wbtiger
/
foundationdb
mirror of https://github.com/apple/foundationdb.git
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity

Refactor throttle command

This commit is contained in:
Chaoguang Lin 2021-07-27 17:58:11 +00:00
parent d49bd6807f
commit 28128d79b1
4 changed files with 651 additions and 296 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
fdbcli/CMakeLists.txt
View File

@ -8,6 +8,7 @@ set(FDBCLI_SRCS
ForceRecoveryWithDataLossCommand.actor.cpp
MaintenanceCommand.actor.cpp
SnapshotCommand.actor.cpp
ThrottleCommand.actor.cpp
Util.cpp
linenoise/linenoise.h)

645
fdbcli/ThrottleCommand.actor.cpp Normal file
View File

@ -0,0 +1,645 @@
/*
* ThrottleCommand.actor.cpp
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2021 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.
*/
#include "fdbcli/fdbcli.actor.h"
#include "fdbclient/IClientApi.h"
#include "fdbclient/TagThrottle.h"
#include "fdbclient/Knobs.h"
#include "fdbclient/SystemData.h"
#include "fdbclient/CommitTransaction.h"
#include "flow/Arena.h"
#include "flow/FastRef.h"
#include "flow/ThreadHelper.actor.h"
#include "flow/genericactors.actor.h"
#include "flow/actorcompiler.h" // This must be the last #include.
namespace {
// Helper functions copied from TagThrottle.actor.cpp
// The only difference is transactions are changed to go through MultiversionTransaction,
// instead of the native Transaction(i.e., RYWTransaction)
ACTOR Future<bool> getValidAutoEnabled(Reference<ITransaction> tr) {
state bool result;
loop {
Optional<Value> value = wait(safeThreadFutureToFuture(tr->get(tagThrottleAutoEnabledKey)));
if (!value.present()) {
tr->reset();
wait(delay(CLIENT_KNOBS->DEFAULT_BACKOFF));
continue;
} else if (value.get() == LiteralStringRef("1")) {
result = true;
} else if (value.get() == LiteralStringRef("0")) {
result = false;
} else {
TraceEvent(SevWarnAlways, "InvalidAutoTagThrottlingValue").detail("Value", value.get());
tr->reset();
wait(delay(CLIENT_KNOBS->DEFAULT_BACKOFF));
continue;
}
return result;
};
}
ACTOR Future<std::vector<TagThrottleInfo>> getThrottledTags(Reference<IDatabase> db,
int limit,
bool containsRecommend = false) {
state Reference<ITransaction> tr = db->createTransaction();
state bool reportAuto = containsRecommend;
loop {
tr->setOption(FDBTransactionOptions::READ_SYSTEM_KEYS);
try {
if (!containsRecommend) {
wait(store(reportAuto, getValidAutoEnabled(tr)));
}
state ThreadFuture<RangeResult> f = tr->getRange(
reportAuto ? tagThrottleKeys : KeyRangeRef(tagThrottleKeysPrefix, tagThrottleAutoKeysPrefix), limit);
RangeResult throttles = wait(safeThreadFutureToFuture(f));
std::vector<TagThrottleInfo> results;
for (auto throttle : throttles) {
results.push_back(TagThrottleInfo(TagThrottleKey::fromKey(throttle.key),
TagThrottleValue::fromValue(throttle.value)));
}
return results;
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
ACTOR Future<std::vector<TagThrottleInfo>> getRecommendedTags(Reference<IDatabase> db, int limit) {
state Reference<ITransaction> tr = db->createTransaction();
loop {
tr->setOption(FDBTransactionOptions::READ_SYSTEM_KEYS);
try {
bool enableAuto = wait(getValidAutoEnabled(tr));
if (enableAuto) {
return std::vector<TagThrottleInfo>();
}
state ThreadFuture<RangeResult> f =
tr->getRange(KeyRangeRef(tagThrottleAutoKeysPrefix, tagThrottleKeys.end), limit);
RangeResult throttles = wait(safeThreadFutureToFuture(f));
std::vector<TagThrottleInfo> results;
for (auto throttle : throttles) {
results.push_back(TagThrottleInfo(TagThrottleKey::fromKey(throttle.key),
TagThrottleValue::fromValue(throttle.value)));
}
return results;
