foundationdb/flow/Knobs.cpp

565 lines
26 KiB
C++

/*
* Knobs.cpp
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2022 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 "flow/EncryptUtils.h"
#include "flow/Error.h"
#include "flow/flow.h"
#include "flow/Knobs.h"
#include "flow/BooleanParam.h"
#include "flow/UnitTest.h"
#include <cmath>
#include <cinttypes>
FDB_BOOLEAN_PARAM(IsSimulated);
FDB_BOOLEAN_PARAM(Randomize);
FlowKnobs::FlowKnobs(Randomize randomize, IsSimulated isSimulated) {
initialize(randomize, isSimulated);
}
FlowKnobs bootstrapGlobalFlowKnobs(Randomize::False, IsSimulated::False);
FlowKnobs const* FLOW_KNOBS = &bootstrapGlobalFlowKnobs;
#define init(...) KNOB_FN(__VA_ARGS__, INIT_ATOMIC_KNOB, INIT_KNOB)(__VA_ARGS__)
// clang-format off
void FlowKnobs::initialize(Randomize randomize, IsSimulated isSimulated) {
init( AUTOMATIC_TRACE_DUMP, 1 );
init( PREVENT_FAST_SPIN_DELAY, .01 );
init( HOSTNAME_RESOLVE_INIT_INTERVAL, .05 );
init( HOSTNAME_RESOLVE_MAX_INTERVAL, 1.0 );
init( HOSTNAME_RECONNECT_INIT_INTERVAL, .05 );
init( HOSTNAME_RECONNECT_MAX_INTERVAL, 1.0 );
init( ENABLE_COORDINATOR_DNS_CACHE, false ); if( randomize && BUGGIFY ) ENABLE_COORDINATOR_DNS_CACHE = true;
init( CACHE_REFRESH_INTERVAL_WHEN_ALL_ALTERNATIVES_FAILED, 1.0 );
init( DELAY_JITTER_OFFSET, 0.9 );
init( DELAY_JITTER_RANGE, 0.2 );
init( BUSY_WAIT_THRESHOLD, 0 ); // 1e100 == never sleep
init( CLIENT_REQUEST_INTERVAL, 1.0 ); if( randomize && BUGGIFY ) CLIENT_REQUEST_INTERVAL = 2.0;
init( SERVER_REQUEST_INTERVAL, 1.0 ); if( randomize && BUGGIFY ) SERVER_REQUEST_INTERVAL = 2.0;
init( REACTOR_FLAGS, 0 );
init( DISABLE_ASSERTS, 0 );
init( QUEUE_MODEL_SMOOTHING_AMOUNT, 2.0 );
init( RUN_LOOP_PROFILING_INTERVAL, 0.125 ); // A value of 0 disables run loop profiling
init( SLOWTASK_PROFILING_LOG_INTERVAL, 0 ); // A value of 0 means use RUN_LOOP_PROFILING_INTERVAL
init( SLOWTASK_PROFILING_MAX_LOG_INTERVAL, 1.0 );
init( SLOWTASK_PROFILING_LOG_BACKOFF, 2.0 );
init( SLOWTASK_BLOCKED_INTERVAL, 60.0 );
init( SATURATION_PROFILING_LOG_INTERVAL, 0.5 ); // A value of 0 means use RUN_LOOP_PROFILING_INTERVAL
init( SATURATION_PROFILING_MAX_LOG_INTERVAL, 5.0 );
init( SATURATION_PROFILING_LOG_BACKOFF, 2.0 );
init( RANDOMSEED_RETRY_LIMIT, 4 );
init( FAST_ALLOC_LOGGING_BYTES, 10e6 );
init( FAST_ALLOC_ALLOW_GUARD_PAGES, false );
init( HUGE_ARENA_LOGGING_BYTES, 100e6 );
init( HUGE_ARENA_LOGGING_INTERVAL, 5.0 );
init( MEMORY_USAGE_CHECK_INTERVAL, 1.0 );
// Chaos testing - enabled for simulation by default
init( ENABLE_CHAOS_FEATURES, isSimulated );
init( CHAOS_LOGGING_INTERVAL, 5.0 );
init( WRITE_TRACING_ENABLED, true ); if( randomize && BUGGIFY ) WRITE_TRACING_ENABLED = false;
init( TRACING_SPAN_ATTRIBUTES_ENABLED, false ); // Additional K/V and tenant data added to Span Attributes
init( TRACING_SAMPLE_RATE, 0.0); // Fraction of distributed traces (not spans) to sample (0 means ignore all traces)
