def main():
origin = open('10k.txt', 'r')
lines = origin.readlines()
x = []
label = []
for l in lines:
l = l.split(',')
ip1 = l[2].split('.')
ip2 = l[3].split('.')
d = [datetime.fromtimestamp(int(l[1][0:11])).hour, int("%02x%02x%02x%02x"%(int(ip1[0]),int(ip1[1]),int(ip1[2]),int(ip1[3])),16), int("%02x%02x%02x%02x" % (int(ip2[0]),int(ip2[1]),int(ip2[2]),int(ip2[3])),16)] + l[4:6] + l[7:10]
x.append(d)
data = np.array(x, dtype='float32')
model = SpectralCoclustering(n_clusters=5)
model.fit(data)
print model.rows_
for i in range(5):
print "Cluster" + str(i) + ':'
for j in range(10000):
if model.rows_[i][j]:
print j,
print ' '
def find_disjoint_biclusters(self, biclusters_number=50):
data = np.asarray_chkfinite(self.matrix)
data[data == 0] = 0.000001
coclustering = SpectralCoclustering(n_clusters=biclusters_number, random_state=0)
coclustering.fit(data)
biclusters = set()
for i in range(biclusters_number):
rows, columns = coclustering.get_indices(i)
row_set = set(rows)
columns_set = set(columns)
if len(row_set) > 0 and len(columns_set) > 0:
density = self._calculate_box_cluster_density(row_set, columns_set)
odd_columns = set()
for column in columns_set:
col_density = self._calculate_column_density(column, row_set)
if col_density < density / 4:
odd_columns.add(column)
columns_set.difference_update(odd_columns)
if len(columns_set) == 0:
continue
odd_rows = set()
for row in row_set:
row_density = self._calculate_row_density(row, columns_set)
if row_density < density / 4:
odd_rows.add(row)
row_set.difference_update(odd_rows)
if len(row_set) > 0 and len(columns_set) > 0:
density = self._calculate_box_cluster_density(row_set, columns_set)
biclusters.add(Bicluster(row_set, columns_set, density))
return biclusters
def run(self, data):
bc = SpectralCoclustering(n_clusters=(self.n_gene_classes,
self.n_classes))
bc.fit(data)
gene_clusters = bc.row_labels_
cell_clusters = bc.column_labels_
return cell_clusters
def test_spectral_coclustering():
# Test Dhillon's Spectral CoClustering on a simple problem.
param_grid = {
'svd_method': ['randomized', 'arpack'],
'n_svd_vecs': [None, 20],
'mini_batch': [False, True],
'init': ['k-means++'],
'n_init': [10],
'n_jobs': [1]
}
random_state = 0
S, rows, cols = make_biclusters((30, 30),
3,
noise=0.5,
random_state=random_state)
S -= S.min() # needs to be nonnegative before making it sparse
S = np.where(S < 1, 0, S) # threshold some values
for mat in (S, csr_matrix(S)):
for kwargs in ParameterGrid(param_grid):
model = SpectralCoclustering(n_clusters=3,
random_state=random_state,
**kwargs)
model.fit(mat)
assert_equal(model.rows_.shape, (3, 30))
assert_array_equal(model.rows_.sum(axis=0), np.ones(30))
assert_array_equal(model.columns_.sum(axis=0), np.ones(30))
assert_equal(consensus_score(model.biclusters_, (rows, cols)), 1)
_test_shape_indices(model)
def test_spectral_coclustering():
"""Test Dhillon's Spectral CoClustering on a simple problem."""
param_grid = {'svd_method': ['randomized', 'arpack'],
'n_svd_vecs': [None, 20],
'mini_batch': [False, True],
'init': ['k-means++'],
'n_init': [10],
'n_jobs': [1]}
random_state = 0
S, rows, cols = make_biclusters((30, 30), 3, noise=0.5,
random_state=random_state)
S -= S.min() # needs to be nonnegative before making it sparse
S = np.where(S < 1, 0, S) # threshold some values
for mat in (S, csr_matrix(S)):
for kwargs in ParameterGrid(param_grid):
model = SpectralCoclustering(n_clusters=3,
random_state=random_state,
**kwargs)
model.fit(mat)
assert_equal(model.rows_.shape, (3, 30))
assert_array_equal(model.rows_.sum(axis=0), np.ones(30))
assert_array_equal(model.columns_.sum(axis=0), np.ones(30))
assert_equal(consensus_score(model.biclusters_,
(rows, cols)), 1)
def update_bicluster(batch_df, task_df, compound_df, mode='RobustMT', K=5):
if mode == 'RobustMT':
n_tasks = task_df.shape[1] - 1
elif mode == 'ST':
n_tasks = 1
elif mode == 'MT':
n_tasks = task_df.shape[1]
if not mode == 'ST':
# cocluster of the minibatch predictive matrix
X = preprocessing.scale(np.matrix(batch_df)[:, 0:n_tasks])
cocluster = SpectralCoclustering(n_clusters=K, random_state=0)
cocluster.fit(X)
batch_df['batch_label'] = cocluster.row_labels_
else:
rank_x = batch_df[batch_df.columns[0]].rank().tolist()
groups = pd.qcut(rank_x, K, duplicates='drop')
batch_df['batch_label'] = groups.codes
# generate color hex for batch_label
lut = dict(zip(batch_df['batch_label'].unique(), Category20_20))
batch_df['batch_label_color'] = batch_df['batch_label'].map(lut)
# generate color hex for compound_df
lut2 = dict(zip(batch_df['Label_id'], batch_df['batch_label_color']))
compound_df['batch_label_color'] = compound_df['label'].map(lut2)
lut22 = dict(zip(batch_df['Label_id'], batch_df['batch_label']))
compound_df['batch_label'] = compound_df['label'].map(lut22)
groups = pd.qcut(compound_df['label'].tolist(),
len(Category20b_20),
duplicates='drop')
c = [Category20b_20[xx] for xx in groups.codes]
compound_df['label_color'] = c
return batch_df, task_df, compound_df
def correlation_matrix(df):
sns.set(style='white', font_scale=.9)
clusters = 4
pearson = df.drop(['asset', 'unixtime'], axis=1).corr(method='pearson')
clust = SpectralCoclustering(n_clusters=clusters, random_state=0)
clust.fit(pearson)
pearson = pearson.iloc[np.argsort(clust.row_labels_)[::-1],
np.argsort(clust.column_labels_)]
grid = dict(width_ratios=[1.5, pearson.shape[1]])
fig, axs = plt.subplots(1, 2, figsize=(10, 8), gridspec_kw=grid)
sns.heatmap(data=np.sort(clust.row_labels_)[::-1].reshape(-1, 1),
ax=axs[0],
cbar=False,
linewidths=.005,
cmap=sns.color_palette('Spectral'))
axs[0].set(xticks=(), yticks=())
sns.heatmap(data=pearson,
cmap=sns.diverging_palette(220, 10, n=11),
linewidths=.005,
cbar_kws={'shrink': .75},
vmax=1,
vmin=-1,
ax=axs[1])
axs[1].set_xticklabels(pearson.columns, rotation='vertical')
axs[1].set_yticklabels(pearson.index, rotation='horizontal')
fig.suptitle(f'Variable Correlation Matrix in {clusters} Clusters',
fontsize=20)
fig.tight_layout(w_pad=.5, rect=(.03, 0, 1, .95))
fig.savefig('reports/correlation_matrix.png')
def print_similarity_matrix(sphns, model, model2=None):
print " ",
for phn1 in sphns:
print phn1, " ",
print ""
m = np.ndarray((len(sphns), len(sphns)), dtype=np.float32)
for i, phn1 in enumerate(sphns):
print phn1.ljust(4) + ":",
for j, phn2 in enumerate(sphns):
sim = model.similarity(phn1, phn2)
if model2 != None:
sim -= model2.similarity(phn1, phn2)
print "%0.2f" % sim,
m[i][j] = sim
print ""
phn_order = [phn for phn in sphns]
if BICLUSTER:
#model = SpectralBiclustering(n_clusters=4, method='log',
model = SpectralCoclustering(n_clusters=n_clusters,
random_state=0)
model.fit(m)
print "INDICES:",
indices = [model.get_indices(i) for i in xrange(n_clusters)]
print indices
tmp = []
for i in xrange(n_clusters):
tmp.extend([phn_order[indices[i][0][j]] for j in xrange(len(indices[i][0]))])
phn_order = tmp
fit_data = m[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
m = fit_data
return phn_order, m
def bi_clustering(data, args):
print 'clustering...'
