org.apache.flink.api.java.io.TextInputFormat Java Examples

@Test
public void testInvalidPathSpecification() throws Exception {

	String invalidPath = "hdfs://" + hdfsCluster.getURI().getHost() + ":" + hdfsCluster.getNameNodePort() + "/invalid/";
	TextInputFormat format = new TextInputFormat(new Path(invalidPath));

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_ONCE, 1, INTERVAL);
	try {
		monitoringFunction.run(new DummySourceContext() {
			@Override
			public void collect(TimestampedFileInputSplit element) {
				// we should never arrive here with an invalid path
				Assert.fail("Test passes with an invalid path.");
			}
		});

		// we should never arrive here with an invalid path
		Assert.fail("Test passed with an invalid path.");

	} catch (FileNotFoundException e) {
		Assert.assertEquals("The provided file path " + format.getFilePath() + " does not exist.", e.getMessage());
	}
}
 

@Test
public void testInvalidPathSpecification() throws Exception {

	String invalidPath = "hdfs://" + hdfsCluster.getURI().getHost() + ":" + hdfsCluster.getNameNodePort() + "/invalid/";
	TextInputFormat format = new TextInputFormat(new Path(invalidPath));

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_ONCE, 1, INTERVAL);
	try {
		monitoringFunction.run(new DummySourceContext() {
			@Override
			public void collect(TimestampedFileInputSplit element) {
				// we should never arrive here with an invalid path
				Assert.fail("Test passes with an invalid path.");
			}
		});

		// we should never arrive here with an invalid path
		Assert.fail("Test passed with an invalid path.");

	} catch (FileNotFoundException e) {
		Assert.assertEquals("The provided file path " + format.getFilePath() + " does not exist.", e.getMessage());
	}
}
 

@Test
public void testInvalidPathSpecification() throws Exception {

	String invalidPath = "hdfs://" + hdfsCluster.getURI().getHost() + ":" + hdfsCluster.getNameNodePort() + "/invalid/";
	TextInputFormat format = new TextInputFormat(new Path(invalidPath));

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_ONCE, 1, INTERVAL);
	try {
		monitoringFunction.run(new DummySourceContext() {
			@Override
			public void collect(TimestampedFileInputSplit element) {
				// we should never arrive here with an invalid path
				Assert.fail("Test passes with an invalid path.");
			}
		});

		// we should never arrive here with an invalid path
		Assert.fail("Test passed with an invalid path.");

	} catch (FileNotFoundException e) {
		Assert.assertEquals("The provided file path " + format.getFilePath() + " does not exist.", e.getMessage());
	}
}
 

public static void main(String... args) throws  Exception {
    File txtFile = new File("/tmp/test/file.txt");
    File csvFile = new File("/tmp/test/file.csv");
    File binFile = new File("/tmp/test/file.bin");

    writeToFile(txtFile, "txt");
    writeToFile(csvFile, "csv");
    writeToFile(binFile, "bin");

    final ExecutionEnvironment env =
            ExecutionEnvironment.getExecutionEnvironment();
    final TextInputFormat format = new TextInputFormat(new Path("/tmp/test"));

    GlobFilePathFilter filesFilter = new GlobFilePathFilter(
            Collections.singletonList("**"),
            Arrays.asList("**/file.bin")
    );
    System.out.println(Arrays.toString(GlobFilePathFilter.class.getDeclaredFields()));
    format.setFilesFilter(filesFilter);

    DataSet<String> result = env.readFile(format, "/tmp");
    result.writeAsText("/temp/out");
    env.execute("GlobFilePathFilter-Test");
}
 

@Override
public void testProgram(StreamExecutionEnvironment env) {

	env.enableCheckpointing(10);

	// create and start the file creating thread.
	fc = new FileCreator();
	fc.start();

	// create the monitoring source along with the necessary readers.
	TextInputFormat format = new TextInputFormat(new org.apache.flink.core.fs.Path(localFsURI));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	DataStream<String> inputStream = env.readFile(format, localFsURI,
		FileProcessingMode.PROCESS_CONTINUOUSLY, INTERVAL);

	TestingSinkFunction sink = new TestingSinkFunction();

	inputStream.flatMap(new FlatMapFunction<String, String>() {
		@Override
		public void flatMap(String value, Collector<String> out) throws Exception {
			out.collect(value);
		}
	}).addSink(sink).setParallelism(1);
}
 

@Override
public void translateNode(TextIO.Read.Bound<String> transform, FlinkBatchTranslationContext context) {
	String path = transform.getFilepattern();
	String name = transform.getName();

	TextIO.CompressionType compressionType = transform.getCompressionType();
	boolean needsValidation = transform.needsValidation();

