Related
I have read in many places that "getters and setters are evil". And I understood why so. But I don't know how to avoid them completely. Say Item is a class that has information about item name, qty, price etc...
and ItemList is a class, which has a list of Items. To find the grand total:
int grandTotal()
{
int total = 0;
for (Item item: itemList)
total += item.getPrice();
return total;
}
In the above case, how does one avoid getPrice()? The Item class provides getName, setName, etc....
How do I avoid them?
When should you use getters and setters?
Getters and setters are great for configuring or determining the configuration of a class, or retrieving data from a model
Getting the price of an item is an entirely reasonable use of a getter. That is data that needs to be available and may involve special considerations to protect the data by adding validation or sanitization to the setter.
You can also provide getters without setters. They do not have to come in pairs.
When shouldn't you use getters and setters?
Sometimes objects rely on internal properties that will never be exposed. For example, Iterators and internal collections. Exposing the internal collection could have dramatically negative and unexpected consequences.
Also, for example, let's say you are communicating via some HttpURLConnection. Exposing the setter for your HttpURLConnection means that you could end up with a very odd state should the connection be changed while waiting to receive data. This connection is something that should be created on instantiation or entirely managed internally.
Summary
If you have data that is for all intents and purposes public, but needs to be managed: use getters and setters.
If you have data that needs to be retrieved but under no circumstances should ever be changed: use a getter but not a setter.
If you have data that needs to be set for internal purposes and should never be publicly exposed (and cannot be set at instantiation): use a setter but not a getter (setter presumably prevents a second call affecting the internal property)
If you have something that is entirely internal and no other class needs to access it or change it directly, then use neither.
Don't forget that setters and getters can be private and even for internally managed properties, having a setter that manages the property may be desirable. For example, taking a connection string and passing it to the setter for HttpURLConnection.
Also note:
Allen Holub's article Why getter and setter methods are evil seems to be the source of OP's reasoning but, in my opinion, the article does a poor job of explaining its point.
Edit: Added summary
Edit 2: spelling corrections
It's a shame to see a small, vocal minority take a back lash against the whole "Getters and Setters" are evil debate. Firstly the article title is purposely provocative to draw you in, as should any blog post. I've in turn blogged about this before and several years later updated my opinions and ideas about this question. I'll summarise the best I can here.
Getters and setters (accessors) are not evil
They are "evil" (unnecessary) most of the time however
Encapsulation is not just adding accessors around private fields to control change, after all there is no benefit to added get/set methods that just modify a private field
You should write as much code as possible with the principle of "Tell, Don't Ask"
You need to use accessors for framework code, DTOs, serialisation and so forth. Don't try to fight this.
You want your core domain logic (business objects) to be as property free as possible however. You should tell objects to do stuff, not check their internal state at will.
If you have a load of accessors you essentially violate encapsulation. For example:
class Employee
{
public decimal Salary { get; set; }
// Methods with behaviour...
}
This is a crap domain object, because I can do this:
me.Salary = 100000000.00;
This may be a simple example, but as anyone who works in a professional environment can attest to, if there is some code that is public people will make use of it. It would not be wrong for a developer to see this and start adding loads of checks around the codebase using the Salary to decide what do with the Employee.
A better object would be:
class Employee
{
private decimal salary;
public void GivePayRise()
{
// Should this employee get a pay rise.
// Apply business logic - get value etc...
// Give raise
}
// More methods with behaviour
}
Now we cannot rely on Salary being public knowledge. Anyone wanting to give a pay rise to employees must do this via this method. This is great because the business logic for this is contained in one place. We can change this one place and effect everywhere the Employee is used.
The following sample is a brilliant example of boilerplate setters and getters.
class Item{
private double price;
public void setPrice(final double price){
this.price = price;
}
public double getPrice(){
return this.price;
}
}
Some coders think that this is called encapsulation, but in fact this code is exact equivalent of
class Item{
public double price;
}
In both classes price is not protected or encapsulated, but the second class reads easier.
class Item{
private double price;
public void setPrice(final double price){
if(isValidPrice(price))
this.price = price;
else throw new IllegalArgumentException(price+" is not valid!");
}
public double getPrice(){
return this.price;
}
}
This is a real encapsulation, the invariant of the class is guarded by the setPrice. My advice - don't write dummy getters and setters, use getters and setters only if they guard the invariant of your class
I have read in many places that "getters and setters are evil".
Really? That sounds crazy to me. Many? Show us one. We'll tear it to shreds.
And I understood why so.
I don't. It seems crazy to me. Either your misunderstood but think you did understand, or the original source is just crazy.
But I don't know how to avoid them completely.
You shouldn't.
how to avoid getPrice?
See, why would you want to avoid that? How else are you suppose to get data out of your objects?
how to avoid them???
Don't. Stop reading crazy talk.
When someone tells you that getters and setters are evil, think about why they are saying that.
Getters
Are they evil? There is no such thing as evil in code. Code is code and is neither good nor bad. It's just a matter of how hard it is to read and debug.
In your case, I think it is perfectly fine to use a getter to calculate the final price.
The "evil"
Usecase: you think you want the price of an item when buying something.
People sometimes use getters like this:
if(item.getPrice() <= my_balance) {
myBank.buyItem(item);
}
There is nothing wrong with this code, but it isn't as straight-forward as it could be. Look at this (more pragmatic approach):
myBank.buyItem(item); //throws NotEnoughBalanceException
It's not the buyers or the cashiers job to check the price of an item when buying something. It's the actually the bank's job. Imagine that customer A has a SimpleBank.java
public class SimpleBank implements Transaction {
public void buyItem(Item item){
if(getCustomer().getBalance() >= item.getPrice()){
transactionId = doTransaction(item.getPrice());
sendTransactionOK(transactionId);
}
}
}
The first approach seems fine here. But what if customer B has a NewAndImprovedBank.java?
public class NewAndImprovedBank implements Transaction {
public void buyItem(Item item){
int difference = getCustomer().getBalance() - item.getPrice();
if (difference >= 0) {
transactionId = doTransaction(item.getPrice());
sendTransactionOK(transactionId);
} else if (difference <= getCustomer().getCreditLimit()){
transactionId = doTransactionWithCredit(item.getPrice());
sendTransactionOK(transactionId);
}
}
}
You might think that you are being defensive when using the first approach, but actually you are limiting the capabilities of your system.
Conclusion
Don't ask for permission aka item.getPrice() , ask for forgiveness aka NotEnoughBalanceException instead.
getPrice() is accessing a private variable I'm assuming.
To answer your question directly, make the price variable public, and code something like (syntax may differ depending on language, use of pointers etc):
total += item.price;
However this is generally considered bad style. Class variables should generally remain private.
Please see my comment on the question.
How to avoid getters and setters? Design classes that actually act upon the data they hold.
Getters lie about the data anyway. In the Item.getPrice() example, I can see I'm getting an int. But is the price in dollars or cents? Does it include tax(es)? What if I want to know the price in a different country or state, can I still use getPrice()?
Yes, this might be beyond the scope of what the system is designed to do, and yes, you might just end up returning a variable's value from your method, but advertising that implementation detail by using a getter weakens your API.
'Evil' as .getAttention()
This has been discussed often, and even perhaps went a bit viral, as a result of the pejorative term "Evil" used in the dialog. There are times when you need them, of course. But the problem is using them correctly. You see, Professor Holub's rant isn't about what your code is doing now, but about boxing yourself in so that change in the future is painful and error prone.
In fact, all I have read by him carries this as its theme.
How does that theme apply to the class Item?
A look at the future of Item
Here is fictions's item class:
class Item{
private double price;
public void setPrice(final double price){
if(isValidPrice(price))
this.price = price;
else throw new IllegalArgumentException(price+" is not valid!");
}
public double getPrice(){
return this.price;
}
}
This is all well and good- but it is still 'Evil' in the sense that it could cause you a lot of grief in the future.
The grief is apt to come from the fact that one day 'price' may have to take different currencies into account (and perhaps even more complex barter schemes). By setting price to be a double, any code that is written between now and the 'apocalypse' (we're talking evil, after all) will be wiring price to a double.
It is much better (even Good, perhaps) to pass in a Price object instead of a double. By doing so you can easily implement changes to what you mean by 'price' without breaking the existing interfaces.
