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By awoo, history, 3 years ago, translation, In English

1626A - Equidistant Letters

Idea: BledDest

Tutorial
Solution (awoo)

1626B - Minor Reduction

Idea: BledDest

Tutorial
Solution (awoo)

1626C - Monsters And Spells

Idea: BledDest

Tutorial
Solution (awoo)

1626D - Martial Arts Tournament

Idea: BledDest

Tutorial
Solution (awoo)

1626E - Black and White Tree

Idea: BledDest

Tutorial
Solution (BledDest)

1626F - A Random Code Problem

Idea: BledDest

Tutorial
Solution (BledDest)
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3 years ago, # |
  Vote: I like it +16 Vote: I do not like it

it was a really cool round! it's a pity that he was unrated :(

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3 years ago, # |
  Vote: I like it +4 Vote: I do not like it

For problem C, you don't have to worry about half-intervals. Here is my (badly written) code for C with segments that can be of length 0.

143049989

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3 years ago, # |
  Vote: I like it -6 Vote: I do not like it

Can anybody please tell me how this code is working for problem D : 143147171.

Is this logic correct or are the test cases weak?

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    3 years ago, # ^ |
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    I suppose the logic is correct. It uses a greedy approach as mentioned in the editorial. The fact that lengths can only be the power of 2 is used to reduce the time complexity of nested loops.

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3 years ago, # |
  Vote: I like it +17 Vote: I do not like it

Same solution of B, but with regex (with code pattern): Perl — 143030768, (13+).

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3 years ago, # |
  Vote: I like it +7 Vote: I do not like it

Can somebody please explain me how Binary search is applied on problem D????

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3 years ago, # |
  Vote: I like it +26 Vote: I do not like it

C can be solved in $$$O(n)$$$, walking though array backwards or using stack.

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    3 years ago, # ^ |
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    Also using two pointers can achieve %O(n)%

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3 years ago, # |
  Vote: I like it +30 Vote: I do not like it

D can be solved in $$$O(n)$$$. the submission.

The steps of the algorithm is:

  1. Calculate if we want to choose at most $$$i$$$ smallest numbers, how many numbers can we choose.

  2. Calculate if we want to choose at most $$$i$$$ largest numbers, how many numbers can we choose.

  3. Go through $$$i,j$$$ in the powers of two. $$$i$$$ means the number of the first division after inviting extra participants. $$$j$$$ means the number in the third division. Then we can know how many original participants will be in the second division. So it's easy to find the number of participants in the second division. For every $$$i,j$$$, we choose the smallest sum of three divivions, and minus it with $$$n$$$. It will be the answer.

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    3 years ago, # ^ |
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    what about the case when i smallest numbers and j largest numbers are not disjoint there is some overlap ?

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    3 years ago, # ^ |
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    For example: n=2 a={1,2}. Let i=1 and j=1, which means there is one person in the left segment while one person in the right segment. However there is no way to add another person to the middle segment since there is no integer between 1 and 2. In short, your code gives the right answer in a wrong way.

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3 years ago, # |
  Vote: I like it +3 Vote: I do not like it

In Problem D,

I am not getting why the length of the middle segment should be power of 2 for the optimal solution.

Can someone help?

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    3 years ago, # ^ |
      Vote: I like it +8 Vote: I do not like it

    I also don't understand this

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    3 years ago, # ^ |
      Vote: I like it +8 Vote: I do not like it

    It's not the middle segment that should be a power of $$$2$$$. We iterate on the size of the middleweight category, which has to be a power of $$$2$$$.

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3 years ago, # |
  Vote: I like it +10 Vote: I do not like it

Can anyone please explain C in further depth, I'm unable to understand

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    3 years ago, # ^ |
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    Example
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3 years ago, # |
Rev. 2   Vote: I like it 0 Vote: I do not like it

I have a little problem about problem F: Why should we add $$$k\cdot n^{k-1}\cdot x\cdot L$$$ to the answer instead of $$$n^k\cdot x\cdot L$$$?

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    3 years ago, # ^ |
      Vote: I like it +5 Vote: I do not like it

    The multiplier $$$k \cdot n^{k-1}$$$ is the total number of times an element is chosen over all ways to choose elements on the iterations. It can be treated as the number of occurrences of some integer $$$i$$$ in all $$$k$$$-element vectors, where each element is in $$$[1, n]$$$. It is $$$k \cdot n^{k-1}$$$ since the total number of integers in these vectors is $$$k \cdot n^k$$$, and each of $$$n$$$ integers occurs the same number of times.

