print(second_order_tree(test, l, 0.0, deltalist_function=relative_deltalist))
print(second_order_tree(test, l, 0.0))
sys.exit(0)
import database as db
import tools
w = db.select()
score = Score(db.getScore1(w))
melodyscore = score.melody()
#melodyscore.show()
melody = tools.parseScore(melodyscore, list(range(1, 9)))
trees = [second_order_tree(onset, melody, 0.5), second_order_tree(pitch, melody, 0.0, ), first_order_tree(onset, melody, 0.0), first_order_tree(pitch, melody)]
for tree in trees:
print("Tree")
print(tools.recursive_print(tree))
for i in range(5):
for j in range(len(trees)):
groups = groupings(list_to_tree(trees[j]), i)
avg_group = 0
for group in groups:
avg_group += len(group)
avg_group /= float(len(groups))
print("Tree: {0} Level {1} group size {2}".format(j, i, avg_group))
print('------------------')
if len(groups)/float(len(melody)) == 1: break
print("Choose tree")
tree = int(input(''))
m = 1
for i in l:
result.append(i/m)
return result
def square(l):
result = []
for i in l:
result.append(i*i)
return result
if len(sys.argv) > 1:
notes = sys.argv[1]
deltas = [int(x) for x in sys.argv[2]]
s3 = structure.second_order_deltarule(notes, deltas, 0)
print(tools.recursive_print(s3))
sys.exit(0)
selection = db.select()
score = Score(db.getScore1(selection).stripTies())
melody = score.melody()
notes = tools.parseScore(melody)
deltas = []
print("COMBINED DELTA TREES")
#for feature in [structure.pitch, structure.onset]:
# deltas.append(normalize(structure.repetition(feature, notes)))
for feature in [structure.onset, structure.duration, structure.pitch]:
