First of all, let me state that I am new to Command Query Responsibility Segregation and Event Sourcing (Message-Drive Architecture), but I'm already seeing some significant design benefits. However, there are still a few issues on which I'm unclear.
Say I have a
Customer class (an aggregate root) that contains a property called
postalAddress (an instance of the
Address class, which is a value object). I also have an
Order class (another aggregate root) that contains (among
OrderItem objects and other things) a property called
deliveryAddress (also an instance of the
Address class) and a string property called
The customer places an order by issueing a
PlaceOrder command, which triggers the
OrderReceived event. At this point in time, the status of the order is
"RECEIVED". When the order is shipped, someone in the warehouse issues an
ShipOrder command, which triggers the
OrderShipped event. At this point in time, the status of the order is
One of the business rules is that if a
Customer updates their
postalAddress before an order is shipped (i.e., while the status is still
deliveryAddress of the
Order object should also be updated. If the status of the
Order were already
deliveryAddress would not be updated.
Question 1. Is the best place to put this "conditionally cascading address update" in a Saga (a.k.a., Process Manager)? I assume so, given that it is translating an event ("The customer just updated their postal address...") to a command ("... so update the delivery address of order 123").
Question 2. If a Saga is the right tool for the job, how does it identify the orders that belong to the user, given that an aggregate can only be retrieved by it's unique ID (in my case a UUID)?
Continuing on, given that each aggregate represents a transactional boundary, if the system were to crash after the
postalAddress was updated (the
CustomerAddressUpdated event being persisted to the event store) but before the
OrderDeliveryAddressUpdated could be updated (i.e., between the two transactions), then the system is left in an inconsistent state.
Question 3. How are such "violations" of consistency rules detected and rectified?