# max_val = np.max(np.max(data))
# data = -np.exp(data / data.std())
max_val = np.max(np.max(data))
data[data == 0] = max_val
data = data / max_val
model = SpectralCoclustering(n_clusters=args.k, svd_method='arpack')
model.fit(data)
np.savetxt(args.o, model.row_labels_, fmt="%d", newline="\n")
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
if not args.plot:
return
plt.matshow(shuffle(data), cmap=plt.cm.Blues)
plt.title("Org dataset")
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
def bicluster(*cotables):
table = cotables[0]
model = SpectralCoclustering(n_clusters=table.shape[1], random_state=0)
model.fit(table.as_matrix())
return [
cotable.iloc[np.argsort(model.row_labels_),
np.argsort(model.column_labels_)] for cotable in cotables
]
def spectral_co_cluster(data, n_clusters, para_jobs=1, random_state=None):
from sklearn.cluster.bicluster import SpectralCoclustering
model = SpectralCoclustering(n_clusters,
random_state=random_state,
n_jobs=para_jobs)
model.fit(data)
row_labels = model.row_labels_
col_labels = model.column_labels_
return row_labels, col_labels
def biclustering(input,num_clusters):
global agent1_dict
data = np.matrix(input)
model = SpectralCoclustering(n_clusters=num_clusters,random_state=0)
model.fit(data)
#create agent 1 dictionary
agent1_dict = {}
for c in range(num_clusters):
agent1_dict[c] = model.get_indices(c)[0].tolist() #0 row indices, 1 column indices
return agent1_dict
def get_clusters(data):
coclusters = SpectralCoclustering(n_clusters=5, random_state=0)
coclusters.fit(data)
word_clusters = []
hidden_clusters = []
for i in range(5):
wc = coclusters.get_indices(i)[0]
hc = coclusters.get_indices(i)[1]
word_clusters.append(wc.tolist())
hidden_clusters.append(hc.tolist())
return word_clusters, hidden_clusters
def biclustering(data,num_clusters):
clusters = {}
data = np.asmatrix(data)
model = SpectralCoclustering(n_clusters=num_clusters,random_state=0)
#model = SpectralBiclustering(n_clusters=num_clusters)
model.fit(data)
for c in range(num_clusters):
clusters[c] = model.get_indices(c)[0].tolist() #0 row indices, 1 column indices
#fit_data = data[np.argsort(model.row_labels_)]
#fit_data = fit_data[:, np.argsort(model.column_labels_)]
#plot(fit_data)
return clusters
def main():
origin = open('kddcup.txt', 'r')
lines = origin.readlines()
x = []
label = []
for l in lines:
l = l.split(',')
d = l[0:1] + l[4:19] + l[21:-1]
label.append(l[-1])
x.append(d)
data = np.array(x, dtype='float32')
model = SpectralCoclustering(n_clusters=5)
model.fit(data)
evaluation = []
draw_n_x = []
draw_n_y = []
draw_a_x = []
draw_a_y = []
for cluster in model.rows_:
normal = 0.0
attack = 0.0
graph_x = []
graph_y = []
for idx in range(len(cluster)):
if cluster[idx]:
if label[idx] == 'normal.\n':
normal += 1
else:
attack += 1
graph_x.append(data[27])
graph_y.append(data[30])
evaluation.append(normal / (normal + attack))
if normal > attack:
draw_n_x += graph_x
draw_n_y += graph_y
else:
draw_a_x += graph_x
draw_a_y += graph_y
pl.plot(draw_n_x, draw_n_y, 'ro')
pl.plot(draw_a_x, draw_a_y, 'go')
print evaluation
pl.show()
def biclustering(input,num_clusters):
global agent1_dict
data = np.matrix(input)
model = SpectralCoclustering(n_clusters=num_clusters,random_state=0)
model.fit(data)
#create agent 1 dictionary
agent1_dict = {}
for c in range(num_clusters):
agent1_dict[c] = model.get_indices(c)[0].tolist() #0 row indices, 1 column indices
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plot(fit_data)
return agent1_dict
def cluster_data(flavors, whisky):
corr_whisky = pd.DataFrame.corr(flavors.transpose())
model = SpectralCoclustering(n_clusters=6, random_state=0)
model.fit(corr_whisky)
whisky['Group'] = pd.Series(model.row_labels_, index=whisky.index)
whisky = whisky.ix[np.argsort(model.row_labels_)]
whisky = whisky.reset_index(drop=True)
correlation = pd.DataFrame.corr(whisky.iloc[:, 2:14].transpose())
correlation = np.array(correlation)
# print(np.sum(model.rows_, axis=1))
# print(np.sum(model.rows_, axis=0))
# print(model.row_labels_)
# print(correlation)
plot_correlations(correlation)
def plot_coclusters_raw_data(time_ms, t=False):
# take the transpose of sliced matrix
if t:
channels_data = slice_matrix(matrix, time_ms)
else:
channels_data = slice_matrix(matrix, time_ms)
print len(channels_data), len(channels_data[1])
z_score = stats.zscore(channels_data)
plt.title('Z Score Biclustering Over %i ms' % time_ms)
spectral_model = SpectralCoclustering()
spectral_model.fit(z_score)
fit_data = z_score[np.argsort(spectral_model.row_labels_)]
fit_data = fit_data[:, np.argsort(spectral_model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.savefig('z_score_raw_coclustering_all_ts_%i_T_%s.svg' % (time_ms, str(t)))
def cocluster(self, mx, blockdiag=False):
logging.info('Co-clustering Tade..')
