So I'm currently developing application using Spring boot with Axonframework, So in Axonframework there is something called aggregate. It can store some states and etc. Everything work fine, but there's a case where I have to check the same state to every incoming command before update the aggregate. Something like this
#CommandHandler
fun handle(command: UpdateProductCommand){
if (isProductApproved){
throw IllegalArgumentException("This product has not been approved by qa.")
}
... do something
}
#CommandHandler
fun handle(command: PublishProductCommand){
if (isProductApproved){
throw IllegalArgumentException("This product has not been approved by qa.")
}
... do something
}
... Some other commands
... Check the same state again and again to every command
As you can see, I have to check this isProductApproved to most of the commands. Is there anyway to easily apply this checking state to every functions or commands before start doing some logic. I would expect something like this
#Aggregate
#CheckState(value = isProductApproved)
class ProductAggregate {
... apply to every command
}
Or any better ways.
In Axon Framework applications it is possible to define a handler interceptor for a specific component containing the handlers (in your case an Aggregate). This can be achieved by adding a method handling the message, combined with the #MessageHandlerInterceptor annotation.
You can find more details on official Axon Reference guide (docs): https://docs.axoniq.io/reference-guide/axon-framework/messaging-concepts/message-intercepting#messagehandlerinterceptor
In my opinion this would be the most pragmatic way to do some logic that is general to a particular component, which is in your case an Aggregate (but it can be any other messaging component actually: event/query handlers, for example)
You mention that you have to add this check to most of the commands, not all of them. If indeed exceptions to the rule are possible, I think the following boring low-tech solution may be the best fit, even if it's probably not what you had in mind:
private fun requireProductIsApproved() = require(isApprovedProduct) {
"This product has not been approved by qa."
}
#CommandHandler
fun handle(command: PublishProductCommand){
requireProductIsApproved()
//... do something
}
Why?
it's dead simple
it's flexible: simply omit it in CommandHandlers that don't need the check.
it keeps your domain logic independent of Axon-specific mechanisms
When using the Room library for Android the documentation clearly states that we cannot make calls on the main thread unless we specifically allow them. What I'm curious about is methods that have a void return type. It seems silly that returning LiveData will automatically run them off the main thread, but void types will not (unless I'm missing something). Is there any easy way I can do this without having to run this in my own managed thread?
My Query:
#Dao
interface UserDao {
#Query("DELETE FROM users")
fun clear()
}
I've even tried using Kotlin reflection + extension functions, but this seemed to fail during runtime:
fun KFunction<Unit>.execOn(executor: Executor, vararg args: Any?) {
executor.execute {
this.call(args)
}
}
Then make a call like:
myDb.userDao()::clear.execOn(diskExecutor)
Note what does work is:
diskExecutor.execute {
myDb.userDao().clear()
}
It seems silly that returning LiveData will automatically run them off the main thread, but void types will not (unless I'm missing something).
Without some sort of annotation, Room would have no idea that you want a void-returning DAO method to be run on a background thread. With a reactive return type (e.g., LiveData, Single), you are explicitly requesting background execution, so no additional metadata (e.g., an annotation) is required.
You might consider filing a feature request for such an annotation-based approach.
Is there any easy way I can do this without having to run this in my own managed thread?
If you are asking "does Room have a background-execution option for DAO methods other than those with reactive return types?", then the answer is no, at least at the present time.
I will explain with an example. My GWT project has a Company module, which lets a user add, edit, delete, select and list companies.
Of these, the add, edit and delete operations lands back the user on the CompanyList page.
Thus, having three different events - CompanyAddedEvent, CompanyUpdatedEvent and CompanyDeletedEvent, and their respective event handlers - seems overkill to me, as there is absolutely not difference in their function.
Is it OK to let a single event manage the three operations?
One alternative I think is to use some event like CompanyListInvokedEvent. However, somewhere I think its not appropriate, is the event actually is not the list being invoked, but a company being added/updated/deleted.
If it had been only a single module, I would have get the task done with three separate events. But other 10 such modules are facing this dilemma. It means 10x3 = 30 event classes along with their 30 respective handlers. The number is large enough for me to reconsider.
What would be a good solution to this?
UPDATE -
#ColinAlworth's answer made me realize that I could easily use Generics instead of my stupid solution. The following code represents an event EntityUpdatedEvent, which would be raised whenever an entity is updated.
