Let's say you've got an airplane, and it is low on fuel. Unless the plane drops 3000 pounds of passenger weight, it will not be able to reach the next airport. To save the maximum number of lives, we would like to throw the heaviest people off of the plane first.

And oh yeah, there are millions of people on the airplane, and we would like an optimal algorithm to find the heaviest passengers, without necessarily sorting the entire list.

This is a proxy problem for something I'm trying to code in C++. I would like to do a "partial_sort" on the passenger manifest by weight, but I don't know how many elements I'm going to need. I could implement my own "partial_sort" algorithm ("partial_sort_accumulate_until"), but I'm wondering if there's any easier way to do this using standard STL.

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    If the analogy to human holds you could start by throwing off people that weigh more then X, for instance 120 kg, since those are very likely to be among the fattest people. – RedX Oct 12 '11 at 21:15
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    Would all passengers cooperate with any step of the algorithm? – Lior Kogan Oct 12 '11 at 21:20
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    topics like this are why i love IT. – Markus Oct 13 '11 at 7:18
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    Can I ask which airline this is for? I want to make sure I only fly with them before the holiday season - not after I've over indulged myself. – jp2code Oct 18 '11 at 17:18
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    Passenger cooperation is not required with the proper equipment (like ejector seats with built-in scales). – Jim Fred Oct 18 '11 at 18:28

12 Answers 12


One way would be to use a min heap (std::priority_queue in C++). Here's how you'd do it, assuming you had a MinHeap class. (Yes, my example is in C#. I think you get the idea.)

int targetTotal = 3000;
int totalWeight = 0;
// this creates an empty heap!
var myHeap = new MinHeap<Passenger>(/* need comparer here to order by weight */);
foreach (var pass in passengers)
    if (totalWeight < targetTotal)
        // unconditionally add this passenger
        totalWeight += pass.Weight;
    else if (pass.Weight > myHeap.Peek().Weight)
        // If this passenger is heavier than the lightest
        // passenger already on the heap,
        // then remove the lightest passenger and add this one
        var oldPass = myHeap.RemoveFirst();
        totalWeight -= oldPass.Weight;
        totalWeight += pass.Weight;

// At this point, the heaviest people are on the heap,
// but there might be too many of them.
// Remove the lighter people until we have the minimum necessary
while ((totalWeight - myHeap.Peek().Weight) > targetTotal)
    var oldPass = myHeap.RemoveFirst();
    totalWeight -= oldPass.Weight; 
// The heap now contains the passengers who will be thrown overboard.

According to the standard references, running time should be proportional to n log k, where n is the number of passengers and k is the maximum number of items on the heap. If we assume that passengers' weights will typically be 100 lbs or more, then it's unlikely that the heap will contain more than 30 items at any time.

The worst case would be if the passengers are presented in order from lowest weight to highest. That would require that every passenger be added to the heap, and every passenger be removed from the heap. Still, with a million passengers and assuming that the lightest weighs 100 lbs, the n log k works out to a reasonably small number.

If you get the passengers' weights randomly, performance is much better. I use something quite like this for a recommendation engine (I select the top 200 items from a list of several million). I typically end up with only 50,000 or 70,000 items actually added to the heap.

I suspect that you'll see something quite similar: the majority of your candidates will be rejected because they're lighter than the lightest person already on the heap. And Peek is an O(1) operation.

For a more information about the performance of heap select and quick select, see When theory meets practice. Short version: if you're selecting fewer than 1% of the total number of items, then heap select is a clear winner over quick select. More than 1%, then use quick select or a variant like Introselect.

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    SoapBox posted the faster answer. – Mooing Duck Oct 12 '11 at 23:41
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    To my reading, SoapBox's answer is the moral equivalent of Jim Mischel's answer. SoapBox wrote his code in C++, and thus he uses a std::set, which has the same log(N) add time as the MinHeap. – IvyMike Oct 12 '11 at 23:52
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    There is a linear time solution. I'll add it. – Neil G Oct 13 '11 at 1:24
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    There's a STL class for a min-heap: std::priority_queue – bdonlan Oct 13 '11 at 3:42
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    @MooingDuck: Perhaps you misunderstood. My code creates an empty heap, just as SoapBox's code creates an empty set. The major difference, as I see it, is that his code trims the set of excess weight as higher weight items are added, whereas mine maintains the excess and trims it at the end. His set will potentially decrease in size as he moves through the list finding heavier people. My heap stays the same size after it reaches the weight threshold, and I trim it after checking the last item in the list. – Jim Mischel Oct 14 '11 at 2:52

This won't help for your proxy problem, however:

For 1,000,000 passengers to drop 3000 pounds of weight, each passenger must lose (3000/1000000) = 0.003 lbs per person. That could be achieved through jettisoning every ones shirt, or shoes, or probably even fingernail clippings, saving everyone. This assumes efficient collection and jettison before the weight loss needed increased as the plane used more fuel.

