def get_binary_triangle_with_subset_order(size):
num_elements = int((size + 1) * size / 2)
elements = range(num_elements)
tri_list = [util.get_all_zero_triangle(size)]
for i in range(1, num_elements + 1):
subset_list = itertools.combinations(elements, i)
for subset in subset_list:
data = [0] * num_elements
for x in subset:
data[x] = 1
triangle = []
start_idx = 0
for j in range(size):
end_idx = start_idx + j + 1
triangle.append(data[start_idx:end_idx])
start_idx = start_idx + j + 1
tri_list.append(util.flip_triangle(triangle))
return tri_list
def stack_to_magog(stack):
size = len(stack)
magog = util.get_all_zero_triangle(size)
print('CONVERTING')
util.print_array(stack)
for idx in range(size):
stack_row = stack[size - 1 - idx]
start_idx = idx
mrow_idx = size - 1
for i in reversed(range(len(stack_row))):
if stack_row[i] == 0:
start_idx += 1
else:
mrow_len = len(magog[mrow_idx])
for j in range(start_idx, mrow_len):
magog[mrow_idx][j] = magog[mrow_idx][j] + 1
mrow_idx += -1
print('------ idx=', idx)
util.print_array(magog)
return magog
def get_down_for_cliff(B):
size = len(B)
D = util.get_all_zero_triangle(size)
for k in range(size):
#logging.debug('B[k]', k, B[k])
D[k][k] = k + 1 - sum([B[k][j] for j in range(k + 1)])
return D
def to_BD(triangle):
size = len(triangle)
B = util.get_all_zero_triangle(size)
D = util.get_all_zero_triangle(size)
tiered = [[x + idx for x in row] for idx, row in enumerate(triangle)]
path_triangle = [[size - x for x in reversed(row)]
for row in reversed(tiered)]
#util.print_array(path_triangle)
#tiered = [ [size - x - idx for x in row] for idx,row in enumerate(triangle)]
#path_triangle = [[x for x in reversed(row)] for row in reversed(tiered)]
#path_triangle = [ [size - x - idx for x in reversed(row)] for idx,row in enumerate(triangle)]
#path_triangle = [x for x in reversed(path_triangle)]
#print('ballot')
#util.print_array(triangle)
#print('path triangle')
#util.print_array(path_triangle)
for row_idx, row in enumerate(path_triangle):
if row[0] == row_idx:
B[row_idx][0] = 1
for col_idx in range(1, len(row)):
if row[col_idx] < row[col_idx - 1]:
B[row_idx][col_idx] = 1
D[row_idx][-1] = row[-1]
for col_idx in range(0, len(row) - 1):
if row[col_idx] > row[col_idx + 1] + 1:
D[row_idx][col_idx] = row[col_idx] - row[col_idx + 1] - 1
#print('binary')
#util.print_array(B)
#print('down')
#util.print_array(D)
return B, D
def to_sst(columns):
size = len(columns)
triangle = util.get_all_zero_triangle(size)
for idx,x in enumerate(reversed(columns)):
if x > 0:
triangle[idx][x-1] = 1
return triangle
def comb(binary_triangle):
size = len(binary_triangle)
down_triangle = util.get_all_zero_triangle(len(binary_triangle))
for k in reversed(range(size)):
down_triangle[k][k] = k + 1 - sum(
[binary_triangle[k][j] for j in range(k + 1)])
return comb_BD(binary_triangle, down_triangle)
def binary_for_layer(layer, tri_size):
binlayer_tri = util.get_all_zero_triangle(tri_size)
binlayer_tri = [ row for row in reversed(binlayer_tri)]
for idx,x in enumerate(layer):
if x > 0:
binlayer_tri[x-1][idx]=1
rev_tri = [ x for x in reversed(binlayer_tri)]
layer_size = len(layer)
# return the subtriangle for top layering
rev_tri = rev_tri[0: layer_size]
return rev_tri
def tip_west(triangle):
size = len(triangle)
tip_triangle = util.get_all_zero_triangle(size)
tip_triangle = []
for row_idx in range(size):
tip_row = []
for col_idx in range(size - row_idx):
count = 0
for i in range(size - row_idx - col_idx):
if triangle[row_idx][i] > col_idx:
count += 1
tip_row.append(count)
tip_triangle.append(tip_row)
return tip_triangle
def word_to_triangle(word):
size = len(word)
tri = util.get_all_zero_triangle(size)
for idx, w in enumerate(word):
if w > 0:
tri[size - w][idx] = 1
for idx in range(size):
if sum(tri[idx]) == 0:
del tri[idx]
for k in range(idx):
tri[k].append(0)
tri.insert(0, [
0,
])
return tri
