Hungarian algorithm

Template:Short description The Hungarian method is a combinatorial optimization algorithm that solves the assignment problem in polynomial time and which anticipated later primal–dual methods. It was developed and published in 1955 by Harold Kuhn, who gave it the name "Hungarian method" because the algorithm was largely based on the earlier works of two Hungarian mathematicians, Dénes Kőnig and Jenő Egerváry.^[1][2] However, in 2006 it was discovered that Carl Gustav Jacobi had solved the assignment problem in the 19th century, and the solution had been published posthumously in 1890 in Latin.^[3]

James Munkres reviewed the algorithm in 1957 and observed that it is (strongly) polynomial.^[4] Since then the algorithm has been known also as the Kuhn–Munkres algorithm or Munkres assignment algorithm. The time complexity of the original algorithm was ${\displaystyle O(n^4)}$, however Edmonds and Karp, and independently Tomizawa, noticed that it can be modified to achieve an ${\displaystyle O(n^3)}$ running time.^[5][6] Ford and Fulkerson extended the method to general maximum flow problems in form of the Ford–Fulkerson algorithm.

Template:Main

In this simple example, there are three workers: Alice, Bob and Carol. One of them has to clean the bathroom, another sweep the floors and the third washes the windows, but they each demand different pay for the various tasks. The problem is to find the lowest-cost way to assign the jobs. The problem can be represented in a matrix of the costs of the workers doing the jobs. For example:

Template:Diagonal split header	Clean bathroom	Sweep floors	Wash windows
Alice	$8	$4	$7
Bob	$5	$2	$3
Carol	$9	$4	$8

The Hungarian method, when applied to the above table, would give the minimum cost: this is $15, achieved by having Alice clean the bathroom, Carol sweep the floors, and Bob wash the windows. This can be confirmed using brute force:

Template:Diagonal split header	Alice	Bob	Carol
Alice	—	$17	$16
Bob	$18	—	$18
Carol	$15	$16	—

(the unassigned person washes the windows)

In the matrix formulation, we are given an n×n matrix, where the element in the i-th row and j-th column represents the cost of assigning the j-th job to the i-th worker. We have to find an assignment of the jobs to the workers, such that each job is assigned to one worker and each worker is assigned one job, such that the total cost of assignment is minimum.

This can be expressed as permuting the rows of a cost matrix C to minimize the trace of a matrix,

${\displaystyle \underset{P}{\min }\mathrm{Tr}(PC),}$

where P is a permutation matrix. (Equivalently, the columns can be permuted using CP.)

If the goal is to find the assignment that yields the maximum cost, the problem can be solved by negating the cost matrix C.

The algorithm can equivalently be described by formulating the problem using a bipartite graph. We have a complete bipartite graph ${\displaystyle G=(S,T;E)}$ with Template:Mvar worker vertices (Template:Mvar) and Template:Mvar job vertices (Template:Mvar), and the edges (Template:Mvar) each have a cost ${\displaystyle c(i,j)}$. We want to find a perfect matching with a minimum total cost.

Let us call a function ${\displaystyle y:(S\cup T)\to ℝ}$ a potential if ${\displaystyle y(i)+y(j)\le c(i,j)}$ for each ${\displaystyle i\in S,j\in T}$.

The value of potential Template:Mvar is the sum of the potential over all vertices:

${\displaystyle \sum _{v\in S\cup T}y(v)}$.

The cost of each perfect matching is at least the value of each potential: the total cost of the matching is the sum of costs of all edges; the cost of each edge is at least the sum of potentials of its endpoints; since the matching is perfect, each vertex is an endpoint of exactly one edge; hence the total cost is at least the total potential.

The Hungarian method finds a perfect matching and a potential such that the matching cost equals the potential value. This proves that both of them are optimal. In fact, the Hungarian method finds a perfect matching of tight edges: an edge ${\displaystyle ij}$ is called tight for a potential Template:Mvar if ${\displaystyle y(i)+y(j)=c(i,j)}$. Let us denote the subgraph of tight edges by ${\displaystyle G_y}$. The cost of a perfect matching in ${\displaystyle G_y}$ (if there is one) equals the value of Template:Mvar.