init( TRACING_UDP_LISTENER_ADDR, "127.0.0.1"); // Only applicable if TracerType is set to a network option
init( TRACING_UDP_LISTENER_PORT, 8889 ); // Only applicable if TracerType is set to a network option
//connectionMonitor
init( CONNECTION_MONITOR_LOOP_TIME, isSimulated ? 0.75 : 1.0 ); if( randomize && BUGGIFY ) CONNECTION_MONITOR_LOOP_TIME = 6.0;
init( CONNECTION_MONITOR_TIMEOUT, isSimulated ? 1.50 : 2.0 ); if( randomize && BUGGIFY ) CONNECTION_MONITOR_TIMEOUT = 6.0;
init( CONNECTION_MONITOR_IDLE_TIMEOUT, 180.0 ); if( randomize && BUGGIFY ) CONNECTION_MONITOR_IDLE_TIMEOUT = 5.0;
init( CONNECTION_MONITOR_INCOMING_IDLE_MULTIPLIER, 1.2 );
init( CONNECTION_MONITOR_UNREFERENCED_CLOSE_DELAY, 2.0 );
//FlowTransport
init( CONNECTION_REJECTED_MESSAGE_DELAY, 1.0 );
init( CONNECTION_ID_TIMEOUT, 600.0 ); if( randomize && BUGGIFY ) CONNECTION_ID_TIMEOUT = 60.0;
init( CONNECTION_CLEANUP_DELAY, 100.0 );
init( INITIAL_RECONNECTION_TIME, 0.05 );
init( MAX_RECONNECTION_TIME, 0.5 );
init( RECONNECTION_TIME_GROWTH_RATE, 1.2 );
init( RECONNECTION_RESET_TIME, 5.0 );
init( ALWAYS_ACCEPT_DELAY, 15.0 );
init( ACCEPT_BATCH_SIZE, 10 );
init( TOO_MANY_CONNECTIONS_CLOSED_RESET_DELAY, 5.0 );
init( TOO_MANY_CONNECTIONS_CLOSED_TIMEOUT, 20.0 );
init( PEER_UNAVAILABLE_FOR_LONG_TIME_TIMEOUT, 3600.0 );
init( INCOMPATIBLE_PEER_DELAY_BEFORE_LOGGING, 5.0 );
init( PING_LOGGING_INTERVAL, 3.0 );
init( PING_SAMPLE_AMOUNT, 100 );
init( NETWORK_CONNECT_SAMPLE_AMOUNT, 100 );
init( TLS_CERT_REFRESH_DELAY_SECONDS, 12*60*60 );
init( TLS_SERVER_CONNECTION_THROTTLE_TIMEOUT, 9.0 );
init( TLS_CLIENT_CONNECTION_THROTTLE_TIMEOUT, 11.0 );
init( TLS_SERVER_CONNECTION_THROTTLE_ATTEMPTS, 1 );
init( TLS_CLIENT_CONNECTION_THROTTLE_ATTEMPTS, 1 );
init( TLS_CLIENT_HANDSHAKE_THREADS, 0 );
init( TLS_SERVER_HANDSHAKE_THREADS, 64 );
init( TLS_HANDSHAKE_THREAD_STACKSIZE, 64 * 1024 );
init( TLS_MALLOC_ARENA_MAX, 6 );
init( TLS_HANDSHAKE_LIMIT, 1000 );
init( NETWORK_TEST_CLIENT_COUNT, 30 );
init( NETWORK_TEST_REPLY_SIZE, 600e3 );
init( NETWORK_TEST_REQUEST_COUNT, 0 ); // 0 -> run forever
init( NETWORK_TEST_REQUEST_SIZE, 1 );
init( NETWORK_TEST_SCRIPT_MODE, false );
//Authorization
init( ALLOW_TOKENLESS_TENANT_ACCESS, false );
init( PUBLIC_KEY_FILE_MAX_SIZE, 1024 * 1024 );
init( PUBLIC_KEY_FILE_REFRESH_INTERVAL_SECONDS, 30 );
init( MAX_CACHED_EXPIRED_TOKENS, 1024 );
init( AUDIT_TIME_WINDOW, 5.0 );
//AsyncFileCached
init( PAGE_CACHE_4K, 2LL<<30 );
init( PAGE_CACHE_64K, 200LL<<20 );
init( SIM_PAGE_CACHE_4K, 1e8 );
init( SIM_PAGE_CACHE_64K, 1e7 );
init( BUGGIFY_SIM_PAGE_CACHE_4K, 1e6 );
init( BUGGIFY_SIM_PAGE_CACHE_64K, 1e6 );
init( MAX_EVICT_ATTEMPTS, 100 ); if( randomize && BUGGIFY ) MAX_EVICT_ATTEMPTS = 2;
init( CACHE_EVICTION_POLICY, "random" );
init( PAGE_CACHE_TRUNCATE_LOOKUP_FRACTION, 0.1 ); if( randomize && BUGGIFY ) PAGE_CACHE_TRUNCATE_LOOKUP_FRACTION = 0.0; else if( randomize && BUGGIFY ) PAGE_CACHE_TRUNCATE_LOOKUP_FRACTION = 1.0;
init( FLOW_CACHEDFILE_WRITE_IO_SIZE, 0 );
if ( randomize && BUGGIFY) {
