I have a general problem with this use case: I have a class A. This class has a non-abstract method doStuffCallback() which could be overridden but it's not necessary for every subclass. But: I want to ensure that if the method is overriden the subclass-method must call the parents method.
Example:
abstract class A {
private function doStuff() {
$this->doStuffCallback();
}
protected function doStuffCallback() {
// IMPORTANT CODE HERE
}
}
class B extends A {
protected function doStuffCallback() {
parent::doStuffCallback(); // I want to enforce this because the parents method code is important
// ALSO IMPORTANT CODE
}
}
Because the overridden method does the same thing it would be very ugly to define two methods for the same responsibility and a private helper-method which calls both. Like this:
abstract class A {
private function doStuff() {
$this->callDoStuffCallback();
}
private function callDoStuffCallback() {
$this->internalDoStuffCallback();
$this->doStuffCallback();
// This is VERY ugly
}
private function internalDoStuffCallback() {
// IMPORTANT CODE HERE
}
protected function doStuffCallback() {}
}
class B extends A {
protected function doStuffCallback() {
// IMPORTANT CODE
}
}
This is really ugly and laborious. So my question: Is there a way in PHP to force overriden methods to call the parents method?
No. There is no such language feature in PHP; this restriction is not possible in most subtype-'OO' languages.
Instead programs must rely on explicit documentation contracts; and hopefully, unit testing to ensure conformance.
Guards may also be employed such that, at some point by and by when a method on the parent class is used, it could throw an exception if the 'current state' is not valid (eg. such and such a method has not been called yet). This may also be made more explicit by making the subclass required to call (as defined in the documentation contract) some special method, instead of simply the overriden super method. However, such is outside of any type system.
While the self:: scope could be used (eg. call non-overriden method which calls overriden method), this would involve further magic (eg. some stack state) to avoid infinite recursion loops; and it would be as easy to accidentally omit usage.
My recommendation is to call a (private) method that calls this 'maybe overriden' method in relationship to whatever logic applies, as shown in the example (although hopefully with more task specific tames). Then the (protected) overriden method is not expected or required to handle any of the special logic itself; nor is it meant to be called directly outside of the context established by the parent class - it is just what it currently claims to be, a special callback.
I tend to disagree with "This is VERY ugly". It is the standard way of handling this use case and a variant of the Template Method Pattern.
Now I am just guessing because you did not provide a real example but if you say that the two methods "do the same thing", there might be something wrong with your design. If they do the same thing, why is calling the parent implementation necessary if the subclass does the same thing in a different way? To me it sounds like the method actually does more than one thing and you might be able to break it down into several parts that can be overridden individually (or not, then make them private or final).
I know this is an old topic but I was asking myself the same question and what I did is :
abstract class A {
private function doStuff() {
$this->doStuffCallback();
}
final protected function doStuffCallback() {
// IMPORTANT CODE HERE
$this->callNewFunction();
}
abstract protected function callNewFunction();
}
class B extends A {
protected function callNewFunction() {
// ALSO IMPORTANT CODE
}
}
So basically I would mark as "final" the function you wish to force the code for every child and then call a new "Abstract" function to force the childs to implement it. If you do not wish to force the new "Abstract" function, simply don't make it abstract.
Edit : This is basically #Fabian Schmengler's answer but more concrete with your example.
No, you can access, you can use method for parent, like this
<?php
class A {
function s1($p1) {
echo 's1: '.$p1;
}
}
class B extends A {
public function callParent($method, $p1) {
parent::$method($p1);
}
}
$b = new B();
$b->callParent('s1', 'param1');
or replace extending on magic methods __call and etc. https://github.com/StagnantIce/php_extend_magic/blob/master/AExtendClass.php
I've been trying to study up on PHP lately, and I find myself getting hung up on traits. I understand the concept of horizontal code reuse and not wanting to necessarily inherit from an abstract class. What I don't understand is: What is the crucial difference between using traits versus interfaces?
I've tried searching for a decent blog post or article explaining when to use one or the other, but the examples I've found so far seem so similar as to be identical.
