Most of the mainstream languages, including object-oriented programming (OOP) languages such as C#, Visual Basic, C++, and Java were designed to primarily support imperative (procedural) programming, whereas Haskell/gofer like languages are purely functional. Can anybody elaborate on what is the difference between these two ways of programming?

I know it depends on user requirements to choose the way of programming but why is it recommended to learn functional programming languages?


9 Answers 9


Here is the difference:


  • Start
  • Turn on your shoes size 9 1/2.
  • Make room in your pocket to keep an array[7] of keys.
  • Put the keys in the room for the keys in the pocket.
  • Enter garage.
  • Open garage.
  • Enter Car.

... and so on and on ...

  • Put the milk in the refrigerator.
  • Stop.

Declarative, whereof functional is a subcategory:

  • Milk is a healthy drink, unless you have problems digesting lactose.
  • Usually, one stores milk in a refrigerator.
  • A refrigerator is a box that keeps the things in it cool.
  • A store is a place where items are sold.
  • By "selling" we mean the exchange of things for money.
  • Also, the exchange of money for things is called "buying".

... and so on and on ...

  • Make sure we have milk in the refrigerator (when we need it - for lazy functional languages).

Summary: In imperative languages you tell the computer how to change bits, bytes and words in it's memory and in what order. In functional ones, we tell the computer what things, actions etc. are. For example, we say that the factorial of 0 is 1, and the factorial of every other natural number is the product of that number and the factorial of its predecessor. We don't say: To compute the factorial of n, reserve a memory region and store 1 there, then multiply the number in that memory region with the numbers 2 to n and store the result at the same place, and at the end, the memory region will contain the factorial.

  • 8
    I liked your explanation @Igno, but something is still unclear to me. In Declarative, even though you just tell stuffs, but still you need to change bits and make changes to states in the machine to proceed right. It makes me confused, that somehow Declarative is similar to Procedural Programming (like C Functions), and still there is a big difference between them internally. Isn't C Functions same as Functions in Functional programming (on Machine Level) ?
    – phoenisx
    Commented Oct 19, 2016 at 6:34
  • 2
    @Subroto I disagree regarding the need to "change bits" in declarative programming. A declarative language worth its name must shield their users from doing this. To be sure, the implementation of such a language on contemporary hardware will ultimately change bits. -- For your second question: all functional functions can also be written as C functions without observable side effects. But not all C functions are functional, and they tend to be procedures instead (i.e. do this side-effect, then do that side effect, and if this bit is set, cause another side effect).
    – Ingo
    Commented Oct 19, 2016 at 18:14
  • 19
    @Igno, Like Subroto, I don't really understand your explanation. It seems like what you've written can be summarized as: Need answer...get answer. it seems to ignore the important bits which is how. I don't understand how you can just hide that part from the user, at some point someone has to know how it was done...you cant keep the wizard behind the curtain forever. Commented Jan 25, 2017 at 4:49
  • 7
    This is not remotely what I understand functional programming to be. I thought functional programming was the removal of hidden inputs and outputs from functions.
    – Ringo
    Commented Apr 24, 2017 at 6:59
  • 16
    Convoluted explanation.
    – JoeTidee
    Commented May 5, 2017 at 17:30

Definition: An imperative language uses a sequence of statements to determine how to reach a certain goal. These statements are said to change the state of the program as each one is executed in turn.

Examples: Java is an imperative language. For example, a program can be created to add a series of numbers:

 int total = 0;
 int number1 = 5;
 int number2 = 10;
 int number3 = 15;
 total = number1 + number2 + number3; 

Each statement changes the state of the program, from assigning values to each variable to the final addition of those values. Using a sequence of five statements the program is explicitly told how to add the numbers 5, 10 and 15 together.

Functional languages: The functional programming paradigm was explicitly created to support a pure functional approach to problem solving. Functional programming is a form of declarative programming.

Advantages of Pure Functions: The primary reason to implement functional transformations as pure functions is that pure functions are composable: that is, self-contained and stateless. These characteristics bring a number of benefits, including the following: Increased readability and maintainability. This is because each function is designed to accomplish a specific task given its arguments. The function does not rely on any external state.

