304 lines
8.5 KiB
C++
304 lines
8.5 KiB
C++
/*
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* genericactors.actor.cpp
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*
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* This source file is part of the FoundationDB open source project
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*
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* Copyright 2013-2022 Apple Inc. and the FoundationDB project authors
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#include "flow/flow.h"
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#include "flow/UnitTest.h"
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#include "flow/actorcompiler.h" // This must be the last #include.
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ACTOR Future<bool> allTrue(std::vector<Future<bool>> all) {
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state int i = 0;
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while (i != all.size()) {
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bool r = wait(all[i]);
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if (!r)
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return false;
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i++;
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}
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return true;
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}
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ACTOR Future<Void> anyTrue(std::vector<Reference<AsyncVar<bool>>> input, Reference<AsyncVar<bool>> output) {
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loop {
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bool oneTrue = false;
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std::vector<Future<Void>> changes;
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for (auto it : input) {
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if (it->get())
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oneTrue = true;
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changes.push_back(it->onChange());
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}
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output->set(oneTrue);
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wait(waitForAny(changes));
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}
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}
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ACTOR Future<Void> cancelOnly(std::vector<Future<Void>> futures) {
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// We don't do anything with futures except hold them, we never return, but if we are cancelled we (naturally) drop
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// the futures
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wait(Never());
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return Void();
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}
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ACTOR Future<Void> timeoutWarningCollector(FutureStream<Void> input, double logDelay, const char* context, UID id) {
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state uint64_t counter = 0;
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state Future<Void> end = delay(logDelay);
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loop choose {
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when(waitNext(input)) {
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counter++;
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}
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when(wait(end)) {
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if (counter)
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TraceEvent(SevWarn, context, id).detail("LateProcessCount", counter).detail("LoggingDelay", logDelay);
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end = delay(logDelay);
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counter = 0;
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}
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}
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}
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ACTOR Future<Void> waitForMost(std::vector<Future<ErrorOr<Void>>> futures,
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int faultTolerance,
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Error e,
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double waitMultiplierForSlowFutures) {
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state std::vector<Future<bool>> successFutures;
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state double startTime = now();
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successFutures.reserve(futures.size());
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for (const auto& future : futures) {
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successFutures.push_back(fmap([](auto const& result) { return result.present(); }, future));
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}
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bool success = wait(quorumEqualsTrue(successFutures, successFutures.size() - faultTolerance));
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if (!success) {
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throw e;
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}
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wait(delay((now() - startTime) * waitMultiplierForSlowFutures) || waitForAll(successFutures));
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return Void();
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}
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ACTOR Future<bool> quorumEqualsTrue(std::vector<Future<bool>> futures, int required) {
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state std::vector<Future<Void>> true_futures;
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state std::vector<Future<Void>> false_futures;
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true_futures.reserve(futures.size());
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false_futures.reserve(futures.size());
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for (int i = 0; i < futures.size(); i++) {
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true_futures.push_back(onEqual(futures[i], true));
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false_futures.push_back(onEqual(futures[i], false));
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}
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choose {
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when(wait(quorum(true_futures, required))) {
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return true;
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}
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when(wait(quorum(false_futures, futures.size() - required + 1))) {
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return false;
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}
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}
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}
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ACTOR Future<bool> shortCircuitAny(std::vector<Future<bool>> f) {
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std::vector<Future<Void>> sc;
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sc.reserve(f.size());
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for (Future<bool> fut : f) {
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sc.push_back(returnIfTrue(fut));
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}
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choose {
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when(wait(waitForAll(f))) {
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// Handle a possible race condition? If the _last_ term to
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// be evaluated triggers the waitForAll before bubbling
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// out of the returnIfTrue quorum
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for (const auto& fut : f) {
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if (fut.get()) {
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return true;
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}
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}
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return false;
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}
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when(wait(waitForAny(sc))) {
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return true;
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}
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}
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}
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Future<Void> orYield(Future<Void> f) {
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if (f.isReady()) {
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if (f.isError())
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return tagError<Void>(yield(), f.getError());
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else
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return yield();
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} else
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return f;
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}
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ACTOR Future<Void> returnIfTrue(Future<bool> f) {
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bool b = wait(f);
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if (b) {
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return Void();
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}
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wait(Never());
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throw internal_error();
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}
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ACTOR Future<Void> lowPriorityDelay(double waitTime) {
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state int loopCount = 0;
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state int totalLoops =
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std::max<int>(waitTime / FLOW_KNOBS->LOW_PRIORITY_MAX_DELAY, FLOW_KNOBS->LOW_PRIORITY_DELAY_COUNT);
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while (loopCount < totalLoops) {
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wait(delay(waitTime / totalLoops, TaskPriority::Low));
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loopCount++;
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}
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return Void();
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}
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ACTOR Future<Void> delayAfterCleared(Reference<AsyncVar<bool>> condition, double time, TaskPriority taskID) {
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state Future<Void> timer = condition->get() ? Never() : delay(time, taskID);
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state bool previousState = condition->get();
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loop choose {
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when(wait(timer)) {
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return Void();
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}
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when(wait(condition->onChange())) {
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bool currentState = condition->get();
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if (currentState != previousState) {
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timer = currentState ? Never() : delay(time, taskID);
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previousState = currentState;
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}
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}
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}
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}
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// Same as delayAfterCleared, but use lowPriorityDelay.
