foundationdb/fdbserver/RestoreApplier.actor.cpp

777 lines
34 KiB
C++

/*
* RestoreApplier.actor.cpp
*
* 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.
*/
// This file defines the functions used by the RestoreApplier role.
// RestoreApplier role starts at restoreApplierCore actor
#include "fdbclient/NativeAPI.actor.h"
#include "fdbclient/SystemData.h"
#include "fdbclient/BackupAgent.actor.h"
#include "fdbclient/ManagementAPI.actor.h"
#include "fdbclient/MutationList.h"
#include "fdbclient/BackupContainer.h"
#include "fdbserver/Knobs.h"
#include "fdbserver/RestoreCommon.actor.h"
#include "fdbserver/RestoreUtil.h"
#include "fdbserver/RestoreRoleCommon.actor.h"
#include "fdbserver/RestoreApplier.actor.h"
#include "flow/actorcompiler.h" // This must be the last #include.
#include "flow/network.h"
ACTOR static Future<Void> handleSendMutationVectorRequest(RestoreSendVersionedMutationsRequest req,
Reference<RestoreApplierData> self);
ACTOR static Future<Void> handleApplyToDBRequest(RestoreVersionBatchRequest req, Reference<RestoreApplierData> self,
Database cx);
void handleUpdateRateRequest(RestoreUpdateRateRequest req, Reference<RestoreApplierData> self);
ACTOR Future<Void> restoreApplierCore(RestoreApplierInterface applierInterf, int nodeIndex, Database cx) {
state Reference<RestoreApplierData> self =
Reference<RestoreApplierData>(new RestoreApplierData(applierInterf.id(), nodeIndex));
state ActorCollection actors(false);
state Future<Void> exitRole = Never();
actors.add(updateProcessMetrics(self));
actors.add(traceProcessMetrics(self, "RestoreApplier"));
actors.add(traceRoleVersionBatchProgress(self, "RestoreApplier"));
loop {
state std::string requestTypeStr = "[Init]";
try {
choose {
when(RestoreSimpleRequest req = waitNext(applierInterf.heartbeat.getFuture())) {
requestTypeStr = "heartbeat";
actors.add(handleHeartbeat(req, applierInterf.id()));
}
when(RestoreSendVersionedMutationsRequest req =
waitNext(applierInterf.sendMutationVector.getFuture())) {
requestTypeStr = "sendMutationVector";
actors.add(handleSendMutationVectorRequest(req, self));
}
when(RestoreVersionBatchRequest req = waitNext(applierInterf.applyToDB.getFuture())) {
requestTypeStr = "applyToDB";
actors.add(handleApplyToDBRequest(
req, self, cx)); // TODO: Check how FDB uses TaskPriority for ACTORS. We may need to add
// priority here to avoid requests at later VB block requests at earlier VBs
}
when(RestoreUpdateRateRequest req = waitNext(applierInterf.updateRate.getFuture())) {
requestTypeStr = "updateRate";
handleUpdateRateRequest(req, self);
}
when(RestoreVersionBatchRequest req = waitNext(applierInterf.initVersionBatch.getFuture())) {
requestTypeStr = "initVersionBatch";
actors.add(handleInitVersionBatchRequest(req, self));
}
when(RestoreFinishRequest req = waitNext(applierInterf.finishRestore.getFuture())) {
requestTypeStr = "finishRestore";
actors.clear(false); // cancel all pending actors
handleFinishRestoreRequest(req, self);
if (req.terminate) {
exitRole = Void();
}
}
when(wait(actors.getResult())) {}
when(wait(exitRole)) {
TraceEvent("RestoreApplierCoreExitRole", self->id());
break;
}
}
//TraceEvent("RestoreApplierCore", self->id()).detail("Request", requestTypeStr); // For debug only
} catch (Error& e) {
bool isError = e.code() != error_code_operation_cancelled;
TraceEvent(isError ? SevError : SevWarnAlways, "FastRestoreApplierError", self->id())
.detail("RequestType", requestTypeStr)
.error(e, true);
actors.clear(false);
break;
}
}
return Void();
}
// The actor may be invoked multiple times and executed async.
// No race condition as long as we do not wait or yield when operate the shared
// data. Multiple such actors can run on different fileIDs.
// Different files may contain mutations of the same commit versions, but with
// different subsequence number.
// Only one actor can process mutations from the same file.
