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183 lines
No EOL
9.2 KiB
Markdown
---
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layout: blog
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title: "☕ Java Tutorial, Part 3: (Static) Methods"
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summary: In this Java tutorial for beginners, we cover what (static) methods, parameters and return types are.
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tags: [Java Tutorials]
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discuss: https://twitter.com/Ellpeck/status/1182775985885847558
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---
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I've been thinking about how to structure this tutorial a lot, and I decided to teach you all about methods *before* I get into object orientation, so you'll have to wait a little while longer before we get into the real nitty-gritty. To understand this one, you should've already read and understood tutorials 1 and 2. If you haven't, you can get to them by clicking the "Previous Post" button in the navigation bar.
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So, here goes!
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# Methods
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Methods are a way, in programming, to move certain code into a different location where it's more organized and, more importantly, where it can be called multiple times from multiple locations, possibly with different data. You'll see what exactly that means in a minute.
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Let's create a simple method in our main class:
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```java
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public class Main {
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public static void main(String[] args) {
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// I've omitted the code from the previous tutorials for readability
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}
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public static void printInfo() {
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System.out.println("This is some important information!");
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}
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}
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```
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Let's take a look at the `printInfo` method I created. In this tutorial, we'll only be talking about `public` and `static` methods, so you'll just have to take that part for granted for now. Following that, you write `void` and then the name of your method (which can be anything you want), followed by parentheses `()` and then braces `{}`. Similarly to the `if` statement and the `for` loop, the method's content goes between those two curly braces, as I have done in this example with the print statement.
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As you can see, all a method is is pretty much a collection of code. At this point, you might've already noticed that that is exactly what the `main` structure we've previously been writing all of our code into is: `main` is just another method.
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To *call* a method, that is to have the code inside of it be executed, all you have to do is write the following:
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```java
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public class Main {
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public static void main(String[] args) {
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// I've omitted the code from the previous tutorials for readability
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printInfo();
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}
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public static void printInfo() {
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System.out.println("This is some important information!");
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}
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}
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```
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There you go.
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## Variables
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It should be noted at this point that variables which are declared *inside* of a method, like the ones we've been using in the first two tutorials, are known as `local variables`. What this means is that they only exist *inside* of the method they are declared in. Check out this example:
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```java
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// This method declares a variable i that is set to 0
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public static void methodOne() {
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int i = 0;
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}
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// This method declares a *different* variable i that is set to 1
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public static void methodTwo() {
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int i = 1;
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}
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// This method will cause an error if you paste it into your IDE:
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// You cannot declare two variables with the same name in one method.
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public static void erroringMethod() {
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int i = 0;
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int i = 1;
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}
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```
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This same behavior also counts for `if`, `for` and any other curly braces `{}` that you see: They close off any variables which are created inside of them and make them available to only that location.
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# Parameters
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Now you might be wondering what the point of methods is if all they do is execute a predefined list of code. Well... you can actually make a method *accept* a set of data that they can use to do their processing. The data given to a method is called *parameters*, and these parameters are simply variables that you declare between the method's parentheses `()` right after its name.
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Let's take the following example:
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```java
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public static void printInfo(String strg) {
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System.out.println("This is some important information about " + strg);
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}
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```
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I modified the method by adding the parameter `strg` to it, which is of the type `String`. What this means is that now, when calling the method, it expects you to give it a string that it can use to do stuff with (in this case, print it out).
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If you add that parameter to the code we previously wrote, you might notice that your IDE is now displaying an error to you. You can't just do this anymore:
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```java
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public static void main(String[] args) {
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printInfo();
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}
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```
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As we just said, `printInfo` now wants us to give it a string whenever we call it. To give it that string, simply put it between the parentheses `()` of your method call like this:
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```java
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String someString = "Some String";
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printInfo(someString);
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// or, optionally, the shorter form:
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printInfo("Some String");
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```
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Running your code now should cause `This is some important information about Some String` to be displayed in your console.
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In case you're thinking "I've seen that somewhere before", then you would be correct: This is exactly the same thing you do when you try to print something out to the console: You call the `println` method and give it the text you want to print out as the parameter.
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The cool thing is that a method can also accept *multiple* parameters, so multiple bits of data can be passed into it when calling it. Let's look at this example:
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```java
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public class Main {
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public static void main(String[] args) {
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printInfo("Some String", 5);
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}
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public static void printInfo(String strg, int amount) {
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for (int i = 0; i < amount; i = i + 1) {
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System.out.println("This is some important information about " + strg);
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}
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}
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}
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```
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As you can see, the `printInfo` method now takes two parameters, separated by a comma `,`. The code inside of the method should already be familiar to you: It's a simple for loop that prints the same message `amount` times.
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So now, we have something that also demonstrates pretty well the versatility of methods: We can now call `printInfo` with any information that will be printed any amount of times:
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```java
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printInfo("Some String", 5);
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printInfo("Some other String", 10);
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```
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# Returning
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Another thing that methods can do that is really useful is the ability to *return* certain data. What this means is that they can, after their execution finishes, take the data they created or modified and give it back to the caller:
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```java
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public class Main {
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public static void main(String[] args) {
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int tenSquared = square(10);
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System.out.println(tenSquared); // prints 100
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System.out.println(square(5)); // prints 25
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}
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public static int square(int i) {
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return i * i;
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}
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}
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```
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As you can see, I created a method `square` that returns its parameter `i`, but squared. To make a method return a value, two things have to be done:
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- The method's *return type* has to be declared. For methods that don't return anything, the return type is `void`. For methods that return something, just replace `void` with the *type of variable* that it returns.
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- To actually return a specific value after it has been calculated, just type `return`, followed by the value and a semicolon `;`.
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Now, this method can be used as if it were just another number: We can set variables to it and print it out. But instead of it being just another number, it actually executes the code inside it every time.
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## Stopping execution
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A thing that should be noted about returning is that any code that comes after a return statement will *not* be executed. In other words: After returning a value, a method will stop its execution, no matter what comes next.
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```java
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public static int square(int i) {
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return i * i;
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System.out.println("This will never be called");
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}
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```
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In this specific case, that isn't really useful - why write code that can never be executed? But take this other example:
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```java
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public static boolean isIGreaterThanJ(int i, int j) {
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if (i > j) {
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return true;
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}
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System.out.println("i is NOT greater than j!");
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return false;
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}
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```
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In this example, the print statement will not be executed if `i` is greater than `j` despite the fact that it's not wrapped in an `else`, because the method gets returned out of before it can be called.
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## Requirements
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If you create a method that has a return type other than `void` (which, again, means "this method doesn't return anything"), then every possible path that the execution can take inside the method *needs* to return *something*.
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What this means is that you can't have something like this:
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```java
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public static boolean isIGreaterThanJ(int i, int j) {
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if (i > j) {
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return true;
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}
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System.out.println("i is NOT greater than j!");
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}
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```
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Because when `i` is *not* greater than `j`, the print statement will be executed but then, the method doesn't know what value to return, so this code will give out an error before it even tries to execute.
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# Conclusion
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So yea, that's pretty much everything important there is to know about (static) methods. In one of the next tutorials, we'll finally get into actual object orientation and we'll soon be taking a look at non-static methods, which are even more useful than static methods.
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As a little exercise, you might want to create some methods with different return types and different parameters and call them. Have some fun!
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I hope you enjoyed reading, and of course: Happy coding! |