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rocksdb/cache/clock_cache.cc

1258 lines
49 KiB

// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
//
// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file. See the AUTHORS file for names of contributors.
#include "cache/clock_cache.h"
#include <cassert>
#include <functional>
#include "cache/cache_key.h"
#include "monitoring/perf_context_imp.h"
#include "monitoring/statistics.h"
#include "port/lang.h"
#include "util/hash.h"
#include "util/math.h"
#include "util/random.h"
namespace ROCKSDB_NAMESPACE {
namespace clock_cache {
namespace {
inline uint64_t GetRefcount(uint64_t meta) {
return ((meta >> ClockHandle::kAcquireCounterShift) -
(meta >> ClockHandle::kReleaseCounterShift)) &
ClockHandle::kCounterMask;
}
inline uint64_t GetInitialCountdown(Cache::Priority priority) {
// Set initial clock data from priority
// TODO: configuration parameters for priority handling and clock cycle
// count?
switch (priority) {
case Cache::Priority::HIGH:
return ClockHandle::kHighCountdown;
default:
assert(false);
FALLTHROUGH_INTENDED;
case Cache::Priority::LOW:
return ClockHandle::kLowCountdown;
case Cache::Priority::BOTTOM:
return ClockHandle::kBottomCountdown;
}
}
inline void FreeDataMarkEmpty(ClockHandle& h) {
// NOTE: in theory there's more room for parallelism if we copy the handle
// data and delay actions like this until after marking the entry as empty,
// but performance tests only show a regression by copying the few words
// of data.
h.FreeData();
#ifndef NDEBUG
// Mark slot as empty, with assertion
uint64_t meta = h.meta.exchange(0, std::memory_order_release);
assert(meta >> ClockHandle::kStateShift == ClockHandle::kStateConstruction);
#else
// Mark slot as empty
h.meta.store(0, std::memory_order_release);
#endif
}
inline bool ClockUpdate(ClockHandle& h) {
uint64_t meta = h.meta.load(std::memory_order_relaxed);
uint64_t acquire_count =
(meta >> ClockHandle::kAcquireCounterShift) & ClockHandle::kCounterMask;
uint64_t release_count =
(meta >> ClockHandle::kReleaseCounterShift) & ClockHandle::kCounterMask;
// fprintf(stderr, "ClockUpdate @ %p: %lu %lu %u\n", &h, acquire_count,
// release_count, (unsigned)(meta >> ClockHandle::kStateShift));
if (acquire_count != release_count) {
// Only clock update entries with no outstanding refs
return false;
}
if (!((meta >> ClockHandle::kStateShift) & ClockHandle::kStateShareableBit)) {
// Only clock update Shareable entries
return false;
}
if ((meta >> ClockHandle::kStateShift == ClockHandle::kStateVisible) &&
acquire_count > 0) {
// Decrement clock
uint64_t new_count =
std::min(acquire_count - 1, uint64_t{ClockHandle::kMaxCountdown} - 1);
// Compare-exchange in the decremented clock info, but
// not aggressively
uint64_t new_meta =
(uint64_t{ClockHandle::kStateVisible} << ClockHandle::kStateShift) |
(new_count << ClockHandle::kReleaseCounterShift) |
(new_count << ClockHandle::kAcquireCounterShift);
h.meta.compare_exchange_strong(meta, new_meta, std::memory_order_relaxed);
return false;
}
// Otherwise, remove entry (either unreferenced invisible or
// unreferenced and expired visible).
if (h.meta.compare_exchange_strong(
meta,
uint64_t{ClockHandle::kStateConstruction} << ClockHandle::kStateShift,
std::memory_order_acquire)) {
// Took ownership.
return true;
} else {
// Compare-exchange failing probably
// indicates the entry was used, so skip it in that case.
return false;
}
}
} // namespace
void ClockHandleBasicData::FreeData() const {
if (deleter) {
UniqueId64x2 unhashed;
(*deleter)(
ClockCacheShard<HyperClockTable>::ReverseHash(hashed_key, &unhashed),
value);
}
}
HyperClockTable::HyperClockTable(
size_t capacity, bool /*strict_capacity_limit*/,
CacheMetadataChargePolicy metadata_charge_policy, const Opts& opts)
: length_bits_(CalcHashBits(capacity, opts.estimated_value_size,
metadata_charge_policy)),
length_bits_mask_((size_t{1} << length_bits_) - 1),
occupancy_limit_(static_cast<size_t>((uint64_t{1} << length_bits_) *
kStrictLoadFactor)),
array_(new HandleImpl[size_t{1} << length_bits_]) {
if (metadata_charge_policy ==
CacheMetadataChargePolicy::kFullChargeCacheMetadata) {
usage_ += size_t{GetTableSize()} * sizeof(HandleImpl);
}
static_assert(sizeof(HandleImpl) == 64U,
"Expecting size / alignment with common cache line size");
}
HyperClockTable::~HyperClockTable() {
// Assumes there are no references or active operations on any slot/element
// in the table.
for (size_t i = 0; i < GetTableSize(); i++) {
HandleImpl& h = array_[i];
switch (h.meta >> ClockHandle::kStateShift) {
case ClockHandle::kStateEmpty:
// noop
break;
case ClockHandle::kStateInvisible: // rare but possible
case ClockHandle::kStateVisible:
assert(GetRefcount(h.meta) == 0);
h.FreeData();
#ifndef NDEBUG
Rollback(h.hashed_key, &h);
ReclaimEntryUsage(h.GetTotalCharge());
#endif
break;
// otherwise
default:
assert(false);
break;
}
}
#ifndef NDEBUG
for (size_t i = 0; i < GetTableSize(); i++) {
assert(array_[i].displacements.load() == 0);
}
#endif
assert(usage_.load() == 0 ||
usage_.load() == size_t{GetTableSize()} * sizeof(HandleImpl));
assert(occupancy_ == 0);
}
// If an entry doesn't receive clock updates but is repeatedly referenced &
// released, the acquire and release counters could overflow without some
// intervention. This is that intervention, which should be inexpensive
// because it only incurs a simple, very predictable check. (Applying a bit
// mask in addition to an increment to every Release likely would be
// relatively expensive, because it's an extra atomic update.)
//
// We do have to assume that we never have many millions of simultaneous
// references to a cache handle, because we cannot represent so many
// references with the difference in counters, masked to the number of
// counter bits. Similarly, we assume there aren't millions of threads
// holding transient references (which might be "undone" rather than
// released by the way).
//
// Consider these possible states for each counter:
// low: less than kMaxCountdown
// medium: kMaxCountdown to half way to overflow + kMaxCountdown
// high: half way to overflow + kMaxCountdown, or greater
//
// And these possible states for the combination of counters:
// acquire / release
// ------- -------
// low low - Normal / common, with caveats (see below)
// medium low - Can happen while holding some refs
// high low - Violates assumptions (too many refs)
// low medium - Violates assumptions (refs underflow, etc.)
// medium medium - Normal (very read heavy cache)
// high medium - Can happen while holding some refs
// low high - This function is supposed to prevent
// medium high - Violates assumptions (refs underflow, etc.)
// high high - Needs CorrectNearOverflow
//
// Basically, this function detects (high, high) state (inferred from
// release alone being high) and bumps it back down to (medium, medium)
// state with the same refcount and the same logical countdown counter
// (everything > kMaxCountdown is logically the same). Note that bumping
// down to (low, low) would modify the countdown counter, so is "reserved"
// in a sense.
//
// If near-overflow correction is triggered here, there's no guarantee
// that another thread hasn't freed the entry and replaced it with another.
// Therefore, it must be the case that the correction does not affect
// entries unless they are very old (many millions of acquire-release cycles).
// (Our bit manipulation is indeed idempotent and only affects entries in
// exceptional cases.) We assume a pre-empted thread will not stall that long.
// If it did, the state could be corrupted in the (unlikely) case that the top
// bit of the acquire counter is set but not the release counter, and thus
// we only clear the top bit of the acquire counter on resumption. It would
// then appear that there are too many refs and the entry would be permanently
// pinned (which is not terrible for an exceptionally rare occurrence), unless
// it is referenced enough (at least kMaxCountdown more times) for the release
// counter to reach "high" state again and bumped back to "medium." (This
// motivates only checking for release counter in high state, not both in high
// state.)
inline void CorrectNearOverflow(uint64_t old_meta,
std::atomic<uint64_t>& meta) {
// We clear both top-most counter bits at the same time.
constexpr uint64_t kCounterTopBit = uint64_t{1}
<< (ClockHandle::kCounterNumBits - 1);
constexpr uint64_t kClearBits =
(kCounterTopBit << ClockHandle::kAcquireCounterShift) |
(kCounterTopBit << ClockHandle::kReleaseCounterShift);
// A simple check that allows us to initiate clearing the top bits for
// a large portion of the "high" state space on release counter.
constexpr uint64_t kCheckBits =
(kCounterTopBit | (ClockHandle::kMaxCountdown + 1))
<< ClockHandle::kReleaseCounterShift;
if (UNLIKELY(old_meta & kCheckBits)) {
meta.fetch_and(~kClearBits, std::memory_order_relaxed);
}
}
inline Status HyperClockTable::ChargeUsageMaybeEvictStrict(
size_t total_charge, size_t capacity, bool need_evict_for_occupancy) {
if (total_charge > capacity) {
return Status::MemoryLimit(
"Cache entry too large for a single cache shard: " +
std::to_string(total_charge) + " > " + std::to_string(capacity));
}
// Grab any available capacity, and free up any more required.
size_t old_usage = usage_.load(std::memory_order_relaxed);
size_t new_usage;
if (LIKELY(old_usage != capacity)) {
do {
new_usage = std::min(capacity, old_usage + total_charge);
} while (!usage_.compare_exchange_weak(old_usage, new_usage,
std::memory_order_relaxed));
} else {
new_usage = old_usage;
}
// How much do we need to evict then?
size_t need_evict_charge = old_usage + total_charge - new_usage;
size_t request_evict_charge = need_evict_charge;
if (UNLIKELY(need_evict_for_occupancy) && request_evict_charge == 0) {
// Require at least 1 eviction.
request_evict_charge = 1;
}
if (request_evict_charge > 0) {
size_t evicted_charge = 0;
size_t evicted_count = 0;
Evict(request_evict_charge, &evicted_charge, &evicted_count);
occupancy_.fetch_sub(evicted_count, std::memory_order_release);
if (LIKELY(evicted_charge > need_evict_charge)) {
assert(evicted_count > 0);
// Evicted more than enough
usage_.fetch_sub(evicted_charge - need_evict_charge,
std::memory_order_relaxed);
} else if (evicted_charge < need_evict_charge ||
(UNLIKELY(need_evict_for_occupancy) && evicted_count == 0)) {
// Roll back to old usage minus evicted
usage_.fetch_sub(evicted_charge + (new_usage - old_usage),
std::memory_order_relaxed);
if (evicted_charge < need_evict_charge) {
return Status::MemoryLimit(
"Insert failed because unable to evict entries to stay within "
"capacity limit.");
} else {
return Status::MemoryLimit(
"Insert failed because unable to evict entries to stay within "
"table occupancy limit.");
}
}
// If we needed to evict something and we are proceeding, we must have
// evicted something.
