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I have sample project using spring-boot with spring-data-jpa and postgres db with one table.

I'm trying to INSERT 10 000 records in the loop into the table and measure execution time - enabling or disabling flush() method from EntityManager class for each 100 records.

Expected result is that execution time with enabled flush() method is much less then with disabled one, but actually I have the opposite result.

UserService.java

package sample.data;

import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.stereotype.Service;

@Service
public class UserService {
    @Autowired
    UserRepository userRepository;

    public User save(User user) {
        return userRepository.save(user);
    }
}

UserRepository.java

package sample.data;

import org.springframework.data.jpa.repository.JpaRepository;
import org.springframework.stereotype.Repository;

@Repository
public interface UserRepository extends JpaRepository<User, Long> { }

Application.java

package sample;

import org.springframework.data.jpa.repository.config.EnableJpaRepositories;
import org.springframework.beans.factory.annotation.Autowired;
import org.springframework.boot.CommandLineRunner;
import org.springframework.boot.SpringApplication;
import org.springframework.boot.autoconfigure.SpringBootApplication;
import org.springframework.context.annotation.Bean;
import org.springframework.transaction.annotation.Transactional;

import sample.data.User;
import sample.data.UserService;

import javax.persistence.EntityManager;
import javax.persistence.PersistenceContext;

@SpringBootApplication
@EnableJpaRepositories(considerNestedRepositories = true)
public class Application {
    public static void main(String[] args) {
        SpringApplication.run(Application.class, args);
    }

    @Autowired
    private UserService userService;

    @PersistenceContext
    EntityManager entityManager;

    @Bean
    public CommandLineRunner addUsers() {
        return new CommandLineRunner() {
            @Transactional
            public void run(String... args) throws Exception {
                long incoming = System.currentTimeMillis();
                for (int i = 1; i <= 10000; i++) {
                    userService.save(new User("name_" + i));

                    if (i % 100 == 0) {
                        entityManager.flush();
                        entityManager.clear();
                    }
                }
                entityManager.close();
                System.out.println("Time: " + (System.currentTimeMillis() - incoming));
            }
        };
    }
}
  • updated question. 2000 ms - 1000 ms = 1000 ms difference – Drakonoved Aug 7 '18 at 14:13
  • 1
    Why do you expect explicit flush() to be faster? – Stanislav Bashkyrtsev Aug 9 '18 at 17:35
  • With periodical flushing it should work faster this way. The problem should be in the configuration of transactions, but where? – Drakonoved Aug 9 '18 at 18:02
  • 1
    For proper benchmarking the best setup, I suggest you to write several loops: Increasing number of objects (up to 1mio), increasing batch sizes (up to 10k). Also every setup should be executed at least 10 times before measuring is done. My experience with microbenchmarks is, that the first testcase (or run) will take significantly longer than the second one (warumup). This could be a reason why test one is slower than the second one. Also a batch size of 100 may be too low resulting in slowing down caused by overhead. Only with a proper setup you will get significant benchmarks. – SCI Aug 15 '18 at 16:29
8
+25

Make sure you enable JDBC batching in your persistence provider configuration. If you're using Hibernate, add this to your Spring properties:

spring.jpa.properties.hibernate.jdbc.batch_size=20   // or some other reasonable value

Without enabling batching, I guess the performance regression is due to the overhead of clearing the persistence context every 100 entities, but I'm not sure about that (you'd have to measure).

UPDATE:

Actually, enabling JDBC batching or disabling it will not affect the fact that with flush() done every once in a while will not be faster than without it. What you're controlling with the manual flush() is not how the flushing is done (via batched statements or unitary inserts), but instead you're controlling when the flushing to the database will be done.

So what you're comparing is the following:

  1. With flush() every 100 objects: you insert 100 instances into the database upon the flush, and you do this 10000 / 100 = 100 times.
  2. Without flush(): you just collect all 10000 objects in the context in memory and do 10000 inserts upon committing the transaction.

JDBC batching on the other affects how the flushing occurs, but it's still the same number of statements issued with flush() vs without flush().

The benefit of flushing and clearing every once in a while in a loop is to avoid a possible OutOfMemoryError due to the cache holding too many objects.

  • Is it the same if you try to change the value of the batch size, or when you increase the number of objects to save? – manouti Aug 9 '18 at 18:58
  • Difference becomes smaller when I increase the number of objects to save in percentage. When I increase the value of the batch size "smaller" difference increases in percentage too. – Drakonoved Aug 9 '18 at 19:17
  • 1
    @Drakonoved Did you try to enable logging of SQL (stackoverflow.com/questions/30118683/…)? I think flushing every once in a while is meant to avoid memory issues and is not meant to improve execution time. – manouti Aug 9 '18 at 19:27
3

Writing a micro benchmark is hard, which is greatly illustrated by Aleksey Shipilev in his "JMH vs Caliper: reference thread" post. Your case is not exactly a micro benchmark but:

  1. Below 10,000 repetitions won't let the JVM to warm up and JIT the code on the default settings. Before measuring code performance warm up the JVM.

