Update examples.

5 years ago · a26491997d
--- a/gklearn/examples/ged/init.py
+++ b/gklearn/examples/ged/init.py
--- a/gklearn/examples/ged/compute_graph_edit_distance.py
+++ b/gklearn/examples/ged/compute_graph_edit_distance.py
@@ -0,0 +1,58 @@
 # -*- coding: utf-8 -*-
 """compute_graph_edit_distance.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/1Wfgn7WVuyOQQgwOvdUQBz0BzEVdp0YM3

 **This script demonstrates how to compute a graph edit distance.**
 ---

 **0.   Install `graphkit-learn`.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset

 # Predefined dataset name, use dataset "MUTAG".
 ds_name = 'MUTAG'

 # Initialize a Dataset.
 dataset = Dataset()
 # Load predefined dataset "MUTAG".
 dataset.load_predefined_dataset(ds_name)
 graph1 = dataset.graphs[0]
 graph2 = dataset.graphs[1]
 print(graph1, graph2)

 """**2.  Compute graph edit distance.**"""

 from gklearn.ged.env import GEDEnv


 ged_env = GEDEnv() # initailize GED environment.
 ged_env.set_edit_cost('CONSTANT', # GED cost type.
                      edit_cost_constants=[3, 3, 1, 3, 3, 1] # edit costs.
 					  )  
 ged_env.add_nx_graph(graph1, '') # add graph1
 ged_env.add_nx_graph(graph2, '') # add graph2
 listID = ged_env.get_all_graph_ids() # get list IDs of graphs
 ged_env.init(init_type='LAZY_WITHOUT_SHUFFLED_COPIES') # initialize GED environment.
 options = {'initialization_method': 'RANDOM', # or 'NODE', etc.
           'threads': 1 # parallel threads.
 		   }
 ged_env.set_method('BIPARTITE', # GED method.
                   options # options for GED method.
 				   )
 ged_env.init_method() # initialize GED method.

 ged_env.run_method(listID[0], listID[1]) # run.

 pi_forward = ged_env.get_forward_map(listID[0], listID[1]) # forward map.
 pi_backward = ged_env.get_backward_map(listID[0], listID[1]) # backward map.
 dis = ged_env.get_upper_bound(listID[0], listID[1])	# GED bewteen two graphs.
 print(pi_forward)
 print(pi_backward)
 print(dis)
--- a/gklearn/examples/kernels/init.py
+++ b/gklearn/examples/kernels/init.py
--- a/gklearn/examples/kernels/compute_distance_in_kernel_space.py
+++ b/gklearn/examples/kernels/compute_distance_in_kernel_space.py
@@ -0,0 +1,73 @@
 # -*- coding: utf-8 -*-
 """compute_distance_in_kernel_space.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/17tZP6IrineQmzo9sRtfZOnHpHx6HnlMA

 **This script demonstrates how to compute distance in kernel space between the image of a graph and the mean of images of a group of graphs.**
 ---

 **0.   Install `graphkit-learn`.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset

 # Predefined dataset name, use dataset "MUTAG".
 ds_name = 'MUTAG'

 # Initialize a Dataset.
 dataset = Dataset()
 # Load predefined dataset "MUTAG".
 dataset.load_predefined_dataset(ds_name)
 len(dataset.graphs)

 """**2.  Compute graph kernel.**"""

 from gklearn.kernels import PathUpToH
 import multiprocessing

 # Initailize parameters for graph kernel computation.
 kernel_options = {'depth': 3,
 				  'k_func': 'MinMax',
 				  'compute_method': 'trie'
 				  }

 # Initialize graph kernel.
 graph_kernel = PathUpToH(node_labels=dataset.node_labels, # list of node label names.
 						 edge_labels=dataset.edge_labels, # list of edge label names.
 						 ds_infos=dataset.get_dataset_infos(keys=['directed']), # dataset information required for computation.
 						 **kernel_options, # options for computation.
 						 )

 # Compute Gram matrix.
 gram_matrix, run_time = graph_kernel.compute(dataset.graphs,
 											 parallel='imap_unordered', # or None.
 											 n_jobs=multiprocessing.cpu_count(), # number of parallel jobs.
 											 normalize=True, # whether to return normalized Gram matrix.
 											 verbose=2 # whether to print out results.
                                            )