// Choose 16KB to 64KB as I/O size
FLOW_CACHEDFILE_WRITE_IO_SIZE = deterministicRandom()->randomInt(16384, 65537);
}
//AsyncFileEIO
init( EIO_MAX_PARALLELISM, 4 );
init( EIO_USE_ODIRECT, 0 );
//AsyncFileEncrypted
init( ENCRYPTION_BLOCK_SIZE, 4096 );
init( MAX_DECRYPTED_BLOCKS, 10 );
//AsyncFileKAIO
init( MAX_OUTSTANDING, 64 );
init( MIN_SUBMIT, 10 );
init( SQLITE_DISK_METRIC_LOGGING_INTERVAL, 5.0 );
init( KAIO_LATENCY_LOGGING_INTERVAL, 30.0 );
init( KAIO_LATENCY_SAMPLE_SIZE, 30000 );
init( PAGE_WRITE_CHECKSUM_HISTORY, 0 ); if( randomize && BUGGIFY ) PAGE_WRITE_CHECKSUM_HISTORY = 10000000;
init( DISABLE_POSIX_KERNEL_AIO, 0 );
//AsyncFileNonDurable
init( NON_DURABLE_MAX_WRITE_DELAY, 2.0 ); if( randomize && BUGGIFY ) NON_DURABLE_MAX_WRITE_DELAY = 5.0;
init( MAX_PRIOR_MODIFICATION_DELAY, 1.0 ); if( randomize && BUGGIFY ) MAX_PRIOR_MODIFICATION_DELAY = 10.0;
//GenericActors
init( BUGGIFY_FLOW_LOCK_RELEASE_DELAY, 1.0 );
init( LOW_PRIORITY_DELAY_COUNT, 5 );
init( LOW_PRIORITY_MAX_DELAY, 5.0 );
// HTTP
init( HTTP_READ_SIZE, 128*1024 );
init( HTTP_SEND_SIZE, 32*1024 );
init( HTTP_VERBOSE_LEVEL, 0 );
init( HTTP_REQUEST_ID_HEADER, "" );
init( HTTP_RESPONSE_SKIP_VERIFY_CHECKSUM_FOR_PARTIAL_CONTENT, false );
//IAsyncFile
init( INCREMENTAL_DELETE_TRUNCATE_AMOUNT, 5e8 ); //500MB
init( INCREMENTAL_DELETE_INTERVAL, 1.0 ); //every 1 second
//Net2 and FlowTransport
init( MIN_COALESCE_DELAY, 10e-6 ); if( randomize && BUGGIFY ) MIN_COALESCE_DELAY = 0;
init( MAX_COALESCE_DELAY, 20e-6 ); if( randomize && BUGGIFY ) MAX_COALESCE_DELAY = 0;
init( SLOW_LOOP_CUTOFF, 15.0 / 1000.0 );
init( SLOW_LOOP_SAMPLING_RATE, 0.1 );
init( TSC_YIELD_TIME, 1000000 );
init( MIN_LOGGED_PRIORITY_BUSY_FRACTION, 0.05 );
init( CERT_FILE_MAX_SIZE, 5 * 1024 * 1024 );
init( READY_QUEUE_RESERVED_SIZE, 8192 );
init( TASKS_PER_REACTOR_CHECK, 100 );
//Network
init( PACKET_LIMIT, 100LL<<20 );
init( PACKET_WARNING, 2LL<<20 ); // 2MB packet warning quietly allows for 1MB system messages
init( TIME_OFFSET_LOGGING_INTERVAL, 60.0 );
init( MAX_PACKET_SEND_BYTES, 128 * 1024 );
init( MIN_PACKET_BUFFER_BYTES, 4 * 1024 );
init( MIN_PACKET_BUFFER_FREE_BYTES, 256 );
init( FLOW_TCP_NODELAY, 1 );
init( FLOW_TCP_QUICKACK, 0 );
//Sim2
init( MIN_OPEN_TIME, 0.0002 );
init( MAX_OPEN_TIME, 0.0012 );
init( SIM_DISK_IOPS, 5000 );
init( SIM_DISK_BANDWIDTH, 50000000 );
init( MIN_NETWORK_LATENCY, 100e-6 );
init( FAST_NETWORK_LATENCY, 800e-6 );
init( SLOW_NETWORK_LATENCY, 100e-3 );
init( MAX_CLOGGING_LATENCY, 0 ); if( randomize && BUGGIFY ) MAX_CLOGGING_LATENCY = 0.1 * deterministicRandom()->random01();
init( MAX_BUGGIFIED_DELAY, 0 ); if( randomize && BUGGIFY ) MAX_BUGGIFIED_DELAY = 0.2 * deterministicRandom()->random01();
init( MAX_RUNLOOP_SLEEP_DELAY, 0 );
init( SIM_CONNECT_ERROR_MODE, deterministicRandom()->randomInt(0,3) );
//Tracefiles
init( ZERO_LENGTH_FILE_PAD, 1 );
init( TRACE_FLUSH_INTERVAL, 0.25 );
init( TRACE_RETRY_OPEN_INTERVAL, 1.00 );