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
ACTOR Future<Void> updateThrottleCount(Reference<ITransaction> tr, int64_t delta) {
state ThreadFuture<Optional<Value>> countVal = tr->get(tagThrottleCountKey);
state ThreadFuture<Optional<Value>> limitVal = tr->get(tagThrottleLimitKey);
wait(success(safeThreadFutureToFuture(countVal)) && success(safeThreadFutureToFuture(limitVal)));
int64_t count = 0;
int64_t limit = 0;
if (countVal.get().present()) {
BinaryReader reader(countVal.get().get(), Unversioned());
reader >> count;
}
if (limitVal.get().present()) {
BinaryReader reader(limitVal.get().get(), Unversioned());
reader >> limit;
}
count += delta;
if (count > limit) {
throw too_many_tag_throttles();
}
BinaryWriter writer(Unversioned());
writer << count;
tr->set(tagThrottleCountKey, writer.toValue());
return Void();
}
void signalThrottleChange(Reference<ITransaction> tr) {
tr->atomicOp(
tagThrottleSignalKey, LiteralStringRef("XXXXXXXXXX\x00\x00\x00\x00"), MutationRef::SetVersionstampedValue);
}
ACTOR Future<Void> throttleTags(Reference<IDatabase> db,
TagSet tags,
double tpsRate,
double initialDuration,
TagThrottleType throttleType,
TransactionPriority priority,
Optional<double> expirationTime = Optional<double>(),
Optional<TagThrottledReason> reason = Optional<TagThrottledReason>()) {
state Reference<ITransaction> tr = db->createTransaction();
state Key key = TagThrottleKey(tags, throttleType, priority).toKey();
ASSERT(initialDuration > 0);
if (throttleType == TagThrottleType::MANUAL) {
reason = TagThrottledReason::MANUAL;
}
TagThrottleValue throttle(tpsRate,
expirationTime.present() ? expirationTime.get() : 0,
initialDuration,
reason.present() ? reason.get() : TagThrottledReason::UNSET);
BinaryWriter wr(IncludeVersion(ProtocolVersion::withTagThrottleValueReason()));
wr << throttle;
state Value value = wr.toValue();
loop {
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
try {
if (throttleType == TagThrottleType::MANUAL) {
Optional<Value> oldThrottle = wait(safeThreadFutureToFuture(tr->get(key)));
if (!oldThrottle.present()) {
wait(updateThrottleCount(tr, 1));
}
}
tr->set(key, value);
if (throttleType == TagThrottleType::MANUAL) {
signalThrottleChange(tr);
}
wait(safeThreadFutureToFuture(tr->commit()));
return Void();
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
ACTOR Future<bool> unthrottleTags(Reference<IDatabase> db,
TagSet tags,
Optional<TagThrottleType> throttleType,
Optional<TransactionPriority> priority) {
state Reference<ITransaction> tr = db->createTransaction();
state std::vector<Key> keys;
for (auto p : allTransactionPriorities) {
if (!priority.present() || priority.get() == p) {
if (!throttleType.present() || throttleType.get() == TagThrottleType::AUTO) {
keys.push_back(TagThrottleKey(tags, TagThrottleType::AUTO, p).toKey());
}
if (!throttleType.present() || throttleType.get() == TagThrottleType::MANUAL) {
keys.push_back(TagThrottleKey(tags, TagThrottleType::MANUAL, p).toKey());
}
}
}
state bool removed = false;
loop {
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
try {
state std::vector<Future<Optional<Value>>> values;
values.reserve(keys.size());
for (auto key : keys) {
values.push_back(safeThreadFutureToFuture(tr->get(key)));
}
wait(waitForAll(values));
int delta = 0;
for (int i = 0; i < values.size(); ++i) {
if (values[i].get().present()) {
if (TagThrottleKey::fromKey(keys[i]).throttleType == TagThrottleType::MANUAL) {
delta -= 1;
}
tr->clear(keys[i]);
// Report that we are removing this tag if we ever see it present.
// This protects us from getting confused if the transaction is maybe committed.
