As input I have a list of Books. As output I expect a SimilarBookCollection.
A SimilarBookCollection has an author, publishYear and list of Books. The SimilarBookCollection can't be created if the author of the books is different or if the publishYear is different.
The solution so far in PHP:
client.php
----
$arrBook = array(...); // array of books
$objValidator = new SimilarBookCollectionValidator($arrBook);
if ($objValidator->IsValid()) {
$objSimilarBookCollection = new SimilarBookCollection($arrBook);
echo $objSimilarBookCollection->GetAuthor();
}
else {
echo 'Invalid input';
}
SimilarBookCollection.php
---
class SimilarBookCollection() {
public function SimilarBookCollection(array $arrBook) {
$objValidator = new SimilarBookCollectionValidator($arrBook);
if ($objValidator->IsValid()) {
throw new Exception('Invalid books to create collection');
}
$this->author = $arrBook[0]->GetAuthor();
$this->publishYear = $arrBook[0]->GetPublishYear();
$this->books = $arrBook;
}
public function GetAuthor() {
return $this->author;
}
public function GetPublishYear() {
return $this->publishYear;
}
public function GetBooks() {
return $this->books;
}
}
SimilarBookCollectionValidator.php
---
class SimilarBookCollectionValidator() {
public function IsValid() {
$this->ValidateAtLeastOneBook();
$this->ValidateSameAuthor();
$this->ValidateSameYear();
return $this->blnValid;
}
... //actual validation routines
}
The goal is to have a "special" collection with only books that have the same author and publishYear. The idea is to easily access the repeating information like author or year from the object.
How would you name the SimilarBookCollection? The current name is to
generic. Using a name like SameYearAuthorBookCollection looks a bit
long and strange(if more conditions will be added then name will increase)
Would you use a Validator in SimilarBookCollection constructor using a
defensive programming style?
Would you change the design of the code? If yes how?
It all depends ;)
So if I were to aim for a generic adaptable solution I would do the following:
Validator in constructor
On one hand you are validating twice; that is informative in case of a broken precondition/contract (not giving a valid list), but is double the code to run - for what purpose exactly?
If you want to use this in a system depends on its size, how critical it is, product phase, and likely more criterias.
But then it also is controller logic fitted into a model meaning you are spreading your code around.
I would not put it in the constructor.
Name / Design
I would say keep the BookCollection generic as it is, and have any validation strictly in the controller space, instead of bloating the collection which essentially seems to be an array with the extra field of author.
If you want to differentiate between different collection types use either (multiple) inheritance or some sort of additional field "collectionType"; the former if you expect many derivatives or varying functionality to come (also keeps the logic where different nicely separated).
You could also consider your collection as a set on which you perform queries and for convenience's sake you could maintain some sort of meta data like $AuthorCount = N, $publicationDates = array(...) from which you can quickly derive the collection's nature. This approach would also keep your validator-code minimal (or non-existent), as it'd be implicitly in the collection and you could just do the validation in the controller keeping the effective logic behind it clearly visible.
That would also make it more comfortable for you in the future. But the question really is what you want and need it for, and what changes you expect, because you are supposed to fit your design to your requirements and likely changes.
For your very particular problem the constraints as I understand are as follows:
There is only one collection type class in the system at any given
point in time.
The class's items have several attributes, and for a particular, possibly changing subset of these (called identical attributes), the collection only accepts item lists where the chosen attributes of all items are identical.
The class provides getters for all identical attributes
The class must not be usable in any other way than the intended way.
If not for point 1 I would use a generic base class that is either parametrized (ie you tell it upon instantiation which is the set of identical attributes) or uses multiple inheritance (or in php traits) to compose arbitrary combinations with the needed interfaces. Children might rely on the base class but use a predefined subset of the identical attributes.
The parametrized variant might look something as follows:
class BookCollection {
public function __construct($book_list, $identical_fields=array())
{
if (empty($book_list))
{
throw new EmptyCollectionException("Empty book list");
}
$default = $book_list[0];
$this->ia = array();
foreach($identical_fields as $f)
{
$this->ia[$f] = $default->$f;
}
foreach($book_list as $book)
{
foreach($identical_fields as $f)
{
if ($this->ia[$f] !== $book->$f)
{
throw new NotIdenticalFieldException("Field $f is not identical for all");
}
}
}
$this->book_list = $book_list;
}
public function getIdentical($key)
{
$this->ia[$key];
}
}
final class BC_by_Author extends BookCollection{
public function __construct($book_list)
{
parent::__construct($book_list,array('author'));
}
public function getAuthor(){ $this->ia['author']; }
}
or fooling around with abstract and final types (not sure if it's valid like this)
abstract class BookCollection{
public final function __construct($book_list){...}
abstract public function getIdenticalAttributes();
}
final class BC_by_Author {
public function getIdenticalAttributes(){ return array('author'); }
public function getAuthor(){ return $this->ia['author']; }
}
If you rely on getters that do not necessarily match the field names I would go for multiple inheritance/traits.
