I'm looking for an algorithm (or better yet, code!) for a the generation of powers, specifically numbers with an odd exponent greater than 1: third powers, fifth powers, seventh powers, and so forth. My desired output is then

```
8, 27, 32, 125, 128, 216, 243, 343, 512, 1000
```

and so forth up to a specified limit.

I don't want to store the powers in a list and sort them, because I'm making too many to fit in memory -- hopefully the limit be 10^{30} or so, corresponding to a memory requirement of ≈ 1 TB.

My basic idea is to have an array holding the current number (starting at 2) for each exponent, starting with 3 and going up to the binary log of the limit. At each step I loop through the exponent array, finding the one which yields the smallest power (finding either pow(base, exponent) or more likely exponent * log(base), probably memoizing these values). At that point call the 'output' function, which will actually do calculations with the number but of course you don't need to worry about that.

Of course because of the range of the numbers involved, bignums must be used -- built into the language, in a library, or self-rolled. Relevant code or code snippets would be appreciated: I feel that this task is similar to some classic problems (e.g., Hamming's problem of generating numbers that are of the form 2^{x}3^{y}5^{z}) and can be solved efficiently. I'm fairly language-agnostic here: all I'll need for my 'output' function are arrays, subtraction, bignum-word comparison, and a bignum integer square root function.

lazylanguage like Haskell to generate infinite sequences? – deceze Jan 27 '11 at 6:12