foundationdb/fdbrpc/LoadBalance.actor.h

413 lines
14 KiB
C++

/*
* LoadBalance.actor.h
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* 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.
*/
#pragma once
// When actually compiled (NO_INTELLISENSE), include the generated version of this file. In intellisense use the source version.
#if defined(NO_INTELLISENSE) && !defined(FLOW_LOADBALANCE_ACTOR_G_H)
#define FLOW_LOADBALANCE_ACTOR_G_H
#include "fdbrpc/LoadBalance.actor.g.h"
#elif !defined(FLOW_LOADBALANCE_ACTOR_H)
#define FLOW_LOADBALANCE_ACTOR_H
#include "flow/flow.h"
#include "flow/Knobs.h"
#include "fdbrpc/FailureMonitor.h"
#include "fdbrpc/fdbrpc.h"
#include "fdbrpc/Locality.h"
#include "fdbrpc/QueueModel.h"
#include "fdbrpc/MultiInterface.h"
#include "flow/actorcompiler.h" // This must be the last #include.
using std::vector;
struct ModelHolder : NonCopyable, public ReferenceCounted<ModelHolder> {
QueueModel* model;
bool released;
double startTime;
double delta;
uint64_t token;
ModelHolder( QueueModel* model, uint64_t token ) : model(model), token(token), released(false), startTime(now()) {
if(model) {
delta = model->addRequest(token);
}
}
void release(bool clean, bool futureVersion, double penalty, bool measureLatency = true) {
if(model && !released) {
released = true;
double latency = (clean || measureLatency) ? now() - startTime : 0.0;
model->endRequest(token, latency, penalty, delta, clean, futureVersion);
}
}
~ModelHolder() {
release(false, false, -1.0, false);
}
};
struct LoadBalancedReply {
double penalty;
LoadBalancedReply() : penalty(1.0) {}
template <class Ar>
void serialize(Ar &ar) {
serializer(ar, penalty);
}
};
Optional<LoadBalancedReply> getLoadBalancedReply(LoadBalancedReply *reply);
Optional<LoadBalancedReply> getLoadBalancedReply(void*);
// Returns true if we got a value for our request
// Throws an error if the request returned an error that should bubble out
// Returns false if we got an error that should result in reissuing the request
template <class T>
bool checkAndProcessResult(ErrorOr<T> result, Reference<ModelHolder> holder, bool atMostOnce, bool triedAllOptions) {
int errCode = result.isError() ? result.getError().code() : error_code_success;
bool maybeDelivered = errCode == error_code_broken_promise || errCode == error_code_request_maybe_delivered;
bool receivedResponse = result.present() || (!maybeDelivered && errCode != error_code_process_behind);
bool futureVersion = errCode == error_code_future_version || errCode == error_code_process_behind;
Optional<LoadBalancedReply> loadBalancedReply;
if(!result.isError()) {
loadBalancedReply = getLoadBalancedReply(&result.get());
}
holder->release(receivedResponse, futureVersion, loadBalancedReply.present() ? loadBalancedReply.get().penalty : -1.0);
if(result.present()) {
return true;
}
if(receivedResponse) {
throw result.getError();
}
if(atMostOnce && maybeDelivered) {
throw request_maybe_delivered();
}
if(triedAllOptions && errCode == error_code_process_behind) {
throw future_version();
}
return false;
}
ACTOR template <class Request>
Future<Optional<REPLY_TYPE(Request)>> makeRequest(RequestStream<Request> const* stream, Request request, double backoff, Future<Void> requestUnneeded, QueueModel *model, bool isFirstRequest, bool atMostOnce, bool triedAllOptions) {
if(backoff > 0.0) {
wait(delay(backoff) || requestUnneeded);
}
if(requestUnneeded.isReady()) {
return Optional<REPLY_TYPE(Request)>();
}
state Reference<ModelHolder> holder(new ModelHolder(model, stream->getEndpoint().token.first()));
ErrorOr<REPLY_TYPE(Request)> result = wait(stream->tryGetReply(request));
if(checkAndProcessResult(result, holder, atMostOnce, triedAllOptions)) {
return result.get();
}
else {
return Optional<REPLY_TYPE(Request)>();
}
}
template <class Reply>
void addLaggingRequest(Future<Optional<Reply>> reply, Promise<Void> requestFinished, QueueModel *model) {
requestFinished.send(Void());
if(!reply.isReady()) {
if(model) {
if(model->laggingRequestCount > FLOW_KNOBS->MAX_LAGGING_REQUESTS_OUTSTANDING || model->laggingRequests.isReady()) {
model->laggingRequests.cancel();
model->laggingRequestCount = 0;
model->addActor = PromiseStream<Future<Void>>();