Public Service Announcement:
I want to state for the record that I believe traits are almost always a code smell and should be avoided in favor of composition. It's my opinion that single inheritance is frequently abused to the point of being an anti-pattern and multiple inheritance only compounds this problem. You'll be much better served in most cases by favoring composition over inheritance (be it single or multiple). If you're still interested in traits and their relationship to interfaces, read on ...
Let's start by saying this:
Object-Oriented Programming (OOP) can be a difficult paradigm to grasp.
Just because you're using classes doesn't mean your code is
Object-Oriented (OO).
To write OO code you need to understand that OOP is really about the capabilities of your objects. You've got to think about classes in terms of what they can do instead of what they actually do. This is in stark contrast to traditional procedural programming where the focus is on making a bit of code "do something."
If OOP code is about planning and design, an interface is the blueprint and an object is the fully constructed house. Meanwhile, traits are simply a way to help build the house laid out by the blueprint (the interface).
Interfaces
So, why should we use interfaces? Quite simply, interfaces make our code less brittle. If you doubt this statement, ask anyone who's been forced to maintain legacy code that wasn't written against interfaces.
The interface is a contract between the programmer and his/her code. The interface says, "As long as you play by my rules you can implement me however you like and I promise I won't break your other code."
So as an example, consider a real-world scenario (no cars or widgets):
You want to implement a caching system for a web application to cut
down on server load
You start out by writing a class to cache request responses using APC:
class ApcCacher
{
public function fetch($key) {
return apc_fetch($key);
}
public function store($key, $data) {
return apc_store($key, $data);
}
public function delete($key) {
return apc_delete($key);
}
}
Then, in your HTTP response object, you check for a cache hit before doing all the work to generate the actual response:
class Controller
{
protected $req;
protected $resp;
protected $cacher;
public function __construct(Request $req, Response $resp, ApcCacher $cacher=NULL) {
$this->req = $req;
$this->resp = $resp;
$this->cacher = $cacher;
$this->buildResponse();
}
public function buildResponse() {
if (NULL !== $this->cacher && $response = $this->cacher->fetch($this->req->uri()) {
$this->resp = $response;
} else {
// Build the response manually
}
}
public function getResponse() {
return $this->resp;
}
}
This approach works great. But maybe a few weeks later you decide you want to use a file-based cache system instead of APC. Now you have to change your controller code because you've programmed your controller to work with the functionality of the ApcCacher class rather than to an interface that expresses the capabilities of the ApcCacher class. Let's say instead of the above you had made the Controller class reliant on a CacherInterface instead of the concrete ApcCacher like so:
// Your controller's constructor using the interface as a dependency
public function __construct(Request $req, Response $resp, CacherInterface $cacher=NULL)
To go along with that you define your interface like so:
interface CacherInterface
{
public function fetch($key);
public function store($key, $data);
public function delete($key);
}
In turn you have both your ApcCacher and your new FileCacher classes implement the CacherInterface and you program your Controller class to use the capabilities required by the interface.
This example (hopefully) demonstrates how programming to an interface allows you to change the internal implementation of your classes without worrying if the changes will break your other code.
Traits
Traits, on the other hand, are simply a method for re-using code. Interfaces should not be thought of as a mutually exclusive alternative to traits. In fact, creating traits that fulfill the capabilities required by an interface is the ideal use case.
You should only use traits when multiple classes share the same functionality (likely dictated by the same interface). There's no sense in using a trait to provide functionality for a single class: that only obfuscates what the class does and a better design would move the trait's functionality into the relevant class.
Consider the following trait implementation:
interface Person
{
public function greet();
public function eat($food);
}
trait EatingTrait
{
public function eat($food)
{
$this->putInMouth($food);
}
private function putInMouth($food)
{
// Digest delicious food
}
}
class NicePerson implements Person
{
use EatingTrait;
public function greet()
{
echo 'Good day, good sir!';
}
}
class MeanPerson implements Person
{
use EatingTrait;
public function greet()
{
echo 'Your mother was a hamster!';
}
}
A more concrete example: imagine both your FileCacher and your ApcCacher from the interface discussion use the same method to determine whether a cache entry is stale and should be deleted (obviously this isn't the case in real life, but go with it). You could write a trait and allow both classes to use it to for the common interface requirement.
One final word of caution: be careful not to go overboard with traits. Often traits are used as a crutch for poor design when unique class implementations would suffice. You should limit traits to fulfilling interface requirements for best code design.
An interface defines a set of methods that the implementing class must implement.
When a trait is use'd the implementations of the methods come along too--which doesn't happen in an Interface.
That is the biggest difference.
From the Horizontal Reuse for PHP RFC:
Traits is a mechanism for code reuse in single inheritance languages such as PHP. A Trait is intended to reduce some limitations of single inheritance by enabling a developer to reuse sets of methods freely in several independent classes living in different class hierarchies.
A trait is essentially PHP's implementation of a mixin, and is effectively a set of extension methods which can be added to any class through the addition of the trait. The methods then become part of that class' implementation, but without using inheritance.
From the PHP Manual (emphasis mine):
Traits are a mechanism for code reuse in single inheritance languages such as PHP. ... It is an addition to traditional inheritance and enables horizontal composition of behavior; that is, the application of class members without requiring inheritance.
An example:
trait myTrait {
function foo() { return "Foo!"; }
function bar() { return "Bar!"; }
}
With the above trait defined, I can now do the following:
class MyClass extends SomeBaseClass {
use myTrait; // Inclusion of the trait myTrait
}
At this point, when I create an instance of class MyClass, it has two methods, called foo() and bar() - which come from myTrait. And - notice that the trait-defined methods already have a method body - which an Interface-defined method can't.
Additionally - PHP, like many other languages, uses a single inheritance model - meaning that a class can derive from multiple interfaces, but not multiple classes. However, a PHP class can have multiple trait inclusions - which allows the programmer to include reusable pieces - as they might if including multiple base classes.
A few things to note:
-----------------------------------------------
| Interface | Base Class | Trait |
===============================================
> 1 per class | Yes | No | Yes |
---------------------------------------------------------------------
Define Method Body | No | Yes | Yes |
---------------------------------------------------------------------
Polymorphism | Yes | Yes | No |
---------------------------------------------------------------------
Polymorphism:
In the earlier example, where MyClass extends SomeBaseClass, MyClass is an instance of SomeBaseClass. In other words, an array such as SomeBaseClass[] bases can contain instances of MyClass. Similarly, if MyClass extended IBaseInterface, an array of IBaseInterface[] bases could contain instances of MyClass. There is no such polymorphic construct available with a trait - because a trait is essentially just code which is copied for the programmer's convenience into each class which uses it.
Precedence:
As described in the Manual:
An inherited member from a base class is overridden by a member inserted by a Trait. The precedence order is that members from the current class override Trait methods, which in return override inherited methods.
So - consider the following scenario:
class BaseClass {
function SomeMethod() { /* Do stuff here */ }
}
interface IBase {
function SomeMethod();
}
trait myTrait {
function SomeMethod() { /* Do different stuff here */ }
}
class MyClass extends BaseClass implements IBase {
use myTrait;
function SomeMethod() { /* Do a third thing */ }
}
When creating an instance of MyClass, above, the following occurs:
The Interface IBase requires a parameterless function called SomeMethod() to be provided.
The base class BaseClass provides an implementation of this method - satisfying the need.
The trait myTrait provides a parameterless function called SomeMethod() as well, which takes precedence over the BaseClass-version
The class MyClass provides its own version of SomeMethod() - which takes precedence over the trait-version.
Conclusion
An Interface can not provide a default implementation of a method body, while a trait can.
An Interface is a polymorphic, inherited construct - while a trait is not.
Multiple Interfaces can be used in the same class, and so can multiple traits.
I think traits are useful to create classes that contain methods that can be used as methods of several different classes.
