Yesterday I was pairing the socks from the clean laundry and figured out the way I was doing it is not very efficient. I was doing a naive search — picking one sock and "iterating" the pile in order to find its pair. This requires iterating over n/2 * n/4 = n2/8 socks on average.

As a computer scientist I was thinking what I could do? Sorting (according to size/color/...) of course came to mind to achieve an O(NlogN) solution.

Hashing or other not-in-place solutions are not an option, because I am not able to duplicate my socks (though it could be nice if I could).

So, the question is basically:

Given a pile of n pairs of socks, containing 2n elements (assume each sock has exactly one matching pair), what is the best way to pair them up efficiently with up to logarithmic extra space? (I believe I can remember that amount of info if needed.)

I will appreciate an answer that addresses the following aspects:

  • A general theoretical solution for a huge number of socks.
  • The actual number of socks is not that large, I don't believe my spouse and I have more than 30 pairs. (And it is fairly easy to distinguish between my socks and hers; can this be used as well?)
  • Is it equivalent to the element distinctness problem?
  • 486
    I use pigeon hole principle to pair exactly one from the laundry pile. I have 3 different colors of socks (Red,Blue and Green) and 2 pairs of each color. I pick up 4 number of socks each time and I always make up a pair and get to work.
    – Srinivas
    Jan 19, 2013 at 15:37
  • 68
    Yet another pigeon hole principle: if you take a subset of n/2 +1 socks, there must be at least one pair in this subset. Jan 19, 2013 at 15:57
  • 42
    Great question! You might be interested in my article on a related problem, which is a discussion of the probability of pulling two matched socks out of the pile: blogs.msdn.com/b/ericlippert/archive/2010/03/22/… Jan 20, 2013 at 19:08
  • 388
    Why not spawn a child and waitpid so that, as the parent, you're not even sorting any socks yourself?
    – Mxyk
    Sep 6, 2013 at 16:48
  • 183
    I solved this problem by only owning white knee-high socks. They all match. I could simply grab any two socks at random from the pile and they would match. I further simplify the problem by NOT pairing the socks. I have a sock drawer that I simply throw all my socks into, unpaired. I grab two at random from the drawer every morning. I've simplified it down to O(0). Can't get any simpler than that. :)
    – Lee
    Sep 6, 2013 at 20:18

38 Answers 38


What about doing some preprocessing? I would stitch a mark or id number in every sock in a way that every pair has the same mark/id number. This process might be done every time you buy a new pair of socks. Then, you could do a radix sort to get O(n) total cost. Find a place for every mark/id number and just pick all the socks one by one and put them into the correct place.


I thought about this very often during my PhD (in computer science). I came up with multiple solutions, depending on the ability to distinguish socks and thus find correct pairs as fast as possible.

Suppose the cost of looking at socks and memorizing their distinctive patterns is negligible (ε). Then the best solution is simply to throw all socks on a table. This involves those steps:

  1. Throw all socks on a table (1) and create a hashmap {pattern: position} (ε)
  2. While there are remaining socks (n/2):
    1. Pick up one random sock (1)
    2. Find position of corresponding sock (ε)
    3. Retrieve sock (1) and store pair

This is indeed the fastest possibility and is executed in n + 1 = O(n) complexity. But it supposes that you perfectly remember all patterns... In practice, this is not the case, and my personal experience is that you sometimes don't find the matching pair at first attempt:

  1. Throw all socks on a table (1)
  2. While there are remaining socks (n/2):
    1. Pick up one random sock (1)
    2. while it is not paired (1/P):
      1. Find sock with similar pattern
      2. Take sock and compare both (1)
      3. If ok, store pair

This now depends on our ability to find matching pairs. This is particularly true if you have dark/grey pairs or white sports socks that often have very similar patterns! Let's admit that you have a probability of P of finding the corresponding sock. You'll need, on average, 1/P tries before finding the corresponding sock to form a pair. The overall complexity is 1 + (n/2) * (1 + 1/P) = O(n).

Both are linear in the number of socks and are very similar solutions. Let's slightly modify the problem and admit you have multiple pairs of similar socks in the set, and that it is easy to store multiple pairs of socks in one move (1+ε). For K distinct patterns, you may implement:

  1. For each sock (n):
    1. Pick up one random sock (1)
    2. Put it on its pattern's cluster
  2. For each cluster (K):
    1. Take cluster and store pairs of socks (1+ε)

The overall complexity becomes n+K = O(n). It is still linear, but choosing the correct algorithm may now greatly depend on the values of P and K! But one may object again that you may have difficulties to find (or create) cluster for each sock.

Besides, you may also loose time by looking on websites what is the best algorithm and proposing your own solution :)


Towards an efficient algorithm for pairing socks from a pile


  1. There must be at least one sock in the pile
  2. The table must be large enough to accommodate N/2 socks (worst case), where N is the total number of socks.



  1. Pick the first sock
  2. Put it down on the table
  3. Pick next sock, and look at it (may throw 'no more socks in the pile' exception)
  4. Now scan the socks on the table (throws exception if there are no socks left on the table)
  5. Is there any match? a) yes => remove the matching sock from the table b) no => put the sock on the table (may throw 'the table is not large enough' exception)


  • The table is not large enough:
       carefully mix all unpaired socks together, then resume operation
       // this operation will result in a new pile and an empty table

  • No socks left on the table:
       throw (the last unpairable sock)

  • No socks left in the pile:
       exit laundry room


  • If there are still socks in the pile:
       goto 3

Known issues

The algorithm will enter an infinite loop if there is no table around or there is not enough place on the table to accommodate at least one sock.

Possible improvement

Depending on the number of socks to be sorted, throughput could be increased by sorting the socks on the table, provided there's enough space.

In order for this to work, an attribute is needed that has a unique value for each pair of socks. Such an attribute can be easily synthesized from the visual properties of the socks.

Sort the socks on the table by said attribute. Let's call that attribute ' colour'. Arrange the socks in a row, and put darker coloured socks to the right (i.e. .push_back()) and lighter coloured socks to the left (i.e. .push_front())

For huge piles and especially previously unseen socks, attribute synthesis might require significant time, so throughput will apparently decrease. However, these attributes can be persisted in memory and reused.

Some research is needed to evaluate the efficiency of this possible improvement. The following questions arise:

  • What is the optimal number of socks to be paired using above improvement?
  • For a given number of socks, how many iterations are needed before throughput increases?
    a) for the last iteration
    b) for all iterations overall

PoC in line with the MCVE guidelines:

#include <iostream>
#include <vector>
#include <string>
#include <time.h>

using namespace std;

struct pileOfsocks {
    pileOfsocks(int pairCount = 42) :
        elemCount(pairCount<<1) {

        vector<int> used_colors;
        vector<int> used_indices;

        auto getOne = [](vector<int>& v, int c) {
            int r;
            do {
                r = rand() % c;
            } while (find(v.begin(), v.end(), r) != v.end());
            return r;

        for (auto i = 0; i < pairCount; i++) {
            auto sock_color = getOne(used_colors, INT_MAX);
            socks[getOne(used_indices, elemCount)] = sock_color;
            socks[getOne(used_indices, elemCount)] = sock_color;

    void show(const string& prompt) {
        cout << prompt << ":" << endl;
        for (auto i = 0; i < socks.size(); i++){
            cout << socks[i] << " ";
        cout << endl;

    void pair() {
        for (auto i = 0; i < socks.size(); i++) {
            std::vector<int>::iterator it = find(unpaired_socks.begin(), unpaired_socks.end(), socks[i]);
            if (it != unpaired_socks.end()) {

        socks = paired_socks;

    int elemCount;
    vector<int> socks;
    vector<int> unpaired_socks;
    vector<int> paired_socks;

int main() {
    pileOfsocks socks;

    socks.show("unpaired socks");
    socks.show("paired socks");

    return 0;
  • You had be until you used GOTO: :(
    – NTDLS
    Dec 10, 2020 at 18:15
  • I often get my kids to help me with this task, which begs the question: Is this thread safe?
    – NTDLS
    Dec 10, 2020 at 18:16

As many authors have pointed out, radix sort is an efficient way of sorting socks. What has not yet been proposed is a perfect hashing method. Using the time each pair of socks was bought is such a hash. Simply numbering your socks sequentially as you purchase them will let you place them in their own numbered drawer as you go through the pile.

Example for up to 24 pairs of socks. Note that larger sock compartments eliminate the need to roll socks together, the so-called speed/storage tradeoff.

Example for up to 24 pairs of socks. Note that larger sock compartments eliminate the need to roll socks together, the so-called speed/storage tradeoff.


My proposed solution assumes that all socks are identical in details, except by color. If there are more details to defer between socks, these details can be used to define different types of socks instead of colors in my example ..

Given that we have a pile of socks, a sock can come in three colors: Blue, red, or green.

Then we can create a parallel worker for each color; it has its own list to fill corresponding colors.

At time i:

Blue  read  Pile[i]    : If Blue  then Blue.Count++  ; B=TRUE  ; sync

Red   read  Pile[i+1]  : If Red   then Red.Count++   ; R=TRUE  ; sync

Green read  Pile [i+2] : If Green then Green.Count++ ; G=TRUE  ; sync

With synchronization process:

Sync i:


If R is TRUE:
    If G is TRUE:

This requires an initialization:


If Pile[0] != Blue:
    If      Pile[0] = Red   : Red.Count++
    Else if Pile[0] = Green : Green.Count++

If Pile[1] != Red:
    If Pile[0] = Green : Green.Count++


Best Case: B, R, G, B, R, G, .., B, R, G

Worst Case: B, B, B, .., B

Time(Worst-Case) = C * n ~ O(n)

Time(Best-Case) = C * (n/k) ~ O(n/k)

n: number of sock pairs
k: number of colors
C: sync overhead

Two lines of thinking, the speed it takes to find any match, versus the speed it takes to find all matches compared to the storage.

For the second case, I wanted to point out a GPU paralleled version which queries the socks for all matches.

If you have multiple properties for which to match, you can make use of grouped tuples and fancier zip iterators and the transform functions of thrust, for simplicity sake though here is a simple GPU based query:

#include <thrust/device_vector.h>
#include <thrust/sequence.h>
#include <thrust/copy.h>
#include <thrust/count.h>
#include <thrust/remove.h>
#include <thrust/random.h>
#include <iostream>
#include <iterator>
#include <string>

// Define some types for pseudo code readability
typedef thrust::device_vector<int> GpuList;
typedef GpuList::iterator          GpuListIterator;

template <typename T>
struct ColoredSockQuery : public thrust::unary_function<T,bool>
    ColoredSockQuery( int colorToSearch )
    { SockColor = colorToSearch; }

    int SockColor;

    __host__ __device__
    bool operator()(T x)
        return x == SockColor;

struct GenerateRandomSockColor
    float lowBounds, highBounds;

    __host__ __device__
    GenerateRandomSockColor(int _a= 0, int _b= 1) : lowBounds(_a), highBounds(_b) {};

    __host__ __device__
    int operator()(const unsigned int n) const
        thrust::default_random_engine rng;
        thrust::uniform_real_distribution<float> dist(lowBounds, highBounds);
        return dist(rng);

template <typename GpuListIterator>
void PrintSocks(const std::string& name, GpuListIterator first, GpuListIterator last)
    typedef typename std::iterator_traits<GpuListIterator>::value_type T;

    std::cout << name << ": ";
    thrust::copy(first, last, std::ostream_iterator<T>(std::cout, " "));
    std::cout << "\n";

int main()
    int numberOfSocks = 10000000;
    GpuList socks(numberOfSocks);
                      GenerateRandomSockColor(0, 200));

    clock_t start = clock();

    GpuList sortedSocks(socks.size());
    GpuListIterator lastSortedSock = thrust::copy_if(socks.begin(),
    clock_t stop = clock();

    PrintSocks("Sorted Socks: ", sortedSocks.begin(), lastSortedSock);

    double elapsed = (double)(stop - start) * 1000.0 / CLOCKS_PER_SEC;
    std::cout << "Time elapsed in ms: " << elapsed << "\n";

    return 0;

    //nvcc -std=c++11 -o test test.cu

Run time for 10 million socks: 9 ms


Defant & Kravitz (1) give an algorithm for sorting socks by placing them sequentially on and off feet. 1-sorting socks: using just a single foot

Their algorithm works with an arbitrary number of feet. 2-sorting socks: using two feet

The paper gives (Theorem 1.1) a characterization of the sock orders which are sortable using a single foot. It follows from their Theorem 1.3 that every sock ordering with 4 colors can be sorted using at most two feet, while there exist sock orderings with 5 colors which are not possible to sort with two feet.

  1. Colin Defant and Noah Kravitz, Foot-Sorting for Socks (2022)

We can use hashing to our leverage if you can abstract a single pair of socks as the key itself and its other pair as value.

  1. Make two imaginary sections behind you on the floor, one for you and another for your spouse.

  2. Take one from the pile of socks.

  3. Now place the socks on the floor, one by one, following the below rule.

    • Identify the socks as yours or hers and look at the relevant section on the floor.

    • If you can spot the pair on the floor pick it up and knot them up or clip them up or do whatever you would do after you find a pair and place it in a basket (remove it from the floor).

    • Place it in the relevant section.

  4. Repeat 3 until all socks are over from the pile.


Hashing and Abstraction

Abstraction is a very powerful concept that has been used to improve user experience (UX). Examples of abstraction in real-life interactions with computers include:

  • Folder icons used for navigation in a GUI (graphical user interface) to access an address instead of typing the actual address to navigate to a location.
  • GUI sliders used to control various levels of volume, document scroll position, etc..

Hashing or other not-in-place solutions are not an option because I am not able to duplicate my socks (though it could be nice if I could).

I believe the asker was thinking of applying hashing such that the slot to which either pair of sock goes should be known before placing them.

That's why I suggested abstracting a single sock that is placed on the floor as the hash key itself (hence there is no need to duplicate the socks).

How to define our hash key?

The below definition for our key would also work if there are more than one pair of similar socks. That is, let's say there are two pairs of black men socks PairA and PairB, and each sock is named PairA-L, PairA-R, PairB-L, PairB-R. So PairA-L can be paired with PairB-R, but PairA-L and PairB-L cannot be paired.

Let say any sock can be uniqly identified by,

Attribute[Gender] + Attribute[Colour] + Attribute[Material] + Attribute[Type1] + Attribute[Type2] + Attribute[Left_or_Right]

This is our first hash function. Let's use a short notation for this h1(G_C_M_T1_T2_LR). h1(x) is not our location key.

Another hash function eliminating the Left_or_Right attribute would be h2(G_C_M_T1_T2). This second function h2(x) is our location key! (for the space on the floor behind you).

  • To locate the slot, use h2(G_C_M_T1_T2).
  • Once the slot is located then use h1(x) to check their hashes. If they don't match, you have a pair. Else throw the sock into the same slot.

NOTE: Since we remove a pair once we find one, it's safe to assume that there would only be at a maximum one slot with a unique h2(x) or h1(x) value.

In case we have each sock with exactly one matching pair then use h2(x) for finding the location and if no pair, a check is required, since it's safe to assume they are a pair.

Why is it important to lay the socks on the floor

Let's consider a scenario where the socks are stacked over one another in a pile (worst case). This means we would have no other choice but to do a linear search to find a pair.

Spreading them on the floor gives more visibility which improves the chance of spotting the matching sock (matching a hash key). When a sock was placed on the floor in step 3, our mind had subconsciously registered the location. - So in case, this location is available in our memory we can directly find the matching pair. - In case the location is not remembered, don't worry, then we can always revert back to linear search.

Why is it important to remove the pair from the floor?

  • Short-term human memory works best when it has fewer items to remember. Thus increasing the probability of us resorting to hashing to spot the pair.
  • It will also reduce the number of items to be searched through when linear searching for the pair is being used.


  1. Case 1: Worst case when Derpina cannot remember or spot the socks on the floor directly using the hashing technique. Derp does a linear search through the items on the floor. This is not worse than the iterating through the pile to find the pair.
    • Upper bound for comparison: O(n^2).
    • Lower bound for comparison: (n/2). (when every other sock Derpina picks up is the pair of previous one).
  2. Case 2: Derp remembers each the location of every sock that he placed on the floor and each sock has exactly one pair.
    • Upper bound for comparison: O(n/2).
    • Lower bound for comparison: O(n/2).

I am talking about comparison operations, picking the socks from the pile would necessarily be n number of operations. So a practical lower bound would be n iterations with n/2 comparisons.

Speeding up things

To achieve a perfect score so Derp gets O(n/2) comparisons, I would recommend Derpina to,

  • spend more time with the socks to get familiarize with it. Yes, that means spending more time with Derp's socks too.
  • Playing memory games like spot the pairs in a grid can improve short-term memory performance, which can be highly beneficial.

Is this equivalent to the element distinctness problem?

The method I suggested is one of the methods used to solve element distinctness problem where you place them in the hash table and do the comparison.

Given your special case where there exists only one exact pair, it has become very much equivalent to the element distinct problem. Since we can even sort the socks and check adjacent socks for pairs (another solution for EDP).

However, if there is a possibility of more than one pair that can exist for given sock then it deviates from EDP.

  • 2
    So, basically other then splitting the problem into 2 subproblems (without resplitting it again later on) - it offers to "cache" as much elements I can (the top of each "spot"), while piling it up, and repeat while there are still elements. Can you provide complexity analysis for it? My gut tells me it is going to be worse then O(n^2) at average case (though I cannot prove it yet), and you cannot bound the number of iterations you make. You are also going to need some randomization to guarantee you take the elements at different order each time. Or am I missing something here?
    – amit
    Jan 21, 2013 at 15:07
  • worst case (assuming all pairs are men's and are different) would be n^2 and on the extreme other side the number of linear searches you would need would be n/2. I would improve my answer later today to explain how the iterations would be performed on reducing sets.
    – D34dman
    Jan 22, 2013 at 14:42
  • @amit EDIT NOTE: originally i wanted to point out that hashing is possible. But due to human mind behavior being sporadic hashing is not totally reliable and thus a mixture of hashing and linear searching have been suggested. I am in favor of linear searching as against any other form of searching since it involves least stress on human mind. Since hashing method might prove quite stressful linear searching would be quite a relief. IMHO, Efficiency should be measured with respect to time required to complete this operation rather than iterations required.
    – D34dman
    Jan 29, 2013 at 16:35

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