def fall(self, limx, direction, matrix, ladder, floor, wall, coin, donkey, fireballs):
self.collectCoin(matrix, coin)
#direction of fall
if direction == Direction.EAST:
offset = self.velx
elif direction == Direction.WEST:
offset = -1*self.velx
else:
offset = 0
if ((direction == Direction.EAST and matrix.SE_of(self) == matrix.symbol) or (direction == Direction.WEST and matrix.SW_of(self) == matrix.symbol) or matrix.getPosition(self) == matrix.symbol):
while matrix.grid[self.y+self.vely][self.x+offset] in [matrix.symbol, 'o', coin.symbol]:
self.collectCoin(matrix, coin)
matrix.update_character_in_matrix(self.y, self.x, self.trace)
matrix.update_ladders_in_matrix(floor.coordinates, ladder.coordinates, ladder.symbol, floor.gap)
for fireball in fireballs:
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.trace)
fireball.move(limx, matrix, self, ladder, wall, floor, 0)
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.trace)
donkey.move(matrix.grid, self, 0)
matrix.update_coins_in_matrix(coin.coordinates, coin.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.symbol)
self.y += self.vely
if matrix.grid[self.y][self.x+offset] != wall:
self.x += offset
matrix.update_character_in_matrix(self.y, self.x, self.symbol)
# time.sleep(0.05)
matrix.print_matrix(self.score, self.lives)
def climb_down(self, matrix, player, ladder, wall, floor, autocall = 1):
while matrix.S_of(self) not in [floor.symbol, wall]:
self.checkCollision(player)
matrix.update_character_in_matrix(self.y, self.x, self.trace)
matrix.update_ladders_in_matrix(floor.coordinates, ladder.coordinates, ladder.symbol, floor.gap)
self.y += self.vely
matrix.update_character_in_matrix(self.y, self.x, self.symbol)
if autocall == 1:
time.sleep(0.02)
matrix.print_matrix(player.score, player.lives)
def fall(self, matrix, player, ladder, wall, floor, autocall = 1):
offset = self.velx
while matrix.SE_of(self) == matrix.symbol or matrix.SW_of(self) == matrix.symbol:
matrix.update_character_in_matrix(self.y, self.x, self.trace)
matrix.update_ladders_in_matrix(floor.coordinates, ladder.coordinates, ladder.symbol, floor.gap)
self.y += self.vely
if matrix.grid[self.y][self.x+offset] != wall:
self.x += offset
matrix.update_character_in_matrix(self.y, self.x, self.symbol)
if autocall == 1:
time.sleep(0.02)
matrix.print_matrix(player.score, player.lives)
def main():
m = [[1, 4, 6], [5, 4, 4], [0, 0, 1]]
b = [[6, 3, 3], [12, 4, 6], [6, 5, 5]]
m = matrix.scale_row(b, 2, "mul", 2)
f = matrix.scale_row(m, 0, "div", 3)
matrix.print_matrix(m)
matrix.print_matrix(f)
w = matrix.get_vector(m, 1)
matrix.print_matrix(w)
k = [[2, 2], [1, 0], [9, 7], [6, 6]]
c = [[2, 6, 3], [7, 7, 7]]
res = matrix.multiply_matrix(k, c)
matrix.print_matrix(res)
def test():
V = [1,2,3,4]
WE = [(1,2,5),
(2,3,1),
(3,1,8), (3,4,3),
(4,1,2)]
print """
Initial Data
"""
print "V =", V
print "WE =", WE
print """
Determine safe infinity. Safe infinity equals sum of all weights
+ 1.
"""
infinity = 1
for (u,v,w) in WE:
infinity = infinity + w
print "infinity =", infinity
n = len(V)
print """
Original weights.