assert(evicted_count > 0);
}
return Status::OK();
}
inline bool HyperClockTable::ChargeUsageMaybeEvictNonStrict(
size_t total_charge, size_t capacity, bool need_evict_for_occupancy) {
// For simplicity, we consider that either the cache can accept the insert
// with no evictions, or we must evict enough to make (at least) enough
// space. It could lead to unnecessary failures or excessive evictions in
// some extreme cases, but allows a fast, simple protocol. If we allow a
// race to get us over capacity, then we might never get back to capacity
// limit if the sizes of entries allow each insertion to evict the minimum
// charge. Thus, we should evict some extra if it's not a signifcant
// portion of the shard capacity. This can have the side benefit of
// involving fewer threads in eviction.
size_t old_usage = usage_.load(std::memory_order_relaxed);
size_t need_evict_charge;
// NOTE: if total_charge > old_usage, there isn't yet enough to evict
// `total_charge` amount. Even if we only try to evict `old_usage` amount,
// there's likely something referenced and we would eat CPU looking for
// enough to evict.
if (old_usage + total_charge <= capacity || total_charge > old_usage) {
// Good enough for me (might run over with a race)
need_evict_charge = 0;
} else {
// Try to evict enough space, and maybe some extra
need_evict_charge = total_charge;
if (old_usage > capacity) {
// Not too much to avoid thundering herd while avoiding strict
// synchronization, such as the compare_exchange used with strict
// capacity limit.
need_evict_charge += std::min(capacity / 1024, total_charge) + 1;
}
}
if (UNLIKELY(need_evict_for_occupancy) && need_evict_charge == 0) {
// Special case: require at least 1 eviction if we only have to
// deal with occupancy
need_evict_charge = 1;
}
size_t evicted_charge = 0;
size_t evicted_count = 0;
if (need_evict_charge > 0) {
Evict(need_evict_charge, &evicted_charge, &evicted_count);
// Deal with potential occupancy deficit
if (UNLIKELY(need_evict_for_occupancy) && evicted_count == 0) {
assert(evicted_charge == 0);
// Can't meet occupancy requirement
return false;
} else {
// Update occupancy for evictions
occupancy_.fetch_sub(evicted_count, std::memory_order_release);
}
}
// Track new usage even if we weren't able to evict enough
usage_.fetch_add(total_charge - evicted_charge, std::memory_order_relaxed);
// No underflow
assert(usage_.load(std::memory_order_relaxed) < SIZE_MAX / 2);
// Success
return true;
}
inline HyperClockTable::HandleImpl* HyperClockTable::DetachedInsert(
const ClockHandleBasicData& proto) {
// Heap allocated separate from table
HandleImpl* h = new HandleImpl();
ClockHandleBasicData* h_alias = h;
*h_alias = proto;
h->SetDetached();
// Single reference (detached entries only created if returning a refed
// Handle back to user)
uint64_t meta = uint64_t{ClockHandle::kStateInvisible}
<< ClockHandle::kStateShift;
meta |= uint64_t{1} << ClockHandle::kAcquireCounterShift;
h->meta.store(meta, std::memory_order_release);
// Keep track of how much of usage is detached
detached_usage_.fetch_add(proto.GetTotalCharge(), std::memory_order_relaxed);
return h;
}
Status HyperClockTable::Insert(const ClockHandleBasicData& proto,
HandleImpl** handle, Cache::Priority priority,
size_t capacity, bool strict_capacity_limit) {
// Do we have the available occupancy? Optimistically assume we do
// and deal with it if we don't.
size_t old_occupancy = occupancy_.fetch_add(1, std::memory_order_acquire);
auto revert_occupancy_fn = [&]() {
occupancy_.fetch_sub(1, std::memory_order_relaxed);
};
// Whether we over-committed and need an eviction to make up for it
bool need_evict_for_occupancy = old_occupancy >= occupancy_limit_;
// Usage/capacity handling is somewhat different depending on
// strict_capacity_limit, but mostly pessimistic.
bool use_detached_insert = false;
const size_t total_charge = proto.GetTotalCharge();
if (strict_capacity_limit) {
Status s = ChargeUsageMaybeEvictStrict(total_charge, capacity,
need_evict_for_occupancy);
if (!s.ok()) {
revert_occupancy_fn();
return s;
}
} else {
// Case strict_capacity_limit == false
bool success = ChargeUsageMaybeEvictNonStrict(total_charge, capacity,
need_evict_for_occupancy);
if (!success) {
revert_occupancy_fn();
if (handle == nullptr) {
// Don't insert the entry but still return ok, as if the entry
// inserted into cache and evicted immediately.
proto.FreeData();
return Status::OK();
} else {
// Need to track usage of fallback detached insert
usage_.fetch_add(total_charge, std::memory_order_relaxed);
use_detached_insert = true;
}
}
}
auto revert_usage_fn = [&]() {
usage_.fetch_sub(total_charge, std::memory_order_relaxed);
// No underflow
assert(usage_.load(std::memory_order_relaxed) < SIZE_MAX / 2);
};
if (!use_detached_insert) {
// Attempt a table insert, but abort if we find an existing entry for the
// key. If we were to overwrite old entries, we would either
// * Have to gain ownership over an existing entry to overwrite it, which
// would only work if there are no outstanding (read) references and would
// create a small gap in availability of the entry (old or new) to lookups.
