llvm/lib/Support/SmallPtrSet.cpp
Matthias Braun 5f33f2da6d SmallPtrSet: Avoid initializing Array in the small case.
This patch avoids the initial memset at the cost of making iterators
slightly more complex. This should be beneficial as most SmallPtrSets
hold no or only a few elements, while iterating over them is less
common.

Differential Revision: http://reviews.llvm.org/D16672

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@260913 91177308-0d34-0410-b5e6-96231b3b80d8
2016-02-15 21:38:42 +00:00

296 lines
9.9 KiB
C++

//===- llvm/ADT/SmallPtrSet.cpp - 'Normally small' pointer set ------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the SmallPtrSet class. See SmallPtrSet.h for an
// overview of the algorithm.
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/DenseMapInfo.h"
#include "llvm/Support/MathExtras.h"
#include <algorithm>
#include <cstdlib>
using namespace llvm;
void SmallPtrSetImplBase::shrink_and_clear() {
assert(!isSmall() && "Can't shrink a small set!");
free(CurArray);
// Reduce the number of buckets.
unsigned Size = size();
CurArraySize = Size > 16 ? 1 << (Log2_32_Ceil(Size) + 1) : 32;
NumNonEmpty = NumTombstones = 0;
// Install the new array. Clear all the buckets to empty.
CurArray = (const void**)malloc(sizeof(void*) * CurArraySize);
assert(CurArray && "Failed to allocate memory?");
memset(CurArray, -1, CurArraySize*sizeof(void*));
}
std::pair<const void *const *, bool>
SmallPtrSetImplBase::insert_imp_big(const void *Ptr) {
if (LLVM_UNLIKELY(size() * 4 >= CurArraySize * 3)) {
// If more than 3/4 of the array is full, grow.
Grow(CurArraySize < 64 ? 128 : CurArraySize * 2);
} else if (LLVM_UNLIKELY(CurArraySize - NumNonEmpty < CurArraySize / 8)) {
// If fewer of 1/8 of the array is empty (meaning that many are filled with
// tombstones), rehash.
Grow(CurArraySize);
}
// Okay, we know we have space. Find a hash bucket.
const void **Bucket = const_cast<const void**>(FindBucketFor(Ptr));
if (*Bucket == Ptr)
return std::make_pair(Bucket, false); // Already inserted, good.
// Otherwise, insert it!
if (*Bucket == getTombstoneMarker())
--NumTombstones;
else
++NumNonEmpty; // Track density.
*Bucket = Ptr;
return std::make_pair(Bucket, true);
}
bool SmallPtrSetImplBase::erase_imp(const void * Ptr) {
if (isSmall()) {
// Check to see if it is in the set.
for (const void **APtr = CurArray, **E = CurArray + NumNonEmpty; APtr != E;
++APtr)
if (*APtr == Ptr) {
// If it is in the set, replace this element.
*APtr = getTombstoneMarker();
++NumTombstones;
return true;
}
return false;
}
// Okay, we know we have space. Find a hash bucket.
void **Bucket = const_cast<void**>(FindBucketFor(Ptr));
if (*Bucket != Ptr) return false; // Not in the set?
// Set this as a tombstone.
*Bucket = getTombstoneMarker();
++NumTombstones;
return true;
}
const void * const *SmallPtrSetImplBase::FindBucketFor(const void *Ptr) const {
unsigned Bucket = DenseMapInfo<void *>::getHashValue(Ptr) & (CurArraySize-1);
unsigned ArraySize = CurArraySize;
unsigned ProbeAmt = 1;
const void *const *Array = CurArray;
const void *const *Tombstone = nullptr;
while (1) {
// If we found an empty bucket, the pointer doesn't exist in the set.
// Return a tombstone if we've seen one so far, or the empty bucket if
// not.
if (LLVM_LIKELY(Array[Bucket] == getEmptyMarker()))
return Tombstone ? Tombstone : Array+Bucket;
// Found Ptr's bucket?
if (LLVM_LIKELY(Array[Bucket] == Ptr))
return Array+Bucket;
// If this is a tombstone, remember it. If Ptr ends up not in the set, we
// prefer to return it than something that would require more probing.
if (Array[Bucket] == getTombstoneMarker() && !Tombstone)
Tombstone = Array+Bucket; // Remember the first tombstone found.
// It's a hash collision or a tombstone. Reprobe.
Bucket = (Bucket + ProbeAmt++) & (ArraySize-1);
}
}
/// Grow - Allocate a larger backing store for the buckets and move it over.
///
void SmallPtrSetImplBase::Grow(unsigned NewSize) {
const void **OldBuckets = CurArray;
const void **OldEnd = EndPointer();
bool WasSmall = isSmall();
// Install the new array. Clear all the buckets to empty.
CurArray = (const void**)malloc(sizeof(void*) * NewSize);
assert(CurArray && "Failed to allocate memory?");
CurArraySize = NewSize;
memset(CurArray, -1, NewSize*sizeof(void*));
// Copy over all valid entries.
for (const void **BucketPtr = OldBuckets; BucketPtr != OldEnd; ++BucketPtr) {
// Copy over the element if it is valid.
const void *Elt = *BucketPtr;
if (Elt != getTombstoneMarker() && Elt != getEmptyMarker())
*const_cast<void**>(FindBucketFor(Elt)) = const_cast<void*>(Elt);
}
if (!WasSmall)
free(OldBuckets);
NumNonEmpty -= NumTombstones;
NumTombstones = 0;
}
