Add final modifier at runtime in Java - java

It might sound a bit strange, but is it possible to add the final modifier at runtime?
I have a variable which is marked as public static int/short. At certain point I want to prevent changing its value, and I want to keep its accessibility as a standard static value (ClassName.field).
public class Main {
private static int a = 0;
public static void addFinalMod(Field f) {
Field modifiersField = null;
try {
modifiersField = Field.class.getDeclaredField("modifiers");
}
catch (NoSuchFieldException e) {
e.printStackTrace();
}
modifiersField.setAccessible(true);
try {
modifiersField.setInt(f, f.getModifiers() & Modifier.FINAL);
}
catch (IllegalAccessException e) {
e.printStackTrace();
}
}
public static void main(String[] args) {
System.out.println(a);
try {
Field f = Main.class.getDeclaredField("a");
addFinalMod(f);
}
catch (NoSuchFieldException e) {
e.printStackTrace();
}
a = 10; //I was expecting error/exception here
System.out.println(a);
}
Output:
0
10

At certain point I want to prevent changing its value
Do that in application logic. Make the variable only accessible through methods. Keep a flag tracking any change to the variable. After you've applied the change or reached the certain point, raise the flag, and throw an exception for any further attempts at changing the variable.
final is a language keyword/feature for writing your source code and preventing re-assignment of a variable in source code. At runtime, it does (almost) nothing.

Use an immutable object:
public class Thing {
private int value;
public Thing(int value) { this.value = value; }
public int getValue() { return this.value; }
}
Then just replace it when it needs modification:
Thing x = Thing(1);
// do some stuff
x = Thing(2);
// more stuff
If you're thinking, "But then they can still modify the value by replacing the object!" well, of course. The only way to prevent that is to lock down some global state (which is actually impossible if it's not a constant), but you're not using global state, right? Global state is a Bad ThingTM.
Global state has a very simple problem: it makes your code much less reusable and more error prone. Error prone is especially true if you're modifying that global state at runtime. "Aw, crap, things are happening in the wrong order." You have no idea how easy that is. Trying to track order of events is the reason mutlithreading is so hard. In terms of reusability, it means that you can't have two independent instances of the thing, which in turn implies you can't really have any two instances of anything that depends on it (at least when it turns out you needed to vary this thing after all).
Even if this isn't a global, then this is some weird state that everyone who has to modify your code (including yourself) is going to have to be aware of and thinking about as they make changes. Does that sound like it's going to make changing things easier or harder? (Hint: the latter.) Don't do this to yourself or your coworkers. Make it simpler. Take a lesson from the Zen of Python: "Simple is better than complex."
So bottom line: if you need an immutable object, use an immutable object. If you need an immutable global that's not a constant, figure out a better way to organize your code.

Related

Getter on nested objects without having NullPointerException [duplicate]