Actually, they don't allow fingernail clippers on board anymore, so that's out.

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    Love the ability to look through the problem and find a truly better way. – fncomp Oct 19 '11 at 5:39
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    I think shoes alone would cover this – Mooing Duck May 23 '12 at 19:15
  • 0.003 lbs is 0.048 oz, which is just under 1/20 of an ounce. So if a mere one in sixty people on the plane was taking advantage of the three-ounce shampoo rule, you could save the day just by throwing out all that shampoo. – Ryan Lundy Feb 11 '15 at 18:23

Below is a rather simple implementation of the straightforward solution. I don't think there is a faster way that is 100% correct.

size_t total = 0;
std::set<passenger> dead;
for ( auto p : passengers ) {
    if (dead.empty()) {
       total += p.weight;
    if (total < threshold || p.weight > dead.begin()->weight)
        total += p.weight;
        while (total > threshold)
            if (total - dead.begin()->weight < threshold)
            total -= dead.begin()->weight;

This works by filling up the set of "dead people" until it meets the threshold. Once the threshold is met, we keep going through the list of passengers trying to find any that are heavier than the lightest dead person. When we have found one, we add them to the list and then start "Saving" the lightest people off the list until we can't save any more.

In the worst case, this will perform about the same as a sort of the entire list. But in the best case (the "dead list" is filled up properly with the first X people) it will perform O(n).

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    I think you have to update total next to continue; Other than that, this is the answer I was going to post. Super fast solution – Mooing Duck Oct 12 '11 at 23:38
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    This is the correct answer, this is the fastest answer, this is also the answer with the lowest complexity. – Xander Tulip Apr 17 '12 at 1:21
  • You could probably squeeze a little more out of it by caching dead.begin() and by rearranging stuff a bit to minimize branching, which on modern processors is quite slow – Wug Jul 16 '12 at 18:54
  • dead.begin() is most likely trival and would almost certainly be inlined to just a data access. But yeah, moving around a few of the ifs would eek out a little more performance by reducing branches... but at probably great cost to readability. – SoapBox Jul 16 '12 at 22:19
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    This is logically elegant, and addresses ALL of the OP's requirements, including not knowing the # of passengers up front. Having spent much of the last 5 months working with STL Maps & Sets though, I'm sure the extensive use of iterators used would cripple performance. Just populate the set, and then iterate from right to left until the sum of the heaviest people is greater than 3,000. A Set of 1 million elements, presented in random order, will load at ~ 30 million/sec on i5||i7 3.4Ghz cores. Iteration at least 100X as slow. KISS will win here. – user2548100 Nov 22 '13 at 23:06

Assuming all passengers will cooperate: Use a parallel sorting network. (see also this)

Here is a live demonstration

Update: Alternative video (jump to 1:00)

Asking pairs of people to compare-exchange - you can't get faster than this.

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    This is still a sort and will be O(nlogn). You certainly can get faster, as an O(nlogk) where k << n, solution has been provided. – Adam Oct 15 '11 at 0:06
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    @Adam: It's parallel sort. Sorting has a lower bound of O(nlog n) SEQUENTIAL steps. However they can paralleled, so the time complexity can be much lower. see for example cs.umd.edu/~gasarch/ramsey/parasort.pdf – Lior Kogan Oct 15 '11 at 7:17
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    Well, the OP says "This is a proxy problem for something I'm trying to code in C++." So even if the passengers will cooperate, they won't compute for you. It's a neat idea, but that paper's assumption that you get n processors does not hold. – Adam Oct 15 '11 at 7:38
  • @LiorKogan - the live demo video is no longer available on youtube – Adelin Sep 11 '17 at 6:34
  • @Adelin: Thank you, alternative video added – Lior Kogan Sep 11 '17 at 6:45

@Blastfurnace was on the right track. You use quickselect where the pivots are weight thresholds. Each partition splits one set of people into sets, and returns the total weight for each set of people. You continue breaking the appropriate bucket until your buckets corresponding to the highest weight people are over 3000 pounds, and your lowest bucket that is in that set has 1 person (that is, it can't be split any further.)

This algorithm is linear time amortized, but quadratic worst case. I think it is the only linear time algorithm.

