Can someone list some comparison points between Thread Spawning vs Thread Pooling, which one is better? Please consider the .NET framework as a reference implementation that supports both.
Thread pool threads are much cheaper than a regular Thread, they pool the system resources required for threads. But they have a number of limitations that may make them unfit:
- You cannot abort a threadpool thread
- There is no easy way to detect that a threadpool completed, no Thread.Join()
- There is no easy way to marshal exceptions from a threadpool thread
- You cannot display any kind of UI on a threadpool thread beyond a message box
- A threadpool thread should not run longer than a few seconds
- A threadpool thread should not block for a long time
The latter two constraints are a side-effect of the threadpool scheduler, it tries to limit the number of active threads to the number of cores your CPU has available. This can cause long delays if you schedule many long running threads that block often.
Many other threadpool implementations have similar constraints, give or take.
A "pool" contains a list of available "threads" ready to be used whereas "spawning" refers to actually creating a new thread.
The usefulness of "Thread Pooling" lies in "lower time-to-use": creation time overhead is avoided.
In terms of "which one is better": it depends. If the creation-time overhead is a problem use Thread-pooling. This is a common problem in environments where lots of "short-lived tasks" need to be performed.
As pointed out by other folks, there is a "management overhead" for Thread-Pooling: this is minimal if properly implemented. E.g. limiting the number of threads in the pool is trivial.
For some definition of "better", you generally want to go with a thread pool. Without knowing what your use case is, consider that with a thread pool, you have a fixed number of threads which can all be created at startup or can be created on demand (but the number of threads cannot exceed the size of the pool). If a task is submitted and no thread is available, it is put into a queue until there is a thread free to handle it.
If you are spawning threads in response to requests or some other kind of trigger, you run the risk of depleting all your resources as there is nothing to cap the amount of threads created.
Another benefit to thread pooling is reuse - the same threads are used over and over to handle different tasks, rather than having to create a new thread each time.
As pointed out by others, if you have a small number of tasks that will run for a long time, this would negate the benefits gained by avoiding frequent thread creation (since you would not need to create a ton of threads anyway).
All depends on your scenario. Creating new threads is resource intensive and an expensive operation. Most very short asynchronous operations (less than a few seconds max) could make use of the thread pool.
For longer running operations that you want to run in the background, you'd typically create (spawn) your own thread. (Ab)using a platform/runtime built-in threadpool for long running operations could lead to nasty forms of deadlocks etc.
Thread pooling is usually considered better, because the threads are created up front, and used as required. Therefore, if you are using a lot of threads for relatively short tasks, it can be a lot faster. This is because they are saved for future use and are not destroyed and later re-created.
In contrast, if you only need 2-3 threads and they will only be created once, then this will be better. This is because you do not gain from caching existing threads for future use, and you are not creating extra threads which might not be used.
The main difference is that a ThreadPool maintains a set of threads that are already spun-up and available for use, because starting a new thread can be expensive processor-wise.
Note however that even a ThreadPool needs to "spawn" threads... it usually depends on workload - if there is a lot of work to be done, a good threadpool will spin up new threads to handle the load based on configuration and system resources.
For Multi threaded execution combined with getting return values from the execution, or an easy way to detect that a threadpool has completed, java Callables could be used.
See https://blogs.oracle.com/CoreJavaTechTips/entry/get_netbeans_6 for more info.
Assuming C# and Windows 7 and up...
When you create a thread using new Thread(), you create a managed thread that becomes backed by a native OS thread when you call Start – a one to one relationship. It is important to know only one thread runs on a CPU core at any given time.
An easier way is to call ThreadPool.QueueUserWorkItem (i.e. background thread), which in essence does the same thing, except those background threads aren’t forever tied to a single native thread. The .NET scheduler will simulate multitasking between managed threads on a single native thread. With say 4 cores, you’ll have 4 native threads each running multiple managed threads, determined by .NET. This offers lighter-weight multitasking since switching between managed threads happens within the .NET VM not in the kernel. There is some overhead associated with crossing from user mode to kernel mode, and the .NET scheduler minimizes such crossing.
It may be important to note that heavy multitasking might benefit from pure native OS threads in a well-designed multithreading framework. However, the performance benefits aren’t that much.
With using the ThreadPool, just make sure the minimum worker thread count is high enough or ThreadPool.QueueUserWorkItem will be slower than new Thread(). In a benchmark test looping 512 times calling new Thread() left ThreadPool.QueueUserWorkItem in the dust with default minimums. However, first setting the minimum worker thread count to 512, in this test, made new Thread() and ThreadPool.QueueUserWorkItem perform similarly.
A side effective of setting a high worker thread count is that new Task() (or Task.Factory.StartNew) also performed similarly as new Thread() and ThreadPool.QueueUserWorkItem.