 """**3.   Compute distance in kernel space.**

 Given a dataset $\mathcal{G}_N$, compute the distance in kernel space between the image of $G_1 \in \mathcal{G}_N$ and the mean of images of $\mathcal{G}_k \subset \mathcal{G}_N$.
 """

 from gklearn.preimage.utils import compute_k_dis

 # Index of $G_1$.
 idx_1 = 10
 # Indices of graphs in $\mathcal{G}_k$.
 idx_graphs = range(0, 10)

 # Compute the distance in kernel space.
 dis_k = compute_k_dis(idx_1,
                      idx_graphs,
 					  [1 / len(idx_graphs)] * len(idx_graphs), # weights for images of graphs in $\mathcal{G}_k$; all equal when computing the mean.
 					  gram_matrix, # gram matrix of al graphs.
 					  withterm3=False
 					  )
 print(dis_k)
--- a/gklearn/examples/kernels/compute_graph_kernel.py
+++ b/gklearn/examples/kernels/compute_graph_kernel.py
@@ -0,0 +1,87 @@
 # -*- coding: utf-8 -*-
 """compute_graph_kernel.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/17Q2QCl9CAtDweGF8LiWnWoN2laeJqT0u

 **This script demonstrates how to compute a graph kernel.**
 ---

 **0.   Install `graphkit-learn`.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset

 # Predefined dataset name, use dataset "MUTAG".
 ds_name = 'MUTAG'

 # Initialize a Dataset.
 dataset = Dataset()
 # Load predefined dataset "MUTAG".
 dataset.load_predefined_dataset(ds_name)
 len(dataset.graphs)

 """**2.  Compute graph kernel.**"""

 from gklearn.kernels import PathUpToH

 # Initailize parameters for graph kernel computation.
 kernel_options = {'depth': 3,
 			      		  'k_func': 'MinMax',
 					        'compute_method': 'trie'
 								 }

 # Initialize graph kernel.
 graph_kernel = PathUpToH(node_labels=dataset.node_labels, # list of node label names.
 						 edge_labels=dataset.edge_labels, # list of edge label names.
 						 ds_infos=dataset.get_dataset_infos(keys=['directed']), # dataset information required for computation.
 						 **kernel_options, # options for computation.
 						 )

 print('done.')

 import multiprocessing
 import matplotlib.pyplot as plt

 # Compute Gram matrix.
 gram_matrix, run_time = graph_kernel.compute(dataset.graphs,
 											 parallel='imap_unordered', # or None.
 											 n_jobs=multiprocessing.cpu_count(), # number of parallel jobs.
 											 normalize=True, # whether to return normalized Gram matrix.
 											 verbose=2 # whether to print out results.
 											 )
 # Print results.
 print()
 print(gram_matrix)
 print(run_time)
 plt.imshow(gram_matrix)

 import multiprocessing

 # Compute grah kernels between a graph and a list of graphs.
 kernel_list, run_time = graph_kernel.compute(dataset.graphs, # a list of graphs. 
                                             dataset.graphs[0], # a single graph.
 											 parallel='imap_unordered', # or None.
 											 n_jobs=multiprocessing.cpu_count(), # number of parallel jobs.
 											 verbose=2 # whether to print out results.
                                            )
 # Print results.
 print()
 print(kernel_list)
 print(run_time)

 import multiprocessing

 # Compute a grah kernel between two graphs.
 kernel, run_time = graph_kernel.compute(dataset.graphs[0], # a single graph. 
                                        dataset.graphs[1], # another single graph.
 										verbose=2 # whether to print out results.
                                       )
 # Print results.
 print()
 print(kernel)
 print(run_time)
--- a/gklearn/examples/kernels/compute_graph_kernel_old.py
+++ b/gklearn/examples/kernels/compute_graph_kernel_old.py
@@ -0,0 +1,31 @@
 # -*- coding: utf-8 -*-
 """compute_graph_kernel_v0.1.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/10jUz7-ahPiE_T1qvFrh2NvCVs1e47noj

 **This script demonstrates how to compute a graph kernel.**
 ---

 **0.   Install `graphkit-learn`.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils.graphfiles import loadDataset

 graphs, targets = loadDataset('../../../datasets/MUTAG/MUTAG_A.txt')

 """**2.  Compute graph kernel.**"""

 from gklearn.kernels import untilhpathkernel

 gram_matrix, run_time = untilhpathkernel(
 	graphs, # The list of input graphs.
 	depth=5, # The longest length of paths.
 	k_func='MinMax', # Or 'tanimoto'.
 	compute_method='trie', # Or 'naive'.
 	n_jobs=1, # The number of jobs to run in parallel.
 	verbose=True)
--- a/gklearn/examples/kernels/model_selection_old.py
+++ b/gklearn/examples/kernels/model_selection_old.py
@@ -0,0 +1,38 @@
 # -*- coding: utf-8 -*-
 """model_selection_old.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/1uVkl7scNgEPrimX8ks6iEC5ijuhB8L_D