The takeaway on getters and setters
If you find yourself using getters and setters on simple types, make sure you consider possible future changes to the interface. There is a very good chance you shouldn't be. Are you using setName(String name)? You should consider setName(IdentityObject id) or even setIdentity(IdentityObject id) in case other identification models show up (avatars, keys, whatever). Sure you can always go around and setAvatar and setKey on everything, but by using an object in your method signature you make it easier to extend in the future to the objects that can use the new identity properties and not break the legacy objects.
A different perspective that is missing here so far: getters and setters invite to violate the Tell Don't Ask principle!
Imagine you go shopping in the supermarket. In the end, the cashier wants money from you. The getter/setter approach is: you hand over your purse to the cashier, the cashier counts the money in your purse, takes the money you owe, and gives back the purse.
Is that how you do things in reality? Not at all. In the real world, you typically don't care about the internal state of "autonomous" other "objects". The cashier tells you: "your bill is 5,85 USD". Then you pay. How you do that is up to you, the only thing the cashier wants/needs is he receives that amount of money from your side.
Thus: you avoid getters and setters by thinking in terms of behavior, not in terms of state. Getters/setters manipulate state, from the "outside" (by doing avail = purse.getAvailableMoney() and purse.setAvailableMoney(avail - 5.85). Instead, you want to call person.makePayment(5.85).
How to avoid getters and setters in Java?
Use Project Lombok
Cloudanger answer is is one, but you must also realize that the item list will likely contain many item objects with quantity ordered on it.
Solution : create another class in between them that stores your item in the item list and the qty ordered for that item (Let's say the class is called OrderLine).
OrderLine will have Item and qty as fields.
After that, code something like calculateTotal(int qty) in Item which return price*qty.
Create a method in OrderLine that call calculateTotal(qtyOrdered)
Pass the return value to the itemList.
This way, you avoid getters.
The ItemList will only know the total price.
Your code should live with your data.
Ask the Object who has the data to calculate the totalPrice instead of asking that object for raw data to calculate your totalPrice.
Really?
I don't think that. on the contrary the getters and setters help you to protect the consistense of the variables.
The importance of getters and setters is to provide protection to private attributes so that they can not be accessed directly for this it is best that you create a class with the attribute item in which you include the corresponding get and set.
Use a helper class ShoppingCart. Item's method item.addTo(ShoppingCart cart) would add the price to the totalSum of the cart using shoppingCart.addItem(Item item, int price)
Dependency from Item to ShoppingCart isn't disadvantageous if the Items are meant to be items of ShoppingCarts.
In the case where Items live solely for the ShoppingCart and the Item class is small, I would more likely have the Item as an inner class of the ShoppingCart, so that the ShoppingCart would have access to the private variables of the items.
Other thoughts
It would also be possible, although quite unintuitive design, to have the Item class count the sum (item.calculateSum(List<Item> items)), since it can access the private parts of other items without breaking encapsulation.
To others wondering why the getters are bad. Consider the given example where the getPrice() returns integer. If you would want to change that to something better like BigDecimal at least or a custom money type with currency, then it wouldn't be possible since the return type int exposes the internal type.
Getters and setters are evil because they break encapsulation and can unnecessarily expose an objects internal state and allow it to be modified in way it should not be. The following article elaborates on this problem:
http://programmer.97things.oreilly.com/wiki/index.php/Encapsulate_Behavior,_not_Just_State
You can avoid getter and setter at places by using _classname__attributename because that's the changed new name once you declare private to any attribute.
So if Item is the class with a private attribute declared as __price
then instead of item.getPrice() you can write _Item__price.
It will work fine.
I had a discussion at work regarding "Inheritance in domain model is complicating developers life". I'm an OO programmer so I started to look for arguments that having inheritance in domain model will ease the developer life actually instead of having switches all over the place.
What I would like to see is this :
class Animal {
}
class Cat : Animal {
}
class Dog : Animal {
}
What the other colleague is saying is :
public enum AnimalType {
Unknown,
Cat,
Dog
}
public class Animal {
public AnimalType Type { get; set; }
}
How do I convince him (links are WELCOME ) that a class hierarchy would be better than having a enum property for this kind of situations?