For example:
trait ToolKit
{
public $errors = array();
public function error($msg)
{
$this->errors[] = $msg;
return false;
}
}
You can have and use this "error" method in any class that uses this trait.
class Something
{
use Toolkit;
public function do_something($zipcode)
{
if (preg_match('/^[0-9]{5}$/', $zipcode) !== 1)
return $this->error('Invalid zipcode.');
// do something here
}
}
While with interfaces you can only declare the method signature, but not its functions' code. Also, to use an interface you need to follow a hierarchy, using implements. This is not the case with traits.
It is completely different!
For beginners above answer might be difficult, this is the easiest way to understand it:
Traits
trait SayWorld {
public function sayHello() {
echo 'World!';
}
}
so if you want to have sayHello function in other classes without re-creating the whole function you can use traits,
class MyClass{
use SayWorld;
}
$o = new MyClass();
$o->sayHello();
Cool right!
Not only functions you can use anything in the trait(function, variables, const...). Also, you can use multiple traits: use SayWorld, AnotherTraits;
Interface
interface SayWorld {
public function sayHello();
}
class MyClass implements SayWorld {
public function sayHello() {
echo 'World!';
}
}
So this is how interfaces differ from traits: You have to re-create everything in the interface in an implemented class. Interfaces don't have an implementation and interfaces can only have functions and constants, it cannot have variables.
I hope this helps!
Traits are simply for code reuse.
Interface just provides the signature of the functions that is to be defined in the class where it can be used depending on the programmer's discretion. Thus giving us a prototype for a group of classes.
For reference-
http://www.php.net/manual/en/language.oop5.traits.php
An often-used metaphor to describe Traits is Traits are interfaces with implementation.
This is a good way of thinking about it in most circumstances, but there are a number of subtle differences between the two.
For a start, the instanceof operator will not work with traits (ie, a trait is not a real object), therefore you can't use that to see if a class has a certain trait (or to see if two otherwise unrelated classes share a trait). That's what they mean by it being a construct for horizontal code re-use.
There are functions now in PHP that will let you get a list of all the traits a class uses, but trait-inheritance means you'll need to do recursive checks to reliably check if a class at some point has a specific trait (there's example code on the PHP doco pages). But yeah, it's certainly not as simple and clean as instanceof is, and IMHO it's a feature that would make PHP better.
Also, abstract classes are still classes, so they don't solve multiple-inheritance related code re-use problems. Remember you can only extend one class (real or abstract) but implement multiple interfaces.
I've found traits and interfaces are really good to use hand in hand to create pseudo multiple inheritance. Eg:
class SlidingDoor extends Door implements IKeyed
{
use KeyedTrait;
[...] // Generally not a lot else goes here since it's all in the trait
}
Doing this means you can use instanceof to determine if the particular Door object is Keyed or not, you know you'll get a consistent set of methods, etc, and all the code is in one place across all the classes that use the KeyedTrait.
You can consider a trait as an automated "copy-paste" of code, basically.
Using traits is dangerous since there is no mean to know what it does before execution.
However, traits are more flexible because of their lack of limitations such as inheritance.
Traits can be useful to inject a method which checks something into a class, for example, the existence of another method or attribute. A nice article on that (but in French, sorry).
For French-reading people who can get it, the GNU/Linux Magazine HS 54 has an article on this subject.
If you know English and know what trait means, it is exactly what the name says. It is a class-less pack of methods and properties you attach to existing classes by typing use.
Basically, you could compare it to a single variable. Closures functions can use these variables from outside of the scope and that way they have the value inside. They are powerful and can be used in everything. Same happens to traits if they are being used.
Other answers did a great job of explaining differences between interfaces and traits. I will focus on a useful real world example, in particular one which demonstrates that traits can use instance variables - allowing you add behavior to a class with minimal boilerplate code.
Again, like mentioned by others, traits pair well with interfaces, allowing the interface to specify the behavior contract, and the trait to fulfill the implementation.
Adding event publish / subscribe capabilities to a class can be a common scenario in some code bases. There's 3 common solutions:
Define a base class with event pub/sub code, and then classes which want to offer events can extend it in order to gain the capabilities.
