# compute bootstrapping algorithm using Map/Reduce

This question was originally a homework assignment I had, but my answer was wrong, and I'm curious what is the best solution for this problem.

The goal is to compute key aspects of the "Recommender System bootstrapping algorithm" using 4 map reduce steps. My problem is with the 3rd step, so I'll bring only its details.

input: records of the form:
1. (population id, item, number of rating users, sum of ratings, sum of ratings squared)
2. (population id, splitter item, likers/dislikers, item, number of rating users, sum of ratings, sum of ratings squared)

The 2nd form is pretty much like the 1st form, but a record for each (splitter,likers/dislikers) - where likers/dislikers is a boolean.

This means (I think) there are 2^|items| records of the seconds form for each record from the 1st form... (many classmates made the wrong (again, I think..) assumption that there are the same amount of 1st and 2nd form records)

This step will compute, per splitter movie, the squared error (SE) induced by each movie.

• Output: records of the form (population id, splitter item, item, squared error on item given a split on the splitter).

Hint:

assume that there exists a string that precedes (in the system’s sort order) any splitter movie id.

This must be done within one mapreduce step!

This was learned at the context of "The Netflix Challange"

SE definition: EDIT: additional material concerning the problem [some description on the netflix challenge and mathematical information about the problem ] can be found in this link [slides 12-24 especially]

EDIT2: note that since we are using map/reduce, we cannot assume anything about the ORDER records will be processed [in both map and reduce].

• In your text item = movie ? What's splitter items ? do you have examples of record ? – Ricky Bobby Aug 12 '11 at 14:38
• item = movie. splitter item is a movie we split our users according to the answers we have. it is explained in more details in the attached link. – amit Aug 12 '11 at 14:40
• Can you point to the original algorithm? I found some slides, but it would be best if you could point to it. Btw, typo in "Recommander" - I can't edit, though. – Iterator Aug 12 '11 at 14:44
• @Iterator: as side in the slides, it is more series of computations than an algorithm. the last computation is on slide 24. my problem is computing these steps using map/reduce, and as I said, I failed to find the right computation for the 3rd step. – amit Aug 13 '11 at 8:22
• p.s. thank you for the spelling correction, and thanks to @Ashelly for fixing it. – amit Aug 13 '11 at 8:22

I am not sure I understand your question.

What you ultimately want is SE(U). After some math details at slides 23 and 24, it is "trivially" computed with \sum_{i} SE(U)_i

You have understood by yourself that the 4th and last sept is a map reduce to get this sum.

The 3rd step is a map reduce to get (LaTeX style)

SE(U)_i = \sum_{u in U_i} (r_{u,i} - r_i)^2 • The reduce function sums over u in U_i
• The map function splits the terms to be summed

In Python this might look like:

def map(Ui):
''' Ui is the list of user who have rated the film i'''
for user in Ui:
results.append((user,(r_{u,i} - r_i)^2))

def reduce(results):
''' Returns a final pair (item, SE(U)_i ) '''
return (item, sum([value for user,value in results]))


Edit: My original answer was incomplete. Let me expain again.

What you ultimately want is SE(U) for every splitter.

Step a prepares some useful data about items. The emitted entries are defined with:

key = (population_id, item)
value =
number: |U_i|,
sum_of_ratings: \sum_{u \ in U_i} r_{u,i}
sum_of_squared_ratings: \sum_{u \in U_i} r_{u,i} ^2

• The map function explodes the statistics over the items.
• The reduce functions computes the sums.

Now, for any given splitter movie M:

U_M = U_{+M} + U_{-M} + U_{M?}


Step b explicitly computes, for each splitter M, the statistics for the small sub-populations M+ and M-.

