vn-verdnaturachat/ios/Pods/Flipper-Folly/folly/synchronization/HazptrDomain.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.
*/
#pragma once
#include <folly/synchronization/Hazptr-fwd.h>
#include <folly/synchronization/HazptrObj.h>
#include <folly/synchronization/HazptrRec.h>
#include <folly/synchronization/HazptrThrLocal.h>
#include <folly/Memory.h>
#include <folly/Portability.h>
#include <folly/executors/QueuedImmediateExecutor.h>
#include <folly/synchronization/AsymmetricMemoryBarrier.h>
#include <atomic>
#include <unordered_set> // for hash set in bulk_reclaim
///
/// Classes related to hazard pointer domains.
///
namespace folly {
namespace detail {
constexpr int hazptr_domain_rcount_threshold() {
return 1000;
}
} // namespace detail
/**
* hazptr_domain
*
* A domain manages a set of hazard pointers and a set of retired objects.
*
* Most user code need not specify any domains.
*
* Notes on destruction order, tagged objects, locking and deadlock
* avoidance:
* - Tagged objects support reclamation order guarantees. A call to
* cleanup_cohort_tag(tag) guarantees that all objects with the
* specified tag are reclaimed before the function returns.
* - Due to the strict order, access to the set of tagged objects
* needs synchronization and care must be taken to avoid deadlock.
* - There are two types of reclamation operations to consider:
* - Type A: A Type A reclamation operation is triggered by meeting
* some threshold. Reclaimed objects may have different
* tags. Hazard pointers are checked and only unprotected objects
* are reclaimed. This type is expected to be expensive but
* infrequent and the cost is amortized over a large number of
* reclaimed objects. This type is needed to guarantee an upper
* bound on unreclaimed reclaimable objects.
* - Type B: A Type B reclamation operation is triggered by a call
* to the function cleanup_cohort_tag for a specific tag. All
* objects with the specified tag must be reclaimed
* unconditionally before returning from such a function
* call. Hazard pointers are not checked. This type of reclamation
* operation is expected to be inexpensive and may be invoked more
* frequently than Type A.
* - Tagged retired objects are kept in a single list in the domain
* structure, named tagged_.
* - Both Type A and Type B of reclamation pop all the objects in
* tagged_ and sort them into two sets of reclaimable and
* unreclaimable objects. The objects in the reclaimable set are
* reclaimed and the objects in the unreclaimable set are pushed
* back in tagged_.
* - The tagged_ list is locked between popping all objects and
* pushing back unreclaimable objects, in order to guarantee that
* Type B operations do not miss any objects that match the
* specified tag.
* - A Type A operation cannot release the lock on the tagged_ list
* before reclaiming reclaimable objects, to prevent concurrent
* Type B operations from returning before the reclamation of
* objects with matching tags.
* - A Type B operation can release the lock on tagged_ before
* reclaiming objects because the set of reclaimable objects by
* Type B operations are disjoint.
* - The lock on the tagged_ list is re-entrant, to prevent deadlock
* when reclamation in a Type A operation requires a Type B
* reclamation operation to complete.
* - The implementation allows only one pattern of re-entrance: An
* inner Type B inside an outer Type A.
* - An inner Type B operation must have access and ability to modify
* the outer Type A operation's set of reclaimable objects and
* their children objects in order not to miss objects that match
* the specified tag. Hence, Type A operations use data members,
* unprotected_ and children_, to keep track of these objects
* between reclamation steps and to provide inner Type B operations
* access to these objects.
*/
template <template <typename> class Atom>
class hazptr_domain {
using Obj = hazptr_obj<Atom>;
using ObjList = hazptr_obj_list<Atom>;
using RetiredList = hazptr_obj_retired_list<Atom>;
using Set = std::unordered_set<const void*>;
using ExecFn = folly::Executor* (*)();
static constexpr int kThreshold = detail::hazptr_domain_rcount_threshold();
static constexpr int kMultiplier = 2;
static constexpr uint64_t kSyncTimePeriod{2000000000}; // nanoseconds
static constexpr uintptr_t kTagBit = hazptr_obj<Atom>::kTagBit;
static folly::Executor* get_default_executor() {
return &folly::QueuedImmediateExecutor::instance();
}
Atom<hazptr_rec<Atom>*> hazptrs_{nullptr};
Atom<hazptr_obj<Atom>*> retired_{nullptr};
Atom<uint64_t> sync_time_{0};
/* Using signed int for rcount_ because it may transiently be negative.
