# How to structure a program to work with minesweeper configurations

EDIT: This was a while ago and I've since got it working, if you'd like to see the code it's included at github.com/LewisGaul/minegaulerQt.

I'm trying to write a program to calculate probabilities for the game minesweeper, and have had some difficulty working out how best to structure it. While it may seem quite simple at first with the example below, I would like to know the best way to allow for more complex configurations. Note I am not looking for help with how to calculate probabilities - I know the method, I just need to implement it!

To make it clear what I'm trying to calculate, I will work through a simple example which can be done by hand. Consider a minesweeper configuration
`# # # #`
`# 1 2 #`
`# # # #`
where `#` represents an unclicked cell. The `1` tells us there is exactly 1 mine in the leftmost 7 unclicked cells, the `2` tells us there are exactly 2 in the rightmost 7. To calculate the probability of each individual cell containing a mine, we need to determine all the different cases (only 2 in this simple case):

1. 1 mine in leftmost 3 cells, 2 mines in rightmost 3 cells (total of 3 mines, 3x3=9 combinations).

2. 1 mine in center 4 cells, 1 mine in rightmost 3 cells (total of 2 mines, 4x3=12 combinations).

Given the probability of a mine being in a random cell is about 0.2, it is (in a random selection of cells) about 4 times more likely there is a total of 2 mines rather than a total of 3, so the total number of mines in a configuration matters, as well as the number of combinations of each configuration. So in this case the probability of case 1 is 9/(9+4x12)=0.158, and the probability of there being a mine in a given leftmost cell is therefore about 0.158/3=0.05, as those cells are effectively equivalent (they share exactly the same revealed neighbours).

I have created a GUI with Tkinter which allows me to easily enter configurations such as the one in the example, which stores the grid as a numpy array. I then made a `NumberGroup` class which isolates each of the clicked/numbered cells, storing the number and a set of the coordinates of its unclicked neighbours. These can be subtracted to get equivalence groups... Although this would not be as straightforward if there were three or more numbers instead of just two. But I am unsure how to go from here to getting the different configurations. I toyed with making a `Configuration` class, but am not hugely familiar with how different classes should work together. See working code below (numpy required).

Note: I am aware I could have attempted to use a brute force approach, but if possible I would like to avoid that, keeping the equivalent groups separate (in the above example there are 3 equivalence groups, the leftmost 3, the middle 4, the rightmost 3). I would like to hear your thoughts on this.

``````import numpy as np

grid = np.array(
[[0, 0, 0, 0],
[0, 2, 1, 0],
[0, 0, 0, 0]]
)
dims = (3, 4) #Dimensions of the grid

class NumberGroup(object):
def __init__(self, mines, coords, dims=None):
"""Takes a number of mines, and a set of coordinates."""
if dims:
self.dims = dims
self.mines = mines
self.coords = coords

def __repr__(self):
return "<Group of {} cells with {} mines>".format(
len(self.coords), self.mines)

def __str__(self):
if hasattr(self, 'dims'):
dims = self.dims
else:
dims = (max([c[0] for c in self.coords]) + 1,
max([c[1] for c in self.coords]) + 1)
grid = np.zeros(dims, int)
for coord in self.coords:
grid[coord] = 1
return str(grid).replace('0', '.').replace('1', '#')

def __sub__(self, other):
if type(other) is NumberGroup:
return self.coords - other.coords
elif type(other) is set:
return self.coords - other.coords
else:
raise TypeError("Can only subtract a group or a set from another.")

def get_neighbours(coord, dims):
x, y = coord
row = [u for u in range(x-1, x+2) if u in range(dims[0])]
col = [v for v in range(y-1, y+2) if v in range(dims[1])]
return {(u, v) for u in row for v in col}

groups = []
all_coords = [(i, j) for i in range(dims[0])
for j in range(dims[1])]
for coord, nr in [(c, grid[c]) for c in all_coords if grid[c] > 0]:
empty_neighbours = {c for c in get_neighbours(coord, dims)
if grid[c] == 0}
if nr > len(empty_neighbours):
print "Error: number {} in cell {} is too high.".format(nr, coord)
break
groups.append(NumberGroup(nr, empty_neighbours, dims))
print groups
for g in groups:
print g
print groups[0] - groups[1]
``````

UPDATE:
I have added a couple of other classes and restructured a bit (see below for working code), and it is now capable of creating and displaying the equivalence groups, which is a step in the right direction. However I still need to work out how to iterate through all the possible mine-configurations, by assigning a number of mines to each group in a way that creates a valid configuration. Any help is appreciated.

