How do I use data classes in Kotlin to store structured data?

By I Wayan Saryada in Kotlin 0 Comment

In Kotlin, data classes are designed to store structured data with minimal boilerplate.

A data class automatically provides useful functions such as:

  • toString()
  • equals()
  • hashCode()
  • copy()
  • component functions for destructuring, like component1(), component2()

Basic example

data class User(
    val id: Int,
    val name: String,
    val email: String
)

You can create and use it like this:

fun main() {
    val user = User(
        id = 1,
        name = "Alice",
        email = "[email protected]"
    )

    println(user)
}

Output:

User(id=1, name=Alice, [email protected])

Accessing properties

println(user.name)
println(user.email)

Because the properties are declared in the primary constructor, they are available directly.

Comparing data objects

Data classes compare values, not object references:

val user1 = User(1, "Alice", "[email protected]")
val user2 = User(1, "Alice", "[email protected]")

println(user1 == user2) // true

Copying with changes

Use copy() to create a modified copy:

val updatedUser = user.copy(email = "[email protected]")

println(updatedUser)

The original object is unchanged.

Destructuring

Data classes support destructuring declarations:

val (id, name, email) = user

println(id)
println(name)
println(email)

Mutable vs immutable properties

Prefer val for immutable data:

data class Product(
    val id: Long,
    val name: String,
    val price: Double
)

Use var only if the property needs to change:

data class MutableUser(
    var name: String,
    var age: Int
)

Example with nested structured data

data class Address(
    val street: String,
    val city: String,
    val postalCode: String
)

data class Customer(
    val id: Int,
    val name: String,
    val address: Address
)

fun main() {
    val customer = Customer(
        id = 100,
        name = "Maria",
        address = Address(
            street = "Main Street",
            city = "Berlin",
            postalCode = "10115"
        )
    )

    println(customer.address.city)
}

Important rules

A Kotlin data class must:

  • Have at least one parameter in the primary constructor
  • Mark primary constructor parameters with val or var
  • Not be abstract, open, sealed, or inner

Example:

data class Book(
    val title: String,
    val author: String,
    val year: Int
)

Use data classes when you mainly need a class to hold data rather than define complex behavior.

How do I use val and var inside Kotlin classes?

By I Wayan Saryada in Kotlin 0 Comment

In Kotlin classes, val and var are used to declare properties.

  • val means read-only after initialization
  • var means mutable / can be reassigned

Basic example

class User {
    val id: Int = 1
    var name: String = "Alice"
}

Usage:

fun main() {
    val user = User()

    println(user.id)      // 1
    println(user.name)    // Alice

    user.name = "Bob"     // OK: name is var

    // user.id = 2        // Error: id is val
}

val inside a class

Use val when the property should not be reassigned after it gets a value.

class Product {
    val sku: String = "ABC-123"
}

You can read it:

val product = Product()
println(product.sku)

But you cannot assign a new value:

// product.sku = "XYZ-999" // Not allowed

var inside a class

Use var when the property can change.

class Counter {
    var count: Int = 0

    fun increment() {
        count++
    }
}

Usage:

fun main() {
    val counter = Counter()

    counter.increment()
    counter.increment()

    println(counter.count) // 2
}

Declaring properties in the constructor

A common Kotlin style is to put properties directly in the class constructor.

class User(
    val id: Int,
    var name: String
)

This creates a class with:

  • a read-only id
  • a mutable name

Usage:

fun main() {
    val user = User(1, "Alice")

    println(user.id)
    println(user.name)

    user.name = "Bob" // OK

    // user.id = 2    // Error
}

Important distinction

If you write this:

val user = User(1, "Alice")

The variable user itself cannot point to another User, because it is a val.

But if the object has var properties, those properties can still change:

val user = User(1, "Alice")

user.name = "Bob" // OK, because name is var

// user = User(2, "Charlie") // Error, because user is val

So:

val user

means the reference cannot be reassigned.

var name

inside the class means the property can be changed.

Rule of thumb

Use val by default, and only use var when the value really needs to change.

class Person(
    val birthYear: Int,
    var displayName: String
)

Here, birthYear probably should not change, but displayName might.

How do I define constructors and initialize class properties in Kotlin?

By I Wayan Saryada in Kotlin 0 Comment

In Kotlin, you usually define constructors and initialize properties directly in the class header using a primary constructor.

1. Primary constructor

The most common style is:

class Person(val name: String, var age: Int)

This defines:

  • a class named Person
  • a read-only property name
  • a mutable property age
  • a constructor that requires both values

Usage:

fun main() {
    val person = Person("Alice", 30)

    println(person.name)
    println(person.age)

    person.age = 31
    println(person.age)
}

Here, val name: String and var age: Int are both constructor parameters and class properties.