// It's ok if someone else actually ends up removing this tag at the same time
// and we aren't the ones to actually do it.
removed = true;
}
}
if (delta != 0) {
wait(updateThrottleCount(tr, delta));
}
if (removed) {
signalThrottleChange(tr);
wait(safeThreadFutureToFuture(tr->commit()));
}
return removed;
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
ACTOR Future<Void> enableAuto(Reference<IDatabase> db, bool enabled) {
state Reference<ITransaction> tr = db->createTransaction();
loop {
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
try {
Optional<Value> value = wait(safeThreadFutureToFuture(tr->get(tagThrottleAutoEnabledKey)));
if (!value.present() || (enabled && value.get() != LiteralStringRef("1")) ||
(!enabled && value.get() != LiteralStringRef("0"))) {
tr->set(tagThrottleAutoEnabledKey, LiteralStringRef(enabled ? "1" : "0"));
signalThrottleChange(tr);
wait(safeThreadFutureToFuture(tr->commit()));
}
return Void();
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
ACTOR Future<bool> unthrottleMatchingThrottles(Reference<IDatabase> db,
KeyRef beginKey,
KeyRef endKey,
Optional<TransactionPriority> priority,
bool onlyExpiredThrottles) {
state Reference<ITransaction> tr = db->createTransaction();
state KeySelector begin = firstGreaterOrEqual(beginKey);
state KeySelector end = firstGreaterOrEqual(endKey);
state bool removed = false;
loop {
tr->setOption(FDBTransactionOptions::ACCESS_SYSTEM_KEYS);
try {
// holds memory of the RangeResult
state ThreadFuture<RangeResult> f = tr->getRange(begin, end, 1000);
state RangeResult tags = wait(safeThreadFutureToFuture(f));
state uint64_t unthrottledTags = 0;
uint64_t manualUnthrottledTags = 0;
for (auto tag : tags) {
if (onlyExpiredThrottles) {
double expirationTime = TagThrottleValue::fromValue(tag.value).expirationTime;
if (expirationTime == 0 || expirationTime > now()) {
continue;
}
}
TagThrottleKey key = TagThrottleKey::fromKey(tag.key);
if (priority.present() && key.priority != priority.get()) {
continue;
}
if (key.throttleType == TagThrottleType::MANUAL) {
++manualUnthrottledTags;
}
removed = true;
tr->clear(tag.key);
unthrottledTags++;
}
if (manualUnthrottledTags > 0) {
wait(updateThrottleCount(tr, -manualUnthrottledTags));
}
if (unthrottledTags > 0) {
signalThrottleChange(tr);
}
wait(safeThreadFutureToFuture(tr->commit()));
if (!tags.more) {
return removed;
}
ASSERT(tags.size() > 0);
begin = KeySelector(firstGreaterThan(tags[tags.size() - 1].key), tags.arena());
} catch (Error& e) {
wait(safeThreadFutureToFuture(tr->onError(e)));
}
}
}
Future<bool> unthrottleAll(Reference<IDatabase> db,
Optional<TagThrottleType> tagThrottleType,
Optional<TransactionPriority> priority) {
KeyRef begin = tagThrottleKeys.begin;
KeyRef end = tagThrottleKeys.end;
if (tagThrottleType.present() && tagThrottleType == TagThrottleType::AUTO) {
begin = tagThrottleAutoKeysPrefix;
} else if (tagThrottleType.present() && tagThrottleType == TagThrottleType::MANUAL) {
end = tagThrottleAutoKeysPrefix;
}
return unthrottleMatchingThrottles(db, begin, end, priority, false);
}
} // namespace
namespace fdb_cli {
ACTOR Future<bool> throttleCommandActor(Reference<IDatabase> db, std::vector<StringRef> tokens) {
if (tokens.size() == 1) {
printUsage(tokens[0]);
return false;
} else if (tokencmp(tokens[1], "list")) {
if (tokens.size() > 4) {
printf("Usage: throttle list [throttled|recommended|all] [LIMIT]\n");
printf("\n");
printf("Lists tags that are currently throttled.\n");
printf("The default LIMIT is 100 tags.\n");
return false;
}
state bool reportThrottled = true;
state bool reportRecommended = false;
if (tokens.size() >= 3) {
if (tokencmp(tokens[2], "recommended")) {
reportThrottled = false;
