/* This file is part of VoltDB.
* Copyright (C) 2008-2014 VoltDB Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*/
/*
* This samples uses the native asynchronous request processing protocol
* to post requests to the VoltDB server, thus leveraging to the maximum
* VoltDB's ability to run requests in parallel on multiple database
* partitions, and multiple servers.
*
* While asynchronous processing is (marginally) more convoluted to work
* with and not adapted to all workloads, it is the preferred interaction
* model to VoltDB as it guarantees blazing performance.
*
* Because there is a risk of 'firehosing' a database cluster (if the
* cluster is too slow (slow or too few CPUs), this sample performs
* auto-tuning to target a specific latency (5ms by default).
* This tuning process, as demonstrated here, is important and should be
* part of your pre-launch evaluation so you can adequately provision your
* VoltDB cluster with the number of servers required for your needs.
*/
package measureoverhead;
import java.util.Random;
import java.util.Timer;
import java.util.TimerTask;
import java.util.concurrent.CountDownLatch;
import java.util.concurrent.atomic.AtomicLong;
import org.voltcore.logging.VoltLogger;
import org.voltcore.utils.Pair;
import org.voltdb.CLIConfig;
import org.voltdb.client.Client;
import org.voltdb.client.ClientConfig;
import org.voltdb.client.ClientFactory;
import org.voltdb.client.ClientResponse;
import org.voltdb.client.ClientStats;
import org.voltdb.client.ClientStatsContext;
import org.voltdb.client.ClientStatusListenerExt;
import org.voltdb.client.NullCallback;
import org.voltdb.client.ProcedureCallback;
public class MOBenchmark {
static VoltLogger log = new VoltLogger("HOST");
// handy, rather than typing this out several times
static final String HORIZONTAL_RULE =
"----------" + "----------" + "----------" + "----------" +
"----------" + "----------" + "----------" + "----------" + "\n";
// validated command line configuration
final MOConfig config;
// Reference to the database connection we will use
final Client client;
// Phone number generator
// Timer for periodic stats printing
Timer timer;
// Benchmark start time
long benchmarkStartTS;
// Statistics manager objects from the client
final ClientStatsContext periodicStatsContext;
final ClientStatsContext fullStatsContext;
final AtomicLong mproCount = new AtomicLong(0);
final AtomicLong mprwCount = new AtomicLong(0);
final AtomicLong sproCount = new AtomicLong(0);
final AtomicLong sprwCount = new AtomicLong(0);
final byte[] payload;
final Random rand = new Random();
/**
* Uses included {@link CLIConfig} class to
* declaratively state command line options with defaults
* and validation.
*/
static class MOConfig extends CLIConfig {
@Option(desc = "Interval for performance feedback, in seconds.")
long displayinterval = 5;
@Option(desc = "Benchmark duration, in seconds.")
int duration = 20;
@Option(desc = "Warmup duration in seconds.")
int warmup = 2;
@Option(desc = "Comma separated list of the form server[:port] to connect to.")
String servers = "localhost";
@Option(desc = "Maximum TPS rate for benchmark.")
int ratelimit = Integer.MAX_VALUE;
@Option(desc = "Determine transaction rate dynamically based on latency.")
boolean autotune = false;
@Option(desc = "Server-side latency target for auto-tuning.")
int latencytarget = 5;
@Option(desc = "Filename to write raw summary statistics to.")
String statsfile = "";
@Option(desc = "User name for connection.")
String user = "";
@Option(desc = "Password for connection.")
String password = "";
@Option(desc = "Scale factor for MP RW workload.")
double mprwscale = 0;
@Option(desc = "Scale factor for MP RO workload.")
double mproscale = 0;
@Option(desc = "Scale factor for SP RW workload.")
double sprwscale = 0;
@Option(desc = "Scale factor for SP RO workload.")
double sproscale = 0;
@Option(desc = "Size of parameter payload in bytes.")
int payloadbytes = 0;
@Override
public void validate() {
if (duration <= 0) exitWithMessageAndUsage("duration must be > 0");
if (warmup < 0) exitWithMessageAndUsage("warmup must be >= 0");
if (displayinterval <= 0) exitWithMessageAndUsage("displayinterval must be > 0");
if (ratelimit <= 0) exitWithMessageAndUsage("ratelimit must be > 0");
if (latencytarget <= 0) exitWithMessageAndUsage("latencytarget must be > 0");
if (sproscale < 0) exitWithMessageAndUsage("sproscale must be >= 0");
if (sprwscale < 0) exitWithMessageAndUsage("sprwscale must be >= 0");
if (mproscale < 0) exitWithMessageAndUsage("mproscale must be >= 0");
if (mprwscale < 0) exitWithMessageAndUsage("mprwscale must be >= 0");
if ((mprwscale + mproscale + sproscale + sprwscale) <= 0)
exitWithMessageAndUsage("sum load scale factors must be > 0");
if (payloadbytes < 0) exitWithMessageAndUsage("payloadbytes must be >= 0");
}
}
/**
* Provides a callback to be notified on node failure.