Here's a Python solution that illustrates this algorithm:

#!/usr/bin/env python
import math
import numpy as np
import random

in_trouble = [math.floor(x * 10) / 10
              for x in np.random.standard_gamma(16.0, 100) * 8.0]
dead = []
spared = []

dead_weight = 0.0

while in_trouble:
    m = np.median(list(set(random.sample(in_trouble, min(len(in_trouble), 5)))))
    print("Partitioning with pivot:", m)
    lighter_partition = []
    heavier_partition = []
    heavier_partition_weight = 0.0
    in_trouble_is_indivisible = True
    for p in in_trouble:
        if p < m:
            heavier_partition_weight += p
        if p != m:
            in_trouble_is_indivisible = False
    if heavier_partition_weight + dead_weight >= OVERWEIGHT and not in_trouble_is_indivisible:
        spared += lighter_partition
        in_trouble = heavier_partition
        dead += heavier_partition
        dead_weight += heavier_partition_weight
        in_trouble = lighter_partition

print("weight of dead people: {}; spared people: {}".format(
    dead_weight, sum(spared)))
print("Dead: ", dead)
print("Spared: ", spared)


Partitioning with pivot: 121.2
Partitioning with pivot: 158.9
Partitioning with pivot: 168.8
Partitioning with pivot: 161.5
Partitioning with pivot: 159.7
Partitioning with pivot: 158.9
weight of dead people: 3051.7; spared people: 9551.7
Dead:  [179.1, 182.5, 179.2, 171.6, 169.9, 179.9, 168.8, 172.2, 169.9, 179.6, 164.4, 164.8, 161.5, 163.1, 165.7, 160.9, 159.7, 158.9]
Spared:  [82.2, 91.9, 94.7, 116.5, 108.2, 78.9, 83.1, 114.6, 87.7, 103.0, 106.0, 102.3, 104.9, 117.0, 96.7, 109.2, 98.0, 108.4, 99.0, 96.8, 90.7, 79.4, 101.7, 119.3, 87.2, 114.7, 90.0, 84.7, 83.5, 84.7, 111.0, 118.1, 112.1, 92.5, 100.9, 114.1, 114.7, 114.1, 113.7, 99.4, 79.3, 100.1, 82.6, 108.9, 103.5, 89.5, 121.8, 156.1, 121.4, 130.3, 157.4, 138.9, 143.0, 145.1, 125.1, 138.5, 143.8, 146.8, 140.1, 136.9, 123.1, 140.2, 153.6, 138.6, 146.5, 143.6, 130.8, 155.7, 128.9, 143.8, 124.0, 134.0, 145.0, 136.0, 121.2, 133.4, 144.0, 126.3, 127.0, 148.3, 144.9, 128.1]
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    +1. This is an interesting idea, although I'm not certain that it's quite linear. Unless I'm missing something, you have to iterate over items in order to compute the total weight of the bucket, and you have to re-compute the high bucket (at least partially) every time you split. It'll still be faster than my heap-based approach in the general case, but I think you're underestimating the complexity. – Jim Mischel Oct 13 '11 at 17:40
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    @Jim: It should be the same complexity as quickselect. I know the description on wikipedia is not the best, but the reason that it's linear amortized time is that every time you do a partition, you work with only one side of the partition. Non-rigorously, imagine each partition divides the set of people in two. Then, the first step takes O(n), then O(n/2), etc. and, n + n/2 + n/4 +... = 2n. – Neil G Oct 13 '11 at 19:19
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    @Jim: Anyway, your algorithm has the best worst case time, while mine has the best average case time. I think that they're both good solutions. – Neil G Oct 13 '11 at 19:21
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    @JimMischel, NeilG: codepad.org/FAx6hbtc I verified all have the same results, and corrected Jim's. FullSort: 1828 ticks. JimMischel: 312 ticks. SoapBox 109 ticks. NeilG: 641 ticks. – Mooing Duck Oct 13 '11 at 22:46
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    @NeilG: codepad.org/0KmcsvwD I used std::partition to make my implementation of your algorithm way faster. stdsort: 1812 ticks. FullHeap 312 ticks. Soapbox/JimMichel: 109 ticks, NeilG: 250 ticks. – Mooing Duck Oct 14 '11 at 18:35

Assuming that, like people's weights, you have a good idea of what the maximum and minimum values are likely to be use a radix sort to sort them in O(n). Then simply work from the heaviest end of the list towards the lightest. Total running time: O(n). Unfortunately, there isn't an implementation of a radix sort in the STL, but it's pretty straightforward to write.

  • I wouldn't use a general radix sort though, as you don't have to fully sort the list to derive the answer. – Mooing Duck Oct 13 '11 at 20:38
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    To clarify, a radix sort is a good idea. Just be sure to write a customized optimized one. – Mooing Duck Oct 13 '11 at 23:23
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    @Mooing: It is true that you don't have to do a complete radix sort, but at the time I posted this, there were no O(n) algorithms posted and this was an easy one to see. I think that Neil G's answer is he best one now that he's explained it more fully and explicitly started using the median as the pivot for his selection. But using a standard radix sort is slightly easier and less likely to have subtle implementation bugs, so I'm going to leave my answer up. Doing a customized partial radix sort would definitely be faster, but not asymptotically so. – Keith Irwin Oct 14 '11 at 0:49

Why don't you use a partial quicksort with a different abort rule than "sorted". You can run it and then use just the higher half and go on until the weight within this higher half does not contain the weight that has at least to be thrown out anymore, than you go back one step in the recursion and sort the list. After that you can start throwing people out from the high end of that sorted list.

