def distance_to_dead_ends(self):
result = list()
for i in self.gen_covers_count:
if i % 100 == 0: print i
f = self.product_field(i)
s = LG_Solver(f)
s.run()
result.append(s.alternative_path_lens())
return result
def distance_to_dead_ends(self):
result = list()
for i in self.gen_covers_count:
if i % 100 == 0: print i
f = self.product_field(i)
s = LG_Solver(f)
s.run()
result.append(s.alternative_path_lens())
return result
def solver_profiling():
path_to_covers = '/home/anosov/data/hard_base/covers/case_0.dump'
h = DataHandler(path_to_covers)
from LG.solver import Solver as LG_Solver
i_ = 0
f = h.product_field(i_)
for i in xrange(1):
s = LG_Solver(f)
a = s.run()
b = s.alternative_path_lens()
print a
print [h.cells[i] for i in h.finished_packed_paths[i_]]
def solver_profiling():
path_to_covers = '/home/anosov/data/hard_base/covers/case_0.dump'
h = DataHandler(path_to_covers)
from LG.solver import Solver as LG_Solver
i_ = 0
f = h.product_field(i_)
for i in xrange(1):
s = LG_Solver(f)
a = s.run()
b = s.alternative_path_lens()
print a
print[h.cells[i] for i in h.finished_packed_paths[i_]]
print b