Define a class with event pub/sub code, and then other classes which want to offer events can use it via composition, defining their own methods to wrap the composed object, proxying the method calls to it.
Define a trait with event pub/sub code, and then other classes which want to offer events can use the trait, aka import it, to gain the capabilities.
How well does each work?
#1 Doesn't work well. It would, until the day you realize you can't extend the base class because you're already extending something else. I won't show an example of this because it should be obvious how limiting it is to use inheritance like this.
#2 & #3 both work well. I'll show an example which highlights some differences.
First, some code that will be the same between both examples:
An interface
interface Observable {
function addEventListener($eventName, callable $listener);
function removeEventListener($eventName, callable $listener);
function removeAllEventListeners($eventName);
}
And some code to demonstrate usage:
$auction = new Auction();
// Add a listener, so we know when we get a bid.
$auction->addEventListener('bid', function($bidderName, $bidAmount){
echo "Got a bid of $bidAmount from $bidderName\n";
});
// Mock some bids.
foreach (['Moe', 'Curly', 'Larry'] as $name) {
$auction->addBid($name, rand());
}
Ok, now lets show how the implementation of the Auction class will differ when using traits.
First, here's how #2 (using composition) would look like:
class EventEmitter {
private $eventListenersByName = [];
function addEventListener($eventName, callable $listener) {
$this->eventListenersByName[$eventName][] = $listener;
}
function removeEventListener($eventName, callable $listener) {
$this->eventListenersByName[$eventName] = array_filter($this->eventListenersByName[$eventName], function($existingListener) use ($listener) {
return $existingListener === $listener;
});
}
function removeAllEventListeners($eventName) {
$this->eventListenersByName[$eventName] = [];
}
function triggerEvent($eventName, array $eventArgs) {
foreach ($this->eventListenersByName[$eventName] as $listener) {
call_user_func_array($listener, $eventArgs);
}
}
}
class Auction implements Observable {
private $eventEmitter;
public function __construct() {
$this->eventEmitter = new EventEmitter();
}
function addBid($bidderName, $bidAmount) {
$this->eventEmitter->triggerEvent('bid', [$bidderName, $bidAmount]);
}
function addEventListener($eventName, callable $listener) {
$this->eventEmitter->addEventListener($eventName, $listener);
}
function removeEventListener($eventName, callable $listener) {
$this->eventEmitter->removeEventListener($eventName, $listener);
}
function removeAllEventListeners($eventName) {
$this->eventEmitter->removeAllEventListeners($eventName);
}
}
Here's how #3 (traits) would look like:
trait EventEmitterTrait {
private $eventListenersByName = [];
function addEventListener($eventName, callable $listener) {
$this->eventListenersByName[$eventName][] = $listener;
}
function removeEventListener($eventName, callable $listener) {
$this->eventListenersByName[$eventName] = array_filter($this->eventListenersByName[$eventName], function($existingListener) use ($listener) {
return $existingListener === $listener;
});
}
function removeAllEventListeners($eventName) {
$this->eventListenersByName[$eventName] = [];
}
protected function triggerEvent($eventName, array $eventArgs) {
foreach ($this->eventListenersByName[$eventName] as $listener) {
call_user_func_array($listener, $eventArgs);
}
}
}
class Auction implements Observable {
use EventEmitterTrait;
function addBid($bidderName, $bidAmount) {
$this->triggerEvent('bid', [$bidderName, $bidAmount]);
}
}
Note that the code inside the EventEmitterTrait is exactly the same as what's inside the EventEmitter class except the trait declares the triggerEvent() method as protected. So, the only difference you need to look at is the implementation of the Auction class.
And the difference is large. When using composition, we get a great solution, allowing us to reuse our EventEmitter by as many classes as we like. But, the main drawback is the we have a lot of boilerplate code that we need to write and maintain because for each method defined in the Observable interface, we need to implement it and write boring boilerplate code that just forwards the arguments onto the corresponding method in our composed the EventEmitter object. Using the trait in this example lets us avoid that, helping us reduce boilerplate code and improve maintainability.
