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// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab ft=cpp
#include "rgw_gc.h"
#include "rgw_tools.h"
#include "include/scope_guard.h"
#include "include/rados/librados.hpp"
#include "cls/rgw/cls_rgw_client.h"
#include "cls/rgw_gc/cls_rgw_gc_client.h"
#include "cls/refcount/cls_refcount_client.h"
#include "cls/version/cls_version_client.h"
#include "rgw_perf_counters.h"
#include "cls/lock/cls_lock_client.h"
#include "include/random.h"
#include "rgw_gc_log.h"
#include <list> // XXX
#include <sstream>
#include "xxhash.h"
#define dout_context g_ceph_context
#define dout_subsys ceph_subsys_rgw
using namespace std;
using namespace librados;
static string gc_oid_prefix = "gc";
static string gc_index_lock_name = "gc_process";
void RGWGC::initialize(CephContext *_cct, RGWRados *_store) {
cct = _cct;
store = _store;
max_objs = min(static_cast<int>(cct->_conf->rgw_gc_max_objs), rgw_shards_max());
obj_names = new string[max_objs];
for (int i = 0; i < max_objs; i++) {
obj_names[i] = gc_oid_prefix;
char buf[32];
snprintf(buf, 32, ".%d", i);
obj_names[i].append(buf);
auto it = transitioned_objects_cache.begin() + i;
transitioned_objects_cache.insert(it, false);
//version = 0 -> not ready for transition
//version = 1 -> marked ready for transition
librados::ObjectWriteOperation op;
op.create(false);
const uint64_t queue_size = cct->_conf->rgw_gc_max_queue_size, num_deferred_entries = cct->_conf->rgw_gc_max_deferred;
gc_log_init2(op, queue_size, num_deferred_entries);
store->gc_operate(this, obj_names[i], &op);
}
}
void RGWGC::finalize()
{
delete[] obj_names;
}
int RGWGC::tag_index(const string& tag)
{
return rgw_shards_mod(XXH64(tag.c_str(), tag.size(), seed), max_objs);
}
std::tuple<int, std::optional<cls_rgw_obj_chain>> RGWGC::send_split_chain(const cls_rgw_obj_chain& chain, const std::string& tag)
{
ldpp_dout(this, 20) << "RGWGC::send_split_chain - tag is: " << tag << dendl;
if (cct->_conf->rgw_max_chunk_size) {
cls_rgw_obj_chain broken_chain;
ldpp_dout(this, 20) << "RGWGC::send_split_chain - rgw_max_chunk_size is: " << cct->_conf->rgw_max_chunk_size << dendl;
for (auto it = chain.objs.begin(); it != chain.objs.end(); it++) {
ldpp_dout(this, 20) << "RGWGC::send_split_chain - adding obj with name: " << it->key << dendl;
broken_chain.objs.emplace_back(*it);
cls_rgw_gc_obj_info info;
info.tag = tag;
info.chain = broken_chain;
cls_rgw_gc_set_entry_op op;
op.info = info;
size_t total_encoded_size = op.estimate_encoded_size();
ldpp_dout(this, 20) << "RGWGC::send_split_chain - total_encoded_size is: " << total_encoded_size << dendl;
if (total_encoded_size > cct->_conf->rgw_max_chunk_size) { //dont add to chain, and send to gc
broken_chain.objs.pop_back();
--it;
ldpp_dout(this, 20) << "RGWGC::send_split_chain - more than, dont add to broken chain and send chain" << dendl;
auto ret = send_chain(broken_chain, tag);
if (ret < 0) {
broken_chain.objs.insert(broken_chain.objs.end(), it, chain.objs.end()); // add all the remainder objs to the list to be deleted inline
ldpp_dout(this, 0) << "RGWGC::send_split_chain - send chain returned error: " << ret << dendl;
return {ret, {broken_chain}};
}
broken_chain.objs.clear();
}
}
if (!broken_chain.objs.empty()) { //when the chain is smaller than or equal to rgw_max_chunk_size
ldpp_dout(this, 20) << "RGWGC::send_split_chain - sending leftover objects" << dendl;
auto ret = send_chain(broken_chain, tag);
if (ret < 0) {
ldpp_dout(this, 0) << "RGWGC::send_split_chain - send chain returned error: " << ret << dendl;
return {ret, {broken_chain}};
}
}
} else {
auto ret = send_chain(chain, tag);
if (ret < 0) {
ldpp_dout(this, 0) << "RGWGC::send_split_chain - send chain returned error: " << ret << dendl;
return {ret, {std::move(chain)}};
}
}
return {0, {}};
}
int RGWGC::send_chain(const cls_rgw_obj_chain& chain, const string& tag)
{
ObjectWriteOperation op;
cls_rgw_gc_obj_info info;
info.chain = chain;
info.tag = tag;