	// TODO: Implement these. We need Flink support for this.
	LOG.warn("Translation of TextIO.CompressionType not yet supported. Is: {}.", compressionType);
	LOG.warn("Translation of TextIO.Read.needsValidation not yet supported. Is: {}.", needsValidation);

	PValue output = context.getOutput(transform);

	TypeInformation<String> typeInformation = context.getTypeInfo(output);
	DataSource<String> source = new DataSource<>(context.getExecutionEnvironment(), new TextInputFormat(new Path(path)), typeInformation, name);

	context.setOutputDataSet(output, source);
}
 

@Override
public void testProgram(StreamExecutionEnvironment env) {

	// set the restart strategy.
	env.getConfig().setRestartStrategy(RestartStrategies.fixedDelayRestart(NO_OF_RETRIES, 0));
	env.enableCheckpointing(10);

	// create and start the file creating thread.
	fc = new FileCreator();
	fc.start();

	// create the monitoring source along with the necessary readers.
	TextInputFormat format = new TextInputFormat(new org.apache.flink.core.fs.Path(localFsURI));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	DataStream<String> inputStream = env.readFile(format, localFsURI,
		FileProcessingMode.PROCESS_CONTINUOUSLY, INTERVAL);

	TestingSinkFunction sink = new TestingSinkFunction();

	inputStream.flatMap(new FlatMapFunction<String, String>() {
		@Override
		public void flatMap(String value, Collector<String> out) throws Exception {
			out.collect(value);
		}
	}).addSink(sink).setParallelism(1);
}
 

@Test
public void testSortingOnModTime() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final long[] modTimes = new long[NO_OF_FILES];
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];

	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		Thread.sleep(400);

		filesCreated[i] = file.f0;
		modTimes[i] = hdfs.getFileStatus(file.f0).getModificationTime();
	}

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// this is just to verify that all splits have been forwarded later.
	FileInputSplit[] splits = format.createInputSplits(1);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_ONCE);

	ModTimeVerifyingSourceContext context = new ModTimeVerifyingSourceContext(modTimes);

	monitoringFunction.open(new Configuration());
	monitoringFunction.run(context);
	Assert.assertEquals(splits.length, context.getCounter());

	// delete the created files.
	for (int i = 0; i < NO_OF_FILES; i++) {
		hdfs.delete(filesCreated[i], false);
	}
}
 

@Test
public void testSortingOnModTime() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final long[] modTimes = new long[NO_OF_FILES];
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];

	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		Thread.sleep(400);

		filesCreated[i] = file.f0;
		modTimes[i] = hdfs.getFileStatus(file.f0).getModificationTime();
	}

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// this is just to verify that all splits have been forwarded later.
	FileInputSplit[] splits = format.createInputSplits(1);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_ONCE);

	ModTimeVerifyingSourceContext context = new ModTimeVerifyingSourceContext(modTimes);

	monitoringFunction.open(new Configuration());
	monitoringFunction.run(context);
	Assert.assertEquals(splits.length, context.getCounter());

	// delete the created files.
	for (int i = 0; i < NO_OF_FILES; i++) {
		hdfs.delete(filesCreated[i], false);
	}
}
 

@Test
public void testSortingOnModTime() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final long[] modTimes = new long[NO_OF_FILES];
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];

	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		Thread.sleep(400);

		filesCreated[i] = file.f0;
		modTimes[i] = hdfs.getFileStatus(file.f0).getModificationTime();
	}

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// this is just to verify that all splits have been forwarded later.
	FileInputSplit[] splits = format.createInputSplits(1);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_ONCE);

	ModTimeVerifyingSourceContext context = new ModTimeVerifyingSourceContext(modTimes);

	monitoringFunction.open(new Configuration());
	monitoringFunction.run(context);
	Assert.assertEquals(splits.length, context.getCounter());

	// delete the created files.
	for (int i = 0; i < NO_OF_FILES; i++) {
		hdfs.delete(filesCreated[i], false);
	}
}
 

@Override
public void testProgram(StreamExecutionEnvironment env) {

	// set the restart strategy.
	env.getConfig().setRestartStrategy(RestartStrategies.fixedDelayRestart(NO_OF_RETRIES, 0));
	env.enableCheckpointing(10);

	// create and start the file creating thread.
	fc = new FileCreator();
	fc.start();

	// create the monitoring source along with the necessary readers.
	TextInputFormat format = new TextInputFormat(new org.apache.flink.core.fs.Path(localFsURI));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	DataStream<String> inputStream = env.readFile(format, localFsURI,
		FileProcessingMode.PROCESS_CONTINUOUSLY, INTERVAL);