if blockdiag:
logging.info('blockdiag')
clusser = SpectralCoclustering(n_jobs=-1)
else: # checkerboard
logging.info('checkerboard')
clusser = SpectralBiclustering(n_jobs=-1, n_clusters=(4,3))
#n_clusters=3, svd_method='randomized',
clusser.fit(mx)
logging.info('Argsorting mx rows..')
mx = mx[np.argsort(clusser.row_labels_)]
self.prev = self.prev[np.argsort(clusser.row_labels_)]
logging.info('Argsorting mx cases..')
mx = mx[:, np.argsort(clusser.column_labels_)]
self.case = self.case[np.argsort(clusser.column_labels_)]
return mx
def main():
files = [DATA_DIR + file for file in os.listdir(DATA_DIR) if fnmatch.fnmatch(file, '*.csv')]
for i in files:
print('processing', i, '...')
table = get_data(i)
cl = SpectralCoclustering(n_clusters=2, random_state=0)
cl.fit(table)
# using http://scikit-learn.org/stable/auto_examples/bicluster/plot_spectral_coclustering.html
fit_data = table[np.argsort(cl.row_labels_)]
fit_data = fit_data[:, np.argsort(cl.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Reds)
plt.title(i[len(DATA_DIR):])
# plt.show()
plt.savefig(i[len(DATA_DIR):-4] + '.pdf')
def main(model):
store = pd.HDFStore(model)
from_ = store['from_'][0][0]
to = store['to'][0][0]
assert from_ == 0
trace_fpath = store['trace_fpath'][0][0]
Theta_zh = store['Theta_zh'].values
Psi_oz = store['Psi_sz'].values
count_z = store['count_z'].values[:, 0]
Psi_oz = Psi_oz / Psi_oz.sum(axis=0)
Psi_zo = (Psi_oz * count_z).T
Psi_zo = Psi_zo / Psi_zo.sum(axis=0)
obj2id = dict(store['source2id'].values)
hyper2id = dict(store['hyper2id'].values)
id2obj = dict((v, k) for k, v in obj2id.items())
ZtZ = Psi_zo.dot(Psi_oz)
ZtZ = ZtZ / ZtZ.sum(axis=0)
L = ZtZ
#ZtZ[ZtZ < (ZtZ.mean())] = 0
L[ZtZ >= 1.0 / (len(ZtZ))] = 1
L[L != 1] = 0
colormap = toyplot.color.brewer.map("Purples", domain_min=0, domain_max=1, reverse=True)
print(colormap)
canvas = toyplot.matrix((L.T, colormap), label="P[z' | z]", \
colorshow=False, tlabel="To z'", llabel="From")[0]
#canvas.axes(ylabel='From z', xlabel='To z\'')
toyplot.pdf.render(canvas, 'tmat.pdf')
model = SpectralCoclustering(n_clusters=3)
model.fit(L)
fit_data = L[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
canvas = toyplot.matrix((fit_data, colormap), label="P[z' | z']", \
colorshow=False)[0]
toyplot.pdf.render(canvas, 'tmat-cluster.pdf')
#AtA = Psi_oz.dot(Psi_zo)
#np.fill_diagonal(AtA, 0)
#AtA = AtA / AtA.sum(axis=0)
store.close()
def cocluster(self, mx, blockdiag=False):
logging.info('Co-clustering Tade..')
if blockdiag:
logging.info('blockdiag')
clusser = SpectralCoclustering(n_jobs=-1)
else: # checkerboard
logging.info('checkerboard')
clusser = SpectralBiclustering(n_jobs=-1, n_clusters=(4, 3))
#n_clusters=3, svd_method='randomized',
clusser.fit(mx)
logging.info('Argsorting mx rows..')
mx = mx[np.argsort(clusser.row_labels_)]
self.prev = self.prev[np.argsort(clusser.row_labels_)]
logging.info('Argsorting mx cases..')
mx = mx[:, np.argsort(clusser.column_labels_)]
self.case = self.case[np.argsort(clusser.column_labels_)]
return mx
def biclustering(db):
#mydata = genfromtxt('/home/fan/intern/process_db/analysis/viewtime_matrix_524.csv',dtype=None,delimiter=',',names=True,skip_header=1)
df = pd.read_csv(
'/home/fan/intern/process_db/analysis/viewtime_matrix_501_0.1.csv')
dma = 501
#print df.head()
print df.shape
dev_list = df.ix[:, 0].values
prog_list = df.columns.values
#print type(dev_list)
#print type(prog_list)
df.drop(df.columns[0], axis=1, inplace=True)
#df[df==0] = 1
df = df.apply(fraction, axis=1)
#print df.head()
#print df.values
#print type(df.values)
#mydata = df.values
#mydata=np.delete(mydata, 0, axis=0)
#mydata=np.delete(mydata, 0, axis=1)
#mydata[mydata==0] = 0.01
#print 'data format is:',mydata,type(mydata)
# model=SpectralCoclustering(n_clusters=5, random_state=0)
#n_clusters=(1000,20) # 4*3 = 12 clusters
#model = SpectralBiclustering(random_state=None)
model = SpectralCoclustering(n_clusters=10)
model.fit(df)
#fit_data=mydata[np.argsort(model.row_labels_)]
#fit_data=fit_data[:,np.argsort(model.column_labels_)]
#plt.matshow(fit_data[0:40],cmap=plt.cm.Blues)
# plt.show()
print model.get_params()
for i in range(0, 5):
print 'Size of one cluster:', model.get_shape(i)
indices = model.get_indices(i)
#print indices[1]
print prog_list[indices[1]]
print model.get_submatrix(i, df.values)
dev_in_cluster = dev_list[indices[0]]
#print type(dev_in_cluster)
print 'number of devices within this cluster:', len(dev_in_cluster)
get_income(db, dma, dev_in_cluster.tolist())
def biclustering(input_list,num_clusters):
global agent1_dict
#clustering agent 1
data = np.matrix(input_list)
#plot(data)#original data
#model = SpectralBiclustering(n_clusters=num_clusters) #Biclustering refer http://scikit-learn.org/stable/auto_examples/bicluster/plot_spectral_biclustering.html#example-bicluster-plot-spectral-biclustering-py
model = SpectralCoclustering(n_clusters=num_clusters,random_state=0) #Coclustering refer http://scikit-learn.org/stable/auto_examples/bicluster/plot_spectral_coclustering.html
model.fit(data)
#create agent 1 dictionary
agent1_dict = {}
for c in range(num_clusters):
agent1_dict[c] = model.get_indices(c)[0].tolist() #0 row indices, 1 column indices
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plot(fit_data)
return agent1_dict