model->laggingRequests = actorCollection( model->addActor.getFuture(), &model->laggingRequestCount );
}
model->addActor.send(success(errorOr(reply)));
}
}
}
// Keep trying to get a reply from any of servers until success or cancellation; tries to take into account
// failMon's information for load balancing and avoiding failed servers
// If ALL the servers are failed and the list of servers is not fresh, throws an exception to let the caller refresh the list of servers
ACTOR template <class Interface, class Request, class Multi>
Future< REPLY_TYPE(Request) > loadBalance(
Reference<MultiInterface<Multi>> alternatives,
RequestStream<Request> Interface::* channel,
Request request = Request(),
int taskID = TaskDefaultPromiseEndpoint,
bool atMostOnce = false, // if true, throws request_maybe_delivered() instead of retrying automatically
QueueModel* model = NULL)
{
state Future<Optional<REPLY_TYPE(Request)>> firstRequest;
state Optional<uint64_t> firstRequestEndpoint;
state Future<Optional<REPLY_TYPE(Request)>> secondRequest;
state Future<Void> secondDelay = Never();
state Promise<Void> requestFinished;
setReplyPriority(request, taskID);
if (!alternatives)
return Never();
ASSERT( alternatives->size() );
state int bestAlt = g_random->randomInt(0, alternatives->countBest());
state int nextAlt = g_random->randomInt(0, std::max(alternatives->size() - 1,1));
if( nextAlt >= bestAlt )
nextAlt++;
if(model) {
double bestMetric = 1e9;
double nextMetric = 1e9;
double bestTime = 1e9;
double nextTime = 1e9;
for(int i=0; i<alternatives->size(); i++) {
if(bestMetric < 1e8 && i == alternatives->countBest()) {
break;
}
RequestStream<Request> const* thisStream = &alternatives->get( i, channel );
if (!IFailureMonitor::failureMonitor().getState( thisStream->getEndpoint() ).failed) {
auto& qd = model->getMeasurement(thisStream->getEndpoint().token.first());
if(now() > qd.failedUntil) {
double thisMetric = qd.smoothOutstanding.smoothTotal();
double thisTime = qd.latency;
if(thisMetric < bestMetric) {
if(i != bestAlt) {
nextAlt = bestAlt;
nextMetric = bestMetric;
nextTime = bestTime;
}
bestAlt = i;
bestMetric = thisMetric;
bestTime = thisTime;
} else if( thisMetric < nextMetric ) {
nextAlt = i;
nextMetric = thisMetric;
nextTime = thisTime;
}
}
}
}
if( nextMetric > 1e8 ) {
for(int i=alternatives->countBest(); i<alternatives->size(); i++) {
RequestStream<Request> const* thisStream = &alternatives->get( i, channel );
if (!IFailureMonitor::failureMonitor().getState( thisStream->getEndpoint() ).failed) {
auto& qd = model->getMeasurement(thisStream->getEndpoint().token.first());
if(now() > qd.failedUntil) {
double thisMetric = qd.smoothOutstanding.smoothTotal();
double thisTime = qd.latency;
if( thisMetric < nextMetric ) {
nextAlt = i;
nextMetric = thisMetric;
nextTime = thisTime;
}
}
}
}
}
if(nextTime < 1e9) {
if(bestTime > FLOW_KNOBS->INSTANT_SECOND_REQUEST_MULTIPLIER*(model->secondMultiplier*(nextTime) + FLOW_KNOBS->BASE_SECOND_REQUEST_TIME)) {
secondDelay = Void();
} else {
secondDelay = delay( model->secondMultiplier*nextTime + FLOW_KNOBS->BASE_SECOND_REQUEST_TIME );
}
}
else {
secondDelay = Never();
}
}
state int startAlt = nextAlt;
state int startDistance = (bestAlt+alternatives->size()-startAlt) % alternatives->size();
state int numAttempts = 0;
state double backoff = 0;
state bool triedAllOptions = false;
loop {
// Find an alternative, if any, that is not failed, starting with nextAlt
state RequestStream<Request> const* stream = NULL;
for(int alternativeNum=0; alternativeNum<alternatives->size(); alternativeNum++) {
int useAlt = nextAlt;
if( nextAlt == startAlt )
useAlt = bestAlt;
else if( (nextAlt+alternatives->size()-startAlt) % alternatives->size() <= startDistance )
useAlt = (nextAlt+alternatives->size()-1) % alternatives->size();
stream = &alternatives->get( useAlt, channel );
if (!IFailureMonitor::failureMonitor().getState( stream->getEndpoint() ).failed && (!firstRequestEndpoint.present() || stream->getEndpoint().token.first() != firstRequestEndpoint.get()))
break;
nextAlt = (nextAlt+1) % alternatives->size();
if(nextAlt == startAlt) triedAllOptions = true;
stream=NULL;
}
if(!stream && !firstRequest.isValid() ) {
// Everything is down! Wait for someone to be up.
