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Justice
Time Limit: 7000/4000 MS (Java/Others) Memory Limit: 262144/262144 K (Java/Others)Total Submission(s): 4856 Accepted Submission(s): 1281
Special Judge
Problem Description
Put simply, the Justice card represents justice, fairness, truth and the law. You are being called to account for your actions and will be judged accordingly. If you have acted in a way that is in alignment with your Higher Self and for the greater good of others, you have nothing to worry about. However, if you have
acted in a way that is out of alignment, you will be called out and required to own up to your actions. If this has you shaking in your boots, know that the Justice card isn’t as black and white as you may think.
On the table there are n weights. On the body of the i-th weight carved a positive integer $k_i$ , indicating that its weight is $\frac{1}{2^{k_i}}$ gram. Is it possible to divide the n weights into two groups and make sure that the sum of the weights in each group is greater or equal to $\frac{1}{2}$ gram? That’s on your call. And please tell us how if possible.
acted in a way that is out of alignment, you will be called out and required to own up to your actions. If this has you shaking in your boots, know that the Justice card isn’t as black and white as you may think.
On the table there are n weights. On the body of the i-th weight carved a positive integer $k_i$ , indicating that its weight is $\frac{1}{2^{k_i}}$ gram. Is it possible to divide the n weights into two groups and make sure that the sum of the weights in each group is greater or equal to $\frac{1}{2}$ gram? That’s on your call. And please tell us how if possible.
Input
In the first line of the input there is a positive integer $T$ (1 ≤ $T$ ≤ 2000), indicating there are $T$ testcases.
In the first line of each of the $T$ testcases, there is a positive integer $n$ (1 ≤ $n$ ≤ $10^5$, ∑n ≤ 7 × $10^5$), indicating there are $n$ weights on the table.
In the next line, there are $n$ integers $k_i$ (1 ≤ ki ≤ $10^9$), indicating the number carved on each weight.
In the first line of each of the $T$ testcases, there is a positive integer $n$ (1 ≤ $n$ ≤ $10^5$, ∑n ≤ 7 × $10^5$), indicating there are $n$ weights on the table.
In the next line, there are $n$ integers $k_i$ (1 ≤ ki ≤ $10^9$), indicating the number carved on each weight.
Output
For each testcase, first print Case $i$: ANSWER in one line, $i$ indicating the case number starting from $1$ and ANSWER should be either YES or NO, indicating whether or not it is possible to divide the weights. Pay attention to the space between : and ANSWER.
If it’s possible, you should continue to output the dividing solution by print a 0/1 string of length $n$ in the next line. The $i$-th character in the string indicating whether you choose to put the i-th weight in group 0 or group 1.
If it’s possible, you should continue to output the dividing solution by print a 0/1 string of length $n$ in the next line. The $i$-th character in the string indicating whether you choose to put the i-th weight in group 0 or group 1.
Sample Input
3 3 2 2 2 3 2 2 1 2 1 1
Sample Output
Case 1: NO Case 2: YES 001 Case 3: YES 10
Source
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