A web service returns a huge XML and I need to access deeply nested fields of it. For example:
return wsObject.getFoo().getBar().getBaz().getInt()
The problem is that getFoo(), getBar(), getBaz() may all return null.
However, if I check for null in all cases, the code becomes very verbose and hard to read. Moreover, I may miss the checks for some of the fields.
if (wsObject.getFoo() == null) return -1;
if (wsObject.getFoo().getBar() == null) return -1;
// maybe also do something with wsObject.getFoo().getBar()
if (wsObject.getFoo().getBar().getBaz() == null) return -1;
return wsObject.getFoo().getBar().getBaz().getInt();
Is it acceptable to write
try {
return wsObject.getFoo().getBar().getBaz().getInt();
} catch (NullPointerException ignored) {
return -1;
}
or would that be considered an antipattern?
Catching NullPointerException is a really problematic thing to do since they can happen almost anywhere. It's very easy to get one from a bug, catch it by accident and continue as if everything is normal, thus hiding a real problem. It's so tricky to deal with so it's best to avoid altogether. (For example, think about auto-unboxing of a null Integer.)
I suggest that you use the Optional class instead. This is often the best approach when you want to work with values that are either present or absent.
Using that you could write your code like this:
public Optional<Integer> m(Ws wsObject) {
return Optional.ofNullable(wsObject.getFoo()) // Here you get Optional.empty() if the Foo is null
.map(f -> f.getBar()) // Here you transform the optional or get empty if the Bar is null
.map(b -> b.getBaz())
.map(b -> b.getInt());
// Add this if you want to return null instead of an empty optional if any is null
// .orElse(null);
// Or this if you want to throw an exception instead
// .orElseThrow(SomeApplicationException::new);
}
Why optional?
Using Optionals instead of null for values that might be absent makes that fact very visible and clear to readers, and the type system will make sure you don't accidentally forget about it.
You also get access to methods for working with such values more conveniently, like map and orElse.
Is absence valid or error?
But also think about if it is a valid result for the intermediate methods to return null or if that is a sign of an error. If it is always an error then it's probably better throw an exception than to return a special value, or for the intermediate methods themselves to throw an exception.
Maybe more optionals?
If on the other hand absent values from the intermediate methods are valid, maybe you can switch to Optionals for them also?
Then you could use them like this:
public Optional<Integer> mo(Ws wsObject) {
return wsObject.getFoo()
.flatMap(f -> f.getBar())
.flatMap(b -> b.getBaz())
.flatMap(b -> b.getInt());
}
Why not optional?
The only reason I can think of for not using Optional is if this is in a really performance critical part of the code, and if garbage collection overhead turns out to be a problem. This is because a few Optional objects are allocated each time the code is executed, and the VM might not be able to optimize those away. In that case your original if-tests might be better.
I suggest considering Objects.requireNonNull(T obj, String message). You might build chains with a detailed message for each exception, like
requireNonNull(requireNonNull(requireNonNull(
wsObject, "wsObject is null")
.getFoo(), "getFoo() is null")
.getBar(), "getBar() is null");
I would suggest you not to use special return-values, like -1. That's not a Java style. Java has designed the mechanism of exceptions to avoid this old-fashioned way which came from the C language.
Throwing NullPointerException is not the best option too. You could provide your own exception (making it checked to guarantee that it will be handled by a user or unchecked to process it in an easier way) or use a specific exception from XML parser you are using.
Assuming the class structure is indeed out of our control, as seems to be the case, I think catching the NPE as suggested in the question is indeed a reasonable solution, unless performance is a major concern. One small improvement might be to wrap the throw/catch logic to avoid clutter:
static <T> T get(Supplier<T> supplier, T defaultValue) {
try {
return supplier.get();
} catch (NullPointerException e) {
return defaultValue;
}
}
Now you can simply do:
return get(() -> wsObject.getFoo().getBar().getBaz().getInt(), -1);
As already pointed out by Tom in the comment,
Following statement disobeys the Law of Demeter,
wsObject.getFoo().getBar().getBaz().getInt()
What you want is int and you can get it from Foo. Law of Demeter says, never talk to the strangers. For your case you can hide the actual implementation under the hood of Foo and Bar.
Now, you can create method in Foo to fetch int from Baz. Ultimately, Foo will have Bar and in Bar we can access Int without exposing Baz directly to Foo. So, null checks are probably divided to different classes and only required attributes will be shared among the classes.
My answer goes almost in the same line as #janki, but I would like to modify the code snippet slightly as below:
if (wsObject.getFoo() != null && wsObject.getFoo().getBar() != null && wsObject.getFoo().getBar().getBaz() != null)
return wsObject.getFoo().getBar().getBaz().getInt();
else
return something or throw exception;
You can add a null check for wsObject as well, if there's any chance of that object being null.
You say that some methods "may return null" but do not say in what circumstances they return null. You say you catch the NullPointerException but you do not say why you catch it. This lack of information suggests you do not have a clear understanding of what exceptions are for and why they are superior to the alternative.
Consider a class method that is meant to perform an action, but the method can not guarantee it will perform the action, because of circumstances beyond its control (which is in fact the case for all methods in Java). We call that method and it returns. The code that calls that method needs to know whether it was successful. How can it know? How can it be structured to cope with the two possibilities, of success or failure?
Using exceptions, we can write methods that have success as a post condition. If the method returns, it was successful. If it throws an exception, it had failed. This is a big win for clarity. We can write code that clearly processes the normal, success case, and move all the error handling code into catch clauses. It often transpires that the details of how or why a method was unsuccessful are not important to the caller, so the same catch clause can be used for handling several types of failure. And it often happens that a method does not need to catch exceptions at all, but can just allow them to propagate to its caller. Exceptions due to program bugs are in that latter class; few methods can react appropriately when there is a bug.
So, those methods that return null.
Does a null value indicate a bug in your code? If it does, you should not be catching the exception at all. And your code should not be trying to second guess itself. Just write what is clear and concise on the assumption that it will work. Is a chain of method calls clear and concise? Then just use them.
Does a null value indicate invalid input to your program? If it does, a NullPointerException is not an appropriate exception to throw, because conventionally it is reserved for indicating bugs. You probably want to throw a custom exception derived from IllegalArgumentException (if you want an unchecked exception) or IOException (if you want a checked exception). Is your program required to provide detailed syntax error messages when there is invalid input? If so, checking each method for a null return value then throwing an appropriate diagnostic exception is the only thing you can do. If your program need not provide detailed diagnostics, chaining the method calls together, catching any NullPointerException and then throwing your custom exception is clearest and most concise.