For example,
`# # # #`
`# 2 1 #`
`# # # #`
There are three equivalence groups G1: the left 3, G2: the middle 4, G3: the right 3. I want the code to loop through, assigning groups with mines in the following way:

• G1=2 (max the first group) => G2=0 => G3=1 (this is all configs with G1=2)
• G1=1 (decrease by one) => G2=1 => G3=0 (this is all with G1=1)
• G1=0 => G2=2 INVALID

So we arrive at both configurations. This needs to work for more complicated setups!

``````import numpy as np

def get_neighbours(coord, dims):
x, y = coord
row = [u for u in range(x-1, x+2) if u in range(dims[0])]
col = [v for v in range(y-1, y+2) if v in range(dims[1])]
return {(u, v) for u in row for v in col}

class NrConfig(object):
def __init__(self, grid):
self.grid = grid
self.dims = grid.shape # Dimensions of grid
self.all_coords = [(i, j) for i in range(self.dims[0])
for j in range(self.dims[1])]
self.numbers = dict()
self.groups = []
self.configs = []
self.get_numbers()
self.get_groups()
self.get_configs()

def __str__(self):
return str(self.grid).replace('0', '.')

def get_numbers(self):
for coord, nr in [(c, self.grid[c]) for c in self.all_coords
if self.grid[c] > 0]:
empty_neighbours = {c for c in get_neighbours(
coord, self.dims) if self.grid[c] == 0}
if nr > len(empty_neighbours):
print "Error: number {} in cell {} is too high.".format(
nr, coord)
return
self.numbers[coord] = Number(nr, coord, empty_neighbours,
self.dims)

def get_groups(self):
coord_neighbours = dict()
for coord in [c for c in self.all_coords if self.grid[c] == 0]:
# Must be a set so that order doesn't matter!
coord_neighbours[coord] = {self.numbers[c] for c in
get_neighbours(coord, self.dims) if c in self.numbers}
while coord_neighbours:
coord, neighbours = coord_neighbours.popitem()
equiv_coords = [coord] + [c for c, ns in coord_neighbours.items()
if ns == neighbours]
for c in equiv_coords:
if c in coord_neighbours:
del(coord_neighbours[c])
self.groups.append(EquivGroup(equiv_coords, neighbours, self.dims))

def get_configs(self):
pass # WHAT GOES HERE?!

class Number(object):
"""Contains information about the group of cells around a number."""
def __init__(self, nr, coord, neighbours, dims):
"""Takes a number of mines, and a set of coordinates."""
self.nr = nr
self.coord = coord
# A list of the available neighbouring cells' coords.
self.neighbours = neighbours
self.dims = dims

def __repr__(self):
return "<Number {} with {} empty neighbours>".format(
int(self), len(self.neighbours))

def __str__(self):
grid = np.zeros(self.dims, int)
grid[self.coord] = int(self)
for coord in self.neighbours:
grid[coord] = 9
return str(grid).replace('0', '.').replace('9', '#')

def __int__(self):
return self.nr

class EquivGroup(object):
"""A group of cells which are effectively equivalent."""
def __init__(self, coords, nrs, dims):
self.coords = coords
# A list of the neighbouring Number objects.
self.nr_neighbours = nrs
self.dims = dims
if self.nr_neighbours:
self.max_mines = min(len(self.coords),
max(map(int, self.nr_neighbours)))
else:
self.max_mines = len(coords)

def __repr__(self):
return "<Equivalence group containing {} cells>".format(
len(self.coords))

def __str__(self):
grid = np.zeros(self.dims, int)
for coord in self.coords:
grid[coord] = 9
for number in self.nr_neighbours:
grid[number.coord] = int(number)
return str(grid).replace('0', '.').replace('9', '#')

grid = np.array(
[[0, 0, 0, 0],
[0, 2, 1, 0],
[0, 0, 0, 0]]
)
config = NrConfig(grid)
print config
print "Number groups:"
for n in config.numbers.values():
print n
print "Equivalence groups:"
for g in config.groups:
print g
``````
• Slightly away from the question, but in minesweeper don't you always know how many mines there are for a given game? On the (wild) assumption you might be trying to implement an 'AI' solver, you might be making things more complicated for yourself than they need to be. If that's not the case tho, then good on you for setting yourself a good challenge :-) – Tom Dalton Aug 12 '15 at 14:47
• The primary aim is not to make a solver, although I get what you're saying. I want to be able to calculate probabilities in situations where there are no possible certain moves – Siwel Aug 12 '15 at 14:50
• See math.stackexchange.com/questions/389619/… for full details of how to calculate the probabilities. – Siwel Aug 25 '15 at 13:02
• I am not sure I got the question correctly. You are looking for a good representation for your mine field, that allows you to do simple lookarounds? – Pietro Saccardi Nov 3 '15 at 13:11

