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I have the following task. There is the 24-hours timetable. And there are some events with fixed length. I have a new event with predefined length ( for example 1 hour and 25 minutes ). The task is to know - how many times I can insert this task during the day (this task must not intersect other events.

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closed as not a real question by Ken White, Oded, Josh Caswell, Thomas Jungblut, kapa May 20 '12 at 11:07

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center. If this question can be reworded to fit the rules in the help center, please edit the question.

And what have you tried? –  Henk Holterman May 20 '12 at 7:13
I tried trivial solution, but now I search for special algos. –  dizpers May 20 '12 at 7:56
There are not really any algorithms to consider, since already naive algorithm accomplishes the task in O(n) :))). But wait, there might be one thing - sacrifice memory for performance, maintain the counts as an array for each free period, and when your daily schedule changes, only update those free periods, that changed. Not much to gain there, however, unless your day has million sections like DNA :))) –  Boris Stitnicky May 20 '12 at 8:31

1 Answer 1

our question might be considered a bit simplistic, so let the answer be simplistic, too (in Ruby):

#! /usr/bin/ruby
DAY_END = 24*60
# now, busy periods as array of size-2 arrays:
BUSY_PERIODS = [[9*60, 9*60+30], [18*60+30, 20*60]]
ADDITIONAL_EVENT_LENGTH = 1*60 + 25   # that is, 1 hour and  25 minutes
# in this simple program,
# time will be expressed as a number of minutes of the day
# for more advanced use, try to use "Time" class

# now let define a function to compute the list of free periods
# from a given list of busy periods:
def compute_free_periods( list_of_events )
  # at the begining of the calculation, our whole day is assumed free:
  free_periods = Array[ [ DAY_START, DAY_END] ]
  # now, one by one, let us take away the busy periods:
  list_of_events.each_with_object free_periods do | busy_period, free_periods |
    # we use 'each_with_object' version of 'each' enumerator
    # list of free_periods is passed in as an external object
    # so that we can gradually take each busy period away from it

    # let us first note the end time for the last free period
    # ( [-1] refers to the last element of the list of free periods,
    # subsequent [1] to the second element of the size-2 array )
    last_free_period_end = free_periods[-1][1]

    # and now, let us split this last free period into two by the
    # current busy period (busy periods assumed non-overlapping and
    # sorted in ascending order)

    # first, end time of the last free period is set to the beginning
    # of the busy period that we consider in this iteration:
    free_periods[-1][1] = busy_period[0]

    # then, additional free period is appended to the list of
    # free periods usind << operator, starting when the busy period ends:
    free_periods << [ busy_period[1], last_free_period_end ]

# now, let us use the function we just defined:
free_periods = compute_free_periods( BUSY_PERIODS )

# Now, for each free period we will count how many times we can stuff
# in the desired additional event:
free_period_capacities = free_periods.map { |free_period|
  # we are using map function for this, which will return
  # an array of the same length as free_periods, having
  # performed prescribed modifications on each element:

  # first, we calculate how many minutes a free period has
  period_length = free_period[1] - free_period[0]
  # then, we will use whole-number division to get the number
  # of additional events that can fit in:
  # (in Ruby, whole number division is the default behavior of / operator)

# and finally, we sum up the free period capacities for our new event:
total_events_possible = free_period_capacities.reduce( :+ )
# (summing is done elegantly by using reduce function with + operator)

# the last remaining thing we can do to consider program finished is to
puts total_events_possible # print the result on the screen

If you take out comments and shorten it, then the program becomes quite short:

#! /usr/bin/ruby
DAY_START, DAY_END = 0, 24*60
BUSY_PERIODS = [[9*60, 9*60+30], [18*60+30, 20*60]]

def compute_free_periods( list_of_events )
  free_periods = Array[ [ DAY_START, DAY_END] ]
  list_of_events.each_with_object free_periods do | busy_period, free_periods |
    last_free_period_end = free_periods[-1][1]
    free_periods[-1][1] = busy_period[0]
    free_periods << [ busy_period[1], last_free_period_end ] end

free_periods = compute_free_periods( BUSY_PERIODS )
free_period_capacities = free_periods.map { |free_period|
  period_length = free_period[1] - free_period[0]
  period_length / ADDITIONAL_EVENT_LENGTH }
puts ( total_events_possible = free_period_capacities.reduce( :+ ) )

You see, there is not so much of an algorithm. Just plain coding. Pick up eg. Ole Foul Zed's textbook Learn Ruby The Hard Way and start reading from Exercise 0 to the end. Or, you can go for some other language, such as Python. Ole Zed has teaching talent. If you appreciate the experience, don't forget to buy it as ebook.

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