	TestingSinkFunction sink = new TestingSinkFunction();

	inputStream.flatMap(new FlatMapFunction<String, String>() {
		@Override
		public void flatMap(String value, Collector<String> out) throws Exception {
			out.collect(value);
		}
	}).addSink(sink).setParallelism(1);
}
 

@Override
public void run() {

    JMetalLogger.logger.info("Run Fink method in the streaming data source invoked") ;
    JMetalLogger.logger.info("Directory: " + directoryName) ;

   // environment.getConfig().setRestartStrategy(RestartStrategies.fixedDelayRestart(1,0));
    //environment.enableCheckpointing(10);
    Path filePath = new Path(directoryName);
    TextInputFormat inputFormat = new TextInputFormat(filePath);
    inputFormat.setFilesFilter(FilePathFilter.createDefaultFilter());
    DataStreamSource<String> data =environment.readFile(inputFormat,directoryName,
            FileProcessingMode.PROCESS_CONTINUOUSLY,time);


    try {
        Iterator<String> it=DataStreamUtils.collect(data);
        while (it.hasNext()){
            Integer number = Integer.parseInt(it.next());
            observable.setChanged();
            observable.notifyObservers(new ObservedValue<Integer>(number));
        }

    } catch (Exception e){
        e.printStackTrace();
    }


}
 

@Test
public void testProgram() throws Exception {

	/*
	* This test checks the interplay between the monitor and the reader
	* and also the failExternally() functionality. To test the latter we
	* set the parallelism to 1 so that we have the chaining between the sink,
	* which throws the SuccessException to signal the end of the test, and the
	* reader.
	* */

	TextInputFormat format = new TextInputFormat(new Path(hdfsURI));
	format.setFilePath(hdfsURI);
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// create the stream execution environment with a parallelism > 1 to test
	final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
	env.setParallelism(PARALLELISM);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_CONTINUOUSLY,
			env.getParallelism(), INTERVAL);

	// the monitor has always DOP 1
	DataStream<TimestampedFileInputSplit> splits = env.addSource(monitoringFunction);
	Assert.assertEquals(1, splits.getParallelism());

	TypeInformation<String> typeInfo = TypeExtractor.getInputFormatTypes(format);

	// the readers can be multiple
	DataStream<String> content = splits.transform("FileSplitReader", typeInfo, new ContinuousFileReaderOperatorFactory<>(format));
	Assert.assertEquals(PARALLELISM, content.getParallelism());

	// finally for the sink we set the parallelism to 1 so that we can verify the output
	TestingSinkFunction sink = new TestingSinkFunction();
	content.addSink(sink).setParallelism(1);

	CompletableFuture<Void> jobFuture = new CompletableFuture<>();
	new Thread(() -> {
		try {
			env.execute("ContinuousFileProcessingITCase Job.");
			jobFuture.complete(null);
		} catch (Exception e) {
			if (ExceptionUtils.findThrowable(e, SuccessException.class).isPresent()) {
				jobFuture.complete(null);
			} else {
				jobFuture.completeExceptionally(e);
			}
		}
	}).start();

	// The modification time of the last created file.
	long lastCreatedModTime = Long.MIN_VALUE;

	// create the files to be read
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> tmpFile;
		long modTime;
		do {

			// give it some time so that the files have
			// different modification timestamps.
			Thread.sleep(50);

			tmpFile = fillWithData(hdfsURI, "file", i, "This is test line.");

			modTime = hdfs.getFileStatus(tmpFile.f0).getModificationTime();
			if (modTime <= lastCreatedModTime) {
				// delete the last created file to recreate it with a different timestamp
				hdfs.delete(tmpFile.f0, false);
			}
		} while (modTime <= lastCreatedModTime);
		lastCreatedModTime = modTime;

		// put the contents in the expected results list before the reader picks them
		// this is to guarantee that they are in before the reader finishes (avoid race conditions)
		expectedContents.put(i, tmpFile.f1);

		org.apache.hadoop.fs.Path file =
			new org.apache.hadoop.fs.Path(hdfsURI + "/file" + i);
		hdfs.rename(tmpFile.f0, file);
		Assert.assertTrue(hdfs.exists(file));
	}

	jobFuture.get();
}
 

@Test
public void testProcessContinuously() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final OneShotLatch latch = new OneShotLatch();

	// create a single file in the directory
	Tuple2<org.apache.hadoop.fs.Path, String> bootstrap =
		createFileAndFillWithData(testBasePath, "file", NO_OF_FILES + 1, "This is test line.");
	Assert.assertTrue(hdfs.exists(bootstrap.f0));

	final Set<String> filesToBeRead = new TreeSet<>();
	filesToBeRead.add(bootstrap.f0.getName());