However, there may be times where you don't want your Auction class to implement the full Observable interface - maybe you only want to expose 1 or 2 methods, or maybe even none at all so that you can define your own method signatures. In such a case, you might still prefer the composition method.
But, the trait is very compelling in most scenarios, especially if the interface has lots of methods, which causes you to write lots of boilerplate.
* You could actually kinda do both - define the EventEmitter class in case you ever want to use it compositionally, and define the EventEmitterTrait trait too, using the EventEmitter class implementation inside the trait :)
The main difference is that, with interfaces, you must define the actual implementation of each method within each class that implements said interface, so you can have many classes implement the same interface but with different behavior, while traits are just chunks of code injected in a class; another important difference is that trait methods can only be class-methods or static-methods, unlike interface methods which can also (and usually are) be instance methods.
The trait is same as a class we can use for multiple inheritance purposes and also code reusability.
We can use trait inside the class and also we can use multiple traits in the same class with 'use keyword'.
The interface is using for code reusability same as a trait
the interface is extend multiple interfaces so we can solve the multiple inheritance problems but when we implement the interface then we should create all the methods inside the class.
For more info click below link:
http://php.net/manual/en/language.oop5.traits.php
http://php.net/manual/en/language.oop5.interfaces.php
An interface is a contract that says “this object is able to do this thing”, whereas a trait is giving the object the ability to do the thing.
A trait is essentially a way to “copy and paste” code between classes.
Try reading this article, What are PHP traits?
This question already has answers here:
Closed 12 years ago.
Possible Duplicate:
PHP: What is the difference between an interface and abstract class?
As far as I understand, a class implements or extends abstract or interface class has to use the default methods. I know we can use implement keyword to use multiple interfaces, but we only can extend 1 abstract. Which one to use in real life project and the difference?
The differences are both theoretical and practical:
interface is a description of some capability your class has and advertises (so various classes implementing the same interface can be used the same way)
abstract class can be a default implementation, containing the parts which are likely to appear in all the implementations. It doesn't have to implement the complete interface
Example - an interface:
// define what any class implementing this must be capable of
interface IRetrieveData {
// retrieve the resource
function fetch($url);
// get the result of the retrieval (true on success, false otherwise)
function getOperationResult();
// what is this class called?
function getMyClassName();
}
Now we have the set of requirements that will be checked for every class implementing this. Let's make an abstract class and its children:
// define default behavior for the children of this class
abstract class AbstractRetriever implements IRetrieveData {
protected $result = false;
// define here, so we don't need to define this in every implementation
function getResult() {
return $result;
}
// note we're not implementing the other two methods,
// as this will be very different for each class.
}
class CurlRetriever extends AbstractRetriever {
function fetch($url) {
// (setup, config etc...)
$out = curl_execute();
$this->result = !(curl_error());
return $out;
}
function getMyClassName() {
return 'CurlRetriever is my name!';
}
}
class PhpRetriever extends AbstractRetriever {
function fetch($url) {
$out = file_get_contents($url);
$this->result = ($out !== FALSE);
return $out;
}
function getMyClassName() {
return 'PhpRetriever';
}
}
A completely different abstract class (unrelated to the interface), with a subclass which implements our interface:
abstract class AbstractDog {
function bark() {
return 'Woof!';
}
}
class GoldenRetriever extends AbstractDog implements IRetrieveData {
// this class has a completely different implementation
// than AbstractRetriever
// so it doesn't make sense to extend AbstractRetriever
// however, we need to implement all the methods of the interface
private $hasFetched = false;
function getResult() {
return $this->hasFetched;
}
function fetch($url) {
// (some retrieval code etc...)
$this->hasFetched = true;
return $response;
}
function getMyClassName() {
return parent::bark();
}
}
Now, in other code, we can do this:
function getStuff(IRetrieveData $retriever, $url) {
$stuff = $retriever->fetch($url);
}
and we don't have to worry which of the retrievers (cURL, PHP, or Golden) will be passed in, and how are they going to accomplish the goal, as all should be capable of behaving similarly. You could do this with an abstract class, too, but then you're restricting yourself based on the classes' ancestor, instead of its capability.