init( MIN_TRACE_SEVERITY, isSimulated ? 1 : 10, Atomic::NO ); // Related to the trace severity in Trace.h
init( MAX_TRACE_SUPPRESSIONS, 1e4 );
init( TRACE_DATETIME_ENABLED, true ); // trace time in human readable format (always real time)
init( TRACE_SYNC_ENABLED, 0 );
init( TRACE_EVENT_METRIC_UNITS_PER_SAMPLE, 500 );
init( TRACE_EVENT_THROTTLER_SAMPLE_EXPIRY, 1800.0 ); // 30 mins
init( TRACE_EVENT_THROTTLER_MSG_LIMIT, 20000 );
init( MAX_TRACE_FIELD_LENGTH, 495 ); // If the value of this is changed, the corresponding default in Trace.cpp should be changed as well
init( MAX_TRACE_EVENT_LENGTH, 4000 ); // If the value of this is changed, the corresponding default in Trace.cpp should be changed as well
init( ALLOCATION_TRACING_ENABLED, true );
init( SIM_SPEEDUP_AFTER_SECONDS, 450 );
init( MAX_TRACE_LINES, 1'000'000 );
init( CODE_COV_TRACE_EVENT_SEVERITY, 10 ); // Code coverage TraceEvent severity level
//TDMetrics
init( MAX_METRICS, 600 );
init( MAX_METRIC_SIZE, 2500, Atomic::NO );
init( MAX_METRIC_LEVEL, 25 );
init( METRIC_LEVEL_DIVISOR, log(4) );
init( METRIC_LIMIT_START_QUEUE_SIZE, 10 ); // The queue size at which to start restricting logging by disabling levels
init( METRIC_LIMIT_RESPONSE_FACTOR, 10 ); // The additional queue size at which to disable logging of another level (higher == less restrictive)
//Load Balancing
init( LOAD_BALANCE_ZONE_ID_LOCALITY_ENABLED, 0 );
init( LOAD_BALANCE_DC_ID_LOCALITY_ENABLED, 1 );
init( LOAD_BALANCE_MAX_BACKOFF, 5.0 );
init( LOAD_BALANCE_START_BACKOFF, 0.01 );
init( LOAD_BALANCE_BACKOFF_RATE, 2.0 );
init( MAX_LAGGING_REQUESTS_OUTSTANDING, 100000 );
init( INSTANT_SECOND_REQUEST_MULTIPLIER, 2.0 );
init( BASE_SECOND_REQUEST_TIME, 0.0005 );
init( SECOND_REQUEST_MULTIPLIER_GROWTH, 0.01 );
init( SECOND_REQUEST_MULTIPLIER_DECAY, 0.00025 );
init( SECOND_REQUEST_BUDGET_GROWTH, 0.05 );
init( SECOND_REQUEST_MAX_BUDGET, 100.0 );
init( ALTERNATIVES_FAILURE_RESET_TIME, 5.0 );
init( ALTERNATIVES_FAILURE_MIN_DELAY, 0.05 );
init( ALTERNATIVES_FAILURE_DELAY_RATIO, 0.2 );
init( ALTERNATIVES_FAILURE_MAX_DELAY, 1.0 );
init( ALTERNATIVES_FAILURE_SLOW_DELAY_RATIO, 0.04 );
init( ALTERNATIVES_FAILURE_SLOW_MAX_DELAY, 30.0 );
init( ALTERNATIVES_FAILURE_SKIP_DELAY, 1.0 );
init( FUTURE_VERSION_INITIAL_BACKOFF, 1.0 );
init( FUTURE_VERSION_MAX_BACKOFF, 8.0 );
init( FUTURE_VERSION_BACKOFF_GROWTH, 2.0 );
init( LOAD_BALANCE_MAX_BAD_OPTIONS, 1 ); //should be the same as MAX_MACHINES_FALLING_BEHIND
init( LOAD_BALANCE_PENALTY_IS_BAD, true );
init( BASIC_LOAD_BALANCE_UPDATE_RATE, 10.0 ); //should be longer than the rate we log network metrics
init( BASIC_LOAD_BALANCE_MAX_CHANGE, 0.10 );
init( BASIC_LOAD_BALANCE_MAX_PROB, 2.0 );
init( BASIC_LOAD_BALANCE_MIN_REQUESTS, 20 ); //do not adjust LB probabilities if the proxies are less than releasing less than 20 transactions per second
init( BASIC_LOAD_BALANCE_MIN_CPU, 0.05 ); //do not adjust LB probabilities if the proxies are less than 5% utilized