Thanks!
Here is how I reason about it:
Only use inheritance if the role/type will never change.
e.g.
using inheritance for things like:
Fireman <- Employee <- Person is wrong.
as soon as Freddy the fireman changes job or becomes unemployed, you have to kill him and recreate a new object of the new type with all of the old relations attached to it.
So the naive solution to the above problem would be to give a JobTitle enum property to the person class.
This can be enough in some scenarios, e.g. if you don't need very complex behaviors associated with the role/type.
The more correct way would be to give the person class a list of roles.
Each role represents e.g an employment with a time span.
e.g.
freddy.Roles.Add(new Employement( employmentDate, jobTitle ));
or if that is overkill:
freddy.CurrentEmployment = new Employement( employmentDate, jobTitle );
This way , Freddy can become a developer w/o we having to kill him first.
However, all my ramblings still haven't answered if you should use an enum or type hierarchy for the jobtitle.
In pure in mem OO I'd say that it's more correct to use inheritance for the jobtitles here.
But if you are doing O/R mapping you might end up with a bit overcomplex data model behind the scenes if the mapper tries to map each sub type to a new table.
So in such cases, I often go for the enum approach if there is no real/complex behavior associated with the types.
I can live with a "if type == JobTitles.Fireman ..." if the usage is limited and it makes things easer or less complex.
e.g. the Entity Framework 4 designer for .NET can only map each sub type to a new table. and you might get an ugly model or alot of joins when you query your database w/o any real benefit.
However I do use inheritance if the type/role is static.
e.g. for Products.
you might have CD <- Product and Book <- Product.
Inheritance wins here because in this case you most likely have different state associated with the types.
CD might have a number of tracks property while a book might have number of pages property.
So in short, it depends ;-)
Also, at the end of the day you will most likely end up with a lot of switch statements either way.
Let's say you want to edit a "Product" , even if you use inheritance, you will probably have code like this:
if (product is Book)
Response.Redicted("~/EditBook.aspx?id" + product.id);
Because encoding the edit book url in the entity class would be plain ugly since it would force your business entites to know about your site structure etc.
Having an enum is like throwing a party for all those Open/Closed Principle is for suckers people.
It invites you to check if an animal is of a certain type and then apply custom logic for each type. And that can render horrible code, which makes it hard to continue building on your system.
Why?
Doing "if this type, do this, else do that" prevents good code.
Any time you introduce a new type, all those ifs get invalid if the new type is not handled. In larger systems, it's hard to find all those ifs, which will lead to bugs eventually.
A much better approach is to use small, well-defined feature interfaces (Interface segregation principle).
Then you will only have an if but no 'else' since all concretes can implement a specific feature.
Compare
if (animal is ICanFly flyer)
flyer.Sail();
to
// A bird and a fly are fundamentally different implementations
// but both can fly.
if (animal is Bird b)
b.Sail();
else if (animal is Fly f)
b.Sail();
See? the former one needs to be checked once while the latter has to be checked for every animal that can fly.
Enums are good when:
The set of values is fixed and never or very rarely changes.
You want to be able to represent a union of values (i.e. combining flags).
You don't need to attach other state to each value. (Java doesn't have this limitation.)
If you could solve your problem with a number, an enum is likely a good fit and more type safe. If you need any more flexibility than the above, then enums are likely not the right answer. Using polymorphic classes, you can:
Statically ensure that all type-specific behavior is handled. For example, if you need all animals to be able to Bark(), making Animal classes with an abstract Bark() method will let the compiler check for you that each subclass implements it. If you use an enum and a big switch, it won't ensure that you've handled every case.
You can add new cases (types of animals in your example). This can be done across source files, and even across package boundaries. With an enum, once you've declared it, it's frozen. Open-ended extension is one of the primary strengths of OOP.
It's important to note that your colleague's example is not in direct opposition to yours. If he wants an animal's type to be an exposed property (which is useful for some things), you can still do that without using an enum, using the type object pattern:
public abstract class AnimalType {
public static AnimalType Unknown { get; private set; }
public static AnimalType Cat { get; private set; }
public static AnimalType Dog { get; private set; }
static AnimalType() {
Unknown = new AnimalType("Unknown");
Cat = new AnimalType("Cat");
Dog = new AnimalType("Dog");
}
}
public class Animal {
public AnimalType Type { get; set; }
}
This gives you the convenience of an enum: you can do AnimalType.Cat and you can get the type of an animal. But it also gives you the flexibility of classes: you can add fields to AnimalType to store additional data with each type, add virtual methods, etc. More importantly, you can define new animal types by just creating new instances of AnimalType.
