The Floyd-Warshall algorithm, named after its creators Robert Floyd and Stephen Warshall, is fundamental in computer science and graph theory. It is used to find the shortest paths between all pairs of nodes in a weighted graph. This algorithm is highly efficient and can handle graphs with both positive and negative edge weights, making it a versatile tool for solving a wide range of network and connectivity problems.
The Floyd Warshall Algorithm is an all-pair shortest path algorithm, unlike Dijkstra and Bellman-Ford which are single source shortest path algorithms. This algorithm works for both the directed and undirected weighted graphs. However, it does not work for the graphs with negative cycles (where the sum of the edges in a cycle is negative). It follows the Dynamic Programming approach to check every possible path going via every possible node to calculate the shortest distance between every pair of nodes.
Floyd-Warshall Algorithm in Python:
- Initialize the solution matrix the same as the input graph matrix as a first step.
- Then update the solution matrix by considering all vertices as an intermediate vertex.
- The idea is to pick all vertices one by one and update all shortest paths which include the picked vertex as an intermediate vertex in the shortest path.
- When we pick vertex number k as an intermediate vertex, we already have considered vertices {0, 1, 2, .. k-1} as intermediate vertices.
- For every pair (i, j) of the source and destination vertices respectively, there are two possible cases.
- k is not an intermediate vertex in the shortest path from i to j. We keep the value of dist[i][j] as it is.
- k is an intermediate vertex in the shortest path from i to j. We update the value of dist[i][j] as dist[i][k] + dist[k][j], if dist[i][j] > dist[i][k] + dist[k][j]
# Python3 Program for Floyd Warshall Algorithm
# Number of vertices in the graph
V = 4
# Define infinity as the large
# enough value. This value will be
# used for vertices not connected to each other
INF = 99999
# Solves all pair shortest path
# via Floyd Warshall Algorithm
def floydWarshall(graph):
""" dist[][] will be the output
matrix that will finally
have the shortest distances
between every pair of vertices """
""" initializing the solution matrix
same as input graph matrix
OR we can say that the initial
values of shortest distances
are based on shortest paths considering no
intermediate vertices """
dist = list(map(lambda i: list(map(lambda j: j, i)), graph))
""" Add all vertices one by one
to the set of intermediate
vertices.
---> Before start of an iteration,
we have shortest distances
between all pairs of vertices
such that the shortest
distances consider only the
vertices in the set
{0, 1, 2, .. k-1} as intermediate vertices.
----> After the end of a
iteration, vertex no. k is
added to the set of intermediate
vertices and the
set becomes {0, 1, 2, .. k}
"""
for k in range(V):
# pick all vertices as source one by one
for i in range(V):
# Pick all vertices as destination for the
# above picked source
for j in range(V):
# If vertex k is on the shortest path from
# i to j, then update the value of dist[i][j]
dist[i][j] = min(dist[i][j],
dist[i][k] + dist[k][j]
)
printSolution(dist)
# A utility function to print the solution
def printSolution(dist):
print("Following matrix shows the shortest distances\
between every pair of vertices")
for i in range(V):
for j in range(V):
if(dist[i][j] == INF):
print("%7s" % ("INF"), end=" ")
else:
print("%7d\t" % (dist[i][j]), end=' ')
if j == V-1:
print()
# Driver's code
if __name__ == "__main__":
"""
10
(0)------->(3)
| /|\
5 | |
| | 1
\|/ |
(1)------->(2)
3 """
graph = [[0, 5, INF, 10],
[INF, 0, 3, INF],
[INF, INF, 0, 1],
[INF, INF, INF, 0]
]
# Function call
floydWarshall(graph)
Output
Following matrix shows the shortest distances between every pair of vertices
0 5 8 9
INF 0 3 4
INF INF 0 1
INF INF...Complexity Analysis of Floyd Warshall Algorithm:
- Time Complexity: O(V3), where V is the number of vertices in the graph and we run three nested loops each of size V
- Auxiliary Space: O(V2), to create a 2-D matrix in order to store the shortest distance for each pair of nodes.