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I want to create a link between the nodes in a network in python based on a similarity metric defined as the Euclidean distance between them. The problem is the code takes 200 seconds to just create the network and as I am tuning my model and the code executes at least 100 times, the long execution time of this piece is making the whole code run slowly.

So, the nodes are in fact customers. I defined a class for the. They have two attributes gender (numerical; specified by number 0 or 1) and age (varies from 24 to 44) which are stored in a csv file. I have generated here like this:

#number of customers
ncons = 5000
gender = [random.randint(0, 1) for i in range(ncons)]
age = [random.randint(22, 39) for i in range(ncons)]
customer_df = pd.DataFrame(
    {'customer_gender': gender,
     'customer_age': age
    })
customer_df.to_csv('customer_df.csv', mode = 'w', index=False)

The Euclidean distance delta_ik as enter image description herefollowing. In the formula, n is the number of attributes. Here the attributes are gender and age. For customers i and k, S_f,i - S_f,k is the difference between attribute f = 1,2 which id divided by the maximum range of attribute f for all the customers (max d_f). So the distance is distance in attributes not geographical positions. Then I define the similarity metric H_ik which creates a number between 0 and 1 from delta_ik as follow:customer similarity. Finally, For customers i and k, I generate a random number rho between 0 and 1. If rho is smallre than H_ik, the nodes are connected.

So, the code that keeps delta_ik in a matrix and then uses that to generate the network looks as below:

import random
import pandas as pd
import time
import csv
import networkx as nx
import numpy as np
import math
#Read the csv file containing the part worth utilities of 184 consumers
def readCSVPWU():
    global headers
    global Attr
    Attr = []
    with open('customer_df.csv') as csvfile:
        csvreader = csv.reader(csvfile,delimiter=',')
        headers = next(csvreader)  # skip the first row of the CSV file.
        #CSV header cells are string and should be turned to a float number.
        for i in range(len(headers)):   
            if headers[i].isnumeric():
                headers[i] = float(headers[i])
        for row in csvreader:
            AttrS = row
            Attr.append(AttrS)
    #convert strings to float numbers
    Attr = [[float(j) for j in i] for i in Attr]
    #Return the CSV as a matrix with 17 columns and 184 rows 
    return Attr

#customer class
class Customer:
    def __init__(self, PWU = None, Ut = None):
        self.Ut = Ut
        self.PWU = Attr[random.randint(0,len(Attr)-1)]  # Pick random row from survey utility data  


#Generate a network by connecting nodes based on their similarity metric
def Network_generation(cust_agent):
    start_time = time.time() # track execution time

    #we form links/connections between consumeragentsbasedontheirdegreeofsocio-demographic similarity.
    global ncons
    Gcons = nx.Graph()
    #add nodes
    [Gcons.add_node(i, data = cust_agent[i]) for i in range(ncons)]
    #**********Compute the node to node distance
    #Initialize Deltaik with zero's
    Deltaik = [[0 for xi in range(ncons)] for yi in range(ncons)] 
    #For each attribute, find the maximum range of that attribute; for instance max age diff = max age - min age = 53-32=21
    maxdiff = []
    allval = []
    #the last two columns of Attr keep income and age data
    #Make a 2D numpy array to slice the last 2 columns
    np_Attr = np.array(Attr)
    #Take the last two columns, income and age of the participants, respectively
    socio = np_Attr[:, [len(Attr[0])-2, len(Attr[0])-1]]
    #convert numpy array to a list of list
    socio = socio.tolist()
    #Max diff for each attribute

    for f in range(len(socio[0])):
        for node1 in Gcons.nodes():
        #keep all values of an attribute to find the max range
            allval.append((Gcons.nodes[node1]['data'].PWU[-2:][f]))
        maxdiff.append((max(allval)-min(allval)))
        allval = []
# THE SECOND MOST TIME CONSUMING PART ********************

    for node1 in Gcons.nodes():
        for node2 in Gcons.nodes():
            tempdelta = 0
            #for each feature (attribute)
            for f in range(len(socio[0])):
                Deltaik[node1][node2] = (Gcons.nodes[node1]['data'].PWU[-2:][f]-Gcons.nodes[node2]['data'].PWU[-2:][f])
                #max difference
                insidepar = (Deltaik[node1][node2] / maxdiff[f])**2
                tempdelta += insidepar
            Deltaik[node1][node2] = math.sqrt(tempdelta)
     # THE END OF THE SECOND MOST TIME CONSUMING PART ********************
       
    #Find maximum of a matrix
    maxdel = max(map(max, Deltaik))
    #Find the homopholic weight
    import copy
    Hik = copy.deepcopy(Deltaik)
    for i in range(len(Deltaik)):
        for j in range(len(Deltaik[0])):
            
            Hik[i][j] =1 - (Deltaik[i][j]/maxdel)
    #Define a dataframe to save Hik
    dfHik = pd.DataFrame(columns = list(range(ncons) ),index = list(range(ncons) ))
    temp_h = []
    #For every consumer pair $i$ and $k$, a random number $\rho$ from a uniform distribution $U(0,1)$ is drawn and compared with $H_{i,k}$ . The two consumers are connected in the social network if $\rho$ is smaller than $H_{i,k}$~\cite{wolf2015changing}.
# THE MOST TIME CONSUMING PART ********************
    for node1 in Gcons.nodes():
        for node2 in Gcons.nodes():
            #Add Hik to the dataframe
            temp_h.append(Hik[node1][node2])
            rho = np.random.uniform(0,1,1)
            if node1 != node2:
                if rho < Hik[node1][node2]:
                    Gcons.add_edge(node1, node2)
        #Row idd for consumer idd keeps homophily with every other consumer
        dfHik.loc[node1] = temp_h
        temp_h = []
    # nx.draw(Gcons, with_labels=True)            
    print("Simulation time: %.3f seconds" % (time.time() - start_time))
# THE END OF THE MOST TIME CONSUMING PART ********************

    return Gcons     
#%%
#number of customers
ncons = 5000
gender = [random.randint(0, 1) for i in range(ncons)]
age = [random.randint(22, 39) for i in range(ncons)]
customer_df = pd.DataFrame(
    {'customer_gender': gender,
     'customer_age': age
    })
customer_df.to_csv('customer_df.csv', mode = 'w', index=False)
readCSVPWU()
customer_agent = dict(enumerate([Customer(PWU = [], Ut = []) for ij in range(ncons)])) # Ut=[]
G = Network_generation(customer_agent)

I would tremendously appreciate if you could please give me some advice on using more pythonic commands to decrease the elapsed time.

Thank you so much

3
  • Being "pythonic" doesn't necessarily confer better performance. – Robert Harvey Mar 1 at 18:50
  • Thanks very much for pointing this out. I noticed there are two nestd for loops that are taking the most time and marked them in the code as THE MOST and THE SECOND MOST TIME COSUMING PARTs. Can I make them more time efficient? – user710 Mar 1 at 19:31
  • 2
    Questions asking for general improvements to working code are off topic here -- Stack Overflow questions need to be about specific, narrow problems (and a performance question that might be best answered by switching to a completely different algorithm is nothing like narrow). Consider our sister site Code Review (subject to the guidelines laid out in the Help Center there). – Charles Duffy Mar 1 at 21:14