def cluster_data(self, row_distance="euclidean", row_linkage="single", axis="row", column_distance="euclidean", column_linkage="ward"):
"""Performs clustering according to the given parameters.
@datatype - numeric/binary
@row_distance/column_distance - see. DISTANCES variable
@row_linkage/column_linkage - see. LINKAGES variable
@axis - row/both
"""
print("Clustering rows:", row_distance, row_linkage)
self.clustering_axis = axis
row_linkage = str(row_linkage)
if row_linkage in RAW_LINKAGES:
self.clustering = fastcluster.linkage(self.data, method=row_linkage, metric=row_distance)
else:
self.distance_vector = fastcluster.pdist(self.data, row_distance)
if self.datatype == "numeric" and not row_distance in DISTANCES[self.datatype]:
raise Exception("".join(["When clustering numeric data you must choose from these distance measures: ", ", ".join(DISTANCES[self.datatype])]))
elif (self.datatype == "binary" or self.datatype == "nominal") and not row_distance in DISTANCES[self.datatype]:
raise Exception("".join(["When clustering binary or nominal data you must choose from these distance measures: ", ", ".join(DISTANCES[self.datatype])]))
self.clustering = fastcluster.linkage(self.distance_vector, method=str(row_linkage))
if not self.missing_values is False:
self.data = self.__return_missing_values__(self.data, self.missing_values_indexes)
self.column_clustering = []
if axis == "both" and len(self.data[0]) > 2:
print("Clustering columns:", column_distance, column_linkage)
self.__cluster_columns__(column_distance, column_linkage)
if self.write_original or self.datatype == "nominal":
self.data = self.original_data
def test_basic_clustering(self):
data = [
[1.0, 2.0],
[2.0, 1.0],
[2.1, 1.1],
[2, 1.1],
[1.0, 2.1],
]
data = np.array(data)
dist = fastcluster.pdist(data)
result = fastcluster.linkage(dist).tolist()
assert_that(int(result[0][0])).is_equal_to(0)
assert_that(int(result[0][1])).is_equal_to(4)
assert_that(result[0][2]).is_close_to(0.1, 0.00001)
assert_that(int(result[0][3])).is_equal_to(2)
assert_that(int(result[1][0])).is_equal_to(1)
assert_that(int(result[1][1])).is_equal_to(3)
assert_that(result[1][2]).is_close_to(0.1, 0.00001)
assert_that(int(result[1][3])).is_equal_to(2)
assert_that(int(result[2][0])).is_equal_to(2)
assert_that(int(result[2][1])).is_equal_to(6)
assert_that(result[2][2]).is_close_to(0.1, 0.00001)
assert_that(int(result[2][3])).is_equal_to(3)
assert_that(int(result[3][0])).is_equal_to(5)
assert_that(int(result[3][1])).is_equal_to(7)
assert_that(result[3][2]).is_close_to(1.34536, 0.00001)
assert_that(int(result[3][3])).is_equal_to(5)
def cluster_data(self, row_distance="euclidean", row_linkage="single", axis="row", column_distance="euclidean", column_linkage="ward"):
"""Performs clustering according to the given parameters.
@datatype - numeric/binary
@row_distance/column_distance - see. DISTANCES variable
@row_linkage/column_linkage - see. LINKAGES variable
@axis - row/both
"""
print("Clustering rows:", row_distance, row_linkage)
self.clustering_axis = axis
row_linkage = str(row_linkage)
if row_linkage in RAW_LINKAGES:
self.clustering = fastcluster.linkage(self.data, method=row_linkage, metric=row_distance)
else:
self.distance_vector = fastcluster.pdist(self.data, row_distance)
if self.datatype == "numeric" and not row_distance in DISTANCES[self.datatype]:
raise Exception("".join(["When clustering numeric data you must choose from these distance measures: ", ", ".join(DISTANCES[self.datatype])]))
elif (self.datatype == "binary" or self.datatype == "nominal") and not row_distance in DISTANCES[self.datatype]:
raise Exception("".join(["When clustering binary or nominal data you must choose from these distance measures: ", ", ".join(DISTANCES[self.datatype])]))
self.clustering = fastcluster.linkage(self.distance_vector, method=str(row_linkage))
if not self.missing_value is False:
self.data = self.__return_missing_values__(self.data, self.missing_values_indexes)
self.column_clustering = []
if axis == "both" and len(self.data[0]) > 2:
print("Clustering columns:", column_distance, column_linkage)
self.__cluster_columns__(column_distance, column_linkage)
if self.write_original or self.datatype == "nominal":
self.data = self.original_data
def cluster_data(self, data_type="numeric", row_distance="euclidean", row_linkage="single", axis="row", column_distance="euclidean", column_linkage="ward"):
"""Performs clustering according to the given parameters.