reportRecommended = true;
} else if (tokencmp(tokens[2], "all")) {
reportThrottled = true;
reportRecommended = true;
} else if (!tokencmp(tokens[2], "throttled")) {
printf("ERROR: failed to parse `%s'.\n", printable(tokens[2]).c_str());
return false;
}
}
state int throttleListLimit = 100;
if (tokens.size() >= 4) {
char* end;
throttleListLimit = std::strtol((const char*)tokens[3].begin(), &end, 10);
if ((tokens.size() > 4 && !std::isspace(*end)) || (tokens.size() == 4 && *end != '\0')) {
fprintf(stderr, "ERROR: failed to parse limit `%s'.\n", printable(tokens[3]).c_str());
return false;
}
}
state std::vector<TagThrottleInfo> tags;
if (reportThrottled && reportRecommended) {
wait(store(tags, getThrottledTags(db, throttleListLimit, true)));
} else if (reportThrottled) {
wait(store(tags, getThrottledTags(db, throttleListLimit)));
} else if (reportRecommended) {
wait(store(tags, getRecommendedTags(db, throttleListLimit)));
}
bool anyLogged = false;
for (auto itr = tags.begin(); itr != tags.end(); ++itr) {
if (itr->expirationTime > now()) {
if (!anyLogged) {
printf("Throttled tags:\n\n");
printf(" Rate (txn/s) | Expiration (s) | Priority | Type | Reason |Tag\n");
printf(" --------------+----------------+-----------+--------+------------+------\n");
anyLogged = true;
}
std::string reasonStr = "unset";
if (itr->reason == TagThrottledReason::MANUAL) {
reasonStr = "manual";
} else if (itr->reason == TagThrottledReason::BUSY_WRITE) {
reasonStr = "busy write";
} else if (itr->reason == TagThrottledReason::BUSY_READ) {
reasonStr = "busy read";
}
printf(" %12d | %13ds | %9s | %6s | %10s |%s\n",
(int)(itr->tpsRate),
std::min((int)(itr->expirationTime - now()), (int)(itr->initialDuration)),
transactionPriorityToString(itr->priority, false),
itr->throttleType == TagThrottleType::AUTO ? "auto" : "manual",
reasonStr.c_str(),
itr->tag.toString().c_str());
}
}
if (tags.size() == throttleListLimit) {
printf("\nThe tag limit `%d' was reached. Use the [LIMIT] argument to view additional tags.\n",
throttleListLimit);
printf("Usage: throttle list [LIMIT]\n");
}
if (!anyLogged) {
printf("There are no %s tags\n", reportThrottled ? "throttled" : "recommended");
}
} else if (tokencmp(tokens[1], "on")) {
if (tokens.size() < 4 || !tokencmp(tokens[2], "tag") || tokens.size() > 7) {
printf("Usage: throttle on tag <TAG> [RATE] [DURATION] [PRIORITY]\n");
printf("\n");
printf("Enables throttling for transactions with the specified tag.\n");
printf("An optional transactions per second rate can be specified (default 0).\n");
printf("An optional duration can be specified, which must include a time suffix (s, m, h, "
"d) (default 1h).\n");
printf("An optional priority can be specified. Choices are `default', `immediate', and "
"`batch' (default `default').\n");
return false;
}
double tpsRate = 0.0;
uint64_t duration = 3600;
TransactionPriority priority = TransactionPriority::DEFAULT;
if (tokens.size() >= 5) {
char* end;
tpsRate = std::strtod((const char*)tokens[4].begin(), &end);
if ((tokens.size() > 5 && !std::isspace(*end)) || (tokens.size() == 5 && *end != '\0')) {
fprintf(stderr, "ERROR: failed to parse rate `%s'.\n", printable(tokens[4]).c_str());
return false;
}
if (tpsRate < 0) {
fprintf(stderr, "ERROR: rate cannot be negative `%f'\n", tpsRate);
return false;
}
}
if (tokens.size() == 6) {
Optional<uint64_t> parsedDuration = parseDuration(tokens[5].toString());
if (!parsedDuration.present()) {
fprintf(stderr, "ERROR: failed to parse duration `%s'.\n", printable(tokens[5]).c_str());
return false;
}
duration = parsedDuration.get();
if (duration == 0) {
fprintf(stderr, "ERROR: throttle duration cannot be 0\n");
return false;
}
}
if (tokens.size() == 7) {
