# Minimum Sum of All Travel Times

There was a puzzle online that i tried to solve as follows,

`There is an infinite integer grid at which N people have their houses on. They decide to unite at a common meeting place, which is someone's house. From any given cell, all 8 adjacent cells are reachable in 1 unit of time. eg: (x,y) can be reached from (x-1,y+1) in a single unit of time. Find a common meeting place which minimizes the sum of the travel times of all the persons.`

I solved with all the sample test cases producing the correct output. But the code is failing some hidden test cases. Not sure if i have a bug in my code. Could someone please help with my approach.

-
What are "hidden test cases", and how is your code failing them? Maybe you are not parsing the data file correctly? –  Chronial Aug 11 '11 at 14:41
Are you saying that the output "8" in this case is wrong? Or is that a case that is failing because your program does not return 8 (which is the correct answer)? –  love_me_some_linux Aug 11 '11 at 14:57
@Ziyao - just now tried...still failing –  Prabhu Jayaraman Aug 11 '11 at 15:37
@Chronial - hidden test cases are that i am not able to think off –  Prabhu Jayaraman Aug 11 '11 at 15:38
@love... 8 is correct answer...and my code is also able to print it. –  Prabhu Jayaraman Aug 11 '11 at 15:39
show 4 more comments

This looks like the Interview Street 'Meeting Point' challenge. The code you posted doesn't compile as is but the basic approach looks like it will produce the correct answer. If you are trying to pass the Interview Street tests with that code though you'll fail the later tests because you'll run out of time. I think you'd also exceed the allowed memory usage - N can be up to 10000 according to the problem spec.

My first attempt at the problem was also an O(N^2) algorithm in time (though I didn't use any temporary storage) and failed the tests due to running over the allotted time. Obviously any solution that calculates the distance between every pair of points is going to be O(N^2) so in order to pass all the tests you need to figure out an algorithm that doesn't need to do that... There is a solution that has much lower algorithmic complexity - think about how you might solve the problem in 1D first without resorting to calculating the distance between every pair of points and then try and extend to 2D.

-
I tried a O(n) solution, could you tell me,why this scheme is failing? Pastebin link –  Greyhound Sep 3 '11 at 16:40
@Greyhound - because that's not a correct answer. Consider this input:(-3, 0) (-2, 0) (-1, 0) (0, 0) (10, 0) (50, 0). Because of the outlier at (50,0) your solution thinks (10,0) is the closest point to all others when it's really (0,0) or (-1,0). –  Jordan Messina Sep 3 '11 at 23:06
im able to do everything.. just unable to do that extending 1D to 2D thing :-| –  ghostCoder Apr 21 '12 at 21:27

Maybe it is the `abs` you are using?

`cstdlib`'s `abs()` only have these two versions:

`int abs(int n)`

`long abs(long n)`

Maybe it is failing on your unsigned long long.

See here, I made a test to prove my theory, and I believe it could be the problem.

-
tried changing the function...still failing...what algo did you use to solve this one ? –  Prabhu Jayaraman Aug 12 '11 at 5:51

A possible (if ridiculous, but this was an interview question, right?) test case would be the one where there are zero houses. Seems to me the correct answer then would be 0 (no travel time), but I think your code will say ULONG_MAX.

You also don't seem to have much error handling, what if the user says "four" instead of 4 or some other bogus input?

Also, the question clearly states that the grid is infinite, while you limit it to what fits in a ullong.

-

The question says to find the common meeting place but the output of your function is not a meeting place, it is just the sum of some distances. Could that be the problem? I'm not sure how your function would pass any test cases if that were the problem.

EDIT 1: The plane is infinite but you are using integer data types that have a limited range and could overflow. I guess you can't use Ruby and its Integer class which don't have this limitation?

-
The question is to find the minimum sum of all travel times. It's not about to find the common meeting place. –  Ravi Joshi Apr 14 '12 at 14:50
Hmm, maybe I'm hallucinating but the last sentence says "find a common meeting place which minimizes the sum..." –  David Grayson Apr 15 '12 at 15:32

Any O(n^2) approach to this problem will fail. You need something O(n log n) or better. My solution was O(n) time.

One way to solve this problem is to think carefully about the way you're allowed to move in the grid. Moving one square in any direction, including diagonals, is the same way a king moves on a chess board. Is there anything you can say about how kings move on chess boards? Is there any other metric space you know that's similar to this one?

-
hey could you give some pointers on this Java solution? I only passed first 4 test cases. gist.github.com/3951277 –  knd Oct 25 '12 at 8:00

I also gave an O(n) solution. But it passed only 11 of 13 testcases. My solution was based on Geometric median and Chebyshev distance. But I dont know about other two test cases.

-

my solution was same as @pkvprakash solution. i got through 12/13. no clue to get the last one. it is not time exceeded but wrong answer. :( and it is only the 5th case not even the 13th case

-

Doesn't just computing the minimal rectangle that contains the N grid immediately solve the problem? Maybe coding in C++ is the hardest part?

-
my bad.. I misunderstood the problem. Could anyone check my code? My solution is O(m*N) where m looks to be "reasonably small". Thanks.. –  mnish Feb 20 '12 at 13:08

I used the centroid method... Even though it gives wrong answer for the cases where the points are scattered, it passed 12 / 13 cases.. Only case #5 is failing just like rumnalp's.

-
did you passed case #5 ? I'm having the same problem ... –  gabitzish Oct 6 '12 at 21:07

Initially, I wanted to do the centroid method as follows

1. Get the centroid
2. Find the point that's nearest to the centroid. This should be their meeting point
3. Calculate the distances to that point

That solution passed 12/13 cases. Then I thought, due to rounding errors, the centroid and consequently the nearest point might be shifted a bit. So, I thought about having the nearest k-points to the centroid as candidate meeting points. I let k=4 (arbitrarily) and calculated the distances to those 4 points and got the minimum from them and voila, solved.

My final solution - that passes all tests is

1. Get the centroid
2. Find the nearest k-point that are nearest to the centroid. These should be good candidates for the meeting point
3. Calculate the distances from those points and select the minimum
-