One of the answers claims that the chained method calls violate the Law of Demeter and thus are bad. That claim is mistaken.
When it comes to program design, there are not really any absolute rules about what is good and what is bad. There are only heuristics: rules that are right much (even almost all) of the time. Part of the skill of programming is knowing when it is OK to break those kinds of rules. So a terse assertion that "this is against rule X" is not really an answer at all. Is this one of the situations where the rule should be broken?
The Law of Demeter is really a rule about API or class interface design. When designing classes, it is useful to have a hierarchy of abstractions. You have low level classes that uses the language primitives to directly perform operations and represent objects in an abstraction that is higher level than the language primitives. You have medium level classes that delegate to the low level classes, and implement operations and representations at a higher level than the low level classes. You have high level classes that delegate to the medium level classes, and implement still higher level operations and abstractions. (I've talked about just three levels of abstraction here, but more are possible). This allows your code to express itself in terms of appropriate abstractions at each level, thereby hiding complexity. The rationale for the Law of Demeter is that if you have a chain of method calls, that suggests you have a high level class reaching in through a medium level class to deal directly with low level details, and therefore that your medium level class has not provided a medium-level abstract operation that the high level class needs. But it seems that is not the situation you have here: you did not design the classes in the chain of method calls, they are the result of some auto-generated XML serialization code (right?), and the chain of calls is not descending through an abstraction hierarchy because the des-serialized XML is all at the same level of the abstraction hierarchy (right?)?
As others have said, respecting the Law of Demeter is definitely part of the solution. Another part, wherever possible, is to change those chained methods so they cannot return null. You can avoid returning null by instead returning an empty String, an empty Collection, or some other dummy object that means or does whatever the caller would do with null.
To improve readability, you may want to use multiple variables, like
Foo theFoo;
Bar theBar;
Baz theBaz;
theFoo = wsObject.getFoo();
if ( theFoo == null ) {
// Exit.
}
theBar = theFoo.getBar();
if ( theBar == null ) {
// Exit.
}
theBaz = theBar.getBaz();
if ( theBaz == null ) {
// Exit.
}
return theBaz.getInt();
Don't catch NullPointerException. You don't know where it is coming from (I know it is not probable in your case but maybe something else threw it) and it is slow.
You want to access the specified field and for this every other field has to be not null. This is a perfect valid reason to check every field. I would probably check it in one if and then create a method for readability. As others pointed out already returning -1 is very oldschool but I don't know if you have a reason for it or not (e.g. talking to another system).
public int callService() {
...
if(isValid(wsObject)){
return wsObject.getFoo().getBar().getBaz().getInt();
}
return -1;
}
public boolean isValid(WsObject wsObject) {
if(wsObject.getFoo() != null &&
wsObject.getFoo().getBar() != null &&
wsObject.getFoo().getBar().getBaz() != null) {
return true;
}
return false;
}
Edit: It is debatable if it's disobeyes the Law Of Demeter since the WsObject is probably only a data structure (check https://stackoverflow.com/a/26021695/1528880).
If you don't want to refactor the code and you can use Java 8, it is possible to use Method references.
A simple demo first (excuse the static inner classes)
public class JavaApplication14
{
static class Baz
{
private final int _int;
public Baz(int value){ _int = value; }
public int getInt(){ return _int; }
}
static class Bar
{
private final Baz _baz;
public Bar(Baz baz){ _baz = baz; }
public Baz getBar(){ return _baz; }
}
static class Foo
{
private final Bar _bar;
public Foo(Bar bar){ _bar = bar; }
public Bar getBar(){ return _bar; }
}
static class WSObject
{
private final Foo _foo;
public WSObject(Foo foo){ _foo = foo; }
public Foo getFoo(){ return _foo; }
}
interface Getter<T, R>
{
R get(T value);
}
static class GetterResult<R>
{
public R result;
public int lastIndex;
}
/**
* #param args the command line arguments
*/
public static void main(String[] args)
{
WSObject wsObject = new WSObject(new Foo(new Bar(new Baz(241))));
WSObject wsObjectNull = new WSObject(new Foo(null));
GetterResult<Integer> intResult
= getterChain(wsObject, WSObject::getFoo, Foo::getBar, Bar::getBar, Baz::getInt);
GetterResult<Integer> intResult2
= getterChain(wsObjectNull, WSObject::getFoo, Foo::getBar, Bar::getBar, Baz::getInt);
System.out.println(intResult.result);
System.out.println(intResult.lastIndex);
System.out.println();
System.out.println(intResult2.result);
System.out.println(intResult2.lastIndex);
// TODO code application logic here
}
public static <R, V1, V2, V3, V4> GetterResult<R>
getterChain(V1 value, Getter<V1, V2> g1, Getter<V2, V3> g2, Getter<V3, V4> g3, Getter<V4, R> g4)
{
GetterResult result = new GetterResult<>();
Object tmp = value;
if (tmp == null)
return result;
tmp = g1.get((V1)tmp);
result.lastIndex++;
if (tmp == null)
return result;
tmp = g2.get((V2)tmp);
result.lastIndex++;
if (tmp == null)
return result;
tmp = g3.get((V3)tmp);
result.lastIndex++;
if (tmp == null)
return result;
tmp = g4.get((V4)tmp);
result.lastIndex++;
result.result = (R)tmp;
return result;
}
}
Output
241
4
null
2
The interface Getter is just a functional interface, you may use any equivalent.
GetterResult class, accessors stripped out for clarity, hold the result of the getter chain, if any, or the index of the last getter called.
The method getterChain is a simple, boilerplate piece of code, that can be generated automatically (or manually when needed).
I structured the code so that the repeating block is self evident.
This is not a perfect solution as you still need to define one overload of getterChain per number of getters.
I would refactor the code instead, but if can't and you find your self using long getter chains often you may consider building a class with the overloads that take from 2 to, say, 10, getters.
I'd like to add an answer which focus on the meaning of the error. Null exception in itself doesn't provide any meaning full error. So I'd advise to avoid dealing with them directly.
There is a thousands cases where your code can go wrong: cannot connect to database, IO Exception, Network error... If you deal with them one by one (like the null check here), it would be too much of a hassle.
In the code:
wsObject.getFoo().getBar().getBaz().getInt();
Even when you know which field is null, you have no idea about what goes wrong. Maybe Bar is null, but is it expected? Or is it a data error? Think about people who read your code
Like in xenteros's answer, I'd propose using custom unchecked exception. For example, in this situation: Foo can be null (valid data), but Bar and Baz should never be null (invalid data)
The code can be re-written:
void myFunction()
{
try
{
if (wsObject.getFoo() == null)
{
throw new FooNotExistException();
}
return wsObject.getFoo().getBar().getBaz().getInt();
}
catch (Exception ex)
{
log.error(ex.Message, ex); // Write log to track whatever exception happening
throw new OperationFailedException("The requested operation failed")
}
}
void Main()
{
try
{
myFunction();
}