I'd urge you to reconsider: in an anemic domain model (per the comments above), cats don't behave differently than dogs, so there's no polymorphism. An animal's type really is just an attribute. It's hard to see what inheritance buys you there.
Most importantly OOPS means modeling reality. Inheritance gives you the opportunity to say Cat is an animal. Animal should not know if its a cat now shout it and then decide that it is suppose to Meow and not Bark, Encapsulation gets defeated there. Less code as now you do not have to do If else as you said.
Both solutions are right.
You should look which techniques applies better to you problem.
If your program uses few different objects, and doesn't add new classes, its better to stay with enumerations.
But if you program uses a lot of different objects (different classes), and may add new classes, in the future, better try the inheritance way.
Using online dictionary tools doesn't really help. I think the way encapsulate is use in computer science doesn't exactly match its meaning in plain English.
What is the antonym of computer science's version of encaspulate? More specifically, what is an antonym for encapsulate that would work as a function name.
Why should I care? Here's my motivation:
// A class with a private member variable;
class Private
{
public:
// Test will be able to access Private's private members;
class Test;
private:
int i;
}
// Make Test exactly like Private
class Private::Test : public Private
{
public:
// Make Private's copy of i available publicly in Test
using Private::i;
};
// A convenience function to quickly break encapsulation on a class to be tested.
// I don't have good name for what it does
Private::Test& foo( Private& p )
{ return *reinterpret_cast<Private::Test*>(&p); } // power cast
void unit_test()
{
Private p;
// using the function quickly grab access to p's internals.
// obviously it would be evil to use this anywhere except in unit tests.
assert( foo(p).i == 42 );
}
The antonym is "C".
Ok, just kidding. (Sort of.)
The best terms I can come up with are "expose" and "violate".
The purpose behind encapsulation is to hide/cover/protect. The antonym would be reveal/expose/make public.
How about Decapsulation..
Though it aint a computer science term, but in medical science, Surgical removal of a capsule or enveloping membrane.. Check out here..
"Removing/Breaking encapsulation" is about the closest thing I've seen, honestly.
If you think of the word in the English sense, to encapsulate means to enclose within something. But in the CS sense, there's this concept of protection levels and it looks like you want to imply circumventing the access levels as well, so something like "extraction" doesn't really convey the meaning you're looking for.
But if you just think of it in terms of what the access levels are, it looks like you're making something public so, how about "publicizing"?
This is not such a simple question - Scott Meyers had an interesting article to demonstrate some of the nuances around encapsulation here.
I'll start with the punchline: If
you're writing a function that can be
implemented as either a member or as a
non-friend non-member, you should
prefer to implement it as a non-member
function. That decision increases
class encapsulation. When you think
encapsulation, you should think
non-member functions.
How about "Bad Idea"?
The true antonym of "Encapsulation" is "Global State".
The general opposite of encapsulation is coupling and we often talk about systems that are tightly coupled or loosely coupled.
The reason you'd want components to be encapsulated is because it makes it easier to reason about how they work.
Take the analogy of trains: the consequence of coupling the railcars is that the driver must consider the characteristics (inertia, length) of the entire train.
Obviously, though, we couple systems because we need them to work together.
Inverted encapsulation and data structures
There's another term that I've been digging for, which is how I came across this question, that refers to a non-standard style of data structures.
The standard style of encapsulation is exemplified by Java's LinkedList; the actual nodes of the list are designed to be inaccessible to the consumer. The theory is that this is an implementation detail and can change to improve performance, while existing code will continue to run.