"""
W = matrix.make(n, n, infinity)
for (u,v,w) in WE:
W[u-1][v-1] = w
for i in xrange(n):
W[i][i] = 0
matrix.print_matrix(W, infinity)
print """
Repeated squaring
"""
D = all_pairs_shortest_paths(W, infinity)
matrix.print_matrix(D, infinity)
print """
Floyd-Warshall
"""
D = floyd_warshall(W, infinity)
matrix.print_matrix(D, infinity)
def test():
V = [1, 2, 3, 4]
WE = [(1, 2, 5), (2, 3, 1), (3, 1, 8), (3, 4, 3), (4, 1, 2)]
print """
Initial Data
"""
print "V =", V
print "WE =", WE
print """
Determine safe infinity. Safe infinity equals sum of all weights
+ 1.
"""
infinity = 1
for (u, v, w) in WE:
infinity = infinity + w
print "infinity =", infinity
n = len(V)
print """
Original weights.
"""
W = matrix.make(n, n, infinity)
for (u, v, w) in WE:
W[u - 1][v - 1] = w
for i in xrange(n):
W[i][i] = 0
matrix.print_matrix(W, infinity)
print """
Repeated squaring
"""
D = all_pairs_shortest_paths(W, infinity)
matrix.print_matrix(D, infinity)
print """
Floyd-Warshall
"""
D = floyd_warshall(W, infinity)
matrix.print_matrix(D, infinity)
import matrix mat = matrix.generate_matrix(10,10) mat[0][0] = 7 matrix.print_matrix(mat)
points = []
for y in range(len(maze)):
for x in range(len(maze[0])):
if maze[y][x] == 0:
points.append(Point(x, y))
return points
points = validPoints(maze)
startPos = r.choice(points)
endPos = r.choice(points)
start = Node(startPos, None)
end = Node(endPos, None)
path = aStar(start, end, maze)
for y in range(len(maze)):
for x in range(len(maze[0])):
if maze[y][x] == 0:
maze[y][x] = '.'
else:
maze[y][x] = '#'
for i in path:
maze[i.y][i.x] = 'X'
matrix.print_matrix(maze)
# https://www.growingwiththeweb.com/2012/06/a-pathfinding-algorithm.html
def test_q4():
print("-------------------------------------------")
print("Testing Q4: Matrix Library")
filename = 'q4_solution.txt'
outFile = open(filename, 'w')
print()
outFile.write('1- Testing is_vector:\n')
outFile.write('is_vector({}) = {}\n'.format([], matrix.is_vector([])))
outFile.write('is_vector({}) = {}\n'.format([10], matrix.is_vector([10])))
outFile.write('is_vector({}) = {}\n'.format([10, 20],
matrix.is_vector([10, 20])))
outFile.write('is_vector({}) = {}\n'.format(10, matrix.is_vector(10)))
outFile.write('is_vector({}) = {}\n'.format([3, 4.5],
matrix.is_vector([3, 4.5])))
outFile.write('is_vector({}) = {}\n'.format([[]], matrix.is_vector([[]])))
outFile.write('is_vector({}) = {}\n'.format([[1, 2], [3, 4]],
matrix.is_vector([[1, 2],
[3, 4]])))
outFile.write('\n')
outFile.write('2- Testing is_matrix')
A = []
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [5]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [[1, 2], [3, 4]]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [[1], [2], [3]]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [[1, 2, 3], [4, 5, 6]]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = 5
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [5.5]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
A = [[1, 2, 3], [4, 5]]
outFile.write('is_matrix({}) = {}\n'.format(A, matrix.is_matrix(A)))
outFile.write('\n')
print('3- Testing print_matrix')
A = []
print('print_matrix({})='.format(A))
matrix.print_matrix(A)
A = [10, 20, 30]
print('print_matrix({})='.format(A))
matrix.print_matrix(A)
A = [[10], [20], [30]]
print('print_matrix({})='.format(A))
matrix.print_matrix(A)