  2. System.nanoTime() not System.currentTimeMillis() for measuring elapsed time. If you are measuring in ms your results will get skewed by clock drift in System.currentTimeMillis().

  3. You most likely want to measure this on the database end to pinpoint the bottleneck. Without bottleneck it's hard to understand what is the root cause e.g. your database might be on the other side of the Atlantic Ocean and the network connection cost will overshadow INSERT statement cost.

  4. Is your benchmark sufficiently isolated? If the database is shared by multiple users and connections, other than your benchmark it's performance will vary.

Find the bottleneck in the current setup, make an assumption on how to verify it, change the benchmark to match the assumption and then measure again to confirm. That's the only way to figure it out.

  • Application, database and measurements are made on the local machine.To find the bottleneck is the question.. – Drakonoved Aug 9 '18 at 16:31
  • @Drakonoved It's not an ideal setup, the client doing the test should not compete with the database for system resources. You should check that there are sufficient free resources to run both on one machine. – Karol Dowbecki Aug 9 '18 at 16:36
  • Free resources are more than enough.. This is developer's machine. This project is made as a boundary value problem, but it don't work. – Drakonoved Aug 9 '18 at 16:48
  • @Drakonoved what database are you using? – Karol Dowbecki Aug 9 '18 at 16:50
  • I am using PostgreSQL – Drakonoved Aug 9 '18 at 17:07
2

Can you please explain why you believe:

Expected result is that execution time with enabled flush() method is much less then with disabled one

It seems to me that this is a fundamentally faulty assumption. There is no strong reason to believe that performing this trivial operation 10k times will be FASTER with a flush than without.

As long as all of the records fits into memory, I would expect that the non-intermediate-flush version to be faster. What indicates that performing network IO to access the database 100 times should be faster than doing it 1 time at the end?

  • If it can't be faster, why then construction like spring.jpa.properties.hibernate.jdbc.batch_size=20 makes difference smaller? – Drakonoved Aug 15 '18 at 16:31
  • Because it's completely orthogonal to flushing. The batch size defines how many records are grouped into a single INSERT query. Batch Size determines how many records will be included in each insert statement, flush determines when those insert statements will be sent to the database. For reference please see: stackoverflow.com/questions/6687422/… – Ben M Aug 15 '18 at 17:17
1

The most expensive part of persisting an entity is writing to the database. The time spent persisting the entity in JPA is trivial in comparison, since it is a pure in-memory operation. It's IO compared to memory.

Writing to the database might also have a quite significant static overhead, which means that the number of times you write to the database might affect execution time. When you invoke EntityManager#flush, you instruct Hibernate to write all pending changes to the database.

So what you are doing is comparing an execution with 100 database writes, to one with one database write. Due to the overhead of IO, the former will be significantly slower.

1

Two aspects that are not mentioned by the other answers. Besides flushing you need to clear the Hibernate session. Without clearing it it will grow and will impact your memory consumption which may lead to performance penalty.

One more thing when persisting entities make sure your ID generator uses a hilosequence. If your IDs are 1,2,3,4,5..... each insert will have extra roundtrip in order to increment the ID.

  • According to this question, we shouldn't manually manage hibernate sessions. Instead I do entityManager.clear(); – Drakonoved Aug 9 '18 at 20:02
  • @Drakonoved performancewise it is a big one. The reason is because if you have 10 000 records the ID generator needs to invoke the database sequence responsible for the ID generation 10 000 times which equivalents 10 000 network calls. If you are using @SequenceGenerator(name="EMP_SEQ", allocationSize=25) note the allocationSize attribute. The 25 means that it will increment the sequence with 25 and will use the 25 available numbers in between to assign the newly created IDS. If the allocationSize is 1 then the sequence will be invoked for each ID generated. Which is insane performancewise. – Alexandar Petrov Aug 9 '18 at 20:37
  • @Drakonoved Hilo - sequence is a good id generation strategy , but you can use a sequence with good allocation size. One more thing, you might not notice the difference in insertion speed so much on localhost with allocation size 1 due to the very low latency of the local host, but put the DB remotely and see what will happen. – Alexandar Petrov Aug 9 '18 at 20:38
  • SequenceGenerator and allocationSize stay the same in both cases. – Drakonoved Aug 9 '18 at 20:44
  • @Drakonoved stay the same ? Not sure I got you. – Alexandar Petrov Aug 9 '18 at 20:47

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