# The most efficient way to implement an integer based power function pow(int, int)

What is the most efficient way given to raise an integer to the power of another integer in C?

``````// 2^3
pow(2,3) == 8

// 5^5
pow(5,5) == 3125
``````
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When you say "efficiency," you need to specify efficient in relation to what. Speed? Memory usage? Code size? Maintainability? –  Andy Lester Oct 2 '08 at 17:26
Doesn't C have a pow() function? –  jalf May 30 '09 at 13:07
yes, but that works on floats or doubles, not on ints –  Nathan Fellman May 30 '09 at 13:46

Exponentiation by squaring.

``````int ipow(int base, int exp)
{
int result = 1;
while (exp)
{
if (exp & 1)
result *= base;
exp >>= 1;
base *= base;
}

return result;
}
``````

This is the standard method for doing modular exponentiation for huge numbers in asymmetric cryptography.

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Thanks for the code Elias. I beautified the code a bit for better presentation. –  Ashwin Nanjappa May 30 '09 at 12:58
You should probably add a check that "exp" isn't negative. Currently, this function will either give a wrong answer or loop forever. (Depending on whether >>= on a signed int does zero-padding or sign-extension - C compilers are allowed to pick either behaviour). –  user9876 Jul 28 '09 at 16:42
GSL's gsl_sf_pow_int implements this, including the negative case handling: gnu.org/software/gsl/manual/html_node/Power-Function.html –  Rhys Ulerich Apr 14 '10 at 22:29
I wrote a more optimized version of this, freely downloadable here: gist.github.com/3551590 On my machine it was about 2.5x faster. –  orlp Aug 31 '12 at 11:18
@AkhilJain: It's perfectly good C; to make it valid also in Java, replace `while (exp)` and `if (exp & 1)` with `while (exp != 0)` and `if ((exp & 1) != 0)` respectively. –  Ilmari Karonen Apr 8 '13 at 16:38

Note that exponentiation by squaring is not the most optimal method. It is probably the best you can do as a general method that works for all exponent values, but for a specific exponent value there might be a better sequence that needs fewer multiplications.

For instance, if you want to compute x^15, the method of exponentiation by squaring will give you:

``````x^15 = (x^7)*(x^7)*x
x^7 = (x^3)*(x^3)*x
x^3 = x*x*x
``````

This is a total of 6 multiplications.

It turns out this can be done using "just" 5 multiplications.

``````n*n = n^2
n^2*n = n^3
n^3*n^3 = n^6
n^6*n^6 = n^12
n^12*n^3 = n^15
``````

I don't remember the source now, but I vaguely remember that there are no efficient algorithms to find this optimal sequence of multiplications.

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@JeremySalwen: As this answer states, binary exponentiation is not in general the most optimal method. There are no efficient algorithms currently known for finding the minimal sequence of multiplications. –  Eric Postpischil Dec 27 '13 at 21:32
@EricPostpischil, That depends on your application. Usually we don't need a general algorithm to work for all numbers. See The Art of Computer Programming, Vol. 2: Seminumerical Algorithms –  Pacerier Sep 16 '14 at 9:03

Exponentiation by squaring might be worth taking a look at...

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While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. –  ericbn May 4 at 18:12

Here is the method in Java

``````private int ipow(int base, int exp)
{
int result = 1;
while (exp != 0)
{
if ((exp & 1) == 1)
result *= base;
exp >>= 1;
base *= base;
}

return result;
}
``````
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does not work for large numbes e.g pow(71045970,41535484) –  Anushree Acharjee Jul 10 at 5:26
@AnushreeAcharjee of course not. Computing such a number would require arbitrary precision arithmetic. –  David Etler Sep 4 at 21:13

