64_t SourceBegin, SourceEnd;
bool IsSplittable;
};
MemTransferOffsets getMemTransferOffsets(MemTransferInst &II) const {
return MemTransferInstData.lookup(&II);
}
/// \brief Map from a PHI or select operand back to a partition.
///
/// When manipulating PHI nodes or selects, they can use more than one
/// partition of an alloca. We store a special mapping to allow finding the
/// partition referenced by each of these operands, if any.
iterator findPartitionForPHIOrSelectOperand(Instruction &I, Value *Op) {
SmallDenseMap<std::pair<Instruction *, Value *>,
std::pair<unsigned, unsigned> >::const_iterator MapIt
= PHIOrSelectOpMap.find(std::make_pair(&I, Op));
if (MapIt == PHIOrSelectOpMap.end())
return end();
return begin() + MapIt->second.first;
}
/// \brief Map from a PHI or select operand back to the specific use of
/// a partition.
///
/// Similar to mapping these operands back to the partitions, this maps
/// directly to the use structure of that partition.
use_iterator findPartitionUseForPHIOrSelectOperand(Instruction &I,
Value *Op) {
SmallDenseMap<std::pair<Instruction *, Value *>,
std::pair<unsigned, unsigned> >::const_iterator MapIt
= PHIOrSelectOpMap.find(std::make_pair(&I, Op));
assert(MapIt != PHIOrSelectOpMap.end());
return Uses[MapIt->second.first].begin() + MapIt->second.second;
}
/// \brief Compute a common type among the uses of a particular partition.
///
/// This routines walks all of the uses of a particular partition and tries
/// to find a common type between them. Untyped operations such as memset and
/// memcpy are ignored.
Type *getCommonType(iterator I) const;
#if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
void print(raw_ostream &OS, const_iterator I, StringRef Indent = " ") const;
void printUsers(raw_ostream &OS, const_iterator I,
StringRef Indent = " ") const;
void print(raw_ostream &OS) const;
void LLVM_ATTRIBUTE_NOINLINE LLVM_ATTRIBUTE_USED dump(const_iterator I) const;
void LLVM_ATTRIBUTE_NOINLINE LLVM_ATTRIBUTE_USED dump() const;
#endif
private:
template <typename DerivedT, typename RetT = void> class BuilderBase;
class PartitionBuilder;
friend class AllocaPartitioning::PartitionBuilder;
class UseBuilder;
friend class AllocaPartitioning::UseBuilder;
#ifndef NDEBUG
/// \brief Handle to alloca instruction to simplify method interfaces.
AllocaInst &AI;
#endif
/// \brief The instruction responsible for this alloca having no partitioning.
///
/// When an instruction (potentially) escapes the pointer to the alloca, we
/// store a pointer to that here and abort trying to partition the alloca.
/// This will be null if the alloca is partitioned successfully.
Instruction *PointerEscapingInstr;
/// \brief The partitions of the alloca.
///
/// We store a vector of the partitions over the alloca here. This vector is
/// sorted by increasing begin offset, and then by decreasing end offset. See
/// the Partition inner class for more details. Initially (during
/// construction) there are overlaps, but we form a disjoint sequence of
/// partitions while finishing construction and a fully constructed object is
/// expected to always have this as a disjoint space.
SmallVector<Partition, 8> Partitions;
/// \brief The uses of the partitions.
///
/// This is essentially a mapping from each partition to a list of uses of
/// that partition. The mapping is done with a Uses vector that has the exact
/// same number of entries as the partition vector. Each entry is itself
/// a vector of the uses.
SmallVector<SmallVector<PartitionUse, 2>, 8> Uses;
/// \brief Instructions which will become dead if we rewrite the alloca.
///
/// Note that these are not separated by partition. This is because we expect
/// a partitioned alloca to be completely rewritten or not rewritten at all.
/// If rewritten, all these instructions can simply be removed and replaced
/// with undef as they come from outside of the allocated space.
SmallVector<Instruction *, 8> DeadUsers;
/// \brief Operands which will become dead if we rewrite the alloca.
///
/// These are operands that in their particular use can be replaced with
/// undef when we rewrite the alloca. These show up in out-of-bounds inputs
/// to PHI nodes and the like. They aren't entirely dead (there might be
/// a GEP back into the bounds using it elsewhere) and nor is the PHI, but we
/// want to swap this particular input for undef to simplify the use lists of
/// the alloca.
SmallVector<Use *, 8> DeadOperands;
/// \brief The underlying storage for auxiliary memcpy and memset info.
SmallDenseMap<MemTransferInst *, MemTransferOffsets, 4> MemTransferInstData;
/// \brief A side datastructure used when building up the partitions and uses.
///
/// This mapping is only really used during the initial building of the
/// partitioning so that we can retain information about PHI and select nodes
/// processed.
SmallDenseMap<Instruction *, std::pair<uint64_t, bool> > PHIOrSelectSizes;
/// \brief Auxiliary information for particular PHI or select operands.
SmallDenseMap<std::pair<Instruction *, Value *>,
std::pair<unsigned, unsigned>, 4> PHIOrSelectOpMap;
/// \brief A utility routine called from the constructor.
///
/// This does what it says on the tin. It is the key of the alloca partition
/// splitting and merging. After it is called we have the desired disjoint
/// collection of partitions.
void splitAndMergePartitions();
};
}
template <typename DerivedT, typename RetT>
class AllocaPartitioning::BuilderBase
: public InstVisitor<DerivedT, RetT> {
public:
BuilderBase(const TargetData &TD, AllocaInst &AI, AllocaPartitioning &P)
: TD(TD),
AllocSize(TD.getTypeAllocSize(AI.getAllocatedType())),
P(P) {
enqueueUsers(AI, 0);
}
protected:
const TargetData &TD;
const uint64_t AllocSize;
AllocaPartitioning &P;
struct OffsetUse {
Use *U;
int64_t Offset;
};
SmallVector<OffsetUse, 8> Queue;
// The active offset and use while visiting.
Use *U;
int64_t Offset;
void enqueueUsers(Instruction &I, int64_t UserOffset) {
SmallPtrSet<User *, 8> UserSet;
for (Value::use_iterator UI = I.use_begin(), UE = I.use_end();
UI != UE; ++UI) {
if (!UserSet.insert(*UI))
continue;
OffsetUse OU = { &UI.getUse(), UserOffset };
Queue.push_back(OU);
}
}
bool computeConstantGEPOffset(GetElementPtrInst &GEPI, int64_t &GEPOffset) {
GEPOffset = Offset;
for (gep_type_iterator GTI = gep_type_begin(GEPI), GTE = gep_type_end(GEPI);
GTI != GTE; ++GTI) {
ConstantInt *OpC = dyn_cast<ConstantInt>(GTI.getOperand());
if (!OpC)
return false;
if (OpC->isZero())
continue;
// Handle a struct index, which adds its field offset to the pointer.
if (StructType *STy = dyn_cast<StructType>(*GTI)) {
unsigned ElementIdx = OpC->getZExtValue();
const StructLayout *SL = TD.getStructLayout(STy);
uint64_t ElementOffset = SL->getElementOffset(ElementIdx);
// Check that we can continue to model this GEP in a signed 64-bit offset.
if (ElementOffset > INT64_MAX ||
(GEPOffset >= 0 &&
((uint64_t)GEPOffset + ElementOffset) > INT64_MAX)) {
DEBUG(dbgs() << "WARNING: Encountered a cumulative offset exceeding "
<< "what can be represented in an int64_t!\n"
<< " alloca: " << P.AI << "\n");
return false;
}
if (GEPOffset < 0)
GEPOffset = ElementOffset + (uint64_t)-GEPOffset;
else
GEPOffset += ElementOffset;
continue;
}
APInt Index = OpC->getValue().sextOrTrunc(TD.getPointerSizeInBits());
Index *= APInt(Index.getBitWidth(),
TD.getTypeAllocSize(GTI.getIndexedType()));
Index += APInt(Index.getBitWidth(), (uint64_t)GEPOffset,
/*isSigned*/true);
// Check if the result can be stored in our int64_t offset.
if (!Index.isSignedIntN(sizeof(GEPOffset) * 8)) {
DEBUG(dbgs() << "WARNING: Encountered a cumulative offset exceeding "
<< "what can be represented in an int64_t!\n"
<< " alloca: " << P.AI << "\n");
return false;
}
GEPOffset = Index.getSExtValue();
}
return true;
}
Value *foldSelectInst(SelectInst &SI) {
// If the condition being selected on is a constant or the same value is
// being selected between, fold the select. Yes this does (rarely) happen
// early on.
if (ConstantInt *CI = dyn_cast<ConstantInt>(SI.getCondition()))
return SI.getOperand(1+CI->isZero());
if (SI.getOperand(1) == SI.getOperand(2)) {
assert(*U == SI.getOperand(1));
return SI.getOperand(1);
}
return 0;
}
};
/// \brief Builder for the alloca partitioning.
///
/// This class builds an alloca partitioning by recursively visiting the uses
/// of an alloca and splitting the partitions for each load and store at each
/// offset.
class AllocaPartitioning::PartitionBuilder
: public BuilderBase<PartitionBuilder, bool> {
friend class InstVisitor<PartitionBuilder, bool>;
SmallDenseMap<Instruction *, unsigned> MemTransferPartitionMap;
public:
PartitionBuilder(const TargetData &TD, AllocaInst &AI, AllocaPartitioning &P)
: BuilderBase<PartitionBuilder, bool>(TD, AI, P) {}
/// \brief Run the builder over the allocation.
bool operator()() {
// Note that we have to re-evaluate size on each trip through the loop as
// the queue grows at the tail.
for (unsigned Idx = 0; Idx < Queue.size(); ++Idx) {
U = Queue[Idx].U;
Offset = Queue[Idx].Offset;
if (!visit(cast<Instruction>(U->getUser())))
return false;
}
return true;
}
private:
bool markAsEscaping(Instruction &I) {
P.PointerEscapingInstr = &I;
return false;
}
void insertUse(Instruction &I, int64_t Offset, uint64_t Size,
bool IsSplittable = false) {
// Completely skip uses which have a zero size or don't overlap the
// allocation.
if (Size == 0 ||
(Offset >= 0 && (uint64_t)Offset >= AllocSize) ||
(Offset < 0 && (uint64_t)-Offset >= Size)) {
DEBUG(dbgs() << "WARNING: Ignoring " << Size << " byte use @" << Offset
<< " which starts past the end of the " << AllocSize
<< " byte alloca:\n"
<< " alloca: " << P.AI << "\n"
<< " use: " << I << "\n");
return;
}
// Clamp the start to the beginning of the allocation.
if (Offset < 0) {
DEBUG(dbgs() << "WARNING: Clamping a " << Size << " byte use @" << Offset
<< " to start at the beginning of the alloca:\n"
<< " alloca: " << P.AI << "\n"
<< " use: " << I << "\n");
Size -= (uint64_t)-Offset;
Offset = 0;
}
uint64_t BeginOffset = Offset, EndOffset = BeginOffset + Size;
// Clamp the end offset to the end of the allocation. Note that this is
// formulated to handle even the case where "BeginOffset + Size" overflows.
assert(AllocSize >= BeginOffset); // Established above.
if (Size > AllocSize - BeginOffset) {
DEBUG(dbgs() << "WARNING: Clamping a " << Size << " byte use @" << Offset
<< " to remain within the " << AllocSize << " byte alloca:\n"
<< " alloca: " << P.AI << "\n"
<< " use: " << I << "\n");
EndOffset = AllocSize;
}
// See if we can just add a user onto the last slot currently occupied.
if (!P.Partitions.empty() &&
P.Partitions.back().BeginOffset == BeginOffset &&
P.Partitions.back().EndOffset == EndOffset) {
P.Partitions.back().IsSplittable &= IsSplittable;
return;
}
Partition New(BeginOffset, EndOffset, IsSplittable);
P.Partitions.push_back(New);
}
bool handleLoadOrStore(Type *Ty, Instruction &I, int64_t Offset) {
uint64_t Size = TD.getTypeStoreSize(Ty);
// If this memory access can be shown to *statically* extend outside the
// bounds of of the allocation, it's behavior is undefined, so simply
// ignore it. Note that this is more strict than the generic clamping
// behavior of insertUse. We also try to handle cases which might run the
// risk of overflow.
// FIXME: We should instead consider the pointer to have escaped if this
// function is being instrumented for addressing bugs or race conditions.
if (Offset < 0 || (uint64_t)Offset >= AllocSize ||
Size > (AllocSize - (uint64_t)Offset)) {
DEBUG(dbgs() << "WARNING: Ignoring " << Size << " byte "
<< (isa<LoadInst>(I) ? "load" : "store") << " @" << Offset
<< " which extends past the end of the " << AllocSize
<< " byte alloca:\n"
<< " alloca: " << P.AI << "\n"
<< " use: " << I << "\n");
return true;
}
insertUse(I, Offset, Size);
return true;
}
bool visitBitCastInst(BitCastInst &BC) {
enqueueUsers(BC, Offset);
return true;
}
bool visitGetElementPtrInst(GetElementPtrInst &GEPI) {
int64_t GEPOffset;
if (!computeConstantGEPOffset(GEPI, GEPOffset))
return markAsEscaping(GEPI);
enqueueUsers(GEPI, GEPOffset);
return true;
}
bool visitLoadInst(LoadInst &LI) {
assert((!LI.isSimple() || LI.getType()->isSingleValueType()) &&
"All simple FCA loads should have been pre-split");
return handleLoadOrStore(LI.getType(), LI, Offset);
}
bool visitStoreInst(StoreInst &SI) {
Value *ValOp = SI.getValueOperand();
if (ValOp == *U)
return markAsEscaping(SI);
assert((!SI.isSimple() || ValOp->getType()->isSingleValueType()) &&
"All simple FCA stores should have been pre-split");
return handleLoadOrStore(ValOp->getType(), SI, Offset);
}
bool visitMemSetInst(MemSetInst &II) {
assert(II.getRawDest() == *U && "Pointer use is not the destination?");
ConstantInt *Length = dyn_cast<ConstantInt>(II.getLength());
uint64_t Size = Length ? Length->getZExtValue() : AllocSize - Offset;
insertUse(II, Offset, Size, Length);
return true;
}
bool visitMemTransferInst(MemTransferInst &II) {
ConstantInt *Length = dyn_cast<ConstantInt>(II.getLength());
uint64_t Size = Length ? Length->getZExtValue() : AllocSize - Offset;
if (!Size)
// Zero-length mem transfer intrinsics can be ignored entirely.
return true;
MemTransferOffsets &Offsets = P.MemTransferInstData[&II];
// Only intrinsics with a constant length can be split.
