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txn_proto2_impl.cc
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txn_proto2_impl.cc
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#include <iostream>
#include <thread>
#include <fcntl.h>
#include <unistd.h>
#include <sys/uio.h>
#include <limits.h>
#include <numa.h>
#include "txn_proto2_impl.h"
#include "counter.h"
#include "util.h"
using namespace std;
using namespace util;
/** logger subsystem **/
/*{{{*/
bool txn_logger::g_persist = false;
bool txn_logger::g_call_fsync = true;
bool txn_logger::g_use_compression = false;
bool txn_logger::g_fake_writes = false;
size_t txn_logger::g_nworkers = 0;
txn_logger::epoch_array
txn_logger::per_thread_sync_epochs_[txn_logger::g_nmax_loggers];
aligned_padded_elem<atomic<uint64_t>>
txn_logger::system_sync_epoch_(0);
percore<txn_logger::persist_ctx>
txn_logger::g_persist_ctxs;
percore<txn_logger::persist_stats>
txn_logger::g_persist_stats;
event_counter
txn_logger::g_evt_log_buffer_epoch_boundary("log_buffer_epoch_boundary");
event_counter
txn_logger::g_evt_log_buffer_out_of_space("log_buffer_out_of_space");
event_counter
txn_logger::g_evt_log_buffer_bytes_before_compress("log_buffer_bytes_before_compress");
event_counter
txn_logger::g_evt_log_buffer_bytes_after_compress("log_buffer_bytes_after_compress");
event_counter
txn_logger::g_evt_logger_writev_limit_met("logger_writev_limit_met");
event_counter
txn_logger::g_evt_logger_max_lag_wait("logger_max_lag_wait");
event_avg_counter
txn_logger::g_evt_avg_log_buffer_compress_time_us("avg_log_buffer_compress_time_us");
event_avg_counter
txn_logger::g_evt_avg_log_entry_ntxns("avg_log_entry_ntxns_per_entry");
event_avg_counter
txn_logger::g_evt_avg_logger_bytes_per_writev("avg_logger_bytes_per_writev");
event_avg_counter
txn_logger::g_evt_avg_logger_bytes_per_sec("avg_logger_bytes_per_sec");
static event_avg_counter
evt_avg_log_buffer_iov_len("avg_log_buffer_iov_len");
void
txn_logger::Init(
size_t nworkers,
const vector<string> &logfiles,
const vector<vector<unsigned>> &assignments_given,
vector<vector<unsigned>> *assignments_used,
bool call_fsync,
bool use_compression,
bool fake_writes)
{
INVARIANT(!g_persist);
INVARIANT(g_nworkers == 0);
INVARIANT(nworkers > 0);
INVARIANT(!logfiles.empty());
INVARIANT(logfiles.size() <= g_nmax_loggers);
INVARIANT(!use_compression || g_perthread_buffers > 1); // need 1 as scratch buf
vector<int> fds;
for (auto &fname : logfiles) {
int fd = open(fname.c_str(), O_CREAT|O_WRONLY|O_TRUNC, 0664);
if (fd == -1) {
perror("open");
ALWAYS_ASSERT(false);
}
fds.push_back(fd);
}
g_persist = true;
g_call_fsync = call_fsync;
g_use_compression = use_compression;
g_fake_writes = fake_writes;
g_nworkers = nworkers;
for (size_t i = 0; i < g_nmax_loggers; i++)
for (size_t j = 0; j < g_nworkers; j++)
per_thread_sync_epochs_[i].epochs_[j].store(0, memory_order_release);
vector<thread> writers;
vector<vector<unsigned>> assignments(assignments_given);
if (assignments.empty()) {
// compute assuming homogenous disks
if (g_nworkers <= fds.size()) {
// each thread gets its own logging worker
for (size_t i = 0; i < g_nworkers; i++)
assignments.push_back({(unsigned) i});
} else {
// XXX: currently we assume each logger is equally as fast- we should
// adjust ratios accordingly for non-homogenous loggers
const size_t threads_per_logger = g_nworkers / fds.size();
for (size_t i = 0; i < fds.size(); i++) {
assignments.emplace_back(
MakeRange<unsigned>(
i * threads_per_logger,
((i + 1) == fds.size()) ? g_nworkers : (i + 1) * threads_per_logger));
}
}
}
