vn-verdnaturachat/ios/Pods/Flipper-Folly/folly/experimental/QuotientMultiSet-inl.h

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/*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <folly/experimental/QuotientMultiSet.h>
#include <folly/Format.h>
#include <folly/Portability.h>
#include <folly/experimental/Bits.h>
#include <folly/experimental/Select64.h>
#include <folly/lang/Bits.h>
#include <folly/lang/SafeAssert.h>
#include <glog/logging.h>
#if FOLLY_QUOTIENT_MULTI_SET_SUPPORTED
namespace folly {
namespace qms_detail {
/*
* Reference: Faster Remainder by Direct Computation: Applications to Compilers
* and Software Libraries, Software: Practice and Experience 49 (6), 2019.
*/
FOLLY_ALWAYS_INLINE UInt64InverseType getInverse(uint64_t divisor) {
UInt64InverseType fraction = UInt64InverseType(-1);
fraction /= divisor;
fraction += 1;
return fraction;
}
FOLLY_ALWAYS_INLINE uint64_t
mul128(UInt64InverseType lowbits, uint64_t divisor) {
UInt64InverseType bottomHalf =
(lowbits & UINT64_C(0xFFFFFFFFFFFFFFFF)) * divisor;
bottomHalf >>= 64;
UInt64InverseType topHalf = (lowbits >> 64) * divisor;
UInt64InverseType bothHalves = bottomHalf + topHalf;
bothHalves >>= 64;
return static_cast<uint64_t>(bothHalves);
}
FOLLY_ALWAYS_INLINE std::pair<uint64_t, uint64_t> getQuotientAndRemainder(
uint64_t dividend,
uint64_t divisor,
UInt64InverseType inverse) {
if (FOLLY_UNLIKELY(divisor == 1)) {
return {dividend, 0};
}
auto quotient = mul128(inverse, dividend);
auto remainder = dividend - quotient * divisor;
DCHECK_LT(remainder, divisor);
return {quotient, remainder};
}
// Max value for given bits.
FOLLY_ALWAYS_INLINE uint64_t maxValue(uint32_t nbits) {
return nbits == 64 ? std::numeric_limits<uint64_t>::max()
: (uint64_t(1) << nbits) - 1;
}
} // namespace qms_detail
template <class Instructions>
struct QuotientMultiSet<Instructions>::Metadata {
// Total number of blocks.
uint64_t numBlocks;
uint64_t numKeys;
uint64_t divisor;
uint8_t keyBits;
uint8_t remainderBits;
std::string debugString() const {
return sformat(
"Number of blocks: {}\n"
"Number of elements: {}\n"
"Divisor: {}\n"
"Key bits: {}\n"
"Remainder bits: {}",
numBlocks,
numKeys,
divisor,
keyBits,
remainderBits);
}
} FOLLY_PACK_ATTR;
template <class Instructions>
struct QuotientMultiSet<Instructions>::Block {
static const Block* get(const char* data) {
return reinterpret_cast<const Block*>(data);
}
static BlockPtr make(size_t remainderBits) {
auto ptr = reinterpret_cast<Block*>(calloc(blockSize(remainderBits), 1));
return {ptr, free};
}
uint64_t payload;
uint64_t occupieds;
uint64_t offset;
uint64_t runends;
char remainders[0];
static uint64_t blockSize(size_t remainderBits) {
return sizeof(Block) + remainderBits * 8;
}
FOLLY_ALWAYS_INLINE bool isOccupied(size_t offsetInBlock) const {
return ((occupieds >> offsetInBlock) & uint64_t(1)) != 0;
}
FOLLY_ALWAYS_INLINE bool isRunend(size_t offsetInBlock) const {
return ((runends >> offsetInBlock) & uint64_t(1)) != 0;
}
FOLLY_ALWAYS_INLINE uint64_t getRemainder(
size_t offsetInBlock,
size_t remainderBits,
size_t remainderMask) const {
DCHECK_LE(remainderBits, 56);
const size_t bitPos = offsetInBlock * remainderBits;
const uint64_t remainderWord =
loadUnaligned<uint64_t>(remainders + (bitPos / 8));
return (remainderWord >> (bitPos % 8)) & remainderMask;
}
void setOccupied(size_t offsetInBlock) {
occupieds |= uint64_t(1) << offsetInBlock;
}
void setRunend(size_t offsetInBlock) {
runends |= uint64_t(1) << offsetInBlock;
}
void
setRemainder(size_t offsetInBlock, size_t remainderBits, uint64_t remainder) {
DCHECK_LT(offsetInBlock, kBlockSize);
if (FOLLY_UNLIKELY(remainderBits == 0)) {
return;
}
Bits<uint64_t>::set(
reinterpret_cast<uint64_t*>(remainders),
offsetInBlock * remainderBits,
remainderBits,
remainder);
}
} FOLLY_PACK_ATTR;
template <class Instructions>
QuotientMultiSet<Instructions>::QuotientMultiSet(StringPiece data) {
static_assert(