If you don't want to brute-force it, you could model the process as a decision tree. Suppose we start with your example:

``````####
#21#
####
``````

If we want to start placing mines in a valid configuration, we at this point essentially have eight choices. Since it doesn't really matter which square we pick within an equivalence group, we can narrow that down to three choices. The tree branches. Let's go down one branch:

``````*###
#11#
####
``````

I placed a mine in G1, indicated by the asterisk. Also, I've updated the numbers (just one number in this case) associated with this equivalence group, to indicate that these numbered squares can now border one fewer mines.

This hasn't reduced our freedom of choice for the following step, we can still place a mine in any of the equivalence groups. Let's place another one in G1:

``````*XX#
*01#
XXX#
``````

Another asterisk marks the new mine, and the numbered square has again been lowered by one. It has now reached zero, meaning it cannot border any more mines. That means that for our next choice of mine placement, all the equivalence groups dependent upon this numbered square are ruled out. `X`s mark squares where we can now not place any mine. We can only make one choice now:

``````*XX*
*00X
XXXX
``````

Here the branch ends and you've found a valid configuration. By running along all the branches in this tree in this manner, you should find all of them. Here we found your first configuration. Of course, there's more than one way to get there. If we had started by placing a mine in G3, we would have been forced to place the other two in G1. That branch leads to the same configuration, so you should check for duplicates. I don't see a way to avoid this redundancy right now.

The second configuration is found by either starting with G2, or placing one mine in G1 and then the second in G2. In either case you again end up at a branch end:

``````**XX
X00X
XXXX
``````

Invalid configurations like your example with zero mines in G1 do not pop up. There are no valid choices along the tree that lead you there. Here is the whole tree of valid choices.

``````Choice 1:        1     |     2     |     3
Choice 2:    1   2   3 | 1         | 1
Choice 3:     3     1  |           |1
``````

Valid configurations are the branch ends at which no further choice is possible, i.e.

``````113
12
131
21
311
``````

which obviously fall into two equivalent classes if we disregard the order of the numbers.

• Thanks for your answer, this is certainly an option. The only concern I have is whether this is the most efficient way when we have a more complex situation, given that in general the same configurations may be found multiple times. – Siwel Mar 25 '16 at 15:00
• It's possible you could tweak it a bit to avoid going down branches that will lead to redundant things. For example, knowing that 1-2 is a dead end, there is no reason to try going down 1-3-2 or 2-1 or 3-1-2 or 3-2-1. They are all ruled out or will obviously lead to a redundant result. This way you could prevent some unnecessary calculations. – Marco Tompitak Mar 25 '16 at 16:58
• Also note this can in fact give invalid configurations due to capacity limits, for example if the 2 was replaced with a 4 the only valid configuration would be G1=0, G2=1, G3=3, but this method doesn't know that assigning a mine to G1 will be invalid. This is not a huge issue and it can be addressed, but I thought it might be worth pointing out. – Siwel Mar 26 '16 at 2:29
• That's a very good point, I had not considered that. It means you would have to verify that your branch end not only allows no more moves, but also that all the number on the board are zero. – Marco Tompitak Mar 26 '16 at 8:15