INVARIANT(AssignmentsValid(assignments, fds.size(), g_nworkers));
for (size_t i = 0; i < assignments.size(); i++) {
writers.emplace_back(
&txn_logger::writer,
i, fds[i], assignments[i]);
writers.back().detach();
}
thread persist_thread(&txn_logger::persister, assignments);
persist_thread.detach();
if (assignments_used)
*assignments_used = assignments;
}
void
txn_logger::persister(
vector<vector<unsigned>> assignments)
{
timer loop_timer;
for (;;) {
const uint64_t last_loop_usec = loop_timer.lap();
const uint64_t delay_time_usec = ticker::tick_us;
if (last_loop_usec < delay_time_usec) {
const uint64_t sleep_ns = (delay_time_usec - last_loop_usec) * 1000;
struct timespec t;
t.tv_sec = sleep_ns / ONE_SECOND_NS;
t.tv_nsec = sleep_ns % ONE_SECOND_NS;
nanosleep(&t, nullptr);
}
advance_system_sync_epoch(assignments);
}
}
void
txn_logger::advance_system_sync_epoch(
const vector<vector<unsigned>> &assignments)
{
uint64_t min_so_far = numeric_limits<uint64_t>::max();
const uint64_t best_tick_ex =
ticker::s_instance.global_current_tick();
// special case 0
const uint64_t best_tick_inc =
best_tick_ex ? (best_tick_ex - 1) : 0;
for (size_t i = 0; i < assignments.size(); i++)
for (auto j : assignments[i])
for (size_t k = j; k < NMAXCORES; k += g_nworkers) {
persist_ctx &ctx = persist_ctx_for(k, INITMODE_NONE);
// we need to arbitrarily advance threads which are not "doing
// anything", so they don't drag down the persistence of the system. if
// we can see that a thread is NOT in a guarded section AND its
// core->logger queue is empty, then that means we can advance its sync
// epoch up to best_tick_inc, b/c it is guaranteed that the next time
// it does any actions will be in epoch > best_tick_inc
if (!ctx.persist_buffers_.peek()) {
spinlock &l = ticker::s_instance.lock_for(k);
if (!l.is_locked()) {
bool did_lock = false;
for (size_t c = 0; c < 3; c++) {
if (l.try_lock()) {
did_lock = true;
break;
}
}
if (did_lock) {
if (!ctx.persist_buffers_.peek()) {
min_so_far = min(min_so_far, best_tick_inc);
per_thread_sync_epochs_[i].epochs_[k].store(
best_tick_inc, memory_order_release);
l.unlock();
continue;
}
l.unlock();
}
}
}
min_so_far = min(
per_thread_sync_epochs_[i].epochs_[k].load(
memory_order_acquire),
min_so_far);
}
const uint64_t syssync =
system_sync_epoch_->load(memory_order_acquire);
INVARIANT(min_so_far < numeric_limits<uint64_t>::max());
INVARIANT(syssync <= min_so_far);
// need to aggregate from [syssync + 1, min_so_far]
const uint64_t now_us = timer::cur_usec();
for (size_t i = 0; i < g_persist_stats.size(); i++) {
auto &ps = g_persist_stats[i];
for (uint64_t e = syssync + 1; e <= min_so_far; e++) {
auto &pes = ps.d_[e % g_max_lag_epochs];
const uint64_t ntxns_in_epoch = pes.ntxns_.load(memory_order_acquire);
const uint64_t start_us = pes.earliest_start_us_.load(memory_order_acquire);
INVARIANT(now_us >= start_us);
non_atomic_fetch_add(ps.ntxns_persisted_, ntxns_in_epoch);
non_atomic_fetch_add(
ps.latency_numer_,
(now_us - start_us) * ntxns_in_epoch);
pes.ntxns_.store(0, memory_order_release);
pes.earliest_start_us_.store(0, memory_order_release);
}
}
system_sync_epoch_->store(min_so_far, memory_order_release);
}
void
txn_logger::writer(
unsigned id, int fd,
vector<unsigned> assignment)
{
if (g_pin_loggers_to_numa_nodes) {
ALWAYS_ASSERT(!numa_run_on_node(id % numa_num_configured_nodes()));
ALWAYS_ASSERT(!sched_yield());
}
vector<iovec> iovs(
min(size_t(IOV_MAX), g_nworkers * g_perthread_buffers));
vector<pbuffer *> pxs;
timer loop_timer;
// XXX: sense is not useful for now, unless we want to
// fsync in the background...