Offsets.IsSplittable = Length;
if (*U != II.getRawDest()) {
assert(*U == II.getRawSource());
Offsets.SourceBegin = Offset;
Offsets.SourceEnd = Offset + Size;
} else {
Offsets.DestBegin = Offset;
Offsets.DestEnd = Offset + Size;
}
insertUse(II, Offset, Size, Offsets.IsSplittable);
unsigned NewIdx = P.Partitions.size() - 1;
SmallDenseMap<Instruction *, unsigned>::const_iterator PMI;
bool Inserted = false;
llvm::tie(PMI, Inserted)
= MemTransferPartitionMap.insert(std::make_pair(&II, NewIdx));
if (!Inserted && Offsets.IsSplittable) {
// We've found a memory transfer intrinsic which refers to the alloca as
// both a source and dest. We refuse to split these to simplify splitting
// logic. If possible, SROA will still split them into separate allocas
// and then re-analyze.
Offsets.IsSplittable = false;
P.Partitions[PMI->second].IsSplittable = false;
P.Partitions[NewIdx].IsSplittable = false;
}
return true;
}
// Disable SRoA for any intrinsics except for lifetime invariants.
// FIXME: What about debug instrinsics? This matches old behavior, but
// doesn't make sense.
bool visitIntrinsicInst(IntrinsicInst &II) {
if (II.getIntrinsicID() == Intrinsic::lifetime_start ||
II.getIntrinsicID() == Intrinsic::lifetime_end) {
ConstantInt *Length = cast<ConstantInt>(II.getArgOperand(0));
uint64_t Size = std::min(AllocSize - Offset, Length->getLimitedValue());
insertUse(II, Offset, Size, true);
return true;
}
return markAsEscaping(II);
}
Instruction *hasUnsafePHIOrSelectUse(Instruction *Root, uint64_t &Size) {
// We consider any PHI or select that results in a direct load or store of
// the same offset to be a viable use for partitioning purposes. These uses
// are considered unsplittable and the size is the maximum loaded or stored
// size.
SmallPtrSet<Instruction *, 4> Visited;
SmallVector<std::pair<Instruction *, Instruction *>, 4> Uses;
Visited.insert(Root);
Uses.push_back(std::make_pair(cast<Instruction>(*U), Root));
// If there are no loads or stores, the access is dead. We mark that as
// a size zero access.
Size = 0;
do {
Instruction *I, *UsedI;
llvm::tie(UsedI, I) = Uses.pop_back_val();
if (LoadInst *LI = dyn_cast<LoadInst>(I)) {
Size = std::max(Size, TD.getTypeStoreSize(LI->getType()));
continue;
}
if (StoreInst *SI = dyn_cast<StoreInst>(I)) {
Value *Op = SI->getOperand(0);
if (Op == UsedI)
return SI;
Size = std::max(Size, TD.getTypeStoreSize(Op->getType()));
continue;
}
if (GetElementPtrInst *GEP = dyn_cast<GetElementPtrInst>(I)) {
if (!GEP->hasAllZeroIndices())
return GEP;
} else if (!isa<BitCastInst>(I) && !isa<PHINode>(I) &&
!isa<SelectInst>(I)) {
return I;
}
for (Value::use_iterator UI = I->use_begin(), UE = I->use_end(); UI != UE;
++UI)
if (Visited.insert(cast<Instruction>(*UI)))
Uses.push_back(std::make_pair(I, cast<Instruction>(*UI)));
} while (!Uses.empty());
return 0;
}
bool visitPHINode(PHINode &PN) {
// See if we already have computed info on this node.
std::pair<uint64_t, bool> &PHIInfo = P.PHIOrSelectSizes[&PN];
if (PHIInfo.first) {
PHIInfo.second = true;
insertUse(PN, Offset, PHIInfo.first);
return true;
}
// Check for an unsafe use of the PHI node.
if (Instruction *EscapingI = hasUnsafePHIOrSelectUse(&PN, PHIInfo.first))
return markAsEscaping(*EscapingI);
insertUse(PN, Offset, PHIInfo.first);
return true;
}
bool visitSelectInst(SelectInst &SI) {
if (Value *Result = foldSelectInst(SI)) {
if (Result == *U)
// If the result of the constant fold will be the pointer, recurse
// through the select as if we had RAUW'ed it.
enqueueUsers(SI, Offset);
return true;
}
// See if we already have computed info on this node.
std::pair<uint64_t, bool> &SelectInfo = P.PHIOrSelectSizes[&SI];
if (SelectInfo.first) {
SelectInfo.second = true;
insertUse(SI, Offset, SelectInfo.first);
return true;
}
// Check for an unsafe use of the PHI node.
if (Instruction *EscapingI = hasUnsafePHIOrSelectUse(&SI, SelectInfo.first))
return markAsEscaping(*EscapingI);
insertUse(SI, Offset, SelectInfo.first);
return true;
}
/// \brief Disable SROA entirely if there are unhandled users of the alloca.
bool visitInstruction(Instruction &I) { return markAsEscaping(I); }
};
/// \brief Use adder for the alloca partitioning.
///
/// This class adds the uses of an alloca to all of the partitions which they
/// use. For splittable partitions, this can end up doing essentially a linear
/// walk of the partitions, but the number of steps remains bounded by the
/// total result instruction size:
/// - The number of partitions is a result of the number unsplittable
/// instructions using the alloca.
/// - The number of users of each partition is at worst the total number of
/// splittable instructions using the alloca.
/// Thus we will produce N * M instructions in the end, where N are the number
/// of unsplittable uses and M are the number of splittable. This visitor does
/// the exact same number of updates to the partitioning.
///
/// In the more common case, this visitor will leverage the fact that the
/// partition space is pre-sorted, and do a logarithmic search for the
/// partition needed, making the total visit a classical ((N + M) * log(N))
/// complexity operation.
class AllocaPartitioning::UseBuilder : public BuilderBase<UseBuilder> {
friend class InstVisitor<UseBuilder>;
/// \brief Set to de-duplicate dead instructions found in the use walk.
SmallPtrSet<Instruction *, 4> VisitedDeadInsts;
public:
UseBuilder(const TargetData &TD, AllocaInst &AI, AllocaPartitioning &P)
: BuilderBase<UseBuilder>(TD, AI, P) {}
/// \brief Run the builder over the allocation.
void operator()() {
// Note that we have to re-evaluate size on each trip through the loop as
// the queue grows at the tail.
for (unsigned Idx = 0; Idx < Queue.size(); ++Idx) {
U = Queue[Idx].U;
Offset = Queue[Idx].Offset;
this->visit(cast<Instruction>(U->getUser()));
}
}
private:
void markAsDead(Instruction &I) {
if (VisitedDeadInsts.insert(&I))
P.DeadUsers.push_back(&I);
}
void insertUse(Instruction &User, int64_t Offset, uint64_t Size) {
// If the use has a zero size or extends outside of the allocation, record
// it as a dead use for elimination later.
if (Size == 0 || (uint64_t)Offset >= AllocSize ||
(Offset < 0 && (uint64_t)-Offset >= Size))
return markAsDead(User);
// Clamp the start to the beginning of the allocation.
if (Offset < 0) {
Size -= (uint64_t)-Offset;
Offset = 0;
}
uint64_t BeginOffset = Offset, EndOffset = BeginOffset + Size;
// Clamp the end offset to the end of the allocation. Note that this is
// formulated to handle even the case where "BeginOffset + Size" overflows.
assert(AllocSize >= BeginOffset); // Established above.
if (Size > AllocSize - BeginOffset)
EndOffset = AllocSize;
// NB: This only works if we have zero overlapping partitions.
iterator B = std::lower_bound(P.begin(), P.end(), BeginOffset);
if (B != P.begin() && llvm::prior(B)->EndOffset > BeginOffset)
B = llvm::prior(B);
for (iterator I = B, E = P.end(); I != E && I->BeginOffset < EndOffset;
++I) {
PartitionUse NewUse(std::max(I->BeginOffset, BeginOffset),
std::min(I->EndOffset, EndOffset),
&User, cast<Instruction>(*U));
P.use_push_back(I, NewUse);
if (isa<PHINode>(U->getUser()) || isa<SelectInst>(U->getUser()))
P.PHIOrSelectOpMap[std::make_pair(&User, U->get())]
= std::make_pair(I - P.begin(), P.Uses[I - P.begin()].size() - 1);
}
}
void handleLoadOrStore(Type *Ty, Instruction &I, int64_t Offset) {
uint64_t Size = TD.getTypeStoreSize(Ty);
// If this memory access can be shown to *statically* extend outside the
// bounds of of the allocation, it's behavior is undefined, so simply
// ignore it. Note that this is more strict than the generic clamping
// behavior of insertUse.
if (Offset < 0 || (uint64_t)Offset >= AllocSize ||
Size > (AllocSize - (uint64_t)Offset))
return markAsDead(I);
insertUse(I, Offset, Size);
}
void visitBitCastInst(BitCastInst &BC) {
if (BC.use_empty())
return markAsDead(BC);
enqueueUsers(BC, Offset);
}
void visitGetElementPtrInst(GetElementPtrInst &GEPI) {
if (GEPI.use_empty())
return markAsDead(GEPI);
int64_t GEPOffset;
if (!computeConstantGEPOffset(GEPI, GEPOffset))
llvm_unreachable("Unable to compute constant offset for use");
enqueueUsers(GEPI, GEPOffset);
}
void visitLoadInst(LoadInst &LI) {
handleLoadOrStore(LI.getType(), LI, Offset);
}
void visitStoreInst(StoreInst &SI) {
handleLoadOrStore(SI.getOperand(0)->getType(), SI, Offset);
}
void visitMemSetInst(MemSetInst &II) {
ConstantInt *Length = dyn_cast<ConstantInt>(II.getLength());
uint64_t Size = Length ? Length->getZExtValue() : AllocSize - Offset;
insertUse(II, Offset, Size);
}
void visitMemTransferInst(MemTransferInst &II) {
ConstantInt *Length = dyn_cast<ConstantInt>(II.getLength());
uint64_t Size = Length ? Length->getZExtValue() : AllocSize - Offset;
insertUse(II, Offset, Size);
}
void visitIntrinsicInst(IntrinsicInst &II) {
assert(II.getIntrinsicID() == Intrinsic::lifetime_start ||
II.getIntrinsicID() == Intrinsic::lifetime_end);
ConstantInt *Length = cast<ConstantInt>(II.getArgOperand(0));
insertUse(II, Offset,
std::min(AllocSize - Offset, Length->getLimitedValue()));
}
void insertPHIOrSelect(Instruction &User, uint64_t Offset) {
uint64_t Size = P.PHIOrSelectSizes.lookup(&User).first;
// For PHI and select operands outside the alloca, we can't nuke the entire
// phi or select -- the other side might still be relevant, so we special
// case them here and use a separate structure to track the operands
// themselves which should be replaced with undef.
if (Offset >= AllocSize) {
P.DeadOperands.push_back(U);
return;
}
insertUse(User, Offset, Size);
}
void visitPHINode(PHINode &PN) {
if (PN.use_empty())
return markAsDead(PN);
insertPHIOrSelect(PN, Offset);
}
void visitSelectInst(SelectInst &SI) {
if (SI.use_empty())
return markAsDead(SI);
if (Value *Result = foldSelectInst(SI)) {
if (Result == *U)
// If the result of the constant fold will be the pointer, recurse
// through the select as if we had RAUW'ed it.
enqueueUsers(SI, Offset);
else
// Otherwise the operand to the select is dead, and we can replace it
// with undef.
P.DeadOperands.push_back(U);
return;
}
insertPHIOrSelect(SI, Offset);
}
/// \brief Unreachable, we've already visited the alloca once.
void visitInstruction(Instruction &I) {
llvm_unreachable("Unhandled instruction in use builder.");
}
};
void AllocaPartitioning::splitAndMergePartitions() {
size_t NumDeadPartitions = 0;
// Track the range of splittable partitions that we pass when accumulating
// overlapping unsplittable partitions.
uint64_t SplitEndOffset = 0ull;
Partition New(0ull, 0ull, false);
for (unsigned i = 0, j = i, e = Partitions.size(); i != e; i = j) {
++j;
if (!Partitions[i].IsSplittable || New.BeginOffset == New.EndOffset) {
assert(New.BeginOffset == New.EndOffset);
New = Partitions[i];
} else {
assert(New.IsSplittable);
New.EndOffset = std::max(New.EndOffset, Partitions[i].EndOffset);
}
assert(New.BeginOffset != New.EndOffset);
// Scan the overlapping partitions.
while (j != e && New.EndOffset > Partitions[j].BeginOffset) {
// If the new partition we are forming is splittable, stop at the first
// unsplittable partition.
if (New.IsSplittable && !Partitions[j].IsSplittable)
break;
// Grow the new partition to include any equally splittable range. 'j' is
// always equally splittable when New is splittable, but when New is not
// splittable, we may subsume some (or part of some) splitable partition
// without growing the new one.
if (New.IsSplittable == Partitions[j].IsSplittable) {
New.EndOffset = std::max(New.EndOffset, Partitions[j].EndOffset);
} else {
assert(!New.IsSplittable);
assert(Partitions[j].IsSplittable);
SplitEndOffset = std::max(SplitEndOffset, Partitions[j].EndOffset);
}
Partitions[j].BeginOffset = Partitions[j].EndOffset = UINT64_MAX;
++NumDeadPartitions;
++j;
}
// If the new partition is splittable, chop off the end as soon as the
// unsplittable subsequent partition starts and ensure we eventually cover
// the splittable area.
if (j != e && New.IsSplittable) {
SplitEndOffset = std::max(SplitEndOffset, New.EndOffset);
New.EndOffset = std::min(New.EndOffset, Partitions[j].BeginOffset);
}
// Add the new partition if it differs from the original one and is
// non-empty. We can end up with an empty partition here if it was
// splittable but there is an unsplittable one that starts at the same
// offset.
if (New != Partitions[i]) {
if (New.BeginOffset != New.EndOffset)
Partitions.push_back(New);
// Mark the old one for removal.
