I am writing a java (processing) library for unexperienced students, and am looking for the best architecture for implementing it.
Initialization of an object should be as close as possible to this:
myObject = new General("type1");
Such that myObject will become an instance of Type1 which extends General:
class General {
public General() {}
}
class Type1 extends General {
public Type1() {}
}
class Type2 extends General {
public Type1() {}
}
As far as I know, this isn't possible (choosing between extended classes during initialization), but I'm looking for the closest solution possible.
So far, my best solution is to make a static initializer inside General:
class General {
...
static General init (String type) {
General temp;
if (type.equals("type1") {
temp = new Type1();
}
...
return temp;
}
and the initialization is:
General myObject;
myObject = General.init("type1");
This is far from ideal...
thanks.
you can make a factory class that manages initialization.
instead of doing it inside the parent.
// Empty vocabulary of actual object
public interface IPerson
{
string GetName();
}
public class Villager : IPerson
{
public string GetName()
{
return "Village Person";
}
}
public class CityPerson : IPerson
{
public string GetName()
{
return "City Person";
}
}
public enum PersonType
{
Rural,
Urban
}
/// <summary>
/// Implementation of Factory - Used to create objects.
/// </summary>
public class Factory
{
public IPerson GetPerson(PersonType type)
{
switch (type)
{
case PersonType.Rural:
return new Villager();
case PersonType.Urban:
return new CityPerson();
default:
throw new NotSupportedException();
}
}
}
The State design pattern can be a solution here. Rather than the constructor argument changing the type of the object (which isn't possible) it can set a field of the object, to make it behave as if its type is different.
package stackoverflow.questions;
public class Main {
private interface MyInterface {
String foo();
int bar();
}
private static class Type1 implements MyInterface {
#Override public String foo() { return "lorem ipsum "; }
#Override public int bar() { return 6; }
}
private static class Type2 implements MyInterface {
#Override public String foo() { return "dolor sit amet"; }
#Override public int bar() { return 7; }
}
public static class General {
private final MyInterface type;
public General(String type) {
try {
this.type = (MyInterface) Class
.forName("stackoverflow.questions.Main$" + type)
.getDeclaredConstructor().newInstance();
} catch (Exception e) {
throw new IllegalArgumentException("Invalid type: " + type);
}
}
public String method1() { return type.foo(); }
public int method2() { return type.bar(); }
}
public static void main(String... args) {
General one = new General("Type1");
General two = new General("Type2");
System.out.println(one.method1() + two.method1());
System.out.println(one.method2() * two.method2());
}
}
I am trying to re-build an OOP approach to mobile verification at the developers discretion. The concept I come up with is to allow for interfaces to manipulate the class. If the class implements the interface, then the verify method will be executed.
The problem I am facing, because I am only used to programming in less strongly-typed languages (PHP) is how to get a protected variable from a class extending the current class.
_areaCodes.stream().forEach(o -> {
try {
int prefix = Integer.parseInt(this._mobileNumber.charAt(0), this._mobileNumber.charAt(1));
} catch (Exception e) {}
});
This line of code is now giving me an error
_mobileNumber cannot be resolved or is not a field
Here is my full code and here is an example I wrote of the same concept in PHP which I am trying to implement in Java.
import java.util.ArrayList;
interface Verification
{
public void initVerification();
}
class AreaCode
{
private int _code;
private String _country;
public AreaCode(int code, String country)
{
this._code = code;
this._country = country;
}
public int getAreaCode() { return this._code; }
public String getAreaCountry() { return this._country; }
}
class VerificationHandler
{
private ArrayList<AreaCode> _areaCodes = new ArrayList<AreaCode>() {{
this.add(new AreaCode(44, "UNITED KINGDOM"));
this.add(new AreaCode(91, "INDIA"));
}};
public void initVerification()
{
if(this instanceof Verification) {
this.verify();
}
}
protected void verify()
{
_areaCodes.stream().forEach(o -> {
try {
int prefix = Integer.parseInt(this._mobileNumber.charAt(0), this._mobileNumber.charAt(1));
} catch (Exception e) {}
});
}
}
class Main extends VerificationHandler implements Verification {
protected String _mobileNumber = "+447435217761";
}
public class Hack1337 { public static void main(String[] args) { new Main(); } }
How can I retrieve a variable in a class extending another, ie:
class A { public String getB() { return this.b; } }
class B extends A { protected String b = 'A should get this'; }
B b = new B().getB();
Only instances of class B, or sub-classes of B can access the b instance variable directly (unless you cast A to B within the body of the A class, which is bad practice).
