- MVP (Model-View-Presenter design pattern)
- agile iteration
There are three essential iterative stages.
- MVP state-machine planning
- MVP presenter design
- MVP view tie-in
There are three tiers of technology to tie together:
- the backend
- the servlet(S) and container
- the client
So, you probably say .. MVP? Whazat? No need to involve MVP.
I advocate MVP over MVC for web apps.
There is no point in mocking up anything if you have no idea of the state-machine.
State-machine? Why do I have to consider introducing the complexity of a state-machine?
Every discrete process is a state-machine. Every application with an UI is easily mapped into a state-machine.
If you cannot design a state-machine for your application it means you have difficulty understanding the requirements of your application. State machine mapping is actually very simple. State-machine mapping is difficult because understanding the specification of the application is difficult.
Mapping out the state-machine of an app is to make the intricacies of the application glaringly obvious. If you encounter difficulty mapping out the state-machine, it means your requirements are too complex for you to understand. Then, complying to the attitude of agile development, start with a simpler process that you can grasp.
What is a state-machine? This is a state-machine: http://www.maineturnpike.com/tolls/cash_tolls.php. (Oh gwawd! they are using php?)
And this is one of the state-machines being a component to a larger network of state-machines: http://www.maineturnpike.com/pdf/tollcharts/Cash%20v%20E-ZPass%20cl1.pdf.
Let's say you have four locations along your highway: A B C D. Construct this the src-destination transition chart (what I would call the state-turnpike table, I meant "state" as in state-machine, not the "states" of Maine or Nebraska):
dest> A B C D
A - Tab Tac -
B Tba - - Tbd
C Tca Tcb - -
D - - Tdc -
This table maps out the allowed transitions very clearly. The hyphens denote not-allowed transitions. The best way to construct the state-turnpike chart is to use a spreadsheet and use a grey background instead of hyphens for non-applicable transitions.
The first state-machine that you could most easily define is the client UI state-machine. Consider each View as a state:
Login Page ->transition(login) -> Start Page
Any Page ->transition(timedout) -> Login Page
Start Page ->transition(searchEmployees) -> Employee search Result.
... so on and so forth, etc, etc, ...
Simple, isn't it? It's gawdy tedious though. But it's not the fault of the state-machine technique. It is the fault of the complexity of your application. So start simple.
The transition definition table
The next is to define what the transitions are in another sheet of your workbook. So now, your state-machine workbook in your spreadsheet has two sheets: state-turnpike and transition definition.
Tcb = request for list of retired employees.
Simple, isn't it?
Your UI client obviously has a state machine easily mapped out as I have exemplified. Then, your servlet has a state-machine. So does your data access/manipulation model.
Let's look at the burger process:
Patty Frozen -> thaw -> available burger patty
available burger patty typeA -> customer places order $k -> patty on order
patty typeA on order -> cook -> cooked patty typeA
cooked patty typeA -> bun -> burger typeA on order $k
burger typeA on order $k -> customer changes mind -> burger typeA available
burger typeA available -> reconcile queue -> burger typeA on new order $n
So you can form a state-turnpike table from the process easily.
Now your UI state-machine at the cashier counter:
Customer Order Page -> submits order -> Payment Page.
That "submits order" transition sends an event to burger process state-machine resulting in the transition "customer places order $k". So the transition of one state-machine triggers a transition in another state-machine.
Therefore, if your UI state-machine gets too huge, you could also break them up into multiple state-machines interconnected thro transition events. If you look at your UI state-turnpike table, you would see clusters of proximity. If your are mathematically inclined, you could of course use cluster proximity analysis to break up a complex state-machine into multiple granular ones. But you don't have to, because visual inspection and reasoning would be sufficient in most cases.
Mock-up and customer consultation
Now with a bird's eye view of your simplified process, you can then proceed to mock up and show it to your users. Now you can start iterating on the design of your state-machine.