Partitions[i].BeginOffset = Partitions[i].EndOffset = UINT64_MAX;
++NumDeadPartitions;
}
New.BeginOffset = New.EndOffset;
if (!New.IsSplittable) {
New.EndOffset = std::max(New.EndOffset, SplitEndOffset);
if (j != e && !Partitions[j].IsSplittable)
New.EndOffset = std::min(New.EndOffset, Partitions[j].BeginOffset);
New.IsSplittable = true;
// If there is a trailing splittable partition which won't be fused into
// the next splittable partition go ahead and add it onto the partitions
// list.
if (New.BeginOffset < New.EndOffset &&
(j == e || !Partitions[j].IsSplittable ||
New.EndOffset < Partitions[j].BeginOffset)) {
Partitions.push_back(New);
New.BeginOffset = New.EndOffset = 0ull;
}
}
}
// Re-sort the partitions now that they have been split and merged into
// disjoint set of partitions. Also remove any of the dead partitions we've
// replaced in the process.
std::sort(Partitions.begin(), Partitions.end());
if (NumDeadPartitions) {
assert(Partitions.back().BeginOffset == UINT64_MAX);
assert(Partitions.back().EndOffset == UINT64_MAX);
assert((ptrdiff_t)NumDeadPartitions ==
std::count(Partitions.begin(), Partitions.end(), Partitions.back()));
}
Partitions.erase(Partitions.end() - NumDeadPartitions, Partitions.end());
}
AllocaPartitioning::AllocaPartitioning(const TargetData &TD, AllocaInst &AI)
:
#ifndef NDEBUG
AI(AI),
#endif
PointerEscapingInstr(0) {
PartitionBuilder PB(TD, AI, *this);
if (!PB())
return;
if (Partitions.size() > 1) {
// Sort the uses. This arranges for the offsets to be in ascending order,
// and the sizes to be in descending order.
std::sort(Partitions.begin(), Partitions.end());
// Intersect splittability for all partitions with equal offsets and sizes.
// Then remove all but the first so that we have a sequence of non-equal but
// potentially overlapping partitions.
for (iterator I = Partitions.begin(), J = I, E = Partitions.end(); I != E;
I = J) {
++J;
while (J != E && *I == *J) {
I->IsSplittable &= J->IsSplittable;
++J;
}
}
Partitions.erase(std::unique(Partitions.begin(), Partitions.end()),
Partitions.end());
// Split splittable and merge unsplittable partitions into a disjoint set
// of partitions over the used space of the allocation.
splitAndMergePartitions();
}
// Now build up the user lists for each of these disjoint partitions by
// re-walking the recursive users of the alloca.
Uses.resize(Partitions.size());
UseBuilder UB(TD, AI, *this);
UB();
}
Type *AllocaPartitioning::getCommonType(iterator I) const {
Type *Ty = 0;
for (const_use_iterator UI = use_begin(I), UE = use_end(I); UI != UE; ++UI) {
if (isa<IntrinsicInst>(*UI->User))
continue;
if (UI->BeginOffset != I->BeginOffset || UI->EndOffset != I->EndOffset)
continue;
Type *UserTy = 0;
if (LoadInst *LI = dyn_cast<LoadInst>(&*UI->User)) {
UserTy = LI->getType();
} else if (StoreInst *SI = dyn_cast<StoreInst>(&*UI->User)) {
UserTy = SI->getValueOperand()->getType();
} else if (SelectInst *SI = dyn_cast<SelectInst>(&*UI->User)) {
if (PointerType *PtrTy = dyn_cast<PointerType>(SI->getType()))
UserTy = PtrTy->getElementType();
} else if (PHINode *PN = dyn_cast<PHINode>(&*UI->User)) {
if (PointerType *PtrTy = dyn_cast<PointerType>(PN->getType()))
UserTy = PtrTy->getElementType();
}
if (Ty && Ty != UserTy)
return 0;
Ty = UserTy;
}
return Ty;
}
#if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
void AllocaPartitioning::print(raw_ostream &OS, const_iterator I,
StringRef Indent) const {
OS << Indent << "partition #" << (I - begin())
<< " [" << I->BeginOffset << "," << I->EndOffset << ")"
<< (I->IsSplittable ? " (splittable)" : "")
<< (Uses[I - begin()].empty() ? " (zero uses)" : "")
<< "\n";
}
void AllocaPartitioning::printUsers(raw_ostream &OS, const_iterator I,
StringRef Indent) const {
for (const_use_iterator UI = use_begin(I), UE = use_end(I);
UI != UE; ++UI) {
OS << Indent << " [" << UI->BeginOffset << "," << UI->EndOffset << ") "
<< "used by: " << *UI->User << "\n";
if (MemTransferInst *II = dyn_cast<MemTransferInst>(&*UI->User)) {
const MemTransferOffsets &MTO = MemTransferInstData.lookup(II);
bool IsDest;
if (!MTO.IsSplittable)
IsDest = UI->BeginOffset == MTO.DestBegin;
else
IsDest = MTO.DestBegin != 0u;
OS << Indent << " (original " << (IsDest ? "dest" : "source") << ": "
<< "[" << (IsDest ? MTO.DestBegin : MTO.SourceBegin)
<< "," << (IsDest ? MTO.DestEnd : MTO.SourceEnd) << ")\n";
}
}
}
void AllocaPartitioning::print(raw_ostream &OS) const {
if (PointerEscapingInstr) {
OS << "No partitioning for alloca: " << AI << "\n"
<< " A pointer to this alloca escaped by:\n"
<< " " << *PointerEscapingInstr << "\n";
return;
}
OS << "Partitioning of alloca: " << AI << "\n";
unsigned Num = 0;
for (const_iterator I = begin(), E = end(); I != E; ++I, ++Num) {
print(OS, I);
printUsers(OS, I);
}
}
void AllocaPartitioning::dump(const_iterator I) const { print(dbgs(), I); }
void AllocaPartitioning::dump() const { print(dbgs()); }
#endif // !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
namespace {
/// \brief Implementation of LoadAndStorePromoter for promoting allocas.
///
/// This subclass of LoadAndStorePromoter adds overrides to handle promoting
/// the loads and stores of an alloca instruction, as well as updating its
/// debug information. This is used when a domtree is unavailable and thus
/// mem2reg in its full form can't be used to handle promotion of allocas to
/// scalar values.
class AllocaPromoter : public LoadAndStorePromoter {
AllocaInst &AI;
DIBuilder &DIB;
SmallVector<DbgDeclareInst *, 4> DDIs;
SmallVector<DbgValueInst *, 4> DVIs;
public:
AllocaPromoter(const SmallVectorImpl<Instruction*> &Insts, SSAUpdater &S,
AllocaInst &AI, DIBuilder &DIB)
: LoadAndStorePromoter(Insts, S), AI(AI), DIB(DIB) {}
void run(const SmallVectorImpl<Instruction*> &Insts) {
// Remember which alloca we're promoting (for isInstInList).
if (MDNode *DebugNode = MDNode::getIfExists(AI.getContext(), &AI)) {
for (Value::use_iterator UI = DebugNode->use_begin(),
UE = DebugNode->use_end();
UI != UE; ++UI)
if (DbgDeclareInst *DDI = dyn_cast<DbgDeclareInst>(*UI))
DDIs.push_back(DDI);
else if (DbgValueInst *DVI = dyn_cast<DbgValueInst>(*UI))
DVIs.push_back(DVI);
}
LoadAndStorePromoter::run(Insts);
AI.eraseFromParent();
while (!DDIs.empty())
DDIs.pop_back_val()->eraseFromParent();
while (!DVIs.empty())
DVIs.pop_back_val()->eraseFromParent();
}
virtual bool isInstInList(Instruction *I,
const SmallVectorImpl<Instruction*> &Insts) const {
if (LoadInst *LI = dyn_cast<LoadInst>(I))
return LI->getOperand(0) == &AI;
return cast<StoreInst>(I)->getPointerOperand() == &AI;
}
virtual void updateDebugInfo(Instruction *Inst) const {
for (SmallVector<DbgDeclareInst *, 4>::const_iterator I = DDIs.begin(),
E = DDIs.end(); I != E; ++I) {
DbgDeclareInst *DDI = *I;
if (StoreInst *SI = dyn_cast<StoreInst>(Inst))
ConvertDebugDeclareToDebugValue(DDI, SI, DIB);
else if (LoadInst *LI = dyn_cast<LoadInst>(Inst))
ConvertDebugDeclareToDebugValue(DDI, LI, DIB);
}
for (SmallVector<DbgValueInst *, 4>::const_iterator I = DVIs.begin(),
E = DVIs.end(); I != E; ++I) {
DbgValueInst *DVI = *I;
Value *Arg = NULL;
if (StoreInst *SI = dyn_cast<StoreInst>(Inst)) {
// If an argument is zero extended then use argument directly. The ZExt
// may be zapped by an optimization pass in future.
if (ZExtInst *ZExt = dyn_cast<ZExtInst>(SI->getOperand(0)))
Arg = dyn_cast<Argument>(ZExt->getOperand(0));
if (SExtInst *SExt = dyn_cast<SExtInst>(SI->getOperand(0)))
Arg = dyn_cast<Argument>(SExt->getOperand(0));
if (!Arg)
Arg = SI->getOperand(0);
} else if (LoadInst *LI = dyn_cast<LoadInst>(Inst)) {
Arg = LI->getOperand(0);
} else {
continue;
}
Instruction *DbgVal =
DIB.insertDbgValueIntrinsic(Arg, 0, DIVariable(DVI->getVariable()),
Inst);
DbgVal->setDebugLoc(DVI->getDebugLoc());
}
}
};
} // end anon namespace
namespace {
/// \brief An optimization pass providing Scalar Replacement of Aggregates.
///
/// This pass takes allocations which can be completely analyzed (that is, they
/// don't escape) and tries to turn them into scalar SSA values. There are
/// a few steps to this process.
///
/// 1) It takes allocations of aggregates and analyzes the ways in which they
/// are used to try to split them into smaller allocations, ideally of
/// a single scalar data type. It will split up memcpy and memset accesses
/// as necessary and try to isolate invidual scalar accesses.
/// 2) It will transform accesses into forms which are suitable for SSA value
/// promotion. This can be replacing a memset with a scalar store of an
/// integer value, or it can involve speculating operations on a PHI or
/// select to be a PHI or select of the results.
/// 3) Finally, this will try to detect a pattern of accesses which map cleanly
/// onto insert and extract operations on a vector value, and convert them to
/// this form. By doing so, it will enable promotion of vector aggregates to
/// SSA vector values.
class SROA : public FunctionPass {
const bool RequiresDomTree;
LLVMContext *C;
const TargetData *TD;
DominatorTree *DT;
/// \brief Worklist of alloca instructions to simplify.
///
/// Each alloca in the function is added to this. Each new alloca formed gets
/// added to it as well to recursively simplify unless that alloca can be
/// directly promoted. Finally, each time we rewrite a use of an alloca other
/// the one being actively rewritten, we add it back onto the list if not
/// already present to ensure it is re-visited.
SetVector<AllocaInst *, SmallVector<AllocaInst *, 16> > Worklist;
/// \brief A collection of instructions to delete.
/// We try to batch deletions to simplify code and make things a bit more
/// efficient.
SmallVector<Instruction *, 8> DeadInsts;
/// \brief A set to prevent repeatedly marking an instruction split into many
/// uses as dead. Only used to guard insertion into DeadInsts.
SmallPtrSet<Instruction *, 4> DeadSplitInsts;
/// \brief A collection of alloca instructions we can directly promote.
std::vector<AllocaInst *> PromotableAllocas;
public:
SROA(bool RequiresDomTree = true)
: FunctionPass(ID), RequiresDomTree(RequiresDomTree),
C(0), TD(0), DT(0) {
initializeSROAPass(*PassRegistry::getPassRegistry());
}
bool runOnFunction(Function &F);
void getAnalysisUsage(AnalysisUsage &AU) const;
const char *getPassName() const { return "SROA"; }
static char ID;
private:
friend class AllocaPartitionRewriter;
friend class AllocaPartitionVectorRewriter;
bool rewriteAllocaPartition(AllocaInst &AI,
AllocaPartitioning &P,
AllocaPartitioning::iterator PI);
bool splitAlloca(AllocaInst &AI, AllocaPartitioning &P);
bool runOnAlloca(AllocaInst &AI);
void deleteDeadInstructions(SmallPtrSet<AllocaInst *, 4> &DeletedAllocas);
bool promoteAllocas(Function &F);
};
}
char SROA::ID = 0;
FunctionPass *llvm::createSROAPass(bool RequiresDomTree) {
return new SROA(RequiresDomTree);
}
INITIALIZE_PASS_BEGIN(SROA, "sroa", "Scalar Replacement Of Aggregates",
false, false)
INITIALIZE_PASS_DEPENDENCY(DominatorTree)
INITIALIZE_PASS_END(SROA, "sroa", "Scalar Replacement Of Aggregates",
false, false)
/// \brief Accumulate the constant offsets in a GEP into a single APInt offset.
///
/// If the provided GEP is all-constant, the total byte offset formed by the
/// GEP is computed and Offset is set to it. If the GEP has any non-constant
/// operands, the function returns false and the value of Offset is unmodified.
static bool accumulateGEPOffsets(const TargetData &TD, GEPOperator &GEP,
APInt &Offset) {
APInt GEPOffset(Offset.getBitWidth(), 0);
for (gep_type_iterator GTI = gep_type_begin(GEP), GTE = gep_type_end(GEP);
GTI != GTE; ++GTI) {
ConstantInt *OpC = dyn_cast<ConstantInt>(GTI.getOperand());
if (!OpC)
return false;
if (OpC->isZero()) continue;
// Handle a struct index, which adds its field offset to the pointer.
if (StructType *STy = dyn_cast<StructType>(*GTI)) {
unsigned ElementIdx = OpC->getZExtValue();
const StructLayout *SL = TD.getStructLayout(STy);
GEPOffset += APInt(Offset.getBitWidth(),
SL->getElementOffset(ElementIdx));
continue;
}
APInt TypeSize(Offset.getBitWidth(),
TD.getTypeAllocSize(GTI.getIndexedType()));
if (VectorType *VTy = dyn_cast<VectorType>(*GTI)) {
assert((VTy->getScalarSizeInBits() % 8) == 0 &&
"vector element size is not a multiple of 8, cannot GEP over it");
TypeSize = VTy->getScalarSizeInBits() / 8;
}
GEPOffset += OpC->getValue().sextOrTrunc(Offset.getBitWidth()) * TypeSize;
}
Offset = GEPOffset;
return true;
}
/// \brief Build a GEP out of a base pointer and indices.