You can give class A read-only access to that value by overriding getB():
class B extends A
{
protected String b = 'A should get this';
#Override
public String getB() {
return this.b;
}
}
and you may also want to make the getB() method abstract in class A (which means making class A abstract):
abstract class A
{
public abstract String getB();
}
This would only make sense if different sub-classes of A are expected to return different things in getB(). Otherwise, you may as well move the b variable to the base class A.
i'm trying to write anonymous inner class
interface Face{
void seeThis(String what);
}
class Eyes {
public void show(Face f){}
}
public class Seen {
public void test() {
Eyes e = new Eyes();
e.show(new Face() {
#Override
public void seeThis(String what){
System.out.print(what);
}
});
public static void main(String[] args) {
Seen s = new Seen();
s.test();
}
}
How to call seeThis() and how to pass parameter to it?
Method seeThis() belongs to Face class, which instance is anonymous and thus cannot be reached without storing reference to it. If you want to store a reference, you can do this in the following way:
public class Seen {
public Face face;
....
this.face = new Face() { ... };
e.show(this.face);
And then,
Seen s = new Seen();
s.face.seeThis();
Now, regarding passing the parameter. You have two options - declare parameter outside of anonymous class and make it final in order to be reachable by this anonymous class, or replace anonymous class with normal one and pass the parameter to its constructor:
Approach one:
final int parameter = 5;
...(new Face() {
#Override
public void seeThis() {
System.out.println(parameter);
}
});
Approach two:
public class MyFace implements Face() {
private final int parameter;
public MyFace(int parameter) {
this.parameter = parameter;
}
#Override
public void seeThis() {
System.out.println(parameter);
}
}
Then,
...
e.show(new MyFace(10));
I have an object hierarchy that increases in complexity as the inheritance tree deepens. None of these are abstract, hence, all of their instances serve a, more or less sophisticated, purpose.
As the number of parameters is quite high, I would want to use the Builder Pattern to set properties rather than code several constructors. As I need to cater to all permutations, leaf classes in my inheritance tree would have telescoping constructors.
I have browsed for an answer here when I hit some problems during my design. First of, let me give you a simple, shallow example to illustrate the problem.
public class Rabbit
{
public String sex;
public String name;
public Rabbit(Builder builder)
{
sex = builder.sex;
name = builder.name;
}
public static class Builder
{
protected String sex;
protected String name;
public Builder() { }
public Builder sex(String sex)
{
this.sex = sex;
return this;
}
public Builder name(String name)
{
this.name = name;
return this;
}
public Rabbit build()
{
return new Rabbit(this);
}
}
}
public class Lop extends Rabbit
{
public float earLength;
public String furColour;
public Lop(LopBuilder builder)
{
super(builder);
this.earLength = builder.earLength;
this.furColour = builder.furColour;
}
public static class LopBuilder extends Rabbit.Builder
{
protected float earLength;
protected String furColour;
public LopBuilder() { }
public Builder earLength(float length)
{
this.earLength = length;
return this;
}
public Builder furColour(String colour)
{
this.furColour = colour;
return this;
}
public Lop build()
{
return new Lop(this);
}
}
}
Now that we have some code to go on, imaging I want to build a Lop:
Lop lop = new Lop.LopBuilder().furColour("Gray").name("Rabbit").earLength(4.6f);
This call will not compile as the last chained call cannot be resolved, Builder not defining the method earLength. So this way requires that all calls be chained in a specific order which is very impractical, especially with a deep hierarchy tree.
Now, during my search for an answer, I came across Subclassing a Java Builder class which suggests using the Curiously Recursive Generic Pattern. However, as my hierarchy does not contain an abstract class, this solution will not work for me. But the approach relies on abstraction and polymorphism to function which is why I don't believe I can adapt it to my needs.
An approach I have currently settled with is to override all methods of the superclass Builder in the hierarchy and simply do the following:
public ConcreteBuilder someOverridenMethod(Object someParameter)
{
super(someParameter);
return this;
}
With this approach I can assure I am being returned an instance I can issue chain calls on. While this is not as worse as the Telescoping Anti-pattern, it is a close second and I consider it a bit "hacky".
Is there another solution to my problem that I am not aware of? Preferably a solution consistent with the design pattern. Thank you!
This is certainly possible with the recursive bound, but the subtype builders need to also be generic, and you need a few interim abstract classes. It's a little bit cumbersome, but it's still easier than the non-generic version.