NB likers/dislikers is not a boolean per se, it is the sub-population identicator '+' or '-'

There are 2 new entries for each splitter item:

key = (population_id, item, M, '+')
value =
number: |U_i(+)|
sum_of_ratings: \sum_{u \ in U_i(+)} r_{u,i}
sum_of_squared_ratings: \sum_{u \in U_i(+)} r_{u,i} ^2

Same thing for '-'


Or if you like better the dis/likers notation

key = (population_id, item, M, dis/likers)
value =
number: |U_i(dis/likers)|
sum_of_ratings: \sum_{u \ in U_i(dis/likers)} r_{u,i}
sum_of_squared_ratings: \sum_{u \in U_i(dis/likers)} r_{u,i} ^2


cf Middle of slide 24

NB If you consider each film might be a splitter there are 2x |item|^2 items of the second form ; that's because item -> (boolean, item, splitter) -- which is far less than your 2^|item| evaluation taht you haven't explained.

Step c computes, for each splitter M, the estimated SE by each movie, i.e. SE(U_M)_i

Because a sum can be split accross its different members:

U_M = U_{+M} + U_{-M} + U_{M?}

SE(U_M)_i = SE(U_M?)_i + SE(U_+M) + SE(U_-M)


with SE(U_{+M}) explicitly computed with this map function:

def map(key, value):
'''
key = (population_id, item, M, dis/likers)
'''
value =
count: 1
dist: (r_u,i - r_i)^2

emit key, value

def reduce(key, values):
'''
This function explicitly computes the SE for dis/likers
key = (population_id, item, M, dis/likers)
value= count, dist
'''
emit key, sum(count, sum(dist))


Now all we need SE(U_{M?})_i which is a "trivial" computation given in slide 24:

SE(?)_i = \sum_{u \in U_i(?)}{r_{u,i}^2} - (\sum r)^2 / |U_i(?)|


Of course, we are not going to do this big sums, but use the remark just above in the lecture, and the data already computed in step a (that's the conclusion I draw from slide 24 from the last 3 equations)

SE(?)_i = \sum_{u \in U_i}{r_{u,i}^2} - \sum_{u \in U_i('+'/'-')}{r_{u,i}^2} - (...)/ (|U_i| - |U_i('+'/'-'))


So this one is even not a Map/Reduce, it is just a finalize step:

def finalize(key, values):
for [k in keys if k match key]:
''' From all entries get
# from step a
key = (population_id, item) value=(nb_ratings, sum_ratings, sum_ratings_squared)
# from step b
key = (population_id, item, M, '+') value=(nb_ratings_likers, sum_ratings_likers, sum_ratings_squared_likers)
key = (population_id, item, M, '-') value=(nb_ratings_dislikers, sum_ratings_dislikers, sum_ratings_squared_dislikers)
# from step c
key = (population_id, item, M, '+') value=(se_likers)
key = (population_id, item, M, '-') value=(se_dislikers)
'''
se_other = sum_rating_squared - sum_ratings_squared_likers  - sum_ratins_squared_dislikers - sum_ratings_likers / (nb_ratings -  (nb_ratings_likers)) - sum_ratins_squared_dislikers  - sum_ratings_likers / (nb_ratings -  (nb_ratings_likers))
emit
key: (population_id, splitter, item)
value : se_likers + se_dislikers + se_other


Step d Finally, the last steps computes the SE for U_M. It is simply the sum of previous entries, and a trivual Map/Reduce:

For a splitter M:

SE(U_M) = \sum_i SE(U_M)_i = \sum_i SE(U_M?)_i + \sum_i SE(U_+M) + \sum_i SE(U_-M)

• And of course the actual computation of (r_{u,i} - r_i)^2 must be done on each done (that's the resposibily of the framework and it's results object). Also not that the variables are in LaTeX style, this won't compile in Python. – rds Aug 16 '11 at 15:25
• please use the terms of the question, the input for this stage is NOT r_{u,i}, it is records in the given form [two types, mentioned in the question]. also, it seems this solution does not use the hint given by the lecturer [which might be Ok, but still raises a red flag]. – amit Aug 16 '11 at 18:37
• I think I know where you misunderstood me, the given records are the input of step3, the specific step I'm having troubles with, and not to the whole algorithm. – amit Aug 16 '11 at 18:57
• @rds: allowed myself to TeXify your formula for better readability! – Jean-François Corbett Aug 16 '11 at 20:32
• Merci @Jean-François, I haven't found any reference to LaTex in the help about the Mardown syntax. Good to know it is supported, even though my answer is not good. – rds Aug 16 '11 at 21:52