if (tokens[6] == LiteralStringRef("default")) {
priority = TransactionPriority::DEFAULT;
} else if (tokens[6] == LiteralStringRef("immediate")) {
priority = TransactionPriority::IMMEDIATE;
} else if (tokens[6] == LiteralStringRef("batch")) {
priority = TransactionPriority::BATCH;
} else {
fprintf(stderr,
"ERROR: unrecognized priority `%s'. Must be one of `default',\n `immediate', "
"or `batch'.\n",
tokens[6].toString().c_str());
return false;
}
}
TagSet tags;
tags.addTag(tokens[3]);
wait(throttleTags(db, tags, tpsRate, duration, TagThrottleType::MANUAL, priority));
printf("Tag `%s' has been throttled\n", tokens[3].toString().c_str());
} else if (tokencmp(tokens[1], "off")) {
int nextIndex = 2;
TagSet tags;
bool throttleTypeSpecified = false;
bool is_error = false;
Optional<TagThrottleType> throttleType = TagThrottleType::MANUAL;
Optional<TransactionPriority> priority;
if (tokens.size() == 2) {
is_error = true;
}
while (nextIndex < tokens.size() && !is_error) {
if (tokencmp(tokens[nextIndex], "all")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = Optional<TagThrottleType>();
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "auto")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = TagThrottleType::AUTO;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "manual")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = TagThrottleType::MANUAL;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "default")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::DEFAULT;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "immediate")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::IMMEDIATE;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "batch")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::BATCH;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "tag")) {
if (tags.size() > 0 || nextIndex == tokens.size() - 1) {
is_error = true;
continue;
}
tags.addTag(tokens[nextIndex + 1]);
nextIndex += 2;
}
}
if (!is_error) {
state const char* throttleTypeString =
!throttleType.present() ? "" : (throttleType.get() == TagThrottleType::AUTO ? "auto-" : "manually ");
state std::string priorityString =
priority.present() ? format(" at %s priority", transactionPriorityToString(priority.get(), false)) : "";
if (tags.size() > 0) {
bool success = wait(unthrottleTags(db, tags, throttleType, priority));
if (success) {
printf("Unthrottled tag `%s'%s\n", tokens[3].toString().c_str(), priorityString.c_str());
} else {
printf("Tag `%s' was not %sthrottled%s\n",
tokens[3].toString().c_str(),
throttleTypeString,
priorityString.c_str());
}
} else {
bool unthrottled = wait(unthrottleAll(db, throttleType, priority));
if (unthrottled) {
printf("Unthrottled all %sthrottled tags%s\n", throttleTypeString, priorityString.c_str());
} else {
printf("There were no tags being %sthrottled%s\n", throttleTypeString, priorityString.c_str());
}
}
} else {
printf("Usage: throttle off [all|auto|manual] [tag <TAG>] [PRIORITY]\n");
printf("\n");
printf("Disables throttling for throttles matching the specified filters. At least one "
"filter must be used.\n\n");
printf("An optional qualifier `all', `auto', or `manual' can be used to specify the type "
"of throttle\n");
printf("affected. `all' targets all throttles, `auto' targets those created by the "
"cluster, and\n");
printf("`manual' targets those created manually (default `manual').\n\n");
printf("The `tag' filter can be use to turn off only a specific tag.\n\n");
printf("The priority filter can be used to turn off only throttles at specific priorities. "
"Choices are\n");
printf("`default', `immediate', or `batch'. By default, all priorities are targeted.\n");
}
} else if (tokencmp(tokens[1], "enable") || tokencmp(tokens[1], "disable")) {
