BFS finds shortest path in general unweighted graph - and also specifically in DAG [since it is also a graph]. It is also pretty simple to code it.

Note that DFS will find a path - but it doesn't have to be the shortest one.

You might also want to have a look at this post to see how to get the actual path from BFS after running it.

**EDIT:** according to your comments, it seems you want `O(|V|)`

solution, and it doesn't have to be shortest. a modification of DFS is the way to do then, since the DAG has a single source and a single sink, **every path from the source reaches the sink**.

Note that since your graph is a DAG and since we established that every path from the source reaches the sink, you don't need to go backward after exploring a certain path [so no recursion or stack is needed].

pseudo-code:

```
modifiedDFS(source,target):
map <- new map
current <- source
while (current != target):
next <- current.getNextVertex() //just chose an arbitrary edge and follow it, doesn't matter which
map.put(next,current) //we "discovered" next by following current
current <- next
```

after running this algorithm, you need to follow back the map from the target to the
source - and you get the actual path [reversed of course]

The complexity is indeed `O(n)`

because we visit each node at most once. In order to maintain `O(n)`

the map has to be a hashmap [and not a treemap]. If the vertices are enumerated - you can even implement the map as an array.