Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have a list of customers and features in the following format:

UserID, Feature1, Feature2, Feature3, Feature4

So I have a list -- called "Customers" -- and it looks like this:

[
['975676924', '1345207523', '-1953633084', '-2041119774', '587903155'], 
['1619201613', '-1384105381', '1433106581', '1445361759', '587903155'], 
['-1470352544', '-1068707556', '-1002282042', '-563691616', '587903155'], 
['-1958275692', '-739953679', '69580355', '-481818422', '587903155'],
['1619201613', '-739953679', '-1002282042', '-481818422', '587903155']
]

Each line is a transaction with specific characteristics. The first element in each line is the UserID (customer) doing that transaction. Therefore, Customers[1] gives the second line and Customers[1][0] gives the UserID of that line (1619201613).

The UserIDs can be repeated in other lines (new transactions), as repeat customers will be appended to the list. So, for instance, note that Customers[4][0] gives the same UserID (1619201613), but the features of Customers[4] are not the same as that of Customers[1] -- i.e., the customer came back and bought a different product with different features.

So here's the central question: How do I efficiently calculate similarity between every two distinct customers in my list?
I think the question should actually be split into two different questions / tasks:

  1. Grouping together the distinct UserIDs. So the first question is: How do I efficiently put together all the distinct features of a single UserID, so that, for instance, Customers[1] and Customers[4] are put into a single new line (new list?) of the form:
    ['1619201613', '-1384105381', '1433106581', '1445361759', '587903155', '-739953679', '-1002282042', '-481818422']

  2. Finding similarity of Customers via their transactions. So the second question is: How do I efficiently evaluate a similarity function in [0,1] that tells me if two distinct customers are interested in the same stuff?


PS. Some additional notes:

  1. The order of the features does not matter, as they are hashed and uniquely identified.
  2. The cardinality of the features does not matter either, i.e., we don't care if the same feature appears twice or three times for the same UserID.
  3. The end-result of this whole thing is to be able to get a network of customers, where the UserIDs are nodes and the edges between them are weighted by the similarity score.
  4. I tend to prefer cosine similarity, or Jaccard index, but open to alternatives.
  5. I need speed and scalability, even if that sacrifices some accuracy, to a small degree of course.
  6. I have checked previous questions thoroughly - e.g., the following are not relevant: Calculating the similarity of two lists; Python Checking Multiple Lists For Similarities; How to compute the similarity between lists of features?
share|improve this question
    
For a complete question you should show your current attempt –  jamylak May 29 '13 at 11:26
    
I haven't been able to make a first attempt, jamylak. I'm relatively new to Python and I am using it in this context so as to scale up to hundreds of thousands of users and process them as networks (then use NetworkX, with which I am a bit more familiar). –  mmScript May 29 '13 at 11:33

2 Answers 2

up vote 1 down vote accepted

This answers part one of your question:

raw_data = [
['975676924', '1345207523', '-1953633084', '-2041119774', '587903155'],
['1619201613', '-1384105381', '1433106581', '1445361759', '587903155'],
['-1470352544', '-1068707556', '-1002282042', '-563691616', '587903155'],
['-1958275692', '-739953679', '69580355', '-481818422', '587903155'],
['1619201613', '-739953679', '-1002282042', '-481818422', '587903155']
]

import collections
data = collections.defaultdict(list)

for line in raw_data:
    data[line[0]].extend(line[1:])

Now you have a dictionary with the id as key:

defaultdict(<type 'list'>, {
'1619201613': 
         ['-1384105381', '1433106581', '1445361759', '587903155',
          '-739953679', '-1002282042', '-481818422', '587903155'],  
'-1470352544': 
         ['-1068707556', '-1002282042', '-563691616', '587903155'], 
 '975676924': 
        ['1345207523', '-1953633084', '-2041119774', '587903155'],
 '-1958275692':
         ['-739953679', '69580355', '-481818422', '587903155']})  

You will get the desired list by rearranging:

data_list = [[key] + value for key, value in data.items()]
share|improve this answer
    
Thanks Mike, this works just fine. –  mmScript May 29 '13 at 14:01

Step 1: Group the distinct User assuming your list named l

summary = {}  # init a map for group
for entry in l:
    if summary[entry[0]]:
        summary[entry[0]] += entry[1:]
    else:
        summary[entry[0]] = entry[1:]

# delete duplicate element
for s in summary:
    summary[s] = [int(x) for x in list(set(summary[s]))]

Step 2: Build a network, actually a two-dimensional array, and calculate the similarity between different users.

# the row and column number of this array
cnt = len(summary) 
network = [[0] * cnt] * cnt

index = [x for x in summary]
for x, xvalue in enumerate(index):
    for y, yvalue in enumerate(index):
        common = len(set(summary[xvalue]) & set(summary[yvalue]))
        network[x][y] = common

Now network is the a two-dimensional array, containing the common item number between each UserID.

For example, your list is:

[['100', '2', '3','4'],
 ['110', '2', '5', '6'],
 ['120', '6', '3', '4']]

Then network is:

[[3, 1, 2],
 [1, 3, 1],
 [2, 1, 3]]

Some code is taken from this question

share|improve this answer
    
Thanks Roger. The first step produces an empty dictionary (for summary). The second one (adapted to take the dictionary from the second answer by Mike) produces a NxN table, but it doesn't look right to me - there is a column all 0's and the diagonal is not always equal to 1. Perhaps I misread your answer of course! –  mmScript May 29 '13 at 14:03
    
Sorry. The first step is wrong, I have fixed it. And network generated in second step tells how many items both bought by two users. For instance, element in [0,1] is 1, which means User0 and User1 bought 1 same item. If the value is 0, then these two users have no same item. You could add 1 to every element to make there's no 0 in the matrix. –  Roger May 29 '13 at 14:24
    
Thanks Roger - first part now works fine with small datasets (up to a few 10k of lines) but struggles with > 1 million lines. I get "Out of Memory" in the bigger case. I saw somewhere else (stackoverflow.com/questions/11283220/memory-error-in-python) that it is possible to use a baffer?? Do you know about this? –  mmScript May 29 '13 at 14:40
    
Which statement cause out of memory? –  Roger May 29 '13 at 14:49
    
Out of Memory is caused by the for loop (the first one, which builds up "summary") –  mmScript May 29 '13 at 15:59

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.