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	final int totalNoOfFilesToBeRead = NO_OF_FILES + 1; // 1 for the bootstrap + NO_OF_FILES
	final FileVerifyingSourceContext context = new FileVerifyingSourceContext(latch,
		monitoringFunction, 1, totalNoOfFilesToBeRead);

	final Thread t = new Thread() {

		@Override
		public void run() {
			try {
				monitoringFunction.open(new Configuration());
				monitoringFunction.run(context);
			} catch (Exception e) {
				Assert.fail(e.getMessage());
			}
		}
	};
	t.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	// create some additional files that will be processed in the case of PROCESS_CONTINUOUSLY
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		filesCreated[i] = file.f0;
		filesToBeRead.add(file.f0.getName());
	}

	// wait until the monitoring thread exits
	t.join();

	Assert.assertArrayEquals(filesToBeRead.toArray(), context.getSeenFiles().toArray());

	// finally delete the files created for the test.
	hdfs.delete(bootstrap.f0, false);
	for (org.apache.hadoop.fs.Path path: filesCreated) {
		hdfs.delete(path, false);
	}
}
 

private static DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(new TextInputFormat(new Path("/")), new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO)));
}
 

private static final DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(
			new TextInputFormat(new Path("/ignored")), 
			new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO),
			"source"));
}
 

@Test
public void testProcessOnce() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final OneShotLatch latch = new OneShotLatch();

	// create a single file in the directory
	Tuple2<org.apache.hadoop.fs.Path, String> bootstrap =
		createFileAndFillWithData(testBasePath, "file", NO_OF_FILES + 1, "This is test line.");
	Assert.assertTrue(hdfs.exists(bootstrap.f0));

	// the source is supposed to read only this file.
	final Set<String> filesToBeRead = new TreeSet<>();
	filesToBeRead.add(bootstrap.f0.getName());

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_ONCE);

	final FileVerifyingSourceContext context = new FileVerifyingSourceContext(latch, monitoringFunction);

	final Thread t = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.open(new Configuration());
				monitoringFunction.run(context);

				// we would never arrive here if we were in
				// PROCESS_CONTINUOUSLY mode.

				// this will trigger the latch
				context.close();

			} catch (Exception e) {
				Assert.fail(e.getMessage());
			}
		}
	};
	t.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	// create some additional files that should be processed in the case of PROCESS_CONTINUOUSLY
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> ignoredFile =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		filesCreated[i] = ignoredFile.f0;
	}

	// wait until the monitoring thread exits
	t.join();

	Assert.assertArrayEquals(filesToBeRead.toArray(), context.getSeenFiles().toArray());

	// finally delete the files created for the test.
	hdfs.delete(bootstrap.f0, false);
	for (org.apache.hadoop.fs.Path path: filesCreated) {
		hdfs.delete(path, false);
	}
}
 

/**
 * Manually run this to write binary snapshot data. Remove @Ignore to run.
 */
@Ignore
@Test
public void writeMonitoringSourceSnapshot() throws Exception {

	File testFolder = tempFolder.newFolder();

	long fileModTime = Long.MIN_VALUE;
	for (int i = 0; i < 1; i++) {
		Tuple2<File, String> file = createFileAndFillWithData(testFolder, "file", i, "This is test line.");
		fileModTime = file.f0.lastModified();
	}

	TextInputFormat format = new TextInputFormat(new Path(testFolder.getAbsolutePath()));

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format, FileProcessingMode.PROCESS_CONTINUOUSLY, 1, INTERVAL);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> src =
		new StreamSource<>(monitoringFunction);

	final AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarness =
			new AbstractStreamOperatorTestHarness<>(src, 1, 1, 0);

	testHarness.open();

	final Throwable[] error = new Throwable[1];

	final OneShotLatch latch = new OneShotLatch();

	// run the source asynchronously
	Thread runner = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.run(new DummySourceContext() {
					@Override
					public void collect(TimestampedFileInputSplit element) {
						latch.trigger();
					}

					@Override
					public void markAsTemporarilyIdle() {

					}
				});
			}
			catch (Throwable t) {
				t.printStackTrace();
				error[0] = t;
			}
		}
	};
	runner.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	final OperatorSubtaskState snapshot;
	synchronized (testHarness.getCheckpointLock()) {
		snapshot = testHarness.snapshot(0L, 0L);
	}

	OperatorSnapshotUtil.writeStateHandle(
			snapshot,
			"src/test/resources/monitoring-function-migration-test-" + fileModTime + "-flink" + flinkGenerateSavepointVersion + "-snapshot");

	monitoringFunction.cancel();
	runner.join();

	testHarness.close();
}
 

@Test
public void testProcessOnce() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final OneShotLatch latch = new OneShotLatch();

	// create a single file in the directory
	Tuple2<org.apache.hadoop.fs.Path, String> bootstrap =
		createFileAndFillWithData(testBasePath, "file", NO_OF_FILES + 1, "This is test line.");
	Assert.assertTrue(hdfs.exists(bootstrap.f0));

	// the source is supposed to read only this file.
	final Set<String> filesToBeRead = new TreeSet<>();
	filesToBeRead.add(bootstrap.f0.getName());

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_ONCE);

	final FileVerifyingSourceContext context = new FileVerifyingSourceContext(latch, monitoringFunction);

	final Thread t = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.open(new Configuration());
				monitoringFunction.run(context);

				// we would never arrive here if we were in
				// PROCESS_CONTINUOUSLY mode.

				// this will trigger the latch
				context.close();

			} catch (Exception e) {
				Assert.fail(e.getMessage());
			}
		}
	};
	t.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	// create some additional files that should be processed in the case of PROCESS_CONTINUOUSLY
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> ignoredFile =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		filesCreated[i] = ignoredFile.f0;
	}

	// wait until the monitoring thread exits
	t.join();

	Assert.assertArrayEquals(filesToBeRead.toArray(), context.getSeenFiles().toArray());

	// finally delete the files created for the test.
	hdfs.delete(bootstrap.f0, false);
	for (org.apache.hadoop.fs.Path path: filesCreated) {
		hdfs.delete(path, false);
	}
}
 

@Test
public void testFunctionRestore() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	org.apache.hadoop.fs.Path path = null;
	long fileModTime = Long.MIN_VALUE;
	for (int i = 0; i < 1; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file = createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		path = file.f0;
		fileModTime = hdfs.getFileStatus(file.f0).getModificationTime();
	}

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> src =
		new StreamSource<>(monitoringFunction);

	final AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarness =
		new AbstractStreamOperatorTestHarness<>(src, 1, 1, 0);
	testHarness.open();

	final Throwable[] error = new Throwable[1];

	final OneShotLatch latch = new OneShotLatch();

	final DummySourceContext sourceContext = new DummySourceContext() {
		@Override
		public void collect(TimestampedFileInputSplit element) {
			latch.trigger();
		}
	};

	// run the source asynchronously
	Thread runner = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.run(sourceContext);
			}
			catch (Throwable t) {
				t.printStackTrace();
				error[0] = t;
			}
		}
	};
	runner.start();

	// first condition for the source to have updated its state: emit at least one element
	if (!latch.isTriggered()) {
		latch.await();
	}

	// second condition for the source to have updated its state: it's not on the lock anymore,
	// this means it has processed all the splits and updated its state.
	synchronized (sourceContext.getCheckpointLock()) {}

	OperatorSubtaskState snapshot = testHarness.snapshot(0, 0);
	monitoringFunction.cancel();
	runner.join();

	testHarness.close();

	final ContinuousFileMonitoringFunction<String> monitoringFunctionCopy =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> srcCopy =
		new StreamSource<>(monitoringFunctionCopy);

	AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarnessCopy =
		new AbstractStreamOperatorTestHarness<>(srcCopy, 1, 1, 0);
	testHarnessCopy.initializeState(snapshot);
	testHarnessCopy.open();

	Assert.assertNull(error[0]);
	Assert.assertEquals(fileModTime, monitoringFunctionCopy.getGlobalModificationTime());

	hdfs.delete(path, false);
}
 

@Test
public void testProcessContinuously() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	final OneShotLatch latch = new OneShotLatch();

	// create a single file in the directory
	Tuple2<org.apache.hadoop.fs.Path, String> bootstrap =
		createFileAndFillWithData(testBasePath, "file", NO_OF_FILES + 1, "This is test line.");
	Assert.assertTrue(hdfs.exists(bootstrap.f0));

	final Set<String> filesToBeRead = new TreeSet<>();
	filesToBeRead.add(bootstrap.f0.getName());

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	final int totalNoOfFilesToBeRead = NO_OF_FILES + 1; // 1 for the bootstrap + NO_OF_FILES
	final FileVerifyingSourceContext context = new FileVerifyingSourceContext(latch,
		monitoringFunction, 1, totalNoOfFilesToBeRead);

	final Thread t = new Thread() {

		@Override
		public void run() {
			try {
				monitoringFunction.open(new Configuration());
				monitoringFunction.run(context);
			} catch (Exception e) {
				Assert.fail(e.getMessage());
			}
		}
	};
	t.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	// create some additional files that will be processed in the case of PROCESS_CONTINUOUSLY
	final org.apache.hadoop.fs.Path[] filesCreated = new org.apache.hadoop.fs.Path[NO_OF_FILES];
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file =
			createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		filesCreated[i] = file.f0;
		filesToBeRead.add(file.f0.getName());
	}