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3 years ago, # |
Rev. 2   Vote: I like it 0 Vote: I do not like it

Can someone please explain for Problem E, I tried this test case - for the solution mentioned in editorial

input —

13
1 0 0 0 0 0 0 0 1 0 0 0 1
1 2
2 3
3 4
4 5
5 6
6 7
7 8
8 9

the output is —

1 1 1 1 1 1 1 1 1 0 0 0 1 

As per my understanding, according to the problem st. shouldn't it be, only black nodes and the ones adjacent to it, i.e. 1, 13, 9, 2, 12, 8

1 1 0 0 0 0 0 1 1 0 0 1 1

Can someone explain this?

Upd: Sorry I gave wrong input.

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    3 years ago, # ^ |
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    It doesn't have to be only black nodes and the ones adjacent to it. Consider an edge which links two white nodes. If the number of black nodes on the left side of this edge (in the entire tree) are 2 or more, then we can go from right to left along this edge, and similarly for left to right. The adjacent-black-node condition is only needed when the number of black nodes on one side of an edge are less than two.

    Example: If your tree is 1-2-3-4-5 and 1,2 are black nodes. Then from 5 you can select 1 and move the chip to 4. Then you can select 2 and move the chip to 3, and so on. So, whenever you have 2 or more black nodes on one side of the edge, you won't get forced back as you move along the edge in that direction.

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      3 years ago, # ^ |
        Vote: I like it 0 Vote: I do not like it

      Got it, thanks for the explanation!

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3 years ago, # |
Rev. 2   Vote: I like it +1 Vote: I do not like it

Problem C is a lot simpler using stack, when we introduce a new segment, we pop the stack for the segments that were overlapping, then in the end answer is simply derived from the segments left in stack as they are all non overlapping.

Here is my code for the same 143004113

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3 years ago, # |
  Vote: I like it +11 Vote: I do not like it

In Problem D, I ran 3 nested loops i, j, k for the power of 2 the first second and third segment needs to be, and checked if it was possible to divide the array into these groups, if it was possible, simple store the minimum for every iteration of i, j, k. answer in any iteration will be 2^i+2^j+2^k-n.

Here is my code for the same 143024306

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    3 years ago, # ^ |
      Vote: I like it +3 Vote: I do not like it

    got the same idea as you!

    it's cool to solve it in $$$O(n + \log^4 n)$$$ instead of $$$O(n \log n)$$$

    can even solve in $$$O(n + \log^3 n)$$$ after some optimization

    143025919

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3 years ago, # |
  Vote: I like it -19 Vote: I do not like it

question statement of problem B says "You are given a decimal representation of an integer x". Initially, I didn't get that the input in problem B is a string or an integer....?

firstly, I have tried my solution with an integer and got runtime error in test case 3 and later have tried with a string as input and my solution got accepted.

Moral: a decimal representation of an integer x is a String.

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    3 years ago, # ^ |
      Vote: I like it +9 Vote: I do not like it

    Correct Moral: read constraints carefully next time.

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3 years ago, # |
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C has a tag of binary search, can someone please share/explain a binary search based solution if they have implemented it?

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3 years ago, # |
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E.

Another solution and explanation of E.
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3 years ago, # |
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Problem E was not that tough, I have solved it with in out dp; Solution link

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3 years ago, # |
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Problem C can be solved with $$$\mathcal O(n)$$$.

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3 years ago, # |
Rev. 6   Vote: I like it 0 Vote: I do not like it

Hi everyone, I want to share my solution for C which is $$$O(n)$$$.

Here is my submission:144945360.

Spoiler
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2 years ago, # |
Rev. 4   Vote: I like it 0 Vote: I do not like it

It’s interesting to notice that in D’s solution the while loop has the condition of “mid <= n” instead of “len1 + mid <= n”. Actually I can prove “len1 + mid / 2 <= n” will not miss cases but cannot prove the other two condition’s correctness.

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22 months ago, # |
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D can be solved with dp + segment tree in $$$O(nlog^2 n)$$$.

Here
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20 months ago, # |
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Dumb rerooting solution for problem E: link .

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14 months ago, # |
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In problem E if there were 3 black vertices why shouldn't the answer be 1 for all vertices