# Bellman-ford algorithm for negative cycles explanation

I tried to implement BF algorithm for negative cycle detection.

I followed the lecture notes to implement algorithm. My solution was the following:

``````def belman_ford(s, adj, cost):
dist_arr = [MAX_VAL]*arr_len
prev_arr = [None]*arr_len
dist_arr[s] = 0

for u in range(arr_len):
if dist_arr[v] == MAX_VAL:
break
if dist_arr[v] > dist_arr[u] + cost[u][i]:
dist_arr[v] = dist_arr[u] + cost[u][i]
prev_arr[v] = u

#detect negative cycle
for u in range(arr_len):
if dist_arr[v] == MAX_VAL:
break
if dist_arr[v] < dist_arr[u] + cost[u][i]:
return 1

return 0

``````

However I found another solution that helped me to pass coding challenge.

``````def negative_cycle(adj, cost):
distance[0] = 0
if distance[v] > distance[u] + cost[u][v_index]:
distance[v] = distance[u] + cost[u][v_index]
return 1
return 0
``````

I can't understand the logic behind it. Why actually this `if ind==len(adj) - 1` if statement leads to the cycle detection

As an input I get the adjacency and cost list

For the basic idea of Bellman-Ford algorithm, here's some quick review from Wikipedia:

the Bellman–Ford algorithm simply relaxes all the edges, and does this `|V|-1` times, where `|V|` is the number of vertices in the graph.

Then the explanation for your line `if ind==len(adj) - 1` is

Since the longest possible path without a cycle can be `|V|-1` edges, the edges must be scanned `|V|-1` times to ensure the shortest path has been found for all nodes.

A final scan of all the edges is performed and if any distance is updated, then a path of length `|V|` edges has been found which can only occur if at least one negative cycle exists in the graph.

Bellman-Ford assumes that distances are very large (infinity) at first, then gradually brings them down to the lowest possible. This is called relaxation. In each iteration, the edges one step farther from the source get relaxed.

`S --> A --> B --> C --> D --> E --> F --> G --> H --> I`

Now say you have a graph with no negative cycles. Say it has 10 vertices, you need no more than 9 relaxations to reach (get the shortest path of) the farthest vertex from the source. What if after 9 relaxations you still get improvement? You must have negative cycles in your graph.

The `ind` in your code is a counter. When `ind == len(adj) - 1` it means you have relaxed distances for `|V|` times, which tells the existence of negative cycle(s).

Also check out the third page from last in your own note.

• Thanks for clarification. I think I got your idea. I was a bit confused why they missed the step of checking for negative-weight cycles, as it described here for example geeksforgeeks.org/detect-negative-cycle-graph-bellman-ford – Daniel Chepenko Dec 28 '18 at 7:05
• @DanielChepenko It's not skipped compared with the one in your link. They are the same. In the version in your link, the relaxation first runs for `V - 1` times, then a last time. If you merge that last time with the first `V - 1` times, it's the code in your question. – aafulei Dec 28 '18 at 7:42
• As a bouns, there're some extra early-abandon tricks in implementing Bellman-Ford algorithm. Say whenever you found the shortest distance from source to itself, i.e. `distance[0]`, becomes bizarrely negative, you could stop and conclude you find a negative cycle. In this way, you may not even need to wait for `|V|` scans. – aafulei Dec 28 '18 at 7:50
• Thanks, by the way I noticed that in this implementation they initiate distance with 0 at the first step. Any reason to do that instead of initialising with infinity large values? – Daniel Chepenko Dec 28 '18 at 14:13
• @DanielChepenko Just noticed that line (`distance=[0]*len(adj)`). Weird. Could you please double check that this line is in the code that passes the test cases? If so, what's point of again setting `distance[0] = 0`? – aafulei Dec 28 '18 at 14:55