Using signed int for all integer variables that may be involved in
calculations related to the value of rcount_. */
Atom<int> hcount_{0};
Atom<int> rcount_{0};
Atom<uint16_t> num_bulk_reclaims_{0};
bool shutdown_{false};
RetiredList untagged_;
RetiredList tagged_;
Obj* unprotected_; // List of unprotected objects being reclaimed
ObjList children_; // Children of unprotected objects being reclaimed
Atom<uint64_t> tagged_sync_time_{0};
Atom<uint64_t> untagged_sync_time_{0};
Atom<ExecFn> exec_fn_{nullptr};
Atom<int> exec_backlog_{0};
public:
/** Constructor */
hazptr_domain() = default;
/** Destructor */
~hazptr_domain() {
shutdown_ = true;
reclaim_all_objects();
free_hazptr_recs();
DCHECK(tagged_.empty());
}
hazptr_domain(const hazptr_domain&) = delete;
hazptr_domain(hazptr_domain&&) = delete;
hazptr_domain& operator=(const hazptr_domain&) = delete;
hazptr_domain& operator=(hazptr_domain&&) = delete;
void set_executor(ExecFn exfn) {
exec_fn_.store(exfn, std::memory_order_release);
}
void clear_executor() {
exec_fn_.store(nullptr, std::memory_order_release);
}
/** retire - nonintrusive - allocates memory */
template <typename T, typename D = std::default_delete<T>>
void retire(T* obj, D reclaim = {}) {
struct hazptr_retire_node : hazptr_obj<Atom> {
std::unique_ptr<T, D> obj_;
hazptr_retire_node(T* retireObj, D toReclaim)
: obj_{retireObj, std::move(toReclaim)} {}
};
auto node = new hazptr_retire_node(obj, std::move(reclaim));
node->reclaim_ = [](hazptr_obj<Atom>* p, hazptr_obj_list<Atom>&) {
delete static_cast<hazptr_retire_node*>(p);
};
hazptr_obj_list<Atom> l(node);
push_retired(l);
}
/** cleanup */
void cleanup() noexcept {
relaxed_cleanup();
wait_for_zero_bulk_reclaims(); // wait for concurrent bulk_reclaim-s
}
/** cleanup_cohort_tag */
void cleanup_cohort_tag(const hazptr_obj_cohort<Atom>* cohort) noexcept {
auto tag = reinterpret_cast<uintptr_t>(cohort) + kTagBit;
auto obj = tagged_.pop_all(RetiredList::kAlsoLock);
ObjList match, nomatch;
list_match_tag(tag, obj, match, nomatch);
if (unprotected_) { // There must be ongoing do_reclamation
ObjList match2, nomatch2;
list_match_tag(tag, unprotected_, match2, nomatch2);
match.splice(match2);
unprotected_ = nomatch2.head();
}
if (children_.head()) {
ObjList match2, nomatch2;
list_match_tag(tag, children_.head(), match2, nomatch2);
match.splice(match2);
children_ = std::move(nomatch2);
}
auto count = nomatch.count();
nomatch.set_count(0);
tagged_.push_unlock(nomatch);
obj = match.head();
reclaim_list_transitive(obj);
if (count >= threshold()) {
check_threshold_and_reclaim(
tagged_, RetiredList::kAlsoLock, tagged_sync_time_);
}
}
void
list_match_tag(uintptr_t tag, Obj* obj, ObjList& match, ObjList& nomatch) {
list_match_condition(
obj, match, nomatch, [tag](Obj* o) { return o->cohort_tag() == tag; });
}
private:
using hazptr_rec_alloc = AlignedSysAllocator<
hazptr_rec<Atom>,
FixedAlign<alignof(hazptr_rec<Atom>)>>;
friend void hazptr_domain_push_list<Atom>(
hazptr_obj_list<Atom>&,
hazptr_domain<Atom>&) noexcept;
friend void hazptr_domain_push_retired<Atom>(
hazptr_obj_list<Atom>&,
bool check,
hazptr_domain<Atom>&) noexcept;
friend class hazptr_holder<Atom>;
friend class hazptr_obj<Atom>;
friend class hazptr_obj_cohort<Atom>;
#if FOLLY_HAZPTR_THR_LOCAL
friend class hazptr_tc<Atom>;
#endif
/** hprec_acquire */
hazptr_rec<Atom>* hprec_acquire() {
auto rec = try_acquire_existing_hprec();
return rec != nullptr ? rec : acquire_new_hprec();
}
/** hprec_release */
void hprec_release(hazptr_rec<Atom>* hprec) noexcept {
hprec->release();
}
/** push_retired */