gc_log_enqueue2(op, cct->_conf->rgw_gc_obj_min_wait, info);
int i = tag_index(tag);
ldpp_dout(this, 20) << "RGWGC::send_chain - on object name: " << obj_names[i] << "tag is: " << tag << dendl;
auto ret = store->gc_operate(this, obj_names[i], &op);
if (ret != -ECANCELED && ret != -EPERM) {
return ret;
}
ObjectWriteOperation set_entry_op;
cls_rgw_gc_set_entry(set_entry_op, cct->_conf->rgw_gc_obj_min_wait, info);
return store->gc_operate(this, obj_names[i], &set_entry_op);
}
struct defer_chain_state {
librados::AioCompletion* completion = nullptr;
// TODO: hold a reference on the state in RGWGC to avoid use-after-free if
// RGWGC destructs before this completion fires
RGWGC* gc = nullptr;
cls_rgw_gc_obj_info info;
~defer_chain_state() {
if (completion) {
completion->release();
}
}
};
static void async_defer_callback(librados::completion_t, void* arg)
{
std::unique_ptr<defer_chain_state> state{static_cast<defer_chain_state*>(arg)};
if (state->completion->get_return_value() == -ECANCELED) {
state->gc->on_defer_canceled(state->info);
}
}
void RGWGC::on_defer_canceled(const cls_rgw_gc_obj_info& info)
{
const std::string& tag = info.tag;
const int i = tag_index(tag);
// ECANCELED from cls_version_check() tells us that we've transitioned
transitioned_objects_cache[i] = true;
ObjectWriteOperation op;
cls_rgw_gc_queue_defer_entry(op, cct->_conf->rgw_gc_obj_min_wait, info);
cls_rgw_gc_remove(op, {tag});
auto c = librados::Rados::aio_create_completion(nullptr, nullptr);
store->gc_aio_operate(obj_names[i], c, &op);
c->release();
}
int RGWGC::async_defer_chain(const string& tag, const cls_rgw_obj_chain& chain)
{
const int i = tag_index(tag);
cls_rgw_gc_obj_info info;
info.chain = chain;
info.tag = tag;
// if we've transitioned this shard object, we can rely on the cls_rgw_gc queue
if (transitioned_objects_cache[i]) {
ObjectWriteOperation op;
cls_rgw_gc_queue_defer_entry(op, cct->_conf->rgw_gc_obj_min_wait, info);
// this tag may still be present in omap, so remove it once the cls_rgw_gc
// enqueue succeeds
cls_rgw_gc_remove(op, {tag});
auto c = librados::Rados::aio_create_completion(nullptr, nullptr);
int ret = store->gc_aio_operate(obj_names[i], c, &op);
c->release();
return ret;
}
// if we haven't seen the transition yet, write the defer to omap with cls_rgw
ObjectWriteOperation op;
// assert that we haven't initialized cls_rgw_gc queue. this prevents us
// from writing new entries to omap after the transition
gc_log_defer1(op, cct->_conf->rgw_gc_obj_min_wait, info);
// prepare a callback to detect the transition via ECANCELED from cls_version_check()
auto state = std::make_unique<defer_chain_state>();
state->gc = this;
state->info.chain = chain;
state->info.tag = tag;
state->completion = librados::Rados::aio_create_completion(
state.get(), async_defer_callback);
int ret = store->gc_aio_operate(obj_names[i], state->completion, &op);
if (ret == 0) {
state.release(); // release ownership until async_defer_callback()
}
return ret;
}
int RGWGC::remove(int index, const std::vector<string>& tags, AioCompletion **pc)
{
ObjectWriteOperation op;
cls_rgw_gc_remove(op, tags);
auto c = librados::Rados::aio_create_completion(nullptr, nullptr);
int ret = store->gc_aio_operate(obj_names[index], c, &op);
if (ret < 0) {
c->release();
} else {
*pc = c;
}
return ret;
}
int RGWGC::remove(int index, int num_entries)
{
ObjectWriteOperation op;
cls_rgw_gc_queue_remove_entries(op, num_entries);
return store->gc_operate(this, obj_names[index], &op);
}
int RGWGC::list(int *index, string& marker, uint32_t max, bool expired_only, std::list<cls_rgw_gc_obj_info>& result, bool *truncated, bool& processing_queue)
{
result.clear();
string next_marker;
bool check_queue = false;
for (; *index < max_objs && result.size() < max; (*index)++, marker.clear(), check_queue = false) {
std::list<cls_rgw_gc_obj_info> entries, queue_entries;
int ret = 0;
//processing_queue is set to true from previous iteration if the queue was under process and probably has more elements in it.
