I'm trying to test the limits of the apache http client libraries and I'm running into a strange bottleneck. My test consists of the following:
A wiremock server that simulates a fixed 80ms delay
A unit test which uses an
org.apache.http.impl.nio.client.CloseableHttpAsyncClient
to make a configurable number of requests to the wiremock server as fast as possible, while gathering statistics.A unit test which uses an
org.apache.http.impl.client.CloseableHttpClient
to make a configurable number of requests to the wiremock server as fast as possible, from a configurable number of threads, while gathering statistics.A unit test which uses an
org.springframework.web.reactive.function.client.WebClient
to make a configurable number of requests to the wiremock server as fast as possible, while gathering statistics.
All of the the tests show the same performance numbers of 570 requests / second on my local machine. The CPU is very low when running these tests, about 5% utilization. So I can assume that the bottleneck is not in the CPU, but rather somewhere else...
My question is where is this bottleneck and how can we widen it?
My System Configuration:
- Processor: 3.1 GHz Quad-Core Intel Core i7
- Memory: 16 GB 2133 MHz LPDDR3
- OS: OSX 10.15.5
- Java version: 11.0.4
My Unit Test:
package com.blakeparmeter.bottleneck_mystery;
import org.apache.http.HttpResponse;
import org.apache.http.client.methods.CloseableHttpResponse;
import org.apache.http.client.methods.HttpGet;
import org.apache.http.concurrent.FutureCallback;
import org.apache.http.impl.client.CloseableHttpClient;
import org.apache.http.impl.client.HttpClientBuilder;
import org.apache.http.impl.nio.client.CloseableHttpAsyncClient;
import org.apache.http.impl.nio.client.HttpAsyncClients;
import org.junit.jupiter.api.Assertions;
import org.junit.jupiter.api.Test;
import java.io.IOException;
import java.net.URI;
import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.ForkJoinPool;
import java.util.stream.IntStream;
/**
* Used to illustrate a performance bottleneck with the apache HttpClients
*/
public class BottleneckTest {
// Test variables
final int totalTests = 5_000;
final long messageInterval = 1000; //ms
final URI testUri = URI.create("http://localhost:5000/wait/fixed/empty");
@Test
public void testSync() throws InterruptedException, ExecutionException {
final int numThreads = 100;
// Creates the sync client (unit under test)
final CloseableHttpClient unitUnderTest = HttpClientBuilder
.create()
.setMaxConnTotal(5000)
.setMaxConnPerRoute(5000)
.build();
// Run the test on an executor, send results to a stats aggregator
final ForkJoinPool executor = new ForkJoinPool(numThreads);
final StatsAggregator statsAggregator = new StatsAggregator(totalTests, messageInterval);
executor.submit(() -> IntStream.range(0, numThreads)
.parallel()
.forEach(threadNum -> IntStream.range(0, totalTests / numThreads).forEach(testNum -> {
final long runStart = System.currentTimeMillis();
try (final CloseableHttpResponse response = unitUnderTest.execute(new HttpGet(testUri))) {
// we don't need to do anything with the response, just make sure it's sent.
} catch (final IOException e) {
Assertions.fail(e);
}
statsAggregator.addTestDuration(System.currentTimeMillis() - runStart);
})))
.get();
// print the stats one last time (await is not needed since we wait on the executor)
statsAggregator.printStats();
}
@Test
public void testAsync() throws InterruptedException {
// Creates the async client (unit under test)
final CloseableHttpAsyncClient unitUnderTest = HttpAsyncClients.custom()
.setMaxConnTotal(5000)
.setMaxConnPerRoute(5000)
.build();
unitUnderTest.start();
// Runs all of the tests, sends results to a stats aggregator
final CountDownLatch testCountdown = new CountDownLatch(totalTests);
final StatsAggregator statsAggregator = new StatsAggregator(totalTests, messageInterval);
IntStream.range(0, totalTests).forEach(testNum -> {
final long runStart = System.currentTimeMillis();
unitUnderTest.execute(new HttpGet(testUri), new FutureCallback<>() {
@Override
public void completed(final HttpResponse response) {
statsAggregator.addTestDuration(System.currentTimeMillis() - runStart);
testCountdown.countDown();
}
@Override
public void failed(final Exception ex) {
Assertions.fail(ex.getMessage());
}
@Override
public void cancelled() {
Assertions.fail("Http Request Cancelled");
}
});
});
// await execution then print the stats one last time
testCountdown.await();
statsAggregator.printStats();
}
@Test
public void testReactive() {
final WebClient unitUnderTest = WebClient.builder().build();
// Runs all of the tests, sends results to a stats aggregator
final StatsAggregator statsAggregator = new StatsAggregator(totalTests, messageInterval);
Flux.range(0, totalTests)
.flatMap(testNum -> {
final long runStart = System.currentTimeMillis();
return unitUnderTest.get()
.uri(testUri)
.retrieve()
.bodyToMono(Object.class)
.doOnSuccess(obj -> statsAggregator.addTestDuration(System.currentTimeMillis() - runStart));
})
.then()
.block();
// print the stats one last time
statsAggregator.printStats();
}
}
StatsAggregator.java:
package com.blakeparmeter.bottleneck_mystery;
import java.text.DecimalFormat;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.Timer;
import java.util.TimerTask;
/**
* @author Blake L. Parmeter
*/
public class StatsAggregator {
private static final DecimalFormat testCompleteFormat = new DecimalFormat("###,###,###");
private static final DecimalFormat avgRequestFormat = new DecimalFormat("###,###.##");
private final long start = System.currentTimeMillis();
private final List<Long> times;
private final TimerTask renderStatisticsTask;
// Creates a timer task to calculate and render runtime stats in realtime.