	// wait until the monitoring thread exits
	t.join();

	Assert.assertArrayEquals(filesToBeRead.toArray(), context.getSeenFiles().toArray());

	// finally delete the files created for the test.
	hdfs.delete(bootstrap.f0, false);
	for (org.apache.hadoop.fs.Path path: filesCreated) {
		hdfs.delete(path, false);
	}
}
 

private static DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(new TextInputFormat(new Path("/")), new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO)));
}
 

private static final DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(
			new TextInputFormat(new Path("/ignored")), 
			new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO),
			"source"));
}
 

@Test
public void testFunctionRestore() throws Exception {
	String testBasePath = hdfsURI + "/" + UUID.randomUUID() + "/";

	org.apache.hadoop.fs.Path path = null;
	long fileModTime = Long.MIN_VALUE;
	for (int i = 0; i < 1; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> file = createFileAndFillWithData(testBasePath, "file", i, "This is test line.");
		path = file.f0;
		fileModTime = hdfs.getFileStatus(file.f0).getModificationTime();
	}

	TextInputFormat format = new TextInputFormat(new Path(testBasePath));

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> src =
		new StreamSource<>(monitoringFunction);

	final AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarness =
		new AbstractStreamOperatorTestHarness<>(src, 1, 1, 0);
	testHarness.open();

	final Throwable[] error = new Throwable[1];

	final OneShotLatch latch = new OneShotLatch();

	final DummySourceContext sourceContext = new DummySourceContext() {
		@Override
		public void collect(TimestampedFileInputSplit element) {
			latch.trigger();
		}
	};

	// run the source asynchronously
	Thread runner = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.run(sourceContext);
			}
			catch (Throwable t) {
				t.printStackTrace();
				error[0] = t;
			}
		}
	};
	runner.start();

	// first condition for the source to have updated its state: emit at least one element
	if (!latch.isTriggered()) {
		latch.await();
	}

	// second condition for the source to have updated its state: it's not on the lock anymore,
	// this means it has processed all the splits and updated its state.
	synchronized (sourceContext.getCheckpointLock()) {}

	OperatorSubtaskState snapshot = testHarness.snapshot(0, 0);
	monitoringFunction.cancel();
	runner.join();

	testHarness.close();

	final ContinuousFileMonitoringFunction<String> monitoringFunctionCopy =
		createTestContinuousFileMonitoringFunction(format, FileProcessingMode.PROCESS_CONTINUOUSLY);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> srcCopy =
		new StreamSource<>(monitoringFunctionCopy);

	AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarnessCopy =
		new AbstractStreamOperatorTestHarness<>(srcCopy, 1, 1, 0);
	testHarnessCopy.initializeState(snapshot);
	testHarnessCopy.open();

	Assert.assertNull(error[0]);
	Assert.assertEquals(fileModTime, monitoringFunctionCopy.getGlobalModificationTime());

	hdfs.delete(path, false);
}
 

/**
 * Manually run this to write binary snapshot data. Remove @Ignore to run.
 */
@Ignore
@Test
public void writeMonitoringSourceSnapshot() throws Exception {

	File testFolder = tempFolder.newFolder();

	long fileModTime = Long.MIN_VALUE;
	for (int i = 0; i < 1; i++) {
		Tuple2<File, String> file = createFileAndFillWithData(testFolder, "file", i, "This is test line.");
		fileModTime = file.f0.lastModified();
	}

	TextInputFormat format = new TextInputFormat(new Path(testFolder.getAbsolutePath()));

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format, FileProcessingMode.PROCESS_CONTINUOUSLY, 1, INTERVAL);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> src =
		new StreamSource<>(monitoringFunction);

	final AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarness =
			new AbstractStreamOperatorTestHarness<>(src, 1, 1, 0);

	testHarness.open();

	final Throwable[] error = new Throwable[1];

	final OneShotLatch latch = new OneShotLatch();

	// run the source asynchronously
	Thread runner = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.run(new DummySourceContext() {
					@Override
					public void collect(TimestampedFileInputSplit element) {
						latch.trigger();
					}

					@Override
					public void markAsTemporarilyIdle() {

					}
				});
			}
			catch (Throwable t) {
				t.printStackTrace();
				error[0] = t;
			}
		}
	};
	runner.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	final OperatorSubtaskState snapshot;
	synchronized (testHarness.getCheckpointLock()) {
		snapshot = testHarness.snapshot(0L, 0L);
	}

	OperatorSnapshotUtil.writeStateHandle(
			snapshot,
			"src/test/resources/monitoring-function-migration-test-" + fileModTime + "-flink" + flinkGenerateSavepointVersion + "-snapshot");

	monitoringFunction.cancel();
	runner.join();

	testHarness.close();
}
 

@Test
public void testProgram() throws Exception {

	/*
	* This test checks the interplay between the monitor and the reader
	* and also the failExternally() functionality. To test the latter we
	* set the parallelism to 1 so that we have the chaining between the sink,
	* which throws the SuccessException to signal the end of the test, and the
	* reader.
	* */

	TextInputFormat format = new TextInputFormat(new Path(hdfsURI));
	format.setFilePath(hdfsURI);
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// create the stream execution environment with a parallelism > 1 to test
	final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
	env.setParallelism(PARALLELISM);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_CONTINUOUSLY,
			env.getParallelism(), INTERVAL);

	// the monitor has always DOP 1
	DataStream<TimestampedFileInputSplit> splits = env.addSource(monitoringFunction);
	Assert.assertEquals(1, splits.getParallelism());

	ContinuousFileReaderOperator<String> reader = new ContinuousFileReaderOperator<>(format);
	TypeInformation<String> typeInfo = TypeExtractor.getInputFormatTypes(format);

	// the readers can be multiple
	DataStream<String> content = splits.transform("FileSplitReader", typeInfo, reader);
	Assert.assertEquals(PARALLELISM, content.getParallelism());

	// finally for the sink we set the parallelism to 1 so that we can verify the output
	TestingSinkFunction sink = new TestingSinkFunction();
	content.addSink(sink).setParallelism(1);

	Thread job = new Thread() {

		@Override
		public void run() {
			try {
				env.execute("ContinuousFileProcessingITCase Job.");
			} catch (Exception e) {
				Throwable th = e;
				for (int depth = 0; depth < 20; depth++) {
					if (th instanceof SuccessException) {
						return;
					} else if (th.getCause() != null) {
						th = th.getCause();
					} else {
						break;
					}
				}
				e.printStackTrace();
				Assert.fail(e.getMessage());
			}
		}
	};
	job.start();

	// The modification time of the last created file.
	long lastCreatedModTime = Long.MIN_VALUE;

	// create the files to be read
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> tmpFile;
		long modTime;
		do {

			// give it some time so that the files have
			// different modification timestamps.
			Thread.sleep(50);

			tmpFile = fillWithData(hdfsURI, "file", i, "This is test line.");

			modTime = hdfs.getFileStatus(tmpFile.f0).getModificationTime();
			if (modTime <= lastCreatedModTime) {
				// delete the last created file to recreate it with a different timestamp
				hdfs.delete(tmpFile.f0, false);
			}
		} while (modTime <= lastCreatedModTime);
		lastCreatedModTime = modTime;

		// put the contents in the expected results list before the reader picks them
		// this is to guarantee that they are in before the reader finishes (avoid race conditions)
		expectedContents.put(i, tmpFile.f1);

		org.apache.hadoop.fs.Path file =
			new org.apache.hadoop.fs.Path(hdfsURI + "/file" + i);
		hdfs.rename(tmpFile.f0, file);
		Assert.assertTrue(hdfs.exists(file));
	}

	// wait for the job to finish.
	job.join();
}
 

@Test
public void testProgram() throws Exception {

	/*
	* This test checks the interplay between the monitor and the reader
	* and also the failExternally() functionality. To test the latter we
	* set the parallelism to 1 so that we have the chaining between the sink,
	* which throws the SuccessException to signal the end of the test, and the
	* reader.
	* */

	TextInputFormat format = new TextInputFormat(new Path(hdfsURI));
	format.setFilePath(hdfsURI);
	format.setFilesFilter(FilePathFilter.createDefaultFilter());

	// create the stream execution environment with a parallelism > 1 to test
	final StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
	env.setParallelism(PARALLELISM);

	ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format,
			FileProcessingMode.PROCESS_CONTINUOUSLY,
			env.getParallelism(), INTERVAL);

	// the monitor has always DOP 1
	DataStream<TimestampedFileInputSplit> splits = env.addSource(monitoringFunction);
	Assert.assertEquals(1, splits.getParallelism());

	ContinuousFileReaderOperator<String> reader = new ContinuousFileReaderOperator<>(format);
	TypeInformation<String> typeInfo = TypeExtractor.getInputFormatTypes(format);

	// the readers can be multiple
	DataStream<String> content = splits.transform("FileSplitReader", typeInfo, reader);
	Assert.assertEquals(PARALLELISM, content.getParallelism());

