Hexagonal Architecture (a.k.a. Ports and Adapters) is a design pattern conceived by Alistair Cockburn. It elegantly solves some of the biggest problems in larger software projects, by
- isolating the business logic from the rest of a software system,
- moving it into the very center of the architecture and
- attaching all the other parts like plug-in extensions around it.
I made this example project as a supplement to a blog post about the pattern, to demonstrate some of the many shapes and variations this pattern can be implemented in - even not considering languages, platforms and tools, there must be quite a few distinct versions, each with its own advantages and disadvantages - and of course, it falls short:
- The business case is naive, at best.
Indeed. It's the smallest example I could think of, that would leave enough complexity to show some of the key decisions we face in real-life projects. - The domain core is OK, but leaves a lot to be improved.
Agreed. I think I gave it a respectable first shot, but I am aware that there are shortcomings that might be solved with some love and a day or... sixteen. This is a demo, and I am not getting paid for it. So, thank you for pointing that out - I am always happy to accept pull requests. - Not all the code has proper tests.
True, and I regret that. However, the important parts (the core) have the important coverage, and GUIs are often best tested manually, itfp. Again, I welcome pull requests. - I fail to see why I should go to all the troubles.
I understand. Sadly, this is something I cannot solve for you. Long term benefits will neither become obvious, nor easily understandable, unless you actually work and evolve a system with DDD and Hexagonal in a real life scenario: But even if it's a pet project, it may only takes weeks, before you face the first learning that leads to a pivot and makes you want to re-design your entire system - which, now, you actually can, without losing much sleep over it. - It would have been much better in Haskell..
Well, admittedly, according to some people I have much respect for, everything would be. However, I chose React, because I am foolishly biased towards the JavaScript ecosystem and the way it makes me progress and enjoy programming again. And for the same reason, I probably would have chosen NodeJS over Java in an instant, but alas, instead I picked Maven and SpringBoot for demo purposes - mostly, because some of the issues that arise from persistence handling in layered architectures are quite apparent in Java, and in combination with widely used frameworks from the Spring family.
It's a web shop. Simple as that.
It contains some master data (the products; there are some default ones, but you can add your own as you please),
a single bounded context (adding and removing items to the shopping cart, as well as taking it to check-out),
and finally produces orders.
It is extremely naive, of course - only one user, and one administrator, no security, no payment, no complex validation
(except one where we check if an item is a valid product). However, it is enough to show how to handle inter-context dependencies, mapping between serialized "DTO" type of objects and domain entities, and how data storage structures can end up looking quite different from domain objects.
There are branches that contain the different implementations, and they are named:
- 1_monolith:
The most straightforward example, containing a single backend server and the two frontend apps. - 2_shared_kernel:
The same application, but with "microservices", or rather, a few small services that share the same business logic as a library, as well as the database. Warning: This is not an approach I would recommend as a target architecture, but rather the "step in between" a monolith and actual microservices, when you are aiming to transition to a distributed system. - 3_microservices:
Same partitioning as 2, but this time without shared anything, and the domain core properly split into several libraries. - 4_cqrs:
Further separated commands and queries into individual components, and add a message bus. This is probably the most extensive (and counter-intuitive) set of changes on our journey. We move from a procedural to an event-driven (reactive) paradigm, and create lots of new code.
####COMING SOON:
- 5_mq
Extract the read models into individual services, and connect all the parts via a message queue. This example shows how Ports and Adapters can also apply at network level, rather than in micro architecture. - 6_event_sourcing:
We replace some of our relational databases with an event store. This design is almost completely decoupled and all components are independently manageable.
Each branch contains docker containers for all the relevant parts, that can be easily built and started using the
build.sh and run.sh scripts I have included - unless you're on Windows, in which case I can give no guarantees they will work with PowerShell.
Sorry.
You can always deploy manually, following the instructions in INSTALL.md for every branch.
Once everything runs, you should be able to access the store and administration GUIs at http://localhost/ and http://localhost/admin, respectively.
Awesome! You can reach me on Twitter, or open an issue or submit pull requests, and I'll do my very best to respond swiftly. :)