  • That's the basic concept behind Neil G's algorithm I think. – Mooing Duck Oct 13 '11 at 20:42
  • that's the essence of quickselect, which is what Neil G is using. – Michael Donohue Oct 25 '11 at 4:22

Massively Parallel Tournament Sort:-

Assuming a standard three seats each side of the ailse:-

  1. Ask the passengers in the window seat to move to the middle seat if they are heavier than the person in the window seat.

  2. Ask the passengers in the middle seat to swap with the passenger in aisle seat if they are heavier.

  3. Ask the passenger in the left aisle seat to swap with the passenger in the right aisle seat id they are heavier.

  4. Bubble sort the passengers in the right aisle seat. (Takes n steps for n rows). -- ask the passengers in the right aisle seat to swap with the person in front n -1 times.

5 Kick them out the door until you reach 3000 pounds.

3 steps + n steps plus 30 steps if you have a really skinny passenger load.

For a two aisle plane -- the instructions are more complex but the performance is about the same.

  • same as Lior Kogan's answer, but much more detail. – Mooing Duck Oct 13 '11 at 20:40
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    A "good enough" solution would be to offer "free hotdogs" and throw out the first fifteen that reached the front. Will not provide the optimal solution every time but runs in plain "O". – James Anderson Oct 14 '11 at 1:37
  • Wouldn't it be better to throw out the last 15 since the heavier ones will probably be slower? – Peter Oct 26 '11 at 16:20
  • @Patriker -- I believe the aim is to lose 3000 pounds with the minimum number of people. Although you could optimise the algorithm by change step 4 to "swap with the person in from n - 29 times" which would get the 30 porkiest to the front, though, not in strict order of weight. – James Anderson Oct 27 '11 at 1:59

I would probably use std::nth_element to partition off the 20 heaviest people in linear time. Then use a more complex method to find and bump off the heaviest of the heavies.


You could make one pass over the list to get the mean and the standard deviation, then use that to approximate the number of people that have to go. Use partial_sort to generate the list based on that number. If the guess was low, use partial_sort again on the remainder with a new guess.


@James has the answer in the comments: a std::priority_queue if you can use any container, or a combination of std::make_heap and std::pop_heap (and std::push_heap) if you want to use something like a std::vector.


Here's a heap-based solution using Python's built-in heapq module. It's in Python so doesn't answer the original question, but it's cleaner (IMHO) than the other posted Python solution.

import itertools, heapq

# Test data
from collections import namedtuple

Passenger = namedtuple("Passenger", "name seat weight")

passengers = [Passenger(*p) for p in (
    ("Alpha", "1A", 200),
    ("Bravo", "2B", 800),
    ("Charlie", "3C", 400),
    ("Delta", "4A", 300),
    ("Echo", "5B", 100),
    ("Foxtrot", "6F", 100),
    ("Golf", "7E", 200),
    ("Hotel", "8D", 250),
    ("India", "8D", 250),
    ("Juliet", "9D", 450),
    ("Kilo", "10D", 125),
    ("Lima", "11E", 110),

# Find the heaviest passengers, so long as their
# total weight does not exceeed 3000

to_toss = []
total_weight = 0.0

for passenger in passengers:
    weight = passenger.weight
    total_weight += weight
    heapq.heappush(to_toss, (weight, passenger))

    while total_weight - to_toss[0][0] >= 3000:
        weight, repreived_passenger = heapq.heappop(to_toss)
        total_weight -= weight

if total_weight < 3000:
    # Not enough people!
    raise Exception("We're all going to die!")

# List the ones to toss. (Order doesn't matter.)

print "We can get rid of", total_weight, "pounds"
for weight, passenger in to_toss:
    print "Toss {p.name!r} in seat {p.seat} (weighs {p.weight} pounds)".format(p=passenger)

If k = the number of passengers to toss and N = the number of passengers, then the best case for this algorithm is O(N) and the worst case for this algorithm is Nlog(N). The worst case occurs if k is near N for a long time. Here's an example of the worst cast:

weights = [2500] + [1/(2**n+0.0) for n in range(100000)] + [3000]

However, in this case (throwing people off the plane (with a parachute, I presume)) then k must be less than 3000, which is << "millions of people". The average runtime should therefore be about Nlog(k), which is linear to the number of people.

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