/**
* Extend this for Mammal subtype builders.
*/
abstract class GenericMammalBuilder<B extends GenericMammalBuilder<B>> {
String sex;
String name;
B sex(String sex) {
this.sex = sex;
return self();
}
B name(String name) {
this.name = name;
return self();
}
abstract Mammal build();
#SuppressWarnings("unchecked")
final B self() {
return (B) this;
}
}
/**
* Use this to actually build new Mammal instances.
*/
final class MammalBuilder extends GenericMammalBuilder<MammalBuilder> {
#Override
Mammal build() {
return new Mammal(this);
}
}
/**
* Extend this for Rabbit subtype builders, e.g. LopBuilder.
*/
abstract class GenericRabbitBuilder<B extends GenericRabbitBuilder<B>>
extends GenericMammalBuilder<B> {
Color furColor;
B furColor(Color furColor) {
this.furColor = furColor;
return self();
}
#Override
abstract Rabbit build();
}
/**
* Use this to actually build new Rabbit instances.
*/
final class RabbitBuilder extends GenericRabbitBuilder<RabbitBuilder> {
#Override
Rabbit build() {
return new Rabbit(this);
}
}
There's a way to avoid having the "concrete" leaf classes, where if we had this:
class MammalBuilder<B extends MammalBuilder<B>> {
...
}
class RabbitBuilder<B extends RabbitBuilder<B>>
extends MammalBuilder<B> {
...
}
Then you need to create new instances with a diamond, and use wildcards in the reference type:
static RabbitBuilder<?> builder() {
return new RabbitBuilder<>();
}
That works because the bound on the type variable ensures that all the methods of e.g. RabbitBuilder have a return type with RabbitBuilder, even when the type argument is just a wildcard.
I'm not much of a fan of that, though, because you need to use wildcards everywhere, and you can only create a new instance using the diamond or a raw type. I suppose you end up with a little awkwardness either way.
And by the way, about this:
#SuppressWarnings("unchecked")
final B self() {
return (B) this;
}
There's a way to avoid that unchecked cast, which is to make the method abstract:
abstract B self();
And then override it in the leaf subclass:
#Override
RabbitBuilder self() { return this; }
The issue with doing it that way is that although it's more type-safe, the subclass can return something other than this. Basically, either way, the subclass has the opportunity to do something wrong, so I don't really see much of a reason to prefer one of those approaches over the other.
Confronted with the same issue, I used the solution proposed by emcmanus at: https://community.oracle.com/blogs/emcmanus/2010/10/24/using-builder-pattern-subclasses
I'm just recopying his/her preferred solution here. Let say we have two classes, Shape and Rectangle. Rectangle inherits from Shape.
public class Shape {
private final double opacity;
public double getOpacity() {
return opacity;
}
protected static abstract class Init<T extends Init<T>> {
private double opacity;
protected abstract T self();
public T opacity(double opacity) {
this.opacity = opacity;
return self();
}
public Shape build() {
return new Shape(this);
}
}
public static class Builder extends Init<Builder> {
#Override
protected Builder self() {
return this;
}
}
protected Shape(Init<?> init) {
this.opacity = init.opacity;
}
}
There is the Init inner class, which is abstract, and the Builder inner class, that is an actual implementation. Will be useful when implementing the Rectangle:
public class Rectangle extends Shape {
private final double height;
public double getHeight() {
return height;
}
protected static abstract class Init<T extends Init<T>> extends Shape.Init<T> {
private double height;
public T height(double height) {
this.height = height;
return self();
}
public Rectangle build() {
return new Rectangle(this);
}
}
public static class Builder extends Init<Builder> {
#Override
protected Builder self() {
return this;
}
}
protected Rectangle(Init<?> init) {
super(init);
this.height = init.height;
}
}
To instantiate the Rectangle:
new Rectangle.Builder().opacity(1.0D).height(1.0D).build();
Again, an abstract Init class, inheriting from Shape.Init, and a Build that is the actual implementation. Each Builder class implement the self method, which is responsible to return a correctly cast version of itself.
Shape.Init <-- Shape.Builder
^
|
|
Rectangle.Init <-- Rectangle.Builder
If anyone still bumped into the same problem, I suggest the following solution, that conforms "Prefer composition over inheritance" design pattern.