A = [[10, 20, 30], [40, 50, 60], [70, 80, 10]]
print('print_matrix({})='.format(A))
matrix.print_matrix(A)
A = [[10, 20, 30], [40, 50, 60], [70, 80]]
print('print_matrix({})='.format(A))
print(matrix.print_matrix(A))
print()
outFile.write('4/5/6- Testing size functions\n')
A = []
outFile.write('get_rowCount({}) = {}\n'.format(A,
matrix.get_rowCount(A)))
outFile.write('get_ColumnCount({}) = {}\n'.format(
A, matrix.get_columnCount(A)))
outFile.write('get_size({}) = {}\n'.format(A, matrix.get_size(A)))
outFile.write('\n')
A = [1, 2, 3]
outFile.write('get_rowCount({}) = {}\n'.format(A,
matrix.get_rowCount(A)))
outFile.write('get_ColumnCount({}) = {}\n'.format(
A, matrix.get_columnCount(A)))
outFile.write('get_size({}) = {}\n'.format(A, matrix.get_size(A)))
outFile.write('\n')
A = [[1, 2], [3, 4], [5, 6]]
outFile.write('get_rowCount({}) = {}\n'.format(A,
matrix.get_rowCount(A)))
outFile.write('get_ColumnCount({}) = {}\n'.format(
A, matrix.get_columnCount(A)))
outFile.write('get_size({}) = {}\n'.format(A, matrix.get_size(A)))
outFile.write('\n')
A = [[1, 2], [3]]
outFile.write('get_rowCount({}) = {}\n'.format(A,
matrix.get_rowCount(A)))
outFile.write('get_ColumnCount({}) = {}\n'.format(
A, matrix.get_columnCount(A)))
outFile.write('get_size({}) = {}\n'.format(A, matrix.get_size(A)))
outFile.write('\n')
outFile.write('7- Testing is_square\n')
A = []
outFile.write('is_square({}) = {}\n'.format(A, matrix.is_square(A)))
A = [5]
outFile.write('is_square({}) = {}\n'.format(A, matrix.is_square(A)))
A = [5, 6]
outFile.write('is_square({}) = {}\n'.format(A, matrix.is_square(A)))
A = [[1, 2], [3, 4]]
outFile.write('is_square({}) = {}\n'.format(A, matrix.is_square(A)))
A = [5.5]
outFile.write('is_square({}) = {}\n'.format(A, matrix.is_square(A)))
outFile.write('\n')
outFile.write('8/9/10- Testing getter functions\n')
A = [[1, 2, 3], [4, 5, 6]]
i = 0
j = 1
outFile.write('get_row({},{}) = {}\n'.format(A, i, matrix.get_row(A,
i)))
outFile.write('get_Column({},{}) = {}\n'.format(A, j,
matrix.get_column(A, j)))
outFile.write('get_element({},{},{}) = {}\n'.format(
A, i, j, matrix.get_element(A, i, j)))
outFile.write('\n')
i = 2
j = 2
outFile.write('get_row({},{}) = {}\n'.format(A, i, matrix.get_row(A,
i)))
outFile.write('get_Column({},{}) = {}\n'.format(A, j,
matrix.get_column(A, j)))
outFile.write('get_element({},{},{}) = {}\n'.format(
A, i, j, matrix.get_element(A, i, j)))
outFile.write('\n')
i = 1
j = 3
outFile.write('get_row({},{}) = {}\n'.format(A, i, matrix.get_row(A,
i)))
outFile.write('get_Column({},{}) = {}\n'.format(A, j,
matrix.get_column(A, j)))
outFile.write('get_element({},{},{}) = {}\n'.format(
A, i, j, matrix.get_element(A, i, j)))
outFile.write('\n')
A = [[1, 2, 3], []]
outFile.write('get_row({},{}) = {}\n'.format(A, i, matrix.get_row(A,
i)))
outFile.write('get_Column({},{}) = {}\n'.format(A, j,
matrix.get_column(A, j)))
outFile.write('get_element({},{},{}) = {}\n'.format(
A, i, j, matrix.get_element(A, i, j)))
outFile.write('\n')
outFile.write('11- Testing new_matrix\n')
r = 0
c = 0
pad = 0
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
c = 1
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
r = 1
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
r = 2
c = 1
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
c = 2
r = 1
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