Event handler class -
public class EntityUpdatedEvent<T> extends GwtEvent<EntityUpdatedEventHandler<T>>{
private Type<EntityUpdatedEventHandler<T>> type;
private final String statusMessage;
public EntityUpdatedEvent(Type<EntityUpdatedEventHandler<T>> type, String statusMessage) {
this.statusMessage = statusMessage;
this.type = type;
}
public String getStatusMessage() {
return this.statusMessage;
}
#Override
public com.google.gwt.event.shared.GwtEvent.Type<EntityUpdatedEventHandler<T>> getAssociatedType() {
return this.type;
}
#Override
protected void dispatch(EntityUpdatedEventHandler<T> handler) {
handler.onEventRaised(this);
}
}
Event handler interface -
public interface EntityUpdatedEventHandler<T> extends EventHandler {
void onEventRaised(EntityUpdatedEvent<T> event);
}
Adding the handler to event bus -
eventBus.addHandler(CompanyEventHandlerTypes.CompanyUpdated, new EntityUpdatedEventHandler<Company>() {
#Override
public void onEventRaised(EntityUpdatedEvent<Company> event) {
History.newItem(CompanyToken.CompanyList.name());
Presenter presenter = new CompanyListPresenter(serviceBundle, eventBus, new CompanyListView(), event.getStatusMessage());
presenter.go(container);
}
});
Likewise, I have two other Added and Deleted generic events, thus eliminating entire redundancy from my event-related codebase.
Are there any suggestions on this solution?
P.S. > This discussion provides more insight on this problem.
To answer this question, let me first pose another way of thinking about this same kind of problem - instead of events, we'll just use methods.
In my tiered application, two modules communicate via an interface (notice that these methods are all void, so they are rather like events - the caller doesn't expect an answer back):
package com.acme.project;
public interface CompanyServiceInteface {
public void addCompany(CompanyDto company) throws AcmeBusinessLogicException;
public void updateCompany(CompanyDto company) throws AcmeBusinessLogicException;
public void deleteCompany(CompanyDto company) throws AcmeBusinessLogicException;
}
This seems like overkill to me - why not just reduce the size of this API to one method, and add an enum argument to simplify this. This way, when I build an alternative implementation or need to mock this in my unit tests, I just have one method to build instead of three. This gets to be clearly overkill when I make the rest of my application - why not just ObjectServiceInterface.modify(Object someDto, OperationEnum invocation); to work for all 10 modules?
One answer is that you might want want to drastically modify the implementation of one but not the others - now that you've reduced this to just one method, all of this belongs inside that switch case. Another is that once simplified in this way, the inclination often to further simplify - perhaps to combine create and update into just one method. Once this is done, all callsites must make sure to fulfill all possible details of that method's contract instead of just the one specific one.
If the receivers of those events are simple and will remain so, there may be no good reason to not just have a single ModelModifiedEvent that clearly is generic enough for all possible use cases - perhaps just wrapping the ID to request that all client modules refresh their view of that object. If a future use case arises where only one kind of event is important, now the event must change, as must all sites that cause the event to be created so that they properly populate this new field.
Java shops typically don't use Java because it is the prettiest language, or because it is the easiest language to write or find developers for, but because it is relatively easy to maintain and refactor. When designing an API, it is important to consider future needs, but also to think about what it will take to modify the current API - your IDE almost certainly has a shortcut key to find all invocations of a particular method or constructor, allowing you to easily find all places where that is used and update them. So consider what other use cases you expect, and how easily the rest of the codebase can be udpated.
Finally, don't forget about generics - for my example above, I would probably make a DtoServiceInterface to simplify matters, so that I just declare the one interface with three methods, and implement it and refer to it as needed. In the same way, you can make one set of three GwtEvent types (with *Handler interfaces and possibly Has*Handlers as well), but keep them generic for all possible types. Consider com.google.gwt.event.logical.shared.SelectionEvent<T> as an example here - in your case you would probably want to make the model object type a parameter so that handlers can check which type of event they are dealing with (remember that generics are erased in Java), or source from one EventBus for each model type.
I would like to use ServiceTracker in order to consume the services published by our company.
Instead of creating new ServiceTracker for each service I want to consume I thought it would be better to create just one with a filter and then get the services from it:
Filter filter = ctx.createFilter("(" + Constants.OBJECTCLASS + "=com.mycomp*)");
tracker = new ServiceTracker(ctx, filter, null);
The problem with this approach is that I then need to iterate over the service references the tracker had found examine their objectClass property and see if I can assign it to the service object which is very cumbersome and error prone due to casting that is required.
Any other ideas how to cunsume multiple services using more elegant way?
I think it is the wrong question :-) From the question I infer that you have a method that takes a service from your company and you want that method called. That is, somewhere in your code you need to be informed about a specific type com.mycomp.X, that is, you're not interested in general services from your company, you have a clear type dependency. In your question you assume that they need to be dispatched centrally which is usually not robust, error prone, and a maintenance hotspot; every time you have a new company service you need to update the dispatch method.
A MUCH better solution seems to be to use Declarative services and use bndtools with annotations. In that model, each place where you need service:
#Component public class SomeMyCompComponent {
...
#Reference
void foo( com.mycomp.X x ) { ... }
...
}
In this model, you do not need to centrally maintain a dispatcher, any class can get the services it needs when they need it. This model also accurately handles multiple dependencies and lots more goodies.
Maybe I do not understand the problem correctly because I inferred the problem from the solution you required. However, I think you try to abuse the Service Tracker for a task it was not intended to do.
Unfortunately, DS is not build into the framework as we should have done :-(
You could subclass ServiceTracker and add methods to provide direct access to the service types in which you are interested. For example, you could store the services in a typesafe heterogeneous container [1]. Then you would be able to call method on your ServiceTracker subclass which take the type of the service you are interested in and they could be easily looked up in the typesafe heterogeneous container.
[1] Effective Java, 2nd Ed., Item 29.
I'm writing my code in Haxe. This is quite irrelevant to the question though, as long as you keep in mind that it's a high level language and compareable with Java, ActionScript, JavaScript, C#, etc. (I'm using pseudocode here).
I'm going to work on a big project and am busy preparing now. For this question I'll create a small scenario though: a simple application which has a Main class (this one is executed when the application launches) and a LoginScreen class (this is basically a class that loads a login screen so that the user can login).
Typically I guess this would look like the following:
Main constructor:
loginScreen = new LoginScreen()
loginScreen.load();
LoginScreen load():
niceBackground = loader.loadBitmap("somebg.png");
someButton = new gui.customButton();
someButton.onClick = buttonIsPressed;
LoginScreen buttonIsPressed():
socketConnection = new network.SocketConnection();
socketConnection.connect(host, ip);
socketConnection.write("login#auth#username#password");
socketConnection.onData = gotAuthConfirmation;
LoginScreen gotAuthConfirmation(response):
if response == "success" {
//login success.. continue
}
This simple scenario adds the following dependencies and downsides to our classes:
Main will not load without LoginScreen
LoginScreen will not load without the custom loader class
LoginScreen will not load without our custom button class
LoginScreen will not load without our custom SocketConnection class
SocketConnection (which will have to be accessed by a lot of different classes in the future) has been set inside LoginScreen now, which is actually quite irrelevant from it, apart from the fact that the LoginScreen requires a socket connection for the first time
To solve these problems, I have been suggested to do "Event-Driven-Programming", or loose coupling. As far as I understand, this basically means that one has to make classes independent from each other and then bind them together in separate binders.
So question 1: is my view on it true or false? Does one have to use binders?
I heard Aspect Oriented Programming could help here. Unfortunately Haxe does not support this configuration.
However, I do have access to an event library which basically allows me to create a signaller (public var loginPressedSignaller = new Signaller()), to fire a signaller (loginPressedSignaller.fire()) and to listen to a signalller (someClass.loginPressedSignaller.bind(doSomethingWhenLoginPressed)).
So, with little further investigation I figured this would change my previous setup to:
Main:
public var appLaunchedSignaller = new Signaller();
Main constructor:
appLaunchedSignaller.fire();
LoginScreen:
public var loginPressedSignaller = new Signaller();
LoginScreen load():
niceBackground = !!! Question 2: how do we use Event Driven Programming to load our background here, while not being dependent on the custom loader class !!!
someButton = !!! same as for niceBackground, but for the customButton class !!!
someButton.onClick = buttonIsPressed;
LoginScreen buttonIsPressed():
loginPressedSignaller.fire(username, pass);
LoginScreenAuthenticator:
public var loginSuccessSignaller = new Signaller();
public var loginFailSignaller = new Signaller();
LoginScreenAuthenticator auth(username, pass):
socketConnection = !!! how do we use a socket connection here, if we cannot call a custom socket connection class !!!
socketConnection.write("login#auth#username#password");
This code is not finished yet, eg. I still have to listen for the server response, but you probably understand where I am getting stuck.