Another style is the classic functional cons-list. This is a singly linked list, and the idea is that it's so simple that there's nothing to improve about the data structure, e.g.
data [a] = [] | a : [a] deriving (Eq, Ord)
-- Haskellers then work directly with the list
-- There's nothing to hide because it's so simple
typicalHaskell :: [a] -> b
typicalHaskell [] = emptyValue
typicalHaskell h : t = h `doAThing` (typicalHaskell t)
That's the definition from Haskell's standard prelude though the report notes that isn't valid Haskell syntax, and in practice [a] is defined in the guts of the compiler.
Then there's what I'm calling an "inverted" data structure, but I'm still looking for the correct term. This is, I think, really the opposite of encapsulation.
A good example of this is Python's heapq module. The data structure here is a binary heap, but there isn't a Heap class. Rather, you get a collection of functions that operate on generic Python lists and you're responsible for using those methods correctly to ensure the heap invariants are maintained.
How about "spaghetti"?
This is quite a common problem I run into. Let's hear your solutions. I'm going to use an Employee-managing application as an example:-
We've got some entity classes, some of which implement a particular interface.
public interface IEmployee { ... }
public interface IRecievesBonus { int Amount { get; } }
public class Manager : IEmployee, IRecievesBonus { ... }
public class Grunt : IEmployee /* This company sucks! */ { ... }
We've got a collection of Employees that we can iterate over. We need to grab all the objects that implement IRecievesBonus and pay the bonus.
The naive implementation goes something along the lines of:-
foreach(Employee employee in employees)
{
IRecievesBonus bonusReciever = employee as IRecievesBonus;
if(bonusReciever != null)
{
PayBonus(bonusReciever);
}
}
or alternately in C#:-
foreach(IRecievesBonus bonusReciever in employees.OfType<IRecievesBonus>())
{
PayBonus(bonusReciever);
}
We cannot modify the IEmployee interface to include details of the child type as we don't want to pollute the super-type with details that only the sub-type cares about.
We do not have an existing collection of only the subtype.
We cannot use the Visitor pattern because the element types are not stable. Also, we might have a type which implements both IRecievesBonus and IDrinksTea. Its Accept method would contain an ambiguous call to visitor.Visit(this).
Often we're forced down this route because we can't modify the super-type, nor the collection e.g. in .NET we may need to find all the Buttons on this Form via the child Controls collection. We may need to do something to the child types that depends on some aspect of the child type (e.g. the bonus amount in the example above).
Strikes me as odd that there isn't an "accepted" way to do this, given how often it comes up.
1) Is the type conversion worth avoiding?
2) Are there any alternatives I haven't thought of?
EDIT
Péter Török suggests composing Employee and pushing the type conversion further down the object tree:-
public interface IEmployee
{
public IList<IEmployeeProperty> Properties { get; }
}
public interface IEmployeeProperty { ... }
public class DrinksTeaProperty : IEmployeeProperty
{
int Sugars { get; set; }
bool Milk { get; set; }
}
foreach (IEmployee employee in employees)
{
foreach (IEmployeeProperty property in employee.Propeties)
{
// Handle duplicate properties if you need to.
// Since this is just an example, we'll just
// let the greedy ones have two cups of tea.
DrinksTeaProperty tea = property as DrinksTeaProperty;
if (tea != null)
{
MakeTea(tea.Sugers, tea.Milk);
}
}
}
In this example it's definitely worth pushing these traits out of the Employee type - particularly because some managers might drink tea and some might not - but we still have the same underlying problem of the type conversion.
Is it the case that it's "ok" so long as we do it at the right level? Or are we just moving the problem around?
The holy grail would be a variant on the Visitor pattern where:-
You can add element members without modifying all the visitors
Visitors should only visit types they're interested in visiting
The visitor can visit the member based on an interface type
Elements might implement multiple interfaces which are visited by different visitors
Doesn't involve casting or reflection
but I appreciate that's probably unrealistic.
I would definitely try to resolve this with composition instead of inheritance, by associating the needed properties/traits to Employee, instead of subclassing it.
I can give an example partly in Java, I think it's close enough to your language (C#) to be useful.
public enum EmployeeProperty {
RECEIVES_BONUS,
DRINKS_TEA,
...
}
public class Employee {
Set<EmployeeProperty> properties;
// methods to add/remove/query properties
...