* This example only logs the event.
*/
class StatusListener extends ClientStatusListenerExt {
@Override
public void connectionLost(String hostname, int port, int connectionsLeft, DisconnectCause cause) {
// if the benchmark is still active
if ((System.currentTimeMillis() - benchmarkStartTS) < (config.duration * 1000)) {
System.err.printf("Connection to %s:%d was lost.\n", hostname, port);
}
}
}
/**
* Constructor for benchmark instance.
* Configures VoltDB client and prints configuration.
*
* @param config Parsed & validated CLI options.
*/
public MOBenchmark(MOConfig config) {
this.config = config;
// make a payload
payload = new byte[config.payloadbytes];
rand.nextBytes(payload);
ClientConfig clientConfig = new ClientConfig(config.user, config.password, new StatusListener());
if (config.autotune) {
clientConfig.enableAutoTune();
clientConfig.setAutoTuneTargetInternalLatency(config.latencytarget);
}
else {
clientConfig.setMaxTransactionsPerSecond(config.ratelimit);
}
client = ClientFactory.createClient(clientConfig);
periodicStatsContext = client.createStatsContext();
fullStatsContext = client.createStatsContext();
System.out.print(HORIZONTAL_RULE);
System.out.println(" Command Line Configuration");
System.out.println(HORIZONTAL_RULE);
System.out.println(config.getConfigDumpString());
}
/**
* Connect to a single server with retry. Limited exponential backoff.
* No timeout. This will run until the process is killed if it's not
* able to connect.
*
* @param server hostname:port or just hostname (hostname can be ip).
*/
void connectToOneServerWithRetry(String server) {
int sleep = 1000;
while (true) {
try {
client.createConnection(server);
break;
}
catch (Exception e) {
System.err.printf("Connection failed - retrying in %d second(s).\n", sleep / 1000);
try { Thread.sleep(sleep); } catch (Exception interruted) {}
if (sleep < 8000) sleep += sleep;
}
}
System.out.printf("Connected to VoltDB node at: %s.\n", server);
}
/**
* Connect to a set of servers in parallel. Each will retry until
* connection. This call will block until all have connected.
*
* @param servers A comma separated list of servers using the hostname:port
* syntax (where :port is optional).
* @throws InterruptedException if anything bad happens with the threads.
*/
void connect(String servers) throws InterruptedException {
System.out.println("Connecting to VoltDB...");
String[] serverArray = servers.split(",");
final CountDownLatch connections = new CountDownLatch(serverArray.length);
// use a new thread to connect to each server
for (final String server : serverArray) {
new Thread(new Runnable() {
@Override
public void run() {
connectToOneServerWithRetry(server);
connections.countDown();
}
}).start();
}
// block until all have connected
connections.await();
}
/**
* Create a Timer task to display performance data on the Vote procedure
* It calls printStatistics() every displayInterval seconds
*/
public void schedulePeriodicStats() {
timer = new Timer();
TimerTask statsPrinting = new TimerTask() {
@Override
public void run() { printStatistics(); }
};
timer.scheduleAtFixedRate(statsPrinting,
config.displayinterval * 1000,
config.displayinterval * 1000);
}
/**
* Prints a one line update on performance that can be printed
* periodically during a benchmark.
*/
public synchronized void printStatistics() {
ClientStats stats = periodicStatsContext.fetchAndResetBaseline().getStats();
long time = Math.round((stats.getEndTimestamp() - benchmarkStartTS) / 1000.0);
System.out.printf("%02d:%02d:%02d ", time / 3600, (time / 60) % 60, time % 60);
System.out.printf("Throughput %d/s, ", stats.getTxnThroughput());
System.out.printf("Aborts/Failures %d/%d, ",
stats.getInvocationAborts(), stats.getInvocationErrors());
System.out.printf("Avg/95%% Latency %.2f/%.2fms\n", stats.getAverageLatency(),
stats.kPercentileLatencyAsDouble(0.95));
}
/**
* Prints the results of the voting simulation and statistics
* about performance.
*
* @throws Exception if anything unexpected happens.