The naming then would be something like BC_Field1Field2Field3.
Alternatively or additionally, you could also use exactly the same classname but develop your solutions in different namespaces, which would mean you wouldn't have to change your code when you change the namespace, plus you can keep it short in the controllers.
But because there will only ever be one class, I would name it BookCollection and not unnecessarily discuss it any further.
Because of constraint 4, the white box constraint, the given book list must be validated by the class itself, ie in the constructor.
Related
I need to model a Region that has a contains(point) method. That method determines whether a point falls within the boundaries of the Region.
I currently see two implementations of Region:
One where the region is defined by a start and end postalcode.
One where the region is defined by a lat/lng and a radius.
Now, my main problem is how to define the interface for the contains() method.
Possible solution #1:
One easy solution is to let a point also be defined by a Region:
PostalcodeRegion implements Region
region = new PostalcodeRegion(postalStart: 1000, postalEnd: 2000);
point = new PostalcodeRegion(postalStart: 1234, postalEnd: 1234);
region.contains(point); // true
The interface could look like this:
Region
+ contains(Region region):bool
The problem with this is that the contains() method is not specific, and that we abuse Region to let it be something it is not: a Point.
Possible solution #2:
Or, we define a new point class:
PostalcodeRegion implements Region {}
PostalcodePoint implements Point {}
region = new PostalcodeRegion(postalStart: 1000, postalEnd: 2000);
point = new PostalcodePoint(postalCode: 1234);
region.contains(point); // true
Interface:
Region
+ contains(Point point)
There are several problems with this method:
contains() method is still not specific
There is a pointless Point concept. In and of itself it is/does nothing, it is just a marker interface.
Clarification:
Ok, so this is the first time I encounter where I provide my line of thinking, in the form of possible solutions, that is actually counter productive. My apologies.
Let me try and describe the use case: The system this use case is part of is used to handle insurance claims (amongst other things). When someone claims water damages from a leaking pipe f.e., this system handles the entire workflow from entry by the customer, all the way to sending a repair company etc to close the file.
Now, depending on circumstances, there are two ways to find eligible repair companies: by postal code, or by lat lng.
In the first case (postal code), we could find eligible repair companies with the following code:
region = new PostalCodeRegion(customer.postalCode - 500, customer.postalCode + 500)
region.contains(new PostalCodePoint(repairCompany1.postalCode))
region.contains(new PostalCodePoint(repairCompany2.postalCode))
Or, in the second case:
region = new LatLngRegion(customer.latLng, 50) // 50 km radius
region.contains(new LatLngPoint(repairCompany1.latLng))
region.contains(new LatLngPoint(repairCompany2.latLng))
I want to be able to safely pass around Regions and Points, so I can make sure they are Regions and Points. But I don't actually care about their sub-types.
One thing I would like, but I am not sure it is possible, is to not have to do a runtime check on the passed point in the contains() method. Preferably it would be enforced by contract that I get the correct data (fitting to the chosen Region implementation) to work with.
I'm mostly just thinking out loud. I am inclined to go with method #2, and do a runtime type check of the passed point var in contains() implementation.
I would like to hear some thoughts over one or the other, or even better: a new suggestion I haven't thought of.
It shouldn't be really relevant, but the target platform is PHP. So I can't use generics for example.
Given that a Region would have to operate on two abstractions that have nothing in common (Point and Postcode) then a generic interface is one way of crafting a clean strongly typed common interface, but you should question whether that abstraction is useful to model or not. As developers it's easy to get lost in too much abstractions e.g. maybe a Region<T> is just a Container<T>, etc. and all of a sudden the concepts you work with are nowhere to be found in your domain's Ubiquitous Language.
public interface Region<T> {
public boolean contains(T el);
}
class PostalRegion implements Region<Postcode> {
public boolean contains(Postcode el) { ... }
}
class GeographicRegion implements Region<Point> {
public boolean contains(Point el) { ... }
}
The issue with such question is that it's focusing on how to achieve a specific design rather than explaining the real business problem and that makes it difficult to judge whether or not the solution is appropriate or which alternate solution would.
How would the system leverage the common interface if such interface was implemented? Would it make the model easier to work with?
Since we are forced to assume a problem domain, here's a fictional scenario about developing a city zonage system (I know nothing about this domain so the example may be silly).
In the context of city zonage management, we have uniquely
identified regions that are defined by a postal code range and a
geographical area. We need a system that can answer whether or not a
postal code and/or a point is contained within a specific region.