// * Have to insert into a suboptimal location (more probes) so that the
// old entry can be kept around as well.
uint64_t initial_countdown = GetInitialCountdown(priority);
assert(initial_countdown > 0);
size_t probe = 0;
HandleImpl* e = FindSlot(
proto.hashed_key,
[&](HandleImpl* h) {
// Optimistically transition the slot from "empty" to
// "under construction" (no effect on other states)
uint64_t old_meta =
h->meta.fetch_or(uint64_t{ClockHandle::kStateOccupiedBit}
<< ClockHandle::kStateShift,
std::memory_order_acq_rel);
uint64_t old_state = old_meta >> ClockHandle::kStateShift;
if (old_state == ClockHandle::kStateEmpty) {
// We've started inserting into an available slot, and taken
// ownership Save data fields
ClockHandleBasicData* h_alias = h;
*h_alias = proto;
// Transition from "under construction" state to "visible" state
uint64_t new_meta = uint64_t{ClockHandle::kStateVisible}
<< ClockHandle::kStateShift;
// Maybe with an outstanding reference
new_meta |= initial_countdown << ClockHandle::kAcquireCounterShift;
new_meta |= (initial_countdown - (handle != nullptr))
<< ClockHandle::kReleaseCounterShift;
#ifndef NDEBUG
// Save the state transition, with assertion
old_meta = h->meta.exchange(new_meta, std::memory_order_release);
assert(old_meta >> ClockHandle::kStateShift ==
ClockHandle::kStateConstruction);
#else
// Save the state transition
h->meta.store(new_meta, std::memory_order_release);
#endif
return true;
} else if (old_state != ClockHandle::kStateVisible) {
// Slot not usable / touchable now
return false;
}
// Existing, visible entry, which might be a match.
// But first, we need to acquire a ref to read it. In fact, number of
// refs for initial countdown, so that we boost the clock state if
// this is a match.
old_meta = h->meta.fetch_add(
ClockHandle::kAcquireIncrement * initial_countdown,
std::memory_order_acq_rel);
// Like Lookup
if ((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateVisible) {
// Acquired a read reference
if (h->hashed_key == proto.hashed_key) {
// Match. Release in a way that boosts the clock state
old_meta = h->meta.fetch_add(
ClockHandle::kReleaseIncrement * initial_countdown,
std::memory_order_acq_rel);
// Correct for possible (but rare) overflow
CorrectNearOverflow(old_meta, h->meta);
// Insert detached instead (only if return handle needed)
use_detached_insert = true;
return true;
} else {
// Mismatch. Pretend we never took the reference
old_meta = h->meta.fetch_sub(
ClockHandle::kAcquireIncrement * initial_countdown,
std::memory_order_acq_rel);
}
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateInvisible)) {
// Pretend we never took the reference
// WART: there's a tiny chance we release last ref to invisible
// entry here. If that happens, we let eviction take care of it.
old_meta = h->meta.fetch_sub(
ClockHandle::kAcquireIncrement * initial_countdown,
std::memory_order_acq_rel);
} else {
// For other states, incrementing the acquire counter has no effect
// so we don't need to undo it.
// Slot not usable / touchable now.
}
(void)old_meta;
return false;
},
[&](HandleImpl* /*h*/) { return false; },
[&](HandleImpl* h) {
h->displacements.fetch_add(1, std::memory_order_relaxed);
},
probe);
if (e == nullptr) {
// Occupancy check and never abort FindSlot above should generally
// prevent this, except it's theoretically possible for other threads
// to evict and replace entries in the right order to hit every slot
// when it is populated. Assuming random hashing, the chance of that
// should be no higher than pow(kStrictLoadFactor, n) for n slots.
// That should be infeasible for roughly n >= 256, so if this assertion
// fails, that suggests something is going wrong.
assert(GetTableSize() < 256);
use_detached_insert = true;
}
if (!use_detached_insert) {
// Successfully inserted
if (handle) {
*handle = e;
}
return Status::OK();
}
// Roll back table insertion
Rollback(proto.hashed_key, e);
revert_occupancy_fn();
// Maybe fall back on detached insert
if (handle == nullptr) {
revert_usage_fn();
// As if unrefed entry immdiately evicted
proto.FreeData();
return Status::OK();
}
}
// Run detached insert
assert(use_detached_insert);
*handle = DetachedInsert(proto);
// The OkOverwritten status is used to count "redundant" insertions into
// block cache. This implementation doesn't strictly check for redundant
// insertions, but we instead are probably interested in how many insertions
// didn't go into the table (instead "detached"), which could be redundant
// Insert or some other reason (use_detached_insert reasons above).
return Status::OkOverwritten();
}
HyperClockTable::HandleImpl* HyperClockTable::Lookup(
const UniqueId64x2& hashed_key) {
size_t probe = 0;
HandleImpl* e = FindSlot(
hashed_key,
[&](HandleImpl* h) {
// Mostly branch-free version (similar performance)
/*
uint64_t old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
bool Shareable = (old_meta >> (ClockHandle::kStateShift + 1)) & 1U;
bool visible = (old_meta >> ClockHandle::kStateShift) & 1U;
bool match = (h->key == key) & visible;
h->meta.fetch_sub(static_cast<uint64_t>(Shareable & !match) <<
ClockHandle::kAcquireCounterShift, std::memory_order_release); return
match;
*/
// Optimistic lookup should pay off when the table is relatively
// sparse.
constexpr bool kOptimisticLookup = true;
uint64_t old_meta;
if (!kOptimisticLookup) {
old_meta = h->meta.load(std::memory_order_acquire);
if ((old_meta >> ClockHandle::kStateShift) !=
ClockHandle::kStateVisible) {
return false;
}
}
// (Optimistically) increment acquire counter
old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
// Check if it's an entry visible to lookups
if ((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateVisible) {
// Acquired a read reference
if (h->hashed_key == hashed_key) {
// Match
return true;
} else {
// Mismatch. Pretend we never took the reference
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
}
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateInvisible)) {
// Pretend we never took the reference
// WART: there's a tiny chance we release last ref to invisible
// entry here. If that happens, we let eviction take care of it.