def spectral_coclustering(cls, *args):
"""
Wrapper method for the spectral_coclustering algorithm
:param args: the arguments to be sent to the sci-kit implementation
:return: returns the Biclustering object
"""
model = SpectralCoclustering(*args)
return cls(model)
def Spectral_CoClustering(args):
'''Function to perform bipartite clustering'''
# Create model
try:
if args.arpack:
model = SpectralCoclustering(
n_clusters=args.nClusters, svd_method='arpack')
else:
model = SpectralCoclustering(
n_clusters=args.nClusters)
except:
print '-r 1 may cause problems when svd_method has been set to arpack'
print('Running coclustering')
model.fit(args.M.tocsc())
print('Coclustering done')
# Fit to data
# fit_data = args.M[np.argsort(model.row_labels_)]
# fit_data = fit_data[:, np.argsort(model.column_labels_)]
fit_data = args.M.tocoo()
fit_data.row = invert_permutation(np.argsort(model.row_labels_))[fit_data.row]
fit_data.col = invert_permutation(np.argsort(model.column_labels_))[fit_data.col]
save_clusters(model, fit_data, args, '_CoClustering')
return model, fit_data
def plot_biclusters():
co_grid = ParameterGrid(
{'n_clusters': np.arange(2, 10, 1), 'n_init': [20]}
)
_y = pd.read_csv('./../../data_source/to_analysis/original_images/dfs_original_images.csv', index_col=0)
y_orig = np.squeeze(_y.values)
X_orig = pd.read_csv('./../../data_source/to_analysis/original_images/all_features_original_images.csv', index_col=0)
scaler = StandardScaler()
X_orig_std = scaler.fit_transform(X_orig.values)
#_run_experiment(co_grid, X_orig_std)
df_avg_co_scores = pd.read_csv('bic_scores.csv', index_col=0)
best_co_config = co_grid[
np.argmin(df_avg_co_scores.loc[:, 'tvr'].values) - 1
]
print(best_co_config, min(df_avg_co_scores.loc[:, 'tvr'].values))
orig_co_model = SpectralCoclustering(random_state=0, svd_method='arpack')
orig_co_model.set_params(**best_co_config)
orig_co_model.fit(X_orig_std)
#plt.figure()
#_plot_tve(df_avg_co_scores, co_grid)
plt.figure()
_plot_bicmaps(X_orig_std, best_co_config)
def cluster_ex_by_feature_matrix(sub_ex_by_feat_mat, plot_file):
if sub_ex_by_feat_mat.shape[0] > 50000:
print "Matrix too large to be efficient, pleased reduce number of examples"
# Subset down to motifs that are used
plot_df = sub_ex_by_feat_mat[:,
np.apply_along_axis(
np.max, 0, sub_ex_by_feat_mat.toarray()
) != 0]
# for numpy array
plot_df = sub_ex_by_feat_mat_1[np.apply_along_axis(
lambda row:
(row != 0).sum(), 1, sub_ex_by_feat_mat_1.toarray()) > 10, :]
plot_df = plot_df[:,
np.apply_along_axis(lambda column:
(column != 0).sum(), 0,
sub_ex_by_feat_mat_1.toarray()) > 50]
# for pandas
plot_df = sub_ex_by_feat_df2.ix[
sub_ex_by_feat_df2.apply(lambda row: (row != 0).sum(), 1) > 10, :]
plot_df = plot_df.ix[:,
plot_df.apply(lambda row: (row != 0).sum(), 0) > 50]
plot_df = sub_ex_by_feat_df2
np.apply_along_axis(lambda column: (column != 0).sum(), 0,
sub_ex_by_feat_mat_1.toarray())
model = SpectralCoclustering(n_clusters=50)
model.fit(plot_df) # fits for 50K
fit_data = plot_df.ix[np.argsort(model.row_labels_)]
fit_data = fit_data.ix[:, np.argsort(model.column_labels_)]
plt.figure()
plt.matshow(fit_data.ix[0:500, ], cmap=plt.cm.YlGnBu, aspect='auto')
plt.savefig(plot_file)
print "DONE: biclustering plot here: {0}".format(plot_file)
return "pretty picture"
def _plot_bicmaps(X_orig_std, best_co_config):
# Train model with best config.
orig_co_model = SpectralCoclustering(random_state=0, svd_method='arpack')
orig_co_model.set_params(**best_co_config)
orig_co_model.fit(X_orig_std)
orig_co_row_sorted = X_orig_std[np.argsort(orig_co_model.row_labels_), :]
orig_co_fit_data = orig_co_row_sorted[:, np.argsort(orig_co_model.column_labels_)]
hmap = sns.heatmap(
orig_co_fit_data,
robust=True,
cmap=plt.cm.viridis,
fmt='f',
vmin=np.min(orig_co_fit_data),
vmax=np.max(orig_co_fit_data),
cbar=False
)
coords = bic_coords(orig_co_model, best_co_config['n_clusters'])
for num in coords.index:
plt.plot(
(coords.loc[num, ['x1', 'x2', 'x2', 'x1', 'x1']]),
(coords.loc[num, ['y1', 'y1', 'y2', 'y2', 'y1']]),
c='darkred'
)
plt.ylabel('Patients')
plt.xlabel('Features')
plt.yticks([], [])
plt.xticks([], [])
ax_divider = make_axes_locatable(hmap)
cax = ax_divider.append_axes('right', size='3%', pad='2%')
colorbar.colorbar(
hmap.get_children()[0],
cax=cax,
orientation='vertical'
)
#cax.xaxis.set_label_text('AUC', fontname='Sans')
#cax.xaxis.set_label_position('top')
cbar_ticks = np.linspace(
np.nanmin(orig_co_fit_data),
np.nanmax(orig_co_fit_data),
6
)
cax.yaxis.set_ticks(cbar_ticks)
cax.yaxis.set_ticklabels([f'{num:.01f}' for num in cbar_ticks])
plt.savefig(
'../biclustering/bic_map_original_images.pdf',
bbox_inches='tight',
transparent=True,
dpi=CONFIG.DPI,
)
def _get_clusters_using_spectrals(corrarr, n_clusters=5, mode='co'):
if mode=='co':
model = SpectralCoclustering(n_clusters, random_state=0)
model.fit(corrarr)
indices = np.arange(corrarr.columns.size)
clusters = [indices[x].tolist() for x in model.columns_]
return clusters
elif mode=='bi':
model = SpectralBiclustering(n_clusters, random_state=0)
model.fit(corrarr)
indices = np.arange(corrarr.columns.size)
clusters = [indices[x].tolist() for x in model.columns_]
repetition_start = clusters[1:].index(clusters[0]) + 1
return clusters[:repetition_start]
else:
raise("Mode wrong?")