During the algorithm we maintain a potential Template:Mvar and an orientation of ${\displaystyle G_y}$ (denoted by ${\displaystyle \overrightarrow{G_y}}$) which has the property that the edges oriented from Template:Mvar to Template:Mvar form a matching Template:Mvar. Initially, Template:Mvar is 0 everywhere, and all edges are oriented from Template:Mvar to Template:Mvar (so Template:Mvar is empty). In each step, either we modify Template:Mvar so that its value increases, or modify the orientation to obtain a matching with more edges. We maintain the invariant that all the edges of Template:Mvar are tight. We are done if Template:Mvar is a perfect matching.

In a general step, let ${\displaystyle R_S\subseteq S}$ and ${\displaystyle R_T\subseteq T}$ be the vertices not covered by Template:Mvar (so ${\displaystyle R_S}$ consists of the vertices in Template:Mvar with no incoming edge and ${\displaystyle R_T}$ consists of the vertices in Template:Mvar with no outgoing edge). Let Template:Mvar be the set of vertices reachable in ${\displaystyle \overrightarrow{G_y}}$ from ${\displaystyle R_S}$ by a directed path. This can be computed by breadth-first search.

If ${\displaystyle R_T\cap Z}$ is nonempty, then reverse the orientation of all edges along a directed path in ${\displaystyle \overrightarrow{G_y}}$ from ${\displaystyle R_S}$ to ${\displaystyle R_T}$. Thus the size of the corresponding matching increases by 1.

If ${\displaystyle R_T\cap Z}$ is empty, then let

${\displaystyle \mathrm{\Delta }:=\min \{c(i,j)-y(i)-y(j):i\in Z\cap S,j\in T\setminus Z\}.}$

Template:Math is well defined because at least one such edge ${\displaystyle ij}$ must exist whenever the matching is not yet of maximum possible size (see the following section); it is positive because there are no tight edges between ${\displaystyle Z\cap S}$ and ${\displaystyle T\setminus Z}$. Increase Template:Mvar by Template:Math on the vertices of ${\displaystyle Z\cap S}$ and decrease Template:Mvar by Template:Math on the vertices of ${\displaystyle Z\cap T}$. The resulting Template:Mvar is still a potential, and although the graph ${\displaystyle G_y}$ changes, it still contains Template:Mvar (see the next subsections). We orient the new edges from Template:Mvar to Template:Mvar. By the definition of Template:Math the set Template:Mvar of vertices reachable from ${\displaystyle R_S}$ increases (note that the number of tight edges does not necessarily increase). If the vertex added to ${\displaystyle Z\cap T}$ is unmatched (that is, it is also in ${\displaystyle R_T}$), then at the next iteration the graph will have an augmenting path.

We repeat these steps until Template:Mvar is a perfect matching, in which case it gives a minimum cost assignment. The running time of this version of the method is ${\displaystyle O(n^4)}$: Template:Mvar is augmented Template:Mvar times, and in a phase where Template:Mvar is unchanged, there are at most Template:Mvar potential changes (since Template:Mvar increases every time). The time sufficient for a potential change is ${\displaystyle O(n^2)}$.

We must show that as long as the matching is not of maximum possible size, the algorithm is always able to make progress — that is, to either increase the number of matched edges, or tighten at least one edge. It suffices to show that at least one of the following holds at every step:

• Template:Mvar is of maximum possible size.
• ${\displaystyle G_y}$ contains an augmenting path.
• Template:Mvar contains a loose-tailed path: a path from some vertex in ${\displaystyle R_S}$ to a vertex in ${\displaystyle T\setminus Z}$ that consists of any number (possibly zero) of tight edges followed by a single loose edge. The trailing loose edge of a loose-tailed path is thus from ${\displaystyle Z\cap S}$, guaranteeing that Template:Math is well defined.

