There is a workaround to this problem. Consider the following implementation:
int corePoolSize = 40;
int maximumPoolSize = 40;
ThreadPoolExecutor threadPoolExecutor = new ThreadPoolExecutor(corePoolSize, maximumPoolSize,
60L, TimeUnit.SECONDS, new LinkedBlockingQueue<Runnable>());
By setting the allowCoreThreadTimeOut() to
true, the threads in the pool are allowed to terminate after the specified timeout (60 seconds in this example). With this solution, it is the
corePoolSize constructor argument that determines the maximum pool size in practice, because the thread pool will grow up to the
corePoolSize, and then start adding jobs to the queue. It is likely that the pool may never grow bigger than that, because the pool will not spawn new threads until the queue is full (which, given that the
LinkedBlockingQueue has an
Integer.MAX_VALUE capacity may never happen). Consequently, there is little point in setting
maximumPoolSize to a larger value than
Consideration: The thread pool have 0 idle threads after the timeout has expired, which means that there will be some latency before the threads are created (normally, you would always have
corePoolSize threads available).
More details can be found in the JavaDoc of ThreadPoolExecutor.