That gives us a little more context to work with and come up with a model that can fulfill the needs.
We can assume that an application service such as RegionService could maybe look like:
class RegionService {
IRegionRepository regionRepository;
...
boolean regionContainsPoint(regionId, lat, lng) {
region = regionRepository.regionOfId(regionId);
return region.contains(new Point(lat, lng));
}
boolean regionContainsPostcode(regionId, postcode) {
region = regionRepository.regionOfId(regionId);
return region.contains(new Postcode(postcode));
}
}
Then, maybe the design would benefit from applying the Interface Segregation Principle (ISP) where you'd have a Locator<T> interface or explicit PostcodeLocator and PointLocator interfaces, implemented either by Region or other services and used by the RegionService or be a service of their own.
If answering the questions requires complex processing, etc. then maybe the logic should be extracted from a PostalRange and an Area. Applying the ISP would help keeping the design more flexible.
It's important to note that a domain model shines on the write side to protect invariants and compute complex rules & state transitions, but querying needs are often better expressed as stateless services that leverages powerful infrastructure components (e.g. database).
EDIT 1:
I had not realized you mentioned "no generics". Still leaving my answer there b/c I think it still gives good modeling insights and warns about not so useful abstractions. Always think about how the client will be using the API as it helps to determine the usefulness of an abstraction.
EDIT 2 (after clarification added):
It seems that the Specification Pattern could be a useful modeling tool here.
Customers could be said to have a repair company eligibility specification...
E.g.
class Customer {
...
repairCompanyEligibilitySpec() {
//The factory method for creating the specification doesn't have to be on the Customer
postalRange = new PostalRange(this.postalCode - 500, this.postCode + 500);
postalCodeWithin500Range = new PostalCodeWithinRange(postalRange);
locationWithin50kmRadius = new LocationWithinRadius(this.location, Distance.ofKm(50));
return postalCodeWithin500Range.and(locationWithin50kmRadius);
}
}
//Usage
repairCompanyEligibilitySpec = customer.repairCompanyEligibilitySpec();
companyEligibleForRepair = repairCompanyEligibilitySpec.isSatisfiedBy(company);
Note that I haven't really understood what you mean by "I want to be able to safely pass around Regions and Points" or at least failed to understand why this requires a common interface so perhaps the proposed design wouldn't be suitable. Making the policy/rule/spec explicit has several advantages and the specification pattern is easily extensible to support features such as describing why a company was not eligible, etc.
e.g.
unsatisfiedSpec = repairCompanyEligibilitySpec.remainderUnsatisfiedBy(company);
reasonUnsatisfied = unsatisfiedSpec.describe();
Ultimately the specification itself doesn't have to implement the operations. You could use the Visitor Pattern in order to add new operations to a set of specifications and/or to segregate operations by logical layer.
I think it's better not to have the implementation of contains in the data object and to create a seperate class for each of the contains implementations. Something like:
class Region
{
...
}
class RegionCheckManager
{
function registerCheckerForPointType(string $pointType, RegionCheckerInterface $checkerImplementation): void
{
...
}
function contains(PointInterface $point, Region $region): bool
{
return $this->getCheckerForPoint($point)->check($region, $point);
}
/** get correct checker for point type **/
private function getCheckerForPoint(PointInterface $point): RegionCheckerInterface
{
...
}
}
interface RegionCheckerInterface
{
public function contains(PointInterface $point): bool;
}
class PostcodeChecker implements RegionCheckerInterface
{
...
}
class PointChecker implements RegionCheckerInterface
{
...
}
Postcode and Point are different conceptual things, they are two different types. Postcode is a scalar value, Point is a geographic item. In fact, your PostalCodeRegion class is a range of scalar value, your LatLngRegion class is a geographic area that has center coordinates and radius. You try to combine two incompatible abstractions. Attempt to make one interface for two absolutely different things is the wrong way which leads to unobvious code and implicit abstractions. You should rethink your abstractions. For example:
What is a postcode? It is a positive number in the simplest case. You can create a Postcode class as a value object and implement simple methods to work with its data.
class Postcode
{
private $number;
public function __constuct(int $number)
{
assert($value <= 0, 'Postcode must be greater than 0');
$this->number = $number;
}
public function getNumber(): int
{
return $this->number;
}
public function greatOrEqual(Postalcode $value): bool
{
return $this->number >= $value->getNumber();
}
public function lessOrEqual(Postalcode $value): bool
{
return $this->number <= $value->getNumber();
}
}
What is a postcode range? It a set of postcodes that contains start postcode and end postcode. So you can also create a value object of a range and implement contains method in it.