Easier reiterative development. Because the code is easier to refactor, changes to design are often easier to implement. For example, suppose you write a complicated transformation, and then realize that some code is repeated several times in the transformation. If you refactor through a pure method, you can call your pure method at will without worrying about side effects.

Easier testing and debugging. Because pure functions can more easily be tested in isolation, you can write test code that calls the pure function with typical values, valid edge cases, and invalid edge cases.

For OOP People or Imperative languages:

Object-oriented languages are good when you have a fixed set of operations on things and as your code evolves, you primarily add new things. This can be accomplished by adding new classes which implement existing methods and the existing classes are left alone.

Functional languages are good when you have a fixed set of things and as your code evolves, you primarily add new operations on existing things. This can be accomplished by adding new functions which compute with existing data types and the existing functions are left alone.


It depends on the user requirements to choose the way of programming, so there is harm only when users don’t choose the proper way.

When evolution goes the wrong way, you have problems:

  • Adding a new operation to an object-oriented program may require editing many class definitions to add a new method
  • Adding a new kind of thing to a functional program may require editing many function definitions to add a new case.
  • 14
    A pure function in this case is the equivalent of a mathematical function. The same inputs will always map to the same outputs. They also lack any side effects (other than returning a value or values) which means the compiler can do some cool optimizations, and it makes it easier to run function in parallel as there's nothing to contend with.
    – WorBlux
    Commented Jul 24, 2013 at 22:00
  • So, the right ways of and the best practices of composing maintainable and testable oop applications tend to be designing imperative code with a declerative state of mind? Commented Mar 7, 2014 at 8:09
  • 5
    I don't see a clear difference on the text where the feature of each programming are highlighted. Most of the description for procedural programming can be exchanged by the imperative programming text and vice versa.
    – AxeEffect
    Commented Apr 21, 2015 at 7:31
  • 14
    This answer attempts to clarify what functional programming is but does not even bother to define what a pure function is. I don't see how anyone could read this answer and come away feeling confident in knowing the difference between declarative and procedural programming.
    – Ringo
    Commented Apr 24, 2017 at 7:02

Most modern languages are in varying degree both imperative and functional but to better understand functional programming, it will be best to take an example of pure functional language like Haskell in contrast of imperative code in not so functional language like java/C#. I believe it is always easy to explain by example, so below is one.

Functional programming: calculate factorial of n i.e n! i.e n x (n-1) x (n-2) x ...x 2 X 1

-- | Haskell comment goes like
-- | below 2 lines is code to calculate factorial and 3rd is it's execution  

factorial 0 = 1
factorial n = n * factorial (n - 1)
factorial 3

-- | for brevity let's call factorial as f; And x => y shows order execution left to right
-- | above executes as := f(3) as 3 x f(2) => f(2) as 2 x f(1) => f(1) as 1 x f(0) => f(0) as 1  
-- | 3 x (2 x (1 x (1)) = 6

Notice that Haskel allows function overloading to the level of argument value. Now below is example of imperative code in increasing degree of imperativeness:

//somewhat functional way
function factorial(n) {
  if(n < 1) {
     return 1;
  return n * factorial(n-1);   

//somewhat more imperative way
function imperativeFactor(n) {
  int f = 1;
  for(int i = 1; i <= n; i++) {
     f = f * i;
  return f;

This read can be a good reference to understand that how imperative code focus more on how part, state of machine (i in for loop), order of execution, flow control.

The later example can be seen as java/C# lang code roughly and first part as limitation of the language itself in contrast of Haskell to overload the function by value (zero) and hence can be said it is not purist functional language, on the other hand you can say it support functional prog. to some extent.

Disclosure: none of the above code is tested/executed but hopefully should be good enough to convey the concept; also I would appreciate comments for any such correction :)

  • 2
    Shouldn't it be return n * factorial(n-1);?
    – jinawee
    Commented Feb 20, 2019 at 10:06
  • @jinawee, thanks for pointing out, I have corrected it from n * (n-1)
    – old-monk
    Commented Feb 21, 2019 at 17:12
  • 1
    It's more a comparison of recursive and non-recursive approaches. Personally, I don't see how functional program can be considered "declarative". Just like in the imperative programs, we have to specify the steps for a program to execute. It just appears that language such as Haskell has many neat one-liners which shorten the program, and that's all.
    – mnj
    Commented Feb 2, 2022 at 13:58

Functional Programming is a form of declarative programming, which describe the logic of computation and the order of execution is completely de-emphasized.