 **This script demonstrates how to compute a graph kernel.**
 ---

 **0.   Install `graphkit-learn`.**
 """

 """**1. Perform model seletion and classification.**"""

 from gklearn.utils import model_selection_for_precomputed_kernel
 from gklearn.kernels import untilhpathkernel
 import numpy as np

 # Set parameters.
 datafile = '../../../datasets/MUTAG/MUTAG_A.txt'
 param_grid_precomputed = {'depth': np.linspace(1, 10, 10),
                          'k_func': ['MinMax', 'tanimoto'],
                          'compute_method': ['trie']}
 param_grid = {'C': np.logspace(-10, 10, num=41, base=10)}

 # Perform model selection and classification.
 model_selection_for_precomputed_kernel(
 	datafile, # The path of dataset file.
 	untilhpathkernel, # The graph kernel used for estimation.
 	param_grid_precomputed, # The parameters used to compute gram matrices.
 	param_grid, # The penelty Parameters used for penelty items.
 	'classification', # Or 'regression'.
 	NUM_TRIALS=30, # The number of the random trials of the outer CV loop.
 	ds_name='MUTAG', # The name of the dataset.
 	n_jobs=1,
 	verbose=True)
--- a/gklearn/examples/preimage/init.py
+++ b/gklearn/examples/preimage/init.py
--- a/gklearn/examples/preimage/median_preimege_generator.py
+++ b/gklearn/examples/preimage/median_preimege_generator.py
@@ -0,0 +1,115 @@
 # -*- coding: utf-8 -*-
 """example_median_preimege_generator.ipynb

 Automatically generated by Colaboratory.

 Original file is located at
    https://colab.research.google.com/drive/1PIDvHOcmiLEQ5Np3bgBDdu0kLOquOMQK

 **This script demonstrates how to generate a graph preimage using Boria's method.**
 ---
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset, split_dataset_by_target

 # Predefined dataset name, use dataset "MAO".
 ds_name = 'MAO'
 # The node/edge labels that will not be used in the computation.
 irrelevant_labels = {'node_attrs': ['x', 'y', 'z'], 'edge_labels': ['bond_stereo']}

 # Initialize a Dataset.
 dataset_all = Dataset()
 # Load predefined dataset "MAO".
 dataset_all.load_predefined_dataset(ds_name)
 # Remove irrelevant labels.
 dataset_all.remove_labels(**irrelevant_labels)
 # Split the whole dataset according to the classification targets.
 datasets = split_dataset_by_target(dataset_all)
 # Get the first class of graphs, whose median preimage will be computed.
 dataset = datasets[0]
 len(dataset.graphs)

 """**2.  Set parameters.**"""

 import multiprocessing

 # Parameters for MedianPreimageGenerator (our method).
 mpg_options = {'fit_method': 'k-graphs', # how to fit edit costs. "k-graphs" means use all graphs in median set when fitting.
 			   'init_ecc': [4, 4, 2, 1, 1, 1], # initial edit costs.
 			   'ds_name': ds_name, # name of the dataset.
 			   'parallel': True, # whether the parallel scheme is to be used.
 			   'time_limit_in_sec': 0, # maximum time limit to compute the preimage. If set to 0 then no limit.
 			   'max_itrs': 100, # maximum iteration limit to optimize edit costs. If set to 0 then no limit.
 			   'max_itrs_without_update': 3, # If the times that edit costs is not update is more than this number, then the optimization stops.
 			   'epsilon_residual': 0.01, # In optimization, the residual is only considered changed if the change is bigger than this number.
 			   'epsilon_ec': 0.1, # In optimization, the edit costs are only considered changed if the changes are bigger than this number.
 			   'verbose': 2 # whether to print out results.
               }
 # Parameters for graph kernel computation.
 kernel_options = {'name': 'PathUpToH', # use path kernel up to length h.
 				  'depth': 9,
 				  'k_func': 'MinMax',
 				  'compute_method': 'trie',
 				  'parallel': 'imap_unordered', # or None
 				  'n_jobs': multiprocessing.cpu_count(),
 				  'normalize': True, # whether to use normalized Gram matrix to optimize edit costs.
 				  'verbose': 2 # whether to print out results.
                  }
 # Parameters for GED computation.
 ged_options = {'method': 'IPFP', # use IPFP huristic.
 			   'initialization_method': 'RANDOM', # or 'NODE', etc.
 			   'initial_solutions': 10, # when bigger than 1, then the method is considered mIPFP.
 			   'edit_cost': 'CONSTANT', # use CONSTANT cost.
 			   'attr_distance': 'euclidean', # the distance between non-symbolic node/edge labels is computed by euclidean distance.
 			   'ratio_runs_from_initial_solutions': 1,
 			   'threads': multiprocessing.cpu_count(), # parallel threads. Do not work if mpg_options['parallel'] = False.
 			   'init_option': 'EAGER_WITHOUT_SHUFFLED_COPIES'
               }
 # Parameters for MedianGraphEstimator (Boria's method).
 mge_options = {'init_type': 'MEDOID', # how to initial median (compute set-median). "MEDOID" is to use the graph with smallest SOD.
 			   'random_inits': 10, # number of random initialization when 'init_type' = 'RANDOM'.
 			   'time_limit': 600, # maximum time limit to compute the generalized median. If set to 0 then no limit.
 			   'verbose': 2, # whether to print out results.
 			   'refine': False # whether to refine the final SODs or not.
               }
 print('done.')