If Template:Mvar is of maximum possible size, we are of course finished. Otherwise, by Berge's lemma, there must exist an augmenting path Template:Mvar with respect to Template:Mvar in the underlying graph Template:Mvar. However, this path may not exist in ${\displaystyle G_y}$: Although every even-numbered edge in Template:Mvar is tight by the definition of Template:Mvar, odd-numbered edges may be loose and thus absent from ${\displaystyle G_y}$. One endpoint of Template:Mvar is in ${\displaystyle R_S}$, the other in ${\displaystyle R_T}$; w.l.o.g., suppose it begins in ${\displaystyle R_S}$. If every edge on Template:Mvar is tight, then it remains an augmenting path in ${\displaystyle G_y}$ and we are done. Otherwise, let ${\displaystyle uv}$ be the first loose edge on Template:Mvar. If ${\displaystyle v\notin Z}$ then we have found a loose-tailed path and we are done. Otherwise, Template:Mvar is reachable from some other path Template:Mvar of tight edges from a vertex in ${\displaystyle R_S}$. Let ${\displaystyle P_v}$ be the subpath of Template:Mvar beginning at Template:Mvar and continuing to the end, and let ${\displaystyle P^{\prime }}$ be the path formed by traveling along Template:Mvar until a vertex on ${\displaystyle P_v}$ is reached, and then continuing to the end of ${\displaystyle P_v}$. Observe that ${\displaystyle P^{\prime }}$ is an augmenting path in Template:Mvar with at least one fewer loose edge than Template:Mvar. Template:Mvar can be replaced with ${\displaystyle P^{\prime }}$ and this reasoning process iterated (formally, using induction on the number of loose edges) until either an augmenting path in ${\displaystyle G_y}$ or a loose-tailed path in Template:Mvar is found.

To show that every edge in Template:Mvar remains after adjusting Template:Mvar, it suffices to show that for an arbitrary edge in Template:Mvar, either both of its endpoints, or neither of them, are in Template:Mvar. To this end let ${\displaystyle vu}$ be an edge in Template:Mvar from Template:Mvar to Template:Mvar. It is easy to see that if Template:Mvar is in Template:Mvar then Template:Mvar must be too, since every edge in Template:Mvar is tight. Now suppose, toward contradiction, that ${\displaystyle u\in Z}$ but ${\displaystyle v\notin Z}$. Template:Mvar itself cannot be in ${\displaystyle R_S}$ because it is the endpoint of a matched edge, so there must be some directed path of tight edges from a vertex in ${\displaystyle R_S}$ to Template:Mvar. This path must avoid Template:Mvar, since that is by assumption not in Template:Mvar, so the vertex immediately preceding Template:Mvar in this path is some other vertex ${\displaystyle v^{\prime }\in T}$. ${\displaystyle v^{\prime }u}$ is a tight edge from Template:Mvar to Template:Mvar and is thus in Template:Mvar. But then Template:Mvar contains two edges that share the vertex Template:Mvar, contradicting the fact that Template:Mvar is a matching. Thus every edge in Template:Mvar has either both endpoints or neither endpoint in Template:Mvar.

To show that Template:Mvar remains a potential after being adjusted, it suffices to show that no edge has its total potential increased beyond its cost. This is already established for edges in Template:Mvar by the preceding paragraph, so consider an arbitrary edge Template:Mvar from Template:Mvar to Template:Mvar. If ${\displaystyle y(u)}$ is increased by Template:Math, then either ${\displaystyle v\in Z\cap T}$, in which case ${\displaystyle y(v)}$ is decreased by Template:Math, leaving the total potential of the edge unchanged, or ${\displaystyle v\in T\setminus Z}$, in which case the definition of Template:Math guarantees that ${\displaystyle y(u)+y(v)+\mathrm{\Delta }\le c(u,v)}$. Thus Template:Mvar remains a potential.