if (! transitioned_objects_cache[*index] && ! check_queue && ! processing_queue) {
ret = cls_rgw_gc_list(store->gc_pool_ctx, obj_names[*index], marker, max - result.size(), expired_only, entries, truncated, next_marker);
if (ret != -ENOENT && ret < 0) {
return ret;
}
obj_version objv;
cls_version_read(store->gc_pool_ctx, obj_names[*index], &objv);
if (ret == -ENOENT || entries.size() == 0) {
if (objv.ver == 0) {
continue;
} else {
if (! expired_only) {
transitioned_objects_cache[*index] = true;
marker.clear();
} else {
std::list<cls_rgw_gc_obj_info> non_expired_entries;
ret = cls_rgw_gc_list(store->gc_pool_ctx, obj_names[*index], marker, 1, false, non_expired_entries, truncated, next_marker);
if (non_expired_entries.size() == 0) {
transitioned_objects_cache[*index] = true;
marker.clear();
}
}
}
}
if ((objv.ver == 1) && (entries.size() < max - result.size())) {
check_queue = true;
marker.clear();
}
}
if (transitioned_objects_cache[*index] || check_queue || processing_queue) {
processing_queue = false;
ret = cls_rgw_gc_queue_list_entries(store->gc_pool_ctx, obj_names[*index], marker, (max - result.size()) - entries.size(), expired_only, queue_entries, truncated, next_marker);
if (ret < 0) {
return ret;
}
}
if (entries.size() == 0 && queue_entries.size() == 0)
continue;
std::list<cls_rgw_gc_obj_info>::iterator iter;
for (iter = entries.begin(); iter != entries.end(); ++iter) {
result.push_back(*iter);
}
for (iter = queue_entries.begin(); iter != queue_entries.end(); ++iter) {
result.push_back(*iter);
}
marker = next_marker;
if (*index == max_objs - 1) {
if (queue_entries.size() > 0 && *truncated) {
processing_queue = true;
} else {
processing_queue = false;
}
/* we cut short here, truncated will hold the correct value */
return 0;
}
if (result.size() == max) {
if (queue_entries.size() > 0 && *truncated) {
processing_queue = true;
} else {
processing_queue = false;
*index += 1; //move to next gc object
}
/* close approximation, it might be that the next of the objects don't hold
* anything, in this case truncated should have been false, but we can find
* that out on the next iteration
*/
*truncated = true;
return 0;
}
}
*truncated = false;
processing_queue = false;
return 0;
}
class RGWGCIOManager {
const DoutPrefixProvider* dpp;
CephContext *cct;
RGWGC *gc;
struct IO {
enum Type {
UnknownIO = 0,
TailIO = 1,
IndexIO = 2,
} type{UnknownIO};
librados::AioCompletion *c{nullptr};
string oid;
int index{-1};
string tag;
};
deque<IO> ios;
vector<std::vector<string> > remove_tags;
/* tracks the number of remaining shadow objects for a given tag in order to
* only remove the tag once all shadow objects have themselves been removed
*/
vector<map<string, size_t> > tag_io_size;
#define MAX_AIO_DEFAULT 10
size_t max_aio{MAX_AIO_DEFAULT};
public:
RGWGCIOManager(const DoutPrefixProvider* _dpp, CephContext *_cct, RGWGC *_gc) : dpp(_dpp),
cct(_cct),
gc(_gc) {
max_aio = cct->_conf->rgw_gc_max_concurrent_io;
remove_tags.resize(min(static_cast<int>(cct->_conf->rgw_gc_max_objs), rgw_shards_max()));
tag_io_size.resize(min(static_cast<int>(cct->_conf->rgw_gc_max_objs), rgw_shards_max()));
}
~RGWGCIOManager() {
for (auto io : ios) {
io.c->release();
}
}
int schedule_io(IoCtx *ioctx, const string& oid, ObjectWriteOperation *op,
int index, const string& tag) {
while (ios.size() > max_aio) {
if (gc->going_down()) {
return 0;
}
auto ret = handle_next_completion();
