Given array of N elements. Find number of coprime pairs.
1 <= N <= 30000
1 <= A[i] <= 10^8
TL: 0.6s
ML: 64MB
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Given array of N elements. Find number of coprime pairs.
1 <= N <= 30000
1 <= A[i] <= 10^8
TL: 0.6s
ML: 64MB
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Hmmm, I don't really know. But, I'll let you know as soon as I come up with a solution! (If I come up with one) :D
Preprocess all the primes smaller than 108 by Eratosthenes Sieve.
Now, for all the numbers ai, make a vector of it's prime divisors (not counting the multiplicity). We will actually find the numbers of non-coprime pairs of numbers and subtract it from n * (n - 1) / 2
Suppose that, for some i, we have ai = p1 * p2 * ... * pk. (We, again, disregard multiplicity). Note that the time allows us to go through all subsets of {p1, p2, ..., pk} for all i. Build two maps, cnt[] and sgn[]. cnt[X] tells us how many times subset with product equal to X appears in all elements of array a[], while sgn[X] tells us how many elements the subset has.
And for the finale just use the Inclusion — Exclusion Principle.
Can you please explain the time complexity part? I couldn't understand how the time is sufficient here. Since the primes vector size is ~1200(number of primes in [1,10000]), won't it take time to iterate through all these primes, for every element (n=30000, so 30000*1200 in the worst case), to get its vector of prime divisors? I am not aware of any other optimized approach here to get the vector. Any further explanation regarding what I am missing would be extremely helpful.
Since a[i] <= 10^8 and the smallest prime number is 2.Consider a[i] has some x number of prime factors(including multiplicity) then a[i] >= 2^x. Using a[i] <= 10^8, we can get maximum value of x can be around 25-30 and hence it satisfies the given time constraints.
Got It. Thanks!
Can anyone show the implementation part ?
I am unable to put the Inclusion Exclusion principle with the rest of solution.
Maybe there is another ways, mine is here: (idk is it late to answer)
Time complexity: O(n*2^n)
No, it's not late. Tysm.
I'm the author of this task :) It appeared on the national programming competition in Serbia this year.
Problem 6 (In Serbian)
The intended solution for 100 points is what The_Wolfpack has written, with a small correction — you only need to process primes up to 104.
Hvala obojici :)
Can I get the aforementioned problem in English? I really liked that concept. Thank You very much.
It's identical to the problem posted in the blog: Find the number of pairs i, j (1 ≤ i < j ≤ n) such that gcd(ai, aj) = 1. Constraints are: 1 ≤ N ≤ 30000, 1 ≤ ai ≤ 108. TL = 0.6s. Problem statements are traditionally long and full of unnecessary details and stories.
Can you explain in brief how can we apply inclusion-exclusion after calculating above mentioned things by The_Wolfpack?
If we have stored
X = p1*p2
, then we would also have storedX=p1
andX=p2
in our maps (because we are traversing over all subsets of distinct primes for each element of the array).Now, all those pairs of elements which have either
p1
orp2
orboth p1 and p2
common in their prime factorisation, they can't be co-primes. So, now we can use inclusion-exclusion to find all such pairs.Thank a lot for the info! I was able to solve this codechef problem from your idea. It's not the same but asks us to find the number of triplets.
But there is one mistake in your code. We subtract toRemove if x is odd and add when it's even.
Umm, why do we have to subtract toRemove if x is odd? The code just implements the Incl-Excl directly.
Btw, this cses problem also uses this same idea
can you tell that 'small correction' so that we only need to process upto $$$10^4$$$. I mean let's say I have number whose prime divisor are >$$$10^4$$$ then how we can check it?
if there are any prime divisors which are greater than $$$10^4$$$ then the quotient will be obviously less than $$$10^4$$$. And the quotient will have prime factors which are already calculated. So you just divide the number again and again by those prime factors. If you end up with a number greater than 1 then that is also a prime factor.
I think that there exist a simpler solution, which allow us to calculate this value straightforwardly.
We want to maintain array $$$DP[x]$$$ — number of pairs $$$(a, b)$$$, that $$$GCD(a, b) = x$$$.
Let's iterate over all possible results of $$$GCD$$$ starting from the greatest element in array (lets call it $$$M$$$).
To count $$$DP[x]$$$ we only have to consider elements of array that are multiple of $$$x$$$. If $$$f(x)$$$ is the number of all pairs we can obtain from the set of $$$x$$$ elements, and $$$q(x)$$$ is number of elements that are multiple of $$$x$$$, then
The result is of course
Overall complexity:
It's simpler but unfortunately it won't work here because $$$M = 10^8$$$.
I think you can calculate the number of coprimes to n aka ϕ(n)
we can calculate ϕ(1 -> n) in O(n log log n)
After that we just need to calculate the sum of ϕ(1) + ϕ(2) + ... + ϕ(n)
If you need to solve for queies. Using prefix sum array can help you answer the problem in O(1) after O(n log log n) precalculating
I think you should read the problem again carefully, particularly this comment
I think the problem asking about find number of pair(i, j) where 1 ≤ i, j ≤ n and gcd(i, j) = 1.
So I calculate ϕ(j) for every 1 ≤ j ≤ n. Then I will know the number i in range [1..j] that gcd(i, j) = 1
Then I calculate the sum of all ϕ(j) in range [1..n].
Is my approach correct problemsetter ?
Ah, number of pair(ai, aj). Sorry for my reading the problem carelessly
So how about this new approach
For each pair (i, j) that 1 ≤ i ≤ j ≤ n
I increase the result whenever gcd(ai, aj) = 1
Time Complexity: O(n ^ 2 log (n ^ 2))
2 numbers are co-prime if their SPFs are different.
Preprocess all the SPFs and then store the SPFs of the numbers in the array in map.
Now you will have the numbers whose SPFs is the same.
Let ans = n*(n+1)/2 (n = size of the array), now you could iterate through the map and subtract the sizeofmapC2 from the answer.
Edit: the above idea of 2 numbers being co-prime is just an observation. Point it if i'm wrong
False: 10, 15
What the hell is SPF? Googling doesn't give much after filtering out sunscreen and sender policy framework.
smallest prime factor