Go, Gopher! Interactive 컴파일 명령
시간 제한 | 메모리 제한 | 제출 횟수 | 통과한 사람 수 | 비율 |
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10000 ms | 1024 MiB | 51 | 17 | 33.33% |
The Code Jam team has just purchased an orchard that is a two-dimensional matrix of cells of unprepared soil, with 1000 rows and 1000 columns. We plan to use this orchard to grow a variety of trees — AVL, binary, red-black, splay, and so on — so we need to prepare some of the cells by digging holes:
- In order to have enough trees to use for each year's tree problems, we need there to be at least $A$ prepared cells.
- In order to care for our trees properly, the set of all prepared cells must form a single grid-aligned rectangle in which every cell within the rectangle is prepared.
Note that the above also implies that none of the cells outside of that rectangle can be prepared. We want the orchard to look tidy!
For example, when $A=11$, although the eleven prepared cells in the left figure below form a 3x4 rectangle (that is, with 3 rows and 4 columns), the cell in the center of the rectangle is not prepared. As a result, we have not yet completed preparing our orchard, since not every cell of the 3x4 rectangle is prepared. However, after just preparing the center cell, the rectangle of size at least 11 is fully filled, and the orchard is ready.
See below for another example. In this case, $A=6$. Note that the middle figure prepares a cell outside the 3x2 rectangle, so although the rightmost figure prepares a rectangle of size 6, the entire set of the prepared cells does not form a rectangle (due to the extra cell on the left). As a result, the orchard is not ready.
Digging is hard work for humans, so we have borrowed the Go gopher from the Google Go team and trained it to help us out by preparing cells. We can deploy the gopher by giving it the coordinates of a target cell in the matrix that is not along any of the borders of the matrix. However, we have not yet perfected the gopher's training, so it will choose a cell uniformly at (pseudo-)random from the 3x3 block of nine cells centered on the target cell, and then prepare the cell it has chosen. (If it chooses a cell that was already prepared, it will uselessly prepare it again.)
We can only deploy the gopher up to 1000 times before it gets too tired to keep digging, so we need your help in figuring out how to deploy it strategically. When you deploy the gopher, you will be told which cell the gopher actually prepared, and you can take this information into account before deploying it again, if needed. Note that you do not have to declare the dimensions or location of a rectangle in advance.
Input and output
This problem is interactive, which means that the concepts of input and output are different than in standard Code Jam problems. You will interact with a separate process that both provides you with information and evaluates your responses. All information comes into your program via standard input; anything that you need to communicate should be sent via standard output. Remember that many programming languages buffer the output by default, so make sure your output actually goes out (for instance, by flushing the buffer) before blocking to wait for a response. See the FAQ for an explanation of what it means to flush the buffer. Anything your program sends through standard error is ignored, but it might consume some memory and be counted against your memory limit, so do not overflow it. To help you debug, a local testing tool script (in Python) is provided at the very end of the problem statement. In addition, sample solutions to a previous Code Jam interactive problem (in all of our supported languages) are provided here.
Initially, your program should read a single line containing a single integer $T$ indicating the number of test cases. Then, you need to process $T$ test cases.
For each test case, your program will read a single line containing a single integer $A$ indicating the minimum required prepared rectangular area. Then, your program will process up to 1000 exchanges with our judge.
For each exchange, your program needs to use standard output to send a single line containing two integers $I$ and $J$: the row and column number you want to deploy the gopher to. The two integers must be between 2 and 999, and written in base-10 without leading zeroes. If your output format is wrong (e.g., out of bounds values), your program will fail, and the judge will send you a single line with -1 -1 which signals that your test has failed, and it will not send anything to your input stream after that. Otherwise, in response to your deployment, the judge will print a single line containing two integers $I'$ and $J'$ to your input stream, which your program must read through standard input.
If the last deployment caused the set of prepared cells to be a rectangle of area at least $A$, you will get $I' = J' = 0$, signaling the end of the test case. Otherwise, $I'$ and $J'$ are the row and column numbers of the cell that was actually prepared by the gopher, with $\texttt{abs}(I'-I) \le 1$ and $\texttt{abs}(J'-J) \le 1$. Then, you can start another exchange.
If your program gets something wrong (e.g. wrong output format, or out-of-bounds values), as mentioned above, the judge will send $I' = J' = -1$, and stop sending output to your input stream afterwards. If your program continues to wait for the judge after reading in $I' = J' = -1$, your program will time out, resulting in a Time Limit Exceeded error. Notice that it is your responsibility to have your program exit in time to receive the appropriate verdict (Wrong Answer, Runtime Error, etc.) instead of a Time Limit Exceeded error. As usual, if the total time or memory is exceeded, or your program gets a runtime error, you will receive the appropriate verdict.