}
And the modified loop would look like this:
foreach(Employee employee in employees) {
if (employee.getProperties().contains(EmployeeProperty.RECEIVES_BONUS)) {
PayBonus(employee);
}
}
This solution is much more flexible than subclassing:
it can trivially handle any combination of employee properties, while with subclassing you would experience a combinatorial explosion of subclasses as the number of properties grow,
it trivially allows you to change Employee properties runtime, while with subclassing this would require changing the concrete class of your object!
In Java, enums can have properties or (even virtual) methods themselves - I don't know whether this is possible in C#, but in the worst case, if you need more complex properties, you can implement them with a class hierarchy. (Even in this case, you are not back to square one, since you have an extra level of indirection which gives you the flexibility described above.)
Update
You are right that in the most general case (discussed in the last sentence above) the type conversion problem is not resolved, just pushed one level down on the object graph.
In general, I don't know a really satisfying solution to this problem. The typical way to handle it is using polymorphism: pull up the common interface and manipulate the objects via that, thus eliminating the need for downcasts. However, in cases when the objects in question do not have a common interface, what to do? It may help to realize that in these cases the design does not reflect reality well: practically, we created a marker interface solely to enable us to put a bunch of distinct objects into a common collection, but there is no semantical relationship between the objects.
So I believe in these cases the awkwardness of downcasts is a signal that there may be a deeper problem with our design.
You could implement a custom iterator that only iterates over the IRecievesBonus types.
I have a simple question about object oriented design but I have some difficulties figuring out what is the best solution. Say that I have an object with some methods and a fairly large amount of properties, perhaps an Employee object. Properties, like FirstName, Address and so on, which indicates a data structure. Then there could be methods on the Employee object, like IsDueForPromotion(), that is more of OO nature.
Mixing this does not feel right to me, I would like to separate the two but I do not know how to do it in a good way. I have been thinking about putting all property data in a struct and have an internal struct object inside the employee object, private EmployeeStruct employeData ...
I am not sure this is a really good idea however, maybe I should just have all methods and proerties in the same class and go with that. Am I making things to complicated if I separate data from methods?
I would very much appreciate if someone have any ideas about this.
J
Wasn't the idea of OO-design to encapsulate data and the corresponding methods together?
The question here is how the Employee object could possibly know about begin due for promotion. I guess that method belongs somewhere else to a class which has the informations to decicde that. really stupid example Manager m = new Manager(); manager.IsDueForPromotion(employeeobject);
But other methods to access the fields of Employee belong to this class.
The question I raised about IsDueForPromotion depends on you application and if your Employee is a POJO or DTO only or if it can have more "intelligent" methods associated too.
if your data evolves slower than behaviour you may want to give a try to Visitor pattern:
class Employee {
String name;
String surName;
int age;
// blah blah
// ...getters
// ...setters
// other boilerplate
void accept(EmployeeVisitor visitor) {
visitor.visitName(name);
visitor.visitAge(age);
// ...
}
}
interface EmployeeVisitor {
void visitName(String name);
void visitAge(int age);
}
with this design you can add new operations without changing the Employee class.
Check also use the specification pattern.
Object operations (methods) are supposed to use the properties. So I feel its better to leave them together.
If it does not require properties, its a kind of utility method and should be defined else ware, may in some helper class.
Well, OO is a way of grouping data and functionality that belong together in the same location. I don't really see why you would make an exception 'when there is a lot of data'. The only reason I can think of is legibility.
Personally I think you would be making things needlessly complex by coming up with a separate struct to hold your data. I'm also conflicted as to wether this would be good practice. On the one hand, how a class implements it's functionality, or stores it's data is supposed to be hidden from the outside world. On the other hand, if data belongs to a class, it feels unnatural to store it in something like a struct.
It may be interesting to look at the data you have and see if it can be modeled into smaller domain objects. For example, have an Address object that holds a street, housenumber, state, zip, country, etc value. That way, your Employee object will just hold an Address object. The Address object could then be reused for your Company objects etc.
The basic principle of Object Oriented programming is grouping data such as FirstName and Address with the functionality that goes with it, such as IsDueForPromotion(). It doesn't matter how much data the object is holding, it will still hold that data. The only time you want to remove data from an object is if it has nothing to do with that object, like storing the company name in the Employee object when it should be stored in a company object.