rocksdb/util/rate_limiter.cc
Siying Dong 41cbb72749 options.delayed_write_rate use the rate of rate_limiter by default.
Summary:
It's hard for RocksDB to come up with a good default of delayed write rate. Use rate given by rate limiter if it is availalbe. This provides the I/O order of magnitude.
Closes https://github.com/facebook/rocksdb/pull/2357

Differential Revision: D5115324

Pulled By: siying

fbshipit-source-id: 341065ad2211c981fc804011c0f0e59a50c7e754
2017-05-24 09:58:24 -07:00

251 lines
8.4 KiB
C++

// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
// This source code is licensed under the BSD-style license found in the
// LICENSE file in the root directory of this source tree. An additional grant
// of patent rights can be found in the PATENTS file in the same directory.
// This source code is also licensed under the GPLv2 license found in the
// COPYING file in the root directory of this source tree.
//
// 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 "util/rate_limiter.h"
#include "monitoring/statistics.h"
#include "port/port.h"
#include "rocksdb/env.h"
#include "util/sync_point.h"
namespace rocksdb {
// Pending request
struct GenericRateLimiter::Req {
explicit Req(int64_t _bytes, port::Mutex* _mu)
: request_bytes(_bytes), bytes(_bytes), cv(_mu), granted(false) {}
int64_t request_bytes;
int64_t bytes;
port::CondVar cv;
bool granted;
};
GenericRateLimiter::GenericRateLimiter(int64_t rate_bytes_per_sec,
int64_t refill_period_us,
int32_t fairness)
: refill_period_us_(refill_period_us),
rate_bytes_per_sec_(rate_bytes_per_sec),
refill_bytes_per_period_(
CalculateRefillBytesPerPeriod(rate_bytes_per_sec)),
env_(Env::Default()),
stop_(false),
exit_cv_(&request_mutex_),
requests_to_wait_(0),
available_bytes_(0),
next_refill_us_(NowMicrosMonotonic(env_)),
fairness_(fairness > 100 ? 100 : fairness),
rnd_((uint32_t)time(nullptr)),
leader_(nullptr) {
total_requests_[0] = 0;
total_requests_[1] = 0;
total_bytes_through_[0] = 0;
total_bytes_through_[1] = 0;
}
GenericRateLimiter::~GenericRateLimiter() {
MutexLock g(&request_mutex_);
stop_ = true;
requests_to_wait_ = static_cast<int32_t>(queue_[Env::IO_LOW].size() +
queue_[Env::IO_HIGH].size());
for (auto& r : queue_[Env::IO_HIGH]) {
r->cv.Signal();
}
for (auto& r : queue_[Env::IO_LOW]) {
r->cv.Signal();
}
while (requests_to_wait_ > 0) {
exit_cv_.Wait();
}
}
// This API allows user to dynamically change rate limiter's bytes per second.
void GenericRateLimiter::SetBytesPerSecond(int64_t bytes_per_second) {
assert(bytes_per_second > 0);
rate_bytes_per_sec_ = bytes_per_second;
refill_bytes_per_period_.store(
CalculateRefillBytesPerPeriod(bytes_per_second),
std::memory_order_relaxed);
}
void GenericRateLimiter::Request(int64_t bytes, const Env::IOPriority pri,
Statistics* stats) {
assert(bytes <= refill_bytes_per_period_.load(std::memory_order_relaxed));
TEST_SYNC_POINT("GenericRateLimiter::Request");
MutexLock g(&request_mutex_);
if (stop_) {
return;
}
++total_requests_[pri];
if (available_bytes_ >= bytes) {
// Refill thread assigns quota and notifies requests waiting on
// the queue under mutex. So if we get here, that means nobody
// is waiting?
available_bytes_ -= bytes;
total_bytes_through_[pri] += bytes;
return;
}
// Request cannot be satisfied at this moment, enqueue
Req r(bytes, &request_mutex_);
queue_[pri].push_back(&r);
do {
bool timedout = false;
// Leader election, candidates can be:
// (1) a new incoming request,
// (2) a previous leader, whose quota has not been not assigned yet due
// to lower priority
// (3) a previous waiter at the front of queue, who got notified by
// previous leader
if (leader_ == nullptr &&
((!queue_[Env::IO_HIGH].empty() &&
&r == queue_[Env::IO_HIGH].front()) ||
(!queue_[Env::IO_LOW].empty() &&
&r == queue_[Env::IO_LOW].front()))) {
leader_ = &r;
int64_t delta = next_refill_us_ - NowMicrosMonotonic(env_);