*/
public synchronized void printResults() throws Exception {
ClientStats stats = fullStatsContext.fetch().getStats();
// 3. Performance statistics
System.out.print(HORIZONTAL_RULE);
System.out.println(" Client Workload Statistics");
System.out.println(HORIZONTAL_RULE);
long total = mproCount.get() + mprwCount.get() + sproCount.get() + sprwCount.get();
System.out.printf("SP RO count: %,11d txns (%.2f%%)\n", sproCount.get(), (sproCount.get() * 100.0) / total);
System.out.printf("SP RW count: %,11d txns (%.2f%%)\n", sprwCount.get(), (sprwCount.get() * 100.0) / total);
System.out.printf("MP RO count: %,11d txns (%.2f%%)\n", mproCount.get(), (mproCount.get() * 100.0) / total);
System.out.printf("MP RW count: %,11d txns (%.2f%%)\n", mprwCount.get(), (mprwCount.get() * 100.0) / total);
System.out.printf("Average throughput: %,9d txns/sec\n", stats.getTxnThroughput());
System.out.printf("Average latency: %,9.2f ms\n", stats.getAverageLatency());
System.out.printf("95th percentile latency: %,9.2f ms\n", stats.kPercentileLatencyAsDouble(.95));
System.out.printf("99th percentile latency: %,9.2f ms\n", stats.kPercentileLatencyAsDouble(.99));
System.out.print("\n" + HORIZONTAL_RULE);
System.out.println(" System Server Statistics");
System.out.println(HORIZONTAL_RULE);
if (config.autotune) {
System.out.printf("Targeted Internal Avg Latency: %,9d ms\n", config.latencytarget);
}
System.out.printf("Reported Internal Avg Latency: %,9.2f ms\n", stats.getAverageInternalLatency());
// 4. Write stats to file if requested
client.writeSummaryCSV(stats, config.statsfile);
}
/**
* Callback to handle the response to a stored procedure call.
* Tracks response types.
*
*/
class MOCallback implements ProcedureCallback {
final AtomicLong counter;
MOCallback(AtomicLong counter) {
this.counter = counter;
}
@Override
public void clientCallback(ClientResponse response) throws Exception {
if (response.getStatus() == ClientResponse.SUCCESS) {
counter.incrementAndGet();
}
else {
System.exit(-1);
}
}
}
Pair<String, AtomicLong> nextProc() {
double scale = config.sproscale + config.sprwscale + config.mproscale + config.mprwscale;
double nextR = rand.nextDouble() * scale;
if (nextR < config.sproscale) {
return new Pair<String, AtomicLong>("MO_ROSP", sproCount);
}
else if (nextR < (config.sproscale + config.sprwscale)) {
return new Pair<String, AtomicLong>("MO_RWSP", sprwCount);
}
else if (nextR < (config.sproscale + config.sprwscale + config.mproscale)) {
return new Pair<String, AtomicLong>("MO_ROMP", mproCount);
}
else {
return new Pair<String, AtomicLong>("MO_RWMP", mprwCount);
}
}
/**
* Core benchmark code.
* Connect. Initialize. Run the loop. Cleanup. Print Results.
*
* @throws Exception if anything unexpected happens.
*/
public void runBenchmark() throws Exception {
System.out.print(HORIZONTAL_RULE);
System.out.println(" Setup & Initialization");
System.out.println(HORIZONTAL_RULE);
// connect to one or more servers, loop until success
connect(config.servers);
System.out.print(HORIZONTAL_RULE);
System.out.println("Starting Benchmark");
System.out.println(HORIZONTAL_RULE);
// Run the benchmark loop for the requested warmup time
// The throughput may be throttled depending on client configuration
System.out.println("Warming up...");
final long warmupEndTime = System.currentTimeMillis() + (1000l * config.warmup);
while (warmupEndTime > System.currentTimeMillis()) {
// asynchronously call the next procedure
client.callProcedure(new NullCallback(), nextProc().getFirst(), rand.nextInt(), payload);
}
// reset the stats after warmup
fullStatsContext.fetchAndResetBaseline();
periodicStatsContext.fetchAndResetBaseline();
// print periodic statistics to the console
benchmarkStartTS = System.currentTimeMillis();
schedulePeriodicStats();
// Run the benchmark loop for the requested duration
// The throughput may be throttled depending on client configuration
System.out.println("\nRunning benchmark...");
final long benchmarkEndTime = System.currentTimeMillis() + (1000l * config.duration);
while (benchmarkEndTime > System.currentTimeMillis()) {
// asynchronously call the next procedure
Pair<String, AtomicLong> next = nextProc();
client.callProcedure(new MOCallback(next.getSecond()), next.getFirst(), rand.nextInt(), payload);
}
// cancel periodic stats printing
timer.cancel();
// block until all outstanding txns return
client.drain();
// print the summary results
printResults();
// close down the client connections
client.close();
}
/**
* Main routine creates a benchmark instance and kicks off the run method.
*
* @param args Command line arguments.
* @throws Exception if anything goes wrong.
* @see {@link VoterConfig}
*/
public static void main(String[] args) throws Exception {
// create a configuration from the arguments
MOConfig config = new MOConfig();
config.parse(MOBenchmark.class.getName(), args);
MOBenchmark benchmark = new MOBenchmark(config);
benchmark.runBenchmark();
}
}