Suppose there are ${\displaystyle J}$ jobs and ${\displaystyle W}$ workers (${\displaystyle J\le W}$). We describe how to compute for each prefix of jobs the minimum total cost to assign each of these jobs to distinct workers. Specifically, we add the ${\displaystyle j}$th job and update the total cost in time ${\displaystyle O(jW)}$, yielding an overall time complexity of ${\displaystyle O\left({\displaystyle \sum _{j=1}^J}jW\right)=O(J^{2}W)}$. Note that this is better than ${\displaystyle O(W^3)}$ when the number of jobs is small relative to the number of workers.

We use the same notation as the previous section, though we modify their definitions as necessary. Let ${\displaystyle S_j}$ denote the set of the first ${\displaystyle j}$ jobs and ${\displaystyle T}$ denote the set of all workers.

Before the ${\displaystyle j}$th step of the algorithm, we assume that we have a matching on ${\displaystyle S_{j-1}\cup T}$ that matches all jobs in ${\displaystyle S_{j-1}}$ and potentials ${\displaystyle y}$ satisfying the following condition: the matching is tight with respect to the potentials, and the potentials of all unmatched workers are zero, and the potentials of all matched workers are non-positive. Note that such potentials certify the optimality of the matching.

During the ${\displaystyle j}$th step, we add the ${\displaystyle j}$th job to ${\displaystyle S_{j-1}}$ to form ${\displaystyle S_j}$ and initialize ${\displaystyle Z=\{j\}}$. At all times, every vertex in ${\displaystyle Z}$ will be reachable from the ${\displaystyle j}$th job in ${\displaystyle G_y}$. While ${\displaystyle Z}$ does not contain a worker that has not been assigned a job, let

${\displaystyle \mathrm{\Delta }:=\min \{c(j,w)-y(j)-y(w):j\in Z\cap S_j,w\in T\setminus Z\}}$

and ${\displaystyle w_{\text{next}}}$ denote any ${\displaystyle w}$ at which the minimum is attained. After adjusting the potentials in the way described in the previous section, there is now a tight edge from ${\displaystyle Z}$ to ${\displaystyle w_{\text{next}}}$.

• If ${\displaystyle w_{\text{next}}}$ is unmatched, then we have an augmenting path in the subgraph of tight edges from ${\displaystyle j}$ to ${\displaystyle w_{\text{next}}}$. After toggling the matching along this path, we have now matched the first ${\displaystyle j}$ jobs, and this procedure terminates.
• Otherwise, we add ${\displaystyle w_{\text{next}}}$ and the job matched with it to ${\displaystyle Z}$.

Adjusting potentials takes ${\displaystyle O(W)}$ time. Recomputing ${\displaystyle \mathrm{\Delta }}$ and ${\displaystyle w_{\text{next}}}$ after changing the potentials and ${\displaystyle Z}$ also can be done in ${\displaystyle O(W)}$ time. Case 1 can occur at most ${\displaystyle j-1}$ times before case 2 occurs and the procedure terminates, yielding the overall time complexity of ${\displaystyle O(jW)}$.

For convenience of implementation, the code below adds an additional worker ${\displaystyle w_W}$ such that ${\displaystyle y(w_W)}$ stores the negation of the sum of all ${\displaystyle \mathrm{\Delta }}$ computed so far. After the ${\displaystyle j}$th job is added and the matching updated, the cost of the current matching equals the sum of all ${\displaystyle \mathrm{\Delta }}$ computed so far, or ${\displaystyle -y(w_W)}$.

This code is adapted from e-maxx :: algo.^[7]

/**
 * Solution to https://open.kattis.com/problems/cordonbleu using Hungarian
 * algorithm.
 */

#include <cassert>
#include <iostream>
#include <limits>
#include <vector>
using namespace std;

/**
 * Sets a = min(a, b)
 * @return true if b < a
 */
template <class T> bool ckmin(T &a, const T &b) { return b < a ? a = b, 1 : 0; }