ACTOR static Future<Void> handleSendMutationVectorRequest(RestoreSendVersionedMutationsRequest req,
Reference<RestoreApplierData> self) {
state Reference<ApplierBatchData> batchData; // initialized as nullptr
state bool printTrace = false;
state NotifiedVersion* curMsgIndex = nullptr;
if (req.batchIndex <= self->finishedBatch.get()) { // Handle duplicate request from batchIndex that has finished
TraceEvent(SevWarn, "FastRestoreApplierRestoreSendVersionedMutationsRequestTooLate")
.detail("RequestBatchIndex", req.batchIndex)
.detail("FinishedBatchIndex", self->finishedBatch.get());
req.reply.send(RestoreCommonReply(self->id(), true));
ASSERT_WE_THINK(false); // Test to see if simulation can reproduce this
return Void();
}
batchData = self->batch[req.batchIndex];
ASSERT(batchData.isValid());
ASSERT(self->finishedBatch.get() < req.batchIndex);
// wait(delay(0.0, TaskPriority::RestoreApplierReceiveMutations)); // This hurts performance from 100MB/s to 60MB/s
// on circus
batchData->receiveMutationReqs += 1;
// Trace when the receive phase starts at a VB and when it finishes.
// This can help check if receiveMutations block applyMutation phase.
// If so, we need more sophisticated scheduler to ensure priority execution
printTrace = (batchData->receiveMutationReqs % SERVER_KNOBS->FASTRESTORE_NUM_TRACE_EVENTS == 0);
TraceEvent(printTrace ? SevInfo : SevFRDebugInfo, "FastRestoreApplierPhaseReceiveMutations", self->id())
.detail("BatchIndex", req.batchIndex)
.detail("RestoreAsset", req.asset.toString())
.detail("RestoreAssetMesssageIndex", batchData->processedFileState[req.asset].get())
.detail("Request", req.toString())
.detail("CurrentMemory", getSystemStatistics().processMemory)
.detail("PreviousVersionBatchState", batchData->vbState.get())
.detail("ReceiveMutationRequests", batchData->receiveMutationReqs);
wait(isSchedulable(self, req.batchIndex, __FUNCTION__));
ASSERT(batchData.isValid());
ASSERT(req.batchIndex > self->finishedBatch.get());
// Assume: processedFileState[req.asset] will not be erased while the actor is active.
// Note: Insert new items into processedFileState will not invalidate the reference.
curMsgIndex = &batchData->processedFileState[req.asset];
wait(curMsgIndex->whenAtLeast(req.msgIndex - 1));
batchData->vbState = ApplierVersionBatchState::RECEIVE_MUTATIONS;
state bool isDuplicated = true;
if (curMsgIndex->get() == req.msgIndex - 1) {
isDuplicated = false;
for (int mIndex = 0; mIndex < req.versionedMutations.size(); mIndex++) {
const VersionedMutation& versionedMutation = req.versionedMutations[mIndex];
TraceEvent(SevFRDebugInfo, "FastRestoreApplierPhaseReceiveMutations", self->id())
.detail("RestoreAsset", req.asset.toString())
.detail("Version", versionedMutation.version.toString())
.detail("Index", mIndex)
.detail("MutationReceived", versionedMutation.mutation.toString());
batchData->receivedBytes += versionedMutation.mutation.totalSize();
batchData->counters.receivedBytes += versionedMutation.mutation.totalSize();
batchData->counters.receivedWeightedBytes +=
versionedMutation.mutation.weightedTotalSize(); // atomicOp will be amplified
batchData->counters.receivedMutations += 1;
batchData->counters.receivedAtomicOps +=
isAtomicOp((MutationRef::Type)versionedMutation.mutation.type) ? 1 : 0;
// Sanity check
ASSERT_WE_THINK(req.asset.isInVersionRange(versionedMutation.version.version));
ASSERT_WE_THINK(req.asset.isInKeyRange(
versionedMutation.mutation)); // mutation is already applied removePrefix and addPrefix
// Note: Log and range mutations may be delivered out of order. Can we handle it?