2. Constructor parameters without properties

If you omit val or var, the parameter is only available during initialization:

class Person(name: String) {
    val uppercaseName = name.uppercase()
}

Usage:

fun main() {
    val person = Person("Alice")

    println(person.uppercaseName)
}

In this example, name is not a property. You cannot access person.name unless you declare it with val or var.

3. Initialize properties in the class body

You can initialize properties using constructor values:

class Rectangle(val width: Int, val height: Int) {
    val area: Int = width * height
}

Usage:

fun main() {
    val rectangle = Rectangle(5, 4)

    println(rectangle.area)
}

Output:

20

4. Use an init block

If you need validation or setup logic, use an init block:

class User(val username: String, val age: Int) {
    init {
        require(username.isNotBlank()) {
            "Username must not be blank"
        }

        require(age >= 0) {
            "Age must not be negative"
        }
    }
}

The init block runs when an object is created:

fun main() {
    val user = User("kotlinFan", 25)

    println(user.username)
}

5. Default constructor values

You can give constructor parameters default values:

class Product(
    val name: String,
    val price: Double = 0.0,
    val inStock: Boolean = true
)

Usage:

fun main() {
    val freeSample = Product("Sticker")
    val laptop = Product("Laptop", 999.99, false)

    println(freeSample.price)
    println(laptop.inStock)
}

6. Named arguments

Named arguments make constructor calls clearer:

class Book(
    val title: String,
    val author: String,
    val pages: Int
)

fun main() {
    val book = Book(
        title = "Kotlin Basics",
        author = "JetBrains",
        pages = 250
    )

    println(book.title)
}

7. Secondary constructors

Kotlin also supports secondary constructors, but they are less common:

class Car {
    val brand: String
    val year: Int

    constructor(brand: String, year: Int) {
        this.brand = brand
        this.year = year
    }
}

Usage:

fun main() {
    val car = Car("Toyota", 2024)

    println(car.brand)
    println(car.year)
}

However, this is usually better written with a primary constructor:

class Car(val brand: String, val year: Int)

8. Primary and secondary constructors together

If a class has a primary constructor, secondary constructors must delegate to it using this(...):

class Employee(val name: String, val role: String) {
    constructor(name: String) : this(name, "Employee")
}

Usage:

fun main() {
    val employee = Employee("Sam")
    val manager = Employee("Dana", "Manager")

    println(employee.role)
    println(manager.role)
}

9. Late initialization with lateinit

For mutable non-null properties initialized later, use lateinit var:

class Session {
    lateinit var token: String

    fun start(token: String) {
        this.token = token
    }
}

Usage:

fun main() {
    val session = Session()

    session.start("abc123")

    println(session.token)
}

Use lateinit carefully. Accessing it before initialization causes an exception.

10. Custom getters and setters

You can customize property access:

class Temperature(celsius: Double) {
    var celsius: Double = celsius
        set(value) {
            require(value >= -273.15) {
                "Temperature cannot be below absolute zero"
            }
            field = value
        }

    val fahrenheit: Double
        get() = celsius * 9 / 5 + 32
}

Usage:

fun main() {
    val temperature = Temperature(25.0)

    println(temperature.fahrenheit)

    temperature.celsius = 30.0
    println(temperature.fahrenheit)
}

Quick summary

class Person(
    val name: String,
    var age: Int = 0
) {
    init {
        require(name.isNotBlank()) {
            "Name cannot be blank"
        }
    }

    val isAdult: Boolean
        get() = age >= 18
}

This example shows:

  • val name: read-only property initialized from constructor
  • var age: mutable property with a default value
  • init: validation logic
  • isAdult: computed property

In most Kotlin code, prefer a primary constructor with val or var properties unless you specifically need more complex construction logic.

How do I create a class and an object in Kotlin?

By I Wayan Saryada in Kotlin 0 Comment

In Kotlin, you create a class with the class keyword, and you create an object instance by calling the class constructor.

class Person {
    var name: String = "Unknown"
    var age: Int = 0
}

fun main() {
    val person = Person()

    person.name = "Alice"
    person.age = 25

    println("${person.name} is ${person.age} years old")
}

Output:

Alice is 25 years old

Class with a constructor

A more common Kotlin style is to define properties directly in the constructor:

class Person(
    val name: String,
    var age: Int
)

fun main() {
    val person = Person("Alice", 25)

    println("${person.name} is ${person.age} years old")
}

Here:

  • class Person(...) defines a class.
  • val name is a read-only property.
  • var age is a mutable property.
  • Person("Alice", 25) creates an object of the class.