/**
 * Given J jobs and W workers (J <= W), computes the minimum cost to assign each
 * prefix of jobs to distinct workers.
 *
 * @tparam T a type large enough to represent integers on the order of J *
 * max(|C|)
 * @param C a matrix of dimensions JxW such that C[j][w] = cost to assign j-th
 * job to w-th worker (possibly negative)
 *
 * @return a vector of length J, with the j-th entry equaling the minimum cost
 * to assign the first (j+1) jobs to distinct workers
 */
template <class T> vector<T> hungarian(const vector<vector<T>> &C) {
    const int J = (int)size(C), W = (int)size(C[0]);
    assert(J <= W);
    // job[w] = job assigned to w-th worker, or -1 if no job assigned
    // note: a W-th worker was added for convenience
    vector<int> job(W + 1, -1);
    vector<T> ys(J), yt(W + 1);  // potentials
    // -yt[W] will equal the sum of all deltas
    vector<T> answers;
    const T inf = numeric_limits<T>::max();
    for (int j_cur = 0; j_cur < J; ++j_cur) {  // assign j_cur-th job
        int w_cur = W;
        job[w_cur] = j_cur;
        // min reduced cost over edges from Z to worker w
        vector<T> min_to(W + 1, inf);
        vector<int> prv(W + 1, -1);  // previous worker on alternating path
        vector<bool> in_Z(W + 1);    // whether worker is in Z
        while (job[w_cur] != -1) {   // runs at most j_cur + 1 times
            in_Z[w_cur] = true;
            const int j = job[w_cur];
            T delta = inf;
            int w_next;
            for (int w = 0; w < W; ++w) {
                if (!in_Z[w]) {
                    if (ckmin(min_to[w], C[j][w] - ys[j] - yt[w]))
                        prv[w] = w_cur;
                    if (ckmin(delta, min_to[w])) w_next = w;
                }
            }
            // delta will always be nonnegative,
            // except possibly during the first time this loop runs
            // if any entries of C[j_cur] are negative
            for (int w = 0; w <= W; ++w) {
                if (in_Z[w]) ys[job[w]] += delta, yt[w] -= delta;
                else min_to[w] -= delta;
            }
            w_cur = w_next;
        }
        // update assignments along alternating path
        for (int w; w_cur != W; w_cur = w) job[w_cur] = job[w = prv[w_cur]];
        answers.push_back(-yt[W]);
    }
    return answers;
}

/**
 * Sanity check: https://en.wikipedia.org/wiki/Hungarian_algorithm#Example
 * First job (5):
 *   clean bathroom: Bob -> 5
 * First + second jobs (9):
 *   clean bathroom: Bob -> 5
 *   sweep floors: Alice -> 4
 * First + second + third jobs (15):
 *   clean bathroom: Alice -> 8
 *   sweep floors: Carol -> 4
 *   wash windows: Bob -> 3
 */
void sanity_check_hungarian() {
    vector<vector<int>> costs{{8, 5, 9}, {4, 2, 4}, {7, 3, 8}};
    assert((hungarian(costs) == vector<int>{5, 9, 15}));
    cerr << "Sanity check passed.\n";
}

// solves https://open.kattis.com/problems/cordonbleu
void cordon_bleu() {
    int N, M;
    cin >> N >> M;
    vector<pair<int, int>> B(N), C(M);
    vector<pair<int, int>> bottles(N), couriers(M);
    for (auto &b : bottles) cin >> b.first >> b.second;
    for (auto &c : couriers) cin >> c.first >> c.second;
    pair<int, int> rest;
    cin >> rest.first >> rest.second;
    vector<vector<int>> costs(N, vector<int>(N + M - 1));
    auto dist = [&](pair<int, int> x, pair<int, int> y) {
        return abs(x.first - y.first) + abs(x.second - y.second);
    };
    for (int b = 0; b < N; ++b) {
        for (int c = 0; c < M; ++c) {  // courier -> bottle -> restaurant
            costs[b][c] =
                dist(couriers[c], bottles[b]) + dist(bottles[b], rest);
        }
        for (int _ = 0; _ < N - 1; ++_) {  // restaurant -> bottle -> restaurant
            costs[b][_ + M] = 2 * dist(bottles[b], rest);
        }
    }
    cout << hungarian(costs).back() << "\n";
}