	// finally for the sink we set the parallelism to 1 so that we can verify the output
	TestingSinkFunction sink = new TestingSinkFunction();
	content.addSink(sink).setParallelism(1);

	Thread job = new Thread() {

		@Override
		public void run() {
			try {
				env.execute("ContinuousFileProcessingITCase Job.");
			} catch (Exception e) {
				Throwable th = e;
				for (int depth = 0; depth < 20; depth++) {
					if (th instanceof SuccessException) {
						return;
					} else if (th.getCause() != null) {
						th = th.getCause();
					} else {
						break;
					}
				}
				e.printStackTrace();
				Assert.fail(e.getMessage());
			}
		}
	};
	job.start();

	// The modification time of the last created file.
	long lastCreatedModTime = Long.MIN_VALUE;

	// create the files to be read
	for (int i = 0; i < NO_OF_FILES; i++) {
		Tuple2<org.apache.hadoop.fs.Path, String> tmpFile;
		long modTime;
		do {

			// give it some time so that the files have
			// different modification timestamps.
			Thread.sleep(50);

			tmpFile = fillWithData(hdfsURI, "file", i, "This is test line.");

			modTime = hdfs.getFileStatus(tmpFile.f0).getModificationTime();
			if (modTime <= lastCreatedModTime) {
				// delete the last created file to recreate it with a different timestamp
				hdfs.delete(tmpFile.f0, false);
			}
		} while (modTime <= lastCreatedModTime);
		lastCreatedModTime = modTime;

		// put the contents in the expected results list before the reader picks them
		// this is to guarantee that they are in before the reader finishes (avoid race conditions)
		expectedContents.put(i, tmpFile.f1);

		org.apache.hadoop.fs.Path file =
			new org.apache.hadoop.fs.Path(hdfsURI + "/file" + i);
		hdfs.rename(tmpFile.f0, file);
		Assert.assertTrue(hdfs.exists(file));
	}

	// wait for the job to finish.
	job.join();
}
 

private static final DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(
			new TextInputFormat(new Path("/ignored")), 
			new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO),
			"source"));
}
 

private static DataSourceNode getSourceNode() {
	return new DataSourceNode(new GenericDataSourceBase<String, TextInputFormat>(new TextInputFormat(new Path("/")), new OperatorInformation<String>(BasicTypeInfo.STRING_TYPE_INFO)));
}
 

/**
 * Manually run this to write binary snapshot data. Remove @Ignore to run.
 */
@Ignore
@Test
public void writeMonitoringSourceSnapshot() throws Exception {

	File testFolder = tempFolder.newFolder();

	long fileModTime = Long.MIN_VALUE;
	for (int i = 0; i < 1; i++) {
		Tuple2<File, String> file = createFileAndFillWithData(testFolder, "file", i, "This is test line.");
		fileModTime = file.f0.lastModified();
	}

	TextInputFormat format = new TextInputFormat(new Path(testFolder.getAbsolutePath()));

	final ContinuousFileMonitoringFunction<String> monitoringFunction =
		new ContinuousFileMonitoringFunction<>(format, FileProcessingMode.PROCESS_CONTINUOUSLY, 1, INTERVAL);

	StreamSource<TimestampedFileInputSplit, ContinuousFileMonitoringFunction<String>> src =
		new StreamSource<>(monitoringFunction);

	final AbstractStreamOperatorTestHarness<TimestampedFileInputSplit> testHarness =
			new AbstractStreamOperatorTestHarness<>(src, 1, 1, 0);

	testHarness.open();

	final Throwable[] error = new Throwable[1];

	final OneShotLatch latch = new OneShotLatch();

	// run the source asynchronously
	Thread runner = new Thread() {
		@Override
		public void run() {
			try {
				monitoringFunction.run(new DummySourceContext() {
					@Override
					public void collect(TimestampedFileInputSplit element) {
						latch.trigger();
					}

					@Override
					public void markAsTemporarilyIdle() {

					}
				});
			}
			catch (Throwable t) {
				t.printStackTrace();
				error[0] = t;
			}
		}
	};
	runner.start();

	if (!latch.isTriggered()) {
		latch.await();
	}

	final OperatorSubtaskState snapshot;
	synchronized (testHarness.getCheckpointLock()) {
		snapshot = testHarness.snapshot(0L, 0L);
	}

	OperatorSnapshotUtil.writeStateHandle(
			snapshot,
			"src/test/resources/monitoring-function-migration-test-" + fileModTime + "-flink" + flinkGenerateSavepointVersion + "-snapshot");

	monitoringFunction.cancel();
	runner.join();

	testHarness.close();
}