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
} else {
// For other states, incrementing the acquire counter has no effect
// so we don't need to undo it. Furthermore, we cannot safely undo
// it because we did not acquire a read reference to lock the
// entry in a Shareable state.
}
(void)old_meta;
return false;
},
[&](HandleImpl* h) {
return h->displacements.load(std::memory_order_relaxed) == 0;
},
[&](HandleImpl* /*h*/) {}, probe);
return e;
}
bool HyperClockTable::Release(HandleImpl* h, bool useful,
bool erase_if_last_ref) {
// In contrast with LRUCache's Release, this function won't delete the handle
// when the cache is above capacity and the reference is the last one. Space
// is only freed up by EvictFromClock (called by Insert when space is needed)
// and Erase. We do this to avoid an extra atomic read of the variable usage_.
uint64_t old_meta;
if (useful) {
// Increment release counter to indicate was used
old_meta = h->meta.fetch_add(ClockHandle::kReleaseIncrement,
std::memory_order_release);
} else {
// Decrement acquire counter to pretend it never happened
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
}
assert((old_meta >> ClockHandle::kStateShift) &
ClockHandle::kStateShareableBit);
// No underflow
assert(((old_meta >> ClockHandle::kAcquireCounterShift) &
ClockHandle::kCounterMask) !=
((old_meta >> ClockHandle::kReleaseCounterShift) &
ClockHandle::kCounterMask));
if (erase_if_last_ref || UNLIKELY(old_meta >> ClockHandle::kStateShift ==
ClockHandle::kStateInvisible)) {
// Update for last fetch_add op
if (useful) {
old_meta += ClockHandle::kReleaseIncrement;
} else {
old_meta -= ClockHandle::kAcquireIncrement;
}
// Take ownership if no refs
do {
if (GetRefcount(old_meta) != 0) {
// Not last ref at some point in time during this Release call
// Correct for possible (but rare) overflow
CorrectNearOverflow(old_meta, h->meta);
return false;
}
if ((old_meta & (uint64_t{ClockHandle::kStateShareableBit}
<< ClockHandle::kStateShift)) == 0) {
// Someone else took ownership
return false;
}
// Note that there's a small chance that we release, another thread
// replaces this entry with another, reaches zero refs, and then we end
// up erasing that other entry. That's an acceptable risk / imprecision.
} while (!h->meta.compare_exchange_weak(
old_meta,
uint64_t{ClockHandle::kStateConstruction} << ClockHandle::kStateShift,
std::memory_order_acquire));
// Took ownership
size_t total_charge = h->GetTotalCharge();
if (UNLIKELY(h->IsDetached())) {
h->FreeData();
// Delete detached handle
delete h;
detached_usage_.fetch_sub(total_charge, std::memory_order_relaxed);
usage_.fetch_sub(total_charge, std::memory_order_relaxed);
} else {
Rollback(h->hashed_key, h);
FreeDataMarkEmpty(*h);
ReclaimEntryUsage(total_charge);
}
return true;
} else {
// Correct for possible (but rare) overflow
CorrectNearOverflow(old_meta, h->meta);
return false;
}
}
void HyperClockTable::Ref(HandleImpl& h) {
// Increment acquire counter
uint64_t old_meta = h.meta.fetch_add(ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
assert((old_meta >> ClockHandle::kStateShift) &
ClockHandle::kStateShareableBit);
// Must have already had a reference
assert(GetRefcount(old_meta) > 0);
(void)old_meta;
}
void HyperClockTable::TEST_RefN(HandleImpl& h, size_t n) {
// Increment acquire counter
uint64_t old_meta = h.meta.fetch_add(n * ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
assert((old_meta >> ClockHandle::kStateShift) &
ClockHandle::kStateShareableBit);
(void)old_meta;
}
void HyperClockTable::TEST_ReleaseN(HandleImpl* h, size_t n) {
if (n > 0) {
// Split into n - 1 and 1 steps.
uint64_t old_meta = h->meta.fetch_add(
(n - 1) * ClockHandle::kReleaseIncrement, std::memory_order_acquire);
assert((old_meta >> ClockHandle::kStateShift) &
ClockHandle::kStateShareableBit);
(void)old_meta;
Release(h, /*useful*/ true, /*erase_if_last_ref*/ false);
}
}
void HyperClockTable::Erase(const UniqueId64x2& hashed_key) {
size_t probe = 0;
(void)FindSlot(
hashed_key,
[&](HandleImpl* h) {
// Could be multiple entries in rare cases. Erase them all.
// Optimistically increment acquire counter
uint64_t old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
// Check if it's an entry visible to lookups
if ((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateVisible) {
// Acquired a read reference
if (h->hashed_key == hashed_key) {
// Match. Set invisible.
old_meta =
h->meta.fetch_and(~(uint64_t{ClockHandle::kStateVisibleBit}
<< ClockHandle::kStateShift),
std::memory_order_acq_rel);
// Apply update to local copy
old_meta &= ~(uint64_t{ClockHandle::kStateVisibleBit}
<< ClockHandle::kStateShift);
for (;;) {
uint64_t refcount = GetRefcount(old_meta);
assert(refcount > 0);
if (refcount > 1) {
// Not last ref at some point in time during this Erase call
// Pretend we never took the reference
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
break;
} else if (h->meta.compare_exchange_weak(
old_meta,
uint64_t{ClockHandle::kStateConstruction}
<< ClockHandle::kStateShift,
std::memory_order_acq_rel)) {
// Took ownership
assert(hashed_key == h->hashed_key);
size_t total_charge = h->GetTotalCharge();
FreeDataMarkEmpty(*h);
ReclaimEntryUsage(total_charge);
// We already have a copy of hashed_key in this case, so OK to
// delay Rollback until after releasing the entry
Rollback(hashed_key, h);
break;
}
}
} else {
// Mismatch. Pretend we never took the reference
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
}
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
ClockHandle::kStateInvisible)) {
// Pretend we never took the reference
// WART: there's a tiny chance we release last ref to invisible
// entry here. If that happens, we let eviction take care of it.
