List of the Top 25 Programming Languages for Apache NetBeans in 2025

MATLAB® provides a specialized desktop environment designed for iterative design and analysis, complemented by a programming language that facilitates the straightforward expression of matrix and array computations. It includes the Live Editor, which allows users to craft scripts that seamlessly integrate code, outputs, and formatted text within an interactive notebook format. The toolboxes offered by MATLAB are carefully crafted, rigorously tested, and extensively documented for user convenience. Moreover, MATLAB applications enable users to visualize the interactions between various algorithms and their datasets. Users can enhance their outcomes through iterative processes and can easily create a MATLAB program to replicate or automate their workflows. Additionally, the platform supports scaling analyses across clusters, GPUs, and cloud environments with little adjustment to existing code. There is no necessity to completely change your programming habits or to learn intricate big data techniques. MATLAB allows for the automatic conversion of algorithms into C/C++, HDL, and CUDA code, permitting execution on embedded processors or FPGA/ASIC systems. In addition, when combined with Simulink, MATLAB bolsters the support for Model-Based Design methodologies, proving to be a flexible tool for both engineers and researchers. This versatility underscores MATLAB as a vital asset for addressing a broad spectrum of computational issues, ensuring that users can effectively tackle their specific challenges with confidence.

At the core of extensible programming is the concept of defining functions. Python facilitates this with mandatory and optional parameters, keyword arguments, and the capability to handle arbitrary lists of arguments. Whether you're a novice in programming or possess years of expertise, Python remains approachable and easy to grasp. This language is notably inviting for newcomers while still providing considerable depth for those experienced in other programming languages. The following sections lay a strong groundwork for anyone eager to start their Python programming adventure! The dynamic community actively organizes various conferences and meetups to foster collaborative coding and the exchange of ideas. Furthermore, the comprehensive documentation acts as an invaluable guide, while mailing lists help maintain user connections. The Python Package Index (PyPI) offers a wide selection of third-party modules that enhance the Python experience. With an extensive standard library alongside community-contributed modules, Python presents endless programming possibilities, making it an adaptable choice for developers at every skill level. Additionally, the thriving ecosystem encourages continuous learning and innovation among its users.

The Java™ Programming Language is crafted to be a flexible, concurrent, and strongly typed language that is oriented around objects and follows a class-based framework. It is usually converted into bytecode that complies with the guidelines established in the Java Virtual Machine Specification. Developers typically write their source code in plain text documents, which are designated with a .java extension. These source files are then compiled into .class files using the javac compiler. Unlike code meant for native processors, a .class file contains bytecodes that represent the machine language recognized by the Java Virtual Machine (Java VM). To run an application, the java launcher tool initiates an instance of the Java Virtual Machine, enabling the smooth execution of the compiled bytecode. This entire workflow illustrates the remarkable efficiency and portability that Java provides across a wide range of computing platforms, showcasing its adaptability in diverse programming environments. As a result, developers can rely on Java to create applications that function consistently regardless of the underlying system architecture.

Cascading Style Sheets, or CSS, act as a style sheet language that web developers utilize to arrange the layout of HTML and other elements on a website. Renowned for its widespread use, CSS is one of the most commonly employed languages throughout the Internet. For style sheets to perform optimally, it is essential that your markup is devoid of errors. To easily correct markup issues, employing a utility such as HTML Tidy can prove advantageous. This tool not only tidies up the markup but also improves its clarity and makes it easier to modify. I strongly recommend using Tidy regularly on any markup you handle, as it is particularly effective in refining content produced by authoring tools that may have inconsistent formatting practices. Each style property begins with the property name, followed by a colon, and concludes with the specific value assigned to that property. When you have multiple style properties, it is important to separate each with a semicolon to ensure clear differentiation. In summary, embracing best practices with tools like Tidy can greatly enhance web development efficiency and elevate the quality of your code. Additionally, adopting such practices will ultimately contribute to a more maintainable and scalable web project in the long run.