class PostcodeRange
{
private $start;
private $end;
public function __construct(Postcode $start, Postcode $end)
{
assert(!$start->lessOrEqual($end));
$this->start = $start;
$this->end = $end;
}
public function contains(Postcode $value): bool
{
return $value->greatOrEqual($this->start) && $value->lessOrEqual($this->end);
}
}
What is a point? It is a geographic item that has some coordinates.
class Point
{
private $lan;
private $lng;
public function __constuct(float $lan, float $lng)
{
$this->lan = $lan;
$this->lng = $lng;
}
public function getLan(): float
{
return $this->lan;
}
public function getLng(): float
{
return $this->lng;
}
}
What is an area? It is a geographic region that has some borders. In your case, those borders defined with a circle that has a center point and some radius.
class Area
{
private $center;
private $radius;
public function __constuct(Point $center, int $radius)
{
$this->center = $center;
$this->radius = $radius;
}
public function contains(Point $point): bool
{
// implementation of method
}
}
So, each company has a postcode and some location defined by its coordinates.
class Company
{
private $postcode;
private $location;
public function __construct(Postcode $postcode, Point $location)
{
$this->postcode = $postcode;
$this->location = $location;
}
public function getPostcode(): Postcode
{
return $this->postcode;
}
public function getLocation(): Point
{
return $this->location;
}
}
So, how you said you have a list of companies and try to find it by postcode range or area. So you can create company collection which can contain all companies and can implement algorithms to search by necessary criteria.
class CompanyCollection
{
private $items;
public function __constuct(array $items)
{
$this->items = $items;
}
public function findByPostcodeRange(PostcodeRange $range): CompanyCollection
{
$items = array_filter($this->items, function(Company $item) use ($range) {
return $range->contains($item->getPostcode());
});
return new static($items);
}
public function findByArea(Area $area): CompanyCollection
{
$items = array_filter($this->items, function(Company $item) use ($area) {
return $area->contains($item->getLocation());
});
return new static($items);
}
}
Example of usage:
$collection = new CompanyCollection([
new Company(new Postcode(1200), new Point(1, 1)),
new Company(new Postcode(1201), new Point(2, 2)),
])
$range = new PostcodeRange(new Postcode(1000), new Postcode(2000));
$area = new Area(new Point(0, 0), 50);
// find only by postcode range
$collection->findByPostcodeRange($range);
// find only by area
$collection->findByArea($area);
// find by postcode range and area
$collection->findByPostcodeRange($range)->findByArea($area);
If I understand the problem correctly, you have some module M, which needs to accept some 3 objects:
implementation of region (postcodes vs radius, let's call them R1 vs R2)
implementation of point (postcode vs lat/lng, P1 vs P2)
some API C to check the point is within the region
and it then applies the 3rd object on the first 2.
(Could be that C is R1 or R2, that's immaterial for the problem definition).
So spelling out the problem: you can apply C on R1+P1 or R2+P2, but not R1+P2 or R2+P1.
I'm afraid the only way to implement it in a type-safe manner is as follows:
C is an interface, apply().
C1 implements C, and has fields of type R1, P1.
C2 implements C, and has fields of type R2, P2.
The caller builds either C1 or C2, passes it to M, and M calls c.apply().
Note how M doesn't even see points, only the checker interface C. That's because there is nothing common between P1 and P2 that anyone other than then C can use.
I'm looking at a well-known problem and therefore there has to be a design pattern or a mix of patterns to solve it.
With the following classes and properties:
CTask
Name
Duration
TaskArea
CTaskArea
Name
CPerson
Name
Abilities
CAbility
Name
CTool
Name
CleaningTime
CConstraint
Name
Constraint
CTask, CPerson, CTool could have constraints e.g. Task A could only be done by persons with ability X, or person A could not do tasks of TaskArea X and so on.
For example, when I create a new CTask, CPerson or CTool I could imagine a constraint config dialog with dropdowns like:
Class | Operator | Class | Property | Value
CPerson | NOT | CTool | Name | Hammer
What design pattern provides the opportunity to dynamically configure constraints for all the classes, without forcing the classes to know additional information or take additional dependencies on each other?
Can I use an interface for objects to express that they accept constraints being applied somehow, or to discover classes which should be configurable with constraints?
Why not to have contraints_for_xxx property at each object having a constraint for particular xxx property?
When some child property is to be added into a collection, it is first run through constraints collection. If any constraint item returns false... exception is thrown, heaven thunders etc.
Constraints can be filled in object's constructor or later via some setupConstraints() call.