def _run_experiment(co_grid, X_orig_std):
np.random.seed(seed=0)
random_states = np.random.choice(40, size=40)
avg_co_scores = {}
for num, co_param_config in enumerate(co_grid):
orig_co_scores = []
for random_state in random_states:
orig_co_model = SpectralCoclustering(random_state=random_state, svd_method='arpack')
# NOTE: Outputs a TVE score.
orig_co_clusters = biclusters(orig_co_model, X_orig_std, co_param_config)
orig_co_scores.append(orig_co_clusters.external_metrics.values)
avg_co_scores[num] = np.nanmean(orig_co_scores, axis=0)
avg_orig_co_scores = []
for num, scores in enumerate(avg_co_scores.values()):
avg_orig_co_scores.append(np.mean(scores, axis=0))
df_avg_co_scores = pd.DataFrame(avg_orig_co_scores, columns=['tvr'])
df_avg_co_scores.index.name = 'ConfigID'
df_avg_co_scores.to_csv('bic_scores.csv')
def Block_diagonal(input_path,top_sd,n_clusters,output_path):
###input data
input_dat=pd.read_csv(input_path,index_col=0,sep='\t',comment='#')
### get index and sample name
# get_index = input_dat.index.astype(str)+'_'+input_dat.ix[:,0].astype(str)+'_'+\
# input_dat.ix[:,1].astype(str)+'_'+input_dat.ix[:,2].astype(str)
# get_samp_name = input_dat.columns[3:]
pro_dat = input_dat.fillna(0)
# pro_dat = pro_dat.ix[:,3:]
# pro_dat.index = get_index
# pro_dat.columns = get_samp_name
# pro_dat = 2**pro_dat-1
df_sd = pro_dat.apply(np.std,axis=1)
df_sd_sort = df_sd.sort_values(ascending = False)
df_sd_sort_top = df_sd_sort.ix[:int(len(df_sd_sort)*top_sd)]
pro_dat = pro_dat.ix[df_sd_sort_top.index,:]
sd_index = pro_dat.index
sd_sample_names = pro_dat.columns
#plt.matshow(pro_dat, cmap=plt.cm.Blues)
#plt.title("Original dataset")
### model
model = SpectralCoclustering(n_clusters=n_clusters, random_state=0)
model.fit(pro_dat)
pro_dat = np.array(pro_dat)
fit_data = pro_dat[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
### output the model fitting data
fit_data = pd.DataFrame(fit_data)
fit_data.index = sd_index[np.argsort(model.row_labels_)]
fit_data.columns = sd_sample_names[np.argsort(model.column_labels_)]
out_fit_data_path = os.path.join(output_path,'fit_data.csv')
fit_data.to_csv(out_fit_data_path)
### output image
fig = plt.figure(figsize=(20,40))
ax = fig.add_subplot(111)
ax.matshow(fit_data, cmap=plt.cm.Blues)
#cax = ax.matshow(pro_dat, interpolation='nearest')
#fig.colorbar(cax)
ax.set_title("After biclustering; rearranged to show biclusters")
# ax.set_xticklabels(fit_data.columns )
# ax.set_yticklabels(fit_data.index)
out_img_path = os.path.join(output_path,'bicluster.png')
fig.savefig(out_img_path)
### output module
a11 = pd.Series(model.row_labels_)
b11 = pd.Series(model.column_labels_)
c11 = a11.groupby(a11).size()
c22 = b11.groupby(b11).size()
d11 = pd.DataFrame(a11.sort_values().values,fit_data.index.values)
d22 = pd.DataFrame(b11.sort_values().values,fit_data.columns.values)
d11.columns = ['cpg_module']
d22.columns = ['sample_module']
out_module_path = os.path.join(output_path,'output.xlsx')
writer = pd.ExcelWriter(out_module_path)
d11.to_excel(writer,'Sheet1')
d22.to_excel(writer,'Sheet2')
writer.save()
#
print("\n")
print("cpg module:")
print(c11)
print("\n")
print("sample module:")
print(c22)
for row in ratings:
user_id = user_ids.index(row[0])
profile_id = profile_ids.index(row[1])
user_profile_matrix[user_id,profile_id] = row[2]
#find number of users and movies in each bicluster
'''G = nx_graph_from_biadjacency_matrix(user_movie_matrix)
nx.draw(G)
plt.show()'''
#initialize and carry out clustering
K=50
scc = SpectralCoclustering(n_clusters = K,svd_method='arpack')
scc.fit(user_profile_matrix)
#labels
row_labels = scc.row_labels_
column_labels = scc.column_labels_
bicluster_num_users=np.zeros(K)
bicluster_num_profiles=np.zeros(K)
bicluster_list_users=[]
bicluster_list_profiles=[]
for i in range(K):
bicluster_list_users.append([])
# exclude 'comp.os.ms-windows.misc'
categories = ['alt.atheism', 'comp.graphics',
'comp.sys.ibm.pc.hardware', 'comp.sys.mac.hardware',
'comp.windows.x', 'misc.forsale', 'rec.autos',
'rec.motorcycles', 'rec.sport.baseball',
'rec.sport.hockey', 'sci.crypt', 'sci.electronics',
'sci.med', 'sci.space', 'soc.religion.christian',
'talk.politics.guns', 'talk.politics.mideast',
'talk.politics.misc', 'talk.religion.misc']
newsgroups = fetch_20newsgroups(categories=categories)
y_true = newsgroups.target
vectorizer = TfidfVectorizer(stop_words='english', min_df=5,
tokenizer=number_aware_tokenizer)
cocluster = SpectralCoclustering(n_clusters=len(categories),
svd_method='arpack', random_state=0)
kmeans = MiniBatchKMeans(n_clusters=len(categories), batch_size=20000,
random_state=0)
print("Vectorizing...")