void push_retired(hazptr_obj_list<Atom>& l, bool check = true) {
/*** Full fence ***/ asymmetricLightBarrier();
while (true) {
auto r = retired();
l.tail()->set_next(r);
if (retired_.compare_exchange_weak(
r,
l.head(),
std::memory_order_release,
std::memory_order_acquire)) {
break;
}
}
rcount_.fetch_add(l.count(), std::memory_order_release);
if (check) {
check_cleanup_and_reclaim();
}
}
/** push_list */
void push_list(ObjList& l) {
if (l.empty()) {
return;
}
uintptr_t btag = l.head()->cohort_tag();
bool tagged = ((btag & kTagBit) == kTagBit);
RetiredList& rlist = tagged ? tagged_ : untagged_;
Atom<uint64_t>& sync_time =
tagged ? tagged_sync_time_ : untagged_sync_time_;
/*** Full fence ***/ asymmetricLightBarrier();
/* Only tagged lists need to be locked because tagging is used to
* guarantee the identification of all objects with a specific
* tag. Locking protects against concurrent hazptr_cleanup_tag()
* calls missing tagged objects. */
bool lock =
tagged ? RetiredList::kMayBeLocked : RetiredList::kMayNotBeLocked;
rlist.push(l, lock);
check_threshold_and_reclaim(rlist, lock, sync_time);
}
/** threshold */
int threshold() {
auto thresh = kThreshold;
return std::max(thresh, kMultiplier * hcount());
}
/** check_threshold_and_reclaim */
void check_threshold_and_reclaim(
RetiredList& rlist,
bool lock,
Atom<uint64_t>& sync_time) {
if (!(lock && rlist.check_lock()) &&
(rlist.check_threshold_try_zero_count(threshold()) ||
check_sync_time(sync_time))) {
if (std::is_same<Atom<int>, std::atomic<int>>{} &&
this == &default_hazptr_domain<Atom>() &&
FLAGS_folly_hazptr_use_executor) {
invoke_reclamation_in_executor(rlist, lock);
} else {
do_reclamation(rlist, lock);
}
}
}
/** check_sync_time_and_reclaim **/
void check_sync_time_and_reclaim() {
if (!tagged_.check_lock() && check_sync_time()) {
do_reclamation(tagged_, RetiredList::kAlsoLock);
do_reclamation(untagged_, RetiredList::kDontLock);
}
}
/** do_reclamation */
void do_reclamation(RetiredList& rlist, bool lock) {
auto obj = rlist.pop_all(lock == RetiredList::kAlsoLock);
if (!obj) {
if (lock) {
ObjList l;
rlist.push_unlock(l);
}
return;
}
/*** Full fence ***/ asymmetricHeavyBarrier(AMBFlags::EXPEDITED);
auto hprec = hazptrs_.load(std::memory_order_acquire);
/* Read hazard pointer values into private search structure */
Set hs;
for (; hprec; hprec = hprec->next()) {
hs.insert(hprec->hazptr());
}
/* Check objects against hazard pointer values */
ObjList match, nomatch;
list_match_condition(obj, match, nomatch, [&](Obj* o) {
return hs.count(o->raw_ptr()) > 0;
});
/* Reclaim unprotected objects and push back protected objects and
children of reclaimed objects */
if (lock) {
unprotected_ = nomatch.head();
DCHECK(children_.empty());
reclaim_unprotected_safe();
match.splice(children_);
rlist.push_unlock(match);
} else {
ObjList children;
reclaim_unprotected_unsafe(nomatch.head(), children);
match.splice(children);
rlist.push(match, false);
}
}
/** lookup_and_reclaim */
void lookup_and_reclaim(Obj* obj, const Set& hs, ObjList& keep) {
while (obj) {
auto next = obj->next();
DCHECK_NE(obj, next);
if (hs.count(obj->raw_ptr()) == 0) {
(*(obj->reclaim()))(obj, keep);
} else {
keep.push(obj);
}
obj = next;
}
}
/** list_match_condition */
template <typename Cond>
void list_match_condition(
Obj* obj,
ObjList& match,
ObjList& nomatch,
const Cond& cond) {
while (obj) {
auto next = obj->next();
DCHECK_NE(obj, next);
if (cond(obj)) {
match.push(obj);
} else {
nomatch.push(obj);
}
obj = next;
}
}
/** reclaim_unprotected_safe */
void reclaim_unprotected_safe() {
while (unprotected_) {
