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/*
* This file is open source software, licensed to you under the terms
* of the Apache License, Version 2.0 (the "License"). See the NOTICE file
* distributed with this work for additional information regarding copyright
* ownership. 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.
*/
/*
* Copyright (C) 2016 ScyllaDB
*/
#include <seastar/core/thread.hh>
#include <seastar/testing/test_case.hh>
#include <seastar/testing/thread_test_case.hh>
#include <seastar/testing/test_runner.hh>
#include <seastar/core/sstring.hh>
#include <seastar/core/fair_queue.hh>
#include <seastar/core/do_with.hh>
#include <seastar/util/later.hh>
#include <seastar/core/sleep.hh>
#include <seastar/core/print.hh>
#include <boost/range/irange.hpp>
#include <chrono>
using namespace seastar;
using namespace std::chrono_literals;
struct request {
fair_queue_ticket fqdesc;
unsigned index;
request(unsigned weight, unsigned index)
: fqdesc({weight, 0})
, index(index)
{}
};
class test_env {
fair_queue _fq;
std::vector<int> _results;
std::vector<std::vector<std::exception_ptr>> _exceptions;
std::vector<priority_class_ptr> _classes;
std::vector<request> _inflight;
void drain() {
do {} while (tick() != 0);
}
public:
test_env(unsigned capacity) : _fq(capacity)
{}
// As long as there is a request sitting in the queue, tick() will process
// at least one request. The only situation in which tick() will return nothing
// is if no requests were sent to the fair_queue (obviously).
//
// Because of this property, one useful use of tick() is to implement a drain()
// method (see above) in which all requests currently sent to the queue are drained
// before the queue is destroyed.
unsigned tick(unsigned n = 1) {
unsigned processed = 0;
_fq.dispatch_requests();
for (unsigned i = 0; i < n; ++i) {
std::vector<request> curr;
curr.swap(_inflight);
for (auto& req : curr) {
processed++;
_results[req.index]++;
_fq.notify_requests_finished(req.fqdesc);
}
_fq.dispatch_requests();
}
return processed;
}
~test_env() {
drain();
for (auto& p: _classes) {
_fq.unregister_priority_class(p);
}
}
size_t register_priority_class(uint32_t shares) {
_results.push_back(0);
_exceptions.push_back(std::vector<std::exception_ptr>());
_classes.push_back(_fq.register_priority_class(shares));
return _classes.size() - 1;
}
void do_op(unsigned index, unsigned weight) {
auto cl = _classes[index];
auto req = request(weight, index);
_fq.queue(cl, req.fqdesc, [this, index, req] () mutable noexcept {
try {
_inflight.push_back(std::move(req));
} catch (...) {
auto eptr = std::current_exception();
_exceptions[index].push_back(eptr);
_fq.notify_requests_finished(req.fqdesc);
}
});
}
void update_shares(unsigned index, uint32_t shares) {
auto cl = _classes[index];
cl->update_shares(shares);
}
void reset_results(unsigned index) {
_results[index] = 0;
}
// Verify if the ratios are what we expect. Because we can't be sure about
// precise timing issues, we can always be off by some percentage. In simpler
// tests we really expect it to very low, but in more complex tests, with share
// changes, for instance, they can accumulate
//
// The ratios argument is the ratios towards the first class
void verify(sstring name, std::vector<unsigned> ratios, unsigned expected_error = 1) {
assert(ratios.size() == _results.size());
auto str = name + ":";
for (auto i = 0ul; i < _results.size(); ++i) {
str += format(" r[{:d}] = {:d}", i, _results[i]);
}
std::cout << str << std::endl;
for (auto i = 0ul; i < ratios.size(); ++i) {
int min_expected = ratios[i] * (_results[0] - expected_error);
int max_expected = ratios[i] * (_results[0] + expected_error);
BOOST_REQUIRE(_results[i] >= min_expected);
BOOST_REQUIRE(_results[i] <= max_expected);
BOOST_REQUIRE(_exceptions[i].size() == 0);
}
}
};
// Equal ratios. Expected equal results.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_equal_2classes) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// allow half the requests in
env.tick(100);
env.verify("equal_2classes", {1, 1});
}
// Equal results, spread among 4 classes.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_equal_4classes) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
auto c = env.register_priority_class(10);
auto d = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
env.do_op(c, 1);
env.do_op(d, 1);
}
later().get();
// allow half the requests in
env.tick(200);
env.verify("equal_4classes", {1, 1, 1, 1});
}
// Class2 twice as powerful. Expected class2 to have 2 x more requests.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_different_shares) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(20);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// allow half the requests in
env.tick(100);
return env.verify("different_shares", {1, 2});
}
// Equal ratios, high capacity queue. Should still divide equally.
//
// Note that we sleep less because now more requests will be going through the
// queue.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_equal_hi_capacity_2classes) {
test_env env(10);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// queue has capacity 10, 10 x 10 = 100, allow half the requests in
env.tick(10);
env.verify("hi_capacity_2classes", {1, 1});
}
// Class2 twice as powerful, queue is high capacity. Still expected class2 to
// have 2 x more requests.
//
// Note that we sleep less because now more requests will be going through the
// queue.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_different_shares_hi_capacity) {
test_env env(10);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(20);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// queue has capacity 10, 10 x 10 = 100, allow half the requests in
env.tick(10);
env.verify("different_shares_hi_capacity", {1, 2});
}
// Classes equally powerful. But Class1 issues twice as expensive requests. Expected Class2 to have 2 x more requests.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_different_weights) {
test_env env(2);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 2);
env.do_op(b, 1);
}
later().get();
// allow half the requests in
env.tick(100);
env.verify("different_weights", {1, 2});
}
// Class2 pushes many requests over. Right after, don't expect Class2 to be able to push anything else.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_dominant_queue) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(b, 1);
}
later().get();
// consume all requests
env.tick(100);
// zero statistics.
env.reset_results(b);
for (int i = 0; i < 20; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
// allow half the requests in
env.tick(20);
env.verify("dominant_queue", {1, 0});
}
// Class2 pushes many requests at first. After enough time, this shouldn't matter anymore.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_forgiving_queue) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 100; ++i) {
env.do_op(b, 1);
}
later().get();
// consume all requests
env.tick(100);
sleep(500ms).get();
env.reset_results(b);
for (int i = 0; i < 100; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// allow half the requests in
env.tick(100);
env.verify("forgiving_queue", {1, 1});
}
// Classes push requests and then update swap their shares. In the end, should have executed
// the same number of requests.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_update_shares) {
test_env env(1);
auto a = env.register_priority_class(20);
auto b = env.register_priority_class(10);
for (int i = 0; i < 500; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// allow 25% of the requests in
env.tick(250);
env.update_shares(a, 10);
env.update_shares(b, 20);
later().get();
// allow 25% of the requests in
env.tick(250);
env.verify("update_shares", {1, 1}, 2);
}
// Classes run for a longer period of time. Balance must be kept over many timer
// periods.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_longer_run) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(10);
for (int i = 0; i < 20000; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
// In total allow half the requests in, but do it over a
// long period of time, ticking slowly
for (int i = 0; i < 1000; ++i) {
sleep(1ms).get();
env.tick(2);
}
env.verify("longer_run", {1, 1}, 2);
}
// Classes run for a longer period of time. Proportional balance must be kept over many timer
// periods, despite unequal shares..
SEASTAR_THREAD_TEST_CASE(test_fair_queue_longer_run_different_shares) {
test_env env(1);
auto a = env.register_priority_class(10);
auto b = env.register_priority_class(20);
for (int i = 0; i < 20000; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
// In total allow half the requests in, but do it over a
// long period of time, ticking slowly
for (int i = 0; i < 1000; ++i) {
sleep(1ms).get();
env.tick(2);
}
env.verify("longer_run_different_shares", {1, 2}, 2);
}
// Classes run for a random period of time. Equal operations expected.
SEASTAR_THREAD_TEST_CASE(test_fair_queue_random_run) {
test_env env(1);
auto a = env.register_priority_class(1);
auto b = env.register_priority_class(1);
std::default_random_engine& generator = testing::local_random_engine;
// multiples of 100usec - which is the approximate length of the request. We will
// put a minimum of 10. Below that, it is hard to guarantee anything. The maximum is
// about 50 seconds.
std::uniform_int_distribution<uint32_t> distribution(10, 500 * 1000);
auto reqs = distribution(generator);
// Enough requests for the maximum run (half per queue, + leeway)
for (uint32_t i = 0; i < reqs; ++i) {
env.do_op(a, 1);
env.do_op(b, 1);
}
later().get();
// In total allow half the requests in
env.tick(reqs);
// Accept 5 % error.
auto expected_error = std::max(1, int(round(reqs * 0.05)));
env.verify(format("random_run ({:d} requests)", reqs), {1, 1}, expected_error);
}
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