Problem: I want to change this creature from a horse to a giraffe.

  • Lengthen neck
  • Lengthen legs
  • Apply spots
  • Give the creature a black tongue
  • Remove horse tail

Each item can be run in any order to produce the same result.

Imperative Programming is procedural. State and order is important.

Problem: I want to park my car.

  1. Note the initial state of the garage door
  2. Stop car in driveway
  3. If the garage door is closed, open garage door, remember new state; otherwise continue
  4. Pull car into garage
  5. Close garage door

Each step must be done in order to arrive at desired result. Pulling into the garage while the garage door is closed would result in a broken garage door.

  • 2
    I see only the difference in async vs. sync. Commented Mar 25, 2019 at 14:17
  • @VladimirVukanac async/sync is a mechanism, not a form of programming Commented Mar 29, 2019 at 13:46
  • 3
    Oh, thanks, I will research more about it. Would you be so kind, to update problem 1 to be the same as problem 2 "I want to park my car" but written in functional programming way? Then parallelism will be excluded. Commented Mar 29, 2019 at 15:34
  • 2
    what? the order of operations in functional languages matters all the same. (x - 1) * 3 is not the same as (x * 3) - 1. as another example, fillBasket(emptyBasket(b), items) has a different effect compared to emptyBasket(fillBasket(b, items)).
    – Mulan
    Commented Jan 27, 2021 at 17:27
int a = ...
int b = ...    

int c = 0; //1. there is mutable data
c = a+b;   //2. statements (our +, our =) are used to update existing data (variable c)

An imperative program = sequence of statements that change existing data.

Focus on WHAT = our mutating data (modifiable values aka variables).

To chain imperative statements = use procedures (and/or oop).

const int a = ... //data is always immutable
const int b = ... //data is always immutable

//1. declare pure functions; we use statements to create "new" data (the result of our +), but nothing is ever "changed"
int add(x, y) 
   return x+y; //only depends on inputs; only impact on caller: via "return" value

//2. usage = call functions to get new data
const int c = add(a,b); //c can only be assigned (=) once (const)

A functional program = a list of functions "explaining" how new data can be obtained.

Focus on HOW = our function add.

To chain functional "statements" = use function composition.

These fundamental distinctions have deep implications.

Serious software has a lot of data and a lot of code.

So same data (variable) is used in multiple parts of the code.

A. In an imperative program, the mutability of this (shared) data causes issues

  • code is hard to understand/maintain (since data can be modified in different locations/ways/moments)
  • parallelizing code is hard (only one thread can mutate a memory location at the time) which means mutating accesses to same variable have to be serialized = developer must write additional code to enforce this serialized access to shared resources, typically via locks/semaphores

As an advantage: data is really modified in place, less need to copy. (some performance gains)

B. On the other hand, functional code uses immutable data which does not have such issues. Data is readonly so there are no race conditions. Code can be easily parallelized. Results can be cached. Much easier to understand.

As a disadvantage: data is copied a lot in order to get "modifications".

See also: https://en.wikipedia.org/wiki/Referential_transparency

update: in imperative code, state mutation can occur everywhere. So your logic is interleaved with mutating state, which makes this state actually impact your ... logic, so code becomes very complicated to understand. Distant, non-local state may impact a function in unexpected ways.

In functional approach, only local state matters, only inside a function. Outside, you can safely reuse your function knowing that it will always behave the same way, no external context needed to determine what it does. And composing such functions becomes a very powerful tool, you get complex but reliable code as long as functions are pure.


Imperative programming style was practiced in web development from 2005 all the way to 2013.

With imperative programming, we wrote out code that listed exactly what our application should do, step by step.

The functional programming style produces abstraction through clever ways of combining functions.

There is mention of declarative programming in the answers and regarding that I will say that declarative programming lists out some rules that we are to follow. We then provide what we refer to as some initial state to our application and we let those rules kind of define how the application behaves.

Now, these quick descriptions probably don’t make a lot of sense, so lets walk through the differences between imperative and declarative programming by walking through an analogy.