vector<Future<Void>> ok( alternatives->size() );
for(int i=0; i<ok.size(); i++) {
ok[i] = IFailureMonitor::failureMonitor().onStateEqual( alternatives->get(i, channel).getEndpoint(), FailureStatus(false) );
}
if(!alternatives->alwaysFresh()) {
if(now() - g_network->networkMetrics.newestAlternativesFailure > FLOW_KNOBS->ALTERNATIVES_FAILURE_RESET_TIME) {
g_network->networkMetrics.oldestAlternativesFailure = now();
}
double delay = std::max(std::min((now()-g_network->networkMetrics.oldestAlternativesFailure)*FLOW_KNOBS->ALTERNATIVES_FAILURE_DELAY_RATIO, FLOW_KNOBS->ALTERNATIVES_FAILURE_MAX_DELAY), FLOW_KNOBS->ALTERNATIVES_FAILURE_MIN_DELAY);
// Making this SevWarn means a lot of clutter
if(now() - g_network->networkMetrics.newestAlternativesFailure > 1 || g_random->random01() < 0.01) {
TraceEvent("AllAlternativesFailed")
.detail("Interval", FLOW_KNOBS->CACHE_REFRESH_INTERVAL_WHEN_ALL_ALTERNATIVES_FAILED)
.detail("Alternatives", alternatives->description())
.detail("Delay", delay);
}
g_network->networkMetrics.newestAlternativesFailure = now();
choose {
when ( wait( quorum( ok, 1 ) ) ) {}
when ( wait( ::delayJittered( delay ) ) ) {
throw all_alternatives_failed();
}
}
} else {
wait( quorum( ok, 1 ) );
}
numAttempts = 0; // now that we've got a server back, reset the backoff
} else if(!stream) {
//Only the first location is available.
Optional<REPLY_TYPE(Request)> result = wait( firstRequest );
if(result.present()) {
return result.get();
}
firstRequest = Future<Optional<REPLY_TYPE(Request)>>();
firstRequestEndpoint = Optional<uint64_t>();
} else if( firstRequest.isValid() ) {
//Issue a second request, the first one is taking a long time.
secondRequest = makeRequest(stream, request, backoff, requestFinished.getFuture(), model, false, atMostOnce, triedAllOptions);
state bool firstFinished = false;
loop {
choose {
when(ErrorOr<Optional<REPLY_TYPE(Request)>> result = wait( firstRequest.isValid() ? errorOr(firstRequest) : Never() )) {
if(result.isError() || result.get().present()) {
addLaggingRequest(secondRequest, requestFinished, model);
if(result.isError()) {
throw result.getError();
}
else {
return result.get().get();
}
}
firstRequest = Future<Optional<REPLY_TYPE(Request)>>();
firstRequestEndpoint = Optional<uint64_t>();
firstFinished = true;
}
when(ErrorOr<Optional<REPLY_TYPE(Request)>> result = wait( errorOr(secondRequest) )) {
if(result.isError() || result.get().present()) {
if(!firstFinished) {
addLaggingRequest(firstRequest, requestFinished, model);
}
if(result.isError()) {
throw result.getError();
}
else {
return result.get().get();
}
}
break;
}
}
}
if(++numAttempts >= alternatives->size()) {
backoff = std::min(FLOW_KNOBS->LOAD_BALANCE_MAX_BACKOFF, std::max(FLOW_KNOBS->LOAD_BALANCE_START_BACKOFF, backoff * FLOW_KNOBS->LOAD_BALANCE_BACKOFF_RATE));
}
} else {
//Issue a request, if it takes too long to get a reply, go around the loop
firstRequest = makeRequest(stream, request, backoff, requestFinished.getFuture(), model, true, atMostOnce, triedAllOptions);
firstRequestEndpoint = stream->getEndpoint().token.first();
loop {
choose {
when(ErrorOr<Optional<REPLY_TYPE(Request)>> result = wait( errorOr(firstRequest) )) {
if(model) {
model->secondMultiplier = std::max(model->secondMultiplier-FLOW_KNOBS->SECOND_REQUEST_MULTIPLIER_DECAY, 1.0);
model->secondBudget = std::min(model->secondBudget+FLOW_KNOBS->SECOND_REQUEST_BUDGET_GROWTH, FLOW_KNOBS->SECOND_REQUEST_MAX_BUDGET);
}
if(result.isError()) {
throw result.getError();
}
if(result.get().present()) {
return result.get().get();
}
firstRequest = Future<Optional<REPLY_TYPE(Request)>>();
firstRequestEndpoint = Optional<uint64_t>();
break;
}
when(wait(secondDelay)) {
secondDelay = Never();
if(model && model->secondBudget >= 1.0) {
model->secondMultiplier += FLOW_KNOBS->SECOND_REQUEST_MULTIPLIER_GROWTH;
model->secondBudget -= 1.0;
break;
}
}
}
}
if(++numAttempts >= alternatives->size()) {
backoff = std::min(FLOW_KNOBS->LOAD_BALANCE_MAX_BACKOFF, std::max(FLOW_KNOBS->LOAD_BALANCE_START_BACKOFF, backoff * FLOW_KNOBS->LOAD_BALANCE_BACKOFF_RATE));
}
}
nextAlt = (nextAlt+1) % alternatives->size();
if(nextAlt == startAlt) triedAllOptions = true;
resetReply(request, taskID);
secondDelay = Never();
}
}
#include "flow/unactorcompiler.h"
#endif