Joy is about to go on a long vacation, so she has hired technicians to install a security system based on infrared laser beams. The technicians have given her a diagram that represents her house as a grid of unit cells with R rows and C columns. Each cell in this grid contains one of the following:
/
: A twosided mirror that runs from the cell's lower left
corner to its upper right corner.\
: A twosided mirror that runs from the cell's upper left
corner to its lower right corner.
: A beam shooter that shoots horizontal beams out into the
cells (if any) to the immediate left and right of this cell.
: A beam shooter that shoots vertical beams out into the
cells (if any) immediately above and below this cell.#
: A wall. (Note that the house is not necessarily
surrounded by a border of walls; this is one reason why Joy needs a
security system!).
: Nothing; the cell is empty.
Beams travel in straight lines and continue on through empty cells. When a
beam hits a mirror, it bounces 90 degrees off the mirror's surface and
continues. When a beam traveling to the right hits a /
mirror,
it bounces off the mirror and starts traveling up; beams traveling up, left,
or down that hit a /
mirror bounce off and travel right, down,
or left, respectively. The \
mirror behaves similarly: when a
beam traveling right, up, left or down hits it, it bounces off and starts
traveling down, left, up or right, respectively. When a beam hits a wall or
goes out of the bounds of the grid, it stops. It is fine for beams to cross
other beams, but if a beam hits any beam shooter (including, perhaps, the
beam shooter that originated the beam), that beam shooter will be destroyed!
Joy wants to make sure that every empty cell in the house has at least one
beam passing through it, and that no beam shooters are destroyed, since that
would just be wasting money! Unfortunately, the technicians have already
installed the system, so the most Joy can do is rotate some of the existing
beam shooters 90 degrees. That is, for any number (including zero) of beam
shooters, she can turn 
into 
or vice versa.
Can you find any way for Joy to achieve her goal, or determine that it is impossible? Note that it is not required to minimize the number of rotations of beam shooters.
The first line of the input gives the number of test cases, T.
T test cases follow. Each case begins with one line with two integers
R and C: the number of rows and columns in the grid
representing the house. Then, R lines of C characters each
follow; each character is /
, \
, 
,

, #
, or .
, as described in the
statement.
For each test case, output one line containing Case #x: y
, where
x
is the test case number (starting from 1) and y
is IMPOSSIBLE
if Joy cannot accomplish her goal, or
POSSIBLE
if she can. Then, if the case is possible, output the
same R lines of C characters each from the input grid, with
zero or more instances of 
replaced by 
or vice
versa.
If there are multiple possible answers, you may output any of them.
1 ≤ T ≤ 100.
1 ≤ C ≤ 50.
Each character in the grid is one of /
, \
,

, 
, #
, or .
.
The number of 
characters plus the number of 
characters (that is, the number of beam shooters) in the grid is between 1
and 100, inclusive.
There is at least 1 .
character (that is, empty space) in the
grid.
1 ≤ R ≤ 5.
There are no /
or \
characters (that is, no
mirrors) in the grid.
1 ≤ R ≤ 50.
Input 
Output 
5 1 3 . 3 4 #.## ## #### 2 2 . # 4 3 .. // .. #\/ 3 3 /\ \\/ ./# 
Case #1: IMPOSSIBLE Case #2: POSSIBLE #.## ## #### Case #3: POSSIBLE . # Case #4: POSSIBLE .. // .. #\/ Case #5: IMPOSSIBLE 
Note that the last 2 sample cases would not appear in the Small dataset.
In Sample Case #1, if a beam shooter is positioned to shoot its beam into
the empty cell, it will necessarily destroy the other beam shooter. So the
case is IMPOSSIBLE
.
In Sample Case #2, the leftmost beam shooter must be rotated to cover the empty cell. The rightmost beam shooter must also be rotated to avoid destroying the leftmost beam shooter.
In Sample Case #3, the existing beam shooters already cover all empty cells with their beams and do not destroy each other, so outputting the grid from the input would be acceptable. However, notice that the output that we have given is also correct.
In Sample Case #4, one acceptable solution is to rotate all three of the beam shooters. However, note that the following would also be acceptable:
..
//
..
#\/
since it is not necessary for cells with mirrors to have a beam pass through them. (Who would steal giant diagonal mirrors, anyway?)
In Sample Case #5, the beam shooter would destroy itself no matter which
orientation Joy chooses for it, so the case is IMPOSSIBLE
.