CPerson can look like (PHP example):
class Person
{
protected $constraintsAbc = null;
public function setConstraintsAbc(array $constraints)
{
$this->constraintsAbc = $constraints;
}
public function setABC($value)
{
foreach ($this->constraintsAbc as $constraint) {
if (!$constraint->isValid($value)) {
throw new Exception("Constraint {$constraint->getName()} is not happy with value $value");
}
}
$this->abc = $value;
}
}
class PersonSetup
{
public function setupPerson(Person $person)
{
$constrains[] = new PersonAbcConstraint("Value > 5");
$person->setContraintsABC($constrains);
}
}
This is, of course, fictious example. There is a problem here in some code duplication since you have constraintsAbc, setConstraintsAbc and setAbc as different hard-coded fields. But you can abstract this into some virtual "constraintable" field collection if you like.
this is the solution im ok with:
class CCouldHaveConstraints_Base
{
public virtual GetInstance();
public virtual GetClassName();
public virtual GetPropertyListThatCouldHaveConstraints();
}
class CPerson : CCouldHaveConstraints_Base
{
private String m_PersonName;
private String m_PersonAge;
public String PersonName
{
get {return this.m_PersonName;}
set {this.m_PersonName=value;}
}
public String PersonAge
{
get {return this.m_PersonAge;}
set {this.m_PersonAge=value;}
}
public override GetInstance()
{
return new CPerson;
}
public override GetClassName
{
return "Person";
}
public list<string> GetPropertyListThatCouldHaveConstraints()
{
list <string> ConstraintPropsList = new list<string>;
ConstraintPropsList.Add ("PersonName")
}
}
// class contains a list of all objects that could have constraints
class CConstraint_Lst
{
private list<CConstraint> m_ListOfConstraints;
private list<CCouldHaveConstraints_Base> m_ListOfObjectsThatCouldHaveConstraints;
}
// e.g Person | Person.Name | Tim | NOT | Tool | Tool.Name | "Hammer"
class CConstraint
{
private String m_ClassName_A;
private String m_ClassProperty_A;
private String m_ClassProperty_A_Value;
private String m_Operator;
private String m_ClassName_B;
private String m_ClassProperty_B;
private String m_ClassProperty_B_Value;
}
Is that enough code to figure out how im thinking?
Regards,
Tim
You've already made a great conceptual leap to model the constraints as CConstraint objects. The remaining core of the question seems to be "How do I then organize the execution of the constraints, provide them with the right inputs, and collect their outputs? (the outputs are constraint violations, validation errors, or warnings)"
CConstraints obviously can't be evaluated without any input, but you have some choices on how exactly to provide them with input, which we can explore with questions:
Do they get given a 'global state' which they can explore and look for violations in?
Or do they get given a tuple of objects, or object graph, which they return a success or failure result for?
How do they signal constraint violations? Is it by throwing exceptions, returning results, adding them to a collection of violations, or removing violating objects from the world, or triggering repair rules?
Do they provide an "explanation" output that helpfully explains which object or combination of objects is the offending combination, and what rule it violates?
Compilers might be an interesting place to look for inspiration. We know a good compiler processes some complicated input, and produces one or more easy-to-understand error messages allowing the programmer to fix any problem in their program.
Compilers often have to choose some pattern of organizing the work that they're doing like recursion (recursive descent), or a visitor pattern (visit a tree of objects in some arrangement), or stateful pattern matching on a stream of input approach (syntax token recognition by regex matching, or processing a stream of characters), or a chain-of-responsibility (one processor validates and processes input, passes it to the next processor in the chain). Which is actually a whole family of design patterns you can choose from.
Probably one of the most flexible patterns to look at which is useful for your case is the visitor pattern, because you can extend your domain model with additional classes, all of which know how to do a 'visiting' phase, which is basically what 'validation' often entails - someone visits all the objects in a scenario, and inspects their properties, with an easily extensible set of logics (the validation rules) specific to those types of objects, without needing to worry about the mechanics of the visiting procedure (how you traverse the object graph) in each validation rule.
I'm trying to recreate Hearthstone cards as objects in Java, but I'm having trouble doing this in a good and efficient way.
All cards have some common properties like a 'name'. But the problem is that there is about 300 cards to generate, and there is about 30 different abilities that each card may or may not have. Now, do I have to create a basic card class with all the possible abilities set to false and then set all its specific ability parameters to true? This approach seems to get very messy with all the getters and all the extra information that some abilities needs to specify... So my question is if there's there a better way to solve this kind of problem?
I would like to create these card objects so that I'm only 'adding' the specific abilities as fields, but I can't figure out how to do this in a good way.
Thankful for help!
Like Dave said, it's a little difficult to be sure what the best solution to your problem is without more context. However, from what I can gather, your problem is a pretty common one. For common problems, programmers often create efficient solutions that can be used over and over again called design patterns.
Design patterns aren't needed in every case, so be careful not to overuse them, but it seems like they could help you here. Both solutions mentioned by Dave may work, but the problem with making each ability an object is that it requires you to make as many classes as you have abilities. Furthermore, if each ability is a simple variable, it may be overkill to create classes for all of them, particularly since so many classes can become difficult to maintain. Although having these abilities inherit from an interface somewhat helps with maintainability, I think an easier solution can probably be found in the builder pattern.