kIsLittleEndian, "QuotientMultiSet requires little endianness.");
StringPiece sp = data;
CHECK_GE(sp.size(), sizeof(Metadata));
sp.advance(sp.size() - sizeof(Metadata));
metadata_ = reinterpret_cast<const Metadata*>(sp.data());
VLOG(2) << "Metadata: " << metadata_->debugString();
numBlocks_ = metadata_->numBlocks;
numSlots_ = numBlocks_ * kBlockSize;
divisor_ = metadata_->divisor;
fraction_ = qms_detail::getInverse(divisor_);
keyBits_ = metadata_->keyBits;
maxKey_ = qms_detail::maxValue(keyBits_);
remainderBits_ = metadata_->remainderBits;
remainderMask_ = qms_detail::maxValue(remainderBits_);
blockSize_ = Block::blockSize(remainderBits_);
CHECK_EQ(data.size(), numBlocks_ * blockSize_ + sizeof(Metadata));
data_ = data.data();
}
template <class Instructions>
auto QuotientMultiSet<Instructions>::equalRange(uint64_t key) const
-> SlotRange {
if (key > maxKey_) {
return {0, 0};
}
const auto qr = qms_detail::getQuotientAndRemainder(key, divisor_, fraction_);
const auto& quotient = qr.first;
const auto& remainder = qr.second;
const size_t blockIndex = quotient / kBlockSize;
const size_t offsetInBlock = quotient % kBlockSize;
if (FOLLY_UNLIKELY(blockIndex >= numBlocks_)) {
return {0, 0};
}
const auto* occBlock = getBlock(blockIndex);
__builtin_prefetch(reinterpret_cast<const char*>(&occBlock->occupieds) + 64);
const auto firstRunend = occBlock->offset;
if (!occBlock->isOccupied(offsetInBlock)) {
// Return a position that depends on the contents of the block so
// we can create a dependency in benchmarks.
return {firstRunend, firstRunend};
}
// Look for the right runend for the given key.
const uint64_t occupiedRank = Instructions::popcount(
Instructions::bzhi(occBlock->occupieds, offsetInBlock));
auto runend = findRunend(occupiedRank, firstRunend);
auto& slot = runend.first;
auto& block = runend.second;
// Iterates over the run backwards to find the slots whose remainder
// matches the key.
SlotRange range = {slot + 1, slot + 1};
while (true) {
uint64_t slotRemainder =
block->getRemainder(slot % kBlockSize, remainderBits_, remainderMask_);
if (slotRemainder > remainder) {
range.begin = slot;
range.end = slot;
} else if (slotRemainder == remainder) {
range.begin = slot;
} else {
break;
}
if (FOLLY_UNLIKELY(slot % kBlockSize == 0)) {
// Reached block start and the run starts from a prev block.
size_t slotBlockIndex = slot / kBlockSize;
if (slotBlockIndex > blockIndex) {
block = getBlock(slotBlockIndex - 1);
} else {
break;
}
}
--slot;
// Encounters the previous run.
if (block->isRunend(slot % kBlockSize)) {
break;
}
}
return range;
}
template <class Instructions>
auto QuotientMultiSet<Instructions>::findRunend(
uint64_t occupiedRank,
uint64_t firstRunend) const -> std::pair<uint64_t, const Block*> {
// Look for the right runend.
size_t slotBlockIndex = firstRunend / kBlockSize;
auto block = getBlock(slotBlockIndex);
uint64_t runendWord =
block->runends & (uint64_t(-1) << (firstRunend % kBlockSize));
while (true) {
DCHECK_LE(slotBlockIndex, numBlocks_);
const size_t numRuns = Instructions::popcount(runendWord);
if (FOLLY_LIKELY(numRuns > occupiedRank)) {
break;
}
occupiedRank -= numRuns;
++slotBlockIndex;
block = getBlock(slotBlockIndex);
runendWord = block->runends;
}
return {slotBlockIndex * kBlockSize +
select64<Instructions>(runendWord, occupiedRank),
block};
}
template <class Instructions>
uint64_t QuotientMultiSet<Instructions>::getBlockPayload(
uint64_t blockIndex) const {
DCHECK_LT(blockIndex, numBlocks_);
return getBlock(blockIndex)->payload;
}
template <class Instructions>
QuotientMultiSet<Instructions>::Iterator::Iterator(
const QuotientMultiSet<Instructions>* qms)
: qms_(qms),
key_(0),
occBlockIndex_(-1),
occOffsetInBlock_(0),
occWord_(0),
occBlock_(nullptr),
pos_(-1) {}
template <class Instructions>
bool QuotientMultiSet<Instructions>::Iterator::next() {
if (pos_ == size_t(-1) ||
qms_->getBlock(pos_ / kBlockSize)->isRunend(pos_ % kBlockSize)) {
// Move to start of next run.