auto obj = unprotected_;
unprotected_ = obj->next();
(*(obj->reclaim()))(obj, children_);
}
}
/** reclaim_unprotected_unsafe */
void reclaim_unprotected_unsafe(Obj* obj, ObjList& children) {
while (obj) {
auto next = obj->next();
(*(obj->reclaim()))(obj, children);
obj = next;
}
}
/** reclaim_unconditional */
void reclaim_unconditional(Obj* head, ObjList& children) {
while (head) {
auto next = head->next();
(*(head->reclaim()))(head, children);
head = next;
}
}
hazptr_rec<Atom>* head() const noexcept {
return hazptrs_.load(std::memory_order_acquire);
}
hazptr_obj<Atom>* retired() const noexcept {
return retired_.load(std::memory_order_acquire);
}
int hcount() const noexcept {
return hcount_.load(std::memory_order_acquire);
}
int rcount() const noexcept {
return rcount_.load(std::memory_order_acquire);
}
bool reached_threshold(int rc, int hc) const noexcept {
return rc >= kThreshold && rc >= kMultiplier * hc;
}
void reclaim_all_objects() {
auto head = retired_.exchange(nullptr);
reclaim_list_transitive(head);
head = untagged_.pop_all(RetiredList::kDontLock);
reclaim_list_transitive(head);
}
void reclaim_list_transitive(Obj* head) {
while (head) {
ObjList children;
reclaim_unconditional(head, children);
head = children.head();
}
}
void free_hazptr_recs() {
/* Leak the hazard pointers for the default domain to avoid
destruction order issues with thread caches. */
if (this == &default_hazptr_domain<Atom>()) {
return;
}
auto rec = head();
while (rec) {
auto next = rec->next();
DCHECK(!rec->active());
rec->~hazptr_rec<Atom>();
hazptr_rec_alloc{}.deallocate(rec, 1);
rec = next;
}
}
void check_cleanup_and_reclaim() {
if (try_timed_cleanup()) {
return;
}
if (reached_threshold(rcount(), hcount())) {
try_bulk_reclaim();
}
}
void relaxed_cleanup() noexcept {
#if FOLLY_HAZPTR_THR_LOCAL
hazptr_obj<Atom>* h = nullptr;
hazptr_obj<Atom>* t = nullptr;
for (hazptr_priv<Atom>& priv :
hazptr_priv_singleton<Atom>::accessAllThreads()) {
priv.collect(h, t);
}
if (h) {
DCHECK(t);
hazptr_obj_list<Atom> l(h, t, 0);
push_retired(l);
}
#endif
rcount_.store(0, std::memory_order_release);
bulk_reclaim(true);
}
void wait_for_zero_bulk_reclaims() {
while (num_bulk_reclaims_.load(std::memory_order_acquire) > 0) {
std::this_thread::yield();
}
}
void try_bulk_reclaim() {
auto hc = hcount();
auto rc = rcount();
if (!reached_threshold(rc, hc)) {
return;
}
rc = rcount_.exchange(0, std::memory_order_release);
if (!reached_threshold(rc, hc)) {
/* No need to add rc back to rcount_. At least one concurrent
try_bulk_reclaim will proceed to bulk_reclaim. */
return;
}
bulk_reclaim();
}
void bulk_reclaim(bool transitive = false) {
num_bulk_reclaims_.fetch_add(1, std::memory_order_acquire);
while (true) {
auto obj = retired_.exchange(nullptr, std::memory_order_acquire);
/*** Full fence ***/ asymmetricHeavyBarrier(AMBFlags::EXPEDITED);
auto rec = hazptrs_.load(std::memory_order_acquire);
/* Part 1 - read hazard pointer values into private search structure */
std::unordered_set<const void*> hashset; // TOTO: lock-free fixed hash set
for (; rec; rec = rec->next()) {
hashset.insert(rec->hazptr());
}
/* Part 2 - for each retired object, reclaim if no match */
if (bulk_lookup_and_reclaim(obj, hashset) || !transitive) {
break;
}
}
num_bulk_reclaims_.fetch_sub(1, std::memory_order_release);
}
bool bulk_lookup_and_reclaim(
hazptr_obj<Atom>* obj,
const std::unordered_set<const void*>& hashset) {
hazptr_obj_list<Atom> children;
hazptr_obj_list<Atom> matched;
while (obj) {
auto next = obj->next();
DCHECK_NE(obj, next);
if (hashset.count(obj->raw_ptr()) == 0) {
