**EDIT:**

*Goal :*

Generate a ubiquitous method for deriving a custom power function that outperforms the built-in `pow(double, uint)`

by reusing precalculated/cached powers from power calculations on common variables.

*What's already been done:*

I've already derived such a function that's roughly 40% faster than the built-in, however this is a brute-force hand-derived function -- I want a method for autogenerating such a power function block for an arbitrary `uint`

power.

**KNOWNS**

To derive an optimal custom `pow(double, uint)`

you need some knowns. For this question the knowns (to clarify) are:

- The power will be an integer.
- The maximum the power can be is known (
`N_MAX`

). - The precalculated powers that can be (re)used are known
at compile time (e.g. in my example
`r2`

,`r4`

, and`r6`

). - The square
`r2`

can be assumed to always have been calculated regardless of the other precalculated powers.

**SOLUTION REQUIREMENTS**

An optimal solution requiring a separate program to write a `case`

lookup table or preprocessor logic to generate such a table is acceptable, however, non-optimal solutions using hand-generated (i.e. brute force derived) lookup tables using the powers on hand will not be accepted (as I have that already, and show that in my example... the idea is to get away from this).

**POSSIBLE SOLUTION ROUTE**

As a suggestion, you know `N_MAX`

and a set of powers that are precalculated `B`

(`B={2,4,6}`

for my example). You can produce either in a separate program or in the preprocessor a table of all squares of `Sq(Bi, x`

) <= N_MAX`. You can use this to form a basis set`

A`, which you then search somehow to determine the least number of terms that can be summed to produce an arbitrary exponent of`

n>>1`, where`

n<=N_MAX` (the shift is due to that we take care of the odd case by checking the LSB and multiplying by the sqrt(r2)).

**THEORETICAL BACKGROUND**

I believe formally the below method is a modified version of exponentations by squaring:

http://en.wikipedia.org/wiki/Exponentiation_by_squaring

....which takes advantage of the fact that certain lower order powers are already by necessity precalculated, hence it shifts the optimal set of multiplications from a vanilla exponentation by squaring (which I assume `pow(double, int)`

uses).

However there are significant savings by using the stored small power intermediates instead of simple exp. by squares on the `r2`

.

**THEORETICAL PERFORMANCE**

For example, for one set of objects `n=14`

.... in this scenario exp. by powers gives

```
double r4 = Sq(r2), r14=Sq(r4)*r4*r2; //4 op.
```

... which takes **4 FP multiplications**..... but using the `r2`

and `r6`

we have

```
double r14=Sq(r6)*r2; //2 op.
```

.... **2 FP multiplications**.... in other words, by going from "dumb" exponentation by squares to my modified exp. by squares using the common exponent precaching, I've cut my cost of calculations for 50% in terms of multiplications ... at least until memory costs are considered.

**REAL PERFORMANCE**

With my current method (compiled with `gcc -O3`

) I get **35.1 sec.** to run 1 million cycles of my program, versus (w/ no other modifications) **56.6 s** using the built int `pow(double, int)`

.... so almost the theoretical speedup.

At this point you may be scratching your head at how a 50% cut in multiplications on a single instruction line can deliver a ~40% speedup. But basically this line of code is called 1,000+ times per cycle and is by far the most evaluated/most expensive line of code in the entire program. Hence the program appears highly sensitive to a small optimization/improvement in this chunk.

**ORIGINAL POST and EXAMPLE CODE**

I need to replace the `pow(double, int)`

function as I already have calculated a 6th power term and have 2nd, 4th power intermediates saved, all of which can be used to reduce multiplications in the second `pow`

call, which uses the same `double`

base.

More specifically, in my c++ code I have a performance critical calculation snippet of code where I raise the reciprocal of the distance between 3D points to the 6th power and nth power. e.g.:

```
double distSq = CalcDist(p1,p2), r2 = a/distSq, r6 = r2 * r2 * r2;
results += m*(pow(sqrt(r2), n) - r6);
```

Where `m`

and `a`

are constants related to the fitted equation and `n`

is the arbitrary power.

A slightly more efficient form is:

```
double distSq = CalcDist(p1,p2), r2 = a/distSq, r6 = r2 * r2 * r2;
results += m*(pow(r2, n)*(n&0x1?sqrt(r2):1.0) - r6);
```

However, this is also not optimal. What I've found to be significantly faster is to have a custom `pow`

function that uses the multiples r2, r4, and r6, which I have to calculate already anyways for the second term.

e.g.:

```
double distSq = CalcDist(p1,p2), r2 = a/distSq, r4 = r2 * r2, r6 = r4 * r2;
results += m*(POW(r2, r4, r6 n) - r6);
```

Inside the function:

```
double POW(double r2, double r4, double r6, uint n)
{
double results = (n&0x1 : sqrt(r2) : 1.0);
n >>= 1;
switch (n)
{
case 1:
....
case 12:
Sq(Sq(r6));
}
return result;
}
```

The good thing is that my function appears fast in preliminary testing. The bad news is that it's not very ubiquitous and is very long as I need `case`

statements for `int`

powers from `8`

to `50`

or so (potentially even higher in the future). Further each case I had to examine and try different combinations to find by brute force derivation which combination of `r2`

, `r4`

, and `r6`

yielded the least multiplications

Does anyone have a more ubiquitous solution for a `pow(double, int)`

replacement that uses precalculated powers of the base to cut the number of necessary multiplications, and/or have a a ubiquitous theory of how you can determine the ideal combination to produce the least multiplications for an arbitrary `n`

and some set of precalculated multiples??

`int`

exponentation by squaring. The key modification is that you have three power bases -- (x^2), (x^4), and (x^6) that are precalculated and can be combined to produce the fastest result. – Jason R. Mick Sep 22 '13 at 15:22