SmallPtrSetImplBase::SmallPtrSetImplBase(const void **SmallStorage,
const SmallPtrSetImplBase &that) {
SmallArray = SmallStorage;
// If we're becoming small, prepare to insert into our stack space
if (that.isSmall()) {
CurArray = SmallArray;
// Otherwise, allocate new heap space (unless we were the same size)
} else {
CurArray = (const void**)malloc(sizeof(void*) * that.CurArraySize);
assert(CurArray && "Failed to allocate memory?");
}
// Copy over the that array.
CopyHelper(that);
}
SmallPtrSetImplBase::SmallPtrSetImplBase(const void **SmallStorage,
unsigned SmallSize,
SmallPtrSetImplBase &&that) {
SmallArray = SmallStorage;
MoveHelper(SmallSize, std::move(that));
}
void SmallPtrSetImplBase::CopyFrom(const SmallPtrSetImplBase &RHS) {
assert(&RHS != this && "Self-copy should be handled by the caller.");
if (isSmall() && RHS.isSmall())
assert(CurArraySize == RHS.CurArraySize &&
"Cannot assign sets with different small sizes");
// If we're becoming small, prepare to insert into our stack space
if (RHS.isSmall()) {
if (!isSmall())
free(CurArray);
CurArray = SmallArray;
// Otherwise, allocate new heap space (unless we were the same size)
} else if (CurArraySize != RHS.CurArraySize) {
if (isSmall())
CurArray = (const void**)malloc(sizeof(void*) * RHS.CurArraySize);
else {
const void **T = (const void**)realloc(CurArray,
sizeof(void*) * RHS.CurArraySize);
if (!T)
free(CurArray);
CurArray = T;
}
assert(CurArray && "Failed to allocate memory?");
}
CopyHelper(RHS);
}
void SmallPtrSetImplBase::CopyHelper(const SmallPtrSetImplBase &RHS) {
// Copy over the new array size
CurArraySize = RHS.CurArraySize;
// Copy over the contents from the other set
std::copy(RHS.CurArray, RHS.EndPointer(), CurArray);
NumNonEmpty = RHS.NumNonEmpty;
NumTombstones = RHS.NumTombstones;
}
void SmallPtrSetImplBase::MoveFrom(unsigned SmallSize,
SmallPtrSetImplBase &&RHS) {
if (!isSmall())
free(CurArray);
MoveHelper(SmallSize, std::move(RHS));
}
void SmallPtrSetImplBase::MoveHelper(unsigned SmallSize,
SmallPtrSetImplBase &&RHS) {
assert(&RHS != this && "Self-move should be handled by the caller.");
if (RHS.isSmall()) {
// Copy a small RHS rather than moving.
CurArray = SmallArray;
std::copy(RHS.CurArray, RHS.CurArray + RHS.NumNonEmpty, CurArray);
} else {
CurArray = RHS.CurArray;
RHS.CurArray = RHS.SmallArray;
}
// Copy the rest of the trivial members.
CurArraySize = RHS.CurArraySize;
NumNonEmpty = RHS.NumNonEmpty;
NumTombstones = RHS.NumTombstones;
// Make the RHS small and empty.
RHS.CurArraySize = SmallSize;
assert(RHS.CurArray == RHS.SmallArray);
RHS.NumNonEmpty = 0;
RHS.NumTombstones = 0;
}
void SmallPtrSetImplBase::swap(SmallPtrSetImplBase &RHS) {
if (this == &RHS) return;
// We can only avoid copying elements if neither set is small.
if (!this->isSmall() && !RHS.isSmall()) {
std::swap(this->CurArray, RHS.CurArray);
std::swap(this->CurArraySize, RHS.CurArraySize);
std::swap(this->NumNonEmpty, RHS.NumNonEmpty);
std::swap(this->NumTombstones, RHS.NumTombstones);
return;
}
// FIXME: From here on we assume that both sets have the same small size.
// If only RHS is small, copy the small elements into LHS and move the pointer
// from LHS to RHS.
if (!this->isSmall() && RHS.isSmall()) {
assert(RHS.CurArray == RHS.SmallArray);
std::copy(RHS.CurArray, RHS.CurArray + RHS.NumNonEmpty, this->SmallArray);
std::swap(RHS.CurArraySize, this->CurArraySize);
std::swap(this->NumNonEmpty, RHS.NumNonEmpty);
std::swap(this->NumTombstones, RHS.NumTombstones);
RHS.CurArray = this->CurArray;
this->CurArray = this->SmallArray;
return;
}
// If only LHS is small, copy the small elements into RHS and move the pointer
// from RHS to LHS.
if (this->isSmall() && !RHS.isSmall()) {
assert(this->CurArray == this->SmallArray);
std::copy(this->CurArray, this->CurArray + this->NumNonEmpty,
RHS.SmallArray);
std::swap(RHS.CurArraySize, this->CurArraySize);
std::swap(RHS.NumNonEmpty, this->NumNonEmpty);
std::swap(RHS.NumTombstones, this->NumTombstones);
this->CurArray = RHS.CurArray;
RHS.CurArray = RHS.SmallArray;
return;
}
// Both a small, just swap the small elements.
assert(this->isSmall() && RHS.isSmall());
unsigned MinNonEmpty = std::min(this->NumNonEmpty, RHS.NumNonEmpty);
std::swap_ranges(this->SmallArray, this->SmallArray + MinNonEmpty,
RHS.SmallArray);
if (this->NumNonEmpty > MinNonEmpty) {
std::copy(this->SmallArray + MinNonEmpty,
this->SmallArray + this->NumNonEmpty,
RHS.SmallArray + MinNonEmpty);
} else {
std::copy(RHS.SmallArray + MinNonEmpty, RHS.SmallArray + RHS.NumNonEmpty,
this->SmallArray + MinNonEmpty);
}
assert(this->CurArraySize == RHS.CurArraySize);
std::swap(this->NumNonEmpty, RHS.NumNonEmpty);
std::swap(this->NumTombstones, RHS.NumTombstones);
}