int main() {
    sanity_check_hungarian();
    cordon_bleu();
}

The Hungarian algorithm can be seen to be equivalent to the successive shortest path algorithm for minimum cost flow,^[8][9] where the reweighting technique from Johnson's algorithm is used to find the shortest paths. The implementation from the previous section is rewritten below in such a way as to emphasize this connection; it can be checked that the potentials ${\displaystyle h}$ for workers ${\displaystyle 0\dots W-1}$ are equal to the potentials ${\displaystyle y}$ from the previous solution up to a constant offset. When the graph is sparse (there are only ${\displaystyle M}$ allowed job, worker pairs), it is possible to optimize this algorithm to run in ${\displaystyle O(JM+J^2\log W)}$ time by using a Fibonacci heap to determine ${\displaystyle w_{\text{next}}}$ instead of iterating over all ${\displaystyle W}$ workers to find the one with minimum distance (alluded to here).

template <class T> vector<T> hungarian(const vector<vector<T>> &C) {
    const int J = (int)size(C), W = (int)size(C[0]);
    assert(J <= W);
    // job[w] = job assigned to w-th worker, or -1 if no job assigned
    // note: a W-th worker was added for convenience
    vector<int> job(W + 1, -1);
    vector<T> h(W);  // Johnson potentials
    vector<T> answers;
    T ans_cur = 0;
    const T inf = numeric_limits<T>::max();
    // assign j_cur-th job using Dijkstra with potentials
    for (int j_cur = 0; j_cur < J; ++j_cur) {
        int w_cur = W;  // unvisited worker with minimum distance
        job[w_cur] = j_cur;
        vector<T> dist(W + 1, inf);  // Johnson-reduced distances
        dist[W] = 0;
        vector<bool> vis(W + 1);     // whether visited yet
        vector<int> prv(W + 1, -1);  // previous worker on shortest path
        while (job[w_cur] != -1) {   // Dijkstra step: pop min worker from heap
            T min_dist = inf;
            vis[w_cur] = true;
            int w_next = -1;  // next unvisited worker with minimum distance
            // consider extending shortest path by w_cur -> job[w_cur] -> w
            for (int w = 0; w < W; ++w) {
                if (!vis[w]) {
                    // sum of reduced edge weights w_cur -> job[w_cur] -> w
                    T edge = C[job[w_cur]][w] - h[w];
                    if (w_cur != W) {
                        edge -= C[job[w_cur]][w_cur] - h[w_cur];
                        assert(edge >= 0);  // consequence of Johnson potentials
                    }
                    if (ckmin(dist[w], dist[w_cur] + edge)) prv[w] = w_cur;
                    if (ckmin(min_dist, dist[w])) w_next = w;
                }
            }
            w_cur = w_next;
        }
        for (int w = 0; w < W; ++w) {  // update potentials
            ckmin(dist[w], dist[w_cur]);
            h[w] += dist[w];
        }
        ans_cur += h[w_cur];
        for (int w; w_cur != W; w_cur = w) job[w_cur] = job[w = prv[w_cur]];
        answers.push_back(ans_cur);
    }
    return answers;
}

This variant of the algorithm follows the formulation given by Flood,^[10] and later described more explicitly by Munkres, who proved it runs in ${\displaystyle 𝒪(n^4)}$ time.^[4] Instead of keeping track of the potentials of the vertices, the algorithm operates only on a matrix:

${\displaystyle a_{ij}:=c(i,j)-y(i)-y(j)}$

where ${\displaystyle c(i,j)}$ is the original cost matrix and ${\displaystyle y(i),y(j)}$ are the potentials from the graph interpretation. Changing the potentials corresponds to adding or subtracting from rows or columns of this matrix. The algorithm starts with ${\displaystyle a_{ij}=c(i,j)}$. As such, it can be viewed as taking the original cost matrix and modifying it.

Given Template:Mvar workers and tasks, the problem is written in the form of an Template:Mvar×Template:Mvar cost matrix

Template:Aligned table

where a, b, c and d are workers who have to perform tasks 1, 2, 3 and 4. a₁, a₂, a₃, and a₄ denote the penalties incurred when worker "a" does task 1, 2, 3, and 4 respectively.