bool sense = false; // cur is at sense, prev is at !sense
uint64_t epoch_prefixes[2][NMAXCORES];
NDB_MEMSET(&epoch_prefixes[0], 0, sizeof(epoch_prefixes[0]));
NDB_MEMSET(&epoch_prefixes[1], 0, sizeof(epoch_prefixes[1]));
// NOTE: a core id in the persistence system really represets
// all cores in the regular system modulo g_nworkers
size_t nbufswritten = 0, nbyteswritten = 0;
for (;;) {
const uint64_t last_loop_usec = loop_timer.lap();
const uint64_t delay_time_usec = ticker::tick_us;
// don't allow this loop to proceed less than an epoch's worth of time,
// so we can batch IO
if (last_loop_usec < delay_time_usec && nbufswritten < iovs.size()) {
const uint64_t sleep_ns = (delay_time_usec - last_loop_usec) * 1000;
struct timespec t;
t.tv_sec = sleep_ns / ONE_SECOND_NS;
t.tv_nsec = sleep_ns % ONE_SECOND_NS;
nanosleep(&t, nullptr);
}
// we need g_persist_stats[cur_sync_epoch_ex % g_nmax_loggers]
// to remain untouched (until the syncer can catch up), so we
// cannot read any buffers with epoch >=
// (cur_sync_epoch_ex + g_max_lag_epochs)
const uint64_t cur_sync_epoch_ex =
system_sync_epoch_->load(memory_order_acquire) + 1;
nbufswritten = nbyteswritten = 0;
for (auto idx : assignment) {
INVARIANT(idx >= 0 && idx < g_nworkers);
for (size_t k = idx; k < NMAXCORES; k += g_nworkers) {
persist_ctx &ctx = persist_ctx_for(k, INITMODE_NONE);
ctx.persist_buffers_.peekall(pxs);
for (auto px : pxs) {
INVARIANT(px);
INVARIANT(!px->io_scheduled_);
INVARIANT(nbufswritten <= iovs.size());
INVARIANT(px->header()->nentries_);
INVARIANT(px->core_id_ == k);
if (nbufswritten == iovs.size()) {
++g_evt_logger_writev_limit_met;
goto process;
}
if (transaction_proto2_static::EpochId(px->header()->last_tid_) >=
cur_sync_epoch_ex + g_max_lag_epochs) {
++g_evt_logger_max_lag_wait;
break;
}
iovs[nbufswritten].iov_base = (void *) &px->buf_start_[0];
#ifdef LOGGER_UNSAFE_REDUCE_BUFFER_SIZE
#define PXLEN(px) (((px)->curoff_ < 4) ? (px)->curoff_ : ((px)->curoff_ / 4))
#else
#define PXLEN(px) ((px)->curoff_)
#endif
const size_t pxlen = PXLEN(px);
iovs[nbufswritten].iov_len = pxlen;
evt_avg_log_buffer_iov_len.offer(pxlen);
px->io_scheduled_ = true;
nbufswritten++;
nbyteswritten += pxlen;
#ifdef CHECK_INVARIANTS
auto last_tid_cid = transaction_proto2_static::CoreId(px->header()->last_tid_);
auto px_cid = px->core_id_;
if (last_tid_cid != px_cid) {
cerr << "header: " << *px->header() << endl;
cerr << g_proto_version_str(last_tid_cid) << endl;
cerr << "last_tid_cid: " << last_tid_cid << endl;
cerr << "px_cid: " << px_cid << endl;
}
#endif
const uint64_t px_epoch =
transaction_proto2_static::EpochId(px->header()->last_tid_);
INVARIANT(
transaction_proto2_static::CoreId(px->header()->last_tid_) ==
px->core_id_);
INVARIANT(epoch_prefixes[sense][k] <= px_epoch);
INVARIANT(px_epoch > 0);
epoch_prefixes[sense][k] = px_epoch - 1;