catch(FooNotExistException)
{
// Show error: "Your foo does not exist, please check"
}
catch(OperationFailedException)
{
// Show error: "Operation failed, please contact our support"
}
}
NullPointerException is a run-time exception, so generally speaking is not recommended to catch it, but to avoid it.
You will have to catch the exception wherever you want to call the method (or it will propagate up the stack). Nevertheless, if in your case you can keep working with that result with value -1 and you are sure that it won't propagate because you are not using any of the "pieces" that may be null, then it seems right to me to catch it
Edit:
I agree with the later answer from #xenteros, it wil be better to launch your own exception instead returning -1 you can call it InvalidXMLException for instance.
Have been following this post since yesterday.
I have been commenting/voting the comments which says, catching NPE is bad. Here is why I have been doing that.
package com.todelete;
public class Test {
public static void main(String[] args) {
Address address = new Address();
address.setSomeCrap(null);
Person person = new Person();
person.setAddress(address);
long startTime = System.currentTimeMillis();
for (int i = 0; i < 1000000; i++) {
try {
System.out.println(person.getAddress().getSomeCrap().getCrap());
} catch (NullPointerException npe) {
}
}
long endTime = System.currentTimeMillis();
System.out.println((endTime - startTime) / 1000F);
long startTime1 = System.currentTimeMillis();
for (int i = 0; i < 1000000; i++) {
if (person != null) {
Address address1 = person.getAddress();
if (address1 != null) {
SomeCrap someCrap2 = address1.getSomeCrap();
if (someCrap2 != null) {
System.out.println(someCrap2.getCrap());
}
}
}
}
long endTime1 = System.currentTimeMillis();
System.out.println((endTime1 - startTime1) / 1000F);
}
}
public class Person {
private Address address;
public Address getAddress() {
return address;
}
public void setAddress(Address address) {
this.address = address;
}
}
package com.todelete;
public class Address {
private SomeCrap someCrap;
public SomeCrap getSomeCrap() {
return someCrap;
}
public void setSomeCrap(SomeCrap someCrap) {
this.someCrap = someCrap;
}
}
package com.todelete;
public class SomeCrap {
private String crap;
public String getCrap() {
return crap;
}
public void setCrap(String crap) {
this.crap = crap;
}
}
Output
3.216
0.002
I see a clear winner here. Having if checks is way too less expensive than catch an exception. I have seen that Java-8 way of doing. Considering that 70% of the current applications still run on Java-7 I am adding this answer.
Bottom Line For any mission critical applications, handling NPE is costly.
If efficiency is an issue then the 'catch' option should be considered.
If 'catch' cannot be used because it would propagate (as mentioned by 'SCouto') then use local variables to avoid multiple calls to methods getFoo(), getBar() and getBaz().
It's worth considering to create your own Exception. Let's call it MyOperationFailedException. You can throw it instead returning a value. The result will be the same - you'll quit the function, but you won't return hard-coded value -1 which is Java anti-pattern. In Java we use Exceptions.
try {
return wsObject.getFoo().getBar().getBaz().getInt();
} catch (NullPointerException ignored) {
throw new MyOperationFailedException();
}
EDIT:
According to the discussion in comments let me add something to my previous thoughts. In this code there are two possibilities. One is that you accept null and the other one is, that it is an error.
If it's an error and it occurs, You can debug your code using other structures for debugging purposes when breakpoints aren't enough.
If it's acceptable, you don't care about where this null appeared. If you do, you definitely shouldn't chain those requests.
The method you have is lengthy, but very readable. If I were a new developer coming to your code base I could see what you were doing fairly quickly. Most of the other answers (including catching the exception) don't seem to be making things more readable and some are making it less readable in my opinion.
Given that you likely don't have control over the generated source and assuming you truly just need to access a few deeply nested fields here and there then I would recommend wrapping each deeply nested access with a method.
private int getFooBarBazInt() {
if (wsObject.getFoo() == null) return -1;
if (wsObject.getFoo().getBar() == null) return -1;
if (wsObject.getFoo().getBar().getBaz() == null) return -1;
return wsObject.getFoo().getBar().getBaz().getInt();
}
If you find yourself writing a lot of these methods or if you find yourself tempted to make these public static methods then I would create a separate object model, nested how you would like, with only the fields you care about, and convert from the web services object model to your object model.
When you are communicating with a remote web service it is very typical to have a "remote domain" and an "application domain" and switch between the two. The remote domain is often limited by the web protocol (for example, you can't send helper methods back and forth in a pure RESTful service and deeply nested object models are common to avoid multiple API calls) and so not ideal for direct use in your client.
For example:
public static class MyFoo {
private int barBazInt;
public MyFoo(Foo foo) {
this.barBazInt = parseBarBazInt();
}
public int getBarBazInt() {
return barBazInt;
}
private int parseFooBarBazInt(Foo foo) {
if (foo() == null) return -1;
if (foo().getBar() == null) return -1;
if (foo().getBar().getBaz() == null) return -1;
return foo().getBar().getBaz().getInt();
}
}
return wsObject.getFooBarBazInt();
by applying the the Law of Demeter,
class WsObject
{
FooObject foo;
..
Integer getFooBarBazInt()
{
if(foo != null) return foo.getBarBazInt();
else return null;
}
}
class FooObject
{
BarObject bar;
..
Integer getBarBazInt()
{
if(bar != null) return bar.getBazInt();
else return null;
}
}
class BarObject
{
BazObject baz;
..
Integer getBazInt()
{
if(baz != null) return baz.getInt();
else return null;
}
}
class BazObject
{
Integer myInt;
..
Integer getInt()
{
return myInt;
}
}
Giving answer which seems different from all others.
I recommend you to check for NULL in ifs.
Reason :
We should not leave a single chance for our program to be crashed.
NullPointer is generated by system. The behaviour of System
generated exceptions can not be predicted. You should not leave your
program in the hands of System when you already have a way of handling
it by your own. And put the Exception handling mechanism for the extra safety.!!
For making your code easy to read try this for checking the conditions :
if (wsObject.getFoo() == null || wsObject.getFoo().getBar() == null || wsObject.getFoo().getBar().getBaz() == null)
return -1;
else
return wsObject.getFoo().getBar().getBaz().getInt();
EDIT :
Here you need to store these values wsObject.getFoo(),
wsObject.getFoo().getBar(), wsObject.getFoo().getBar().getBaz() in
some variables. I am not doing it because i don't know the return
types of that functions.
Any suggestions will be appreciated..!!
I wrote a class called Snag which lets you define a path to navigate through a tree of objects. Here is an example of its use:
Snag<Car, String> ENGINE_NAME = Snag.createForAndReturn(Car.class, String.class).toGet("engine.name").andReturnNullIfMissing();
Meaning that the instance ENGINE_NAME would effectively call Car?.getEngine()?.getName() on the instance passed to it, and return null if any reference returned null:
final String name = ENGINE_NAME.get(firstCar);
It's not published on Maven but if anyone finds this useful it's here (with no warranty of course!)
It's a bit basic but it seems to do the job. Obviously it's more obsolete with more recent versions of Java and other JVM languages that support safe navigation or Optional.