Parent class
The main element of it is the interface that parent class Builder must implement:
public interface RabbitBuilder<T> {
public T sex(String sex);
public T name(String name);
}
Here is the changed parent class with the change:
public class Rabbit {
public String sex;
public String name;
public Rabbit(Builder builder) {
sex = builder.sex;
name = builder.name;
}
public static class Builder implements RabbitBuilder<Builder> {
protected String sex;
protected String name;
public Builder() {}
public Rabbit build() {
return new Rabbit(this);
}
#Override
public Builder sex(String sex) {
this.sex = sex;
return this;
}
#Override
public Builder name(String name) {
this.name = name;
return this;
}
}
}
The child class
The child class Builder must implement the same interface (with different generic type):
public static class LopBuilder implements RabbitBuilder<LopBuilder>
Inside the child class Builder the field referencing parentBuilder:
private Rabbit.Builder baseBuilder;
this ensures that parent Builder methods are called in the child, however, their implementation is different:
#Override
public LopBuilder sex(String sex) {
baseBuilder.sex(sex);
return this;
}
#Override
public LopBuilder name(String name) {
baseBuilder.name(name);
return this;
}
public Rabbit build() {
return new Lop(this);
}
The constructor of Builder:
public LopBuilder() {
baseBuilder = new Rabbit.Builder();
}
The constructor of builded child class:
public Lop(LopBuilder builder) {
super(builder.baseBuilder);
}
I have adopted the following guidelines when creating object hierarchies with builders:
Make the constructor of the class at least protected and use it as copy constructor, thus pass it an instance of the class itself.
Make the fields non-final private and use getters to access them.
Add package private setters for the builders, which is also nice for object serialization frameworks.
Make a generic builder for each class that will have a subclass builder. This builder will already contain the setter methods for the current class, but we create also a second non generic builder for the class that contains the constructor and build method.
The builders will not have any fields. Instead the generic builder that is on top of the hierarchy will contain a generic field for the concrete object to be build.
The Rabbit will look like this:
public class Rabbit {
// private non-final fields
private String sex;
private String name;
// copy constructor
Rabbit(Rabbit rabbit) {
sex = rabbit.sex;
name = rabbit.name;
}
// no-arg constructor for serialization and builder
Rabbit() {}
// getter methods
public final String getSex() {
return sex;
}
public final String getName() {
return name;
}
// package private setter methods, good for serialization frameworks
final void setSex(String sex) {
this.sex = sex;
}
final void setName(String name) {
this.name = name;
}
// create a generic builder for builders that have subclass builders
abstract static class RBuilder<R extends Rabbit, B extends RBuilder<R, B>> {
// the builder creates the rabbit
final R rabbit;
// here we pass the concrete subclass that will be constructed
RBuilder(R rabbit) {
this.rabbit = rabbit;
}
public final B sex(String sex) {
rabbit.setSex(sex);
return self();
}
public final B name(String name) {
rabbit.setName(name);
return self();
}
#SuppressWarnings("unchecked")
final B self() {
return (B) this;
}
}
// the builder that creates the rabbits
public static final class Builder extends RBuilder<Rabbit, Builder> {
// creates a new rabbit builder
public Builder() {
super(new Rabbit());
}
// we could provide a public copy constructor to support modifying rabbits
public Builder(Rabbit rabbit) {
super(new Rabbit(rabbit));
}
// create the final rabbit
public Rabbit build() {
// maybe make a validate method call before?
return new Rabbit(rabbit);
}
}
}
and our Lop:
public final class Lop extends Rabbit {
// private non-final fields
private float earLength;
private String furColour;
// copy constructor
private Lop(Lop lop) {
super(lop);
this.earLength = lop.earLength;
this.furColour = lop.furColour;
}
// no-arg constructor for serialization and builder
Lop() {}
// getter methods
public final float getEarLength() {
return earLength;
}
public final String getFurColour() {
return furColour;
}
// package private setter methods, good for serialization frameworks
final void setEarLength(float earLength) {
this.earLength = earLength;
}
final void setFurColour(String furColour) {
this.furColour = furColour;
}
// the builder that creates lops
public static final class Builder extends RBuilder<Lop, Builder> {
public Builder() {
super(new Lop());
}
// we could provide a public copy constructor to support modifying lops
public Builder(Lop lop) {
super(new Lop(lop));
}
public final Builder earLength(float length) {
rabbit.setEarLength(length);
return self(); // this works also here
}
public final Builder furColour(String colour) {
rabbit.setFurColour(colour);
return self();
}
public Lop build() {
return new Lop(rabbit);
}
}
}
Pros:
The builders will exactly mirror the object hierarchy of your classes with a single derivative for each generic builder to build the objects of the current class. No need to create artificial parents.