X = vectorizer.fit_transform(newsgroups.data)
print("Coclustering...")
start_time = time()
cocluster.fit(X)
y_cocluster = cocluster.row_labels_
print("Done in {:.2f}s. V-measure: {:.4f}".format(
time() - start_time,
v_measure_score(y_cocluster, y_true)))
print("MiniBatchKMeans...")
import pandas as pd
from bokeh.models import HoverTool, ColumnDataSource
from bokeh.plotting import figure, output_file, show
from sklearn.cluster.bicluster import SpectralCoclustering
data = pd.read_csv('docs/whiskies.txt')
data['Region'] = pd.read_csv('docs/regions.txt')
correlations = np.array(data.iloc[:, 2:14].transpose().corr())
plt.figure(figsize=(10, 4))
plt.subplot(121)
plt.title("Original")
plt.pcolor(correlations, cmap='inferno')
plt.colorbar()
model = SpectralCoclustering(n_clusters=6, random_state=0)
model.fit(correlations)
data['Group'] = model.row_labels_
data = data.ix[np.argsort(model.row_labels_)]
data = data.reset_index(drop=True)
correlations = correlations[np.argsort(model.row_labels_), :]
correlations = correlations[:, np.argsort(model.row_labels_)]
plt.subplot(122)
plt.title("Rearranged")
plt.pcolor(correlations, cmap='inferno')
plt.colorbar()
plt.savefig('plots/classifying_whiskies_1')
group_colors = ['red', 'yellow', 'green', 'blue', 'purple', 'orange']
correlation_colors = []
for i in range(len(correlations)):
from sklearn.cluster.bicluster import SpectralCoclustering
from sklearn.metrics import consensus_score
data, rows, columns = make_biclusters(shape=(300, 300),
n_clusters=5,
noise=5,
shuffle=False,
random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Original dataset")
data, row_idx, col_idx = sg._shuffle(data, random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Shuffled dataset")
model = SpectralCoclustering(n_clusters=6, random_state=0)
model.fit(data)
score = consensus_score(model.biclusters_,
(rows[:, row_idx], columns[:, col_idx]))
print("consensus score: {:.3f}".format(score))
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
# exclude 'comp.os.ms-windows.misc'
categories = ['alt.atheism', 'comp.graphics',
'comp.sys.ibm.pc.hardware', 'comp.sys.mac.hardware',
'comp.windows.x', 'misc.forsale', 'rec.autos',
'rec.motorcycles', 'rec.sport.baseball',
'rec.sport.hockey', 'sci.crypt', 'sci.electronics',
'sci.med', 'sci.space', 'soc.religion.christian',
'talk.politics.guns', 'talk.politics.mideast',
'talk.politics.misc', 'talk.religion.misc']
newsgroups = fetch_20newsgroups(categories=categories)
y_true = newsgroups.target
vectorizer = TfidfVectorizer(stop_words='english', min_df=5,
tokenizer=number_aware_tokenizer)
cocluster = SpectralCoclustering(n_clusters=len(categories),
svd_method='arpack', random_state=0)
kmeans = MiniBatchKMeans(n_clusters=len(categories), batch_size=20000,
random_state=0)
print("Vectorizing...")
X = vectorizer.fit_transform(newsgroups.data)
print("Coclustering...")
start_time = time()
cocluster.fit(X)
y_cocluster = cocluster.row_labels_
print("Done in {:.2f}s. V-measure: {:.4f}".format(
time() - start_time,
v_measure_score(y_cocluster, y_true)))
print("MiniBatchKMeans...")
plt.figure(figsize=(15, 25))
sns.heatmap(cluster_counts / cluster_counts.sum(1)[:, np.newaxis],
yticklabels=cluster_cell_types,
vmin=0,
vmax=1,
linewidths=0.5)
plt.xlabel('UNCURL clusters')
plt.ylabel('Seurat clusters')
plt.title('SCH Cerebellum Clusters')
plt.savefig('uncurl_vs_seurat_clusters.png', dpi=200)
# do a biclustering
from sklearn.cluster.bicluster import SpectralCoclustering
spec = SpectralCoclustering(18)
cluster_counts_subset = np.vstack(
[cluster_counts[:31, :], cluster_counts[32:, :]])
spec.fit(cluster_counts + 0.0001)
row_labels = spec.row_labels_
column_labels = spec.column_labels_
row_order = np.argsort(row_labels)
col_order = np.argsort(column_labels)
#row_labels = row_labels[row_order]
#col_labels = column_labels[col_order]
cluster_counts_reordered = cluster_counts[row_order, :]
cluster_counts_reordered = cluster_counts_reordered[:, col_order]
cluster_cell_types_2 = np.array(
def test_co_clustering():
import numpy as np
import nibabel as nb
from matplotlib import pyplot as plt
import sklearn as sk
from sklearn.datasets import make_biclusters
from sklearn.datasets import samples_generator as sg
from sklearn.cluster.bicluster import SpectralCoclustering
from sklearn.metrics import consensus_score
# REAL DATA
subject_file = '/Users/aki.nikolaidis/Desktop/NKI_SampleData/A00060280/3mm_bandpassed_demeaned_filtered_antswarp.nii.gz'
roi_mask_file = home + '/git_repo/basc/masks/BG_3mm.nii.gz'
roi2_mask_file = home + '/git_repo/basc/masks/yeo2_3mm.nii.gz'
data = nb.load(subject_file).get_data().astype('float32')
print('Data Loaded')
print('Setting up NIS')
roi_mask_file_nb = nb.load(roi_mask_file)
roi2_mask_file_nb = nb.load(roi2_mask_file)
roi_mask_nparray = nb.load(roi_mask_file).get_data().astype(
'float32').astype('bool')
roi2_mask_nparray = nb.load(roi2_mask_file).get_data().astype(
'float32').astype('bool')
roi1data = data[roi_mask_nparray]
roi2data = data[roi2_mask_nparray]
#add code that uploads the roi1data and roi2data, divides by the mean and standard deviation of the timeseries
roi1data = sk.preprocessing.normalize(roi1data, norm='l2')
roi2data = sk.preprocessing.normalize(roi2data, norm='l2')
dist_btwn_data_1_2 = np.array(
sp.spatial.distance.cdist(roi1data, roi2data, metric='correlation'))
sim_btwn_data_1_2 = 1 - dist_btwn_data_1_2
sim_btwn_data_1_2[np.isnan(sim_btwn_data_1_2)] = 0
sim_btwn_data_1_2[sim_btwn_data_1_2 < 0] = 0
sim_btwn_data_1_2 = sim_btwn_data_1_2 + (np.random.rand(
len(sim_btwn_data_1_2), len(sim_btwn_data_1_2[1, :]))) / 100
sim_btwn_data_1_2[sim_btwn_data_1_2 > 1] = 1
sum(sum(sim_btwn_data_1_2 == np.inf))
sum(sum(sim_btwn_data_1_2 == np.nan))
model = SpectralCoclustering(n_clusters=5, random_state=0, n_init=100)
model.fit(sim_btwn_data_1_2)
