# Finding the day of the thirteenth of every month over a period of years

I am currently trying to solve some problems from the USACO training website in preparation for an unrelated C++ programming competition.

However, I am stuck on this problem:

Does the 13th of the month land on a Friday less often than on any other day of the week? To answer this question, write a program that will compute the frequency that the 13th of each month lands on Sunday, Monday, Tuesday, Wednesday, Thursday, Friday, and Saturday over a given period of N years. The time period to test will be from January 1, 1900 to December 31, 1900+N-1 for a given number of years, N. N is non-negative and will not exceed 400.

The number N is provided in an input file and the output is to be a file with seven numbers in it, each representing the number of 13th's falling on a particular day of the week.

I was wondering how you guys would approach this problem. I am not looking for code or anything since that would just defeat the purpose of me doing this, instead just a starting point or an algorithm would be helpful.

So far the only thing I could think of is using the Doomsday Algorithm, however I am unsure about how I would implement that in code.

Any help would be greatly appreciated.

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As Denny says, N is so small that you can easily iterate through the months using a table of days-in-a-month and a simple is-a-leap-year predicate to handle February. Just find out what day the 13th of Jan was in 1900 and then add up the elapsed days until 13th Feb, then 13th March etc.. Use a `%` operator to wrap the # of elapsed days back into a day-of-week value.

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This seems likes such a simple way to solve this as compared to all the lofty methods I was thinking of. Thank you so much for the enlightenment! – chandsie Nov 8 '10 at 4:13

Just use brute force. Like this pseudocode example:

``````from datetime import date

day_names = ['Monday', 'Tuesday', 'Wednesday', 'Thursday', 'Friday',
'Saturday', 'Sunday']
counts = [0] * 7
for year in range(1900, 2300):
for month in range(1, 13):
counts[date(year, month, 13).weekday()] += 1
for day, count in zip(day_names, counts):
print('%s: %d' % (day, count))
``````

The "hard" part is calculating the day of the week a date falls on. In C(++), you can use the mktime and localtime library functions if you know that your platform handles a large enough date range.

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"will not exceed" means range(1900, 2301) – Matt Joiner Nov 8 '10 at 3:07
It's a very big deal to assume you're given "date(y,m,d).weekday()" functionality, especially as the C++ Standard doesn't include it (most platforms time_t only go back to 1970). While performance/efficiency's not a concern here, it's worth knowing that such conversions are faily expensive in practice, and you're doing a lot of them needlessly. – Tony D Nov 8 '10 at 3:21
@Tony: it's not really terribly difficult to work your way backward from 1970 to 1900 though. If you're not willing to start with pre-knowledge of which years were leap years, you can work forward from 1970 until you find a year for which Feb 29 is valid (obviously no more than 4 years). From there you can work backward knowing every fourth year will be a leap year except for 1900 (a century year isn't a leap year unless it's also a multiple of 400). Once you've done that, working your way back forward is pretty trivial too. – Jerry Coffin Nov 8 '10 at 3:36
@Jerry: agreed - that's pretty much the solution I advocated. – Tony D Nov 8 '10 at 5:15

N is less than 400? well you just need to go over 365.25*400=146100 days at max. sounds easy to enumerate all of them, convert dates into year/month/date (with your favorite date conversion routine), testing for day of week is trivial.

I would precalculate the table though.

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