when return value from a method,assign that value to a variable first and return that variable is better than return value directly?

When we return value from a method,assign the return value to a variable is better than return value directly without assign to any variable?in the following examples:
public int getCustomerId(){
return CustomerService.getCustomerById();
}
and another example:
public int getCustomerId(){
int id = CustomerService.getCustomberById();
return id;
}
which one is more better and why?I saw one of my friend's code,he assign value to variable first and then return that variable to his service method.
Both the approach are right, it's all depend how much code we are writing in our functions or how much readable our code is.
If it is one-two liner code, i would go for the first approach.
As simple as this, readability is fine.
public int getCustomerId(){
return CustomerService.getCustomerById();
}
This makes code little less readable, because just a service call, i need to go through two steps. Extra debugging.
public int getCustomerId(){
int id = CustomerService.getCustomberById();
return id;
}
If i have some complex logic written, maybe at business layer, multiple if-else, try-catch etc, then 2nd approach looks fine.
Just an example, and it makes sense
f(){
Object obj = null;
try{
if(condition){
obj = // call service1
}else {
obj = // call service2
}
}catch(Exception e){
}
return obj;
}
I agree using extra variable (though local to function), then
assignment, might add little overhead to JVM, but code readability
should also be considered while coding. JVM is again smart enough to optimize your code as highlighted above.
Refer these links for something more. Not exactly related but can help.

