The event loop is the container's single thread that is in charge of reading and writing messages, flushing metrics, checkpointing, and windowing.
Samza uses a single thread because every container is designed to use a single CPU core; to get more parallelism, simply run more containers. This uses a bit more memory than multithreaded parallelism, because each JVM has some overhead, but it simplifies resource management and improves isolation between jobs. This helps Samza jobs run reliably on a multitenant cluster, where many different jobs written by different people are running at the same time.
You are strongly discouraged from using threads in your job's code. Samza uses multiple threads internally for communicating with input and output streams, but all message processing and user code runs on a single-threaded event loop. In general, Samza is not thread-safe.
A container may have multiple SystemConsumers for consuming messages from different input systems. Each SystemConsumer reads messages on its own thread, but writes messages into a shared in-process message queue. The container uses this queue to funnel all of the messages into the event loop.
The event loop works as follows:
The container does this, in a loop, until it is shut down. Note that although there can be multiple task instances within a container (depending on the number of input stream partitions), their process() and window() methods are all called on the same thread, never concurrently on different threads.
The only way in which a developer can hook into a SamzaContainer's lifecycle is through the standard InitableTask, ClosableTask, StreamTask, and WindowableTask. In cases where pluggable logic needs to be added to wrap a StreamTask, the StreamTask can be wrapped by another StreamTask implementation that handles the custom logic before calling into the wrapped StreamTask.
A concrete example is a set of StreamTasks that all want to share the same try/catch logic in their process() method. A StreamTask can be implemented that wraps the original StreamTasks, and surrounds the original process() call with the appropriate try/catch logic. For more details, see this discussion.