if (tokens.size() != 3 || !tokencmp(tokens[2], "auto")) {
printf("Usage: throttle <enable|disable> auto\n");
printf("\n");
printf("Enables or disable automatic tag throttling.\n");
return false;
}
state bool autoTagThrottlingEnabled = tokencmp(tokens[1], "enable");
wait(enableAuto(db, autoTagThrottlingEnabled));
printf("Automatic tag throttling has been %s\n", autoTagThrottlingEnabled ? "enabled" : "disabled");
} else {
printUsage(tokens[0]);
return false;
}
return true;
}
CommandFactory throttleFactory(
"throttle",
CommandHelp("throttle <on|off|enable auto|disable auto|list> [ARGS]",
"view and control throttled tags",
"Use `on' and `off' to manually throttle or unthrottle tags. Use `enable auto' or `disable auto' "
"to enable or disable automatic tag throttling. Use `list' to print the list of throttled tags.\n"));
} // namespace fdb_cli

299
fdbcli/fdbcli.actor.cpp
View File

@ -648,11 +648,6 @@ void initHelp() {
"namespace for all the profiling-related commands.",
"Different types support different actions. Run `profile` to get a list of "
"types, and iteratively explore the help.\n");
helpMap["throttle"] =
CommandHelp("throttle <on|off|enable auto|disable auto|list> [ARGS]",
"view and control throttled tags",
"Use `on' and `off' to manually throttle or unthrottle tags. Use `enable auto' or `disable auto' "
"to enable or disable automatic tag throttling. Use `list' to print the list of throttled tags.\n");
helpMap["cache_range"] = CommandHelp(
"cache_range <set|clear> <BEGINKEY> <ENDKEY>",
"Mark a key range to add to or remove from storage caches.",
@ -4494,300 +4489,12 @@ ACTOR Future<int> cli(CLIOptions opt, LineNoise* plinenoise) {
}
if (tokencmp(tokens[0], "throttle")) {
if (tokens.size() == 1) {
printUsage(tokens[0]);
bool _result = wait(throttleCommandActor(db2, tokens));
if (!_result)
is_error = true;
continue;
} else if (tokencmp(tokens[1], "list")) {
if (tokens.size() > 4) {
printf("Usage: throttle list [throttled|recommended|all] [LIMIT]\n");
printf("\n");
printf("Lists tags that are currently throttled.\n");
printf("The default LIMIT is 100 tags.\n");
is_error = true;
continue;
}
state bool reportThrottled = true;
state bool reportRecommended = false;
if (tokens.size() >= 3) {
if (tokencmp(tokens[2], "recommended")) {
reportThrottled = false;
reportRecommended = true;
} else if (tokencmp(tokens[2], "all")) {
reportThrottled = true;
reportRecommended = true;
} else if (!tokencmp(tokens[2], "throttled")) {
printf("ERROR: failed to parse `%s'.\n", printable(tokens[2]).c_str());
is_error = true;
continue;
}
}
state int throttleListLimit = 100;
if (tokens.size() >= 4) {
char* end;
throttleListLimit = std::strtol((const char*)tokens[3].begin(), &end, 10);
if ((tokens.size() > 4 && !std::isspace(*end)) || (tokens.size() == 4 && *end != '\0')) {
fprintf(stderr, "ERROR: failed to parse limit `%s'.\n", printable(tokens[3]).c_str());
is_error = true;
continue;
}
}
state std::vector<TagThrottleInfo> tags;
if (reportThrottled && reportRecommended) {
wait(store(tags, ThrottleApi::getThrottledTags(db, throttleListLimit, true)));
} else if (reportThrottled) {
wait(store(tags, ThrottleApi::getThrottledTags(db, throttleListLimit)));
} else if (reportRecommended) {
wait(store(tags, ThrottleApi::getRecommendedTags(db, throttleListLimit)));
}
bool anyLogged = false;
for (auto itr = tags.begin(); itr != tags.end(); ++itr) {
if (itr->expirationTime > now()) {
if (!anyLogged) {
printf("Throttled tags:\n\n");
printf(" Rate (txn/s) | Expiration (s) | Priority | Type | Reason |Tag\n");
printf(
" --------------+----------------+-----------+--------+------------+------\n");
anyLogged = true;
}
std::string reasonStr = "unset";
if (itr->reason == TagThrottledReason::MANUAL) {
reasonStr = "manual";
} else if (itr->reason == TagThrottledReason::BUSY_WRITE) {
reasonStr = "busy write";
} else if (itr->reason == TagThrottledReason::BUSY_READ) {
reasonStr = "busy read";
}
printf(" %12d | %13ds | %9s | %6s | %10s |%s\n",
(int)(itr->tpsRate),
std::min((int)(itr->expirationTime - now()), (int)(itr->initialDuration)),
transactionPriorityToString(itr->priority, false),
itr->throttleType == TagThrottleType::AUTO ? "auto" : "manual",
reasonStr.c_str(),
itr->tag.toString().c_str());
}
}
if (tags.size() == throttleListLimit) {
printf(
"\nThe tag limit `%d' was reached. Use the [LIMIT] argument to view additional tags.\n",
throttleListLimit);
printf("Usage: throttle list [LIMIT]\n");
}
if (!anyLogged) {
printf("There are no %s tags\n", reportThrottled ? "throttled" : "recommended");
}
} else if (tokencmp(tokens[1], "on")) {
if (tokens.size() < 4 || !tokencmp(tokens[2], "tag") || tokens.size() > 7) {
printf("Usage: throttle on tag <TAG> [RATE] [DURATION] [PRIORITY]\n");
printf("\n");
printf("Enables throttling for transactions with the specified tag.\n");
printf("An optional transactions per second rate can be specified (default 0).\n");
printf("An optional duration can be specified, which must include a time suffix (s, m, h, "
"d) (default 1h).\n");
printf("An optional priority can be specified. Choices are `default', `immediate', and "
"`batch' (default `default').\n");
is_error = true;
continue;
}
double tpsRate = 0.0;
uint64_t duration = 3600;
TransactionPriority priority = TransactionPriority::DEFAULT;
if (tokens.size() >= 5) {
char* end;
tpsRate = std::strtod((const char*)tokens[4].begin(), &end);
if ((tokens.size() > 5 && !std::isspace(*end)) || (tokens.size() == 5 && *end != '\0')) {
fprintf(stderr, "ERROR: failed to parse rate `%s'.\n", printable(tokens[4]).c_str());
is_error = true;
continue;
}
if (tpsRate < 0) {
fprintf(stderr, "ERROR: rate cannot be negative `%f'\n", tpsRate);
is_error = true;
continue;
}
}
if (tokens.size() == 6) {
Optional<uint64_t> parsedDuration = parseDuration(tokens[5].toString());
if (!parsedDuration.present()) {
fprintf(
stderr, "ERROR: failed to parse duration `%s'.\n", printable(tokens[5]).c_str());
is_error = true;
continue;
}
duration = parsedDuration.get();
if (duration == 0) {
fprintf(stderr, "ERROR: throttle duration cannot be 0\n");
is_error = true;
continue;
}
}
if (tokens.size() == 7) {
if (tokens[6] == LiteralStringRef("default")) {
priority = TransactionPriority::DEFAULT;
} else if (tokens[6] == LiteralStringRef("immediate")) {
priority = TransactionPriority::IMMEDIATE;
} else if (tokens[6] == LiteralStringRef("batch")) {
priority = TransactionPriority::BATCH;
} else {
fprintf(stderr,
"ERROR: unrecognized priority `%s'. Must be one of `default',\n `immediate', "
"or `batch'.\n",
tokens[6].toString().c_str());
is_error = true;
continue;
}
}
TagSet tags;
tags.addTag(tokens[3]);
wait(ThrottleApi::throttleTags(db, tags, tpsRate, duration, TagThrottleType::MANUAL, priority));
printf("Tag `%s' has been throttled\n", tokens[3].toString().c_str());
} else if (tokencmp(tokens[1], "off")) {
int nextIndex = 2;
TagSet tags;
bool throttleTypeSpecified = false;
Optional<TagThrottleType> throttleType = TagThrottleType::MANUAL;
Optional<TransactionPriority> priority;
if (tokens.size() == 2) {
is_error = true;
}
while (nextIndex < tokens.size() && !is_error) {
if (tokencmp(tokens[nextIndex], "all")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = Optional<TagThrottleType>();
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "auto")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = TagThrottleType::AUTO;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "manual")) {