auto &pes = g_persist_stats[k].d_[px_epoch % g_max_lag_epochs];
if (!pes.ntxns_.load(memory_order_acquire))
pes.earliest_start_us_.store(px->earliest_start_us_, memory_order_release);
non_atomic_fetch_add(pes.ntxns_, px->header()->nentries_);
g_evt_avg_log_entry_ntxns.offer(px->header()->nentries_);
}
}
}
process:
if (!nbufswritten) {
// XXX: should probably sleep here
nop_pause();
continue;
}
const bool dosense = sense;
if (!g_fake_writes) {
#ifdef ENABLE_EVENT_COUNTERS
timer write_timer;
#endif
const ssize_t ret = writev(fd, &iovs[0], nbufswritten);
if (unlikely(ret == -1)) {
perror("writev");
ALWAYS_ASSERT(false);
}
if (g_call_fsync) {
const int fret = fdatasync(fd);
if (unlikely(fret == -1)) {
perror("fdatasync");
ALWAYS_ASSERT(false);
}
}
#ifdef ENABLE_EVENT_COUNTERS
{
g_evt_avg_logger_bytes_per_writev.offer(nbyteswritten);
const double bytes_per_sec =
double(nbyteswritten)/(write_timer.lap_ms() / 1000.0);
g_evt_avg_logger_bytes_per_sec.offer(bytes_per_sec);
}
#endif
}
// update metadata from previous write
//
// return all buffers that have been io_scheduled_ - we can do this as
// soon as write returns. we take care to return to the proper buffer
epoch_array &ea = per_thread_sync_epochs_[id];
for (auto idx: assignment) {
for (size_t k = idx; k < NMAXCORES; k += g_nworkers) {
const uint64_t x0 = ea.epochs_[k].load(memory_order_acquire);
const uint64_t x1 = epoch_prefixes[dosense][k];
if (x1 > x0)
ea.epochs_[k].store(x1, memory_order_release);
persist_ctx &ctx = persist_ctx_for(k, INITMODE_NONE);
pbuffer *px, *px0;
while ((px = ctx.persist_buffers_.peek()) && px->io_scheduled_) {
#ifdef LOGGER_STRIDE_OVER_BUFFER
{
const size_t pxlen = PXLEN(px);
const size_t stridelen = 1;
for (size_t p = 0; p < pxlen; p += stridelen)
if ((&px->buf_start_[0])[p] & 0xF)
non_atomic_fetch_add(ea.dummy_work_, 1UL);
}
#endif
px0 = ctx.persist_buffers_.deq();
INVARIANT(px == px0);
INVARIANT(px->header()->nentries_);
px0->reset();
INVARIANT(ctx.init_);
INVARIANT(px0->core_id_ == k);
ctx.all_buffers_.enq(px0);
}
}
}
// bump the sense
sense = !sense;
}
}
tuple<uint64_t, uint64_t, double>
txn_logger::compute_ntxns_persisted_statistics()
{
uint64_t acc = 0, acc1 = 0, acc2 = 0;
uint64_t num = 0;
for (size_t i = 0; i < g_persist_stats.size(); i++) {
acc += g_persist_stats[i].ntxns_persisted_.load(memory_order_acquire);
acc1 += g_persist_stats[i].ntxns_pushed_.load(memory_order_acquire);
acc2 += g_persist_stats[i].ntxns_committed_.load(memory_order_acquire);
num += g_persist_stats[i].latency_numer_.load(memory_order_acquire);
}
INVARIANT(acc <= acc1);
INVARIANT(acc1 <= acc2);
if (acc == 0)
return make_tuple(0, acc1, 0.0);
return make_tuple(acc, acc1, double(num)/double(acc));
}
void
txn_logger::clear_ntxns_persisted_statistics()
{
for (size_t i = 0; i < g_persist_stats.size(); i++) {
auto &ps = g_persist_stats[i];
ps.ntxns_persisted_.store(0, memory_order_release);