Next, you have to map out the state machine with your data model colleagues and define the transitions/messages/events to link the UI, servlet and various backend state-machines.
Warning: don't show them (or your boss) the state-machine tables. They'll kick you out of their offices. The state-machine tables are for you personal edification and convenience.
Do not create any actual views yet, if possible. Just skeletal ones to expose the behaviour of your presenters and state-machines. Then gradually refine on the Views. It is a mistake to let you users tell you to refine on Views early in the project. Get the state-machine working as proof of concept - state your terms of progress. Work only on views that are crucial/representative to the application. For example, if your app is a cloud-based spreadsheet the spreadsheet views are absolutely crucial.
Your presenters are the raw representation of the views. Your presenters are the non-visual handlers of the views (or pages). The base of the MVP is the state-machine, which is why you need to map out your state-machine in order to facilitate control-flow model. The state-machine model tells the presenter to present itself but does/should not tell the presenter how to layout the UI. The presenter is the mediator between the state-machine.
Your presenter will trigger transitions and be triggered by transitions. Those transitions may or may not cross into another state-machine. For example, UI presenter getting/posting from/to the servlet.
Your UI layout (The view) should never handle any MVP state-machine events. The only events the view needs to handle are mouse/screen/keyboard events. You may even want to relegate that to the presenter. That is the view majorly takes care of layout and handles as few events as possible.
Using the state machine design methodology, you are able to unit-test and construct a completely working servlet without even writing a single line of client code. You could create alternatives between IPhone view and browser view, since the views are not tied down by events or the MVP state-machine awareness. Without changing any state-machine code.
How much independence/decoupling between a presenter and its view depends on the client technology coupling. If you have decided that you only wish to use GWT but across devices of different physical stimulus and dimensional constraints then, the decoupling need not be very loose.
The next keyword is REST and REST-RPC (jaxrs). REST allows a very loose coupling.
The most useful UML diagram for web app design is the sequence diagram. If you have performed telephony protocol design/analysis, you would know why the sequence diagram is very helpful in application communication design.
The other is the deployment diagram. Of course, the use case diagram is good to show your IT director because that is probably the only UML diagram he could understand.
The most useful UML tool I have used is BOUML. Many UML tools are either too weak or too strong. BOUML has the best balance between consistency and free-style
Unfortunately, the author of BOUML was cyber-bullied (by a couple of fellow europeans) into hiding himself. The cyber bullying was, IMO, criticising that his product is useless because it is too non-compliant to the over-engineered UML standards. So it is available only on Ubuntu because the Ubuntu build process has a copy of the last build.
Additional comments for ER diagramming
IMO, the ER diagrams should have been done long ago. The ER diagrams are the motivation why you are considering a web app to replace or supplement your current thick app. To understand the process is to have a strong grasp of the Entity Relationships of your business/manufacturing process.
You should do a large print of your ER diagram and draw out the deployment boundaries on that print out. What are its present boundaries and what are the proposed boundaries.
May be, you should laminate it first so that you could use erasable white board markers on it and carry it around with your meetings and use a phone camera to record every mutation of the boundaries.
Boundaries? Boundaries of which database they are stored? No. But the boundaries of what software processes are sourcing, transmitting and consuming them.
Phase-lag/Phase-lead analysis of Entity Relationships
This is a simple but tedious procedure. Frequently, project architects would have drawn a beautifully accurate ERD that reflects the business processes perfectly. Then they start on the project. After the half a year of iterative development, they discover the horror of phase misalignment of their Entity Relationships. For example, they might discover that you cannot join the Product with the ProductCost using the productId as the key, because the ProductCost is updated in the middle of the week and Products are started every Monday mornings. Which calls for an introduction of datetime and version in the schemata. Which calls for you to bravely walk up to the Product planning manager and say they are show-stopping the application unless they use versioning in their planning. it is best that phase lead/lag analysis be understood as early as possible.
Data Transfer Objects (DTO) Design