The class does not have a dependency to its builder. All it needs is an instance of itself to copy the fields, which might be useful for alternative factories.
The classes work very well with serialization frameworks like JSON or Hibernate, since they most often need getters and setters to be present. E.g. Jackson works fine with package private setters.
No need to duplicate fields in the builder. The builder contains the object to be constructed.
No need to override setter methods in the subtype builders since the direct parent class is generic.
Build-in support for copy constructors to allow creating a modified version of an instance, making the objects 'kind of immutable'.
Cons:
Requires at least one additional generic builder.
Fields are not final, thus it's not safe to make them public.
The class itself needs additional setter methods to be called from the builders.
Let's create some rabbits..
#Test
void test() {
// creating a rabbit
Rabbit rabbit = new Rabbit.Builder() //
.sex("M")
.name("Rogger")
.build();
assertEquals("M", rabbit.getSex());
// create a lop
Lop lop = new Lop.Builder() //
.furColour("Gray")
.name("Rabbit")
.earLength(4.6f)
.build();
// modify only the name of the lop
lop = new Lop.Builder(lop) //
.name("Lop")
.build();
assertEquals("Gray", lop.getFurColour());
assertEquals("Lop", lop.getName());
}
This form seems to nearly work. It is not very tidy but it looks like it avoids your issues:
class Rabbit<B extends Rabbit.Builder<B>> {
String name;
public Rabbit(Builder<B> builder) {
this.name = builder.colour;
}
public static class Builder<B extends Rabbit.Builder<B>> {
protected String colour;
public B colour(String colour) {
this.colour = colour;
return (B)this;
}
public Rabbit<B> build () {
return new Rabbit<>(this);
}
}
}
class Lop<B extends Lop.Builder<B>> extends Rabbit<B> {
float earLength;
public Lop(Builder<B> builder) {
super(builder);
this.earLength = builder.earLength;
}
public static class Builder<B extends Lop.Builder<B>> extends Rabbit.Builder<B> {
protected float earLength;
public B earLength(float earLength) {
this.earLength = earLength;
return (B)this;
}
#Override
public Lop<B> build () {
return new Lop<>(this);
}
}
}
public class Test {
public void test() {
Rabbit rabbit = new Rabbit.Builder<>().colour("White").build();
Lop lop1 = new Lop.Builder<>().earLength(1.4F).colour("Brown").build();
Lop lop2 = new Lop.Builder<>().colour("Brown").earLength(1.4F).build();
//Lop.Builder<Lop, Lop.Builder> builder = new Lop.Builder<>();
}
public static void main(String args[]) {
try {
new Test().test();
} catch (Throwable t) {
t.printStackTrace(System.err);
}
}
}
Although I have successfully built Rabbit and Lop (in both forms) I cannot at this stage work out how to actually instantiate one of the Builder objects with it's full type.
The essence of this method relies on the cast to (B) in the Builder methods. This allow you to define the type of object and the type of the Builder and retain that within the object while it is constructed.
If anyone could work out the correct syntax for this (which is wrong) I would appreciate it.
Lop.Builder<Lop.Builder> builder = new Lop.Builder<>();
I did some experimenting and I found this to work quite nicely for me.
Note that I prefer to create the actual instance at the start and the call all the setters on that instance. This is just a preference.
The main differences with the accepted answer is that
I pass a parameter that indicated the return type
There is no need for an Abstract... and a final builder.
I create a 'newBuilder' convenience method.