///
/// This will return the BasePtr if that is valid, or build a new GEP
/// instruction using the IRBuilder if GEP-ing is needed.
static Value *buildGEP(IRBuilder<> &IRB, Value *BasePtr,
SmallVectorImpl<Value *> &Indices,
const Twine &Prefix) {
if (Indices.empty())
return BasePtr;
// A single zero index is a no-op, so check for this and avoid building a GEP
// in that case.
if (Indices.size() == 1 && cast<ConstantInt>(Indices.back())->isZero())
return BasePtr;
return IRB.CreateInBoundsGEP(BasePtr, Indices, Prefix + ".idx");
}
/// \brief Get a natural GEP off of the BasePtr walking through Ty toward
/// TargetTy without changing the offset of the pointer.
///
/// This routine assumes we've already established a properly offset GEP with
/// Indices, and arrived at the Ty type. The goal is to continue to GEP with
/// zero-indices down through type layers until we find one the same as
/// TargetTy. If we can't find one with the same type, we at least try to use
/// one with the same size. If none of that works, we just produce the GEP as
/// indicated by Indices to have the correct offset.
static Value *getNaturalGEPWithType(IRBuilder<> &IRB, const TargetData &TD,
Value *BasePtr, Type *Ty, Type *TargetTy,
SmallVectorImpl<Value *> &Indices,
const Twine &Prefix) {
if (Ty == TargetTy)
return buildGEP(IRB, BasePtr, Indices, Prefix);
// See if we can descend into a struct and locate a field with the correct
// type.
unsigned NumLayers = 0;
Type *ElementTy = Ty;
do {
if (ElementTy->isPointerTy())
break;
if (SequentialType *SeqTy = dyn_cast<SequentialType>(ElementTy)) {
ElementTy = SeqTy->getElementType();
Indices.push_back(IRB.getInt(APInt(TD.getPointerSizeInBits(), 0)));
} else if (StructType *STy = dyn_cast<StructType>(ElementTy)) {
ElementTy = *STy->element_begin();
Indices.push_back(IRB.getInt32(0));
} else {
break;
}
++NumLayers;
} while (ElementTy != TargetTy);
if (ElementTy != TargetTy)
Indices.erase(Indices.end() - NumLayers, Indices.end());
return buildGEP(IRB, BasePtr, Indices, Prefix);
}
/// \brief Recursively compute indices for a natural GEP.
///
/// This is the recursive step for getNaturalGEPWithOffset that walks down the
/// element types adding appropriate indices for the GEP.
static Value *getNaturalGEPRecursively(IRBuilder<> &IRB, const TargetData &TD,
Value *Ptr, Type *Ty, APInt &Offset,
Type *TargetTy,
SmallVectorImpl<Value *> &Indices,
const Twine &Prefix) {
if (Offset == 0)
return getNaturalGEPWithType(IRB, TD, Ptr, Ty, TargetTy, Indices, Prefix);
// We can't recurse through pointer types.
if (Ty->isPointerTy())
return 0;
// We try to analyze GEPs over vectors here, but note that these GEPs are
// extremely poorly defined currently. The long-term goal is to remove GEPing
// over a vector from the IR completely.
if (VectorType *VecTy = dyn_cast<VectorType>(Ty)) {
unsigned ElementSizeInBits = VecTy->getScalarSizeInBits();
if (ElementSizeInBits % 8)
return 0; // GEPs over non-multiple of 8 size vector elements are invalid.
APInt ElementSize(Offset.getBitWidth(), ElementSizeInBits / 8);
APInt NumSkippedElements = Offset.udiv(ElementSize);
if (NumSkippedElements.ugt(VecTy->getNumElements()))
return 0;
Offset -= NumSkippedElements * ElementSize;
Indices.push_back(IRB.getInt(NumSkippedElements));
return getNaturalGEPRecursively(IRB, TD, Ptr, VecTy->getElementType(),
Offset, TargetTy, Indices, Prefix);
}
if (ArrayType *ArrTy = dyn_cast<ArrayType>(Ty)) {
Type *ElementTy = ArrTy->getElementType();
APInt ElementSize(Offset.getBitWidth(), TD.getTypeAllocSize(ElementTy));
APInt NumSkippedElements = Offset.udiv(ElementSize);
if (NumSkippedElements.ugt(ArrTy->getNumElements()))
return 0;
Offset -= NumSkippedElements * ElementSize;
Indices.push_back(IRB.getInt(NumSkippedElements));
return getNaturalGEPRecursively(IRB, TD, Ptr, ElementTy, Offset, TargetTy,
Indices, Prefix);
}
StructType *STy = dyn_cast<StructType>(Ty);
if (!STy)
return 0;
const StructLayout *SL = TD.getStructLayout(STy);
uint64_t StructOffset = Offset.getZExtValue();
if (StructOffset >= SL->getSizeInBytes())
return 0;
unsigned Index = SL->getElementContainingOffset(StructOffset);
Offset -= APInt(Offset.getBitWidth(), SL->getElementOffset(Index));
Type *ElementTy = STy->getElementType(Index);
if (Offset.uge(TD.getTypeAllocSize(ElementTy)))
return 0; // The offset points into alignment padding.
Indices.push_back(IRB.getInt32(Index));
return getNaturalGEPRecursively(IRB, TD, Ptr, ElementTy, Offset, TargetTy,
Indices, Prefix);
}
/// \brief Get a natural GEP from a base pointer to a particular offset and
/// resulting in a particular type.
///
/// The goal is to produce a "natural" looking GEP that works with the existing
/// composite types to arrive at the appropriate offset and element type for
/// a pointer. TargetTy is the element type the returned GEP should point-to if
/// possible. We recurse by decreasing Offset, adding the appropriate index to
/// Indices, and setting Ty to the result subtype.
///
/// If no natural GEP can be constructed, this function returns null.
static Value *getNaturalGEPWithOffset(IRBuilder<> &IRB, const TargetData &TD,
Value *Ptr, APInt Offset, Type *TargetTy,
SmallVectorImpl<Value *> &Indices,
const Twine &Prefix) {
PointerType *Ty = cast<PointerType>(Ptr->getType());
// Don't consider any GEPs through an i8* as natural unless the TargetTy is
// an i8.
if (Ty == IRB.getInt8PtrTy() && TargetTy->isIntegerTy(8))
return 0;
Type *ElementTy = Ty->getElementType();
if (!ElementTy->isSized())
return 0; // We can't GEP through an unsized element.
APInt ElementSize(Offset.getBitWidth(), TD.getTypeAllocSize(ElementTy));
if (ElementSize == 0)
return 0; // Zero-length arrays can't help us build a natural GEP.
APInt NumSkippedElements = Offset.udiv(ElementSize);
Offset -= NumSkippedElements * ElementSize;
Indices.push_back(IRB.getInt(NumSkippedElements));
return getNaturalGEPRecursively(IRB, TD, Ptr, ElementTy, Offset, TargetTy,
Indices, Prefix);
}
/// \brief Compute an adjusted pointer from Ptr by Offset bytes where the
/// resulting pointer has PointerTy.
///
/// This tries very hard to compute a "natural" GEP which arrives at the offset
/// and produces the pointer type desired. Where it cannot, it will try to use
/// the natural GEP to arrive at the offset and bitcast to the type. Where that
/// fails, it will try to use an existing i8* and GEP to the byte offset and
/// bitcast to the type.
///
/// The strategy for finding the more natural GEPs is to peel off layers of the
/// pointer, walking back through bit casts and GEPs, searching for a base
/// pointer from which we can compute a natural GEP with the desired
/// properities. The algorithm tries to fold as many constant indices into
/// a single GEP as possible, thus making each GEP more independent of the
/// surrounding code.
static Value *getAdjustedPtr(IRBuilder<> &IRB, const TargetData &TD,
Value *Ptr, APInt Offset, Type *PointerTy,
const Twine &Prefix) {
// Even though we don't look through PHI nodes, we could be called on an
// instruction in an unreachable block, which may be on a cycle.
SmallPtrSet<Value *, 4> Visited;
Visited.insert(Ptr);
SmallVector<Value *, 4> Indices;
// We may end up computing an offset pointer that has the wrong type. If we
// never are able to compute one directly that has the correct type, we'll
// fall back to it, so keep it around here.
Value *OffsetPtr = 0;
// Remember any i8 pointer we come across to re-use if we need to do a raw
// byte offset.
Value *Int8Ptr = 0;
APInt Int8PtrOffset(Offset.getBitWidth(), 0);
Type *TargetTy = PointerTy->getPointerElementType();
do {
// First fold any existing GEPs into the offset.
while (GEPOperator *GEP = dyn_cast<GEPOperator>(Ptr)) {
APInt GEPOffset(Offset.getBitWidth(), 0);
if (!accumulateGEPOffsets(TD, *GEP, GEPOffset))
break;
Offset += GEPOffset;
Ptr = GEP->getPointerOperand();
if (!Visited.insert(Ptr))
break;
}
// See if we can perform a natural GEP here.
Indices.clear();
if (Value *P = getNaturalGEPWithOffset(IRB, TD, Ptr, Offset, TargetTy,
Indices, Prefix)) {
if (P->getType() == PointerTy) {
// Zap any offset pointer that we ended up computing in previous rounds.
if (OffsetPtr && OffsetPtr->use_empty())
if (Instruction *I = dyn_cast<Instruction>(OffsetPtr))
I->eraseFromParent();
return P;
}
if (!OffsetPtr) {
OffsetPtr = P;
}
}
// Stash this pointer if we've found an i8*.
if (Ptr->getType()->isIntegerTy(8)) {
Int8Ptr = Ptr;
Int8PtrOffset = Offset;
}
// Peel off a layer of the pointer and update the offset appropriately.
if (Operator::getOpcode(Ptr) == Instruction::BitCast) {
Ptr = cast<Operator>(Ptr)->getOperand(0);
} else if (GlobalAlias *GA = dyn_cast<GlobalAlias>(Ptr)) {
if (GA->mayBeOverridden())
break;
Ptr = GA->getAliasee();
} else {
break;
}
assert(Ptr->getType()->isPointerTy() && "Unexpected operand type!");
} while (Visited.insert(Ptr));
if (!OffsetPtr) {
if (!Int8Ptr) {
Int8Ptr = IRB.CreateBitCast(Ptr, IRB.getInt8PtrTy(),
Prefix + ".raw_cast");
Int8PtrOffset = Offset;
}
OffsetPtr = Int8PtrOffset == 0 ? Int8Ptr :
IRB.CreateInBoundsGEP(Int8Ptr, IRB.getInt(Int8PtrOffset),
Prefix + ".raw_idx");
}
Ptr = OffsetPtr;
// On the off chance we were targeting i8*, guard the bitcast here.
if (Ptr->getType() != PointerTy)
Ptr = IRB.CreateBitCast(Ptr, PointerTy, Prefix + ".cast");
return Ptr;
}
/// \brief Test whether the given alloca partition can be promoted to a vector.
///
/// This is a quick test to check whether we can rewrite a particular alloca
/// partition (and its newly formed alloca) into a vector alloca with only
/// whole-vector loads and stores such that it could be promoted to a vector
/// SSA value. We only can ensure this for a limited set of operations, and we
/// don't want to do the rewrites unless we are confident that the result will
/// be promotable, so we have an early test here.
static bool isVectorPromotionViable(const TargetData &TD,
Type *AllocaTy,
AllocaPartitioning &P,
uint64_t PartitionBeginOffset,
uint64_t PartitionEndOffset,
AllocaPartitioning::const_use_iterator I,
AllocaPartitioning::const_use_iterator E) {
VectorType *Ty = dyn_cast<VectorType>(AllocaTy);
if (!Ty)
return false;
uint64_t VecSize = TD.getTypeSizeInBits(Ty);
uint64_t ElementSize = Ty->getScalarSizeInBits();
// While the definition of LLVM vectors is bitpacked, we don't support sizes
// that aren't byte sized.
if (ElementSize % 8)
return false;
assert((VecSize % 8) == 0 && "vector size not a multiple of element size?");
VecSize /= 8;
ElementSize /= 8;
for (; I != E; ++I) {
uint64_t BeginOffset = I->BeginOffset - PartitionBeginOffset;
uint64_t BeginIndex = BeginOffset / ElementSize;
if (BeginIndex * ElementSize != BeginOffset ||
BeginIndex >= Ty->getNumElements())
return false;
uint64_t EndOffset = I->EndOffset - PartitionBeginOffset;
uint64_t EndIndex = EndOffset / ElementSize;
if (EndIndex * ElementSize != EndOffset ||
EndIndex > Ty->getNumElements())
return false;
// FIXME: We should build shuffle vector instructions to handle
// non-element-sized accesses.
if ((EndOffset - BeginOffset) != ElementSize &&
(EndOffset - BeginOffset) != VecSize)
return false;
if (MemIntrinsic *MI = dyn_cast<MemIntrinsic>(&*I->User)) {
if (MI->isVolatile())
return false;
if (MemTransferInst *MTI = dyn_cast<MemTransferInst>(&*I->User)) {
const AllocaPartitioning::MemTransferOffsets &MTO
= P.getMemTransferOffsets(*MTI);
if (!MTO.IsSplittable)
return false;
}
} else if (I->Ptr->getType()->getPointerElementType()->isStructTy()) {
// Disable vector promotion when there are loads or stores of an FCA.
return false;
} else if (!isa<LoadInst>(*I->User) && !isa<StoreInst>(*I->User)) {
return false;
}
}
return true;
}
/// \brief Test whether the given alloca partition can be promoted to an int.
///
/// This is a quick test to check whether we can rewrite a particular alloca
/// partition (and its newly formed alloca) into an integer alloca suitable for
/// promotion to an SSA value. We only can ensure this for a limited set of
/// operations, and we don't want to do the rewrites unless we are confident
/// that the result will be promotable, so we have an early test here.
static bool isIntegerPromotionViable(const TargetData &TD,
Type *AllocaTy,
AllocaPartitioning &P,
AllocaPartitioning::const_use_iterator I,
AllocaPartitioning::const_use_iterator E) {
IntegerType *Ty = dyn_cast<IntegerType>(AllocaTy);
if (!Ty)
return false;
// Check the uses to ensure the uses are (likely) promoteable integer uses.