ps.ntxns_pushed_.store(0, memory_order_release);
ps.ntxns_committed_.store(0, memory_order_release);
ps.latency_numer_.store(0, memory_order_release);
for (size_t e = 0; e < g_max_lag_epochs; e++) {
auto &pes = ps.d_[e];
pes.ntxns_.store(0, memory_order_release);
pes.earliest_start_us_.store(0, memory_order_release);
}
}
}
void
txn_logger::wait_for_idle_state()
{
for (size_t i = 0; i < NMAXCORES; i++) {
persist_ctx &ctx = persist_ctx_for(i, INITMODE_NONE);
if (!ctx.init_)
continue;
pbuffer *px;
while (!(px = ctx.all_buffers_.peek()) || px->header()->nentries_)
nop_pause();
while (ctx.persist_buffers_.peek())
nop_pause();
}
}
void
txn_logger::wait_until_current_point_persisted()
{
const uint64_t e = ticker::s_instance.global_current_tick();
cerr << "waiting for system_sync_epoch_="
<< system_sync_epoch_->load(memory_order_acquire)
<< " to be < e=" << e << endl;
while (system_sync_epoch_->load(memory_order_acquire) < e)
nop_pause();
}
/*}}}*/
/** garbage collection subsystem **/
static event_counter evt_local_chain_cleanups("local_chain_cleanups");
static event_counter evt_try_delete_unlinks("try_delete_unlinks");
static event_avg_counter evt_avg_time_inbetween_ro_epochs_usec(
"avg_time_inbetween_ro_epochs_usec");
void
transaction_proto2_static::InitGC()
{
g_flags->g_gc_init.store(true, memory_order_release);
}
static void
sleep_ro_epoch()
{
const uint64_t sleep_ns = transaction_proto2_static::ReadOnlyEpochUsec * 1000;
struct timespec t;
t.tv_sec = sleep_ns / ONE_SECOND_NS;
t.tv_nsec = sleep_ns % ONE_SECOND_NS;
nanosleep(&t, nullptr);
}
void
transaction_proto2_static::PurgeThreadOutstandingGCTasks()
{
#ifdef PROTO2_CAN_DISABLE_GC
if (!IsGCEnabled())
return;
#endif
INVARIANT(!rcu::s_instance.in_rcu_region());
threadctx &ctx = g_threadctxs.my();
uint64_t e;
if (!ctx.queue_.get_latest_epoch(e))
return;
// wait until we can clean up e
for (;;) {
const uint64_t last_tick_ex = ticker::s_instance.global_last_tick_exclusive();
const uint64_t ro_tick_ex = to_read_only_tick(last_tick_ex);
if (unlikely(!ro_tick_ex)) {
sleep_ro_epoch();
continue;
}
const uint64_t ro_tick_geq = ro_tick_ex - 1;
if (ro_tick_geq < e) {
sleep_ro_epoch();
continue;
}
break;
}
clean_up_to_including(ctx, e);
INVARIANT(ctx.queue_.empty());
}
//#ifdef CHECK_INVARIANTS
//// make sure hidden is blocked by version e, when traversing from start
//static bool
//IsBlocked(dbtuple *start, dbtuple *hidden, uint64_t e)
//{
// dbtuple *c = start;
// while (c) {
// if (c == hidden)
// return false;
// if (c->is_not_behind(e))
// // blocked
// return true;
// c = c->next;
// }
// ALWAYS_ASSERT(false); // hidden should be found on chain
//}
//#endif
void
transaction_proto2_static::clean_up_to_including(threadctx &ctx, uint64_t ro_tick_geq)
{
INVARIANT(!rcu::s_instance.in_rcu_region());
INVARIANT(ctx.last_reaped_epoch_ <= ro_tick_geq);