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
} else {
// For other states, incrementing the acquire counter has no effect
// so we don't need to undo it.
}
return false;
},
[&](HandleImpl* h) {
return h->displacements.load(std::memory_order_relaxed) == 0;
},
[&](HandleImpl* /*h*/) {}, probe);
}
void HyperClockTable::ConstApplyToEntriesRange(
std::function<void(const HandleImpl&)> func, size_t index_begin,
size_t index_end, bool apply_if_will_be_deleted) const {
uint64_t check_state_mask = ClockHandle::kStateShareableBit;
if (!apply_if_will_be_deleted) {
check_state_mask |= ClockHandle::kStateVisibleBit;
}
for (size_t i = index_begin; i < index_end; i++) {
HandleImpl& h = array_[i];
// Note: to avoid using compare_exchange, we have to be extra careful.
uint64_t old_meta = h.meta.load(std::memory_order_relaxed);
// Check if it's an entry visible to lookups
if ((old_meta >> ClockHandle::kStateShift) & check_state_mask) {
// Increment acquire counter. Note: it's possible that the entry has
// completely changed since we loaded old_meta, but incrementing acquire
// count is always safe. (Similar to optimistic Lookup here.)
old_meta = h.meta.fetch_add(ClockHandle::kAcquireIncrement,
std::memory_order_acquire);
// Check whether we actually acquired a reference.
if ((old_meta >> ClockHandle::kStateShift) &
ClockHandle::kStateShareableBit) {
// Apply func if appropriate
if ((old_meta >> ClockHandle::kStateShift) & check_state_mask) {
func(h);
}
// Pretend we never took the reference
h.meta.fetch_sub(ClockHandle::kAcquireIncrement,
std::memory_order_release);
// No net change, so don't need to check for overflow
} else {
// For other states, incrementing the acquire counter has no effect
// so we don't need to undo it. Furthermore, we cannot safely undo
// it because we did not acquire a read reference to lock the
// entry in a Shareable state.
}
}
}
}
void HyperClockTable::EraseUnRefEntries() {
for (size_t i = 0; i <= this->length_bits_mask_; i++) {
HandleImpl& h = array_[i];
uint64_t old_meta = h.meta.load(std::memory_order_relaxed);
if (old_meta & (uint64_t{ClockHandle::kStateShareableBit}
<< ClockHandle::kStateShift) &&
GetRefcount(old_meta) == 0 &&
h.meta.compare_exchange_strong(old_meta,
uint64_t{ClockHandle::kStateConstruction}
<< ClockHandle::kStateShift,
std::memory_order_acquire)) {
// Took ownership
size_t total_charge = h.GetTotalCharge();
Rollback(h.hashed_key, &h);
FreeDataMarkEmpty(h);
ReclaimEntryUsage(total_charge);
}
}
}
inline HyperClockTable::HandleImpl* HyperClockTable::FindSlot(
const UniqueId64x2& hashed_key, std::function<bool(HandleImpl*)> match_fn,
std::function<bool(HandleImpl*)> abort_fn,
std::function<void(HandleImpl*)> update_fn, size_t& probe) {
// NOTE: upper 32 bits of hashed_key[0] is used for sharding
//
// We use double-hashing probing. Every probe in the sequence is a
// pseudorandom integer, computed as a linear function of two random hashes,
// which we call base and increment. Specifically, the i-th probe is base + i
// * increment modulo the table size.
size_t base = static_cast<size_t>(hashed_key[1]);
// We use an odd increment, which is relatively prime with the power-of-two
// table size. This implies that we cycle back to the first probe only
// after probing every slot exactly once.
// TODO: we could also reconsider linear probing, though locality benefits
// are limited because each slot is a full cache line
size_t increment = static_cast<size_t>(hashed_key[0]) | 1U;
size_t current = ModTableSize(base + probe * increment);
while (probe <= length_bits_mask_) {
HandleImpl* h = &array_[current];
if (match_fn(h)) {
probe++;
return h;
}
if (abort_fn(h)) {
return nullptr;
}
probe++;
update_fn(h);
current = ModTableSize(current + increment);
}
// We looped back.
return nullptr;
}
inline void HyperClockTable::Rollback(const UniqueId64x2& hashed_key,
const HandleImpl* h) {
size_t current = ModTableSize(hashed_key[1]);
size_t increment = static_cast<size_t>(hashed_key[0]) | 1U;
while (&array_[current] != h) {
array_[current].displacements.fetch_sub(1, std::memory_order_relaxed);
current = ModTableSize(current + increment);
}
}
inline void HyperClockTable::ReclaimEntryUsage(size_t total_charge) {
auto old_occupancy = occupancy_.fetch_sub(1U, std::memory_order_release);
(void)old_occupancy;
// No underflow
assert(old_occupancy > 0);
auto old_usage = usage_.fetch_sub(total_charge, std::memory_order_relaxed);
(void)old_usage;
// No underflow
assert(old_usage >= total_charge);
}
inline void HyperClockTable::Evict(size_t requested_charge,
size_t* freed_charge, size_t* freed_count) {
// precondition
assert(requested_charge > 0);
// TODO: make a tuning parameter?
constexpr size_t step_size = 4;
// First (concurrent) increment clock pointer
uint64_t old_clock_pointer =
clock_pointer_.fetch_add(step_size, std::memory_order_relaxed);
// Cap the eviction effort at this thread (along with those operating in
// parallel) circling through the whole structure kMaxCountdown times.