// Also ensure that the alloca has a covering load or store. We don't want
// promote because of some other unsplittable entry (which we may make
// splittable later) and lose the ability to promote each element access.
bool WholeAllocaOp = false;
for (; I != E; ++I) {
if (LoadInst *LI = dyn_cast<LoadInst>(&*I->User)) {
if (LI->isVolatile() || !LI->getType()->isIntegerTy())
return false;
if (LI->getType() == Ty)
WholeAllocaOp = true;
} else if (StoreInst *SI = dyn_cast<StoreInst>(&*I->User)) {
if (SI->isVolatile() || !SI->getValueOperand()->getType()->isIntegerTy())
return false;
if (SI->getValueOperand()->getType() == Ty)
WholeAllocaOp = true;
} else if (MemIntrinsic *MI = dyn_cast<MemIntrinsic>(&*I->User)) {
if (MI->isVolatile())
return false;
if (MemTransferInst *MTI = dyn_cast<MemTransferInst>(&*I->User)) {
const AllocaPartitioning::MemTransferOffsets &MTO
= P.getMemTransferOffsets(*MTI);
if (!MTO.IsSplittable)
return false;
}
} else {
return false;
}
}
return WholeAllocaOp;
}
namespace {
/// \brief Visitor to rewrite instructions using a partition of an alloca to
/// use a new alloca.
///
/// Also implements the rewriting to vector-based accesses when the partition
/// passes the isVectorPromotionViable predicate. Most of the rewriting logic
/// lives here.
class AllocaPartitionRewriter : public InstVisitor<AllocaPartitionRewriter,
bool> {
// Befriend the base class so it can delegate to private visit methods.
friend class llvm::InstVisitor<AllocaPartitionRewriter, bool>;
const TargetData &TD;
AllocaPartitioning &P;
SROA &Pass;
AllocaInst &OldAI, &NewAI;
const uint64_t NewAllocaBeginOffset, NewAllocaEndOffset;
// If we are rewriting an alloca partition which can be written as pure
// vector operations, we stash extra information here. When VecTy is
// non-null, we have some strict guarantees about the rewriten alloca:
// - The new alloca is exactly the size of the vector type here.
// - The accesses all either map to the entire vector or to a single
// element.
// - The set of accessing instructions is only one of those handled above
// in isVectorPromotionViable. Generally these are the same access kinds
// which are promotable via mem2reg.
VectorType *VecTy;
Type *ElementTy;
uint64_t ElementSize;
// This is a convenience and flag variable that will be null unless the new
// alloca has a promotion-targeted integer type due to passing
// isIntegerPromotionViable above. If it is non-null does, the desired
// integer type will be stored here for easy access during rewriting.
IntegerType *IntPromotionTy;
// The offset of the partition user currently being rewritten.
uint64_t BeginOffset, EndOffset;
Instruction *OldPtr;
// The name prefix to use when rewriting instructions for this alloca.
std::string NamePrefix;
public:
AllocaPartitionRewriter(const TargetData &TD, AllocaPartitioning &P,
AllocaPartitioning::iterator PI,
SROA &Pass, AllocaInst &OldAI, AllocaInst &NewAI,
uint64_t NewBeginOffset, uint64_t NewEndOffset)
: TD(TD), P(P), Pass(Pass),
OldAI(OldAI), NewAI(NewAI),
NewAllocaBeginOffset(NewBeginOffset),
NewAllocaEndOffset(NewEndOffset),
VecTy(), ElementTy(), ElementSize(), IntPromotionTy(),
BeginOffset(), EndOffset() {
}
/// \brief Visit the users of the alloca partition and rewrite them.
bool visitUsers(AllocaPartitioning::const_use_iterator I,
AllocaPartitioning::const_use_iterator E) {
if (isVectorPromotionViable(TD, NewAI.getAllocatedType(), P,
NewAllocaBeginOffset, NewAllocaEndOffset,
I, E)) {
++NumVectorized;
VecTy = cast<VectorType>(NewAI.getAllocatedType());
ElementTy = VecTy->getElementType();
assert((VecTy->getScalarSizeInBits() % 8) == 0 &&
"Only multiple-of-8 sized vector elements are viable");
ElementSize = VecTy->getScalarSizeInBits() / 8;
} else if (isIntegerPromotionViable(TD, NewAI.getAllocatedType(),
P, I, E)) {
IntPromotionTy = cast<IntegerType>(NewAI.getAllocatedType());
}
bool CanSROA = true;
for (; I != E; ++I) {
BeginOffset = I->BeginOffset;
EndOffset = I->EndOffset;
OldPtr = I->Ptr;
NamePrefix = (Twine(NewAI.getName()) + "." + Twine(BeginOffset)).str();
CanSROA &= visit(I->User);
}
if (VecTy) {
assert(CanSROA);
VecTy = 0;
ElementTy = 0;
ElementSize = 0;
}
return CanSROA;
}
private:
// Every instruction which can end up as a user must have a rewrite rule.
bool visitInstruction(Instruction &I) {
DEBUG(dbgs() << " !!!! Cannot rewrite: " << I << "\n");
llvm_unreachable("No rewrite rule for this instruction!");
}
Twine getName(const Twine &Suffix) {
return NamePrefix + Suffix;
}
Value *getAdjustedAllocaPtr(IRBuilder<> &IRB, Type *PointerTy) {
assert(BeginOffset >= NewAllocaBeginOffset);
APInt Offset(TD.getPointerSizeInBits(), BeginOffset - NewAllocaBeginOffset);
return getAdjustedPtr(IRB, TD, &NewAI, Offset, PointerTy, getName(""));
}
ConstantInt *getIndex(IRBuilder<> &IRB, uint64_t Offset) {
assert(VecTy && "Can only call getIndex when rewriting a vector");
uint64_t RelOffset = Offset - NewAllocaBeginOffset;
assert(RelOffset / ElementSize < UINT32_MAX && "Index out of bounds");
uint32_t Index = RelOffset / ElementSize;
assert(Index * ElementSize == RelOffset);
return IRB.getInt32(Index);
}
Value *extractInteger(IRBuilder<> &IRB, IntegerType *TargetTy,
uint64_t Offset) {
assert(IntPromotionTy && "Alloca is not an integer we can extract from");
Value *V = IRB.CreateLoad(&NewAI, getName(".load"));
assert(Offset >= NewAllocaBeginOffset && "Out of bounds offset");
uint64_t RelOffset = Offset - NewAllocaBeginOffset;
if (RelOffset)
V = IRB.CreateLShr(V, RelOffset*8, getName(".shift"));
if (TargetTy != IntPromotionTy) {
assert(TargetTy->getBitWidth() < IntPromotionTy->getBitWidth() &&
"Cannot extract to a larger integer!");
V = IRB.CreateTrunc(V, TargetTy, getName(".trunc"));
}
return V;
}
StoreInst *insertInteger(IRBuilder<> &IRB, Value *V, uint64_t Offset) {
IntegerType *Ty = cast<IntegerType>(V->getType());
if (Ty == IntPromotionTy)
return IRB.CreateStore(V, &NewAI);
assert(Ty->getBitWidth() < IntPromotionTy->getBitWidth() &&
"Cannot insert a larger integer!");
V = IRB.CreateZExt(V, IntPromotionTy, getName(".ext"));
assert(Offset >= NewAllocaBeginOffset && "Out of bounds offset");
uint64_t RelOffset = Offset - NewAllocaBeginOffset;
if (RelOffset)
V = IRB.CreateShl(V, RelOffset*8, getName(".shift"));
APInt Mask = ~Ty->getMask().zext(IntPromotionTy->getBitWidth())
.shl(RelOffset*8);
Value *Old = IRB.CreateAnd(IRB.CreateLoad(&NewAI, getName(".oldload")),
Mask, getName(".mask"));
return IRB.CreateStore(IRB.CreateOr(Old, V, getName(".insert")),
&NewAI);
}
void deleteIfTriviallyDead(Value *V) {
Instruction *I = cast<Instruction>(V);
if (isInstructionTriviallyDead(I))
Pass.DeadInsts.push_back(I);
}
Value *getValueCast(IRBuilder<> &IRB, Value *V, Type *Ty) {
if (V->getType()->isIntegerTy() && Ty->isPointerTy())
return IRB.CreateIntToPtr(V, Ty);
if (V->getType()->isPointerTy() && Ty->isIntegerTy())
return IRB.CreatePtrToInt(V, Ty);
return IRB.CreateBitCast(V, Ty);
}
bool rewriteVectorizedLoadInst(IRBuilder<> &IRB, LoadInst &LI, Value *OldOp) {
Value *Result;
if (LI.getType() == VecTy->getElementType() ||
BeginOffset > NewAllocaBeginOffset || EndOffset < NewAllocaEndOffset) {
Result
= IRB.CreateExtractElement(IRB.CreateLoad(&NewAI, getName(".load")),
getIndex(IRB, BeginOffset),
getName(".extract"));
} else {
Result = IRB.CreateLoad(&NewAI, getName(".load"));
}
if (Result->getType() != LI.getType())
Result = getValueCast(IRB, Result, LI.getType());
LI.replaceAllUsesWith(Result);
Pass.DeadInsts.push_back(&LI);
DEBUG(dbgs() << " to: " << *Result << "\n");
return true;
}
bool rewriteIntegerLoad(IRBuilder<> &IRB, LoadInst &LI) {
assert(!LI.isVolatile());
Value *Result = extractInteger(IRB, cast<IntegerType>(LI.getType()),
BeginOffset);
LI.replaceAllUsesWith(Result);
Pass.DeadInsts.push_back(&LI);
DEBUG(dbgs() << " to: " << *Result << "\n");
return true;
}
bool visitLoadInst(LoadInst &LI) {
DEBUG(dbgs() << " original: " << LI << "\n");
Value *OldOp = LI.getOperand(0);
assert(OldOp == OldPtr);
IRBuilder<> IRB(&LI);
if (VecTy)
return rewriteVectorizedLoadInst(IRB, LI, OldOp);
if (IntPromotionTy)
return rewriteIntegerLoad(IRB, LI);
Value *NewPtr = getAdjustedAllocaPtr(IRB,
LI.getPointerOperand()->getType());
LI.setOperand(0, NewPtr);
DEBUG(dbgs() << " to: " << LI << "\n");
deleteIfTriviallyDead(OldOp);
return NewPtr == &NewAI && !LI.isVolatile();
}
bool rewriteVectorizedStoreInst(IRBuilder<> &IRB, StoreInst &SI,
Value *OldOp) {
Value *V = SI.getValueOperand();
if (V->getType() == ElementTy ||
BeginOffset > NewAllocaBeginOffset || EndOffset < NewAllocaEndOffset) {
if (V->getType() != ElementTy)
V = getValueCast(IRB, V, ElementTy);
V = IRB.CreateInsertElement(IRB.CreateLoad(&NewAI, getName(".load")), V,
getIndex(IRB, BeginOffset),
getName(".insert"));
} else if (V->getType() != VecTy) {
V = getValueCast(IRB, V, VecTy);
}
StoreInst *Store = IRB.CreateStore(V, &NewAI);
Pass.DeadInsts.push_back(&SI);
(void)Store;
DEBUG(dbgs() << " to: " << *Store << "\n");
return true;
}
bool rewriteIntegerStore(IRBuilder<> &IRB, StoreInst &SI) {
assert(!SI.isVolatile());
StoreInst *Store = insertInteger(IRB, SI.getValueOperand(), BeginOffset);
Pass.DeadInsts.push_back(&SI);
(void)Store;
DEBUG(dbgs() << " to: " << *Store << "\n");
return true;
}
bool visitStoreInst(StoreInst &SI) {
DEBUG(dbgs() << " original: " << SI << "\n");
Value *OldOp = SI.getOperand(1);
assert(OldOp == OldPtr);
IRBuilder<> IRB(&SI);
if (VecTy)
return rewriteVectorizedStoreInst(IRB, SI, OldOp);
if (IntPromotionTy)
return rewriteIntegerStore(IRB, SI);
Value *NewPtr = getAdjustedAllocaPtr(IRB,
SI.getPointerOperand()->getType());
SI.setOperand(1, NewPtr);
DEBUG(dbgs() << " to: " << SI << "\n");
deleteIfTriviallyDead(OldOp);
return NewPtr == &NewAI && !SI.isVolatile();
}
bool visitMemSetInst(MemSetInst &II) {
DEBUG(dbgs() << " original: " << II << "\n");
IRBuilder<> IRB(&II);
assert(II.getRawDest() == OldPtr);
// If the memset has a variable size, it cannot be split, just adjust the
// pointer to the new alloca.
if (!isa<Constant>(II.getLength())) {
II.setDest(getAdjustedAllocaPtr(IRB, II.getRawDest()->getType()));
deleteIfTriviallyDead(OldPtr);
return false;
}
// Record this instruction for deletion.
if (Pass.DeadSplitInsts.insert(&II))
Pass.DeadInsts.push_back(&II);
Type *AllocaTy = NewAI.getAllocatedType();
Type *ScalarTy = AllocaTy->getScalarType();
// If this doesn't map cleanly onto the alloca type, and that type isn't
// a single value type, just emit a memset.
if (!VecTy && (BeginOffset != NewAllocaBeginOffset ||
EndOffset != NewAllocaEndOffset ||
!AllocaTy->isSingleValueType() ||
!TD.isLegalInteger(TD.getTypeSizeInBits(ScalarTy)))) {
Type *SizeTy = II.getLength()->getType();
Constant *Size = ConstantInt::get(SizeTy, EndOffset - BeginOffset);
CallInst *New
= IRB.CreateMemSet(getAdjustedAllocaPtr(IRB,
II.getRawDest()->getType()),
II.getValue(), Size, II.getAlignment(),
II.isVolatile());
(void)New;
DEBUG(dbgs() << " to: " << *New << "\n");
return false;
}
// If we can represent this as a simple value, we have to build the actual
// value to store, which requires expanding the byte present in memset to
// a sensible representation for the alloca type. This is essentially
// splatting the byte to a sufficiently wide integer, bitcasting to the
// desired scalar type, and splatting it across any desired vector type.