Imagine that we are not building software, but instead we bake pies for a living. Perhaps we are bad bakers and don’t know how to bake a delicious pie the way we should.

So our boss gives us a list of directions, what we know as a recipe.

The recipe will tell us how to make a pie. One recipe is written in an imperative style like so:

  1. Mix 1 cup of flour
  2. Add 1 egg
  3. Add 1 cup of sugar
  4. Pour the mixture into a pan
  5. Put the pan in the oven for 30 minutes and 350 degrees F.

The declarative recipe would do the following:

1 cup of flour, 1 egg, 1 cup of sugar - initial State


  1. If everything mixed, place in pan.
  2. If everything unmixed, place in bowl.
  3. If everything in pan, place in oven.

So imperative approaches are characterized by step by step approaches. You start with step one and go to step 2 and so on.

You eventually end up with some end product. So making this pie, we take these ingredients mix them, put it in a pan and in the oven and you got your end product.

In a declarative world, its different.In the declarative recipe we would separate our recipe into two separate parts, start with one part that lists the initial state of the recipe, like the variables. So our variables here are the quantities of our ingredients and their type.

We take the initial state or initial ingredients and apply some rules to them.

So we take the initial state and pass them through these rules over and over again until we get a ready to eat rhubarb strawberry pie or whatever.

So in a declarative approach, we have to know how to properly structure these rules.

So the rules we might want to examine our ingredients or state, if mixed, put them in a pan.

With our initial state, that doesn’t match because we haven’t yet mixed our ingredients.

So rule 2 says, if they not mixed then mix them in a bowl. Okay yeah this rule applies.

Now we have a bowl of mixed ingredients as our state.

Now we apply that new state to our rules again.

So rule 1 says if ingredients are mixed place them in a pan, okay yeah now rule 1 does apply, lets do it.

Now we have this new state where the ingredients are mixed and in a pan. Rule 1 is no longer relevant, rule 2 does not apply.

Rule 3 says if the ingredients are in a pan, place them in the oven, great that rule is what applies to this new state, lets do it.

And we end up with a delicious hot apple pie or whatever.

Now, if you are like me, you may be thinking, why are we not still doing imperative programming. This makes sense.

Well, for simple flows yes, but most web applications have more complex flows that cannot be properly captured by imperative programming design.

In a declarative approach, we may have some initial ingredients or initial state like textInput=“”, a single variable.

Maybe text input starts off as an empty string.

We take this initial state and apply it to a set of rules defined in your application.

  1. If a user enters text, update text input. Well, right now that doesn’t apply.

  2. If template is rendered, calculate the widget.

  3. If textInput is updated, re render the template.

Well, none of this applies so the program will just wait around for an event to happen.

So at some point a user updates the text input and then we might apply rule number 1.

We may update that to “abcd”

So we just updated our text and textInput updates, rule number 2 does not apply, rule number 3 says if text input is update, which just occurred, then re render the template and then we go back to rule 2 thats says if template is rendered, calculate the widget, okay lets calculate the widget.

In general, as programmers, we want to strive for more declarative programming designs.

Imperative seems more clear and obvious, but a declarative approach scales very nicely for larger applications.


I think it's possible to express functional programming in an imperative fashion:

  • Using a lot of state check of objects and if... else/ switch statements
  • Some timeout/ wait mechanism to take care of asynchornousness

There are huge problems with such approach:

  • Rules/ procedures are repeated
  • Statefulness leaves chances for side-effects/ mistakes

Functional programming, treating functions/ methods like objects and embracing statelessness, was born to solve those problems I believe.

Example of usages: frontend applications like Android, iOS or web apps' logics incl. communication with backend.

Other challenges when simulating functional programming with imperative/ procedural code:

  • Race condition
  • Complex combination and sequence of events. For example, user tries to send money in a banking app. Step 1) Do all of the following in parallel, only proceed if all is good a) Check if user is still good (fraud, AML) b) check if user has enough balance c) Check if recipient is valid and good (fraud, AML) etc. Step 2) perform the transfer operation Step 3) Show update on user's balance and/ or some kind of tracking. With RxJava for example, the code is concise and sensible. Without it, I can imagine there'd be a lot of code, messy and error prone code

I also believe that at the end of the day, functional code will get translated into assembly or machine code which is imperative/ procedural by the compilers. However, unless you write assembly, as humans writing code with high level/ human-readable language, functional programming is the more appropriate way of expression for the listed scenarios


There seem to be many opinions about what functional programs and what imperative programs are.