Multiple vs. single inheritance:
You can only inherit from a single abstract class
You can implement multiple interfaces
Implementation:
An abstract class can actually have functioning code in it. This lets you share implementation between the child classes
An interface only defines public member functions. Classes implementing the same interface don't actually share code.
That's what I know off the top of my head.
The metaphor I heard best was that an abstract class is a half-completed class. It's not done; you still have to finish it. So when you make a class that extends an abstract class, you are just completing what you began in the abstract class. This is also why you can't instantiate an abstract class; that you've made it abstract indicates that it's incomplete. It still needs some additional functionality.
An an interface just guarantees that certain methods, each with a certain number of arguments, must exist within a class that implements it. So that later on, a programmer who uses a class that implements a particular interface can rest assured that they can call certain methods on that class.
See this page: 5 Main Difference between Abstract class and Interface in PHP
And this: related StackOverflow answer.
Here's a good description of the differences between the two:
http://www.supertom.com/code/php_abstracts_and_interfaces.html
It all boils down to the fact that extends is a "is-a" relationship while implements is a "has-a" relationship.
"An Abstract Class can contain default Implementation, where as an
Interface should not contain any implementation at all. "
As far as which to use in real world application... it really comes down to context.
For example, there was a question on here the other day about implementing a game using PHP. Here they had a abstract class defining a monster and any monster could be based off of this abstract class. This allowed for inheritance of default monster properties.
Whereas for an interface, you are defining a general requirements for a way to "interface" (pardon using the term in the explanation) some system. An example of this from a recent project I did. I implemented a soapclient in php to interact with a soapserver from a third party. This interface defines what soap methods the server supports and thus any class implementing my interface must define those methods.
I'm trying to create a PHP file that calls a function in another file. Some sample code:
Interface code:
interface AJAXDispatcher {
static function dispatch($action);
}
Implementation:
class myAJAX implements AJAXDispatcher {
static function dispatch($action) {
if ($action === "action1") {
do_something();
}
This seems ok to me. I try to call it by first importing the file that it's in. I'm trying to make it independent of the name of the class so that I can do something like this:
AJAXDispatcher::dispatch($action);
Thought this would work as myAJAX would inherit from AJAXDispatcher, but I get the following error:
Fatal error: Cannot call abstract method AJAXDispatcher::dispatch() in ....
Anyone know what I'm doing wrong?
Interfaces with static methods don't make any sense, because to call a static method you (usually) need to know the class name.
Instead, you should make the method non-static and create an instance of myAJAX somewhere. The code that calls the AJAXDispatcher receives the instance and calls it. You can use type hinting to ensure you are getting the right instance.
interface AJAXDispatcher {
public function dispatch($action);
}
class myAJAX implements AJAXDispatcher {
public function dispatch($action) {
do_something();
}
}
class Controller {
private $dispatcher;
public function __construct(AJAXDispatcher $dispatcher) {
$this->dispatcher = $dispatcher;
}
public function action($action) {
$this->dispatcher->dispatch($action);
}
}
$dispatcher = new myAJAX();
$controller = new Controller($dispatcher);
$controller->action('index');
This example uses the Dependency Injection design pattern.
An interface has no method implementation. It only defines a public API that classes have to implement. How they implement it, is up to the concrete classes. Thus, you cannot call methods of an interface directly, because there is no code to call. You have to call the method on the implementing class.
Have a look at the PHP Manual on Interfaces.
No, you can't do that. There are several things wrong here
That's now how inheritance works. Method chaining goes up the class hierarchy, now down.
Static methods are connected to the class. If you override a static method in a subclass, and want to invoke the subclass' version, you must reference the subclass explicitly.
Interfaces have no implementation. Even if the language allowed the type of call you're making, nothing would happen. AJAXDispatcher::dispatch() has no body.
You're going to have to re-think your strategy here.