def increment_un(G, X, UN_X, v):
"""Compute UN of X|v, based on the UN of X"""
U = set()
for S in UN_X:
U.add(subtract(S, v))
U.add(subtract(S, v) | (G.neighborhoods[v] & (G.vertices - (X | v))))
return U
def heuristic(graph):
subset = 0
while is_independent(graph, subset):
# Find valid vertex with the least new neighbors
existing_neighbors = graph(subset)
min_new_neighbors = Infinity
new_vertex = None
for v in iterate(subtract(graph.vertices, subset)):
if not graph(v) & subset:
new_neighbors = subtract(graph(v), existing_neighbors)
if size(new_neighbors) < min_new_neighbors:
min_new_neighbors = size(new_neighbors)
new_vertex = v
if new_vertex == None:
return subset
else:
subset |= new_vertex
def bfs(graph, root):
"""Return vertices of a component of graph in some bfs order, starting with root."""
done = 0
front = root
while front:
v = first(front)
yield v
done |= v
front |= graph.neighborhoods[v]
front = subtract(front, done)
def trivial_case(N, left, right, v):
# No neighbors
if contains(left, N[v]):
return True
# Twins
for u in iterate(left):
if N[v] & right == subtract(N[u], v) & right:
return True
return False
def is_word_in_graph(word: str, graph, last_vertex=0, forbidden_vertices=0):
if not word:
return True
letter = word[0]
candidates = graph.letters_to_vertices[letter] | graph.letters_to_vertices['.']
candidates = subtract(candidates, forbidden_vertices)
if last_vertex:
candidates &= graph.neighborhoods[last_vertex]
return any(is_word_in_graph(word[1:], graph, v, forbidden_vertices | v) for v in iterate(candidates))
def incremental_un_heuristic(G):
lboolw_components = []
decomposition_components = []
for component in components(G):
best_lboolw = Infinity
best_decomposition = None
for i, start in enumerate([first(component)]):
#for i, start in enumerate(iterate(component)):
print('{}th starting vertex'.format(i))
right = subtract(component, start)
left = start
un_left = increment_un(G, 0, {0}, start)
booldim_left = 1
decomposition = [start]
lboolw = len(un_left)
for _ in range(size(component) - 1):
best_vertex, best_un, _ = greedy_step(G, left, right, un_left,
booldim_left, {}, Infinity)
booldim_left = len(best_un)
lboolw = max(lboolw, booldim_left)
un_left = best_un
decomposition.append(best_vertex)
right = subtract(right, best_vertex)
left = left | best_vertex
if lboolw < best_lboolw:
best_lboolw = lboolw
best_decomposition = decomposition
lboolw_components.append(best_lboolw)
decomposition_components.append(best_decomposition)
total_lboolw = max(lboolw_components)
total_decomposition = [v for part in decomposition_components for v in part]
return total_lboolw, total_decomposition
def check_decomposition(G, decomposition):
un = {0}
lboolw = 1
left = 0
right = G.vertices
for v in decomposition:
un = increment_un(G, left | v, v, un)
lboolw = max(lboolw, len(un))
left = left | v
right = subtract(right, v)
return lboolw
def recurse(word: str, graph, last_vertex, forbidden):
if not word:
return True
letter = word[0]
if letter not in graph.letters_to_vertices:
return False
candidates = subtract(graph.letters_to_vertices[letter] &
graph.neighborhoods[last_vertex], forbidden)
if not candidates:
return False
return any(recurse(word[1:], graph, v, forbidden | v) for v in iterate(candidates))