batchData->addMutation(versionedMutation.mutation, versionedMutation.version);
ASSERT(versionedMutation.mutation.type != MutationRef::SetVersionstampedKey &&
versionedMutation.mutation.type != MutationRef::SetVersionstampedValue);
}
curMsgIndex->set(req.msgIndex);
}
req.reply.send(RestoreCommonReply(self->id(), isDuplicated));
TraceEvent(printTrace ? SevInfo : SevFRDebugInfo, "FastRestoreApplierPhaseReceiveMutationsDone", self->id())
.detail("BatchIndex", req.batchIndex)
.detail("RestoreAsset", req.asset.toString())
.detail("ProcessedMessageIndex", curMsgIndex->get())
.detail("Request", req.toString());
return Void();
}
// Clear all ranges in input ranges
ACTOR static Future<Void> applyClearRangeMutations(Standalone<VectorRef<KeyRangeRef>> ranges, double delayTime,
Database cx, UID applierID, int batchIndex,
ApplierBatchData::Counters* cc) {
state Reference<ReadYourWritesTransaction> tr(new ReadYourWritesTransaction(cx));
state int retries = 0;
state double numOps = 0;
wait(delay(delayTime + deterministicRandom()->random01() * delayTime));
TraceEvent(delayTime > 5 ? SevWarnAlways : SevDebug, "FastRestoreApplierClearRangeMutationsStart", applierID)
.detail("BatchIndex", batchIndex)
.detail("Ranges", ranges.size())
.detail("DelayTime", delayTime);
if (SERVER_KNOBS->FASTRESTORE_NOT_WRITE_DB) {
TraceEvent("FastRestoreApplierClearRangeMutationsNotWriteDB", applierID)
.detail("BatchIndex", batchIndex)
.detail("Ranges", ranges.size());
ASSERT(!g_network->isSimulated());
return Void();
}
loop {
try {
// TODO: Consider clearrange traffic in write traffic control
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
tr->setOption(FDBTransactionOptions::LOCK_AWARE);
for (auto& range : ranges) {
debugFRMutation("FastRestoreApplierApplyClearRangeMutation", 0,
MutationRef(MutationRef::ClearRange, range.begin, range.end));
tr->clear(range);
cc->clearOps += 1;
++numOps;
if (numOps >= SERVER_KNOBS->FASTRESTORE_TXN_CLEAR_MAX) {
TraceEvent(SevWarn, "FastRestoreApplierClearRangeMutationsTooManyClearsInTxn")
.suppressFor(5.0)
.detail("Clears", numOps)
.detail("Ranges", ranges.size())
.detail("Range", range.toString());
}
}
wait(tr->commit());
cc->clearTxns += 1;
break;
} catch (Error& e) {
retries++;
if (retries > SERVER_KNOBS->FASTRESTORE_TXN_RETRY_MAX) {
TraceEvent(SevWarnAlways, "RestoreApplierApplyClearRangeMutationsStuck", applierID)
.detail("BatchIndex", batchIndex)
.detail("ClearRanges", ranges.size())
.error(e);
}
wait(tr->onError(e));
}
}
return Void();
}
// Get keys in incompleteStagingKeys and precompute the stagingKey which is stored in batchData->stagingKeys
ACTOR static Future<Void> getAndComputeStagingKeys(
std::map<Key, std::map<Key, StagingKey>::iterator> incompleteStagingKeys, double delayTime, Database cx,
UID applierID, int batchIndex, ApplierBatchData::Counters* cc) {
state Reference<ReadYourWritesTransaction> tr(new ReadYourWritesTransaction(cx));
state std::vector<Future<Optional<Value>>> fValues(incompleteStagingKeys.size(), Never());
state int retries = 0;
state UID randomID = deterministicRandom()->randomUniqueID();
wait(delay(delayTime + deterministicRandom()->random01() * delayTime));
if (SERVER_KNOBS->FASTRESTORE_NOT_WRITE_DB) { // Get dummy value to short-circut DB
TraceEvent("FastRestoreApplierGetAndComputeStagingKeysStartNotUseDB", applierID)
.detail("RandomUID", randomID)
.detail("BatchIndex", batchIndex)
.detail("GetKeys", incompleteStagingKeys.size())
.detail("DelayTime", delayTime);
ASSERT(!g_network->isSimulated());
int i = 0;
for (auto& key : incompleteStagingKeys) {
MutationRef m(MutationRef::SetValue, key.first, LiteralStringRef("0"));
key.second->second.add(m, LogMessageVersion(1));
key.second->second.precomputeResult("GetAndComputeStagingKeys", applierID, batchIndex);
i++;
}
return Void();
}
TraceEvent("FastRestoreApplierGetAndComputeStagingKeysStart", applierID)
.detail("RandomUID", randomID)
.detail("BatchIndex", batchIndex)
.detail("GetKeys", incompleteStagingKeys.size())
.detail("DelayTime", delayTime);
loop {
try {
int i = 0;
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
tr->setOption(FDBTransactionOptions::LOCK_AWARE);
for (auto& key : incompleteStagingKeys) {
fValues[i++] = tr->get(key.first);
cc->fetchKeys += 1;
}
wait(waitForAll(fValues));
cc->fetchTxns += 1;
break;
} catch (Error& e) {
cc->fetchTxnRetries += 1;
if (retries++ > incompleteStagingKeys.size()) {
