ConcurrentHashMap vs Synchronized HashMap
https://stackoverflow.com/questions/1291836
italiano
english
français
española
中国
日本の
العربية
Deutsch
한국어
Português
RussianQuestion
What is the difference between using the wrapper class, SynchronizedMap, on a HashMap and ConcurrentHashMap?
Is it just being able to modify the HashMap while iterating it (ConcurrentHashMap)?
Solution
Synchronized HashMap:
Each method is synchronized using an object level lock. So the get and put methods on synchMap acquire a lock.
Locking the entire collection is a performance overhead. While one thread holds on to the lock, no other thread can use the collection.
ConcurrentHashMap was introduced in JDK 5.
There is no locking at the object level,The locking is at a much finer granularity. For a
ConcurrentHashMap, the locks may be at a hashmap bucket level.The effect of lower level locking is that you can have concurrent readers and writers which is not possible for synchronized collections. This leads to much more scalability.
ConcurrentHashMapdoes not throw aConcurrentModificationExceptionif one thread tries to modify it while another is iterating over it.
This article Java 7: HashMap vs ConcurrentHashMap is a very good read. Highly recommended.
OTHER TIPS
The short answer:
Both maps are thread-safe implementations of the Map interface. ConcurrentHashMap is implemented for higher throughput in cases where high concurrency is expected.
Brian Goetz's article on the idea behind ConcurrentHashMap is a very good read. Highly recommended.
ConcurrentHashMap is thread safe without synchronizing the whole map. Reads can happen very fast while write is done with a lock.
We can achieve thread safety by using both ConcurrentHashMap and synchronisedHashmap. But there is a lot of difference if you look at their architecture.
- synchronisedHashmap
It will maintain the lock at the object level. So if you want to perform any operation like put/get then you have to acquire the lock first. At the same time, other threads are not allowed to perform any operation. So at a time, only one thread can operate on this. So the waiting time will increase here. We can say that performance is relatively low when you comparing with ConcurrentHashMap.
- ConcurrentHashMap
It will maintain the lock at segment level. It has 16 segments and maintains the concurrency level as 16 by default. So at a time, 16 threads can be able to operate on ConcurrentHashMap. Moreover, read operation doesn't require a lock. So any number of threads can perform a get operation on it.
If thread1 wants to perform put operation in segment 2 and thread2 wants to perform put operation on segment 4 then it is allowed here. Means, 16 threads can perform update(put/delete) operation on ConcurrentHashMap at a time.
So that the waiting time will be less here. Hence the performance is relatively better than synchronisedHashmap.
Both are synchronized version of HashMap, with difference in their core functionality and their internal structure.
ConcurrentHashMap consist of internal segments which can be viewed as independent HashMaps Conceptually. All such segments can be locked by separate threads in high concurrent executions. So, multiple threads can get/put key-value pairs from ConcurrentHashMap without blocking/waiting for each other. This is implemented for higher throughput.
whereas
Collections.synchronizedMap(), we get a synchronized version of HashMap and it is accessed in blocking manner. This means if multiple threads try to access synchronizedMap at same time, they will be allowed to get/put key-value pairs one at a time in synchronized manner.
ConcurrentHashMap uses finer-grained locking mechanism known as lock stripping to allow greater degree of shared access. Due to this it provides better concurrency and scalability.
Also iterators returned for ConcurrentHashMap are weakly consistent instead of fail fast technique used by Synchronized HashMap.
Methods on SynchronizedMap hold the lock on the object, whereas in ConcurrentHashMap there's a concept of "lock striping" where locks are held on buckets of the contents instead. Thus improved scalability and performance.
ConcurrentHashMap :
1)Both maps are thread-safe implementations of the Map interface.
2)ConcurrentHashMap is implemented for higher throughput in cases where high concurrency is expected.
3) There is no locking in object level.
Synchronized Hash Map:
1) Each method is synchronized using an object level lock.
A simple performance test for ConcurrentHashMap vs Synchronized HashMap
. The test flow is calling put in one thread and calling get in three threads on Map concurrently. As @trshiv said, ConcurrentHashMap has higher throughput and speed for whose reading operation without lock. The result is when operation times is over 10^7, ConcurrentHashMap is 2x faster than Synchronized HashMap.
ConcurrentHashMap allows concurrent access to data. Whole map is divided into segments.
Read operation ie. get(Object key) is not synchronized even at segment level.
But write operations ie. remove(Object key), get(Object key) acquire lock at segment level. Only part of whole map is locked, other threads still can read values from various segments except locked one.
SynchronizedMap on the other hand, acquire lock at object level. All threads should wait for current thread irrespective of operation(Read/Write).
As per java doc's
Hashtable and Collections.synchronizedMap(new HashMap()) are synchronized. But ConcurrentHashMap is "concurrent".
A concurrent collection is thread-safe, but not governed by a single exclusion lock.
In the particular case of ConcurrentHashMap, it safely permits any number of concurrent reads as well as a tunable number of concurrent writes. "Synchronized" classes can be useful when you need to prevent all access to a collection via a single lock, at the expense of poorer scalability.
In other cases in which multiple threads are expected to access a common collection, "concurrent" versions are normally preferable. And unsynchronized collections are preferable when either collections are unshared, or are accessible only when holding other locks.