Value *V = II.getValue();
IntegerType *VTy = cast<IntegerType>(V->getType());
Type *IntTy = Type::getIntNTy(VTy->getContext(),
TD.getTypeSizeInBits(ScalarTy));
if (TD.getTypeSizeInBits(ScalarTy) > VTy->getBitWidth())
V = IRB.CreateMul(IRB.CreateZExt(V, IntTy, getName(".zext")),
ConstantExpr::getUDiv(
Constant::getAllOnesValue(IntTy),
ConstantExpr::getZExt(
Constant::getAllOnesValue(V->getType()),
IntTy)),
getName(".isplat"));
if (V->getType() != ScalarTy) {
if (ScalarTy->isPointerTy())
V = IRB.CreateIntToPtr(V, ScalarTy);
else if (ScalarTy->isPrimitiveType() || ScalarTy->isVectorTy())
V = IRB.CreateBitCast(V, ScalarTy);
else if (ScalarTy->isIntegerTy())
llvm_unreachable("Computed different integer types with equal widths");
else
llvm_unreachable("Invalid scalar type");
}
// If this is an element-wide memset of a vectorizable alloca, insert it.
if (VecTy && (BeginOffset > NewAllocaBeginOffset ||
EndOffset < NewAllocaEndOffset)) {
StoreInst *Store = IRB.CreateStore(
IRB.CreateInsertElement(IRB.CreateLoad(&NewAI, getName(".load")), V,
getIndex(IRB, BeginOffset),
getName(".insert")),
&NewAI);
(void)Store;
DEBUG(dbgs() << " to: " << *Store << "\n");
return true;
}
// Splat to a vector if needed.
if (VectorType *VecTy = dyn_cast<VectorType>(AllocaTy)) {
VectorType *SplatSourceTy = VectorType::get(V->getType(), 1);
V = IRB.CreateShuffleVector(
IRB.CreateInsertElement(UndefValue::get(SplatSourceTy), V,
IRB.getInt32(0), getName(".vsplat.insert")),
UndefValue::get(SplatSourceTy),
ConstantVector::getSplat(VecTy->getNumElements(), IRB.getInt32(0)),
getName(".vsplat.shuffle"));
assert(V->getType() == VecTy);
}
Value *New = IRB.CreateStore(V, &NewAI, II.isVolatile());
(void)New;
DEBUG(dbgs() << " to: " << *New << "\n");
return !II.isVolatile();
}
bool visitMemTransferInst(MemTransferInst &II) {
// Rewriting of memory transfer instructions can be a bit tricky. We break
// them into two categories: split intrinsics and unsplit intrinsics.
DEBUG(dbgs() << " original: " << II << "\n");
IRBuilder<> IRB(&II);
assert(II.getRawSource() == OldPtr || II.getRawDest() == OldPtr);
bool IsDest = II.getRawDest() == OldPtr;
const AllocaPartitioning::MemTransferOffsets &MTO
= P.getMemTransferOffsets(II);
// For unsplit intrinsics, we simply modify the source and destination
// pointers in place. This isn't just an optimization, it is a matter of
// correctness. With unsplit intrinsics we may be dealing with transfers
// within a single alloca before SROA ran, or with transfers that have
// a variable length. We may also be dealing with memmove instead of
// memcpy, and so simply updating the pointers is the necessary for us to
// update both source and dest of a single call.
if (!MTO.IsSplittable) {
Value *OldOp = IsDest ? II.getRawDest() : II.getRawSource();
if (IsDest)
II.setDest(getAdjustedAllocaPtr(IRB, II.getRawDest()->getType()));
else
II.setSource(getAdjustedAllocaPtr(IRB, II.getRawSource()->getType()));
DEBUG(dbgs() << " to: " << II << "\n");
deleteIfTriviallyDead(OldOp);
return false;
}
// For split transfer intrinsics we have an incredibly useful assurance:
// the source and destination do not reside within the same alloca, and at
// least one of them does not escape. This means that we can replace
// memmove with memcpy, and we don't need to worry about all manner of
// downsides to splitting and transforming the operations.
// Compute the relative offset within the transfer.
unsigned IntPtrWidth = TD.getPointerSizeInBits();
APInt RelOffset(IntPtrWidth, BeginOffset - (IsDest ? MTO.DestBegin
: MTO.SourceBegin));
// If this doesn't map cleanly onto the alloca type, and that type isn't
// a single value type, just emit a memcpy.
bool EmitMemCpy
= !VecTy && (BeginOffset != NewAllocaBeginOffset ||
EndOffset != NewAllocaEndOffset ||
!NewAI.getAllocatedType()->isSingleValueType());
// If we're just going to emit a memcpy, the alloca hasn't changed, and the
// size hasn't been shrunk based on analysis of the viable range, this is
// a no-op.
if (EmitMemCpy && &OldAI == &NewAI) {
uint64_t OrigBegin = IsDest ? MTO.DestBegin : MTO.SourceBegin;
uint64_t OrigEnd = IsDest ? MTO.DestEnd : MTO.SourceEnd;
// Ensure the start lines up.
assert(BeginOffset == OrigBegin);
(void)OrigBegin;
// Rewrite the size as needed.
if (EndOffset != OrigEnd)
II.setLength(ConstantInt::get(II.getLength()->getType(),
EndOffset - BeginOffset));
return false;
}
// Record this instruction for deletion.
if (Pass.DeadSplitInsts.insert(&II))
Pass.DeadInsts.push_back(&II);
bool IsVectorElement = VecTy && (BeginOffset > NewAllocaBeginOffset ||
EndOffset < NewAllocaEndOffset);
Type *OtherPtrTy = IsDest ? II.getRawSource()->getType()
: II.getRawDest()->getType();
if (!EmitMemCpy)
OtherPtrTy = IsVectorElement ? VecTy->getElementType()->getPointerTo()
: NewAI.getType();
// Compute the other pointer, folding as much as possible to produce
// a single, simple GEP in most cases.
Value *OtherPtr = IsDest ? II.getRawSource() : II.getRawDest();
OtherPtr = getAdjustedPtr(IRB, TD, OtherPtr, RelOffset, OtherPtrTy,
getName("." + OtherPtr->getName()));
// Strip all inbounds GEPs and pointer casts to try to dig out any root
// alloca that should be re-examined after rewriting this instruction.
if (AllocaInst *AI
= dyn_cast<AllocaInst>(OtherPtr->stripInBoundsOffsets()))
Pass.Worklist.insert(AI);
if (EmitMemCpy) {
Value *OurPtr
= getAdjustedAllocaPtr(IRB, IsDest ? II.getRawDest()->getType()
: II.getRawSource()->getType());
Type *SizeTy = II.getLength()->getType();
Constant *Size = ConstantInt::get(SizeTy, EndOffset - BeginOffset);
CallInst *New = IRB.CreateMemCpy(IsDest ? OurPtr : OtherPtr,
IsDest ? OtherPtr : OurPtr,
Size, II.getAlignment(),
II.isVolatile());
(void)New;
DEBUG(dbgs() << " to: " << *New << "\n");
return false;
}
Value *SrcPtr = OtherPtr;
Value *DstPtr = &NewAI;
if (!IsDest)
std::swap(SrcPtr, DstPtr);
Value *Src;
if (IsVectorElement && !IsDest) {
// We have to extract rather than load.
Src = IRB.CreateExtractElement(IRB.CreateLoad(SrcPtr,
getName(".copyload")),
getIndex(IRB, BeginOffset),
getName(".copyextract"));
} else {
Src = IRB.CreateLoad(SrcPtr, II.isVolatile(), getName(".copyload"));
}
if (IsVectorElement && IsDest) {
// We have to insert into a loaded copy before storing.
Src = IRB.CreateInsertElement(IRB.CreateLoad(&NewAI, getName(".load")),
Src, getIndex(IRB, BeginOffset),
getName(".insert"));
}
Value *Store = IRB.CreateStore(Src, DstPtr, II.isVolatile());
(void)Store;
DEBUG(dbgs() << " to: " << *Store << "\n");
return !II.isVolatile();
}
bool visitIntrinsicInst(IntrinsicInst &II) {
assert(II.getIntrinsicID() == Intrinsic::lifetime_start ||
II.getIntrinsicID() == Intrinsic::lifetime_end);
DEBUG(dbgs() << " original: " << II << "\n");
IRBuilder<> IRB(&II);
assert(II.getArgOperand(1) == OldPtr);
// Record this instruction for deletion.
if (Pass.DeadSplitInsts.insert(&II))
Pass.DeadInsts.push_back(&II);
ConstantInt *Size
= ConstantInt::get(cast<IntegerType>(II.getArgOperand(0)->getType()),
EndOffset - BeginOffset);
Value *Ptr = getAdjustedAllocaPtr(IRB, II.getArgOperand(1)->getType());
Value *New;
if (II.getIntrinsicID() == Intrinsic::lifetime_start)
New = IRB.CreateLifetimeStart(Ptr, Size);
else
New = IRB.CreateLifetimeEnd(Ptr, Size);
DEBUG(dbgs() << " to: " << *New << "\n");
return true;
}
/// PHI instructions that use an alloca and are subsequently loaded can be
/// rewritten to load both input pointers in the pred blocks and then PHI the
/// results, allowing the load of the alloca to be promoted.
/// From this:
/// %P2 = phi [i32* %Alloca, i32* %Other]
/// %V = load i32* %P2
/// to:
/// %V1 = load i32* %Alloca -> will be mem2reg'd
/// ...
/// %V2 = load i32* %Other
/// ...
/// %V = phi [i32 %V1, i32 %V2]
///
/// We can do this to a select if its only uses are loads and if the operand
/// to the select can be loaded unconditionally.
///
/// FIXME: This should be hoisted into a generic utility, likely in
/// Transforms/Util/Local.h
bool isSafePHIToSpeculate(PHINode &PN, SmallVectorImpl<LoadInst *> &Loads) {
// For now, we can only do this promotion if the load is in the same block
// as the PHI, and if there are no stores between the phi and load.
// TODO: Allow recursive phi users.
// TODO: Allow stores.
BasicBlock *BB = PN.getParent();
unsigned MaxAlign = 0;
for (Value::use_iterator UI = PN.use_begin(), UE = PN.use_end();
UI != UE; ++UI) {
LoadInst *LI = dyn_cast<LoadInst>(*UI);
if (LI == 0 || !LI->isSimple()) return false;
// For now we only allow loads in the same block as the PHI. This is
// a common case that happens when instcombine merges two loads through
// a PHI.
if (LI->getParent() != BB) return false;
// Ensure that there are no instructions between the PHI and the load that
// could store.
for (BasicBlock::iterator BBI = &PN; &*BBI != LI; ++BBI)
if (BBI->mayWriteToMemory())
return false;
MaxAlign = std::max(MaxAlign, LI->getAlignment());
Loads.push_back(LI);
}
// We can only transform this if it is safe to push the loads into the
// predecessor blocks. The only thing to watch out for is that we can't put
// a possibly trapping load in the predecessor if it is a critical edge.
for (unsigned Idx = 0, Num = PN.getNumIncomingValues(); Idx != Num;
++Idx) {
TerminatorInst *TI = PN.getIncomingBlock(Idx)->getTerminator();
Value *InVal = PN.getIncomingValue(Idx);
// If the value is produced by the terminator of the predecessor (an
// invoke) or it has side-effects, there is no valid place to put a load
// in the predecessor.
if (TI == InVal || TI->mayHaveSideEffects())
return false;
// If the predecessor has a single successor, then the edge isn't
// critical.
if (TI->getNumSuccessors() == 1)
continue;
// If this pointer is always safe to load, or if we can prove that there
// is already a load in the block, then we can move the load to the pred
// block.
if (InVal->isDereferenceablePointer() ||
isSafeToLoadUnconditionally(InVal, TI, MaxAlign, &TD))
continue;
return false;
}
return true;
}
bool visitPHINode(PHINode &PN) {
DEBUG(dbgs() << " original: " << PN << "\n");
// We would like to compute a new pointer in only one place, but have it be
// as local as possible to the PHI. To do that, we re-use the location of
// the old pointer, which necessarily must be in the right position to
// dominate the PHI.
IRBuilder<> PtrBuilder(cast<Instruction>(OldPtr));
SmallVector<LoadInst *, 4> Loads;
if (!isSafePHIToSpeculate(PN, Loads)) {
Value *NewPtr = getAdjustedAllocaPtr(PtrBuilder, OldPtr->getType());
// Replace the operands which were using the old pointer.
User::op_iterator OI = PN.op_begin(), OE = PN.op_end();
for (; OI != OE; ++OI)
if (*OI == OldPtr)
*OI = NewPtr;
DEBUG(dbgs() << " to: " << PN << "\n");
deleteIfTriviallyDead(OldPtr);
return false;
}
assert(!Loads.empty());
Type *LoadTy = cast<PointerType>(PN.getType())->getElementType();
IRBuilder<> PHIBuilder(&PN);
PHINode *NewPN = PHIBuilder.CreatePHI(LoadTy, PN.getNumIncomingValues());
NewPN->takeName(&PN);
// Get the TBAA tag and alignment to use from one of the loads. It doesn't
// matter which one we get and if any differ, it doesn't matter.
LoadInst *SomeLoad = cast<LoadInst>(Loads.back());
MDNode *TBAATag = SomeLoad->getMetadata(LLVMContext::MD_tbaa);
unsigned Align = SomeLoad->getAlignment();
Value *NewPtr = getAdjustedAllocaPtr(PtrBuilder, OldPtr->getType());
// Rewrite all loads of the PN to use the new PHI.
do {
LoadInst *LI = Loads.pop_back_val();
LI->replaceAllUsesWith(NewPN);
Pass.DeadInsts.push_back(LI);
} while (!Loads.empty());
// Inject loads into all of the pred blocks.
for (unsigned Idx = 0, Num = PN.getNumIncomingValues(); Idx != Num; ++Idx) {
BasicBlock *Pred = PN.getIncomingBlock(Idx);
TerminatorInst *TI = Pred->getTerminator();
Value *InVal = PN.getIncomingValue(Idx);
IRBuilder<> PredBuilder(TI);
// Map the value to the new alloca pointer if this was the old alloca
// pointer.
bool ThisOperand = InVal == OldPtr;
if (ThisOperand)
InVal = NewPtr;
LoadInst *Load
= PredBuilder.CreateLoad(InVal, getName(".sroa.speculate." +
Pred->getName()));
++NumLoadsSpeculated;
Load->setAlignment(Align);
if (TBAATag)
Load->setMetadata(LLVMContext::MD_tbaa, TBAATag);
NewPN->addIncoming(Load, Pred);
if (ThisOperand)
continue;
Instruction *OtherPtr = dyn_cast<Instruction>(InVal);
if (!OtherPtr)
// No uses to rewrite.
continue;
// Try to lookup and rewrite any partition uses corresponding to this phi
// input.