The problem is equivalent to assigning each worker a unique task such that the total penalty is minimized. Note that each task can only be worked on by one worker.

For each row, its minimum element is subtracted from every element in that row. This causes all elements to have nonnegative values. Therefore, an assignment with a total penalty of 0 is by definition a minimum assignment.

This also leads to at least one zero in each row. As such, a naive greedy algorithm can attempt to assign all workers a task with a penalty of zero. This is illustrated below.

Template:Aligned table

The zeros above would be the assigned tasks.

Worst-case there are Template:Mvar! combinations to try, since multiple zeroes can appear in a row if multiple elements are the minimum. So at some point this naive algorithm should be short circuited.

Sometimes it may turn out that the matrix at this stage cannot be used for assigning, as is the case for the matrix below.

Template:Aligned table

To overcome this, we repeat the above procedure for all columns (i.e. the minimum element in each column is subtracted from all the elements in that column) and then check if an assignment with penalty 0 is possible.

In most situations this will give the result, but if it is still not possible then we need to keep going.

All zeros in the matrix must be covered by marking as few rows and/or columns as possible. Steps 3 and 4 form one way to accomplish this.

For each row, try to assign an arbitrary zero. Assigned tasks are represented by starring a zero. Note that assignments can't be in the same row or column.

• We assign the first zero of Row 1. The second zero of Row 1 can't be assigned.
• We assign the first zero of Row 2. The second zero of Row 2 can't be assigned.
• Zeros on Row 3 and Row 4 can't be assigned, because they are on the same column as the zero assigned on Row 1.

We could end with another assignment if we choose another ordering of the rows and columns.

Template:Aligned table

Cover all columns containing a (starred) zero.

×	×
0*	a2	0	a4
b1	0*	b3	0
0	c2	c3	c4
0	d2	d3	d4

Find a non-covered zero and prime it (mark it with a prime symbol). If no such zero can be found, meaning all zeroes are covered, skip to step 5.

• If the zero is on the same row as a starred zero, cover the corresponding row, and uncover the column of the starred zero.
• Then, GOTO "Find a non-covered zero and prime it."
  • Here, the second zero of Row 1 is uncovered. Because there is another zero starred on Row 1, we cover Row 1 and uncover Column 1.
  • Then, the second zero of Row 2 is uncovered. We cover Row 2 and uncover Column 2.

	×
0*	a2	0'	a4	×
b1	0*	b3	0
0	c2	c3	c4
0	d2	d3	d4

0*	a2	0'	a4	×
b1	0*	b3	0'	×
0	c2	c3	c4
0	d2	d3	d4

• Else the non-covered zero has no assigned zero on its row. We make a path starting from the zero by performing the following steps:
  1. Substep 1: Find a starred zero on the corresponding column. If there is one, go to Substep 2, else, stop.
  2. Substep 2: Find a primed zero on the corresponding row (there should always be one). Go to Substep 1.

The zero on Row 3 is uncovered. We add to the path the first zero of Row 1, then the second zero of Row 1, then we are done.

0*	a2	0'	a4	×
b1	0*	b3	0'	×
0'	c2	c3	c4
0	d2	d3	d4

• (Else branch continued) For all zeros encountered during the path, star primed zeros and unstar starred zeros.
  • As the path begins and ends by a primed zero when swapping starred zeros, we have assigned one more zero.

0	a2	0*	a4
b1	0*	b3	0
0*	c2	c3	c4
0	d2	d3	d4

• (Else branch continued) Unprime all primed zeroes and uncover all lines.
• Repeat the previous steps (continue looping until the above "skip to step 5" is reached).
  • We cover columns 1, 2 and 3. The second zero on Row 2 is uncovered, so we cover Row 2 and uncover Column 2:

×		×
0	a2	0*	a4
b1	0*	b3	0'	×
0*	c2	c3	c4
0	d2	d3	d4

All zeros are now covered with a minimal number of rows and columns.