Kotlin object keyword

Kotlin also has the object keyword, which creates a singleton object:

object AppConfig {
    val appName = "My Kotlin App"
    val version = "1.0"
}

fun main() {
    println(AppConfig.appName)
    println(AppConfig.version)
}

Unlike a class, you do not create instances of an object. There is only one instance, and you access it directly by name.

Java Class File Format Versions

By I Wayan Saryada in General 0 Comment

A compiled Java .class file starts with a fixed header (0xCAFEBABE), followed by a pair of numbers: minor_version and major_version. The pair (commonly written as major.minor, e.g., 52.0) identifies which Java platform level the bytecode targets. The JVM uses this to decide whether it can load the class. If the class was compiled for a newer platform than the JVM supports, you’ll get UnsupportedClassVersionError.

Why It Matters:

  • Backward compatibility: Newer JVMs can generally run older class files, but not the other way around.
  • Build reproducibility: Ensuring all modules target the same release avoids subtle runtime issues.
  • Tooling alignment: IDEs, build tools, containers, and CI images must agree on the target level to prevent version skew.

Quick mapping highlights:

  • Java 8 → 52.0
  • Java 11 → 55.0
  • Java 17 (LTS) → 61.0
  • Java 21 (LTS) → 65.0
  • Java 22 → 66.0, 23 → 67.0, 24 → 68.0, 25 → 69.0, 26 → 70.0, 27 → 71.0, 28 → 72.0
JDK Version Class File Format Version
1.0 45.0
1.1 45.3
1.2 46.0
1.3 47.0
1.4 48.0
5 49.0
6 50.0
7 51.0
8 52.0
9 53.0
10 54.0
11 55.0
12 56.0
13 57.0
14 58.0
15 59.0
16 60.0
17 61.0
18 62.0
19 63.0
20 64.0
21 65.0
22 66.0
23 67.0
24 68.0
25 69.0
26 70.0
27 71.0
28 72.0

Note:

  • Early JDK branding used 1.x (e.g., 1.5, 1.6) but these correspond to modern names 5, 6, etc. The table above reflects the modern naming for 5+.
  • There was no official 1.9 brand; Java 9 is simply 9 → 53.0 (already shown above).

How to check a class file’s version

  • Using javap (JDK tool): 
    javap -v path/to/Some.class | find "major"

    Look for a line like major version: NN (e.g., 52 for Java 8). For modern compilers, minor is typically 0.

  • Reading the header directly (forensics style):

    1. Confirm magic bytes: CA FE BA BE.
    2. Next 2 bytes: minor_version.
    3. Next 2 bytes: major_version (e.g., 0x003D = 61 → Java 17).

How to compile for a specific Java level

  • Recommended (single flag): 
    javac --release 21 -d out $(find src -name "*.java")

    --release consistently sets language features, APIs, and the class file version.

  • Legacy approach (not preferred, can mismatch APIs):

    javac -source 1.8 -target 1.8 -bootclasspath "%JAVA8_HOME%\\jre\\lib\\rt.jar" -extdirs ""
  • Maven (maven-compiler-plugin): 
    <plugin>
  <groupId>org.apache.maven.plugins</groupId>
  <artifactId>maven-compiler-plugin</artifactId>
  <version>3.11.0</version>
  <configuration>
      <release>21</release>
  </configuration>
</plugin>
  • Gradle (Groovy DSL): 
    java {
  toolchain {
      languageVersion = JavaLanguageVersion.of(21)
  }
}
// Or explicitly set the target bytecode
tasks.withType(JavaCompile).configureEach {
  options.release = 21
}

Common failure and how to fix

  • Symptom:
    • java.lang.UnsupportedClassVersionError: … has been compiled by a more recent version of the Java Runtime.
  • Causes:
    • Running on an older JRE/JDK than the class file requires.
    • Mixed toolchains or inconsistent --release/target levels in a multi-module build.
  • Fixes:
    • Upgrade the runtime to meet the class file’s major.minor level; or
    • Recompile with an older target using --release <level> that matches your deployment runtime; and
    • Standardize toolchains via Maven/Gradle toolchains and CI images to avoid skew.

Tips and caveats

  • Prefer --release over -source/-target because it also validates against platform APIs for that release.
  • Preview features do not change the class file version; they require --enable-preview at compile and run time, but the mapping still follows the JDK’s version.
  • When publishing libraries, choose the lowest --release that matches your supported runtime matrix to maximize compatibility; consider multi-release JARs if you need newer APIs while keeping a baseline.