I think functional programs can most easily be described as "lazy evaluation" oriented. Instead of having a program counter iterate through instructions, the language by design takes a recursive approach.

In a functional language, the evaluation of a function would start at the return statement and backtrack, until it eventually reaches a value. This has far reaching consequences with regards to the language syntax.

Imperative: Shipping the computer around

Below, I've tried to illustrate it by using a post office analogy. The imperative language would be mailing the computer around to different algorithms, and then have the computer returned with a result.

Functional: Shipping recipes around

The functional language would be sending recipes around, and when you need a result - the computer would start processing the recipes.

This way, you ensure that you don't waste too many CPU cycles doing work that is never used to calculate the result.

When you call a function in a functional language, the return value is a recipe that is built up of recipes which in turn is built of recipes. These recipes are actually what's known as closures.

// helper function, to illustrate the point
function unwrap(val) {
  while (typeof val === "function") val = val();
  return val;

function inc(val) {
  return function() { unwrap(val) + 1 };

function dec(val) {
  return function() { unwrap(val) - 1 };

function add(val1, val2) {
  return function() { unwrap(val1) + unwrap(val2) }

// lets "calculate" something

let thirteen = inc(inc(inc(10)))
let twentyFive = dec(add(thirteen, thirteen))

// MAGIC! The computer still has not calculated anything.
// 'thirteen' is simply a recipe that will provide us with the value 13

// lets compose a new function

let doubler = function(val) {
  return add(val, val);

// more modern syntax, but it's the same:
let alternativeDoubler = (val) => add(val, val)

// another function
let doublerMinusOne = (val) => dec(add(val, val));

// Will this be calculating anything?

let twentyFive = doubler(thirteen)

// no, nothing has been calculated. If we need the value, we have to unwrap it:
console.log(unwrap(thirteen)); // 26

The unwrap function will evaluate all the functions to the point of having a scalar value.

Language Design Consequences

Some nice features in imperative languages, are impossible in functional languages. For example the value++ expression, which in functional languages would be difficult to evaluate. Functional languages make constraints on how the syntax must be, because of the way they are evaluated.

On the other hand, with imperative languages can borrow great ideas from functional languages and become hybrids.

Functional languages have great difficulty with unary operators like for example ++ to increment a value. The reason for this difficulty is not obvious, unless you understand that functional languages are evaluated "in reverse".

Implementing a unary operator would have to be implemented something like this:

let value = 10;

function increment_operator(value) {
  return function() {
    unwrap(value) + 1;

value++ // would "under the hood" become value = increment_operator(value)

Note that the unwrap function I used above, is because javascript is not a functional language, so when needed we have to manually unwrap the value.

It is now apparent that applying increment a thousand times would cause us to wrap the value with 10000 closures, which is worthless.

The more obvious approach, is to actually directly change the value in place - but voila: you have introduced modifiable values a.k.a mutable values which makes the language imperative - or actually a hybrid.

Under the hood, it boils down to two different approaches to come up with an output when provided with an input.

Below, I'll try to make an illustration of a city with the following items:

  1. The Computer
  2. Your Home
  3. The Fibonaccis

Imperative Languages

Task: Calculate the 3rd fibonacci number. Steps:

  1. Put The Computer into a box and mark it with a sticky note:

    Field Value
    Mail Address The Fibonaccis
    Return Address Your Home
    Parameters 3
    Return Value undefined

    and send off the computer.

  2. The Fibonaccis will upon receiving the box do as they always do:

    • Is the parameter < 2?

      • Yes: Change the sticky note, and return the computer to the post office:

        Field Value
        Mail Address The Fibonaccis
        Return Address Your Home
        Parameters 3
        Return Value 0 or 1 (returning the parameter)

        and return to sender.

      • Otherwise:

        1. Put a new sticky note on top of the old one:

          Field Value
          Mail Address The Fibonaccis
          Return Address Otherwise, step 2, c/oThe Fibonaccis
          Parameters 2 (passing parameter-1)
          Return Value undefined

          and send it.