if (throttleTypeSpecified) {
is_error = true;
continue;
}
throttleTypeSpecified = true;
throttleType = TagThrottleType::MANUAL;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "default")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::DEFAULT;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "immediate")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::IMMEDIATE;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "batch")) {
if (priority.present()) {
is_error = true;
continue;
}
priority = TransactionPriority::BATCH;
++nextIndex;
} else if (tokencmp(tokens[nextIndex], "tag")) {
if (tags.size() > 0 || nextIndex == tokens.size() - 1) {
is_error = true;
continue;
}
tags.addTag(tokens[nextIndex + 1]);
nextIndex += 2;
}
}
if (!is_error) {
state const char* throttleTypeString =
!throttleType.present()
? ""
: (throttleType.get() == TagThrottleType::AUTO ? "auto-" : "manually ");
state std::string priorityString =
priority.present()
? format(" at %s priority", transactionPriorityToString(priority.get(), false))
: "";
if (tags.size() > 0) {
bool success = wait(ThrottleApi::unthrottleTags(db, tags, throttleType, priority));
if (success) {
printf("Unthrottled tag `%s'%s\n",
tokens[3].toString().c_str(),
priorityString.c_str());
} else {
printf("Tag `%s' was not %sthrottled%s\n",
tokens[3].toString().c_str(),
throttleTypeString,
priorityString.c_str());
}
} else {
bool unthrottled = wait(ThrottleApi::unthrottleAll(db, throttleType, priority));
if (unthrottled) {
printf("Unthrottled all %sthrottled tags%s\n",
throttleTypeString,
priorityString.c_str());
} else {
printf("There were no tags being %sthrottled%s\n",
throttleTypeString,
priorityString.c_str());
}
}
} else {
printf("Usage: throttle off [all|auto|manual] [tag <TAG>] [PRIORITY]\n");
printf("\n");
printf("Disables throttling for throttles matching the specified filters. At least one "
"filter must be used.\n\n");
printf("An optional qualifier `all', `auto', or `manual' can be used to specify the type "
"of throttle\n");
printf("affected. `all' targets all throttles, `auto' targets those created by the "
"cluster, and\n");
printf("`manual' targets those created manually (default `manual').\n\n");
printf("The `tag' filter can be use to turn off only a specific tag.\n\n");
printf("The priority filter can be used to turn off only throttles at specific priorities. "
"Choices are\n");
printf("`default', `immediate', or `batch'. By default, all priorities are targeted.\n");
}
} else if (tokencmp(tokens[1], "enable") || tokencmp(tokens[1], "disable")) {
if (tokens.size() != 3 || !tokencmp(tokens[2], "auto")) {
printf("Usage: throttle <enable|disable> auto\n");
printf("\n");
printf("Enables or disable automatic tag throttling.\n");
is_error = true;
continue;
}
state bool autoTagThrottlingEnabled = tokencmp(tokens[1], "enable");
wait(ThrottleApi::enableAuto(db, autoTagThrottlingEnabled));
printf("Automatic tag throttling has been %s\n",
autoTagThrottlingEnabled ? "enabled" : "disabled");
} else {
printUsage(tokens[0]);
is_error = true;
}
continue;
}
if (tokencmp(tokens[0], "cache_range")) {
if (tokens.size() != 4) {
printUsage(tokens[0]);

2
fdbcli/fdbcli.actor.h
View File

@ -83,6 +83,8 @@ ACTOR Future<bool> forceRecoveryWithDataLossCommandActor(Reference<IDatabase> db
ACTOR Future<bool> maintenanceCommandActor(Reference<IDatabase> db, std::vector<StringRef> tokens);
// snapshot command
ACTOR Future<bool> snapshotCommandActor(Reference<IDatabase> db, std::vector<StringRef> tokens);
// throttle command
ACTOR Future<bool> throttleCommandActor(Reference<IDatabase> db, std::vector<StringRef> tokens);
} // namespace fdb_cli