Kotlin is crafted for user-friendliness, enabling developers to create powerful applications from the outset. Its seamless compatibility with the Java ecosystem allows the utilization of favored JVM frameworks and libraries without difficulty. Developers can easily share their application logic across various platforms, including web, mobile, and desktop, while providing users with a native-like experience. This method not only conserves time but also grants unrestricted access to features specific to each platform. The Kotlin community is robust, with a swiftly growing international network of contributors enhancing the language's capabilities. An extensive range of community libraries supports developers, readily offering assistance through various community channels or direct queries to the Kotlin team. For those developing mobile applications for both iOS and Android, Kotlin Multiplatform Mobile functions as an SDK, effectively combining the benefits of cross-platform development with native app creation. By keeping a single codebase for critical elements such as networking, data storage, and analytics, developers can optimize the creation process for their Android and iOS applications. This streamlining of development not only boosts productivity but also cultivates an environment ripe for innovation in various projects, leading to more efficient workflows and enhanced application quality.

PHP is a versatile, flexible, and highly efficient programming language that caters to a variety of applications, from personal blogs to some of the most trafficked websites in the world. Recently, the PHP development team launched version 8.0.20, which is now accessible to all users. Additionally, while exploring the PHP.net website, you can easily obtain the information you need without searching through a box; instead, you can utilize straightforward PHP.net URLs that guide you directly to specific sections. This straightforward navigation enhances the overall user experience, enabling both developers and casual users to interact with PHP resources more effectively and efficiently. Consequently, the improvements in accessibility and usability reflect the ongoing commitment to enhancing the PHP ecosystem.

Participating in Swift programming is not only fun but also interactive, thanks to its concise and expressive syntax that incorporates modern features valued by developers. Built with an emphasis on safety, Swift allows the development of software that functions at impressive speeds. This programming language stands as a result of innovative research in language design, combined with rich experience in creating applications for Apple platforms. The clarity of its syntax supports the use of named parameters, which greatly improves the readability and maintainability of APIs in Swift. A significant advantage is the elimination of semi-colons, which results in a more fluid and streamlined coding process. Additionally, inferred types lead to a more organized codebase and minimize the chances of errors, while modules do away with the necessity for headers, creating well-structured namespaces. To accommodate a variety of international languages and even emojis, Swift strings are designed to be Unicode-compliant and employ UTF-8 encoding for enhanced performance in diverse applications. Furthermore, writing concurrent code is made easy with user-friendly built-in keywords that clarify asynchronous behavior, thereby improving both the clarity and reliability of the code. This rich array of features establishes Swift as an attractive option for developers looking to build efficient, reliable, and innovative applications that meet modern demands. Its growing community and extensive resources also contribute to making the learning curve easier for newcomers.

Are you intrigued by the widespread popularity of Ruby? Proponents of the language often refer to it as a masterpiece of design, blending artistry with practical applications. Since its public debut in 1995, Ruby has cultivated a dedicated community of developers from diverse backgrounds worldwide. By 2006, it had achieved notable recognition, with user groups forming in major cities and Ruby-centric conferences drawing significant attendance. During that time, the Ruby-Talk mailing list became particularly active, averaging around 200 messages each day. Nonetheless, in more recent years, the number of messages has dwindled as the community has splintered into various smaller factions. Ruby remains a mainstay in the top 10 rankings of programming languages, according to several indices that assess their growth and popularity, including the TIOBE index. A key driver of this enduring success is the increasing visibility of Ruby-based software, especially the influential Ruby on Rails web framework, which has been instrumental in attracting developers to the language. The unique combination of elegance, practicality, and a rich ecosystem of tools continues to draw fresh talent into the ever-evolving Ruby community. This ongoing evolution suggests that Ruby will maintain its relevance in the programming world for years to come.