AllocaPartitioning::iterator PI
= P.findPartitionForPHIOrSelectOperand(PN, OtherPtr);
if (PI != P.end()) {
// If the other pointer is within the partitioning, replace the PHI in
// its uses with the load we just speculated, or add another load for
// it to rewrite if we've already replaced the PHI.
AllocaPartitioning::use_iterator UI
= P.findPartitionUseForPHIOrSelectOperand(PN, OtherPtr);
if (isa<PHINode>(*UI->User))
UI->User = Load;
else {
AllocaPartitioning::PartitionUse OtherUse = *UI;
OtherUse.User = Load;
P.use_push_back(PI, OtherUse);
}
}
}
DEBUG(dbgs() << " speculated to: " << *NewPN << "\n");
return NewPtr == &NewAI;
}
/// Select instructions that use an alloca and are subsequently loaded can be
/// rewritten to load both input pointers and then select between the result,
/// allowing the load of the alloca to be promoted.
/// From this:
/// %P2 = select i1 %cond, i32* %Alloca, i32* %Other
/// %V = load i32* %P2
/// to:
/// %V1 = load i32* %Alloca -> will be mem2reg'd
/// %V2 = load i32* %Other
/// %V = select i1 %cond, i32 %V1, i32 %V2
///
/// We can do this to a select if its only uses are loads and if the operand
/// to the select can be loaded unconditionally.
bool isSafeSelectToSpeculate(SelectInst &SI,
SmallVectorImpl<LoadInst *> &Loads) {
Value *TValue = SI.getTrueValue();
Value *FValue = SI.getFalseValue();
bool TDerefable = TValue->isDereferenceablePointer();
bool FDerefable = FValue->isDereferenceablePointer();
for (Value::use_iterator UI = SI.use_begin(), UE = SI.use_end();
UI != UE; ++UI) {
LoadInst *LI = dyn_cast<LoadInst>(*UI);
if (LI == 0 || !LI->isSimple()) return false;
// Both operands to the select need to be dereferencable, either
// absolutely (e.g. allocas) or at this point because we can see other
// accesses to it.
if (!TDerefable && !isSafeToLoadUnconditionally(TValue, LI,
LI->getAlignment(), &TD))
return false;
if (!FDerefable && !isSafeToLoadUnconditionally(FValue, LI,
LI->getAlignment(), &TD))
return false;
Loads.push_back(LI);
}
return true;
}
bool visitSelectInst(SelectInst &SI) {
DEBUG(dbgs() << " original: " << SI << "\n");
IRBuilder<> IRB(&SI);
// Find the operand we need to rewrite here.
bool IsTrueVal = SI.getTrueValue() == OldPtr;
if (IsTrueVal)
assert(SI.getFalseValue() != OldPtr && "Pointer is both operands!");
else
assert(SI.getFalseValue() == OldPtr && "Pointer isn't an operand!");
Value *NewPtr = getAdjustedAllocaPtr(IRB, OldPtr->getType());
// If the select isn't safe to speculate, just use simple logic to emit it.
SmallVector<LoadInst *, 4> Loads;
if (!isSafeSelectToSpeculate(SI, Loads)) {
SI.setOperand(IsTrueVal ? 1 : 2, NewPtr);
DEBUG(dbgs() << " to: " << SI << "\n");
deleteIfTriviallyDead(OldPtr);
return false;
}
Value *OtherPtr = IsTrueVal ? SI.getFalseValue() : SI.getTrueValue();
AllocaPartitioning::iterator PI
= P.findPartitionForPHIOrSelectOperand(SI, OtherPtr);
AllocaPartitioning::PartitionUse OtherUse;
if (PI != P.end()) {
// If the other pointer is within the partitioning, remove the select
// from its uses. We'll add in the new loads below.
AllocaPartitioning::use_iterator UI
= P.findPartitionUseForPHIOrSelectOperand(SI, OtherPtr);
OtherUse = *UI;
P.use_erase(PI, UI);
}
Value *TV = IsTrueVal ? NewPtr : SI.getTrueValue();
Value *FV = IsTrueVal ? SI.getFalseValue() : NewPtr;
// Replace the loads of the select with a select of two loads.
while (!Loads.empty()) {
LoadInst *LI = Loads.pop_back_val();
IRB.SetInsertPoint(LI);
LoadInst *TL =
IRB.CreateLoad(TV, getName("." + LI->getName() + ".true"));
LoadInst *FL =
IRB.CreateLoad(FV, getName("." + LI->getName() + ".false"));
NumLoadsSpeculated += 2;
if (PI != P.end()) {
LoadInst *OtherLoad = IsTrueVal ? FL : TL;
assert(OtherUse.Ptr == OtherLoad->getOperand(0));
OtherUse.User = OtherLoad;
P.use_push_back(PI, OtherUse);
}
// Transfer alignment and TBAA info if present.
TL->setAlignment(LI->getAlignment());
FL->setAlignment(LI->getAlignment());
if (MDNode *Tag = LI->getMetadata(LLVMContext::MD_tbaa)) {
TL->setMetadata(LLVMContext::MD_tbaa, Tag);
FL->setMetadata(LLVMContext::MD_tbaa, Tag);
}
Value *V = IRB.CreateSelect(SI.getCondition(), TL, FL);
V->takeName(LI);
DEBUG(dbgs() << " speculated to: " << *V << "\n");
LI->replaceAllUsesWith(V);
Pass.DeadInsts.push_back(LI);
}
deleteIfTriviallyDead(OldPtr);
return NewPtr == &NewAI;
}
};
}
namespace {
/// \brief Visitor to rewrite aggregate loads and stores as scalar.
///
/// This pass aggressively rewrites all aggregate loads and stores on
/// a particular pointer (or any pointer derived from it which we can identify)
/// with scalar loads and stores.
class AggLoadStoreRewriter : public InstVisitor<AggLoadStoreRewriter, bool> {
// Befriend the base class so it can delegate to private visit methods.
friend class llvm::InstVisitor<AggLoadStoreRewriter, bool>;
const TargetData &TD;
/// Queue of pointer uses to analyze and potentially rewrite.
SmallVector<Use *, 8> Queue;
/// Set to prevent us from cycling with phi nodes and loops.
SmallPtrSet<User *, 8> Visited;
/// The current pointer use being rewritten. This is used to dig up the used
/// value (as opposed to the user).
Use *U;
public:
AggLoadStoreRewriter(const TargetData &TD) : TD(TD) {}
/// Rewrite loads and stores through a pointer and all pointers derived from
/// it.
bool rewrite(Instruction &I) {
DEBUG(dbgs() << " Rewriting FCA loads and stores...\n");
enqueueUsers(I);
bool Changed = false;
while (!Queue.empty()) {
U = Queue.pop_back_val();
Changed |= visit(cast<Instruction>(U->getUser()));
}
return Changed;
}
private:
/// Enqueue all the users of the given instruction for further processing.
/// This uses a set to de-duplicate users.
void enqueueUsers(Instruction &I) {
for (Value::use_iterator UI = I.use_begin(), UE = I.use_end(); UI != UE;
++UI)
if (Visited.insert(*UI))
Queue.push_back(&UI.getUse());
}
// Conservative default is to not rewrite anything.
bool visitInstruction(Instruction &I) { return false; }
/// \brief Generic recursive split emission class.
template <typename Derived>
class OpSplitter {
protected:
/// The builder used to form new instructions.
IRBuilder<> IRB;
/// The indices which to be used with insert- or extractvalue to select the
/// appropriate value within the aggregate.
SmallVector<unsigned, 4> Indices;
/// The indices to a GEP instruction which will move Ptr to the correct slot
/// within the aggregate.
SmallVector<Value *, 4> GEPIndices;
/// The base pointer of the original op, used as a base for GEPing the
/// split operations.
Value *Ptr;
/// Initialize the splitter with an insertion point, Ptr and start with a
/// single zero GEP index.
OpSplitter(Instruction *InsertionPoint, Value *Ptr)
: IRB(InsertionPoint), GEPIndices(1, IRB.getInt32(0)), Ptr(Ptr) {}
public:
/// \brief Generic recursive split emission routine.
///
/// This method recursively splits an aggregate op (load or store) into
/// scalar or vector ops. It splits recursively until it hits a single value
/// and emits that single value operation via the template argument.
///
/// The logic of this routine relies on GEPs and insertvalue and
/// extractvalue all operating with the same fundamental index list, merely
/// formatted differently (GEPs need actual values).
///
/// \param Ty The type being split recursively into smaller ops.
/// \param Agg The aggregate value being built up or stored, depending on
/// whether this is splitting a load or a store respectively.
void emitSplitOps(Type *Ty, Value *&Agg, const Twine &Name) {
if (Ty->isSingleValueType())
return static_cast<Derived *>(this)->emitFunc(Ty, Agg, Name);
if (ArrayType *ATy = dyn_cast<ArrayType>(Ty)) {
unsigned OldSize = Indices.size();
(void)OldSize;
for (unsigned Idx = 0, Size = ATy->getNumElements(); Idx != Size;
++Idx) {
assert(Indices.size() == OldSize && "Did not return to the old size");
Indices.push_back(Idx);
GEPIndices.push_back(IRB.getInt32(Idx));
emitSplitOps(ATy->getElementType(), Agg, Name + "." + Twine(Idx));
GEPIndices.pop_back();
Indices.pop_back();
}
return;
}
if (StructType *STy = dyn_cast<StructType>(Ty)) {
unsigned OldSize = Indices.size();
(void)OldSize;
for (unsigned Idx = 0, Size = STy->getNumElements(); Idx != Size;
++Idx) {
assert(Indices.size() == OldSize && "Did not return to the old size");
Indices.push_back(Idx);
GEPIndices.push_back(IRB.getInt32(Idx));
emitSplitOps(STy->getElementType(Idx), Agg, Name + "." + Twine(Idx));
GEPIndices.pop_back();
Indices.pop_back();
}
return;
}
llvm_unreachable("Only arrays and structs are aggregate loadable types");
}
};
struct LoadOpSplitter : public OpSplitter<LoadOpSplitter> {
LoadOpSplitter(Instruction *InsertionPoint, Value *Ptr)
: OpSplitter<LoadOpSplitter>(InsertionPoint, Ptr) {}
/// Emit a leaf load of a single value. This is called at the leaves of the
/// recursive emission to actually load values.
void emitFunc(Type *Ty, Value *&Agg, const Twine &Name) {
assert(Ty->isSingleValueType());
// Load the single value and insert it using the indices.
Value *Load = IRB.CreateLoad(IRB.CreateInBoundsGEP(Ptr, GEPIndices,
Name + ".gep"),
Name + ".load");
Agg = IRB.CreateInsertValue(Agg, Load, Indices, Name + ".insert");
DEBUG(dbgs() << " to: " << *Load << "\n");
}
};
bool visitLoadInst(LoadInst &LI) {
assert(LI.getPointerOperand() == *U);
if (!LI.isSimple() || LI.getType()->isSingleValueType())
return false;
// We have an aggregate being loaded, split it apart.
DEBUG(dbgs() << " original: " << LI << "\n");
LoadOpSplitter Splitter(&LI, *U);
Value *V = UndefValue::get(LI.getType());
Splitter.emitSplitOps(LI.getType(), V, LI.getName() + ".fca");
LI.replaceAllUsesWith(V);
LI.eraseFromParent();
return true;
}
struct StoreOpSplitter : public OpSplitter<StoreOpSplitter> {
StoreOpSplitter(Instruction *InsertionPoint, Value *Ptr)
: OpSplitter<StoreOpSplitter>(InsertionPoint, Ptr) {}
/// Emit a leaf store of a single value. This is called at the leaves of the
/// recursive emission to actually produce stores.
void emitFunc(Type *Ty, Value *&Agg, const Twine &Name) {
assert(Ty->isSingleValueType());
// Extract the single value and store it using the indices.
Value *Store = IRB.CreateStore(
IRB.CreateExtractValue(Agg, Indices, Name + ".extract"),
IRB.CreateInBoundsGEP(Ptr, GEPIndices, Name + ".gep"));
(void)Store;
DEBUG(dbgs() << " to: " << *Store << "\n");
}
};
bool visitStoreInst(StoreInst &SI) {
if (!SI.isSimple() || SI.getPointerOperand() != *U)
return false;
Value *V = SI.getValueOperand();
if (V->getType()->isSingleValueType())
return false;
// We have an aggregate being stored, split it apart.
DEBUG(dbgs() << " original: " << SI << "\n");
StoreOpSplitter Splitter(&SI, *U);
Splitter.emitSplitOps(V->getType(), V, V->getName() + ".fca");
SI.eraseFromParent();
return true;
}
bool visitBitCastInst(BitCastInst &BC) {
enqueueUsers(BC);
return false;
}
bool visitGetElementPtrInst(GetElementPtrInst &GEPI) {
enqueueUsers(GEPI);
return false;
}
bool visitPHINode(PHINode &PN) {
enqueueUsers(PN);
return false;
}
bool visitSelectInst(SelectInst &SI) {
enqueueUsers(SI);
return false;
}
};
}
/// \brief Try to find a partition of the aggregate type passed in for a given
/// offset and size.
///
/// This recurses through the aggregate type and tries to compute a subtype
/// based on the offset and size. When the offset and size span a sub-section
/// of an array, it will even compute a new array type for that sub-section,
/// and the same for structs.
///
/// Note that this routine is very strict and tries to find a partition of the
/// type which produces the *exact* right offset and size. It is not forgiving
/// when the size or offset cause either end of type-based partition to be off.