if (!nextOccupied()) {
return setEnd();
}
// Next run either starts at pos + 1 or the start of block
// specified by occupied slot.
pos_ = std::max<uint64_t>(pos_ + 1, occBlockIndex_ * kBlockSize);
} else {
// Move to next slot since a run must be contiguous.
pos_++;
}
const Block* block = qms_->getBlock(pos_ / kBlockSize);
uint64_t quotient =
(occBlockIndex_ * kBlockSize + occOffsetInBlock_) * qms_->divisor_;
key_ = quotient +
block->getRemainder(
pos_ % kBlockSize, qms_->remainderBits_, qms_->remainderMask_);
DCHECK_LT(pos_, qms_->numBlocks_ * kBlockSize);
return true;
}
template <class Instructions>
bool QuotientMultiSet<Instructions>::Iterator::skipTo(uint64_t key) {
if (key > qms_->maxKey_) {
return false;
}
const auto qr =
qms_detail::getQuotientAndRemainder(key, qms_->divisor_, qms_->fraction_);
const auto& quotient = qr.first;
occBlockIndex_ = quotient / kBlockSize;
occOffsetInBlock_ = quotient % kBlockSize;
if (FOLLY_UNLIKELY(occBlockIndex_ >= qms_->numBlocks_)) {
return setEnd();
}
occBlock_ = qms_->getBlock(occBlockIndex_);
occWord_ = occBlock_->occupieds & (uint64_t(-1) << occOffsetInBlock_);
if (!nextOccupied()) {
return setEnd();
}
// Search for the next runend.
uint64_t occupiedRank = Instructions::popcount(
Instructions::bzhi(occBlock_->occupieds, occOffsetInBlock_));
auto runend = qms_->findRunend(occupiedRank, occBlock_->offset);
auto& slot = runend.first;
auto& block = runend.second;
uint64_t slotBlockIndex = slot / kBlockSize;
uint64_t slotOffsetInBlock = slot % kBlockSize;
pos_ = slot;
uint64_t nextQuotient =
(occBlockIndex_ * kBlockSize + occOffsetInBlock_) * qms_->divisor_;
uint64_t nextRemainder = block->getRemainder(
slotOffsetInBlock, qms_->remainderBits_, qms_->remainderMask_);
if (nextQuotient + nextRemainder < key) {
// Lower bound element is at the start of next run.
return next();
}
// Iterate over the run backwards to find the first key that is larger than
// or equal to the given key.
while (true) {
uint64_t slotRemainder = block->getRemainder(
slotOffsetInBlock, qms_->remainderBits_, qms_->remainderMask_);
if (nextQuotient + slotRemainder < key) {
break;
}
pos_ = slot;
nextRemainder = slotRemainder;
if (FOLLY_UNLIKELY(slotOffsetInBlock == 0)) {
// Reached block start and the run starts from a prev block.
if (slotBlockIndex > occBlockIndex_) {
--slotBlockIndex;
block = qms_->getBlock(slotBlockIndex);
slotOffsetInBlock = kBlockSize;
} else {
break;
}
}
--slot;
--slotOffsetInBlock;
// Encounters the previous run.
if (block->isRunend(slotOffsetInBlock)) {
break;
}
}
key_ = nextQuotient + nextRemainder;
return true;
}
template <class Instructions>
bool QuotientMultiSet<Instructions>::Iterator::nextOccupied() {
while (FOLLY_UNLIKELY(occWord_ == 0)) {
if (FOLLY_UNLIKELY(++occBlockIndex_ >= qms_->numBlocks_)) {
return false;
}
occBlock_ = qms_->getBlock(occBlockIndex_);
occWord_ = occBlock_->occupieds;
}
occOffsetInBlock_ = Instructions::ctz(occWord_);
occWord_ = Instructions::blsr(occWord_);
return true;
}
} // namespace folly
#endif // FOLLY_QUOTIENT_MULTI_SET_SUPPORTED