 """**3.   Run median preimage generator.**"""

 from gklearn.preimage import MedianPreimageGenerator

 # Create median preimage generator instance.
 mpg = MedianPreimageGenerator()
 # Add dataset.
 mpg.dataset = dataset
 # Set parameters.
 mpg.set_options(**mpg_options.copy())
 mpg.kernel_options = kernel_options.copy()
 mpg.ged_options = ged_options.copy()
 mpg.mge_options = mge_options.copy()
 # Run.
 mpg.run()

 """**4. Get results.**"""

 # Get results.
 import pprint
 pp = pprint.PrettyPrinter(indent=4) # pretty print
 results = mpg.get_results()
 pp.pprint(results)

 # Draw generated graphs.
 def draw_graph(graph):
 	import matplotlib.pyplot as plt
 	import networkx as nx
 	plt.figure()
 	pos = nx.spring_layout(graph)
 	nx.draw(graph, pos, node_size=500, labels=nx.get_node_attributes(graph, 'atom_symbol'), font_color='w', width=3, with_labels=True)
 	plt.show()
 	plt.clf()
 	plt.close()
 
 draw_graph(mpg.set_median)
 draw_graph(mpg.gen_median)
--- a/gklearn/examples/preimage/median_preimege_generator_cml.py
+++ b/gklearn/examples/preimage/median_preimege_generator_cml.py
@@ -0,0 +1,113 @@
 #!/usr/bin/env python3
 # -*- coding: utf-8 -*-
 """
 Created on Tue Jun 16 15:41:26 2020

@author: ljia

 **This script demonstrates how to generate a graph preimage using Boria's method with cost matrices learning.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset, split_dataset_by_target

 # Predefined dataset name, use dataset "MAO".
 ds_name = 'MAO'
 # The node/edge labels that will not be used in the computation.
 irrelevant_labels = {'node_attrs': ['x', 'y', 'z'], 'edge_labels': ['bond_stereo']}

 # Initialize a Dataset.
 dataset_all = Dataset()
 # Load predefined dataset "MAO".
 dataset_all.load_predefined_dataset(ds_name)
 # Remove irrelevant labels.
 dataset_all.remove_labels(**irrelevant_labels)
 # Split the whole dataset according to the classification targets.
 datasets = split_dataset_by_target(dataset_all)
 # Get the first class of graphs, whose median preimage will be computed.
 dataset = datasets[0]
 len(dataset.graphs)

 """**2.  Set parameters.**"""