// In other words, this eviction run must find something/anything that is
// unreferenced at start of and during the eviction run that isn't reclaimed
// by a concurrent eviction run.
uint64_t max_clock_pointer =
old_clock_pointer + (ClockHandle::kMaxCountdown << length_bits_);
for (;;) {
for (size_t i = 0; i < step_size; i++) {
HandleImpl& h = array_[ModTableSize(Lower32of64(old_clock_pointer + i))];
bool evicting = ClockUpdate(h);
if (evicting) {
Rollback(h.hashed_key, &h);
*freed_charge += h.GetTotalCharge();
*freed_count += 1;
FreeDataMarkEmpty(h);
}
}
// Loop exit condition
if (*freed_charge >= requested_charge) {
return;
}
if (old_clock_pointer >= max_clock_pointer) {
return;
}
// Advance clock pointer (concurrently)
old_clock_pointer =
clock_pointer_.fetch_add(step_size, std::memory_order_relaxed);
}
}
template <class Table>
ClockCacheShard<Table>::ClockCacheShard(
size_t capacity, bool strict_capacity_limit,
CacheMetadataChargePolicy metadata_charge_policy,
const typename Table::Opts& opts)
: CacheShardBase(metadata_charge_policy),
table_(capacity, strict_capacity_limit, metadata_charge_policy, opts),
capacity_(capacity),
strict_capacity_limit_(strict_capacity_limit) {
// Initial charge metadata should not exceed capacity
assert(table_.GetUsage() <= capacity_ || capacity_ < sizeof(HandleImpl));
}
template <class Table>
void ClockCacheShard<Table>::EraseUnRefEntries() {
table_.EraseUnRefEntries();
}
template <class Table>
void ClockCacheShard<Table>::ApplyToSomeEntries(
const std::function<void(const Slice& key, void* value, size_t charge,
DeleterFn deleter)>& callback,
size_t average_entries_per_lock, size_t* state) {
// The state is essentially going to be the starting hash, which works
// nicely even if we resize between calls because we use upper-most
// hash bits for table indexes.
size_t length_bits = table_.GetLengthBits();
size_t length = table_.GetTableSize();
assert(average_entries_per_lock > 0);
// Assuming we are called with same average_entries_per_lock repeatedly,
// this simplifies some logic (index_end will not overflow).
assert(average_entries_per_lock < length || *state == 0);
size_t index_begin = *state >> (sizeof(size_t) * 8u - length_bits);
size_t index_end = index_begin + average_entries_per_lock;
if (index_end >= length) {
// Going to end.
index_end = length;
*state = SIZE_MAX;
} else {
*state = index_end << (sizeof(size_t) * 8u - length_bits);
}
table_.ConstApplyToEntriesRange(
[callback](const HandleImpl& h) {
UniqueId64x2 unhashed;
callback(ReverseHash(h.hashed_key, &unhashed), h.value,
h.GetTotalCharge(), h.deleter);
},
index_begin, index_end, false);
}
int HyperClockTable::CalcHashBits(
size_t capacity, size_t estimated_value_size,
CacheMetadataChargePolicy metadata_charge_policy) {
double average_slot_charge = estimated_value_size * kLoadFactor;
if (metadata_charge_policy == kFullChargeCacheMetadata) {
average_slot_charge += sizeof(HandleImpl);
}
assert(average_slot_charge > 0.0);
uint64_t num_slots =
static_cast<uint64_t>(capacity / average_slot_charge + 0.999999);
int hash_bits = FloorLog2((num_slots << 1) - 1);
if (metadata_charge_policy == kFullChargeCacheMetadata) {
// For very small estimated value sizes, it's possible to overshoot
while (hash_bits > 0 &&
uint64_t{sizeof(HandleImpl)} << hash_bits > capacity) {
hash_bits--;
}
}
return hash_bits;
}
template <class Table>
void ClockCacheShard<Table>::SetCapacity(size_t capacity) {
capacity_.store(capacity, std::memory_order_relaxed);
// next Insert will take care of any necessary evictions
}
template <class Table>
void ClockCacheShard<Table>::SetStrictCapacityLimit(
bool strict_capacity_limit) {
strict_capacity_limit_.store(strict_capacity_limit,
std::memory_order_relaxed);
// next Insert will take care of any necessary evictions
}
template <class Table>
Status ClockCacheShard<Table>::Insert(const Slice& key,
const UniqueId64x2& hashed_key,
void* value, size_t charge,
Cache::DeleterFn deleter,
HandleImpl** handle,
Cache::Priority priority) {
if (UNLIKELY(key.size() != kCacheKeySize)) {
return Status::NotSupported("ClockCache only supports key size " +
std::to_string(kCacheKeySize) + "B");
}
ClockHandleBasicData proto;
proto.hashed_key = hashed_key;
proto.value = value;
proto.deleter = deleter;
proto.total_charge = charge;
Status s = table_.Insert(
proto, handle, priority, capacity_.load(std::memory_order_relaxed),
strict_capacity_limit_.load(std::memory_order_relaxed));
return s;
}
template <class Table>
typename ClockCacheShard<Table>::HandleImpl* ClockCacheShard<Table>::Lookup(
const Slice& key, const UniqueId64x2& hashed_key) {
if (UNLIKELY(key.size() != kCacheKeySize)) {
return nullptr;
}