I won't explain it in detail here, but here's a tutorial that seems reasonably simple. It's basic purpose is to
For your particular example it would look something like this:
public class Card
{
private final String name;
private final Ability soundAbility;
private final Ability animationAbility;
private final Ability customMessageAbility;
private final String technology;
// The constructor is private in this case to restrict instantiation to the builder.
private Card(CardBuilder builder)
{
this.name = builder.name;
this.soundAbility = builder.soundAbility;
this.animationAbility = builder.animationAbility;
this.customMessageAbility = builder.customMessageAbility;
this.technology = builder.technology;
}
// Getters
public String getName()
{
return this.name;
}
public Ability getSoundAbility()
{
return this.soundAbility;
}
// ... More getters and stuff ...
#Override
public String toString()
{
String text = "";
text += this.name + ":";
text += "\n\t" + this.soundAbility;
text += "\n\t" + this.animationAbility;
text += "\n\t" + this.customMessageAbility;
text += "\n\tI have the ability of " + this.technology + "!";
return text;
}
// Nested builder class
public static class CardBuilder
{
private final String name;
private Ability soundAbility;
private Ability animationAbility;
private Ability customMessageAbility;
private String technology;
public CardBuilder(String name)
{
this.name = name;
}
public CardBuilder soundAbility(Ability soundAbility)
{
this.soundAbility = soundAbility;
return this;
}
public CardBuilder animationAbility(Ability animationAbility)
{
this.animationAbility = animationAbility;
return this;
}
public CardBuilder customMessageAbility(Ability customMessageAbility)
{
this.customMessageAbility = customMessageAbility;
return this;
}
public CardBuilder technology(String technology)
{
this.technology = technology;
return this;
}
public Card build()
{
return new Card(this);
}
}
}
Then to run the program:
package builderTest;
class BuilderMain
{
public static void main(String[] args)
{
// Initialize ability objects.
Ability a1 = new SoundAbility();
Ability a2 = new AnimationAbility();
Ability a3 = new CustomMessageAbility();
// Build card
Card card = new Card.CardBuilder("Birthday Card")
.soundAbility(a1)
.animationAbility(a2)
.customMessageAbility(a3)
.technology("Flash")
.build();
System.out.println(card);
}
}
The output would be something along the lines of:
Birthday Card:
I have the ability of sound!
I have the ability of animation!
I have the ability of customizing messages!
I have the ability of Flash!
Keep in mind that I'm working without much context, so what you need might be significantly different.
Although previous answers are very good, there is still another way of achieve this Object creation
with very many optional fields
I found myself in similar situation when dealing with DB complexity and Command design pattern. As you know some table columns values are mandatory - some are not. I'm using this Effective Java book
for such cases.
So, useful here is the Consider a builder when faced with many constructor parameters. By doing so, you avoid
first, the Telescoping constructor pattern (does not scale well) - it works, but it is hard to write client code when there are many parameters, and harder still to read it.
second, the JavaBeans Pattern, which is good, but allows inconsistency and mandates mutability. It may be in an inconsistent state partway through its construction and precludes the possibility of making a class immutable too.
The Builder pattern as used simulates named optional parameters as found in Ada and Python.Like a constructor, a builder can impose invariants on its parameters. But it is critical that they be checked after copying the parameters from the builder to the object, and that they be checked on
the object fields rather than the builder fields.
Cheers.
There are a few questions already on Stackoverflow with similar scenarios, but they don't really address my case.
I am currently doing some refactoring and would like to make the code more robust, flexible and readable by applying patterns. Here is the task:
I have a class, let's say class A, which applies some logic when setting one of its members. This logic is prone to change, so I would like to externalise it. This is where the strategy pattern would be useful.
Also, at some stage I need to filter a list of objects of class A. The filter logic should also be configurable, so the stragey pattern would be handy in this task also.
The question is: How do I combine these requirements into the object-oriented design?
My thoughts so far:
- Use a factory for objects of type A, that has two strategy objects: SettingMemberStrategy and FilterStrategy. If the concrete factory is implemented as singleton, the two strategy objects need to be specified before objects can be created.
- Have two methods on the interface of class A: setMember(value); boolean filtered(). The exact implementation of these methods is determined by the strategies. However, should the object then also carry instances of the strategies?
This approach might work, but it seems a bit overengineered for the task and aesthetically not too pleasing.
Could someone hint at a better solution?
Thanks a million.
Cheers,
Martin
public interface IA {
setMember();
filter();
}
public class A implements IA {
private String theMember = "";
getMember() { return this.theMember; }
setMember(String input, otherParameters[]) {
// set value for member based on strategy and parameters
}
boolean filter();
// returns yes/no based on whether this class should be filtered
// as per filter strategy
}
public class myFactory {
private FilterStrategy myFilterStrategy;
private MemberStrategy mySetMemberStrategy;
IA createObjectOfClassA() {
a = new A(mySetMemberStrategy, myFilterStrategy);
}
setFilterStrategy(FilterStrategy s) { this.myFilterStrategy = s }
setMemberStrategy(MemberStrategy s) { this.mySetMemberStrategy = s }
}
This question depends entirely on how you use these objects. My instinct tells me that in most cases you don't need both a factory and a strategy pattern - you would want to choose one or the other, thus simplifying your code.
If for example, you are creating subclasses of object A in your factory, then eliminate the configurable strategy and bake it into your subclasses.
If, however, you don't create subclasses, just have objects with configurable strategies, then eliminate the factory, and just create the objects with the appropriate strategy in their constructor when you need them.
You could also have a combination of the two if you for example create objects based on an input, and use a factory method to give you a proper instance, i.e.
public A MyFactoryMethod(string typeToCreate){
switch(typeToCreate) {
case "AbeforeB":
return new A(new FilterStrategyA(), new MemberStragegyB());
case "allA":
return new A(new FilterA(), new MemberStrategyA());
// etc. etc.
}
}
I'm trying to follow the Law Of Demeter ( see http://en.wikipedia.org/wiki/Law_of_Demeter , http://misko.hevery.com/code-reviewers-guide/flaw-digging-into-collaborators/ ) as I can see the benefits, however I've become a little stuck when it comes to domain objects.
Domain objects do naturally have a chain and sometimes it's necessary to display the information about the entire chain.
For instance, a shopping basket:
Each order contains a user, delivery info and a list of items
Each order item contains a product and quantity
Each product has a name and price.
Each user contains a name and address
The code which displays the order information has to use all the information about the order, users and products.
Surely it's better and more reusable to get this information through the order object e.g. "order.user.address.city" than for some code higher up to do queries for all the objects I listed above then pass them into the code separately?
Any comments/suggestions/tips are welcome!
One problem with using chained references, such as order.user.address.city, is that higher-order dependencies get "baked into" the structure of code outside the class.
Ideally, in cases when you refactor your class, your "forced changes" should be limited to the methods of the class being refactored. When you have multiple chained references in the client code, refactoring drives you to make changes in other places of your code.
Consider an example: suppose that you'd like to replace User with an OrderPlacingParty, an abstraction encapsulating users, companies, and electronic agents that can place an order. This refactoring immediately presents multiple problems:
The User property will be called something else, and it will have a different type
The new property may not have an address that has city in cases when the order is placed by an electronic agent
The human User associated with the order (suppose that your system needs one for legal reasons) may be related to the order indirectly, - for example, by being a designated go-to person in the definition of the OrderPlacingParty.
A solution to these problems would be to pass the order presentation logic everything that it needs directly, rather than having it "understand" the structure of the objects passed in. This way you would be able to localize the changes to the code being refactored, without spreading the changes to other code that is potentially stable.
interface OrderPresenter {
void present(Order order, User user, Address address);
}
interface Address {
...
}
class PhysicalAddress implements Address {
public String getStreetNumber();
public String getCity();
public String getState();
public String getCountry();
}
class ElectronicAddress implements Address {
public URL getUrl();
}
interface OrderPlacingParty {
Address getAddress();
}
interface Order {
OrderPlacingParty getParty();
}
class User implements OrderPlacingParty {
}
class Company implements OrderPlacingParty {
public User getResponsibleUser();
}
class ElectronicAgent implements OrderPlacingParty {
public User getResponsibleUser();
}
I think, when chaining is used to access some property, it is done in two (or at least two) different situation. One is the case that you have mentioned, for example, in your presentation module, you have an Order object and you would like to just display the owner's/user's address, or details like city. In that case, I think it is of not much problem if you do so. Why? Because you are not performing any business logic on the accessed property, which can (potentially) cause tight coupling.
But, things are different if you use such chaining for the purpose of performing some logic on the accessed property. For example, if you have,
String city = order.user.address.city;
...
order.user.address.city = "New York";
This is problematic. Because, this logic is/should more appropriately be performed in a module closer to the target attribute - city. Like, in a place where the Address object is constructed in the first place, or if not that, at least when the User object is constructed (if say User is the entity and address the value type). But, if it goes farther than that, the farther it goes, the more illogical and problematic it becomes. Because there are too many intermediaries are involved between the source and the target.
Thus, according to the the Law of Demeter, if you are performing some logic on the "city" attribute in a class, say OrderAssmebler, which accesses the city attribute in a chain like order.user.address.city, then you should think of moving this logic to a place/module closer to the target.