Static variables in a Java method like in a PHP function behaviour?

knowing that Java is different from PHP, is there a way to reconstruct such a behaviour in Java?:
In PHP I can make something like this:
function a_function() {
static $var = "something";
// do something...
}
After I call this function the first time, all subsequent calls to this function would result in a $var not being reset to "something" at all (its value will be preserved across multiple calls to this function, i.e. if the value of $var will be changed while // do something... is executed, then after a subsequent call, the value of $var would be the last assigned value to $var).
I was wondering if there's a same/like method to do this in Java (declaring a static local variable in a method in Java is not possible, so I guess I can achieve this in some other ways). I thought of making a protected or private static field and use it across multiple calls to a method (here a possible way with a boolean):
public class A {
protected static boolean isSomething = "false";
public void aMethod() {
// do something... e.g. change the isSomething boolean
// if some condition occurs
}
}
What do you think about this approach and what would you do in such a case? Are there other ways to accomplish this?
Thanks for the attention!
Yes, you can do it the way you show in your second example.
Keep in mind that you will have problems with that pattern in multi-thread situations.
It is also not very elegant as a design choice. And depending on your situation its dangerous and error-prone.
Use with care (that is: don't do this unless you know you need it)
Usually you would want something like that to be thread-save and atomic.
You can do it with the volatile keyword if you also take care of synchronization.
public class A {
private static volatile boolean status = true;
public flipStatus() {
synchronized(this) {
status = !status;
}
}
}
Even better is the use of the Atomic classes from java.util.concurrent.atomic
import java.util.concurrent.atomic.*;
public class A {
private static final AtomicBoolean status = new AtomicBoolean(true);
public boolean flipStatusToTrue() { // return true if value has been flipped
return status.compareAndSet(false, true);
}
public boolean flipStatusToFalse() { // return true if value has been flipped
return status.compareAndSet(true, false);
}
}