        2. Take off the returned sticky note. Put a new sticky note on top of the initial one and send The Computer again:

          Field Value
          Mail Address The Fibonaccis
          Return Address Otherwise, done, c/o The Fibonaccis
          Parameters 2 (passing parameter-2)
          Return Value undefined
        3. By now, we should have the initial sticky note from the requester, and two used sticky notes, each having their Return Value field filled. We summarize the return values and put it in the Return Value field of the final sticky note.

          Field Value
          Mail Address The Fibonaccis
          Return Address Your Home
          Parameters 3
          Return Value 2 (returnValue1 + returnValue2)

          and return to sender.

As you can imagine, quite a lot of work starts immediately after you send your computer off to the functions you call.

The entire programming logic is recursive, but in truth the algorithm happens sequentially as the computer moves from algorithm to algorithm with the help of a stack of sticky notes.

Functional Languages

Task: Calculate the 3rd fibonacci number. Steps:

  1. Write the following down on a sticky note:

    Field Value
    Instructions The Fibonaccis
    Parameters 3

That's essentially it. That sticky note now represents the computation result of fib(3).

We have attached the parameter 3 to the recipe named The Fibonaccis. The computer does not have to perform any calculations, unless somebody needs the scalar value.

Functional Javascript Example

I've been working on designing a programming language named Charm, and this is how fibonacci would look in that language.

fib: (n) => if (                         
  n < 2               // test
  n                   // when true
  fib(n-1) + fib(n-2) // when false

This code can be compiled both into imperative and functional "bytecode".

The imperative javascript version would be:

let fib = (n) => 
  n < 2 ?
  n : 
  fib(n-1) + fib(n-2);

The HALF functional javascript version would be:

let fib = (n) => () =>
  n < 2 ?
  n :
  fib(n-1) + fib(n-2);

The PURE functional javascript version would be much more involved, because javascript doesn't have functional equivalents.

let unwrap = ($) =>
  typeof $ !== "function" ? $ : unwrap($());

let $if = ($test, $whenTrue, $whenFalse) => () =>
  unwrap($test) ? $whenTrue : $whenFalse;

let $lessThen = (a, b) => () =>
  unwrap(a) < unwrap(b);

let $add = ($value, $amount) => () =>
  unwrap($value) + unwrap($amount);

let $sub = ($value, $amount) => () =>
  unwrap($value) - unwrap($amount);

let $fib = ($n) => () =>
    $lessThen($n, 2),
    $add( $fib( $sub($n, 1) ), $fib( $sub($n, 2) ) )

I'll manually "compile" it into javascript code:

"use strict";

// Library of functions:
   * Function that resolves the output of a function.
  let $$ = (val) => {
    while (typeof val === "function") {
      val = val();
    return val;

   * Functional if
   * The $ suffix is a convention I use to show that it is "functional"
   * style, and I need to use $$() to "unwrap" the value when I need it.
  let if$ = (test, whenTrue, otherwise) => () =>
    $$(test) ? whenTrue : otherwise;

   * Functional lt (less then)
  let lt$ = (leftSide, rightSide)   => () => 
    $$(leftSide) < $$(rightSide)

   * Functional add (+)
  let add$ = (leftSide, rightSide) => () => 
    $$(leftSide) + $$(rightSide)

// My hand compiled Charm script:

   * Functional fib compiled
  let fib$ = (n) => if$(                 // fib: (n) => if(
    lt$(n, 2),                           //   n < 2
    () => n,                             //   n
    () => add$(fib$(n-2), fib$(n-1))     //   fib(n-1) + fib(n-2)
  )                                      // )

// This takes a microsecond or so, because nothing is calculated

// When you need the value, just unwrap it with $$( fib$(30) )
console.log( $$( fib$(5) ))

// The only problem that makes this not truly functional, is that
console.log(fib$(5) === fib$(5)) // is false, while it should be true
// but that should be solveable



I know this question is older and others already explained it well, I would like to give an example problem which explains the same in simple terms.

Problem: Writing the 1's table.

Solution: -

By Imperative style: =>


By Functional style: =>


Explanation in Imperative style we write the instructions more explicitly and which can be called as in more simplified manner.

Where as in Functional style, things which are self-explanatory will be ignored.

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