The code:
public class MySuper {
private int superProperty;
public MySuper() { }
public void setSuperProperty(int superProperty) {
this.superProperty = superProperty;
}
public static SuperBuilder<? extends MySuper, ? extends SuperBuilder> newBuilder() {
return new SuperBuilder<>(new MySuper());
}
public static class SuperBuilder<R extends MySuper, B extends SuperBuilder<R, B>> {
private final R mySuper;
public SuperBuilder(R mySuper) {
this.mySuper = mySuper;
}
public B withSuper(int value) {
mySuper.setSuperProperty(value);
return (B) this;
}
public R build() {
return mySuper;
}
}
}
and then a subclass look like this:
public class MySub extends MySuper {
int subProperty;
public MySub() {
}
public void setSubProperty(int subProperty) {
this.subProperty = subProperty;
}
public static SubBuilder<? extends MySub, ? extends SubBuilder> newBuilder() {
return new SubBuilder(new MySub());
}
public static class SubBuilder<R extends MySub, B extends SubBuilder<R, B>>
extends SuperBuilder<R, B> {
private final R mySub;
public SubBuilder(R mySub) {
super(mySub);
this.mySub = mySub;
}
public B withSub(int value) {
mySub.setSubProperty(value);
return (B) this;
}
}
}
and a subsub class
public class MySubSub extends MySub {
private int subSubProperty;
public MySubSub() {
}
public void setSubSubProperty(int subProperty) {
this.subSubProperty = subProperty;
}
public static SubSubBuilder<? extends MySubSub, ? extends SubSubBuilder> newBuilder() {
return new SubSubBuilder<>(new MySubSub());
}
public static class SubSubBuilder<R extends MySubSub, B extends SubSubBuilder<R, B>>
extends SubBuilder<R, B> {
private final R mySubSub;
public SubSubBuilder(R mySub) {
super(mySub);
this.mySubSub = mySub;
}
public B withSubSub(int value) {
mySubSub.setSubSubProperty(value);
return (B)this;
}
}
}
To verify it fully works I used this test:
MySubSub subSub = MySubSub
.newBuilder()
.withSuper (1)
.withSub (2)
.withSubSub(3)
.withSub (2)
.withSuper (1)
.withSubSub(3)
.withSuper (1)
.withSub (2)
.build();
The following IEEE conference contribution Refined Fluent Builder in Java gives a comprehensive solution to the problem.
It dissects the original question into two sub-problems of inheritance deficiency and quasi invariance and shows how a solution to these two sub-problems opens for inheritance support with code reuse in the classical builder pattern in Java.
As you cannot use generics, now probably the main task is to somehow loosen typing.
I don't know how you process those properties afterwards, but what if you used a HashMap for storing them as key-value pairs? So there will be just one set(key, value) wrapper method in the builder (or builder might not be necessary any more).
The downside would be additional type castings while processing the stored data.
If this case is too loose, then you could keep the existing properties, but have a general set method, which uses reflection and searches for setter method on the basis of 'key' name. Although I think reflection would be an overkill.
I have a primary class as below:
public class classB{
public classC getObject(String getstring){
return new classC(getstring);
}
}
The classC has a contructor:
public class classC{
String string;
public classC(String s){
this.string = s;
}
public methodC(int i){
<using the `string` variable here>
}
}
Now I've a classA which will be using the object created in classB(which is of course, an instance of classC).
public classA{
int a = 0.5;
<Get the object that was created in classB>.methodC(a);
}
This is needed as a variable is created on some actions from the user and stored in classB and this would be further used in classC's methods. Creating a new object will render my variable in classB set to null which isn't intended.
How can I achieve this?
Assume the Brand is a lightweight objects and Run is heavyweight then creating a field with the container for the lightweight objects and hiding it is a good idea.
But the Brand needs access the container it belongs to it could be done with the mapping but we are simply inject the Run to the Brand so it's better implement the Runable or annotate it with JSR330. And accessing the container through the Run in the normal way.
class MainClass {
public static void main(String[] args) {
Run r = new Run();
}
}
class Run {
private Container con1 = new Container();
public Run() {
Brand cola = new Brand("Coca Cola");
Brand pepsi = new Brand("Pepsi");
// Creates the container object "con1" and adds brands to container.
add(cola);
add(pepsi);
}
public void add(Brand b){
con1.addToList(b);
b.setRun(this);
}
public Container getContainer() {
return con1;
}
}
class Brand {
// In this class I have a method which needs to accsess the con1 object
// containing all the brands and I need to access the method
private String name;
private Run run;
public Brand(String name){
this.name = name;
}
public void brandMethod() {
if(getRun().getContainer().methodExample()) { // Error here. Can't find "con1".**
System.out.println("Method example returned true.");
}
}
public Run getRun() {
return run;
}
public void setRun(Run run) {
this.run = run;
}
}
class Container {
// This class is a container-list containing all brands brands
private ArrayList<Object> list = new ArrayList<Object>();
public boolean methodExample(){
return false;
}
public void addToList(Object o) {
list.add(o);
}
}
If you want to get the object created in classB a static field should do the job
public class classB {
public static objectCReference;
public classC getObject(String getstring){
objectCReference = new classC(getstring);
return objectCReference;
}
}
Then you can access the reference in A
public classA {
int a = 0.5;
if (classB.objectCReference != null) { // Make sure to null check
classB.objectCReference.methodC(a);
}
}
Also please follow the language conventions and start your class names with capital letters.