public StatsAggregator(final int totalTests, final long messageIntervalMillis) {
this.times = new ArrayList<>(totalTests);
renderStatisticsTask = new TimerTask() {
private Long lastLogTime = null;
private Integer lastLogSize = null;
@Override
public void run() {
// Init variables needed for calculations
final long logTime = System.currentTimeMillis();
final List<Long> statsCopy;
synchronized (times) {
if (!times.isEmpty()) {
statsCopy = new ArrayList<>(times);
} else {
System.out.println("No statistics have been loaded. Statistics will not be calculated.");
return;
}
}
Collections.sort(statsCopy);
// print execution completion status
System.out.println();
final double percentComplete = ((double) statsCopy.size() / (double) totalTests);
final long runtime = logTime - start; //ms
final double estimatedTimeRemaining = ((double) runtime / percentComplete) - (double) runtime; //ms
System.out.println(testCompleteFormat.format(statsCopy.size())
+ "\tTests completed of:"
+ testCompleteFormat.format(totalTests)
+ "\t"
+ avgRequestFormat.format(percentComplete * 100)
+ "% complete. "
+ "Running for: "
+ runtime / 1000d
+ " seconds. "
+ "Estimated Time remaining: "
+ testCompleteFormat.format(estimatedTimeRemaining / 1000d)
+ " seconds.");
// print running average requests / second
String sinceLastLogStats = "";
if (lastLogSize != null && lastLogTime != null) {
double numSinceLastLog = (double) statsCopy.size() - lastLogSize;
double timeSinceLastLog = (double) logTime - lastLogTime;
double avgReqPerSecSinceLastLogSec = 1000 * (numSinceLastLog / timeSinceLastLog);
sinceLastLogStats = "\tavg req/sec:"
+ avgRequestFormat.format(avgReqPerSecSinceLastLogSec)
+ "(since last run)";
}
lastLogSize = statsCopy.size();
lastLogTime = logTime;
double avgReqPerSec = 1000 * ((double) statsCopy.size() / (double) (logTime - start));
System.out.println("\tavg req/sec:"
+ avgRequestFormat.format(avgReqPerSec)
+ "(total)"
+ sinceLastLogStats);
// print average min and max
double avg = (double) statsCopy.stream().reduce(Long::sum).orElseThrow() / (double) statsCopy.size();
System.out.println("\tavg:" + avgRequestFormat.format(avg) +
"\tmin:" + statsCopy.get(0) +
"\tmax:" + statsCopy.get(statsCopy.size() - 1));
// print percentiles
System.out.println("\tRequest duration percentiles:\n" +
"\t\t1%:" + percentile(statsCopy, 1) +
"\t5%:" + percentile(statsCopy, 5) +
"\t10%:" + percentile(statsCopy, 10) +
"\t50%:" + percentile(statsCopy, 50) +
"\t90%:" + percentile(statsCopy, 90) +
"\t95%:" + percentile(statsCopy, 95) +
"\t99%:" + percentile(statsCopy, 99) +
"\t99.9%:" + percentile(statsCopy, 99.9) +
"\t99.99%:" + percentile(statsCopy, 99.99));
System.out.println("\tCalculations took:" + (System.currentTimeMillis() - logTime) + "ms.");
}
};
// Schedule printing of statistics on a timer
final Timer timer = new Timer("test-output-timer", true);
timer.schedule(renderStatisticsTask,messageIntervalMillis,messageIntervalMillis);
}
public void printStats() {
renderStatisticsTask.run();
}
public void addTestDuration(final long time) {
times.add(time);
}
private static long percentile(List<Long> times, double percentile) {
int index = (int) Math.ceil(percentile / 100.0 * times.size());
return times.get(index - 1);
}
}
Running wiremock for this test:
- Download the standalone jar from here: http://wiremock.org/docs/running-standalone/ into a directory which will be referred to as
<wiremock_directory>
in these instructions. The file downloaded will be referred as<wiremock.jar>
- Create a directory
<wiremock_directory>/mappings
- Create a file named endpoint.json and put it in
<wiremock_directory>/mappings
{
"request": {
"method": "GET",
"urlPathPattern": "/wait/fixed/empty"
},
"response": {
"headers": {
"Content-Type": "application/json;charset=UTF-8"
},
"status": 200,
"fixedDelayMilliseconds": 80
}
}
- Run wiremock in a mode that can handle high concurrency using the command:
java -jar <wiremock.jar> --port 5000 --container-threads 250 --jetty-acceptor-threads 200 --no-request-journal
NOTE: replace the file name in the command with the file downloaded.