TypeScript enhances JavaScript with improved syntax, creating a smoother integration with development environments, which helps in identifying errors early on within the editor. The TypeScript code is compiled into JavaScript, making it compatible with a wide range of platforms such as web browsers, Node.js, Deno, and mobile apps. Its understanding of JavaScript allows TypeScript to utilize type inference, providing robust tooling while reducing the need for extensive additional code. According to the 2020 State of JS survey, 78% of participants indicated they use TypeScript, and an impressive 93% of those surveyed plan to keep using it. The most common errors developers face are often type errors, where an unexpected type of value is encountered within a specific context. These mistakes can arise from simple errors such as typos, misinterpretations of a library’s API, incorrect assumptions about how code executes at runtime, or various other oversights. Consequently, adopting TypeScript can greatly improve both code quality and developer productivity by mitigating these frequent issues, ultimately leading to a more efficient coding experience. Additionally, its structured approach encourages best practices and fosters a more disciplined development environment.

Scala elegantly combines object-oriented and functional programming paradigms into a singular high-level language. Its static type system effectively reduces the risk of errors in complex applications, while compatibility with JVM and JavaScript empowers developers to build efficient systems that can tap into vast libraries. The Scala compiler excels at handling static types, which means that in most cases, you won’t have to declare variable types explicitly; the powerful type inference system takes care of it for you. Structural data types are represented through case classes, which automatically generate well-defined methods for toString, equals, and hashCode, in addition to enabling deconstruction through pattern matching techniques. Furthermore, functions in Scala are considered first-class citizens, allowing developers to create anonymous functions with a concise syntax. This combination of features not only enhances productivity but also makes Scala a highly attractive option for developers who wish to enjoy the strengths of both programming approaches. Ultimately, the blend of usability and functionality solidifies Scala's reputation as a modern and versatile programming language.

Perl stands out as a remarkably adaptable and feature-packed programming language that has been advancing for over thirty years. It functions effortlessly across more than 100 platforms, from handheld devices to large-scale mainframes, making it an ideal option for both rapid prototyping and larger development projects. The name "Perl" actually refers to a group of languages, with "Raku," which was once known as "Perl 6," being a unique variant that has its own dedicated development team. Although Raku has emerged, it does not significantly impact the continued progression of the original Perl language. Perl comes with powerful tools tailored for text manipulation, making it especially effective for processing HTML, XML, and a variety of both markup and natural languages. Furthermore, Perl can handle encrypted web data, facilitating e-commerce transactions and underscoring its dependability and broad applicability in contemporary programming tasks. This extensive adaptability enables developers to utilize Perl across numerous applications, ensuring it maintains its significance in the current technology landscape, while its ongoing evolution promises to introduce even more innovative features.

Fortran has been expertly designed for tasks demanding high performance, particularly within scientific and engineering fields. It offers dependable and well-established compilers and libraries, which empower developers to build software that functions with remarkable speed and efficiency. The language's static and strong typing allows the compiler to catch various programming errors early in the process, aiding in the creation of optimized binary code. Even with its concise format, Fortran is surprisingly user-friendly for beginners. Crafting intricate mathematical and computational expressions for large arrays is as effortless as writing equations on a whiteboard. Additionally, Fortran provides support for native parallel programming, featuring a user-friendly array-like syntax that streamlines data sharing across CPUs. This adaptability enables users to run nearly identical code on a single processor, as well as on shared-memory multicore systems or distributed-memory high-performance computing (HPC) and cloud platforms. Consequently, Fortran continues to serve as a formidable resource for individuals seeking to address challenging computational problems. Its enduring relevance in the programming landscape showcases its significant contributions to advancing technology and scientific research.

In Haskell, every expression has a type that is determined at compile time. It is essential for the types in function applications to match correctly; if they do not, the compiler will reject the code. This rigorous type system not only ensures correctness but also acts as a framework for defining program structure. Each function in Haskell operates under the principles of mathematical functions, which makes them fundamentally "pure." Even in the case of side-effecting IO operations, these are merely specifications of actions to be executed, produced by pure functions. Haskell avoids the use of statements or commands; it focuses instead on expressions that cannot change variables—either local or global—and cannot alter states like time or randomness. Although it is not mandatory to specify every type within a Haskell program, types can be inferred through a process known as bidirectional unification. Programmers also have the freedom to explicitly declare types when necessary or to ask the compiler to provide them for clarity, thus improving documentation. This level of flexibility empowers Haskell developers to maintain a balance between type safety and user-friendliness while fostering an environment conducive to robust software development. Overall, Haskell's design encourages clarity and precision in programming practices.