//Return error if we are using queue, else ignore it
if (gc->transitioned_objects_cache[index] && ret < 0) {
return ret;
}
}
auto c = librados::Rados::aio_create_completion(nullptr, nullptr);
int ret = ioctx->aio_operate(oid, c, op);
if (ret < 0) {
return ret;
}
ios.push_back(IO{IO::TailIO, c, oid, index, tag});
return 0;
}
int handle_next_completion() {
ceph_assert(!ios.empty());
IO& io = ios.front();
io.c->wait_for_complete();
int ret = io.c->get_return_value();
io.c->release();
if (ret == -ENOENT) {
ret = 0;
}
if (io.type == IO::IndexIO && ! gc->transitioned_objects_cache[io.index]) {
if (ret < 0) {
ldpp_dout(dpp, 0) << "WARNING: gc cleanup of tags on gc shard index=" <<
io.index << " returned error, ret=" << ret << dendl;
}
goto done;
}
if (ret < 0) {
ldpp_dout(dpp, 0) << "WARNING: gc could not remove oid=" << io.oid <<
", ret=" << ret << dendl;
goto done;
}
if (! gc->transitioned_objects_cache[io.index]) {
schedule_tag_removal(io.index, io.tag);
}
done:
ios.pop_front();
return ret;
}
/* This is a request to schedule a tag removal. It will be called once when
* there are no shadow objects. But it will also be called for every shadow
* object when there are any. Since we do not want the tag to be removed
* until all shadow objects have been successfully removed, the scheduling
* will not happen until the shadow object count goes down to zero
*/
void schedule_tag_removal(int index, string tag) {
auto& ts = tag_io_size[index];
auto ts_it = ts.find(tag);
if (ts_it != ts.end()) {
auto& size = ts_it->second;
--size;
// wait all shadow obj delete return
if (size != 0)
return;
ts.erase(ts_it);
}
auto& rt = remove_tags[index];
rt.push_back(tag);
if (rt.size() >= (size_t)cct->_conf->rgw_gc_max_trim_chunk) {
flush_remove_tags(index, rt);
}
}
void add_tag_io_size(int index, string tag, size_t size) {
auto& ts = tag_io_size[index];
ts.emplace(tag, size);
}
int drain_ios() {
int ret_val = 0;
while (!ios.empty()) {
if (gc->going_down()) {
return -EAGAIN;
}
auto ret = handle_next_completion();
if (ret < 0) {
ret_val = ret;
}
}
return ret_val;
}
void drain() {
drain_ios();
flush_remove_tags();
/* the tags draining might have generated more ios, drain those too */
drain_ios();
}
void flush_remove_tags(int index, vector<string>& rt) {
IO index_io;
index_io.type = IO::IndexIO;
index_io.index = index;
ldpp_dout(dpp, 20) << __func__ <<
" removing entries from gc log shard index=" << index << ", size=" <<
rt.size() << ", entries=" << rt << dendl;
auto rt_guard = make_scope_guard(
[&]
{
rt.clear();
}
);
int ret = gc->remove(index, rt, &index_io.c);
if (ret < 0) {
/* we already cleared list of tags, this prevents us from
* ballooning in case of a persistent problem
*/
ldpp_dout(dpp, 0) << "WARNING: failed to remove tags on gc shard index=" <<
index << " ret=" << ret << dendl;
return;
}
if (perfcounter) {
/* log the count of tags retired for rate estimation */
perfcounter->inc(l_rgw_gc_retire, rt.size());
}
ios.push_back(index_io);
}
void flush_remove_tags() {
int index = 0;
for (auto& rt : remove_tags) {
if (! gc->transitioned_objects_cache[index]) {
flush_remove_tags(index, rt);
}
++index;
}
}
int remove_queue_entries(int index, int num_entries) {
int ret = gc->remove(index, num_entries);
if (ret < 0) {
ldpp_dout(dpp, 0) << "ERROR: failed to remove queue entries on index=" <<
index << " ret=" << ret << dendl;
return ret;
}
if (perfcounter) {
/* log the count of tags retired for rate estimation */