How to refactor to avoid passing "special values" into a Java method?

I'm sure there must be a standard way to do this, but my attempts to search Stackoverflow have failed.
I have a method like:
public void processSomeWidgetsForUser(int userItemId) {
Iterator<Widgets> iter = allWidgets.values().iterator();
while(iter.hasNext()) {
Widget thisWidget = iter.next();
if (userItemId == -1 || thisWidget.getUsersItemId() == userItemId) {
widget.process();
}
}
}
As you can see -1 is a "special value" meaning process all. Doing this saves repeating the loop code in another method called processSomeWidgetsForAllUsers.
But I dislike special values like this because they are easy to misuse or misunderstand, which is exactly the situation what I'm having to fix now (where someone thought -1 meant something else).
I can only think of two ways to improve this.
have a constant, containing -1 called something like
Widget.ALLWIDGETS which at least is self-documenting, but doesn't
stop code from using a -1 (if someone integrates old code in, for
example)
change the method to take a list of all user ids to
process, which can be empty, but that doesn't seem great
performance-wise (would need to retrieve all user ids first and then loop through
removing. Also what happens if the number of widgets in the list changes between
retreiving the ids and removing
Is there a better way? I'm sure I'm missing something obvious.
The above code has been changed slightly, so may not compile, but you should get the gist.
Although somewhat redundant, a fairly neat self-documenting approach could be to have 3 methods rather than one;
Make your original method private, and make one small change which would be to add your static final int EXECUTE_ALL = -1 and use that in your original method, then add the two new methods;
public void processWidget(int wID) throws IllegalArgumentException {
if(wID == EXECUTE_ALL) throw new IllegalArgumentException();
originalMethod(wID);
}
public void processAllWidgets() {
originalMethod(EXECUTE_ALL);
}
It makes your class a little more cluttered, but as far as the exposed methods go, it is clearer and hopefully foolproof. You could alter it not to throw an exception and just ignore any invalid ids, that just depends on your situation.
This approach of course has the major downside that it changes how the class appears to other classes, breaking everything that currently uses the, now private, originalMethod().
Number 1 would work very nicely. Be sure to document what the variable is though, so future coders (possibly yourself) know what it means.
/**This is the explanation for the below variable*/
public final static int ALL_WIDGETS = -1;
Have an external method like so:
static boolean idRepresentsAll(int id) {
return id == -1;
}
In this case, if you decide to replace it with a different mechanism, you only replace your magic number one place in your code.
At the very least, you would want to do something like this:
public static final int ID_REPRESENTING_ALL = -1;
You can change the method signature to accept a boolean for when you want to process them all.
public void processSomeWidgets(boolean doAll, int userItemId) {
Iterator<Widgets> iter = allWidgets.values().iterator();
while(iter.hasNext()) {
Widget thisWidget = iter.next();
if (doAll || thisWidget.getUsersItemId() == userItemId) {
widget.process();
}
}
}
This makes it more explicit, and easier to read in my opinion as there are no special values.