delta = delta > 0 ? delta : 0;
if (delta == 0) {
timedout = true;
} else {
int64_t wait_until = env_->NowMicros() + delta;
RecordTick(stats, NUMBER_RATE_LIMITER_DRAINS);
timedout = r.cv.TimedWait(wait_until);
}
} else {
// Not at the front of queue or an leader has already been elected
r.cv.Wait();
}
// request_mutex_ is held from now on
if (stop_) {
--requests_to_wait_;
exit_cv_.Signal();
return;
}
// Make sure the waken up request is always the header of its queue
assert(r.granted ||
(!queue_[Env::IO_HIGH].empty() &&
&r == queue_[Env::IO_HIGH].front()) ||
(!queue_[Env::IO_LOW].empty() &&
&r == queue_[Env::IO_LOW].front()));
assert(leader_ == nullptr ||
(!queue_[Env::IO_HIGH].empty() &&
leader_ == queue_[Env::IO_HIGH].front()) ||
(!queue_[Env::IO_LOW].empty() &&
leader_ == queue_[Env::IO_LOW].front()));
if (leader_ == &r) {
// Waken up from TimedWait()
if (timedout) {
// Time to do refill!
Refill();
// Re-elect a new leader regardless. This is to simplify the
// election handling.
leader_ = nullptr;
// Notify the header of queue if current leader is going away
if (r.granted) {
// Current leader already got granted with quota. Notify header
// of waiting queue to participate next round of election.
assert((queue_[Env::IO_HIGH].empty() ||
&r != queue_[Env::IO_HIGH].front()) &&
(queue_[Env::IO_LOW].empty() ||
&r != queue_[Env::IO_LOW].front()));
if (!queue_[Env::IO_HIGH].empty()) {
queue_[Env::IO_HIGH].front()->cv.Signal();
} else if (!queue_[Env::IO_LOW].empty()) {
queue_[Env::IO_LOW].front()->cv.Signal();
}
// Done
break;
}
} else {
// Spontaneous wake up, need to continue to wait
assert(!r.granted);
leader_ = nullptr;
}
} else {
// Waken up by previous leader:
// (1) if requested quota is granted, it is done.
// (2) if requested quota is not granted, this means current thread
// was picked as a new leader candidate (previous leader got quota).
// It needs to participate leader election because a new request may
// come in before this thread gets waken up. So it may actually need
// to do Wait() again.
assert(!timedout);
}
} while (!r.granted);
}
void GenericRateLimiter::Refill() {
TEST_SYNC_POINT("GenericRateLimiter::Refill");
next_refill_us_ = NowMicrosMonotonic(env_) + refill_period_us_;
// Carry over the left over quota from the last period
auto refill_bytes_per_period =
refill_bytes_per_period_.load(std::memory_order_relaxed);
if (available_bytes_ < refill_bytes_per_period) {
available_bytes_ += refill_bytes_per_period;
}
int use_low_pri_first = rnd_.OneIn(fairness_) ? 0 : 1;
for (int q = 0; q < 2; ++q) {
auto use_pri = (use_low_pri_first == q) ? Env::IO_LOW : Env::IO_HIGH;
auto* queue = &queue_[use_pri];
while (!queue->empty()) {
auto* next_req = queue->front();
if (available_bytes_ < next_req->request_bytes) {
// avoid starvation
next_req->request_bytes -= available_bytes_;
available_bytes_ = 0;
break;
}
available_bytes_ -= next_req->request_bytes;
next_req->request_bytes = 0;
total_bytes_through_[use_pri] += next_req->bytes;
queue->pop_front();
next_req->granted = true;
if (next_req != leader_) {
// Quota granted, signal the thread
next_req->cv.Signal();
}
}
}
}
int64_t GenericRateLimiter::CalculateRefillBytesPerPeriod(
int64_t rate_bytes_per_sec) {
if (port::kMaxInt64 / rate_bytes_per_sec < refill_period_us_) {
// Avoid unexpected result in the overflow case. The result now is still
// inaccurate but is a number that is large enough.
return port::kMaxInt64 / 1000000;
} else {
return std::max(kMinRefillBytesPerPeriod,
rate_bytes_per_sec * refill_period_us_ / 1000000);
}
}
RateLimiter* NewGenericRateLimiter(
int64_t rate_bytes_per_sec, int64_t refill_period_us, int32_t fairness) {
assert(rate_bytes_per_sec > 0);
assert(refill_period_us > 0);
assert(fairness > 0);
return new GenericRateLimiter(
rate_bytes_per_sec, refill_period_us, fairness);
}
} // namespace rocksdb