# Can you answer this 2009 ACM International Collegiate Programming Contest Finals problem?

Out of curiosity, I was checking out the problem set to the 2009 ACM international collegiate programming contest. The questions are pretty interesting. They're available at http://cm.baylor.edu/resources/pdf/2009Problems.pdf. I could not come up with an algorithm that solved problem 1, which I will reproduce here. It set off a lively discussion in the office, and we think we're pretty close to an answer, but we'd really appreciate it if somebody could find/work out a full solution (code not required).

I will reproduce problem here for your convenience:

## Problem 1

Consider the task of scheduling the airplanes that are landing at an airport. Incoming airplanes report their positions, directions, and speeds, and then the controller has to devise a landing schedule that brings all airplanes safely to the ground. Generally, the more time there is between successive landings, the “safer” a landing schedule is. This extra time gives pilots the opportunity to react to changing weather and other surprises. Luckily, part of this scheduling task can be automated – this is where you come in. You will be given scenarios of airplane landings. Each airplane has a time window during which it can safely land. You must compute an order for landing all airplanes that respects these time windows. Furthermore, the airplane landings should be stretched out as much as possible so that the minimum time gap between successive landings is as large as possible. For example, if three airplanes land at 10:00am, 10:05am, and 10:15am, then the smallest gap is five minutes, which occurs between the first two airplanes. Not all gaps have to be the same, but the smallest gap should be as large as possible.

## Input

The input file contains several test cases consisting of descriptions of landing scenarios. Each test case starts with a line containing a single integer n (2 ≤ n ≤ 8), which is the number of airplanes in the scenario. This is followed by n lines, each containing two integers ai, bi, which give the beginning and end of the closed interval [ai, bi] during which the ith plane can land safely. The numbers ai and bi are specified in minutes and satisfy 0 ≤ ai ≤ bi ≤ 1440. The input is terminated with a line containing the single integer zero.

## Output

For each test case in the input, print its case number (starting with 1) followed by the minimum achievable time gap between successive landings. Print the time split into minutes and seconds, rounded to the closest second. Follow the format of the sample output.

Sample Input

``````3
0 10
5 15
10 15
2
0 10
10 20
0
``````

Sample Output

``````Case 1: 7:30
Case 2: 20:00
``````
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I would do something like this:

``````#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#define INPUT_SCALE 60
#define MAX_TIME (1440 * 60)

{
char buf[128];
gets(buf);
int start, end;
sscanf(buf, "%d %d", &start, &end);

for(int i=start * INPUT_SCALE; i<=end * INPUT_SCALE; i++)

if(end * INPUT_SCALE > endTime)
endTime = end * INPUT_SCALE;
}

{
while(start < MAX_TIME)
{
return start;
start++;
}

return -1;
}

{
int next = 0;
for(int i=0; i<planeCount; i++)
{
int nextForPlane = findNextLandingForPlane(landingMask, next, i);
if(nextForPlane == -1)
return false;

next = nextForPlane + minTime;
}

return true;
}

int main(int argc, char* argv[])
{
while(true)
{
char buf[128];
gets(buf);
int count = atoi(buf);
if(count == 0)
break;

int endTime = 0;
for(int i=0; i<count; i++)

while((endTime > 0) && !canLandPlanes(endTime, landingMask, count))
endTime--;

printf("%d:%02d\n", endTime / 60, endTime % 60);
}
}
``````
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Give it the input 3 0 2 7 10 4 6 0 it prints 0:00, while it is possible to shedule plains at 0, 10 and 5, giving answer 5:00. Input is not guaranteed to be sorted –  Pavel Feldman Dec 3 '09 at 21:12
Also, give it input 3 1439 1440 1439 1440 1439 1440 0 and see how long it takes –  Pavel Feldman Dec 3 '09 at 21:15
And #define MAX_TIME (1440 * 60 + 1) because value 1440 is included –  Pavel Feldman Dec 3 '09 at 21:24
@Pavel Feldman - true - it shouldn't rely on sorted input. I leave removing that restriction as an excercise to the reader (adjusting canLandPlanes() to not require sorting should be fairly easy). –  Aaron Dec 3 '09 at 21:26
>adjusting canLandPlanes() to not require sorting should be fairly easy How would you do that? If you presort input, how do you do that, by start time or end time? I can create counter-example for both cases. Say if you sort by start time, then input is 2 0 10 1 2 0 and you place first airplane at 0, then second goes to 2 and gap is 2, however you could place first airplane to 10 and second airplane to 1, giving gap=9. If you sort by end time, give it input 2 8 9 0 10 0 with similar problem. –  Pavel Feldman Dec 3 '09 at 21:35
show 1 more comment

I'll give a sketch of the algorithm.