TraceEvent(SevWarnAlways, "GetAndComputeStagingKeys", applierID)
.suppressFor(1.0)
.detail("RandomUID", randomID)
.detail("BatchIndex", batchIndex)
.error(e);
}
wait(tr->onError(e));
}
}
ASSERT(fValues.size() == incompleteStagingKeys.size());
int i = 0;
for (auto& key : incompleteStagingKeys) {
if (!fValues[i].get().present()) { // Key not exist in DB
// if condition: fValues[i].Valid() && fValues[i].isReady() && !fValues[i].isError() &&
TraceEvent(SevDebug, "FastRestoreApplierGetAndComputeStagingKeysNoBaseValueInDB", applierID)
.suppressFor(5.0)
.detail("BatchIndex", batchIndex)
.detail("Key", key.first)
.detail("IsReady", fValues[i].isReady())
.detail("PendingMutations", key.second->second.pendingMutations.size())
.detail("StagingKeyType", getTypeString(key.second->second.type));
for (auto& vm : key.second->second.pendingMutations) {
TraceEvent(SevDebug, "FastRestoreApplierGetAndComputeStagingKeysNoBaseValueInDB")
.detail("PendingMutationVersion", vm.first.toString())
.detail("PendingMutation", vm.second.toString());
}
key.second->second.precomputeResult("GetAndComputeStagingKeysNoBaseValueInDB", applierID, batchIndex);
} else {
// The key's version ideally should be the most recently committed version.
// But as long as it is > 1 and less than the start version of the version batch, it is the same result.
MutationRef m(MutationRef::SetValue, key.first, fValues[i].get().get());
key.second->second.add(m, LogMessageVersion(1));
key.second->second.precomputeResult("GetAndComputeStagingKeys", applierID, batchIndex);
}
i++;
}
TraceEvent("FastRestoreApplierGetAndComputeStagingKeysDone", applierID)
.detail("RandomUID", randomID)
.detail("BatchIndex", batchIndex)
.detail("GetKeys", incompleteStagingKeys.size())
.detail("DelayTime", delayTime);
return Void();
}
ACTOR static Future<Void> precomputeMutationsResult(Reference<ApplierBatchData> batchData, UID applierID,
int64_t batchIndex, Database cx) {
// Apply range mutations (i.e., clearRange) to database cx
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResultStart", applierID)
.detail("BatchIndex", batchIndex)
.detail("Step", "Applying clear range mutations to DB")
.detail("ClearRanges", batchData->stagingKeyRanges.size());
state std::vector<Future<Void>> fClearRanges;
Standalone<VectorRef<KeyRangeRef>> clearRanges;
double curTxnSize = 0;
double delayTime = 0;
for (auto& rangeMutation : batchData->stagingKeyRanges) {
KeyRangeRef range(rangeMutation.mutation.param1, rangeMutation.mutation.param2);
debugFRMutation("FastRestoreApplierPrecomputeMutationsResultClearRange", rangeMutation.version.version,
MutationRef(MutationRef::ClearRange, range.begin, range.end));
clearRanges.push_back_deep(clearRanges.arena(), range);
curTxnSize += range.expectedSize();
if (curTxnSize >= SERVER_KNOBS->FASTRESTORE_TXN_BATCH_MAX_BYTES) {
fClearRanges.push_back(
applyClearRangeMutations(clearRanges, delayTime, cx, applierID, batchIndex, &batchData->counters));
delayTime += SERVER_KNOBS->FASTRESTORE_TXN_EXTRA_DELAY;
clearRanges = Standalone<VectorRef<KeyRangeRef>>();
curTxnSize = 0;
}
}
if (curTxnSize > 0) {
fClearRanges.push_back(
applyClearRangeMutations(clearRanges, delayTime, cx, applierID, batchIndex, &batchData->counters));
}
// Apply range mutations (i.e., clearRange) to stagingKeyRanges
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResult", applierID)
.detail("BatchIndex", batchIndex)
.detail("Step", "Applying clear range mutations to staging keys")
.detail("ClearRanges", batchData->stagingKeyRanges.size())
.detail("FutureClearRanges", fClearRanges.size());
for (auto& rangeMutation : batchData->stagingKeyRanges) {
ASSERT(rangeMutation.mutation.param1 <= rangeMutation.mutation.param2);
std::map<Key, StagingKey>::iterator lb = batchData->stagingKeys.lower_bound(rangeMutation.mutation.param1);
std::map<Key, StagingKey>::iterator ub = batchData->stagingKeys.lower_bound(rangeMutation.mutation.param2);
while (lb != ub) {
if (lb->first >= rangeMutation.mutation.param2) {
TraceEvent(SevError, "FastRestoreApplerPhasePrecomputeMutationsResultIncorrectUpperBound")
.detail("Key", lb->first)
.detail("ClearRangeUpperBound", rangeMutation.mutation.param2)
.detail("UsedUpperBound", ub->first);
}
// We make the beginKey = endKey for the ClearRange on purpose so that
// we can sanity check ClearRange mutation when we apply it to DB.