Limits
- $1 \le T \le 20$.
- Memory limit: 1 GB.
- Time limit: 10 seconds (different from the original!)
Test set 1 [10 points]
- $A = 20$.
Test set 2 [20 points]
- $A = 200$.
Sample interaction
t = readline_int() // reads 2 into t a = readline_int() // reads 3 into a printline 10 10 to stdout // sends out cell 10 10 to prepare flush stdout x, y = readline_two_int() // reads 10 11, since cell 10 11 is prepared printline 10 10 to stdout // sends out cell 10 10 again to prepare flush stdout x, y = readline_two_int() // reads 10 10, since cell 10 10 is prepared printline 10 12 to stdout // sends out cell 10 12 to prepare flush stdout x, y = readline_two_int() // reads 10 11, since cell 10 11 is prepared again printline 10 10 to stdout // sends out cell 10 10 to prepare flush stdout x, y = readline_two_int() // reads 11 10, since cell 11 10 is prepared printline 11 10 to stdout // sends out cell 11 10 to prepare flush stdout x, y = readline_two_int() // reads 0 0; since cell 11 11 is prepared, a rectangle of size 4
The pseudocode above is the first half of a sample interaction for one test set. Suppose there are only two test cases in this test set. The pseudocode first reads the number of test cases into an integer t. Then the first test case begins. For the first test case, suppose A is 3 (although, in the real test sets, A is always either 20 or 200). The pseudocode first reads the value of A into an integer a, and outputs 10 10 the location of the cell to prepare. By (pseudo-)random choice, the cell at location 10 11 is prepared, so the code reads 10 11 in response. Next, the code outputs cell 10 10 again for preparation, and the gopher prepares 10 10 this time. The code subsequently sends 10 12 with the goal of finishing preparing a rectangle of size 3, but only gets cell 10 11 prepared again. 10 10 is then sent out, and this time 11 10 is prepared. Notice that although the prepared area is of size 3, a rectangle has not been formed, so the preparation goes on. In the end, the pseudocode decides to try out cell 11 10, and 0 0 is sent back, which implies that cell 11 11 has been prepared, completing a rectangle (or square, rather) or size 4. As a result, the first test case is successfully solved.
a = readline_int() // reads 3 into a printline 10 10 to stdout // sends out cell 10 10 to prepare x, y = readline_two_int() // does not flush stdout; hangs on the judge
Now the pseudocode is ready for the second test case. It again first reads an integer a = 3 and decides to send cell 10 10 to prepare. However, this time, the code forgets to flush the stdout buffer! As a result, 10 10 is buffered and not sent to the judge. Both the judge and the code wait on each other, leading to a deadlock and eventually a Time Limit Exceeded error.
a = readline_int() // reads 3 into a printline 1 1 to stdout // sends out cell 1 1 to prepare x, y = readline_two_int() // reads -1 -1, since 1 is outside the range [2, 999] printline 10 10 to stdout // sends a cell location anyway x, y = readline_two_int() // hangs since the judge stops sending info to stdin
The code above is another example. Suppose for the second test case, the code remembers to flush the output buffer, but sends out cell 1 1 to prepare. Remember that the row and column of the chosen cell must both be in the range [2, 999], so 1 1 is illegal! As a result, the judge sends back -1 -1. However, after reading -1 -1 into x and y, the code proceeds to send another cell location to the judge, and wait. Since there is nothing in the input stream (the judge has stopped sending info), the code hangs and will eventually receive a Time Limit Exceeded error.
Note that if the code in the example above exits immediately after reading -1 -1, it will receive a Wrong Answer instead:
a = readline_int() // reads 3 into a printline 1 1 to stdout // sends out cell 1 1 to prepare x, y = readline_two_int() // reads -1 -1, since 1 is outside the range [2, 999] exit // receives a Wrong Answer judgment
Local Testing Tool
To better facilitate local testing, we (Google) provide you the following script. Instructions are included inside. You are encouraged to add more test cases for better testing. Please be advised that although the testing tool is intended to simulate the judging system, it is NOT the real judging system and might behave differently.
If your code passes the testing tool but fails the real judge, please check here to make sure that you are using the same compiler as us.
파일명 | 파일 크기 |
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testing_tool.py | 7.4 KiB |