init( BASIC_LOAD_BALANCE_BUCKETS, 40 ); //proxies bin recent GRV requests into 40 time bins
init( BASIC_LOAD_BALANCE_COMPUTE_PRECISION, 10000 ); //determines how much of the LB usage is holding the CPU usage of the proxy
init( LOAD_BALANCE_TSS_TIMEOUT, 5.0 );
init( LOAD_BALANCE_TSS_MISMATCH_VERIFY_SS, true ); if( randomize && BUGGIFY ) LOAD_BALANCE_TSS_MISMATCH_VERIFY_SS = false; // Whether the client should validate the SS teams all agree on TSS mismatch
init( LOAD_BALANCE_TSS_MISMATCH_TRACE_FULL, false ); if( randomize && BUGGIFY ) LOAD_BALANCE_TSS_MISMATCH_TRACE_FULL = true; // If true, saves the full details of the mismatch in a trace event. If false, saves them in the DB and the trace event references the DB row.
init( TSS_LARGE_TRACE_SIZE, 50000 );
// Health Monitor
init( FAILURE_DETECTION_DELAY, 4.0 ); if( randomize && BUGGIFY ) FAILURE_DETECTION_DELAY = 1.0;
init( HEALTH_MONITOR_MARK_FAILED_UNSTABLE_CONNECTIONS, true );
init( HEALTH_MONITOR_CLIENT_REQUEST_INTERVAL_SECS, 30 );
init( HEALTH_MONITOR_CONNECTION_MAX_CLOSED, 5 );
// Encryption
init( ENCRYPT_CIPHER_KEY_CACHE_TTL, isSimulated ? 5 * 60 : 10 * 60 );
if ( randomize && BUGGIFY) { ENCRYPT_CIPHER_KEY_CACHE_TTL = deterministicRandom()->randomInt(2, 10) * 60; }
init( ENCRYPT_KEY_REFRESH_INTERVAL, isSimulated ? 60 : 8 * 60 );
if ( randomize && BUGGIFY) { ENCRYPT_KEY_REFRESH_INTERVAL = deterministicRandom()->randomInt(2, 10); }
init( TOKEN_CACHE_SIZE, 100 );
init( ENCRYPT_KEY_CACHE_LOGGING_INTERVAL, 5.0 );
init( ENCRYPT_KEY_CACHE_LOGGING_SAMPLE_SIZE, 1000 );
// Refer to EncryptUtil::EncryptAuthTokenAlgo for more details
init( ENCRYPT_HEADER_AUTH_TOKEN_ENABLED, true ); if ( randomize && BUGGIFY ) { ENCRYPT_HEADER_AUTH_TOKEN_ENABLED = !ENCRYPT_HEADER_AUTH_TOKEN_ENABLED; }
init( ENCRYPT_HEADER_AUTH_TOKEN_ALGO, 1 ); if ( randomize && BUGGIFY ) { ENCRYPT_HEADER_AUTH_TOKEN_ALGO = getRandomAuthTokenAlgo(); }
// REST Client
init( RESTCLIENT_MAX_CONNECTIONPOOL_SIZE, 10 );
init( RESTCLIENT_CONNECT_TRIES, 10 );
init( RESTCLIENT_CONNECT_TIMEOUT, 10 );
init( RESTCLIENT_MAX_CONNECTION_LIFE, 120 );
init( RESTCLIENT_REQUEST_TRIES, 10 );
init( RESTCLIENT_REQUEST_TIMEOUT_SEC, 120 );
}
// clang-format on
static std::string toLower(std::string const& name) {
std::string lower_name;
for (auto c = name.begin(); c != name.end(); ++c)
if (*c >= 'A' && *c <= 'Z')
lower_name += *c - 'A' + 'a';
else
lower_name += *c;
return lower_name;
}
// Converts the given string into a double. If any errors are
// encountered, it throws an invalid_option_value exception.
static double safe_stod(std::string const& str) {
size_t n;
double value = std::stod(str, &n);
if (n < str.size()) {
throw invalid_option_value();
}
return value;
}
// Converts the given (possibly hexadecimal) string into an
// integer. If any errors are encountered, it throws an
// invalid_option_value exception.
static int safe_stoi(std::string const& str) {
size_t n;
int value = std::stoi(str, &n, 0);
if (n < str.size()) {
