Mocking is an essential part of unit testing, and the Mockito library makes it easy to write clean and intuitive unit tests for your Java code.
Get started with mocking and improve your application tests using our Mockito guide:
Handling concurrency in an application can be a tricky process with many potential pitfalls. A solid grasp of the fundamentals will go a long way to help minimize these issues.
Get started with understanding multi-threaded applications with our Java Concurrency guide:
Spring 5 added support for reactive programming with the Spring WebFlux module, which has been improved upon ever since. Get started with the Reactor project basics and reactive programming in Spring Boot:
Since its introduction in Java 8, the Stream API has become a staple of Java development. The basic operations like iterating, filtering, mapping sequences of elements are deceptively simple to use.
But these can also be overused and fall into some common pitfalls.
To get a better understanding on how Streams work and how to combine them with other language features, check out our guide to Java Streams:
Explore Spring Boot 3 and Spring 6 in-depth through building a full REST API with the framework:
Yes, Spring Security can be complex, from the more advanced functionality within the Core to the deep OAuth support in the framework.
I built the security material as two full courses - Core and OAuth, to get practical with these more complex scenarios. We explore when and how to use each feature and code through it on the backing project.
You can explore the course here:
Spring Data JPA is a great way to handle the complexity of JPA with the powerful simplicity of Spring Boot.
Get started with Spring Data JPA through the guided reference course:
Refactor Java code safely — and automatically — with OpenRewrite.
Refactoring big codebases by hand is slow, risky, and easy to put off. That’s where OpenRewrite comes in. The open-source framework for large-scale, automated code transformations helps teams modernize safely and consistently.
Each month, the creators and maintainers of OpenRewrite at Moderne run live, hands-on training sessions — one for newcomers and one for experienced users. You’ll see how recipes work, how to apply them across projects, and how to modernize code with confidence.
Join the next session, bring your questions, and learn how to automate the kind of work that usually eats your sprint time.
Distributed systems often come with complex challenges such as service-to-service communication, state management, asynchronous messaging, security, and more.
Dapr (Distributed Application Runtime) provides a set of APIs and building blocks to address these challenges, abstracting away infrastructure so we can focus on business logic.
In this tutorial, we'll focus on Dapr's pub/sub API for message brokering. Using its Spring Boot integration, we'll simplify the creation of a loosely coupled, portable, and easily testable pub/sub messaging system:
1. Overview
In this tutorial, we’ll look at the Fibonacci series.
Specifically, we’ll implement three ways to calculate the nth term of the Fibonacci series, the last one being a constant-time solution.
2. Fibonacci Series
The Fibonacci series is a series of numbers in which each term is the sum of the two preceding terms. It’s first two terms are 0 and 1.
For example, the first 11 terms of the series are 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, and 55.
In mathematical terms, the sequence Sn of the Fibonacci numbers is defined by the recurrence relation:
S(n) = S(n-1) + S(n-2), with S(0) = 0 and S(1) = 1Now, let’s look at how to calculate the nth term of the Fibonacci series. The three methods we’ll be focusing on are recursive, iterative, and using Binet’s formula.
2.1. Recursive Method
For our first solution, let’s simply express the recurrence relation directly in Java:
public static int nthFibonacciTerm(int n) {
if (n == 1 || n == 0) {
return n;
}
return nthFibonacciTerm(n-1) + nthFibonacciTerm(n-2);
}As we can see, we check whether n is equal to 0 or 1. If it true, then we return that value. In any other case, we recursively call the function to calculate the (n-1)th term and (n-2)th term and return their sum.
Although the recursive method is simple to implement, we see that this method does a lot of repeated calculations. For instance, in order to calculate the 6th term, we make calls to calculate the 5th and the 4th term. Moreover, the call to calculate the 5th term makes a call to calculate the 4th term again. Because of this fact, the recursive method does a lot of redundant work.
As it turns out, this makes its time complexity exponential; O(Φn) to be exact.
2.2. Iterative Method
In the iterative method, we can avoid the repeated calculations done in the recursive method. Instead, we calculate the terms of the series and store the previous two terms to calculate the next.
Let’s take a look at its implementation:
public static int nthFibonacciTerm(int n) {
if(n == 0 || n == 1) {
return n;
}
int n0 = 0, n1 = 1;
int tempNthTerm;
for (int i = 2; i <= n; i++) {
tempNthTerm = n0 + n1;
n0 = n1;
n1 = tempNthTerm;
}
return n1;
}Firstly, we check whether the term to be calculated is the 0th term or 1st term. If that is the case, we return the initial values. Otherwise, we compute the 2nd term using n0 and n1. Then, we modify the values of n0 and n1 variables to store the 1st term and 2nd term respectively. We keep on iterating until we have calculated the required term.
The iterative method avoids repetitive work by storing the last two Fibonacci terms in variables. The time complexity and space complexity of the iterative method is O(n) and O(1) respectively.
2.3. Binet’s Formula
We have only defined the nth Fibonacci number in terms of the two before it. Now, we will look at Binet’s formula to calculate the nth Fibonacci number in constant time.
The Fibonacci terms maintain a ratio called golden ratio denoted by Φ, the Greek character pronounced ‘phi’.
First, let’s look at how the golden ratio is calculated:
Φ = ( 1 + √5 )/2 = 1.6180339887...Now, let’s look at Binet’s formula:
Sn = Φⁿ–(– Φ⁻ⁿ)/√5Actually, this means that we should be able to get the nth Fibonacci number with just some arithmetic.
Let’s express this in Java:
public static int nthFibonacciTerm(int n) {
double squareRootOf5 = Math.sqrt(5);
double phi = (1 + squareRootOf5)/2;
int nthTerm = (int) ((Math.pow(phi, n) - Math.pow(-phi, -n))/squareRootOf5);
return nthTerm;
}We first calculate the squareRootof5 and phi and store them in variables. Later, we apply Binet’s formula to get the required term.
Since we’re dealing with irrational numbers here, we’ll only get an approximation. Consequently, we’ll need to hold onto more decimal places for higher Fibonacci numbers to account for round-off error.
We see that the above method calculates the nth Fibonacci term in constant time, or O(1).
3. Conclusion
In this brief article, we looked at the Fibonacci series. We looked at a recursive and an iterative solution. Then, we applied Binet’s formula to create a constant-time solution.
