WebAssembly (WASM) is one of the most exciting developments in the web world today. It is a low-level binary format designed to bring high-performance capabilities to the web platform. While not a programming language itself, WebAssembly allows languages like C, Rust, and C++ to be compiled into a format that can be run in the browser.

With a focus on speed, memory safety, and openness, WebAssembly is revolutionizing web development. It is the second language, after JavaScript, to be natively understood by web browsers. All modern browsers, including Chrome, Firefox, Safari, Edge, and mobile browsers, as well as Node.js, now support WebAssembly.

WebAssembly does not aim to replace JavaScript but rather to complement it. It allows developers who prefer other languages or want to leverage existing code to write parts of their web applications in languages other than JavaScript. By combining the ease of use and flexibility of JavaScript with the power and performance of WebAssembly, developers can create outstanding user experiences on the web.

WebAssembly offers a secure environment for running code, with the same security policies as JavaScript. It runs in a sandboxed environment, ensuring that only authorized operations are performed. For those interested in learning more about the security aspects of WebAssembly, I recommend reading “Memory in WebAssembly” and the security documentation provided by webassembly.org.

Performance is a key advantage of WebAssembly. By being a compiled language, WebAssembly can achieve performance similar to that of natively compiled languages like C. In comparison, JavaScript, being a dynamic and interpreted language, cannot match the speed of WebAssembly. JavaScript code is interpreted and optimized on the fly by the browser, whereas WebAssembly code is already compiled to binaries.

Many companies are already leveraging the power of WebAssembly to improve their web applications. Figma, a popular design application, is built using React, but its graphics editor is a C++ application compiled to WebAssembly and rendered in a Canvas using WebGL. AutoCAD also released its design product running as a web app using WebAssembly, enabling complex editing capabilities previously only available in the desktop client.

To use WebAssembly, you can compile C and C++ applications to WASM using Emscripten, a toolchain that generates a .wasm binary and a .js file. Emscripten handles tasks such as converting OpenGL calls to WebGL and providing bindings for DOM and other browser APIs. Rust code, on the other hand, can be directly compiled to WebAssembly without the need for additional tools.

The future of WebAssembly looks promising. WebAssembly is now at version 1.0 and officially supports three languages (C, Rust, and C++), but support for more languages, including Go, Java, and C#, is on the horizon. Efforts are also underway to enhance the integration of WebAssembly with the browser, allowing it to call DOM, Web Workers, and other browser APIs directly. Furthermore, work is being done to enable JavaScript code to load WebAssembly modules through the ES Modules specification.

To get started with WebAssembly, you can install Emscripten by following the instructions provided in the article. Once set up, you can compile your C programs using Emscripten and run them in the browser. The article includes an example of a “Hello World” program compiled to WebAssembly and executed in the browser using Emscripten.

In addition to running complete programs, you can call WebAssembly functions from JavaScript. The article demonstrates how to modify the “Hello World” program to expose a function that can be called from JavaScript. It covers the usage of ccall and cwrap functions to interact with WebAssembly functions from JavaScript.

WebAssembly is a promising technology that empowers developers to build high-performance web applications using languages beyond JavaScript. With its growing support and potential for future enhancements, WebAssembly is set to play a significant role in the future of web development.

Tags: WebAssembly, web platform, low-level binary format, programming languages, C, Rust, C++, JavaScript, performance, security, Emscripten, sandboxed environment, user experiences, Figma, AutoCAD, future evolution, integration, ES Modules, installation, Hello World program, WebAssembly functions, JavaScript interaction