Question 2: Does this new structure make any sense? how should I solve the problems above mentioned in the !!! delimiters?
Then I heard about binders. So maybe I need to create a binder for each class, to connect everything together. Something like this:
MainBinder:
feature = new Main();
LoginScreenBinder:
feature = new LoginScreen();
MainBinder.feature.appLaunchedSignaller.bind(feature.load);
niceBackgroundLoader = loader.loadBitmap;
someButtonClass = gui.customButton();
etc... hopefully you understand what I mean. This post is getting a bit long so I have to wrap it up a bit.
Question 3: does this make any sense? Doesn't this make things unnecessarily complex?
Also, in the above "Binders" I only had to use classes which are instantiated once, eg. a login screen. What if there are multiple instances of a class, eg. a Player Class in a game of chess.
well, concerning the how, I would point out my 5 commandments to you. :)
For this question only 3 are really important:
single responsibility (SRP)
interface segregation (ISP)
dependency inversion (DIP)
Starting off with SRP, you have to ask yourself the question: "What is the responsibility of class X?".
The login screen is responsible for presenting an interface to the user to fill in and submit his login data. Thus
it makes sense for it to depend on the button class, because it needs the button.
it makes no sense it does all the networking etc.
First of all, you let's abstract the login service:
interface ILoginService {
function login(user:String, pwd:String, onDone:LoginResult->Void):Void;
//Rather than using signalers and what-not, I'll just rely on haXe's support for functional style,
//which renders these cumbersome idioms from more classic languages quite obsolete.
}
enum Result<T> {//this is a generic enum to return results from basically any kind of actions, that may fail
Fail(error:Int, reason:String);
Success(user:T);
}
typedef LoginResult = Result<IUser>;//IUser basically represent an authenticated user
From the point of view of the Main class, the login screen looks like this:
interface ILoginInterface {
function show(inputHandler:String->String->Void):Void;
function hide():Void;
function error(reason:String):Void;
}
performing login:
var server:ILoginService = ... //where ever it comes from. I will say a word about that later
var login:ILoginInterface = ... //same thing as with the service
login.show(function (user, pwd):Void {
server.login(user, pwd, function (result) {
switch (result) {
case Fail(_, reason):
login.error(reason);
case Success(user):
login.hide();
//proceed with the resulting user
}
});
});//for the sake of conciseness I used an anonymous function but usually, you'd put a method here of course
Now ILoginService looks a little titchy. But to be honest, it does all it needs to do. Now it can effectively be implemented by a class Server, that encapsulates all networking in a single class, having a method for each of the N calls your actual server provides, but first of all, ISP suggests, that many client specific interfaces are better than one general purpose interface. For the same reason ILoginInterface is really kept to its bare minimum.
No matter, how these two are actually implemented, you will not need to change Main (unless of course the interface changes). This is DIP being applied. Main doesn't depend on the concrete implementation, only on a very concise abstraction.
Now let's have some implementations:
class LoginScreen implements ILoginInterface {
public function show(inputHandler:String->String->Void):Void {
//render the UI on the screen
//wait for the button to be clicked
//when done, call inputHandler with the input values from the respective fields
}
public function hide():Void {
//hide UI
}
public function error(reason:String):Void {
//display error message
}
public static function getInstance():LoginScreen {
//classical singleton instantiation
}
}
class Server implements ILoginService {
function new(host:String, port:Int) {
//init connection here for example
}
public static function getInstance():Server {
//classical singleton instantiation
}
public function login(user:String, pwd:String, onDone:LoginResult->Void) {
//issue login over the connection
//invoke the handler with the retrieved result
}
//... possibly other methods here, that are used by other classes
}
Ok, that was pretty straight forward, I suppose. But just for the fun of it, let's do something really idiotic:
class MailLogin implements ILoginInterface {
public function new(mail:String) {
//save address
}
public function show(inputHandler:String->String->Void):Void {
//print some sort of "waiting for authentication"-notification on screen
//send an email to the given address: "please respond with username:password"
//keep polling you mail server for a response, parse it and invoke the input handler
}
public function hide():Void {
//remove the "waiting for authentication"-notification
//send an email to the given address: "login successful"
}
public function error(reason:String):Void {
//send an email to the given address: "login failed. reason: [reason] please retry."