INVARIANT(ctx.scratch_.empty());
if (ctx.last_reaped_epoch_ == ro_tick_geq)
return;
#ifdef ENABLE_EVENT_COUNTERS
const uint64_t now = timer::cur_usec();
if (ctx.last_reaped_timestamp_us_ > 0) {
const uint64_t diff = now - ctx.last_reaped_timestamp_us_;
evt_avg_time_inbetween_ro_epochs_usec.offer(diff);
}
ctx.last_reaped_timestamp_us_ = now;
#endif
ctx.last_reaped_epoch_ = ro_tick_geq;
#ifdef CHECK_INVARIANTS
const uint64_t last_tick_ex = ticker::s_instance.global_last_tick_exclusive();
INVARIANT(last_tick_ex);
const uint64_t last_consistent_tid = ComputeReadOnlyTid(last_tick_ex - 1);
const uint64_t computed_last_tick_ex = ticker::s_instance.compute_global_last_tick_exclusive();
INVARIANT(last_tick_ex <= computed_last_tick_ex);
INVARIANT(to_read_only_tick(last_tick_ex) > ro_tick_geq);
#endif
// XXX: hacky
char rcu_guard[sizeof(scoped_rcu_base<false>)] = {0};
const size_t max_niters_with_rcu = 128;
#define ENTER_RCU() \
do { \
new (&rcu_guard[0]) scoped_rcu_base<false>(); \
} while (0)
#define EXIT_RCU() \
do { \
scoped_rcu_base<false> *px = (scoped_rcu_base<false> *) &rcu_guard[0]; \
px->~scoped_rcu_base<false>(); \
} while (0)
ctx.scratch_.empty_accept_from(ctx.queue_, ro_tick_geq);
ctx.scratch_.transfer_freelist(ctx.queue_);
px_queue &q = ctx.scratch_;
if (q.empty())
return;
bool in_rcu = false;
size_t niters_with_rcu = 0, n = 0;
for (auto it = q.begin(); it != q.end(); ++it, ++n, ++niters_with_rcu) {
auto &delent = *it;
INVARIANT(delent.tuple()->opaque.load(std::memory_order_acquire) == 1);
if (!delent.key_.get_flags()) {
// guaranteed to be gc-able now (even w/o RCU)
#ifdef CHECK_INVARIANTS
if (delent.trigger_tid_ > last_consistent_tid /*|| !IsBlocked(delent.tuple_ahead_, delent.tuple(), last_consistent_tid) */) {
cerr << "tuple ahead : " << g_proto_version_str(delent.tuple_ahead_->version) << endl;
cerr << "tuple ahead : " << *delent.tuple_ahead_ << endl;
cerr << "trigger tid : " << g_proto_version_str(delent.trigger_tid_) << endl;
cerr << "tuple : " << g_proto_version_str(delent.tuple()->version) << endl;
cerr << "last_consist_tid: " << g_proto_version_str(last_consistent_tid) << endl;
cerr << "last_tick_ex : " << last_tick_ex << endl;
cerr << "ro_tick_geq : " << ro_tick_geq << endl;
cerr << "rcu_block_tick : " << it.tick() << endl;
}
INVARIANT(delent.trigger_tid_ <= last_consistent_tid);
delent.tuple()->opaque.store(0, std::memory_order_release);
#endif
dbtuple::release_no_rcu(delent.tuple());
} else {
INVARIANT(!delent.tuple_ahead_);
INVARIANT(delent.btr_);
// check if an element preceeds the (deleted) tuple before doing the delete
::lock_guard<dbtuple> lg_tuple(delent.tuple(), false);
#ifdef CHECK_INVARIANTS
if (!delent.tuple()->is_not_behind(last_consistent_tid)) {
cerr << "trigger tid : " << g_proto_version_str(delent.trigger_tid_) << endl;
cerr << "tuple : " << g_proto_version_str(delent.tuple()->version) << endl;