fit_data = sim_btwn_data_1_2[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
#SIMULATION DATA
import numpy as np
from matplotlib import pyplot as plt
from sklearn.datasets import make_biclusters
from sklearn.datasets import samples_generator as sg
from sklearn.cluster.bicluster import SpectralCoclustering
from sklearn.metrics import consensus_score
#Creating Simulated Data
data, rows, columns = make_biclusters(shape=(300, 100),
n_clusters=5,
noise=5,
shuffle=False,
random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Original dataset")
data, row_idx, col_idx = sg._shuffle(data, random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Shuffled dataset")
#Creating Model
model = SpectralCoclustering(n_clusters=5, random_state=0)
model.fit(data)
score = consensus_score(model.biclusters_,
(rows[:, row_idx], columns[:, col_idx]))
print("consensus score: {:.3f}".format(score))
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
####################################################################
####################################################################
from sklearn import cluster
import scipy as sp
import time
from sklearn import cluster, datasets
import numpy as np
from matplotlib import pyplot as plt
from sklearn.datasets import make_biclusters
from sklearn.datasets import samples_generator as sg
from sklearn.cluster.bicluster import SpectralCoclustering
from sklearn.metrics import consensus_score
data1 = generate_simple_blobs(27)
data2 = generate_simple_blobs(27)
data2 = data2[0:150, :]
print("Calculating Cross-clustering")
print("Calculating pairwise distances between areas")
dist_btwn_data_1_2 = np.array(
sp.spatial.distance.cdist(roi1data, roi2data, metric='correlation'))
sim_btwn_data_1_2 = 1 - dist_btwn_data_1_2
sim_btwn_data_1_2[sim_btwn_data_1_2 < 0] = 0
co_cluster = cluster.SpectralCoclustering()
co_cluster.fit(sim_btwn_data_1_2)
score = consensus_score(co_cluster.biclusters_,
(rows[:, row_idx], columns[:, col_idx]))
print("consensus score: {:.3f}".format(score))
fit_data = data[np.argsort(co_cluster.row_labels_)]
fit_data = fit_data[:, np.argsort(co_cluster.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
listOfAbstracts = []
for paper in papers:
if 'Abstract' in paper['MedlineCitation']['Article'].keys():
listOfAbstracts.append(mergeAbstract(paper['MedlineCitation']['Article']['Abstract']['AbstractText']))
# Create TF-IDF matrix
vect = TfidfVectorizer(max_df = 1)
tfidf = vect.fit_transform(listOfAbstracts)
# Non-negative Matrix Factorization
num_topics = 2
num_top_words = 5
nmf = decomposition.NMF(n_components=num_topics, random_state=1)
doctopic = nmf.fit_transform(tfidf)
topic_words = []
vocab = np.array(vect.get_feature_names())
for topic in nmf.components_:
word_idx = np.argsort(topic)[::-1][0:num_top_words]
topic_words.append([vocab[i] for i in word_idx])
# Coclustering
cocluster = SpectralCoclustering(n_clusters=5,svd_method='arpack', random_state=0)
cocluster.fit(tfidf)
y_cocluster = cocluster.row_labels_
x_cocluster = cocluster.column_labels_
# print(np.array(vect.get_feature_names())[x_cocluster == 4])
#mM[np.where(np.logical_and(mM >= 0.25, mM < 1.25))] = 0.5
#mM[mM >= 1.25] = 1
#####
matDF = pd.DataFrame(MatOut).set_index(np.array(indx))
matDF.columns = areas
# Original plot
plt.matshow(MatOut, cmap=plt.cm.Blues)
plt.title("Original dataset")
clusters = 8 #6
model = SpectralCoclustering(n_clusters=clusters)
#model = SpectralBiclustering(n_clusters=clusters)
model.fit(matDF)
fitData_c = matDF.columns[np.argsort(model.column_labels_)]
matDF = matDF[fitData_c]
fitData_i = matDF.index[ np.argsort(model.row_labels_)]
matDF = matDF.reindex(fitData_i)
column_names = np.array([i[13:16] for i in fitData_c])
# plot
fig = plt.figure()
ax = fig.add_subplot(111)
km = KMeans(n_clusters=k)
km = km.fit(df.iloc[:,2:14])
SS.append(km.inertia_)
plt.plot(NC,SS)
plt.xlabel('k')
plt.ylabel('SS')
plt.show()
from sklearn.cluster.bicluster import SpectralCoclustering
flavour=df.iloc[:,2:14]
corr_whisky=pd.DataFrame.corr(flavour.transpose())
print(corr_whisky)
plt.figure(figsize=(8,8))
plt.pcolor(corr_whisky)
import pandas as pd
plt.colorbar()
model=SpectralCoclustering(n_clusters=5,random_state=45)
x=df["Distillery"]
df["disteliries_group"]=pd.Series(x,index=df.index)
cluster=list(zip(df.iloc[:,1],df.iloc[:,13]))
cluster=sorted(cluster, key=lambda x: x[1])
print("the resultant grouped classified whiskey based on their flavour")
print("\n")
c=pd.DataFrame(cluster)
print(c)
model1=pickle.dump(cluster,open('model1.pkl','wb'))
continue
# TODO hack: skip very long lists
if skip_thresh and len(sources) > skip_thresh:
continue
# All events have numbered tweets
rowSelector = np.array([row_lookup[source] for source in sources])
data[rowSelector, j] = 1
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Original dataset")
plt.savefig('%s_original.png' % (identifier), bbox_inches='tight')
model = SpectralCoclustering(n_clusters=n_clusters, random_state=0)
model.fit(data)
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged")
plt.savefig('%s_clustered.png' % (identifier), bbox_inches='tight')
avg_data = np.copy(data)
# Compute average value in each co-cluster for display purposes
for c in range(n_clusters):
for d in range(n_clusters):
print(coOccurencesMatrix)
print(coOccurencesMatrix.shape)
hashtags = vectorizer.get_feature_names()
hashtags = np.array(hashtags)
coOccurencesMatrix = np.where(coOccurencesMatrix == 0, 0, coOccurencesMatrix)
#coOccurencesMatrix = StandardScaler().fit_transform(coOccurencesMatrix)
print(coOccurencesMatrix)
import copy
coOccurencesMatrix2 = copy.deepcopy(coOccurencesMatrix)
coOccurencesMatrix2 = np.corrcoef(coOccurencesMatrix2)
coOccurencesMatrix = np.corrcoef(coOccurencesMatrix)
nbClusters = 40
model = SpectralCoclustering(n_clusters=nbClusters, random_state=1)
model.fit(coOccurencesMatrix)