 import multiprocessing

 # Parameters for MedianPreimageGenerator (our method).
 mpg_options = {'init_method': 'random', # how to initialize node label cost vector. "random" means to initialize randomly.
 			   'init_ecc': [4, 4, 2, 1, 1, 1], # initial edit costs.
 			   'ds_name': ds_name, # name of the dataset.
 			   'parallel': True, # @todo: whether the parallel scheme is to be used.
 			   'time_limit_in_sec': 0, # maximum time limit to compute the preimage. If set to 0 then no limit.
 			   'max_itrs': 3, # maximum iteration limit to optimize edit costs. If set to 0 then no limit.
 			   'max_itrs_without_update': 3, # If the times that edit costs is not update is more than this number, then the optimization stops.
 			   'epsilon_residual': 0.01, # In optimization, the residual is only considered changed if the change is bigger than this number.
 			   'epsilon_ec': 0.1, # In optimization, the edit costs are only considered changed if the changes are bigger than this number.
 			   'verbose': 2 # whether to print out results.
               }
 # Parameters for graph kernel computation.
 kernel_options = {'name': 'PathUpToH', # use path kernel up to length h.
 				  'depth': 9,
 				  'k_func': 'MinMax',
 				  'compute_method': 'trie',
 				  'parallel': 'imap_unordered', # or None
 				  'n_jobs': multiprocessing.cpu_count(),
 				  'normalize': True, # whether to use normalized Gram matrix to optimize edit costs.
 				  'verbose': 2 # whether to print out results.
                  }
 # Parameters for GED computation.
 ged_options = {'method': 'BIPARTITE', # use Bipartite huristic.
 			   'initialization_method': 'RANDOM', # or 'NODE', etc.
 			   'initial_solutions': 10, # when bigger than 1, then the method is considered mIPFP.
 			   'edit_cost': 'CONSTANT', # @todo: not needed. use CONSTANT cost.
 			   'attr_distance': 'euclidean', # @todo: not needed. the distance between non-symbolic node/edge labels is computed by euclidean distance.
 			   'ratio_runs_from_initial_solutions': 1,
 			   'threads': multiprocessing.cpu_count(), # parallel threads. Do not work if mpg_options['parallel'] = False.
 			   'init_option': 'LAZY_WITHOUT_SHUFFLED_COPIES' # 'EAGER_WITHOUT_SHUFFLED_COPIES'
               }
 # Parameters for MedianGraphEstimator (Boria's method).
 mge_options = {'init_type': 'MEDOID', # how to initial median (compute set-median). "MEDOID" is to use the graph with smallest SOD.
 			   'random_inits': 10, # number of random initialization when 'init_type' = 'RANDOM'.
 			   'time_limit': 600, # maximum time limit to compute the generalized median. If set to 0 then no limit.
 			   'verbose': 2, # whether to print out results.
 			   'refine': False # whether to refine the final SODs or not.
               }
 print('done.')

 """**3.   Run median preimage generator.**"""

 from gklearn.preimage import MedianPreimageGeneratorCML

 # Create median preimage generator instance.
 mpg = MedianPreimageGeneratorCML()
 # Add dataset.
 mpg.dataset = dataset
 # Set parameters.
 mpg.set_options(**mpg_options.copy())
 mpg.kernel_options = kernel_options.copy()
 mpg.ged_options = ged_options.copy()
 mpg.mge_options = mge_options.copy()
 # Run.
 mpg.run()

 """**4. Get results.**"""

 # Get results.
 import pprint
 pp = pprint.PrettyPrinter(indent=4) # pretty print
 results = mpg.get_results()
 pp.pprint(results)

 # Draw generated graphs.
 def draw_graph(graph):
 	import matplotlib.pyplot as plt
 	import networkx as nx
 	plt.figure()
 	pos = nx.spring_layout(graph)
 	nx.draw(graph, pos, node_size=500, labels=nx.get_node_attributes(graph, 'atom_symbol'), font_color='w', width=3, with_labels=True)
 	plt.show()
 	plt.clf()
 	plt.close()
 
 draw_graph(mpg.set_median)
 draw_graph(mpg.gen_median)
--- a/gklearn/examples/preimage/median_preimege_generator_py.py
+++ b/gklearn/examples/preimage/median_preimege_generator_py.py
@@ -0,0 +1,114 @@
 #!/usr/bin/env python3
 # -*- coding: utf-8 -*-
 """
 Created on Tue Jun 16 15:41:26 2020

@author: ljia

 **This script demonstrates how to generate a graph preimage using Boria's method with cost matrices learning.**
 """

 """**1.   Get dataset.**"""

 from gklearn.utils import Dataset, split_dataset_by_target

 # Predefined dataset name, use dataset "MAO".
 ds_name = 'MAO'
 # The node/edge labels that will not be used in the computation.
 irrelevant_labels = {'node_attrs': ['x', 'y', 'z'], 'edge_labels': ['bond_stereo']}