cerr << "last_consist_tid: " << g_proto_version_str(last_consistent_tid) << endl;
cerr << "last_tick_ex : " << last_tick_ex << endl;
cerr << "ro_tick_geq : " << ro_tick_geq << endl;
cerr << "rcu_block_tick : " << it.tick() << endl;
}
INVARIANT(delent.tuple()->version == delent.trigger_tid_);
INVARIANT(delent.tuple()->is_not_behind(last_consistent_tid));
INVARIANT(delent.tuple()->is_deleting());
#endif
if (unlikely(!delent.tuple()->is_latest())) {
// requeue it up, except this time as a regular delete
const uint64_t my_ro_tick = to_read_only_tick(
ticker::s_instance.global_current_tick());
ctx.queue_.enqueue(
delete_entry(
nullptr,
MakeTid(CoreMask, NumIdMask >> NumIdShift, (my_ro_tick + 1) * ReadOnlyEpochMultiplier - 1),
delent.tuple(),
marked_ptr<string>(),
nullptr),
my_ro_tick);
++g_evt_proto_gc_delete_requeue;
// reclaim string ptrs
string *spx = delent.key_.get();
if (unlikely(spx))
ctx.pool_.emplace_back(spx);
continue;
}
#ifdef CHECK_INVARIANTS
delent.tuple()->opaque.store(0, std::memory_order_release);
#endif
// if delent.key_ is nullptr, then the key is stored in the tuple
// record storage location, and the size field contains the length of
// the key
//
// otherwise, delent.key_ is a pointer to a string containing the
// key
varkey k;
string *spx = delent.key_.get();
if (likely(!spx)) {
k = varkey(delent.tuple()->get_value_start(), delent.tuple()->size);
} else {
k = varkey(*spx);
ctx.pool_.emplace_back(spx);
}
if (!in_rcu) {
ENTER_RCU();
niters_with_rcu = 0;
in_rcu = true;
}
typename concurrent_btree::value_type removed = 0;
const bool did_remove = delent.btr_->remove(k, &removed);
ALWAYS_ASSERT(did_remove);
INVARIANT(removed == (typename concurrent_btree::value_type) delent.tuple());
delent.tuple()->clear_latest();
dbtuple::release(delent.tuple()); // rcu free it
}
if (in_rcu && niters_with_rcu >= max_niters_with_rcu) {
EXIT_RCU();
niters_with_rcu = 0;
in_rcu = false;
}
}
q.clear();
g_evt_avg_proto_gc_queue_len.offer(n);
if (in_rcu)
EXIT_RCU();
INVARIANT(!rcu::s_instance.in_rcu_region());
}
aligned_padded_elem<transaction_proto2_static::hackstruct>
transaction_proto2_static::g_hack;
aligned_padded_elem<transaction_proto2_static::flags>
transaction_proto2_static::g_flags;
percore_lazy<transaction_proto2_static::threadctx>
transaction_proto2_static::g_threadctxs;
event_counter
transaction_proto2_static::g_evt_worker_thread_wait_log_buffer(
"worker_thread_wait_log_buffer");
event_counter
transaction_proto2_static::g_evt_dbtuple_no_space_for_delkey(
"dbtuple_no_space_for_delkey");
event_counter
transaction_proto2_static::g_evt_proto_gc_delete_requeue(
"proto_gc_delete_requeue");
event_avg_counter
transaction_proto2_static::g_evt_avg_log_entry_size(
"avg_log_entry_size");
event_avg_counter
transaction_proto2_static::g_evt_avg_proto_gc_queue_len(
"avg_proto_gc_queue_len");