MutationRef clearKey(MutationRef::ClearRange, lb->first, lb->first);
lb->second.add(clearKey, rangeMutation.version);
lb++;
}
}
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResult", applierID)
.detail("BatchIndex", batchIndex)
.detail("Step", "Wait on applying clear range mutations to DB")
.detail("FutureClearRanges", fClearRanges.size());
wait(waitForAll(fClearRanges));
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResult", applierID)
.detail("BatchIndex", batchIndex)
.detail("Step", "Getting and computing staging keys")
.detail("StagingKeys", batchData->stagingKeys.size());
// Get keys in stagingKeys which does not have a baseline key by reading database cx, and precompute the key's value
std::vector<Future<Void>> fGetAndComputeKeys;
std::map<Key, std::map<Key, StagingKey>::iterator> incompleteStagingKeys;
std::map<Key, StagingKey>::iterator stagingKeyIter = batchData->stagingKeys.begin();
int numKeysInBatch = 0;
int numGetTxns = 0;
double delayTime = 0; // Start transactions at different time to avoid overwhelming FDB.
for (; stagingKeyIter != batchData->stagingKeys.end(); stagingKeyIter++) {
if (!stagingKeyIter->second.hasBaseValue()) {
incompleteStagingKeys.emplace(stagingKeyIter->first, stagingKeyIter);
numKeysInBatch++;
}
if (numKeysInBatch == SERVER_KNOBS->FASTRESTORE_APPLIER_FETCH_KEYS_SIZE) {
fGetAndComputeKeys.push_back(getAndComputeStagingKeys(incompleteStagingKeys, delayTime, cx, applierID,
batchIndex, &batchData->counters));
numGetTxns++;
delayTime += SERVER_KNOBS->FASTRESTORE_TXN_EXTRA_DELAY;
numKeysInBatch = 0;
incompleteStagingKeys.clear();
}
}
if (numKeysInBatch > 0) {
numGetTxns++;
fGetAndComputeKeys.push_back(getAndComputeStagingKeys(incompleteStagingKeys, delayTime, cx, applierID,
batchIndex, &batchData->counters));
}
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResult", applierID)
.detail("BatchIndex", batchIndex)
.detail("Step", "Compute the other staging keys")
.detail("StagingKeys", batchData->stagingKeys.size())
.detail("GetStagingKeyBatchTxns", numGetTxns);
// Pre-compute pendingMutations to other keys in stagingKeys that has base value
for (stagingKeyIter = batchData->stagingKeys.begin(); stagingKeyIter != batchData->stagingKeys.end();
stagingKeyIter++) {
if (stagingKeyIter->second.hasBaseValue()) {
stagingKeyIter->second.precomputeResult("HasBaseValue", applierID, batchIndex);
}
}
TraceEvent("FastRestoreApplierGetAndComputeStagingKeysWaitOn", applierID);
wait(waitForAll(fGetAndComputeKeys));
// Sanity check all stagingKeys have been precomputed
ASSERT_WE_THINK(batchData->allKeysPrecomputed());
TraceEvent("FastRestoreApplerPhasePrecomputeMutationsResultDone", applierID).detail("BatchIndex", batchIndex);
return Void();
}
bool okToReleaseTxns(double targetMB, double applyingDataBytes) {
return applyingDataBytes < targetMB * 1024 * 1024;
}
ACTOR static Future<Void> shouldReleaseTransaction(double* targetMB, double* applyingDataBytes,
AsyncTrigger* releaseTxns) {
loop {
if (okToReleaseTxns(*targetMB, *applyingDataBytes)) {
break;
} else {
wait(releaseTxns->onTrigger());
wait(delay(0.0)); // Avoid all waiting txns are triggered at the same time and all decide to proceed before
// applyingDataBytes has a chance to update
}
}
return Void();
}
// Apply mutations in batchData->stagingKeys [begin, end).
ACTOR static Future<Void> applyStagingKeysBatch(std::map<Key, StagingKey>::iterator begin,
std::map<Key, StagingKey>::iterator end, Database cx, UID applierID,
ApplierBatchData::Counters* cc, double* appliedBytes,
double* applyingDataBytes, double* targetMB,
AsyncTrigger* releaseTxnTrigger) {
if (SERVER_KNOBS->FASTRESTORE_NOT_WRITE_DB) {
TraceEvent("FastRestoreApplierPhaseApplyStagingKeysBatchSkipped", applierID).detail("Begin", begin->first);
ASSERT(!g_network->isSimulated());
return Void();
}
wait(shouldReleaseTransaction(targetMB, applyingDataBytes, releaseTxnTrigger));
state Reference<ReadYourWritesTransaction> tr(new ReadYourWritesTransaction(cx));
state int sets = 0;
state int clears = 0;
state Key endKey = begin->first;
state double txnSize = 0;
state double txnSizeUsed = 0; // txn size accounted in applyingDataBytes
TraceEvent(SevFRDebugInfo, "FastRestoreApplierPhaseApplyStagingKeysBatch", applierID).detail("Begin", begin->first);
loop {
try {
txnSize = 0;
txnSizeUsed = 0;
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
tr->setOption(FDBTransactionOptions::LOCK_AWARE);
std::map<Key, StagingKey>::iterator iter = begin;
while (iter != end) {
if (iter->second.type == MutationRef::SetValue) {
tr->set(iter->second.key, iter->second.val);
txnSize += iter->second.totalSize();
cc->appliedMutations += 1;
TraceEvent(SevFRMutationInfo, "FastRestoreApplierPhaseApplyStagingKeysBatch", applierID)
.detail("SetKey", iter->second.key);
sets++;
} else if (iter->second.type == MutationRef::ClearRange) {
if (iter->second.key != iter->second.val) {
TraceEvent(SevError, "FastRestoreApplierPhaseApplyStagingKeysBatchClearTooMuchData", applierID)
.detail("KeyBegin", iter->second.key)
.detail("KeyEnd", iter->second.val)
.detail("Version", iter->second.version.version)
.detail("SubVersion", iter->second.version.sub);
}
tr->clear(singleKeyRange(iter->second.key));
txnSize += iter->second.totalSize();
cc->appliedMutations += 1;
TraceEvent(SevFRMutationInfo, "FastRestoreApplierPhaseApplyStagingKeysBatch", applierID)
.detail("ClearKey", iter->second.key);
clears++;
} else {
ASSERT(false);
}
endKey = iter != end ? iter->first : endKey;
iter++;
if (sets > 10000000 || clears > 10000000) {
TraceEvent(SevError, "FastRestoreApplierPhaseApplyStagingKeysBatchInfiniteLoop", applierID)
.detail("Begin", begin->first)
.detail("Sets", sets)
.detail("Clears", clears);
}
}
TraceEvent(SevFRDebugInfo, "FastRestoreApplierPhaseApplyStagingKeysBatchPrecommit", applierID)
.detail("Begin", begin->first)
.detail("End", endKey)
.detail("Sets", sets)
.detail("Clears", clears);
tr->addWriteConflictRange(KeyRangeRef(begin->first, keyAfter(endKey))); // Reduce resolver load
txnSizeUsed = txnSize;
*applyingDataBytes += txnSizeUsed; // Must account for applying bytes before wait for write traffic control
wait(tr->commit());
cc->appliedTxns += 1;
cc->appliedBytes += txnSize;
*appliedBytes += txnSize;
*applyingDataBytes -= txnSizeUsed;
if (okToReleaseTxns(*targetMB, *applyingDataBytes)) {
releaseTxnTrigger->trigger();
}
break;
} catch (Error& e) {
cc->appliedTxnRetries += 1;
wait(tr->onError(e));
*applyingDataBytes -= txnSizeUsed;
}
}
return Void();
}
// Apply mutations in stagingKeys in batches in parallel
ACTOR static Future<Void> applyStagingKeys(Reference<ApplierBatchData> batchData, UID applierID, int64_t batchIndex,
Database cx) {
std::map<Key, StagingKey>::iterator begin = batchData->stagingKeys.begin();
std::map<Key, StagingKey>::iterator cur = begin;
state int txnBatches = 0;
double txnSize = 0;
std::vector<Future<Void>> fBatches;
TraceEvent("FastRestoreApplerPhaseApplyStagingKeysStart", applierID)
.detail("BatchIndex", batchIndex)
.detail("StagingKeys", batchData->stagingKeys.size());
batchData->totalBytesToWrite = 0;
