1

Problem statement:

Do I/O in chunks. Start processing chunks as soon as one becomes available, while further chunks are being read in background (but not more than X chunks are read ahead). Process chunks in parallel as they are being received. Consume each processed chunk in-order-of-reading, i.e. in original order of the chunk being read.

What I've done:

I've set up an MWE class to imitate the situation and it works to an extent:

  • The "prefetch" part doesn't seem to be working as I expect it to, the "generator", which simulates the IO, produces arbitrarily many items before "processing" needs more elements, depending on time delays I set.
  • Final consumption is not in order (expected, but I don't yet know what to do about it).

Pseudo-Rx code explanation of what I'd like to achieve:

Flux.fromFile(path, some-function-to-define-chunk)
   // done with Flux.generate in MWE below

 .prefetchOnIoThread(x-count: int)
   // at this point we try to maintain a buffer filled with x-count pre-read chunks

 .parallelMapOrdered(n-threads: int, limit-process-ahead: int)
   // n-threads: are constantly trying to drain the x-count buffer, doing some transformation
   // limit-process-ahead: as the operation results are needed in order, if we encounter an
   // input element that takes a while to process, we don't want the pipeline to run too far
   // ahead of this problematic element (to not overflow the buffers and use too much memory)

 .consume(TMapped v)

Current attempt with Reactor (MWE):

Dependency: implementation 'io.projectreactor:reactor-core:3.3.5.RELEASE'

import reactor.core.Disposable;
import reactor.core.publisher.Flux;
import reactor.core.publisher.ParallelFlux;
import reactor.core.scheduler.Schedulers;

import java.text.SimpleDateFormat;
import java.util.Date;
import java.util.concurrent.atomic.AtomicInteger;

public class Tmp {
  static final SimpleDateFormat fmt = new SimpleDateFormat("HH:mm:ss.SSS");
  static long millisRead = 1; // time taken to "read" a chunk
  static long millisProcess = 100; // time take to "process" a chunk

  public static void main(String[] args) {
    log("Before flux construct");

    // Step 1: Generate / IO
    Flux<Integer> f = Flux.generate( // imitate IO
        AtomicInteger::new,
        (atomicInteger, synchronousSink) -> {
          sleepQuietly(millisRead);
          Integer next = atomicInteger.getAndIncrement();
          if (next > 50) {
            synchronousSink.complete();
            log("Emitting complete");
          } else {
            log("Emitting next : %d", next);
            synchronousSink.next(next);
          }
          return atomicInteger;
        },
        atomicInteger -> log("State consumer called: pos=%s", atomicInteger.get()));

    f = f.publishOn(Schedulers.elastic());
    f = f.subscribeOn(Schedulers.elastic());

    ParallelFlux<Integer> pf = f.parallel(2, 2);
    pf = pf.runOn(Schedulers.elastic(), 2);


    // Step 2: transform in parallel
    pf = pf.map(i -> {           // imitate processing steps
      log("Processing begin: %d", i);
      sleepQuietly(millisProcess); // 10x the time it takes to create an input for this operation
      log("Processing done : %d", i);
      return 1000 + i;
    });

    // Step 3: use transformed data, preferably in order of generation
    Disposable sub = pf.sequential(3).subscribe(
        next -> log(String.format("Finally got: %d", next)),
        err -> err.printStackTrace(),
        () -> log("Complete!"));

    while (!sub.isDisposed()) {
      log("Waiting pipeline completion...");
      sleepQuietly(500);
    }

    log("Main done");
  }

  public static void log(String message) {
    Thread t = Thread.currentThread();
    Date d = new Date();
    System.out.printf("[%s] @ [%s]: %s\n", t.getName(), fmt.format(d), message);
  }

  public static void log(String format, Object... args) {
    log(String.format(format, args));
  }

  public static void sleepQuietly(long millis) {
    try {
      Thread.sleep(millis);
    } catch (InterruptedException e) {
      throw new IllegalStateException();
    }
  }
}
2
0

Considering lack of answers, I'll post what I came up with.

final int threads = 2;
final int prefetch = 3;

Flux<Integer> gen = Flux.generate(AtomicInteger::new, (ai, sink) -> {
  int i = ai.incrementAndGet();
  if (i > 10) {
    sink.complete();
  } else {
    sink.next(i);
  }
  return ai;
});

gen.parallel(threads, prefetch)             // switch to parallel processing after genrator
    .runOn(Schedulers.parallel(), prefetch) // if you don't do this, it won't run in parallel
    .map(i -> i + 1000)                     // this is done in parallel
    .ordered(Integer::compareTo)            // you can do just .sequential(), which is faster
    .subscribeOn(Schedulers.elastic())      // generator will run on this scheduler (once subscribed)
    .subscribe(i -> {
      System.out.printf("Transformed integer: " + i); // do something with generated and processed item
    });
| improve this answer | |

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.