c = 3
r = 3
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
r = -1
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
r = 3
c = -5
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
c = 5
pad = 3.5
outFile.write('new_matrix({},{},{})=\n{}\n'.format(
r, c, pad, matrix.new_matrix(r, c, pad)))
outFile.write('\n')
outFile.write('12- Testing get_I\n')
size = -1
outFile.write('get_I({}) = {}\n'.format(size, matrix.get_I(size)))
size = 0
outFile.write('get_I({}) = {}\n'.format(size, matrix.get_I(size)))
size = 1
outFile.write('get_I({}) = {}\n'.format(size, matrix.get_I(size)))
size = 2
outFile.write('get_I({}) = {}\n'.format(size, matrix.get_I(size)))
size = 3
outFile.write('get_I({}) = {}\n'.format(size, matrix.get_I(size)))
outFile.write('\n')
outFile.write('13- Testing is_identity\n')
A = [1]
outFile.write('is_identity({}) = {}\n'.format(A, matrix.is_identity(A)))
A = matrix.get_I(3)
outFile.write('is_identity({}) = {}\n'.format(A, matrix.is_identity(A)))
A = [[1, 0], [1, 1]]
outFile.write('is_identity({}) = {}\n'.format(A, matrix.is_identity(A)))
A = [[1, 0], [0, 1, 0]]
outFile.write('is_identity({}) = {}\n'.format(A, matrix.is_identity(A)))
outFile.write('\n')
outFile.write('14- Testing scalar_mul\n')
A = [[1, 2], [3, 4]]
c = 10
outFile.write('scalar_mul({},{}) = {}\n'.format(A, c,
matrix.scalar_mul(c, A)))
A = [1, 2, 3, 4]
outFile.write('scalar_mul({},{}) = {}\n'.format(A, c,
matrix.scalar_mul(c, A)))
A = []
outFile.write('scalar_mul({},{}) = {}\n'.format(A, c,
matrix.scalar_mul(c, A)))
A = [1, 2, 3, [4]]
outFile.write('scalar_mul({},{}) = {}\n'.format(A, c,
matrix.scalar_mul(c, A)))
A = [[1, 2], [3, 4]]
c = [10]
outFile.write('scalar_mul({},{}) = {}\n'.format(A, c,
matrix.scalar_mul(c, A)))
outFile.write('\n')
outFile.write('15- Testing mul\n')
A = [[1, 2], [3, 4]]
B = [[10, 20], [30, 40]]
outFile.write('mul({},{})=\n{}\n'.format(A, c, matrix.mul(A, B)))
A = [[1, 2, 3], [5, 6, 7]]
B = [[10, 20], [30, 40], [50, 60]]
outFile.write('mul({},{})= {}\n'.format(A, c, matrix.mul(A, B)))
A = [5]
B = [10]
outFile.write('mul({},{})= {}\n'.format(A, B, matrix.mul(A, B)))
A = [0, 1, 2]
B = [[0], [1], [2]]
outFile.write('mul({},{})= {}\n'.format(A, B, matrix.mul(A, B)))
A = [[0], 1]
B = [1, 0]
outFile.write('mul({},{})= {}\n'.format(A, B, matrix.mul(A, B)))
A = [1, 0]
B = [[0], 1]
outFile.write('mul({},{})= {}\n'.format(A, B, matrix.mul(A, B)))
A = [[1, 2, 3], [5, 6, 7]]
B = [[10, 20], [30, 40], [50, 60]]
outFile.write('mul({},{})= {}\n'.format(B, A, matrix.mul(B, A)))
A = [[1, 2, 3], [5, 6, 7]]
B = [[10, 20], [30, 40]]
outFile.write('mul({},{})= {}\n'.format(A, B, matrix.mul(A, B)))
outFile.write('\n')
outFile.write('16- Testing matrix_mod\n')
A = [[1, 2], [3, 4]]
m = 2
outFile.write('matrix_mod({},{})= {}\n'.format(A, m,
matrix.matrix_mod(A, m)))
A = [1, 2, 3, 4]
m = 2
outFile.write('matrix_mod({},{})= {}\n'.format(A, m,
matrix.matrix_mod(A, m)))
A = [[3], [5]]
m = 3
outFile.write('matrix_mod({},{})= {}\n'.format(A, m,
matrix.matrix_mod(A, m)))
A = [[3], [5]]
m = 0
outFile.write('matrix_mod({},{})= {}\n'.format(A, m,
matrix.matrix_mod(A, m)))
A = [3, [5]]
m = 6
outFile.write('matrix_mod({},{})= {}\n'.format(A, m,
matrix.matrix_mod(A, m)))
outFile.write('\n')
outFile.write('17- Testing det\n')
A = [[1, 2], [3, 4]]
outFile.write('det({})= {}\n'.format(A, matrix.det(A)))
