Functional programming is a programming paradigm that deals primarily with mathematical functions. In functional languages, functions are first-class values.
Functions take arguments and return results, but typically don't mutate state. This in contrast to imperative programming, which primarily revolves around statements that change state. The advantage of avoiding mutable state is that you can safely compose functions, and you can use algebraic laws and "substitution of equals for equals" to simplify programs or improve their performance.
One consequence of this is that many common patterns in programming can be abstracted as higher-order functions, which apply a function that implements real functionality, and applies it to data in a known way. This can make code more concise and simpler to reason about and understand.
Today, functional programming is getting more and more popular. The main reason of this process is the provability of functional programms, and security is very important nowadays. There are many use cases for functional programming, e.g. Computations or Concurrency handling. Use cases of functional programming
These languages are listed in order of popularity in relation to the
Languages that are primarily functional, although some support mutable state or other programming paradigms:
Languages that have some functional aspects (like support for first class functions) but are not considered functional languages per se: