You will need some inner-looping to remove all powers of each factor.

Some issues with factor checking

- The power of 2 removal only removes the first of potentially many powers of 2 in the factorization.
- So does the
`do i`

loop (which is really the `factor`

).
- The
`do i`

iterates by 1, which means you are checking even numbers. This does not need to be done after removing the 2 factors -- `do i=3 to a by 2 …`

would be better
- the upper limit of a numbers prime factor is sqrt(number)
- if you don't want to compute sqrt, you can use number/2
- regardless of the
`to`

you will be exiting the factorization loop when the number is reduced to 1, so `to a`

is ok.
- a smarter 'solver' will track dynamically known primes and test only those. If complete factorization is not achieved after checking the last known prime, you have to advance by 2

It makes sense to use variable names that correspond to their role in the solution -- so instead of `i`

consider using `factor`

. Certainly for personal code, you can use what names you want, but for code that will be maintained by you or others in the future the best practice is good variable names.

In SAS, instead of hard-coding a single test value at the top of the DTA step, consider processing (prime factorizing) any number of numbers that are contained in a data set.

Looping in SAS is done with a variety of `do`

code constructs

`do … while(condition); …iterated-statements… end;`

- 0 or more loops - condition test is done before doing any iterate-statements

`do … until(condition); … end;`

- 1 or more loops - condition test is done after doing iterated-statements

`do index=from-value to to-value by by-value; … end;`

- index varies by equal steps and can be used as part of iterated-statements
- to-value is computed once and can not be changed by the iterated-statements
`while`

or `until`

can be tacked onto `do index=`

statement
- to-value is optional, however will endless loop unless
`while`

or `until`

is present, or at least one of the iterated-statements performs a `leave`

statement

which you choose depends on the problem.

**Make a data set of numbers to process**

```
data numbers; input number; format number 16.; datalines;
64
720
30
600851475143
8462696833
10086647
6857
run;
```

**Sample code**

Inner-looping is used to remove factors that occur more than once.

Changed: Inner-inner looping (= -1, 1) is used to apply 6n+/-1 is may well be prime theorem to select possible factors.

```
data prime_factorizations(keep=number factor power);
set numbers;
objective = floor(abs(number));
factor = 2;
do power = 0 by 1 while (mod(objective,factor) = 0);
objective = objective / factor;
end;
if power then output;
factor = 3;
do power = 0 by 1 while (mod(objective,factor) = 0);
objective = objective / factor;
end;
if power then output;
* after 2 and 3 all primes are of form 6n +/- 1;
* however, not all 6n +/- 1 are prime;
* in essence operate a sieve to check for factors;
* of course the best sieve is a list of primes,
* but 6n +/- 1 knocks out a lot of unnecessary checks;
do n = 1 to objective while (objective > 1);
do offset = -1, 1;
factor = 6*n + offset;
do power = 0 by 1 while (mod(objective,factor) = 0);
objective = objective / factor;
end;
if power then OUTPUT;
if objective = 1 then leave;
end;
end;
run;
title "Prime factorization of some numbers";
proc print noobs data=prime_factorizations;
run;
proc sql;
title "Max prime factor of various numbers";
select number, max(factor) as max_prime_factor
from prime_factorizations group by number;
quit;
title;
```

Of course this is not how actual large prime number seekers operate, but is a good introduction to programming in any given language. Back in CS "survey of languages" I would try to code the above in the new language being learned.