throw invalid_option_value();
}
return value;
}
// Converts the given (possibly hexadecimal) string into a 64-bit
// integer. If any errors are encountered, it throws an
// invalid_option_value exception.
static int64_t safe_stoi64(std::string const& str) {
size_t n;
int64_t value = static_cast<int64_t>(std::stoll(str, &n, 0));
if (n < str.size()) {
throw invalid_option_value();
}
return value;
}
// Converts the given string into a bool. "true" and "false" are case
// insenstively interpreted as true and false. Otherwise, any non-zero
// integer is true. If any errors are encountered, it throws an
// invalid_option_value exception.
static bool safe_stob(std::string const& str) {
if (toLower(str) == "true") {
return true;
} else if (toLower(str) == "false") {
return false;
} else {
return safe_stoi(str) != 0;
}
}
// Parses a string value into the appropriate type based upon the knob
// name. If any errors are encountered, it throws an
// invalid_option_value exception.
ParsedKnobValue Knobs::parseKnobValue(std::string const& knob, std::string const& value) const {
try {
if (double_knobs.count(knob)) {
return safe_stod(value);
} else if (bool_knobs.count(knob)) {
return safe_stob(value);
} else if (int64_knobs.count(knob)) {
return safe_stoi64(value);
} else if (int_knobs.count(knob)) {
return safe_stoi(value);
} else if (string_knobs.count(knob)) {
return value;
}
return NoKnobFound{};
} catch (...) {
throw invalid_option_value();
}
}
bool Knobs::setKnob(std::string const& knob, int value) {
if (!int_knobs.count(knob)) {
return false;
}
*int_knobs[knob].value = value;
explicitlySetKnobs.insert(toLower(knob));
return true;
}
bool Knobs::setKnob(std::string const& knob, int64_t value) {
if (!int64_knobs.count(knob)) {
return false;
}
*int64_knobs[knob].value = value;
explicitlySetKnobs.insert(toLower(knob));
return true;
}
bool Knobs::setKnob(std::string const& knob, bool value) {
if (!bool_knobs.count(knob)) {
return false;
}
*bool_knobs[knob].value = value;
explicitlySetKnobs.insert(toLower(knob));
return true;
}
bool Knobs::setKnob(std::string const& knob, double value) {
if (!double_knobs.count(knob)) {
return false;
}
*double_knobs[knob].value = value;
explicitlySetKnobs.insert(toLower(knob));
return true;
}
bool Knobs::setKnob(std::string const& knob, std::string const& value) {
if (!string_knobs.count(knob)) {
return false;
}
*string_knobs[knob].value = value;
explicitlySetKnobs.insert(toLower(knob));
return true;
}
ParsedKnobValue Knobs::getKnob(const std::string& name) const {
if (double_knobs.count(name) > 0) {
return ParsedKnobValue{ *double_knobs.at(name).value };
}
if (int64_knobs.count(name) > 0) {
return ParsedKnobValue{ *int64_knobs.at(name).value };
}
if (int_knobs.count(name) > 0) {
return ParsedKnobValue{ *int_knobs.at(name).value };
}
if (string_knobs.count(name) > 0) {
return ParsedKnobValue{ *string_knobs.at(name).value };
}
if (bool_knobs.count(name) > 0) {
return ParsedKnobValue{ *bool_knobs.at(name).value };
