Consider the following simple example of a nested batch with no retries. It shows a common scenario for batch processing: An input source is processed until exhausted, and we commit periodically at the end of a "chunk" of processing.

The input operation (3.1) could be a message-based receive (such as from JMS), or a file-based read, but to recover and continue processing with a chance of completing the whole job, it must be transactional. The same applies to the operation at 3.2. It must be either transactional or idempotent.

If the chunk at REPEAT (3) fails because of a database exception at 3.2, then TX (2) must roll back the whole chunk.

It is also useful to use a retry for an operation which is not transactional, such as a call to a web-service or other remote resource, as shown in the following example:

This is actually one of the most useful applications of a retry, since a remote call is much more likely to fail and be retryable than a database update. As long as the remote access (2.1) eventually succeeds, the transaction, TX (0), commits. If the remote access (2.1) eventually fails, then the transaction, TX (0), is guaranteed to roll back.

The most typical batch processing pattern is to add a retry to the inner block of the chunk, as shown in the following example:

The inner RETRY (4) block is marked as "stateful". See the typical use case for a description of a stateful retry. This means that if the retry PROCESS (5) block fails, the behavior of the RETRY (4) is as follows:

Note that the notation used for the RETRY (4) in the plan above explicitly shows that the input step (4.1) is part of the retry. It also makes clear that there are two alternate paths for processing: the normal case, as denoted by PROCESS (5), and the recovery path, as denoted in a separate block by RECOVER (6). The two alternate paths are completely distinct. Only one is ever taken in normal circumstances.

In special cases (such as a special TranscationValidException type), the retry policy might be able to determine that the RECOVER (6) path can be taken on the last attempt after PROCESS (5) has just failed, instead of waiting for the item to be re-presented. This is not the default behavior, because it requires detailed knowledge of what has happened inside the PROCESS (5) block, which is not usually available. For example, if the output included write access before the failure, then the exception should be re-thrown to ensure transactional integrity.

The completion policy in the outer REPEAT (1) is crucial to the success of the above plan. If the output (5.1) fails, it may throw an exception (it usually does, as described), in which case the transaction, TX (2), fails, and the exception could propagate up through the outer batch REPEAT (1). We do not want the whole batch to stop, because the RETRY (4) might still be successful if we try again, so we add exception=not critical to the outer REPEAT (1).

Note, however, that if the TX (2) fails and we do try again, by virtue of the outer completion policy, the item that is next processed in the inner REPEAT (3) is not guaranteed to be the one that just failed. It might be, but it depends on the implementation of the input (4.1). Thus, the output (5.1) might fail again on either a new item or the old one. The client of the batch should not assume that each RETRY (4) attempt is going to process the same items as the last one that failed. For example, if the termination policy for REPEAT (1) is to fail after 10 attempts, it fails after 10 consecutive attempts but not necessarily at the same item. This is consistent with the overall retry strategy. The inner RETRY (4) is aware of the history of each item and can decide whether or not to have another attempt at it.

The inner batches or chunks in the typical example can be executed concurrently by configuring the outer batch to use an AsyncTaskExecutor. The outer batch waits for all the chunks to complete before completing. The following example shows asynchronous chunk processing:

The individual items in chunks in the typical example can also, in principle, be processed concurrently. In this case, the transaction boundary has to move to the level of the individual item, so that each transaction is on a single thread, as shown in the following example:

This plan sacrifices the optimization benefit, which the simple plan had, of having all the transactional resources chunked together. It is only useful if the cost of the processing (5) is much higher than the cost of transaction management (3).

There is a tighter coupling between batch-retry and transaction management than we would ideally like. In particular, a stateless retry cannot be used to retry database operations with a transaction manager that does not support NESTED propagation.

The following example uses retry without repeat:

Again, and for the same reason, the inner transaction, TX (3), can cause the outer transaction, TX (1), to fail, even if the RETRY (2) is eventually successful.

Unfortunately, the same effect percolates from the retry block up to the surrounding repeat batch if there is one, as shown in the following example:

Now, if TX (3) rolls back, it can pollute the whole batch at TX (1) and force it to roll back at the end.

What about non-default propagation?

Consequently, the NESTED pattern is best if the retry block contains any database access.

Default propagation is always OK for simple cases where there are no nested database transactions. Consider the following example, where the SESSION and TX are not global XA resources, so their resources are orthogonal:

Here there is a transactional message SESSION (0), but it does not participate in other transactions with PlatformTransactionManager, so it does not propagate when TX (3) starts. There is no database access outside the RETRY (2) block. If TX (3) fails and then eventually succeeds on a retry, SESSION (0) can commit (independently of a TX block). This is similar to the vanilla "best-efforts-one-phase-commit" scenario. The worst that can happen is a duplicate message when the RETRY (2) succeeds and the SESSION (0) cannot commit (for example, because the message system is unavailable).

The distinction between a stateless and a stateful retry in the typical example above is important. It is actually ultimately a transactional constraint that forces the distinction, and this constraint also makes it obvious why the distinction exists.

We start with the observation that there is no way to skip an item that failed and successfully commit the rest of the chunk unless we wrap the item processing in a transaction. Consequently, we simplify the typical batch execution plan to be as follows:

The preceding example shows a stateless RETRY (3) with a RECOVER (5) path that kicks in after the final attempt fails. The stateless label means that the block is repeated without re-throwing any exception up to some limit. This only works if the transaction, TX (4), has propagation NESTED.

If the inner TX (4) has default propagation properties and rolls back, it pollutes the outer TX (1). The inner transaction is assumed by the transaction manager to have corrupted the transactional resource, so it cannot be used again.

Support for NESTED propagation is sufficiently rare that we choose not to support recovery with stateless retries in the current versions of Spring Batch. The same effect can always be achieved (at the expense of repeating more processing) by using the typical pattern above.