You're correct and you'll most likely model your value objects something like this
class Order {
User user;
}
class User {
Address shippingAddress;
Address deliveryAddress;
}
class Address {
String city;
...
}
When you start considering how you will persist this data to a database (e.g. ORM) do you start thinking about performance. Think eager vs lazy loading trade offs.
Generally speaking I adhere to the Law of Demeter since it helps to keep changes in a reduced scope, so that a new requirement or a bug fix doesn't spread all over your system. There are other design guidelines that help in this direction, e.g. the ones listed in this article. Having said that, I consider the Law of Demeter (as well as Design Patterns and other similar stuff) as helpful design guidelines that have their trade-offs and that you can break them if you judge it is ok to do so. For example I generally don't test private methods, mainly because it creates fragile tests. However, in some very particular cases I did test an object private method because I considered it to be very important in my app, knowing that that particular test will be subject to changes if the implementation of the object changed. Of course in those cases you have to be extra careful and leave more documentation for other developers explaining why you are doing that. But, in the end, you have to use your good judgement :).
Now, back to the original question. As far as I understand your problem here is writing the (web?) GUI for an object that is the root of a graph of objects that can be accessed through message chains. For that case I would modularize the GUI in a similar way that you created your model, by assigning a view component for each object of your model. As a result you would have classes like OrderView, AddressView, etc that know how to create the HTML for their respective models. You can then compose those views to create your final layout, either by delegating the responsibility to them (e.g. the OrderView creates the AddressView) or by having a Mediator that takes care of composing them and linking them to your model. As an example of the first approach you could have something like this (I'll use PHP for the example, I don't know which language you are using):
class ShoppingBasket
{
protected $orders;
protected $id;
public function getOrders(){...}
public function getId(){...}
}
class Order
{
protected $user;
public function getUser(){...}
}
class User
{
protected $address;
public function getAddress(){...}
}
and then the views:
class ShoppingBasketView
{
protected $basket;
protected $orderViews;
public function __construct($basket)
{
$this->basket = $basket;
$this->orederViews = array();
foreach ($basket->getOrders() as $order)
{
$this->orederViews[] = new OrderView($order);
}
}
public function render()
{
$contents = $this->renderBasketDetails();
$contents .= $this->renderOrders();
return $contents;
}
protected function renderBasketDetails()
{
//Return the HTML representing the basket details
return '<H1>Shopping basket (id=' . $this->basket->getId() .')</H1>';
}
protected function renderOrders()
{
$contents = '<div id="orders">';
foreach ($this->orderViews as $orderView)
{
$contents .= orderViews->render();
}
$contents .= '</div>';
return $contents;
}
}
class OrderView
{
//The same basic pattern; store your domain model object
//and create the related sub-views
public function render()
{
$contents = $this->renderOrderDetails();
$contents .= $this->renderSubViews();
return $contents;
}
protected function renderOrderDetails()
{
//Return the HTML representing the order details
}
protected function renderOrders()
{
//Return the HTML representing the subviews by
//forwarding the render() message
}
}
and in your view.php you would do something like:
$basket = //Get the basket based on the session credentials
$view = new ShoppingBasketView($basket);
echo $view->render();
This approach is based on a component model, where the views are treated as composable components. In this schema you respect the object's boundaries and each view has a single responsibility.
Edit (Added based on the OP comment)
I'll assume that there is no way of organizing the views in subviews and that you need to render the basket id, order date and user name in a single line. As I said in the comment, for that case I would make sure that the "bad" access is performed in a single, well documented place, leaving the view unaware of this.
class MixedView
{
protected $basketId;
protected $orderDate;
protected $userName;
public function __construct($basketId, $orderDate, $userName)
{
//Set internal state
}
public function render()
{
return '<H2>' . $this->userName . "'s basket (" . $this->basketId . ")<H2> " .
'<p>Last order placed on: ' . $this->orderDate. '</p>';
}
}
class ViewBuilder
{
protected $basket;
public function __construct($basket)
{
$this->basket = $basket;
}
public function getView()
{
$basketId = $this->basket->getID();
$orderDate = $this->basket->getLastOrder()->getDate();
$userName = $this->basket->getUser()->getName();
return new MixedView($basketId, $orderDate, $userName);
}
}
If later on you rearrange your domain model and your ShoppingBasket class can't implement the getUser() message anymore then you will have to change a single point in your application, avoid having that change spread all over your system.
HTH
The Law Of Demeter is about calling methods, not accessing properties/fields. I know technically properties are methods, but logically they're meant to be data. So, your example of order.user.address.city seems fine to me.
This article is interesting further reading: http://haacked.com/archive/2009/07/13/law-of-demeter-dot-counting.aspx