#描述#
A problem that is simple to solve in one dimension is often much more difficult to solve in more than one dimension. Consider satisfying a boolean expression in conjunctive normal form in which each conjunct consists of exactly 3 disjuncts. This problem (3-SAT) is NP-complete. The problem 2-SAT is solved quite efficiently, however. In contrast, some problems belong to the same complexity class regardless of the dimensionality of the problem. <br>
Given a 2-dimensional array of positive and negative integers, find the sub-rectangle with the largest sum. The sum of a rectangle is the sum of all the elements in that rectangle. In this problem the sub-rectangle with the largest sum is referred to as the maximal sub-rectangle. A sub-rectangle is any contiguous sub-array of size 1×1 or greater located within the whole array. As an example, the maximal sub-rectangle of the array: <br>
<pre>
0 –2 –7 0
9 2 –6 2
-4 1 –4 1
-1 8 0 –2</pre>
is in the lower-left-hand corner: <pre>
9 2
-4 1
-1 8</pre>
and has the sum of 15.

#格式#
##输入格式##
The input consists of an N×N array of integers. The input begins with a single positive integer N on a line by itself indicating the size of the square two dimensional array. This is followed by N^2 integers separated by white-space (newlines and spaces). These N^2 integers make up the array in row-major order (i.e., all numbers on the first row, left-to-right, then all numbers on the second row, left-to-right, etc.). N may be as large as 100. The numbers in the array will be in the range [-127, 127].

##输出格式##
The output is the sum of the maximal sub-rectangle.

#样例1#
##样例输入1##

4
0 -2 -7  0 9  2 -6  2
-4  1 -4  1 -1
8  0 -2

##样例输出1##

15

#限制#
1000ms
32768KB

#提示#

#来源#