Could someone explain the difference between polynomial-time, non-polynomial-time, and exponential-time algorithms?

For example, if an algorithm takes O(n^2) time, then which category is it in?

10 Answers 10


Below are some common Big-O functions while analyzing algorithms.

  • O(1) - Constant time
  • O(log(n)) - Logarithmic time
  • O((log(n))c) - Polylogarithmic time
  • O(n) - Linear time
  • O(n log(n)) - Linearithmic time
  • O(n2) - Quadratic time
  • O(nc) - Polynomial time
  • O(cn) - Exponential time
  • O(n!) - Factorial time

(n = size of input, c = some constant)

Here is the model graph representing Big-O complexity of some functions

graph model

graph credits http://bigocheatsheet.com/

  • 33
    Plus one for less words and more clarity. Commented Jul 29, 2016 at 15:24
  • 1=n^0 so also polynomial
    – BigChief
    Commented Mar 10, 2019 at 14:02
  • I'm but an individual, but I'm sure I can speak for the majority when I say most, if not all, Computer Science students thank you :)
    – Mario
    Commented Jan 20, 2022 at 15:04
  • Does O(n^n) have a name? Commented Jul 3, 2022 at 9:23
  • 1
    @fearofawhackplanet : O(n^n) is what i call O( rewrite it ) - case in point - if n = 3 ^ 360, then n ^ n has a decimal value in the order of 10 ^ 174 and approximately 2 ^ 2 ^ 579 binary bits - and that's far larger than what GMP is capable of handling, which is :::::::::::::::::::; around 2 ^ ( 2 ^ 30 - 1 ) Commented Oct 16, 2022 at 19:11

Check this out.

Exponential is worse than polynomial.

O(n^2) falls into the quadratic category, which is a type of polynomial (the special case of the exponent being equal to 2) and better than exponential.

Exponential is much worse than polynomial. Look at how the functions grow

n    = 10    |     100   |      1000

n^2  = 100   |   10000   |   1000000 

k^n  = k^10  |   k^100   |    k^1000

k^1000 is exceptionally huge unless k is smaller than something like 1.1. Like, something like every particle in the universe would have to do 100 billion billion billion operations per second for trillions of billions of billions of years to get that done.

I didn't calculate it out, but ITS THAT BIG.

  • 42
    I enjoyed all your illions.
    – Josephine
    Commented Nov 30, 2010 at 19:50
  • 10
    k^1000 is exceptionally huge if k is appreciably larger than 1. If k=1 it's less impressive, and if k=1.00069387..., it's 2.
    – Josephine
    Commented Nov 30, 2010 at 19:53
  • 3
    How about n! vs k^n. I know for 2^n(most common), n! will be more expensive, but i believe for a general k^n where k>2, n! will be less expensive.
    – Saad
    Commented Jul 17, 2016 at 23:44
  • 1
    I'm glad you didn't say "billions and billions". :-) Commented Apr 25, 2018 at 7:02
  • 2
    @Saad n! will always be more expensive than k^n for a constant k, asymptotically. You are right, however, in that this is only the case once we reach a high value of n. By Stirling's approximation, factorial time should become more expensive around when n=e*k, where e=2.71828..
    – inavda
    Commented Mar 22, 2019 at 14:11

O(n^2) is polynomial time. The polynomial is f(n) = n^2. On the other hand, O(2^n) is exponential time, where the exponential function implied is f(n) = 2^n. The difference is whether the function of n places n in the base of an exponentiation, or in the exponent itself.

Any exponential growth function will grow significantly faster (long term) than any polynomial function, so the distinction is relevant to the efficiency of an algorithm, especially for large values of n.

  • This answer has an authoritative (good) air, but it differs from @dheeran's answer, I believe, in whether the base in the exponential case is necessarily 2. Or probably I misunderstand and just need to dust off my algebra. Commented Apr 25, 2018 at 7:18

Polynomial time.

A polynomial is a sum of terms that look like Constant * x^k Exponential means something like Constant * k^x

(in both cases, k is a constant and x is a variable).

The execution time of exponential algorithms grows much faster than that of polynomial ones.


Exponential (You have an exponential function if MINIMAL ONE EXPONENT is dependent on a parameter):

  • E.g. f(x) = constant ^ x

Polynomial (You have a polynomial function if NO EXPONENT is dependent on some function parameters):

  • E.g. f(x) = x ^ constant
  • 7
    I don't like it if nothing from my original answer is left after it has been edited by a user. Is this some kind of "like-fishing"? Commented Dec 10, 2014 at 10:20
  • 2
    I have to agree. The changes are ridiculous. Commented Jun 30, 2015 at 14:01

More precise definition of exponential

The definition of polynomial is pretty much universal and straightforward so I won't discuss it further.

The definition of Big O is also quite universal, you just have to think carefully about the M and the x0 in the Wikipedia definition and work through some examples.

So in this answer I would like to focus on the precise definition of the exponential as it requires a bit more thought/is less well known/is less universal, especially when you start to think about some edge cases. I will then contrast it with polynomials a bit further below

The most common definition of exponential time is:


where polynomial is a polynomial that:

  • is not constant, e.g. 1, otherwise the time is also constant
  • the highest order term has a positive coefficient, otherwise it goes to zero at infinity, e.g. 2^{-n^2 + 2n + 1}

so a polynomial such as this would be good:

2^{n^2 + 2n + 1}

Note that the base 2 could be any number > 1 and the definition would still be valid because we can transform the base by multiplying the exponent, e.g.:

8^{polymonial(n)} = (2^3)^{polymonial(n)} = 2^{3 * polymonial(n)}

and 3 * polymonial(n) is also a polynomial.

Also note that constant addition does not matter, e.g. 2^{n + 1} = 2 * 2^{n} and so the + 1 does not matter for big O notation.

Therefore, two possible nice big O equivalent choices for a canonical "smallest exponential" would be for any small positive e either of:

(1 + e)^{n}

for very small e.

The highest order term of the polynomial in the exponent in both cases is n^1, order one, and therefore the smallest possible non-constant polynomial.

Those two choices are equivalent, because as saw earlier, we can transform base changes into an exponent multiplier.

Superpolynomial and sub-exponential

But note that the above definition excludes some still very big things that show up in practice and that we would be tempted to call "exponential", e.g.:

  • 2^{n^{1/2}}. This is a bit like a polynomial, but it is not a polynomial because polynomial powers must be integers, and here we have 1/2
  • 2^{log_2(n)^2}

Those functions are still very large, because they grow faster than any polynomial.

But strictly speaking, they are big O smaller than the exponentials in our strict definition of exponential!

This motivates the following definitions:

  • superpolynomial: grows faster than any polynomial
  • subexponential: grows less fast than any exponential, i.e. (1 + e)^{n}

and all the examples given above in this section fall into both of those categories. TODO proof.

Keep in mind that if you put something very small on the exponential, it might go back to polynomial of course, e.g.:

2^{log_2(n)} = n

And that is also true for anything smaller than log_2, e.g.:

2^{log_2(log_2(n))} = log_2(n)

is sub-polynomial.

Important superpolynomial and sub-exponential examples

  • the general number field sieve the fastest 2020-known algorithm for integer factorization, see also: What is the fastest integer factorization algorithm? That algorithm has complexity of the form:

    e^{(k + o(1))(ln(n)^(1/3) * ln(ln(n)))^(2/3)}

    where n is the factored number, and the little-o notation o(1) means a term that goes to 0 at infinity.

    That complexity even has a named generalization as it presumably occurs in other analyses: L-notation.

    Note that the above expression itself is clearly polynomial in n, because it is smaller than e^{ln(n)^(1/3) * ln(n))^(2/3)} = e^{ln(n)} = n.

    However, in the context of factorization, what really matters is note n, but rather "the number of digits of n", because cryptography parties can easily generate crypto keys that are twice as large. And the number of digits grows as log_2. So in that complexity, what we really care about is something like:

    e^{(k + o(1))(n^(1/3) * ln(n)^(2/3)}

    which is of course both superpolynomial and sub-exponential.

    The fantastic answer at: What would cause an algorithm to have O(log log n) complexity? gives an intuitive explanation of where the O(log log n) comes from: while log n comes from an algorithm that removes half of the options at each step, and log log n comes from an algorithm that reduces the options to the square root of the total at each step!

  • https://quantumalgorithmzoo.org/ contains a list of algorithms which might be of interest to quantum computers, and in most cases, the quantum speedup relative to a classical computer is not strictly exponential, but rather superpolynomial. However, as this answer will have hopefully highlighted, this is still extremely significant and revolutionary. Understanding that repository is what originally motivated this answer :-)

    It is also worth noting that we currently do not expect quantum computers to solve NP-complete problems, which are also generally expected to require exponential time to solve. But there is no proof otherwise either. See also: https://cs.stackexchange.com/questions/130470/can-quantum-computing-help-solve-np-complete-problems

https://math.stackexchange.com/questions/3975382/what-problems-are-known-to-be-require-superpolynomial-time-or-greater-to-solve asks about any interesting algorithms that have been proven superpolynomial (and presumably with proof of optimality, otherwise the general number sieve would be an obvious choice, but we don't 2020-know if it is optimal or not)

Proof that exponential is always larger than polynomial at infinity


Discussions of different possible definitions of sub-exponential


polynomial time O(n)^k means Number of operations are proportional to power k of the size of input

exponential time O(k)^n means Number of operations are proportional to the exponent of the size of input


Polynomial examples: n^2, n^3, n^100, 5n^7, etc….

Exponential examples: 2^n, 3^n, 100^n, 5^(7n), etc….

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    – Community Bot
    Commented Mar 29, 2022 at 15:50

o(n sequre) is polynimal time complexity while o(2^n) is exponential time complexity if p=np when best case , in the worst case p=np not equal becasue when input size n grow so long or input sizer increase so longer its going to worst case and handling so complexity growth rate increase and depend on n size of input when input is small it is polynimal when input size large and large so p=np not equal it means growth rate depend on size of input "N". optimization, sat, clique, and independ set also met in exponential to polynimal.


Here's the most simplest explaination for newbies:

A Polynomial: if an expression contains or function is equal to when a constant is the power of a variable e.g.

f(n) = 2 ^ n


An Exponential: if an expression contains or function is qual to when a variable is the power of a constant e.g.

f(n) = n ^ 2
  • 3
    Is the other way around. Please update this answer. Commented May 19, 2021 at 15:26
  • @AndresZapata Not yet Commented May 25, 2021 at 14:54

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