# Reducing Integer Fractions Algorithm

(This is derived from a recently completed programming competition)

You are given two arrays of 10^5 ints in the range 1..10^7 inclusive:

``````int N[100000] = { ... }
int D[100000] = { ... }
``````

Imagine the rational number X be the result of multiplying together all the elements of N and dividing by all the elements of D.

Modify the two arrays without changing the value of X (and without assigning any element out of range) such that the product of N and the product of D have no common factor.

A naive solution (I think) would work would be...

``````for (int i = 0; i < 100000; i++)
for (int j = 0; j < 100000; j++)
{
int k = gcd(N[i], D[j]); // euclids algorithm

N[i] /= k;
D[j] /= k;
}
``````

...but this is too slow.

What is a solution that takes less than around 10^9 operations?

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Not sure why you posted a question with a link to the answer. –  Raymond Chen Sep 10 '12 at 21:44
@RaymondChen: I didn't have the solution code when I posted the question, and I didn't understand the solution code when I got it, so posted separate question for explanation and interlinked them. –  Andrew Tomazos Sep 10 '12 at 21:52
Which contest did it appear in? –  nibot Oct 3 '12 at 20:48
Can't remember, either CodeForces or CodeChef. –  Andrew Tomazos Oct 4 '12 at 8:47

Factorise all numbers in the range 1 to 107. Using a modification of a Sieve of Eratosthenes, you can factorise all numbers from 1 to `n` in `O(n*log n)` time (I think it's a bit better, `O(n*(log log n)²)` or so) using `O(n*log log n)` space. Better than that is probably creating an array of just the smallest prime factors.

``````// Not very optimised, one could easily leave out the even numbers, or also the multiples of 3
// to reduce space usage and computation time
int *spf_sieve = malloc((limit+1)*sizeof *spf_sieve);
int root = (int)sqrt(limit);
for(i = 1; i <= limit; ++i) {
spf_sieve[i] = i;
}
for(i = 4; i <= limit; i += 2) {
spf_sieve[i] = 2;
}
for(i = 3; i <= root; i += 2) {
if(spf_sieve[i] == i) {
for(j = i*i, step = 2*i; j <= limit; j += step) {
if (spf_sieve[j] == j) {
spf_sieve[j] = i;
}
}
}
}
``````

To factorise a number `n > 1` using that sieve, look up its smallest prime factor `p`, determine its multiplicity in the factorisation of `n` (either by looking up recursively, or by simply dividing until `p` doesn't evenly divide the remaining cofactor, which is faster depends) and the cofactor. While the cofactor is larger than 1, look up the next prime factor and repeat.

Create a map from primes to integers

Go through both arrays, for each number in `N`, add the exponent of each prime in its factorisation to the value in the map, for the numbers in `D`, subtract.

Go through the map, if the exponent of the prime is positive, enter `p^exponent` to the array `N` (you may need to split that across several indices if the exponent is too large, and for small values, combine several primes into one entry - there are 664579 primes less than 107, so the 100,000 slots in the arrays may not be enough to store each appearing prime with the correct power), if the exponent is negative, do the same with the `D` array, if it's 0, ignore that prime.

Any unused slots in `N` or `D` are then set to 1.

-
I know how to use Sieve to find prime numbers but how do you use it to find prime factorizations? Do you have a web reference? –  Andrew Tomazos Sep 10 '12 at 19:41
Instead of just marking whether a number is composite or not, you record the prime divisors. Actually, it just occurred to me, it's probably better - and easier - to just record the smallest prime factor of each number, you can then use that to recursively factor the numbers in both arrays. Web reference, I have none offhand, except perhaps I can link to a Haskell implementation of such a smallest prime factor sieve. –  Daniel Fischer Sep 10 '12 at 19:48
Finding prime factorizations (or bypassing that operation) is where the real challenge of the problem is. I don't think it's a good thing to handwave. –  Thom Smith Sep 10 '12 at 19:49
I recently discussed sieving for the least prime factor of each of a range of numbers at programmingpraxis.com/2012/05/08/factor-tables. –  user448810 Sep 10 '12 at 21:15
@DanielFischer: See here: stackoverflow.com/questions/12359785/… –  Andrew Tomazos Sep 10 '12 at 21:37
show 1 more comment

Almost everything has been written, i would suggest let p=(multiplication of all the elements in N)
let q=(multiplication of all elements in D)
X=(p/q); should be constant always
find prime factors of p,q;
by possibly storing thier power in a matrix a[0](power of 2),a[1] (power of 3),a[2](power of 5) and so on. now you can compare the values in the matrix and decrease power of the lower one to zero.
eg. p=1280 q=720
for p a[0]=8(power of 2) a[1]=0(power of 3) a[2]=1(power of 5);
for q b[0]=4 b[1]=2 b[2]=1;

make one/both(in case both are equal) value/s zero for index 0,1,2.......

-

Lets prime factorize every element in N & D in O(sqrt(10^7) * 10^5) as

``````N[i]=p1^kn1 * p2^kn2 ...
D[i]=p1^kd1 * p2^kd2 ...
``````

Maintain 2 Power arrays where

``````Power_N[p1]=sum of kn1 for all i's
Power_D[p1]=sum of kd1 for all i's

Divide the N and D by p1^(min(Power_N[p1],Power_D[p2])) in O(10^5) each
``````
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The `O` notation feels quite weird here. Was it intended to compensate rounding down of 3162 to 1000? –  Jirka Hanika Sep 10 '12 at 19:40
Yes. More precisely it should be O(sqrt(10^7)*10^5) as you have pointed out. –  Sajal Jain Sep 10 '12 at 19:50
As long as there is no `O` notation in the question, you can not meaningfully afford it in the answer. Besides, the whole input is constant size, therefore the whole computation is necessarily constant time, in other words, `O(1)` operations, without even thinking too much about the task to be solved, or about the exact input size; as long as it is constant. –  Jirka Hanika Sep 10 '12 at 19:59

Factorize each element of either array, sort, cancel. Factorization is constant time for ints of bounded size, sorting is n log n, and cancellation will be linear. The constant factors may be large, though.

If you're trying for lower actual execution time instead of lower asymptotic complexity, it probably wouldn't hurt to preprocess the arrays by manually cancelling small factors, such as powers of 2, 3, 5, and 7. With high probability (i.e. except for pathological inputs), this will speed up most algorithms immensely, at the cost of a few linear-time passes.

One more sophisticated method, integrating the above approaches, would be to start by building a list of primes up to `sqrt(10^7) ~= 3162`. There should be about `3162/ln(3162) ~= 392` such primes, by the prime number theorem. (In fact, to save running time, you could/should precompute this table.)

Then, for each such integer in `N`, and for each prime, reduce the integer by that prime until it no longer divides evenly, and each time increment a count for that prime. Do the same for `D`, decrementing instead. Once you've gone through the table of primes, the current int will be non-1 if and only if it is a prime larger than 3162. This should be about 7% of the total integers in each array. You can keep these in a heap or somesuch. Set them to ones in the array as well, as you go along.

Finally, you iterate over the positive factors and put their product into N. You will probably need to split this across multiple array slots, which is fine. Put the negative factors into D, and you're done!

The runtime on this will take me a minute to work out. Hopefully, it's reasonable.

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