print("fit")
print(coOccurencesMatrix)
fit_data = coOccurencesMatrix[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
hashtagsrow = hashtags[np.argsort(model.row_labels_)]
hashtagscolumns = hashtags[np.argsort(model.column_labels_)]
print("rowlavels")
print(model.row_labels_)
print("columnlzbels")
print(model.column_labels_)
print("hashtags")
print(hashtags)
print(fit_data.shape)
print(fit_data)
corr_flavors = pd.DataFrame.corr(flavors)
corr_flavors
plt.figure(figsize=(10,10))
plt.pcolor(corr_flavors)
plt.colorbar()
plt.savefig('./python_case_studies/whisky/corr_flavors.pdf')
corr_whisky = pd.DataFrame.corr(flavors.transpose())
plt.figure(figsize=(10,10))
plt.pcolor(corr_whisky)
plt.axis('tight')
plt.colorbar()
plt.savefig('./python_case_studies/whisky/corr_whisky.pdf')
model = SpectralCoclustering(n_clusters=6, random_state=0)
model.fit(corr_whisky)
model.rows_
np.sum(model.rows_, axis=1)
np.sum(model.rows_, axis=0)
model.row_labels_
whisky['Group'] = pd.Series(model.row_labels_, index=whisky.index)
whisky = whisky.ix[np.argsort(model.row_labels_)]
whisky = whisky.reset_index(drop=True)
correlations = pd.DataFrame.corr(whisky.iloc[:,2:14].transpose())
correlations = np.array(correlations)
os.mkdir('solution')
#n_clusters = (3, 2)
n_clusters = 20
arq = open('dados_v2.txt')
dados = np.array([map(float, a.split('\t')[:-1]) for a in arq.readlines()])
plt.matshow(zip(*dados), cmap=cm.PiYG)
plt.title("Original dataset")
pl.savefig('solution/original.png', bbox_inches=0)
#model = SpectralBiclustering(n_clusters=n_clusters, method='log', random_state=0)
model = SpectralCoclustering(n_clusters=n_clusters,
svd_method='arpack',
random_state=0)
model.fit(dados)
fit_data = dados[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(zip(*fit_data), cmap=cm.PiYG)
pl.savefig('solution/biclustered.png', bbox_inches=0)
plt.title("After biclustering; rearranged to show biclusters")
plt.matshow(zip(*np.outer(
np.sort(model.row_labels_) + 1,
np.sort(model.column_labels_) + 1)),
cmap=plt.cm.PiYG)
plt.title("Checkerboard structure of rearranged data")
pl.savefig('solution/biclustered and rearranged.png', bbox_inches=0)
this form of dimensionality reduction, some methods may perform better.
"""
return ("#NUMBER" if token[0].isdigit() else token for token in tokens)
class NumberNormalizingVectorizer(TfidfVectorizer):
def build_tokenizer(self):
tokenize = super(NumberNormalizingVectorizer, self).build_tokenizer()
return lambda doc: list(number_normalizer(tokenize(doc)))
dir = ROOT_DIR+'\\processed_data\\'
data = pickle.load(open(dir+'FT_raw_corpus_2013.p', 'rb'));
vectorizer = NumberNormalizingVectorizer(stop_words='english', min_df=5)
cocluster = SpectralCoclustering(n_clusters= 20,
svd_method='arpack', random_state=0)
kmeans = MiniBatchKMeans(n_clusters=20, batch_size=20000,
random_state=0)
print("Vectorizing...")
X = vectorizer.fit_transform(data)
print("Coclustering...")
start_time = time()
cocluster.fit(X)
y_cocluster = cocluster.row_labels_
print("MiniBatchKMeans...")
start_time = time()
y_kmeans = kmeans.fit_predict(X)
from sklearn.datasets import make_biclusters
from sklearn.datasets import samples_generator as sg
from sklearn.cluster.bicluster import SpectralCoclustering
from sklearn.metrics import consensus_score
data, rows, columns = make_biclusters(
shape=(300, 300), n_clusters=5, noise=5,
shuffle=False, random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Original dataset")
data, row_idx, col_idx = sg._shuffle(data, random_state=0)
plt.matshow(data, cmap=plt.cm.Blues)
plt.title("Shuffled dataset")
model = SpectralCoclustering(n_clusters=5, random_state=0)
model.fit(data)
score = consensus_score(model.biclusters_,
(rows[:, row_idx], columns[:, col_idx]))
print "consensus score: {:.3f}".format(score)
fit_data = data[np.argsort(model.row_labels_)]
fit_data = fit_data[:, np.argsort(model.column_labels_)]
plt.matshow(fit_data, cmap=plt.cm.Blues)
plt.title("After biclustering; rearranged to show biclusters")
plt.show()
cluster_colors = ["red", "orange", "green", "blue", "purple", "gray"]
regions = [
"Speyside", "Highlands", "Lowlands", "Islands", "Campbelltown", "Islay"
]
import numpy as np
region_colors = dict(zip(regions, cluster_colors)) ## ENTER CODE HERE! ##
print(region_colors)
#from lectures
import pandas as pd
import pylab as plt
whisky = pd.read_csv('whiskies.txt')
whisky['Region'] = pd.read_csv('regions.txt')
from sklearn.cluster.bicluster import SpectralCoclustering
model = SpectralCoclustering(n_clusters=6, random_state=0)
flavors = whisky.iloc[:, 2:14]
corr_flavors = pd.DataFrame.corr(flavors)
corr_whisky = pd.DataFrame.corr(flavors.transpose())
model.fit(corr_whisky)
whisky['Group'] = pd.Series(model.row_labels_, index=whisky.index)
whisky = whisky.ix[np.argsort(model.row_labels_)]
whisky = whisky.reset_index(drop=True)
correlations = pd.DataFrame.corr(whisky.iloc[:, 2:14].transpose())
correlations = np.array(correlations)
distilleries = list(whisky.Distillery)
correlation_colors = []
for i in range(len(distilleries)):
for j in range(len(distilleries)):
if correlations[i][
print(len(user_movie_matrix))
print(len(user_movie_matrix[0]))
#print(user_movie_matrix)
print(type(user_movie_matrix))
#find number of users and movies in each bicluster
'''G = nx_graph_from_biadjacency_matrix(user_movie_matrix)
nx.draw(G)
plt.show()'''
#initialize and carry out clustering
K=50
#km = KMeans(n_clusters = K)
#km.fit(user_movie_matrix)
scc = SpectralCoclustering(n_clusters = K,svd_method='arpack')
scc.fit(user_movie_matrix)
#labels
row_labels = scc.row_labels_
column_labels = scc.column_labels_
bicluster_num_users=np.zeros(K)
bicluster_num_movies=np.zeros(K)
#maintain a list of users per bicluster
bicluster_list_users=[]
#maintain a list of movies per bicluster
bicluster_list_movies=[]
for i in range(K):
bicluster_list_users.append([])