return table_.Lookup(hashed_key);
}
template <class Table>
bool ClockCacheShard<Table>::Ref(HandleImpl* h) {
if (h == nullptr) {
return false;
}
table_.Ref(*h);
return true;
}
template <class Table>
bool ClockCacheShard<Table>::Release(HandleImpl* handle, bool useful,
bool erase_if_last_ref) {
if (handle == nullptr) {
return false;
}
return table_.Release(handle, useful, erase_if_last_ref);
}
template <class Table>
void ClockCacheShard<Table>::TEST_RefN(HandleImpl* h, size_t n) {
table_.TEST_RefN(*h, n);
}
template <class Table>
void ClockCacheShard<Table>::TEST_ReleaseN(HandleImpl* h, size_t n) {
table_.TEST_ReleaseN(h, n);
}
template <class Table>
bool ClockCacheShard<Table>::Release(HandleImpl* handle,
bool erase_if_last_ref) {
return Release(handle, /*useful=*/true, erase_if_last_ref);
}
template <class Table>
void ClockCacheShard<Table>::Erase(const Slice& key,
const UniqueId64x2& hashed_key) {
if (UNLIKELY(key.size() != kCacheKeySize)) {
return;
}
table_.Erase(hashed_key);
}
template <class Table>
size_t ClockCacheShard<Table>::GetUsage() const {
return table_.GetUsage();
}
template <class Table>
size_t ClockCacheShard<Table>::GetPinnedUsage() const {
// Computes the pinned usage by scanning the whole hash table. This
// is slow, but avoids keeping an exact counter on the clock usage,
// i.e., the number of not externally referenced elements.
// Why avoid this counter? Because Lookup removes elements from the clock
// list, so it would need to update the pinned usage every time,
// which creates additional synchronization costs.
size_t table_pinned_usage = 0;
const bool charge_metadata =
metadata_charge_policy_ == kFullChargeCacheMetadata;
table_.ConstApplyToEntriesRange(
[&table_pinned_usage, charge_metadata](const HandleImpl& h) {
uint64_t meta = h.meta.load(std::memory_order_relaxed);
uint64_t refcount = GetRefcount(meta);
// Holding one ref for ConstApplyToEntriesRange
assert(refcount > 0);
if (refcount > 1) {
table_pinned_usage += h.GetTotalCharge();
if (charge_metadata) {
table_pinned_usage += sizeof(HandleImpl);
}
}
},
0, table_.GetTableSize(), true);
return table_pinned_usage + table_.GetDetachedUsage();
}
template <class Table>
size_t ClockCacheShard<Table>::GetOccupancyCount() const {
return table_.GetOccupancy();
}
template <class Table>
size_t ClockCacheShard<Table>::GetTableAddressCount() const {
return table_.GetTableSize();
}
// Explicit instantiation
template class ClockCacheShard<HyperClockTable>;
HyperClockCache::HyperClockCache(
size_t capacity, size_t estimated_value_size, int num_shard_bits,
bool strict_capacity_limit,
CacheMetadataChargePolicy metadata_charge_policy,
std::shared_ptr<MemoryAllocator> memory_allocator)
: ShardedCache(capacity, num_shard_bits, strict_capacity_limit,
std::move(memory_allocator)) {
assert(estimated_value_size > 0 ||
metadata_charge_policy != kDontChargeCacheMetadata);
// TODO: should not need to go through two levels of pointer indirection to
// get to table entries
size_t per_shard = GetPerShardCapacity();
InitShards([=](Shard* cs) {
HyperClockTable::Opts opts;
opts.estimated_value_size = estimated_value_size;
new (cs)
Shard(per_shard, strict_capacity_limit, metadata_charge_policy, opts);
});
}
void* HyperClockCache::Value(Handle* handle) {
return reinterpret_cast<const HandleImpl*>(handle)->value;
}
size_t HyperClockCache::GetCharge(Handle* handle) const {
return reinterpret_cast<const HandleImpl*>(handle)->GetTotalCharge();
}
Cache::DeleterFn HyperClockCache::GetDeleter(Handle* handle) const {
auto h = reinterpret_cast<const HandleImpl*>(handle);
return h->deleter;
}
} // namespace clock_cache
// DEPRECATED (see public API)
std::shared_ptr<Cache> NewClockCache(
size_t capacity, int num_shard_bits, bool strict_capacity_limit,
CacheMetadataChargePolicy metadata_charge_policy) {
return NewLRUCache(capacity, num_shard_bits, strict_capacity_limit,
/* high_pri_pool_ratio */ 0.5, nullptr,
kDefaultToAdaptiveMutex, metadata_charge_policy,
/* low_pri_pool_ratio */ 0.0);
}
std::shared_ptr<Cache> HyperClockCacheOptions::MakeSharedCache() const {
auto my_num_shard_bits = num_shard_bits;
if (my_num_shard_bits >= 20) {
return nullptr; // The cache cannot be sharded into too many fine pieces.
}
if (my_num_shard_bits < 0) {
// Use larger shard size to reduce risk of large entries clustering
// or skewing individual shards.
constexpr size_t min_shard_size = 32U * 1024U * 1024U;
my_num_shard_bits = GetDefaultCacheShardBits(capacity, min_shard_size);
}
return std::make_shared<clock_cache::HyperClockCache>(
capacity, estimated_entry_charge, my_num_shard_bits,
strict_capacity_limit, metadata_charge_policy, memory_allocator);
}
} // namespace ROCKSDB_NAMESPACE