The aforementioned detailed description is just one way to draw the minimum number of lines to cover all the 0s. Other methods work as well.

If the number of starred zeros is Template:Mvar (or in the general case ${\displaystyle min(n,m)}$, where Template:Mvar is the number of people and Template:Mvar is the number of jobs), the algorithm terminates. See the Result subsection below on how to interpret the results.

Otherwise, find the lowest uncovered value. Subtract this from every unmarked element and add it to every element covered by two lines. Go back to step 4.

This is equivalent to subtracting a number from all rows which are not covered and adding the same number to all columns which are covered. These operations do not change optimal assignments.

If following this specific version of the algorithm, the starred zeros form the minimum assignment.

From Kőnig's theorem,^[11] the minimum number of lines (minimum vertex cover^[12]) will be Template:Mvar (the size of maximum matching^[13]). Thus, when Template:Mvar lines are required, minimum cost assignment can be found by looking at only zeroes in the matrix.

• R.E. Burkard, M. Dell'Amico, S. Martello: Assignment Problems (Revised reprint). SIAM, Philadelphia (PA.) 2012. Template:ISBN
• M. Fischetti, "Lezioni di Ricerca Operativa", Edizioni Libreria Progetto Padova, Italia, 1995.
• R. Ahuja, T. Magnanti, J. Orlin, "Network Flows", Prentice Hall, 1993.
• S. Martello, "Jeno Egerváry: from the origins of the Hungarian algorithm to satellite communication". Central European Journal of Operational Research 18, 47–58, 2010

Template:Reflist

• Bruff, Derek, The Assignment Problem and the Hungarian Method (matrix formalism).
• Mordecai J. Golin, Bipartite Matching and the Hungarian Method (bigraph formalism), Course Notes, Hong Kong University of Science and Technology.
• Hungarian maximum matching algorithm (both formalisms), in Brilliant website.
• R. A. Pilgrim, Munkres' Assignment Algorithm. Modified for Rectangular Matrices, Course notes, Murray State University.
• Mike Dawes, The Optimal Assignment Problem, Course notes, University of Western Ontario.
• On Kuhn's Hungarian Method – A tribute from Hungary, András Frank, Egervary Research Group, Pazmany P. setany 1/C, H1117, Budapest, Hungary.
• Lecture: Fundamentals of Operations Research - Assignment Problem - Hungarian Algorithm, Prof. G. Srinivasan, Department of Management Studies, IIT Madras.
• Extension: Assignment sensitivity analysis (with O(n^4) time complexity), Liu, Shell.
• Solve any Assignment Problem online, provides a step by step explanation of the Hungarian Algorithm.

Note that not all of these satisfy the ${\displaystyle O(n^3)}$ time complexity, even if they claim so. Some may contain errors, implement the slower ${\displaystyle O(n^4)}$ algorithm, or have other inefficiencies. In the worst case, a code example linked from Wikipedia could later be modified to include exploit code. Verification and benchmarking is necessary when using such code examples from unknown authors.

• Lua and Python versions of R.A. Pilgrim's code (claiming ${\displaystyle O(n^3)}$ time complexity)
• Julia implementation
• C implementation claiming ${\displaystyle O(n^3)}$ time complexity
• Java implementation claiming ${\displaystyle O(n^3)}$ time complexity
• Python implementation
• Ruby implementation with unit tests
• C# implementation claiming ${\displaystyle O(n^3)}$ time complexity
• D implementation with unit tests (port of a Java version claiming ${\displaystyle O(n^3)}$) Template:Webarchive
• Online interactive implementation
• Serial and parallel implementations.
• Matlab and C Template:Webarchive
• Perl implementation
• C++ implementation
• C++ implementation claiming ${\displaystyle O(n^3)}$ time complexity (BSD style open source licensed)
• MATLAB implementation
• C implementation
• JavaScript implementation with unit tests (port of a Java version claiming ${\displaystyle O(n^3)}$ time complexity)
• Clue R package proposes an implementation, solve_LSAP
• Node.js implementation on GitHub
• Python implementation in scipy package

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