/// Also, this is a best-effort routine. It is reasonable to give up and not
/// return a type if necessary.
static Type *getTypePartition(const TargetData &TD, Type *Ty,
uint64_t Offset, uint64_t Size) {
if (Offset == 0 && TD.getTypeAllocSize(Ty) == Size)
return Ty;
if (SequentialType *SeqTy = dyn_cast<SequentialType>(Ty)) {
// We can't partition pointers...
if (SeqTy->isPointerTy())
return 0;
Type *ElementTy = SeqTy->getElementType();
uint64_t ElementSize = TD.getTypeAllocSize(ElementTy);
uint64_t NumSkippedElements = Offset / ElementSize;
if (ArrayType *ArrTy = dyn_cast<ArrayType>(SeqTy))
if (NumSkippedElements >= ArrTy->getNumElements())
return 0;
if (VectorType *VecTy = dyn_cast<VectorType>(SeqTy))
if (NumSkippedElements >= VecTy->getNumElements())
return 0;
Offset -= NumSkippedElements * ElementSize;
// First check if we need to recurse.
if (Offset > 0 || Size < ElementSize) {
// Bail if the partition ends in a different array element.
if ((Offset + Size) > ElementSize)
return 0;
// Recurse through the element type trying to peel off offset bytes.
return getTypePartition(TD, ElementTy, Offset, Size);
}
assert(Offset == 0);
if (Size == ElementSize)
return ElementTy;
assert(Size > ElementSize);
uint64_t NumElements = Size / ElementSize;
if (NumElements * ElementSize != Size)
return 0;
return ArrayType::get(ElementTy, NumElements);
}
StructType *STy = dyn_cast<StructType>(Ty);
if (!STy)
return 0;
const StructLayout *SL = TD.getStructLayout(STy);
if (Offset >= SL->getSizeInBytes())
return 0;
uint64_t EndOffset = Offset + Size;
if (EndOffset > SL->getSizeInBytes())
return 0;
unsigned Index = SL->getElementContainingOffset(Offset);
Offset -= SL->getElementOffset(Index);
Type *ElementTy = STy->getElementType(Index);
uint64_t ElementSize = TD.getTypeAllocSize(ElementTy);
if (Offset >= ElementSize)
return 0; // The offset points into alignment padding.
// See if any partition must be contained by the element.
if (Offset > 0 || Size < ElementSize) {
if ((Offset + Size) > ElementSize)
return 0;
return getTypePartition(TD, ElementTy, Offset, Size);
}
assert(Offset == 0);
if (Size == ElementSize)
return ElementTy;
StructType::element_iterator EI = STy->element_begin() + Index,
EE = STy->element_end();
if (EndOffset < SL->getSizeInBytes()) {
unsigned EndIndex = SL->getElementContainingOffset(EndOffset);
if (Index == EndIndex)
return 0; // Within a single element and its padding.
// Don't try to form "natural" types if the elements don't line up with the
// expected size.
// FIXME: We could potentially recurse down through the last element in the
// sub-struct to find a natural end point.
if (SL->getElementOffset(EndIndex) != EndOffset)
return 0;
assert(Index < EndIndex);
EE = STy->element_begin() + EndIndex;
}
// Try to build up a sub-structure.
SmallVector<Type *, 4> ElementTys;
do {
ElementTys.push_back(*EI++);
} while (EI != EE);
StructType *SubTy = StructType::get(STy->getContext(), ElementTys,
STy->isPacked());
const StructLayout *SubSL = TD.getStructLayout(SubTy);
if (Size != SubSL->getSizeInBytes())
return 0; // The sub-struct doesn't have quite the size needed.
return SubTy;
}
/// \brief Rewrite an alloca partition's users.
///
/// This routine drives both of the rewriting goals of the SROA pass. It tries
/// to rewrite uses of an alloca partition to be conducive for SSA value
/// promotion. If the partition needs a new, more refined alloca, this will
/// build that new alloca, preserving as much type information as possible, and
/// rewrite the uses of the old alloca to point at the new one and have the
/// appropriate new offsets. It also evaluates how successful the rewrite was
/// at enabling promotion and if it was successful queues the alloca to be
/// promoted.
bool SROA::rewriteAllocaPartition(AllocaInst &AI,
AllocaPartitioning &P,
AllocaPartitioning::iterator PI) {
uint64_t AllocaSize = PI->EndOffset - PI->BeginOffset;
if (P.use_begin(PI) == P.use_end(PI))
return false; // No live uses left of this partition.
// Try to compute a friendly type for this partition of the alloca. This
// won't always succeed, in which case we fall back to a legal integer type
// or an i8 array of an appropriate size.
Type *AllocaTy = 0;
if (Type *PartitionTy = P.getCommonType(PI))
if (TD->getTypeAllocSize(PartitionTy) >= AllocaSize)
AllocaTy = PartitionTy;
if (!AllocaTy)
if (Type *PartitionTy = getTypePartition(*TD, AI.getAllocatedType(),
PI->BeginOffset, AllocaSize))
AllocaTy = PartitionTy;
if ((!AllocaTy ||
(AllocaTy->isArrayTy() &&
AllocaTy->getArrayElementType()->isIntegerTy())) &&
TD->isLegalInteger(AllocaSize * 8))
AllocaTy = Type::getIntNTy(*C, AllocaSize * 8);
if (!AllocaTy)
AllocaTy = ArrayType::get(Type::getInt8Ty(*C), AllocaSize);
assert(TD->getTypeAllocSize(AllocaTy) >= AllocaSize);
// Check for the case where we're going to rewrite to a new alloca of the
// exact same type as the original, and with the same access offsets. In that
// case, re-use the existing alloca, but still run through the rewriter to
// performe phi and select speculation.
AllocaInst *NewAI;
if (AllocaTy == AI.getAllocatedType()) {
assert(PI->BeginOffset == 0 &&
"Non-zero begin offset but same alloca type");
assert(PI == P.begin() && "Begin offset is zero on later partition");
NewAI = &AI;
} else {
// FIXME: The alignment here is overly conservative -- we could in many
// cases get away with much weaker alignment constraints.
NewAI = new AllocaInst(AllocaTy, 0, AI.getAlignment(),
AI.getName() + ".sroa." + Twine(PI - P.begin()),
&AI);
++NumNewAllocas;
}
DEBUG(dbgs() << "Rewriting alloca partition "
<< "[" << PI->BeginOffset << "," << PI->EndOffset << ") to: "
<< *NewAI << "\n");
AllocaPartitionRewriter Rewriter(*TD, P, PI, *this, AI, *NewAI,
PI->BeginOffset, PI->EndOffset);
DEBUG(dbgs() << " rewriting ");
DEBUG(P.print(dbgs(), PI, ""));
if (Rewriter.visitUsers(P.use_begin(PI), P.use_end(PI))) {
DEBUG(dbgs() << " and queuing for promotion\n");
PromotableAllocas.push_back(NewAI);
} else if (NewAI != &AI) {
// If we can't promote the alloca, iterate on it to check for new
// refinements exposed by splitting the current alloca. Don't iterate on an
// alloca which didn't actually change and didn't get promoted.
Worklist.insert(NewAI);
}
return true;
}
/// \brief Walks the partitioning of an alloca rewriting uses of each partition.
bool SROA::splitAlloca(AllocaInst &AI, AllocaPartitioning &P) {
bool Changed = false;
for (AllocaPartitioning::iterator PI = P.begin(), PE = P.end(); PI != PE;
++PI)
Changed |= rewriteAllocaPartition(AI, P, PI);
return Changed;
}
/// \brief Analyze an alloca for SROA.
///
/// This analyzes the alloca to ensure we can reason about it, builds
/// a partitioning of the alloca, and then hands it off to be split and
/// rewritten as needed.
bool SROA::runOnAlloca(AllocaInst &AI) {
DEBUG(dbgs() << "SROA alloca: " << AI << "\n");
++NumAllocasAnalyzed;
// Special case dead allocas, as they're trivial.
if (AI.use_empty()) {
AI.eraseFromParent();
return true;
}
// Skip alloca forms that this analysis can't handle.
if (AI.isArrayAllocation() || !AI.getAllocatedType()->isSized() ||
TD->getTypeAllocSize(AI.getAllocatedType()) == 0)
return false;
// First check if this is a non-aggregate type that we should simply promote.
if (!AI.getAllocatedType()->isAggregateType() && isAllocaPromotable(&AI)) {
DEBUG(dbgs() << " Trivially scalar type, queuing for promotion...\n");
PromotableAllocas.push_back(&AI);
return false;
}
bool Changed = false;
// First, split any FCA loads and stores touching this alloca to promote
// better splitting and promotion opportunities.
AggLoadStoreRewriter AggRewriter(*TD);
Changed |= AggRewriter.rewrite(AI);
// Build the partition set using a recursive instruction-visiting builder.
AllocaPartitioning P(*TD, AI);
DEBUG(P.print(dbgs()));
if (P.isEscaped())
return Changed;
// No partitions to split. Leave the dead alloca for a later pass to clean up.
if (P.begin() == P.end())
return Changed;
// Delete all the dead users of this alloca before splitting and rewriting it.
for (AllocaPartitioning::dead_user_iterator DI = P.dead_user_begin(),
DE = P.dead_user_end();
DI != DE; ++DI) {
Changed = true;
(*DI)->replaceAllUsesWith(UndefValue::get((*DI)->getType()));
DeadInsts.push_back(*DI);
}
for (AllocaPartitioning::dead_op_iterator DO = P.dead_op_begin(),
DE = P.dead_op_end();
DO != DE; ++DO) {
Value *OldV = **DO;
// Clobber the use with an undef value.
**DO = UndefValue::get(OldV->getType());
if (Instruction *OldI = dyn_cast<Instruction>(OldV))
if (isInstructionTriviallyDead(OldI)) {
Changed = true;
DeadInsts.push_back(OldI);
}
}
return splitAlloca(AI, P) || Changed;
}
/// \brief Delete the dead instructions accumulated in this run.
///
/// Recursively deletes the dead instructions we've accumulated. This is done
/// at the very end to maximize locality of the recursive delete and to
/// minimize the problems of invalidated instruction pointers as such pointers
/// are used heavily in the intermediate stages of the algorithm.
///
/// We also record the alloca instructions deleted here so that they aren't
/// subsequently handed to mem2reg to promote.
void SROA::deleteDeadInstructions(SmallPtrSet<AllocaInst*, 4> &DeletedAllocas) {
DeadSplitInsts.clear();
while (!DeadInsts.empty()) {
Instruction *I = DeadInsts.pop_back_val();
DEBUG(dbgs() << "Deleting dead instruction: " << *I << "\n");
for (User::op_iterator OI = I->op_begin(), E = I->op_end(); OI != E; ++OI)
if (Instruction *U = dyn_cast<Instruction>(*OI)) {
// Zero out the operand and see if it becomes trivially dead.
*OI = 0;
if (isInstructionTriviallyDead(U))
DeadInsts.push_back(U);
}
if (AllocaInst *AI = dyn_cast<AllocaInst>(I))
DeletedAllocas.insert(AI);
++NumDeleted;
I->eraseFromParent();
}
}
/// \brief Promote the allocas, using the best available technique.
///
/// This attempts to promote whatever allocas have been identified as viable in
/// the PromotableAllocas list. If that list is empty, there is nothing to do.
/// If there is a domtree available, we attempt to promote using the full power
/// of mem2reg. Otherwise, we build and use the AllocaPromoter above which is
/// based on the SSAUpdater utilities. This function returns whether any
/// promotion occured.
bool SROA::promoteAllocas(Function &F) {
if (PromotableAllocas.empty())
return false;
NumPromoted += PromotableAllocas.size();
if (DT && !ForceSSAUpdater) {
DEBUG(dbgs() << "Promoting allocas with mem2reg...\n");
PromoteMemToReg(PromotableAllocas, *DT);
PromotableAllocas.clear();
return true;
}
DEBUG(dbgs() << "Promoting allocas with SSAUpdater...\n");
SSAUpdater SSA;
DIBuilder DIB(*F.getParent());
SmallVector<Instruction*, 64> Insts;
for (unsigned Idx = 0, Size = PromotableAllocas.size(); Idx != Size; ++Idx) {
AllocaInst *AI = PromotableAllocas[Idx];
for (Value::use_iterator UI = AI->use_begin(), UE = AI->use_end();
UI != UE;) {
Instruction *I = cast<Instruction>(*UI++);
// FIXME: Currently the SSAUpdater infrastructure doesn't reason about
// lifetime intrinsics and so we strip them (and the bitcasts+GEPs
// leading to them) here. Eventually it should use them to optimize the
// scalar values produced.
if (isa<BitCastInst>(I) || isa<GetElementPtrInst>(I)) {
assert(onlyUsedByLifetimeMarkers(I) &&
"Found a bitcast used outside of a lifetime marker.");
while (!I->use_empty())
cast<Instruction>(*I->use_begin())->eraseFromParent();
I->eraseFromParent();
continue;
}
if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(I)) {
assert(II->getIntrinsicID() == Intrinsic::lifetime_start ||
II->getIntrinsicID() == Intrinsic::lifetime_end);
II->eraseFromParent();
continue;
}
Insts.push_back(I);
}
AllocaPromoter(Insts, SSA, *AI, DIB).run(Insts);
Insts.clear();
}
PromotableAllocas.clear();
return true;
}
namespace {
/// \brief A predicate to test whether an alloca belongs to a set.
class IsAllocaInSet {
typedef SmallPtrSet<AllocaInst *, 4> SetType;
const SetType &Set;
public:
IsAllocaInSet(const SetType &Set) : Set(Set) {}
bool operator()(AllocaInst *AI) { return Set.count(AI); }
};
}
bool SROA::runOnFunction(Function &F) {
DEBUG(dbgs() << "SROA function: " << F.getName() << "\n");
C = &F.getContext();
TD = getAnalysisIfAvailable<TargetData>();
if (!TD) {
DEBUG(dbgs() << " Skipping SROA -- no target data!\n");
return false;
}
DT = getAnalysisIfAvailable<DominatorTree>();
BasicBlock &EntryBB = F.getEntryBlock();
for (BasicBlock::iterator I = EntryBB.begin(), E = llvm::prior(EntryBB.end());
I != E; ++I)
if (AllocaInst *AI = dyn_cast<AllocaInst>(I))
Worklist.insert(AI);
bool Changed = false;
// A set of deleted alloca instruction pointers which should be removed from
// the list of promotable allocas.
SmallPtrSet<AllocaInst *, 4> DeletedAllocas;
while (!Worklist.empty()) {
Changed |= runOnAlloca(*Worklist.pop_back_val());
deleteDeadInstructions(DeletedAllocas);
if (!DeletedAllocas.empty()) {
PromotableAllocas.erase(std::remove_if(PromotableAllocas.begin(),
PromotableAllocas.end(),
IsAllocaInSet(DeletedAllocas)),
PromotableAllocas.end());
DeletedAllocas.clear();
}
}
Changed |= promoteAllocas(F);
return Changed;
}
void SROA::getAnalysisUsage(AnalysisUsage &AU) const {
if (RequiresDomTree)
AU.addRequired<DominatorTree>();
AU.setPreservesCFG();
}
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