## Question

`what is the best way to generate a cartesian product of some lists, not knowing in advance how many lists there are?`

*You can stop reading here if you like*.

## Background

I don't have money for school so I am trying to teach myself some programming using the Internet whilst working night shifts at a highway tollbooth. I have decided to try to solve some "programming challenge" problems as an exercise.

## Programming assignment

Here's the problem I am trying to tackle, property of TopCoder:

```
http://community.topcoder.com/stat?c=problem_statement&pm=3496
```

I will not copy and paste the full description to respect their copyright notice but I am assuming I can summarise it, provided I don't use pieces of it verbatim (IANAL though).

### Summary

If a "weighted sum" of historical stock prices is the sum of *addenda* obtained
by multiplying a subset of these prices by an equal number of "weighting"
factors, provided the latter add up to **1.0** and are chosen from the given set
of valid values **[-1.0, -0.9, ..., 0.9, 1.0]**, use this formula on all
historical data supplied as an argument to your function, examining **5** prices
at a time, predicting the next price and returning the permutation of "weighting
factors" that yields the lowest average prediction error. There will be at least
6 stock prices in each run so at least one prediction is guaranteed, final
results should be accurate within 1E-9.

### Test data

Format:

- One row for input data, in
`list`

format - One row for the expected result
- One empty row as a spacer

Download from:

## My solution

```
import itertools
# For a permutation of factors to be used in a weighted sum, it should be chosen
# such than the sum of all factors is 1.
WEIGHTED_SUM_TOTAL = 1.0
FACTORS_CAN_BE_USED_IN_WEIGHTED_SUM = lambda x: sum(x) == WEIGHTED_SUM_TOTAL
# Historical stock price data should be examined using a sliding window of width
# 5 when making predictions about the next price.
N_RECENT_PRICES = 5
# Valid values for weighting factors are: [-1.0, -0.9, ..., 0.9, 1.0]
VALID_WEIGHTS = [x / 10. for x in range(-10, 11)]
# A pre-calculated list of valid weightings to consider. This is the cartesiant
# product of the set of valid weigths considering only the combinations which
# are valid as components of a weighted sum.
CARTESIAN_PRODUCT_FACTORS = [VALID_WEIGHTS] * N_RECENT_PRICES
ALL_PERMUTATIONS_OF_WEIGHTS = itertools.product(*CARTESIAN_PRODUCT_FACTORS)
WEIGHTED_SUM_WEIGHTS = filter(FACTORS_CAN_BE_USED_IN_WEIGHTED_SUM,
ALL_PERMUTATIONS_OF_WEIGHTS)
# Generator function to get sliding windows of a given width from a data set
def sliding_windows(data, window_width):
for i in range(len(data) - window_width):
yield data[i:i + window_width], data[i + window_width]
def avg_error(data):
# The supplied data will guarantee at least one iteration
n_iterations = len(data) - 5
best_average_error = None
# Consider each valid weighting (e.g. permutation of weights)
for weighting in WEIGHTED_SUM_WEIGHTS:
# Keep track of the prediction errors for this weighting
errors_for_this_weighting = []
for historical_data, next_to_predict in sliding_windows(data,
N_RECENT_PRICES):
prediction = sum([a * b for a, b in zip(weighting, historical_data)])
errors_for_this_weighting.append(abs(next_to_predict - prediction))
average_error = sum(errors_for_this_weighting) / n_iterations
if average_error == 0: return average_error
best_average_error = (average_error if not best_average_error else
min(average_error, best_average_error))
return best_average_error
def main():
with open('data.txt') as input_file:
while True:
data = eval(input_file.readline())
expected_result = eval(input_file.readline())
spacer = input_file.readline()
if not spacer:
break
result = avg_error(data)
print expected_result, result, (expected_result - result) < 1e-9
if __name__ == '__main__':
main()
```

## My question

I am not asking for a code review of my solution because this would be the wrong StackExchange forum for that. I would post my solution to "Code Review" in that case.

My question instead is small, precise and unambiguous, fitting this site's format (hopefully).

In my code I generate a cartesian product of lists using itertools. In essence, I do not solve the crux of the problem myself but delegate the solution to a library that does that for me. I think this is the wrong approach to take if I want to *learn* from doing these exercises. I should be doing the hard part myself, otherwise why do the exercise at all? So I would like to ask you:

`what is the best way to generate a cartesian product of some lists, not knowing in advance how many lists there are?`

That's all I'd like to know, you can critique my code if you like. That's welcome, even if it passes all the tests (there is always a better way of doing things, especially if you are a beginner like me) but for this question to be "just right" for SO, I am focussing on just one aspect of the code, a concrete problem I have and something I am not happy with. Let me tell you more, I'll also share the canonical "what have you tried already"...

Clearly if I knew the number of lists I could just type in some nested for loops, like the top solvers of this exercise did in the competition. I tried writing a function that does this for an *unknown* number of lists but I was not sure which approach to take. The first approach was to write a recursive function. From list 1, take element 1 and combine it with element 1 of list 2, then element 1 of list 3, etc. I would push onto a stack the elements from each "layer" and pop them upon reaching the desired depth. I would imagine I would not fear a "stack overflow" because the depth reachable would be reasonable. I then struggled to choose a data structure to do this in the most efficient (memory/space) way possible, without passing too many parameters to the recursive calls. Should the data structure exist outside of the calls? Be passed around in the calls? Could I achieve any level of parallelism? How? With so many questions and so few answers I realised I needed to just know more to solve this problem and I could use a nudge in the right direction. You could provide a code snippet and I would study it. Or just explain to me what is the right "Computer Science" way of handling this type of problem. I am sure there is something I am not considering.

Finally, the thing that I *did* consider in my solution above is that thankfully filter filters a generator so the full cartesian product is never kept in memory (as it would if I did a list(ALL_PERMUTATIONS_OF_WEIGHTS) at any time in the code) so I am occupying space in memory only for those combinations which can actually be used as a weighted sum. A similar caution would be nice if applied to whatever system allows me to generate the cartesian product *without* using itertools.