perfcounter->inc(l_rgw_gc_retire, num_entries);
}
return 0;
}
}; // class RGWGCIOManger
int RGWGC::process(int index, int max_secs, bool expired_only,
RGWGCIOManager& io_manager)
{
ldpp_dout(this, 20) << "RGWGC::process entered with GC index_shard=" <<
index << ", max_secs=" << max_secs << ", expired_only=" <<
expired_only << dendl;
rados::cls::lock::Lock l(gc_index_lock_name);
utime_t end = ceph_clock_now();
/* max_secs should be greater than zero. We don't want a zero max_secs
* to be translated as no timeout, since we'd then need to break the
* lock and that would require a manual intervention. In this case
* we can just wait it out. */
if (max_secs <= 0)
return -EAGAIN;
end += max_secs;
utime_t time(max_secs, 0);
l.set_duration(time);
int ret = l.lock_exclusive(&store->gc_pool_ctx, obj_names[index]);
if (ret == -EBUSY) { /* already locked by another gc processor */
ldpp_dout(this, 10) << "RGWGC::process failed to acquire lock on " <<
obj_names[index] << dendl;
return 0;
}
if (ret < 0)
return ret;
string marker;
string next_marker;
bool truncated;
IoCtx *ctx = new IoCtx;
do {
int max = 100;
std::list<cls_rgw_gc_obj_info> entries;
int ret = 0;
if (! transitioned_objects_cache[index]) {
ret = cls_rgw_gc_list(store->gc_pool_ctx, obj_names[index], marker, max, expired_only, entries, &truncated, next_marker);
ldpp_dout(this, 20) <<
"RGWGC::process cls_rgw_gc_list returned with returned:" << ret <<
", entries.size=" << entries.size() << ", truncated=" << truncated <<
", next_marker='" << next_marker << "'" << dendl;
obj_version objv;
cls_version_read(store->gc_pool_ctx, obj_names[index], &objv);
if ((objv.ver == 1) && entries.size() == 0) {
std::list<cls_rgw_gc_obj_info> non_expired_entries;
ret = cls_rgw_gc_list(store->gc_pool_ctx, obj_names[index], marker, 1, false, non_expired_entries, &truncated, next_marker);
if (non_expired_entries.size() == 0) {
transitioned_objects_cache[index] = true;
marker.clear();
ldpp_dout(this, 20) << "RGWGC::process cls_rgw_gc_list returned NO non expired entries, so setting cache entry to TRUE" << dendl;
} else {
ret = 0;
goto done;
}
}
if ((objv.ver == 0) && (ret == -ENOENT || entries.size() == 0)) {
ret = 0;
goto done;
}
}
if (transitioned_objects_cache[index]) {
ret = cls_rgw_gc_queue_list_entries(store->gc_pool_ctx, obj_names[index], marker, max, expired_only, entries, &truncated, next_marker);
ldpp_dout(this, 20) <<
"RGWGC::process cls_rgw_gc_queue_list_entries returned with return value:" << ret <<
", entries.size=" << entries.size() << ", truncated=" << truncated <<
", next_marker='" << next_marker << "'" << dendl;
if (entries.size() == 0) {
ret = 0;
goto done;
}
}
if (ret < 0)
goto done;
marker = next_marker;
string last_pool;
std::list<cls_rgw_gc_obj_info>::iterator iter;
for (iter = entries.begin(); iter != entries.end(); ++iter) {
cls_rgw_gc_obj_info& info = *iter;
ldpp_dout(this, 20) << "RGWGC::process iterating over entry tag='" <<
info.tag << "', time=" << info.time << ", chain.objs.size()=" <<
info.chain.objs.size() << dendl;
std::list<cls_rgw_obj>::iterator liter;
cls_rgw_obj_chain& chain = info.chain;
utime_t now = ceph_clock_now();
if (now >= end) {
goto done;
}
if (! transitioned_objects_cache[index]) {
if (chain.objs.empty()) {
io_manager.schedule_tag_removal(index, info.tag);
} else {
io_manager.add_tag_io_size(index, info.tag, chain.objs.size());
}
}
if (! chain.objs.empty()) {