 # Initialize a Dataset.
 dataset_all = Dataset()
 # Load predefined dataset "MAO".
 dataset_all.load_predefined_dataset(ds_name)
 # Remove irrelevant labels.
 dataset_all.remove_labels(**irrelevant_labels)
 # Split the whole dataset according to the classification targets.
 datasets = split_dataset_by_target(dataset_all)
 # Get the first class of graphs, whose median preimage will be computed.
 dataset = datasets[0]
 # dataset.cut_graphs(range(0, 10))
 len(dataset.graphs)

 """**2.  Set parameters.**"""

 import multiprocessing

 # Parameters for MedianPreimageGenerator (our method).
 mpg_options = {'fit_method': 'k-graphs', # how to fit edit costs. "k-graphs" means use all graphs in median set when fitting.
 			   'init_ecc': [4, 4, 2, 1, 1, 1], # initial edit costs.
 			   'ds_name': ds_name, # name of the dataset.
 			   'parallel': True, # @todo: whether the parallel scheme is to be used.
 			   'time_limit_in_sec': 0, # maximum time limit to compute the preimage. If set to 0 then no limit.
 			   'max_itrs': 100, # maximum iteration limit to optimize edit costs. If set to 0 then no limit.
 			   'max_itrs_without_update': 3, # If the times that edit costs is not update is more than this number, then the optimization stops.
 			   'epsilon_residual': 0.01, # In optimization, the residual is only considered changed if the change is bigger than this number.
 			   'epsilon_ec': 0.1, # In optimization, the edit costs are only considered changed if the changes are bigger than this number.
 			   'verbose': 2 # whether to print out results.
               }
 # Parameters for graph kernel computation.
 kernel_options = {'name': 'PathUpToH', # use path kernel up to length h.
 				  'depth': 9,
 				  'k_func': 'MinMax',
 				  'compute_method': 'trie',
 				  'parallel': 'imap_unordered', # or None
 				  'n_jobs': multiprocessing.cpu_count(),
 				  'normalize': True, # whether to use normalized Gram matrix to optimize edit costs.
 				  'verbose': 2 # whether to print out results.
                  }
 # Parameters for GED computation.
 ged_options = {'method': 'BIPARTITE', # use Bipartite huristic.
 			   'initialization_method': 'RANDOM', # or 'NODE', etc.
 			   'initial_solutions': 10, # when bigger than 1, then the method is considered mIPFP.
 			   'edit_cost': 'CONSTANT', # use CONSTANT cost.
 			   'attr_distance': 'euclidean', # the distance between non-symbolic node/edge labels is computed by euclidean distance.
 			   'ratio_runs_from_initial_solutions': 1,
 			   'threads': multiprocessing.cpu_count(), # parallel threads. Do not work if mpg_options['parallel'] = False.
 			   'init_option': 'LAZY_WITHOUT_SHUFFLED_COPIES' # 'EAGER_WITHOUT_SHUFFLED_COPIES'
               }
 # Parameters for MedianGraphEstimator (Boria's method).
 mge_options = {'init_type': 'MEDOID', # how to initial median (compute set-median). "MEDOID" is to use the graph with smallest SOD.
 			   'random_inits': 10, # number of random initialization when 'init_type' = 'RANDOM'.
 			   'time_limit': 600, # maximum time limit to compute the generalized median. If set to 0 then no limit.
 			   'verbose': 2, # whether to print out results.
 			   'refine': False # whether to refine the final SODs or not.
               }
 print('done.')

 """**3.   Run median preimage generator.**"""

 from gklearn.preimage import MedianPreimageGeneratorPy

 # Create median preimage generator instance.
 mpg = MedianPreimageGeneratorPy()
 # Add dataset.
 mpg.dataset = dataset
 # Set parameters.
 mpg.set_options(**mpg_options.copy())
 mpg.kernel_options = kernel_options.copy()
 mpg.ged_options = ged_options.copy()
 mpg.mge_options = mge_options.copy()
 # Run.
 mpg.run()

 """**4. Get results.**"""

 # Get results.
 import pprint
 pp = pprint.PrettyPrinter(indent=4) # pretty print
 results = mpg.get_results()
 pp.pprint(results)

 # Draw generated graphs.
 def draw_graph(graph):
 	import matplotlib.pyplot as plt
 	import networkx as nx
 	plt.figure()
 	pos = nx.spring_layout(graph)
 	nx.draw(graph, pos, node_size=500, labels=nx.get_node_attributes(graph, 'atom_symbol'), font_color='w', width=3, with_labels=True)
 	plt.show()
 	plt.clf()
 	plt.close()
 
 draw_graph(mpg.set_median)
 draw_graph(mpg.gen_median)