@data_type - numeric/binary
@row_distance/column_distance - see. DISTANCES variable
@row_linkage/column_linkage - see. LINKAGES variable
@axis - row/both
"""
print("Clustering rows:", row_distance, row_linkage)
self.data_type = data_type
self.clustering_axis = axis
row_linkage = str(row_linkage)
if row_linkage in RAW_LINKAGES:
self.clustering = fastcluster.linkage(self.data, method=row_linkage, metric=row_distance)
else:
self.distance_vector = fastcluster.pdist(self.data, row_distance)
if data_type in DISTANCES and not row_distance in DISTANCES[data_type]:
raise Exception("".join(["When clustering" , data_type, "data you must choose from these distance measures: ", ", ".join(DISTANCES[data_type])]))
elif not data_type in DISTANCES.keys():
raise Exception("".join(["You can choose only from data types: ", ", ".join(DISTANCES.keys())]))
self.clustering = fastcluster.linkage(self.distance_vector, method=str(row_linkage))
self.column_clustering = []
if axis == "both" and len(self.data[0]) > 2:
print("Clustering columns:", column_distance, column_linkage)
self.__cluster_columns__(column_distance, column_linkage)
if self.write_original:
self.data = self.original_data
return
def optimal_linkage(data, rows=True, method='ward', metric='euclidean'):
if not rows:
data = data.T
distance = fastcluster.pdist(data, metric=metric)
linkage = fastcluster.linkage(distance, method=method)
optimal_linkage = polo.optimal_leaf_ordering(linkage, distance)
return optimal_linkage
def cal_cophenetic(C):
""" calculate cophenetic correlation coefficient """
print("=== calculate cophenetic correlation coefficient ===")
X = C # Original data (1000 observations)
"""Z = linkage(X)"""
Z = fc.linkage_vector(X) # Clustering
orign_dists = fc.pdist(X) # Matrix of original distances between observations
cophe_dists = cophenet(Z) # Matrix of cophenetic distances between observations
corr_coef = np.corrcoef(orign_dists, cophe_dists)[0,1]
return corr_coef
def cophenetic_correlation(consensus_matrix):
"""Calculates the cophentic correlation co-efficient from a consensus matrix.
Arguments:
consensus_matrix (np.array): the unordered consensus matrix
Returns:
int: the cophenetic correlation co-efficient
"""
ori_dists = fc.pdist(consensus_matrix)
Z = fc.linkage(ori_dists, method="average")
[coph_corr, temporary] = cophenet(Z, ori_dists)
return coph_corr
def _cluster_peaks(mzs: Sequence[float],
ppm: float,
distype: str = 'euclidean',
linkmode: str = 'centroid'):
if len(mzs) == 0:
return np.array([])
if len(mzs) == 1:
return np.zeros_like(mzs, dtype=int).reshape((-1, 1))
outer_mzs = np.add.outer(mzs, mzs)
np.fill_diagonal(outer_mzs, 0)
# avg_mz_pair = np.divide(outer_mzs, 2)
outer_mzs /= 2 # inplace operation to reduce memory usage
# mdist_mz_pair = squareform(avg_mz_pair)
mdist_mz_pair = squareform(outer_mzs)
del outer_mzs # reduce memory use
m = np.column_stack([mzs])
mdist = fc.pdist(m, metric=distype)
del m
# relative_errors = np.multiply(mdist_mz_pair, 1e-6)
mdist_mz_pair *= 1e-6 # inplace operation to reduce memory usage
with np.errstate(divide='ignore', invalid='ignore'
): # using errstate context to avoid seterr side effects
# m_mass_tol = np.divide(mdist, relative_errors)
mdist /= mdist_mz_pair # inplace operation to reduce memory usage
# m_mass_tol[np.isnan(m_mass_tol)] = 0.0
mdist[np.isnan(mdist)] = 0.0
# z = fc.linkage(m_mass_tol, method=linkmode)
z = fc.linkage(mdist, method=linkmode)
del mdist, mdist_mz_pair
# cut tree at ppm threshold
return cluster.hierarchy.cut_tree(z, height=ppm)
def _cluster_peaks(mzs, ppm, distype='euclidean', linkmode='centroid'):
if len(mzs) == 0:
return np.array([])
if len(mzs) == 1:
return np.zeros_like(mzs, dtype=int).reshape((-1, 1))
m = np.column_stack([mzs])
mdist = fc.pdist(m, metric=distype)
outer_mzs = np.add.outer(mzs, mzs)
np.fill_diagonal(outer_mzs, 0)
avg_mz_pair = np.divide(outer_mzs, 2)
mdist_mz_pair = squareform(avg_mz_pair)
relative_errors = np.multiply(mdist_mz_pair, 1e-6)
with np.errstate(divide='ignore', invalid='ignore'
): # using errstate context to avoid seterr side effects
m_mass_tol = np.divide(mdist, relative_errors)
m_mass_tol[np.isnan(m_mass_tol)] = 0.0
z = fc.linkage(m_mass_tol, method=linkmode)
# cut tree at ppm threshold & order matches the order of mzs
return cluster.hierarchy.cut_tree(z, height=ppm)