A = [10]
outFile.write('det({})= {}\n'.format(A, matrix.det(A)))
A = [[1, 1, 1], [2, 2, 2], [3, 3, 3]]
outFile.write('det({})= {}\n'.format(A, matrix.det(A)))
A = [[1, 1, 1], [2, 2]]
outFile.write('det({})= {}\n'.format(A, matrix.det(A)))
outFile.write('\n')
outFile.write('18- Testing inverse\n')
A = [[1, 4], [8, 11]]
m = 26
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [[4, 3], [1, 1]]
m = 5
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [[1, 4], [8, 10]]
m = 26
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [1, 4, 8, 10]
m = 15
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [[4, 3], [1, 1]]
m = -5
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]
m = 7
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
A = [[1, 2, 3], [4, 5]]
m = 7
outFile.write('inverse({},{})= {}\n'.format(A, m, matrix.inverse(A, m)))
outFile.close()
print('Comparing q4_solution with q4_sample:')
print(utilities_A4.compare_files('q4_solution.txt', 'q4_sample.txt'))
print()
print("-------------------------------------------")
width = 100
height = 40
grid = matrix.generate_matrix(width, height, 0)
# set starting points to random values
fill1Queue = [ {'x': r.randint(0,width-1), 'y':r.randint(0,height-1)} ]
fill2Queue = [ {'x': r.randint(0,width-1), 'y':r.randint(0,height-1)} ]
fill3Queue = [ {'x': r.randint(0,width-1), 'y':r.randint(0,height-1)} ]
while TilesLeft():
while len(fill1Queue) > 0 or len(fill2Queue) > 0 or len(fill3Queue) > 0:
# if a queue has tiles left, sets the queue to the result
# of the floodfill method
# specifies different values for each queue
if (len(fill1Queue) > 0):
fill1Queue = FillFrom(fill1Queue, "*")
if (len(fill2Queue) > 0):
fill2Queue = FillFrom(fill2Queue, "#")
if (len(fill3Queue) > 0):
fill3Queue = FillFrom(fill3Queue, ".")
# draw the fill each loop
# os.system('cls')
# matrix.print_matrix(grid)
matrix.print_matrix(grid)
import matrix x = matrix.generate_matrix(20, 20) x[12][7] = 4 matrix.print_matrix(x)
def jump(self, direction, limx, limy, matrix, ladder, floor, wall, coin, donkey, fireballs, max_height = 2, multiplier = 3):
self.collectCoin(matrix, coin)
#direction of jump
if self.motion == Motion.RIGHT:
offset = multiplier*self.velx
elif self.motion == Motion.LEFT:
offset = -1*multiplier*self.velx
elif self.motion == Motion.REST:
offset = 0
matrix.update_character_in_matrix(self.y, self.x, self.trace)
#init jump
if direction == Direction.JUMP and matrix.S_of(self) in [wall, floor.symbol, ladder.symbol]:
maxjump = self.y-max_height
initial_height = self.y
#up
while self.y > maxjump:
matrix.update_character_in_matrix(self.y, self.x, self.trace)
matrix.update_ladders_in_matrix(floor.coordinates, ladder.coordinates, ladder.symbol, floor.gap)
for fireball in fireballs:
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.trace)
fireball.move(limx, matrix, self, ladder, wall, floor, 0)
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.trace)
donkey.move(matrix.grid, self, 0)
matrix.update_coins_in_matrix(coin.coordinates, coin.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.symbol)
if matrix.N_of(self) != floor.symbol or getPosition(self) != floor.symbol:
if matrix.getPosition(self) == ladder.symbol and self.motion != Motion.REST:
break
self.y -= self.vely
else:
break
if self.x + offset not in range(1,limx-2):
if self.motion == Motion.RIGHT:
self.x = limx-2
offset = 0
elif self.motion == Motion.LEFT:
self.x = 1
offset = 0
else:
self.x += offset
matrix.update_character_in_matrix(self.y, self.x, self.symbol)
time.sleep(0.05)
matrix.print_matrix(self.score, self.lives)
#down
while matrix.S_of(self) in [matrix.symbol, 'o', coin.symbol]:
self.collectCoin(matrix, coin)
matrix.update_character_in_matrix(self.y, self.x, self.trace)
matrix.update_ladders_in_matrix(floor.coordinates, ladder.coordinates, ladder.symbol, floor.gap)
for fireball in fireballs:
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.trace)
fireball.move(limx, matrix, self, ladder, wall, floor, 0)
matrix.update_character_in_matrix(fireball.y, fireball.x, fireball.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.trace)
donkey.move(matrix.grid, self, 0)
matrix.update_coins_in_matrix(coin.coordinates, coin.symbol)
matrix.update_character_in_matrix(donkey.y, donkey.x, donkey.symbol)
if matrix.getPosition(self) == ladder.symbol and self.motion != Motion.REST:
break
self.y += self.vely
if self.x + offset not in range(1,limx-1):
if self.motion == Motion.RIGHT:
self.x = limx-2
offest = 0
elif self.motion == Motion.LEFT:
self.x = 1
offset = 0
else:
self.x += offset
matrix.update_character_in_matrix(self.y, self.x, self.symbol)
time.sleep(0.05)
matrix.print_matrix(self.score, self.lives)
asciiMaze = CreateASCIIMaze(grid)
startConnecting = time.time()
carveTime = startConnecting - fullStart
tilesInRooms = []
regions = []
notInRoom = TilesNotInRooms()
while len(notInRoom) > 0:
region = FillFrom(notInRoom[0])
for i in region: tilesInRooms.append(i)
regions.append(region)
notInRoom = TilesNotInRooms()
''' checks region counting
for i in range(len(regions)):
for cell in regions[i]:
asciiMaze[cell['y']][cell['x']] = i
matrix.print_matrix(asciiMaze)
'''
while len(regions) > 1:
walls = GetWalls()
possibleConnectors = []
for wall in walls:
directions = [N, S, E, W]
adjacentTiles = []
positionX = wall['x']
return child
@property
def wih(self) -> list:
"""Weights between input layer and hidden layer"""
return self._wih
@wih.setter
def wih(self, weights: list):
self._wih = weights
@property
def who(self) -> list:
"""Weights between hidden layer and output layer"""
return self._who
@who.setter
def who(self, weights: list):
self._who = weights
if __name__ == "__main__":
n = NeuralNetwork(2, 2, 2)
matrix.print_matrix(n.wih)
print('')
matrix.print_matrix(n.who)
print('')
n_input = [1, -1]
out = n.output(n_input)
print(out)
while TilesRemain():
while len(centerQueue) > 0 or len(TLQueue) > 0 or len(TRQueue) > 0 or len(
BLQueue) > 0 or len(BRQueue) > 0:
if loops > 20:
if len(centerQueue) > 0:
centerQueue = Flood(centerQueue, '.', 'newest')
if len(TLQueue) > 0:
TLQueue = Flood(TLQueue, '#', 'random')
if len(TRQueue) > 0:
TRQueue = Flood(TRQueue, '#', 'random')
if len(BLQueue) > 0:
BLQueue = Flood(BLQueue, '#', 'random')
if len(BRQueue) > 0:
BRQueue = Flood(BRQueue, '#', 'random')
loops += 1
borderedMap = matrix.generate_matrix(width + 1, height + 1)
for y in range(height + 1):
if y > 0 and y < height:
for x in range(width + 1):
if x > 0 and x < width:
borderedMap[y][x] = grid[y - 1][x - 1]
for y in range(height + 1):
for x in range(width + 1):
if borderedMap[y][x] != '#' and borderedMap[y][x] != '.':
borderedMap[y][x] = '#'
matrix.print_matrix(borderedMap)