R is a robust programming language and environment specifically designed for statistical analysis and data visualization. Originating from the GNU project, it has a close relationship with the S language, which was developed by John Chambers and his team at Bell Laboratories, now recognized as Lucent Technologies. In essence, R represents an alternative version of S, and although there are some significant differences, a considerable portion of S scripts can run in R without requiring any adjustments. This dynamic language encompasses a wide array of statistical techniques, ranging from both linear and nonlinear modeling to classical hypothesis tests, time-series analysis, classification, and clustering, while also offering extensive extensibility. The S language often finds application in research focused on statistical techniques, and R provides an open-source platform for those interested in this discipline. Additionally, one of R's standout features is its ability to produce high-quality graphics suitable for publication, seamlessly integrating mathematical symbols and formulas when necessary, which significantly enhances its appeal for researchers and analysts. Furthermore, R’s active community continuously contributes to its development, ensuring that users have access to the latest tools and libraries for their analytical needs. Ultimately, R remains a vital resource for anyone aiming to delve into data exploration and visualization.

Rust is notable for its remarkable speed and efficient memory management, functioning without the necessity of a runtime or garbage collector, which makes it ideal for high-performance applications, embedded systems, and smooth integration with various programming languages. Its sophisticated type system and ownership model guarantee both memory and thread safety, enabling developers to identify a wide range of bugs during the compilation phase. The language is bolstered by comprehensive documentation and a user-friendly compiler that provides detailed error messages, along with a suite of top-notch development tools—including an integrated package manager, build system, smart multi-editor support with auto-completion and type checking, as well as an auto-formatter. Thanks to Rust's rich ecosystem, developing a command-line interface tool is straightforward, equipping developers to confidently manage and distribute their applications. Moreover, Rust can significantly enhance JavaScript projects, streamlining the process of publishing to npm and bundling with webpack, which ultimately boosts the development workflow. By utilizing Rust's features, developers can achieve faster, more reliable software solutions, which can ultimately lead to improved project outcomes and increased productivity.

Apache Groovy is a powerful and efficient programming language that features optional typing and dynamic capabilities, alongside support for static typing and compilation, specifically tailored for the Java platform to boost developer productivity through its concise, familiar, and user-friendly syntax. It integrates effortlessly with existing Java applications, offering an array of robust features such as scripting functionalities, the development of Domain-Specific Languages, and both runtime and compile-time meta-programming, all while incorporating functional programming elements. With an emphasis on clear, readable, and expressive syntax, Groovy stands out as particularly accessible for Java developers transitioning to a more dynamic environment. Its capabilities include closures, builders, and type inference, complemented by flexible syntax and advanced integration options that facilitate the embedding of straightforward business rules into applications. This versatile language is particularly adept at creating compact and maintainable tests, making it a superb choice for diverse build and automation tasks while providing extensive customization options. Additionally, Groovy's dynamic characteristics significantly enhance rapid development cycles, establishing it as a preferred choice among developers who seek both efficiency and innovation in their programming endeavors. Ultimately, Groovy not only streamlines coding processes but also fosters a creative atmosphere for developers aiming to push the boundaries of traditional programming.

Since its creation, Julia has been designed with a focus on delivering high performance. Programs developed using Julia compile into highly efficient native code on various platforms thanks to the LLVM framework. At its core, Julia employs multiple dispatch, which greatly aids in representing a wide range of object-oriented and functional programming principles. The exploration of the Remarkable Effectiveness of Multiple Dispatch highlights its outstanding performance capabilities. Additionally, Julia supports dynamic typing, giving it characteristics akin to a scripting language, while also being well-suited for interactive programming sessions. Moreover, Julia offers features such as asynchronous I/O, metaprogramming, debugging tools, logging, profiling, and a package manager, enhancing its versatility. Developers can use Julia’s extensive ecosystem to build comprehensive applications and microservices. This open-source initiative benefits from the contributions of over 1,000 developers and is governed by the MIT License, showcasing its strong community involvement. The blend of high performance and adaptability in Julia positions it as a formidable asset for contemporary programming challenges. As the programming landscape continues to evolve, Julia remains a relevant and effective choice for developers looking to harness its capabilities.