First you binary search through the answer (minimal interval between flights). To do that, for each selected interval T you must be able to check whether it is possible to achieve it. If it is possible to achieve T, then you try making it smaller, if it is not - make it bigger.

To check whether you can achieve T, try all n! orders in which the planes may be landing (8! is small enough for this algo to work in time). For each permutation P1...Pn, you try assigning the times in a greedy manner:

``````int land = a[0];
for (int i = 1; i < n; i++) {
land = max(a[i], land + **T**);
if (land > b[i]) return "CAN NOT ACHIEVE INTERVAL T";
}
return "CAN ACHIEVE";
``````
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This optimization problem can be solved by linear programming http://en.wikipedia.org/wiki/Linear_programming

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Here's some Ruby code that brute-forces the solution. Note that test_case_one actually fails because I have commented out the code that would make this work with seconds (instead of just whole minutes).

The brute-force strategy is to permute all the sequences in which the planes may land. For each landing sequence, create the product of all possible landing times. This is fine with whole minutes, brutal with seconds.

But of course premature optimization, evil, and all that, so this is a first step:

``````require 'test/unit'

class SampleTests < Test::Unit::TestCase
def test_case_one
problem = Problem.new
problem.solve()
minimum_gap = problem.minimum_gap()
assert_equal(7.5, minimum_gap)
end

def test_case_two
problem = Problem.new
problem.solve()
minimum_gap = problem.minimum_gap()
assert_equal(20, minimum_gap)
end

def test_case_three
problem = Problem.new
minimum_gap = problem.minimum_gap()
assert_equal(5, minimum_gap)
end

def test_case_four
problem = Problem.new
assert_equal(0, problem.minimum_gap())
end

def test_case_five
problem = Problem.new
assert_equal(9, problem.minimum_gap())
end

def test_case_six
problem = Problem.new
assert_equal(9, problem.minimum_gap())
end
end

class Plane
def initialize(min, max)
@ts = Array.new
#This is a cheat to prevent combinatorial explosion. Just ignore 60 seconds in a minute!
#min = min * 60
#max = max * 60
min.upto(max) { | t | @ts << t}
end

#Array of times at which the plane might land.
def times
return @ts
end
end

#from 'permutation' gem
class Array
def permute(prefixed=[])
if (length < 2)
# there are no elements left to permute
yield(prefixed + self)
else
# recursively permute the remaining elements
each_with_index do |e, i|
(self[0,i]+self[(i+1)..-1]).permute(prefixed+[e]) { |a| yield a }
end
end
end
end

class Problem
def initialize
@solved = false
@maximum_gap = 0
@planes = Array.new
end

@planes << plane
end

#given a particular landing schedule, what's the minimum gap?
#A: Sort schedule and spin through it, looking for the min diff

#Note that this will return 0 for invalid schedules (planes landing simultaneously)
def gap_for(schedule)
schedule.sort!
min_gap = 1440
0.upto(schedule.length - 2) { | i |
gap = schedule[i + 1] - schedule[i]
if gap < min_gap
min_gap = gap
end
}
return min_gap
end

#Brute-force strategy
#Get every possible plane sequence (permute)
#Get every possible schedule for that sequence (brute_force_schedule)
#Check that schedule
def solve
@planes.permute { | sequence |
schedules = brute_force_schedule(sequence)
schedules.each { | schedule |
schedule.flatten!
gap = gap_for(schedule)
if gap > @maximum_gap
#puts "Found a new one: #{schedule.inspect}"
@maximum_gap = gap
end
}
}
end

#The list of all possible schedules associated with an array of planes
def brute_force_schedule(planes)
tail = planes[1..-1]
if tail.empty?
#Last element, return the times
else
#Recurse and combine (product)
end
end

def minimum_gap
unless @solved
solve
end
return @maximum_gap
end
end
``````
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