If you need to raise 2 to a power. The fastest way to do so is to bit shift by the power.

``````2 ** 3 == 1 << 3 == 8
2 ** 30 == 1 << 30 == 1073741824 (A Gigabyte)
``````
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Is there an elegant way to do this so that 2 ** 0 == 1 ? –  Rob Smallshire Nov 23 '11 at 21:39
`2 ** 0 == 1 << 0 == 1` –  Jake Dec 30 '11 at 18:22
``````int pow( int base, int exponent)

{   // Does not work for negative exponents. (But that would be leaving the range of int)
if (exponent == 0) return 1;  // base case;
int temp = pow(base, exponent/2);
if (exponent % 2 == 0)
return temp * temp;
else
return (base * temp * temp);
}
``````
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If you're going to downvote, say why. –  Chris Cudmore Nov 14 '14 at 16:31
Not my vote, but `pow(1, -1)` doesn't leave the range of int despite a negative exponent. Now that one works by accident, as does `pow(-1, -1)`. –  MSalters Aug 13 at 9:34

An extremly specialized case is, when you need say 2^(-x to y), where x, is of course is negative and y is too large to do shifting on an int. You can still do 2^x in constant time by screwing with a float.

``````struct IeeeFloat
{

unsigned int base : 23;
unsigned int exponent : 8;
unsigned int signBit : 1;
};

union IeeeFloatUnion
{
IeeeFloat brokenOut;
float f;
};

inline float twoToThe(char exponent)
{
// notice how the range checking is already done on the exponent var
static IeeeFloatUnion u;
u.f = 2.0;
// Change the exponent part of the float
u.brokenOut.exponent += (exponent - 1);
return (u.f);
}
``````

You can get more powers of 2 by using a double as the base type. (Thanks a lot to commenters for helping to square this post away).

There's also the possibility that learning more about Ieee floats, other special cases of exponentiation might present themselves.

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Nifty solution, but unsigend?? –  paxdiablo Sep 19 '08 at 12:37
Yeah, my bad. :) thanks for pointing it out. –  Doug T. Sep 19 '08 at 12:39
An IEEE float is base x 2 ^ exp, changing the exponent value won't lead to anything else than a multiplication by a power of two, and chances are high it will denormalize the float ... your solution is wrong IMHO –  Drealmer Sep 19 '08 at 12:50
*= won't work either, exponent can be null –  Drealmer Sep 19 '08 at 12:55
Base 10? Uh no, it's base 2, unless you meant 10 in binary :) –  Drealmer Sep 19 '08 at 13:02

Just as a follow up to comments on the efficiency of exponentiation by squaring.

The advantage of that approach is that it runs in log(n) time. For example, if you were going to calculate something huge, such as x^1048575 (2^20 - 1), you only have to go thru the loop 20 times, not 1 million+ using the naive approach.

Also, in terms of code complexity, it is simpler than trying to find the most optimal sequence of multiplications, a la Pramod's suggestion.

Edit:

I guess I should clarify before someone tags me for the potential for overflow. This approach assumes that you have some sort of hugeint library.

-

If you want to get the value of an integer for 2 raised to the power of something it is always better to use the shift option:

`pow(2,5)` can be replaced by `1<<5`

This is much more efficient.

-

more generic solution considering negative exponenet

``````private static int pow(int base, int exponent) {

int result = 1;
if (exponent == 0)
return result; // base case;

if (exponent < 0)
return 1 / pow(base, -exponent);
int temp = pow(base, exponent / 2);
if (exponent % 2 == 0)
return temp * temp;
else
return (base * temp * temp);
}
``````
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integer division results in an integer, so your negative exponent could be a lot more efficient since it'll only return 0, 1, or -1... –  jswolf19 Aug 29 '14 at 15:51
`pow(i, INT_MIN)` could be an infinite loop. –  chux Apr 1 at 16:48
@chux: It could format your harddisk: integer overflow is UB. –  MSalters Aug 13 at 9:38
@MSalters `pow(i, INT_MIN)` is not integer overflow. The assignment of that result to `temp` certainly may overflow, potential causing the end of time, but I'll settle for a seemingly random value. :-) –  chux Aug 13 at 14:24