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ACTOR Future<Void> lowPriorityDelayAfterCleared(Reference<AsyncVar<bool>> condition, double time) {
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state Future<Void> timer = condition->get() ? Never() : lowPriorityDelay(time);
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state bool previousState = condition->get();
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loop choose {
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when(wait(timer)) {
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return Void();
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}
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when(wait(condition->onChange())) {
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bool currentState = condition->get();
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if (currentState != previousState) {
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timer = currentState ? Never() : lowPriorityDelay(time);
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previousState = currentState;
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}
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}
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}
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}
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namespace {
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struct DummyState {
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int changed{ 0 };
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int unchanged{ 0 };
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bool operator==(DummyState const& rhs) const { return changed == rhs.changed && unchanged == rhs.unchanged; }
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bool operator!=(DummyState const& rhs) const { return !(*this == rhs); }
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};
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ACTOR Future<Void> testPublisher(Reference<AsyncVar<DummyState>> input) {
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state int i = 0;
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for (; i < 100; ++i) {
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wait(delay(deterministicRandom()->random01()));
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auto var = input->get();
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++var.changed;
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input->set(var);
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}
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return Void();
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}
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ACTOR Future<Void> testSubscriber(Reference<IAsyncListener<int>> output, Optional<int> expected) {
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loop {
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wait(output->onChange());
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ASSERT(expected.present());
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if (output->get() == expected.get()) {
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return Void();
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}
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}
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}
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static Future<ErrorOr<Void>> goodTestFuture(double duration) {
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return tag(delay(duration), ErrorOr<Void>(Void()));
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}
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static Future<ErrorOr<Void>> badTestFuture(double duration, Error e) {
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return tag(delay(duration), ErrorOr<Void>(e));
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}
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} // namespace
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TEST_CASE("/flow/genericactors/AsyncListener") {
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auto input = makeReference<AsyncVar<DummyState>>();
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state Future<Void> subscriber1 =
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testSubscriber(IAsyncListener<int>::create(input, [](auto const& var) { return var.changed; }), 100);
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state Future<Void> subscriber2 =
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testSubscriber(IAsyncListener<int>::create(input, [](auto const& var) { return var.unchanged; }), {});
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wait(subscriber1 && testPublisher(input));
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ASSERT(!subscriber2.isReady());
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return Void();
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}
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TEST_CASE("/flow/genericactors/WaitForMost") {
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state std::vector<Future<ErrorOr<Void>>> futures;
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{
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futures = { goodTestFuture(1), goodTestFuture(2), goodTestFuture(3) };
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wait(waitForMost(futures, 1, operation_failed(), 0.0)); // Don't wait for slowest future
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ASSERT(!futures[2].isReady());
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}
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{
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futures = { goodTestFuture(1), goodTestFuture(2), goodTestFuture(3) };
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wait(waitForMost(futures, 0, operation_failed(), 0.0)); // Wait for all futures
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ASSERT(futures[2].isReady());
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}
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{
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futures = { goodTestFuture(1), goodTestFuture(2), goodTestFuture(3) };
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wait(waitForMost(futures, 1, operation_failed(), 1.0)); // Wait for slowest future
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ASSERT(futures[2].isReady());
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}
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{
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futures = { goodTestFuture(1), goodTestFuture(2), badTestFuture(1, success()) };
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wait(waitForMost(futures, 1, operation_failed(), 1.0)); // Error ignored
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}
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{
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futures = { goodTestFuture(1), goodTestFuture(2), badTestFuture(1, success()) };
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try {
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wait(waitForMost(futures, 0, operation_failed(), 1.0));
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ASSERT(false);
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} catch (Error& e) {
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ASSERT_EQ(e.code(), error_code_operation_failed);
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}
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}
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return Void();
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}
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#if false
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TEST_CASE("/flow/genericactors/generic/storeTuple") {
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state std::vector<UID> resA;
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state int resB;
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state double resC;
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state Promise<std::tuple<std::vector<UID>, int, double>> promise;
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auto future = storeTuple(promise.getFuture(), resA, resB, resC);
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promise.send(std::make_tuple(std::vector<UID>(10), 15, 2.0));
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wait(ready(future));
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ASSERT(resA.size() == 10);
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ASSERT(resB == 15);
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ASSERT(resC == 2.0);
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return Void();
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}
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#endif
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