while (cur != batchData->stagingKeys.end()) {
txnSize += cur->second.totalSize(); // should be consistent with receivedBytes accounting method
if (txnSize > SERVER_KNOBS->FASTRESTORE_TXN_BATCH_MAX_BYTES) {
fBatches.push_back(applyStagingKeysBatch(begin, cur, cx, applierID, &batchData->counters,
&batchData->appliedBytes, &batchData->applyingDataBytes,
&batchData->targetWriteRateMB, &batchData->releaseTxnTrigger));
batchData->totalBytesToWrite += txnSize;
begin = cur;
txnSize = 0;
txnBatches++;
}
cur++;
}
if (begin != batchData->stagingKeys.end()) {
fBatches.push_back(applyStagingKeysBatch(begin, cur, cx, applierID, &batchData->counters,
&batchData->appliedBytes, &batchData->applyingDataBytes,
&batchData->targetWriteRateMB, &batchData->releaseTxnTrigger));
batchData->totalBytesToWrite += txnSize;
txnBatches++;
}
wait(waitForAll(fBatches));
TraceEvent("FastRestoreApplerPhaseApplyStagingKeysDone", applierID)
.detail("BatchIndex", batchIndex)
.detail("StagingKeys", batchData->stagingKeys.size())
.detail("TransactionBatches", txnBatches)
.detail("TotalBytesToWrite", batchData->totalBytesToWrite);
return Void();
}
// Write mutations to the destination DB
ACTOR Future<Void> writeMutationsToDB(UID applierID, int64_t batchIndex, Reference<ApplierBatchData> batchData,
Database cx) {
TraceEvent("FastRestoreApplierPhaseApplyTxnStart", applierID).detail("BatchIndex", batchIndex);
wait(precomputeMutationsResult(batchData, applierID, batchIndex, cx));
wait(applyStagingKeys(batchData, applierID, batchIndex, cx));
TraceEvent("FastRestoreApplierPhaseApplyTxnDone", applierID)
.detail("BatchIndex", batchIndex)
.detail("AppliedBytes", batchData->appliedBytes)
.detail("ReceivedBytes", batchData->receivedBytes);
return Void();
}
void handleUpdateRateRequest(RestoreUpdateRateRequest req, Reference<RestoreApplierData> self) {
TraceEvent ev("FastRestoreApplierUpdateRateRequest", self->id());
ev.suppressFor(10)
.detail("BatchIndex", req.batchIndex)
.detail("FinishedBatch", self->finishedBatch.get())
.detail("WriteMB", req.writeMB);
double remainingDataMB = 0;
if (self->finishedBatch.get() == req.batchIndex - 1) { // current applying batch
Reference<ApplierBatchData> batchData = self->batch[req.batchIndex];
ASSERT(batchData.isValid());
batchData->targetWriteRateMB = req.writeMB;
remainingDataMB = batchData->totalBytesToWrite > 0
? std::max(0.0, batchData->totalBytesToWrite - batchData->appliedBytes) / 1024 / 1024
: batchData->receivedBytes / 1024 / 1024;
ev.detail("TotalBytesToWrite", batchData->totalBytesToWrite)
.detail("AppliedBytes", batchData->appliedBytes)
.detail("ReceivedBytes", batchData->receivedBytes)
.detail("TargetWriteRateMB", batchData->targetWriteRateMB)
.detail("RemainingDataMB", remainingDataMB);
}
req.reply.send(RestoreUpdateRateReply(self->id(), remainingDataMB));
return;
}
ACTOR static Future<Void> traceRate(const char* context, Reference<ApplierBatchData> batchData, int batchIndex,
UID nodeID, NotifiedVersion* finishedVB, bool once = false) {
loop {
if ((finishedVB->get() != batchIndex - 1) || !batchData.isValid()) {
break;
}
TraceEvent(context, nodeID)
.suppressFor(10)
.detail("BatchIndex", batchIndex)
.detail("FinishedBatchIndex", finishedVB->get())
.detail("TotalDataToWriteMB", batchData->totalBytesToWrite / 1024 / 1024)
.detail("AppliedBytesMB", batchData->appliedBytes / 1024 / 1024)
.detail("TargetBytesMB", batchData->targetWriteRateMB)
.detail("InflightBytesMB", batchData->applyingDataBytes)
.detail("ReceivedBytes", batchData->receivedBytes);
if (once) {
break;
}
wait(delay(5.0));
}
return Void();
}
ACTOR static Future<Void> handleApplyToDBRequest(RestoreVersionBatchRequest req, Reference<RestoreApplierData> self,
Database cx) {