As I recall, math.h contains a pow(x, y) function

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yeah but this one works with doubles –  Drealmer Sep 19 '08 at 12:34

One more implementation (in Java). May not be most efficient solution but # of iterations is same as that of Exponential solution.

``````public static long pow(long base, long exp){
if(exp ==0){
return 1;
}
if(exp ==1){
return base;
}

if(exp % 2 == 0){
long half = pow(base, exp/2);
return half * half;
}else{
long half = pow(base, (exp -1)/2);
return base * half * half;
}
}
``````
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I use recursive, if the exp is even,5^10 =25^5.

``````int pow(float base,float exp){
if (exp==0)return 1;
else if(exp>0&&exp%2==0){
return pow(base*base,exp/2);
}else if (exp>0&&exp%2!=0){
return base*pow(base,exp-1);
}
}
``````
-

Late to the party:

Below is a solution that also deals with `y < 0` as best as it can.

1. It uses a result of `intmax_t` for maximum range. There is no provision for answers that do not fit in `intmax_t`.
2. `powjii(0, 0) --> 1` which is a common result for this case.
3. `pow(0,negative)`, another undefined result, returns `INT_MAX`

``````intmax_t powjii(int x, int y) {
if (y < 0) {
switch (x) {
case 0:
return INTMAX_MAX;
case 1:
return 1;
case -1:
return y % 2 ? -1 : 1;
}
return 0;
}
intmax_t z = 1;
intmax_t base = x;
for (;;) {
if (y & 1) {
z *= base;
}
y >>= 1;
if (y == 0) {
break;
}
base *= base;
}
return z;
}
``````

This code uses a forever loop `for(;;)` to avoid the final `base *= base` common in other looped solutions. That multiplication is 1) not needed and 2) could be `int*int` overflow which is UB.

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I have implemented algorithm that memorizes all computed powers and then uses them when need. So for example x^13 is equal to (x^2)^2^2 * x^2^2 * x where x^2^2 it taken from the table instead of computing it once again. The number of multiplication needed is Ceil(Log n)

``````public static int Power(int base, int exp)
{
int tab[] = new int[exp + 1];
tab[0] = 1;
tab[1] = base;
return Power(base, exp, tab);
}

public static int Power(int base, int exp, int tab[])
{
if(exp == 0) return 1;
if(exp == 1) return base;
int i = 1;
while(i < exp/2)
{
if(tab[2 * i] <= 0)
tab[2 * i] = tab[i] * tab[i];
i = i << 1;
}
if(exp <=  i)
return tab[i];
else return tab[i] * Power(base, exp - i, tab);
}
``````
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Ignoring the special case of 2 raised to a power, the most efficient way is going to be simple iteration.

``````int pow(int base, int pow) {
int res = 1;
for(int i=pow; i<pow; i++)
res *= base;

return res;
}
``````

EDIT: As has been pointed out this is not the most efficient way... so long as you define efficiency as cpu cycles which I guess is fair enough.

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O(N) where O(log N) is possible - see yarrkov –  MSalters Sep 19 '08 at 13:06
This could actually be the most efficient. N can't be arbitrarily large. Its maximum is either 31 or 63 (depending on your int size). Its like how insertion sort beats quicksort for low N. –  paperhorse Sep 27 '08 at 22:01
This code doesn't work as written, i should be initialized to 0 not pow. @paperhorse, N is pow, ie 0 to INT_MAX. –  Greg Rogers Oct 11 '08 at 13:54
i=pow; i<pow; i++, `i` is already intialised to `pow` and then iterating to `pow`, the loop will run only once, you should decrement i. isn't it? –  Akhil Jain Dec 16 '12 at 5:55
@paperhorse: Actually `pow(1, INT_MAX)` is well-defined. –  MSalters Aug 13 at 9:40

## protected by Marco A.Jun 20 at 15:45

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