(*(obj->reclaim()))(obj, children);
} else {
matched.push(obj);
}
obj = next;
}
#if FOLLY_HAZPTR_THR_LOCAL
if (!shutdown_) {
hazptr_priv_tls<Atom>().push_all_to_domain(false);
}
#endif
bool done = ((children.count() == 0) && (retired() == nullptr));
matched.splice(children);
if (matched.count() > 0) {
push_retired(matched, false /* don't call bulk_reclaim recursively */);
}
return done;
}
bool check_sync_time(Atom<uint64_t>& sync_time) {
uint64_t time = std::chrono::duration_cast<std::chrono::nanoseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
auto prevtime = sync_time.load(std::memory_order_relaxed);
if (time < prevtime ||
!sync_time.compare_exchange_strong(
prevtime, time + kSyncTimePeriod, std::memory_order_relaxed)) {
return false;
}
return true;
}
bool try_timed_cleanup() {
if (!check_sync_time(sync_time_)) {
return false;
}
relaxed_cleanup(); // calling regular cleanup may self deadlock
return true;
}
hazptr_rec<Atom>* try_acquire_existing_hprec() {
auto rec = head();
while (rec) {
auto next = rec->next();
if (rec->try_acquire()) {
return rec;
}
rec = next;
}
return nullptr;
}
hazptr_rec<Atom>* acquire_new_hprec() {
auto rec = hazptr_rec_alloc{}.allocate(1);
new (rec) hazptr_rec<Atom>();
rec->set_active();
rec->set_domain(this);
while (true) {
auto h = head();
rec->set_next(h);
if (hazptrs_.compare_exchange_weak(
h, rec, std::memory_order_release, std::memory_order_acquire)) {
break;
}
}
hcount_.fetch_add(1);
return rec;
}
void invoke_reclamation_in_executor(RetiredList& rlist, bool lock) {
auto fn = exec_fn_.load(std::memory_order_acquire);
auto ex = fn ? fn() : get_default_executor();
auto backlog = exec_backlog_.fetch_add(1, std::memory_order_relaxed);
if (ex) {
ex->add([this, &rlist, lock] {
exec_backlog_.store(0, std::memory_order_relaxed);
do_reclamation(rlist, lock);
});
} else {
LOG(INFO) << "Skip asynchronous reclamation by hazptr executor";
}
if (backlog >= 10) {
LOG(WARNING) << backlog
<< " request backlog for hazptr reclamation executora";
}
}
}; // hazptr_domain
/**
* Free functions related to hazptr domains
*/
/** default_hazptr_domain: Returns reference to the default domain */
template <template <typename> class Atom>
struct hazptr_default_domain_helper {
static FOLLY_ALWAYS_INLINE hazptr_domain<Atom>& get() {
static hazptr_domain<Atom> domain;
return domain;
}
};
template <>
struct hazptr_default_domain_helper<std::atomic> {
static FOLLY_ALWAYS_INLINE hazptr_domain<std::atomic>& get() {
return default_domain;
}
};
template <template <typename> class Atom>
FOLLY_ALWAYS_INLINE hazptr_domain<Atom>& default_hazptr_domain() {
return hazptr_default_domain_helper<Atom>::get();
}
/** hazptr_domain_push_retired: push a list of retired objects into a domain */
template <template <typename> class Atom>
void hazptr_domain_push_retired(
hazptr_obj_list<Atom>& l,
bool check,
hazptr_domain<Atom>& domain) noexcept {
domain.push_retired(l, check);
}
/** hazptr_domain_push_list */
template <template <typename> class Atom>
void hazptr_domain_push_list(
hazptr_obj_list<Atom>& l,
hazptr_domain<Atom>& domain) noexcept {
domain.push_list(l);
}
/** hazptr_retire */
template <template <typename> class Atom, typename T, typename D>
FOLLY_ALWAYS_INLINE void hazptr_retire(T* obj, D reclaim) {
default_hazptr_domain<Atom>().retire(obj, std::move(reclaim));
}
/** hazptr_cleanup: Reclaims all reclaimable objects retired to the domain */
template <template <typename> class Atom>
void hazptr_cleanup(hazptr_domain<Atom>& domain) noexcept {
domain.cleanup();
}
} // namespace folly