Lua is celebrated as a lightweight and highly efficient scripting language, known for its remarkable versatility and power. It supports a variety of programming styles, such as procedural, object-oriented, functional, and data-driven programming, as well as data description. With its simple procedural syntax and strong data description capabilities rooted in associative arrays and flexible semantics, Lua distinguishes itself from other scripting languages. The language is dynamically typed and utilizes a register-based virtual machine to interpret bytecode, incorporating automatic memory management via incremental garbage collection, which makes it particularly well-suited for tasks like scripting, configuration, and rapid prototyping. Lua is often acknowledged for its outstanding performance, with many other scripting languages striving to match its speed. Benchmarks consistently demonstrate that Lua is among the fastest interpreted scripting languages available. This impressive speed can be seen not only in controlled benchmark scenarios but also in real-world applications, where numerous large-scale projects leverage significant amounts of Lua code. The language's efficiency and adaptability have established it as a favored option for developers aiming to build high-performance applications, making it a staple in various software development environments.

Erlang is a unique programming language crafted for the development of soft real-time systems that excel in scalability and prioritize continuous availability. Its versatility allows it to be utilized in a variety of sectors including telecommunications, finance, online shopping, computer telephony, and instant messaging services. The Erlang runtime system comes with built-in functionalities for concurrency, distribution, and resilience to failures. Furthermore, the Open Telecom Platform (OTP) consists of a suite of Erlang libraries and design principles that act as middleware for building these systems. This suite also features a distributed database, tools for language interoperability, and resources for debugging and managing software deployments. By harnessing these advanced capabilities, developers can create powerful applications that efficiently manage large transaction volumes while sustaining performance across fluctuating loads. Consequently, the combination of Erlang and OTP empowers developers to meet the demands of modern software challenges effectively.

Tcl is a remarkably easy-to-learn programming language that can be understood in a short time frame. For those with some programming background, it is possible to learn enough Tcl essentials to start creating interesting applications within just a few hours. This page provides a brief overview of Tcl's key features. After going through this introduction, you may feel ready to write simple Tcl scripts on your own; however, we recommend delving into one of the many Tcl books available for a deeper grasp of the subject. Each Tcl command consists of multiple words that are separated by spaces, exemplified by the command containing four separate words: expr, 20, +, and 10. The first word indicates the command itself, while the following words act as the command's parameters. While every Tcl command is formed from words, each handles its arguments in distinct manners. For instance, the expr command treats all its arguments as a single arithmetic expression, computes the result, and outputs it as a string. In the context of the expr command, the division of arguments into words is not particularly critical. Moreover, as you become more acquainted with Tcl, you can create increasingly sophisticated and functional scripts, enhancing your programming skills over time. Thus, investing time in understanding Tcl can significantly expand your capabilities as a programmer.

F# combines the ease and brevity reminiscent of Python with the superior correctness, robustness, and performance that outstrip those of C# or Java. This language is open-source and cross-platform, available at no cost, and comes with professional-level tools. F# is an exceptionally capable language for various applications, including web development, cloud computing, and data science, and it integrates smoothly with both JavaScript and the .NET framework. In cloud computing, the ability to leverage multiple interconnected services is crucial, and this is where F# excels due to its unique blend of technologies and features. The surge in popularity of cloud solutions has simplified the deployment of diverse services in the cloud, enhancing the possibilities for storing extensive datasets and performing intricate computations across distributed machine clusters. As the F# developer community grows, the opportunities for groundbreaking cloud-based applications expand significantly, paving the way for innovative solutions in various domains. This evolution not only enhances F#’s reputation but also invites more developers to explore its capabilities in the ever-expanding tech landscape.