}
}
As pedestrian as this authentication may be, from the point of view of the Main class,
this doesn't change anything and thus will work just as well.
A more likely scenario is actually, that your login service is on another server (possibly an HTTP server), that makes the authentication, and in case of success creates a session on the actual app server. Design-wise, this could be reflected in two separate classes.
Now, let's talk about the "..." I left in Main. Well, I'm lazy, so I can tell you, in my code you are likely to see
var server:ILoginService = Server.getInstance();
var login:ILoginInterface = LoginScreen.getInstance();
Of course, this is far from being the clean way to do it. The truth is, it's the easiest way to go and the dependency is limited to one occurrence, that can later be removed through dependency injection.
Just as a simple example for an IoC-Container in haXe:
class Injector {
static var providers = new Hash < Void->Dynamic > ;
public static function setProvider<T>(type:Class<T>, provider:Void->T):Void {
var name = Type.getClassName(type);
if (providers.exists(name))
throw "duplicate provider for " + name;
else
providers.set(name, provider);
}
public static function get<T>(type:Class<T>):T {
var name = Type.getClassName(type);
return
if (providers.exists(name))
providers.get(name);
else
throw "no provider for " + name;
}
}
elegant usage (with using keyword):
using Injector;
//wherever you would like to wire it up:
ILoginService.setProvider(Server.getInstance);
ILoginInterface.setProvider(LoginScreen.getInstance);
//and in Main:
var server = ILoginService.get();
var login = ILoginInterface.get();
This way, you practically have no coupling between the individual classes.
As to the question how to pass events between the button and the login screen:
this is just a matter of taste and implementation.
The point of event driven programming is that both the source and the observer are only coupled in the sense,
that the source must be sending some sort of notification and the target must be able to handle it.
someButton.onClick = handler; basically does exactly that, but it's just so elegant and concise you don't make a fuzz about it.
someButton.onClick(handler); probably is a little better, since you can have multiple handlers, although this is rarely required of UI components. But in the end, if you want signalers, go with signalers.
Now when it comes to AOP, it is not the right approach in this situation. It's not a clever hack to wire up components between one another, but about dealing with cross-cutting concerns, such as adding a log, a history or even things as a persistence layer across a multitude of modules.
In general, try not to modularize or split the little parts of your application.
It is ok to have some spaghetti in your codebase, as long as
the spaghetti segments are well encapsulated
the spaghetti segments are small enough to be understood or otherwise refactored/rewritten in a reasonable amount of time, without breaking the app (which point no. 1 should guarantee)
Try rather to split the whole application into autonomous parts, which interact through concise interfaces. If a part grows too big, refactor it just the same way.
edit:
In response to Tom's questions:
that's a matter of taste. in some frameworks people go as far as using external configuration files, but that makes little sense with haXe, since you need to instruct the compiler to force compilation of the dependencies you inject at runtime. Setting up the dependency in your code, in a central file, is just as much work and far simpler. For more structure, you can split the app into "modules", each module having a loader class responsible for registering the implementations it provides. In your main file, you load the modules.
That depends. I tend to declare them in the package of the class depending on them and later on refactor them to an extra package in case they prove to be needed elsewhere. By using anonymous types, you can also completely decouple things, but you'll have a slight performance hit on platforms as flash9.
I wouldn't abstract the button and then inject an implementation through IoC, but feel free to do so. I would explicitely create it, because in the end, it's just a button. It has a style, a caption, screen position and size and fires click events. I think, this is unnecessary modularization, as pointed out above.
Stick to SRP. If you do, no class will grow unneccessarily big. The role of the Main class is to initialize the app. When done, it should pass control to a login controller, and when that controller acquires a user object, it can pass it on to the main controller of the actual app and so forth. I suggest you read a bit about behavioral patterns to get some ideas.
greetz
back2dos
First of all, I'm not familiar with Haxe at all. However, I would answer that what is described here sounds remarkably similar to how I've learned to do things in .NET, so it sounds to me like this is good practice.
In .NET, you have an "Event" that fires when a user clicks a button to do something (like logon) and then a method executes to "handle" the event.
There will always be code that describes what method is executed in one class when an event in another class is fired. It is not unnecessarily complex, it is necessarily complex. In the Visual Studio IDE, much of this code is hidden in "designer" files, so I don't see it on a regular basis, but if your IDE doesn't have this functionality, you've got to write the code yourself.
As for how this works with your custom loader class, I hope someone here can provide you an answer.