Problems initializing a final variable in Java

I keep running into slight variations of a problem in Java and it's starting to get to me, and I can't really think of a proper way to get around it.
I have an object property that is final, but dynamic. That is, I want the value to be constant once assigned, but the value can be different each runtime. So I declare the class level variable at the beginning of the class - say private final FILE_NAME;. Then, in the constructor, I assign it a value - say FILE_NAME = buildFileName();
The problem begins when I have code in the buildFileName() method that throws an exception. So I try something like this in the constructor:
try{
FILE_NAME = buildFileName();
}
catch(Exception e){
...
System.exit(1);
}
Now I have an error - "The blank final field FILE_NAME may not have been initialized." This is where I start to get slightly annoyed at Java's strict compiler. I know that this won't be a problem because if it gets to the catch the program will exit... But the compiler doesn't know that and so doesn't allow this code. If I try to add a dummy assignment to the catch, I get - "The final field FILE_NAME may already have been assigned." I clearly can't assign a default value before the try-catch because I can only assign to it once.
Any ideas...?
How about
String tempName = null;
try{
tempName = buildFileName();
}
catch(Exception e){
...
System.exit(1);
}
FILE_NAME = tempName;
Either
try {
FILE_NAME = buildFileName();
} catch (Exception e){
...
System.exit(1);
throw new Error();
}
Or some prefer:
private static final String FILE_NAME = fileName();
private static String fileName() {
try {
return buildFileName();
} catch (Exception e){
...
System.exit(1);
throw new Error();
}
}
But calling System.exit in a static initialiser is probably a bad idea. It's going to mess your unit tests up.
On second thought, I think I just came up with a solution! - use an intermediate variable.
String fileName = null;
try{
fileName = buildFileName();
}
catch(Exception e){
...
System.exit(1);
}
FILE_NAME = fileName;
Don't know why it took me so long to think of this...
I would personally just throw an Error -- if your error flow is properly designed, the System.exit() should be redundant. Your program presumably doesn't plough on into the wilderness if an Error is thrown...?
Along the same lines as the OP's issue, I had to be able to find a way to assign values to final fields to be read in from a .properties file on the filesystem, so the values couldn't be known by my app until that happened. Using a generalized method call to assign the value after reading the content of the .properties file into a Properties object on app startup was a Hail Mary pass that thankfully worked out. It also limits the no. of times the file has to be read to once per the app's getting loaded into the memory simply by the code checking to see if the Properties object is or is not currently null. But of course, once assigned, the final field's value cannot be altered except by altering its "final" status via manuipulating the field's modifying definition at runtime (as discussed in some other places here on SO, such as https://stackoverflow.com/a/3301720/1216686 - sneaky, but I love it!). Code example, with typical runtime error checking such as for NPEs omitted for brevity:
import java.util.Properties;
public class MyConstants {
private static Properties props; // declared, not initialized,
// so it can still be set to
// an object reference.
public static String MY_STRING = getProperty("prop1name", "defaultval1");
public static int MY_INT = Integer.parseInt(getProperty("prop2name", "1"));
// more fields...
private static String getProperty(String name, String dflt) {
if ( props == null ) {
readProperties();
}
return props.getProperty(name, dflt);
}
private static void readProperties() {
props = new Properties(); // Use your fave way to read
// props from the file system; a permutation
// of Properties.load(...) worked for me.
}
// Testing...
public static void main(String[] args) {
System.out.println(MY_STRING);
System.out.println(MY_INT);
}
}
This lets you externalize properties to be read into the app and still mark the fields used to hold their values as "final". It also allows you to guarantee a returned value for the final field value since getProperty() in the Properties class allows the method's calling code to pass in a default value to use in case the property's key-value pair wasn't found in the external .properties file.

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