}
return ParsedKnobValue{ NoKnobFound() };
}
bool Knobs::isAtomic(std::string const& knob) const {
if (double_knobs.count(knob)) {
return double_knobs.find(knob)->second.atomic == Atomic::YES;
} else if (int64_knobs.count(knob)) {
return int64_knobs.find(knob)->second.atomic == Atomic::YES;
} else if (int_knobs.count(knob)) {
return int_knobs.find(knob)->second.atomic == Atomic::YES;
} else if (string_knobs.count(knob)) {
return string_knobs.find(knob)->second.atomic == Atomic::YES;
} else if (bool_knobs.count(knob)) {
return bool_knobs.find(knob)->second.atomic == Atomic::YES;
}
return false;
}
void Knobs::initKnob(double& knob, double value, std::string const& name, Atomic atomic) {
if (!explicitlySetKnobs.count(toLower(name))) {
knob = value;
double_knobs[toLower(name)] = KnobValue<double>{ &knob, atomic };
}
}
void Knobs::initKnob(int64_t& knob, int64_t value, std::string const& name, Atomic atomic) {
if (!explicitlySetKnobs.count(toLower(name))) {
knob = value;
int64_knobs[toLower(name)] = KnobValue<int64_t>{ &knob, atomic };
}
}
void Knobs::initKnob(int& knob, int value, std::string const& name, Atomic atomic) {
if (!explicitlySetKnobs.count(toLower(name))) {
knob = value;
int_knobs[toLower(name)] = KnobValue<int>{ &knob, atomic };
}
}
void Knobs::initKnob(std::string& knob, const std::string& value, const std::string& name, Atomic atomic) {
if (!explicitlySetKnobs.count(toLower(name))) {
knob = value;
string_knobs[toLower(name)] = KnobValue<std::string>{ &knob, atomic };
}
}
void Knobs::initKnob(bool& knob, bool value, std::string const& name, Atomic atomic) {
if (!explicitlySetKnobs.count(toLower(name))) {
knob = value;
bool_knobs[toLower(name)] = KnobValue<bool>{ &knob, atomic };
}
}
void Knobs::trace() const {
for (auto& k : double_knobs)
TraceEvent("Knob")
.detail("Name", k.first.c_str())
.detail("Value", *k.second.value)
.detail("Atomic", k.second.atomic);
for (auto& k : int_knobs)
TraceEvent("Knob")
.detail("Name", k.first.c_str())
.detail("Value", *k.second.value)
.detail("Atomic", k.second.atomic);
for (auto& k : int64_knobs)
TraceEvent("Knob")
.detail("Name", k.first.c_str())
.detail("Value", *k.second.value)
.detail("Atomic", k.second.atomic);
for (auto& k : string_knobs)
TraceEvent("Knob")
.detail("Name", k.first.c_str())
.detail("Value", *k.second.value)
.detail("Atomic", k.second.atomic);
for (auto& k : bool_knobs)
TraceEvent("Knob")
.detail("Name", k.first.c_str())
.detail("Value", *k.second.value)
.detail("Atomic", k.second.atomic);
}
TEST_CASE("/flow/Knobs/ParseKnobValue") {
// Test the safe conversion functions.
ASSERT_EQ(safe_stod("4.0"), 4.0);
ASSERT_EQ(safe_stoi("4"), 4);
ASSERT_EQ(safe_stoi64("4"), (int64_t)4);
try {
[[maybe_unused]] int64_t value = safe_stoi64("4GiB");
UNREACHABLE();
} catch (Error& e) {
ASSERT_EQ(e.code(), error_code_invalid_option_value);
}
ASSERT_EQ(safe_stob("true"), true);
ASSERT_EQ(safe_stob("false"), false);
return Void();
}