LaTeX, articulated as either "Lah-tech" or "Lay-tech" (the latter sharing a rhyme with "blech" or "Bertolt Brecht"), is a document preparation system celebrated for its exceptional typesetting abilities. Although its primary use is for medium to large technical and scientific documents, its adaptability makes it suitable for a wide range of publishing requirements. Crucially, LaTeX differs from standard word processors! It prompts authors to prioritize the essence of their work over the visual aspects of the layout. In typical typesetting or word-processing software, writers are tasked with choosing formatting styles and adjusting font sizes and types for different sections, such as opting for 18pt Times Roman for headings and 12pt Times Italic for names. This often results in two significant problems: writers dedicating excessive time to design decisions and the emergence of inadequately designed publications. In contrast, LaTeX is based on the belief that document design should be entrusted to specialists, enabling authors to focus on effectively developing their content. This approach not only improves the overall quality of the finished document but also simplifies the writing experience. By allowing the software to manage formatting, LaTeX fosters a more productive environment for writers to innovate and express their ideas.

OCaml is recognized as a flexible and powerful programming language that emphasizes expressiveness and safety. Its sophisticated type system effectively minimizes the risk of bugs by identifying issues at the compilation stage, which simplifies the maintenance of large and complex codebases, making it an ideal option for critical applications. Moreover, its advanced type inference capabilities allow the language to operate unobtrusively, thereby improving the overall experience for developers. There are two main compilers available: a bytecode compiler that produces compact, portable executables with remarkable speed and a native code compiler that generates highly optimized machine code, rivaling the performance of top-tier modern compilers. Additionally, OCaml is well-supported by leading code editors, with VS Code being particularly favored by beginners, while seasoned developers appreciate the seamless integration provided by Vim and Emacs. The OCaml community is dynamic and encouraging, offering a rich array of resources and tools that enhance the development process. In conclusion, the combination of OCaml’s powerful features, extensive community support, and the availability of efficient tools makes it an attractive choice for developers interested in creating dependable software solutions. Furthermore, its growing popularity indicates a promising future for the language in the programming landscape.

Elixir is a dynamic and adaptable functional programming language crafted for the development of scalable and maintainable applications. This language operates on the Erlang VM, which is well-known for its ability to facilitate low-latency, distributed, and fault-tolerant systems. Elixir is applicable in a variety of domains, such as web development, embedded systems, data processing, and multimedia applications, which broadens its appeal across many sectors. If you're interested in getting started with Elixir, take the time to delve into our extensive guide and learning materials. The language employs lightweight execution threads called processes, designed for isolation and communication through message passing. Due to their lightweight nature, it's typical for a single machine to handle hundreds of thousands of these processes at once. The isolated design allows for independent garbage collection, significantly reducing system-wide pauses and enhancing resource efficiency for vertical scaling. Furthermore, these processes can communicate with others on different machines within the same network, further increasing the language's flexibility and reliability. Overall, Elixir's architecture not only supports the creation of highly concurrent applications but also offers developers a powerful tool for building resilient systems that can thrive in demanding environments. As developers continue to embrace Elixir, its community and ecosystem are expected to grow, leading to even more innovative uses and advancements in the technology.

C#, commonly known as "C Sharp," stands out as a modern programming language defined by its object-oriented and type-safe characteristics. It empowers developers to craft a diverse range of secure and efficient applications that function seamlessly within the .NET framework. Rooted in the C language family, those who are adept in C, C++, Java, and JavaScript are likely to find C# straightforward and approachable. This guide presents a detailed exploration of the fundamental aspects of C# up to version 8. As a language built on object-oriented and component-oriented principles, C# incorporates constructs designed to facilitate the creation and use of software components. Throughout its evolution, C# has integrated features that address emerging workloads and innovative software design strategies. At its core, C# embodies the principles of object orientation, allowing developers to define types and their related behaviors while nurturing a robust environment for application development. Furthermore, the language continuously evolves to remain pertinent in the dynamic realm of technology, adapting to meet the needs of modern developers. Ultimately, C# stands as a testament to the ongoing innovation in programming languages and their pivotal role in software engineering.