for (liter = chain.objs.begin(); liter != chain.objs.end(); ++liter) {
cls_rgw_obj& obj = *liter;
if (obj.pool != last_pool) {
delete ctx;
ctx = new IoCtx;
ret = rgw_init_ioctx(this, store->get_rados_handle(), obj.pool, *ctx);
if (ret < 0) {
if (transitioned_objects_cache[index]) {
goto done;
}
last_pool = "";
ldpp_dout(this, 0) << "ERROR: failed to create ioctx pool=" <<
obj.pool << dendl;
continue;
}
last_pool = obj.pool;
}
ctx->locator_set_key(obj.loc);
const string& oid = obj.key.name; /* just stored raw oid there */
ldpp_dout(this, 5) << "RGWGC::process removing " << obj.pool <<
":" << obj.key.name << dendl;
ObjectWriteOperation op;
cls_refcount_put(op, info.tag, true);
ret = io_manager.schedule_io(ctx, oid, &op, index, info.tag);
if (ret < 0) {
ldpp_dout(this, 0) <<
"WARNING: failed to schedule deletion for oid=" << oid << dendl;
if (transitioned_objects_cache[index]) {
//If deleting oid failed for any of them, we will not delete queue entries
goto done;
}
}
if (going_down()) {
// leave early, even if tag isn't removed, it's ok since it
// will be picked up next time around
goto done;
}
} // chains loop
} // else -- chains not empty
} // entries loop
if (transitioned_objects_cache[index] && entries.size() > 0) {
ret = io_manager.drain_ios();
if (ret < 0) {
goto done;
}
//Remove the entries from the queue
ldpp_dout(this, 5) << "RGWGC::process removing entries, marker: " << marker << dendl;
ret = io_manager.remove_queue_entries(index, entries.size());
if (ret < 0) {
ldpp_dout(this, 0) <<
"WARNING: failed to remove queue entries" << dendl;
goto done;
}
}
} while (truncated);
done:
/* we don't drain here, because if we're going down we don't want to
* hold the system if backend is unresponsive
*/
l.unlock(&store->gc_pool_ctx, obj_names[index]);
delete ctx;
return 0;
}
int RGWGC::process(bool expired_only)
{
int max_secs = cct->_conf->rgw_gc_processor_max_time;
const int start = ceph::util::generate_random_number(0, max_objs - 1);
RGWGCIOManager io_manager(this, store->ctx(), this);
for (int i = 0; i < max_objs; i++) {
int index = (i + start) % max_objs;
int ret = process(index, max_secs, expired_only, io_manager);
if (ret < 0)
return ret;
}
if (!going_down()) {
io_manager.drain();
}
return 0;
}
bool RGWGC::going_down()
{
return down_flag;
}
void RGWGC::start_processor()
{
worker = new GCWorker(this, cct, this);
worker->create("rgw_gc");
}
void RGWGC::stop_processor()
{
down_flag = true;
if (worker) {
worker->stop();
worker->join();
}
delete worker;
worker = NULL;
}
unsigned RGWGC::get_subsys() const
{
return dout_subsys;
}
std::ostream& RGWGC::gen_prefix(std::ostream& out) const
{
return out << "garbage collection: ";
}
void *RGWGC::GCWorker::entry() {
do {
utime_t start = ceph_clock_now();
ldpp_dout(dpp, 2) << "garbage collection: start" << dendl;
int r = gc->process(true);
if (r < 0) {
ldpp_dout(dpp, 0) << "ERROR: garbage collection process() returned error r=" << r << dendl;
}
ldpp_dout(dpp, 2) << "garbage collection: stop" << dendl;
if (gc->going_down())
break;
utime_t end = ceph_clock_now();
end -= start;
int secs = cct->_conf->rgw_gc_processor_period;
if (secs <= end.sec())
continue; // next round
secs -= end.sec();
std::unique_lock locker{lock};
cond.wait_for(locker, std::chrono::seconds(secs));
} while (!gc->going_down());
return NULL;
}
void RGWGC::GCWorker::stop()
{
std::lock_guard l{lock};
cond.notify_all();
}
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