TraceEvent("FastRestoreApplierPhaseHandleApplyToDBStart", self->id())
.detail("BatchIndex", req.batchIndex)
.detail("FinishedBatch", self->finishedBatch.get());
// Ensure batch (i-1) is applied before batch i
// TODO: Add a counter to warn when too many requests are waiting on the actor
wait(self->finishedBatch.whenAtLeast(req.batchIndex - 1));
state bool isDuplicated = true;
if (self->finishedBatch.get() == req.batchIndex - 1) {
// duplicate request from earlier version batch will be ignored
state Reference<ApplierBatchData> batchData = self->batch[req.batchIndex];
ASSERT(batchData.isValid());
TraceEvent("FastRestoreApplierPhaseHandleApplyToDBRunning", self->id())
.detail("BatchIndex", req.batchIndex)
.detail("FinishedBatch", self->finishedBatch.get())
.detail("HasStarted", batchData->dbApplier.present())
.detail("WroteToDBDone", batchData->dbApplier.present() ? batchData->dbApplier.get().isReady() : 0)
.detail("PreviousVersionBatchState", batchData->vbState.get());
ASSERT(batchData.isValid());
if (!batchData->dbApplier.present()) {
isDuplicated = false;
batchData->dbApplier = Never();
batchData->dbApplier = writeMutationsToDB(self->id(), req.batchIndex, batchData, cx);
batchData->vbState = ApplierVersionBatchState::WRITE_TO_DB;
batchData->rateTracer = traceRate("FastRestoreApplierTransactionRateControl", batchData, req.batchIndex,
self->id(), &self->finishedBatch);
}
ASSERT(batchData->dbApplier.present());
ASSERT(!batchData->dbApplier.get().isError()); // writeMutationsToDB actor cannot have error.
// We cannot blindly retry because it is not idempodent
wait(batchData->dbApplier.get());
// Multiple actors can wait on req.batchIndex-1;
// Avoid setting finishedBatch when finishedBatch > req.batchIndex
if (self->finishedBatch.get() == req.batchIndex - 1) {
batchData->rateTracer =
traceRate("FastRestoreApplierTransactionRateControlDone", batchData, req.batchIndex, self->id(),
&self->finishedBatch, true /*print once*/); // Track the last rate info
self->finishedBatch.set(req.batchIndex);
// self->batch[req.batchIndex]->vbState = ApplierVersionBatchState::DONE;
// Free memory for the version batch
self->batch.erase(req.batchIndex);
if (self->delayedActors > 0) {
self->checkMemory.trigger();
}
}
}
req.reply.send(RestoreCommonReply(self->id(), isDuplicated));
TraceEvent("FastRestoreApplierPhaseHandleApplyToDBDone", self->id())
.detail("BatchIndex", req.batchIndex)
.detail("FinishedBatch", self->finishedBatch.get())
.detail("IsDuplicated", isDuplicated);
return Void();
}
// Copy from WriteDuringRead.actor.cpp with small modifications
// Not all AtomicOps are handled in this function: SetVersionstampedKey, SetVersionstampedValue, and CompareAndClear
Value applyAtomicOp(Optional<StringRef> existingValue, Value value, MutationRef::Type type) {
Arena arena;
if (type == MutationRef::AddValue)
return doLittleEndianAdd(existingValue, value, arena);
else if (type == MutationRef::AppendIfFits)
return doAppendIfFits(existingValue, value, arena);
else if (type == MutationRef::And || type == MutationRef::AndV2)
return doAndV2(existingValue, value, arena);
else if (type == MutationRef::Or)
return doOr(existingValue, value, arena);
else if (type == MutationRef::Xor)
return doXor(existingValue, value, arena);
else if (type == MutationRef::Max)
return doMax(existingValue, value, arena);
else if (type == MutationRef::Min || type == MutationRef::MinV2)
return doMinV2(existingValue, value, arena);
else if (type == MutationRef::ByteMin)
return doByteMin(existingValue, value, arena);
else if (type == MutationRef::ByteMax)
return doByteMax(existingValue, value, arena);
else {
TraceEvent(SevError, "ApplyAtomicOpUnhandledType")
.detail("TypeCode", (int)type)
.detail("TypeName", getTypeString(type));
ASSERT(false);
}
return Value();
}