5.4 KiB
| title | description | tags | ||||
|---|---|---|---|---|---|---|
| Iterative algorithms via iterators | Iterative DFS using iterators. |
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Introduction
As we have talked on the seminar, iterative approach to implementing DFS is not very intuitive and is a very easy way how to create an incorrect implementation.
On the other hand, we have seen iterative implementation in the exercises and I have also prepared two from which one was similar to recursive implementation without colors from exercises and the other one used features of high-level languages.
Different implementations
Recursive DFS implementation from exercises without colors
FUNCTION VisitedDFS(u, Visited) IS
Visited <- Union(Visited, { u })
FOR v IN u.successors DO
IF v NOT IN Visited THEN
Visited <- VisitedDFS(v, Visited)
FI
OD
RETURN Visited
END
This implementation is correct, does the DFS traversal as it should, however it has one „smallish“ downside and that is the time complexity. The usage of set raises the time complexity, of course it is implementation dependant. However in case of either RB-tree or hash-table implementation, we get look-up in time \mathcal{O}(n) for hash-table in worst-case or \mathcal{O}(\log n) for the other in the worst-case. Both are not ideal compared to checking color on vertex.
Iterative DFS from the exercises
PROCEDURE IterDFS(u)
stack <- empty stack
Push(stack, (u, 0))
u.color <- gray
time <- 1
u.d <- time
WHILE NOT Empty(stack) DO
(u, k) <- Pop(stack)
IF k < Length(u.successors) THEN
// search is not finished, is pushed back to stack
Push(stack, (u, k + 1))
v <- u.successors[k + 1]
IF v.color = white THEN
Push(stack, (v, 0))
v.color <- gray
time <- time + 1
v.d <- time
FI
ELSE
// u has no other successors, we can finish the search
time <- time + 1
u.f <- time
u.color <- black
FI
OD
END
As we can see, there is some ordering in which we search through the successors. Time complexity is OK, stack holds at most all vertices (they must be on the current path).
My iterative with path in stack
PROCEDURE DFS(G, start) IS
path <- [ start ]
time <- 1
start.d, start.color <- time, gray
WHILE NOT Empty(path) DO
hasSuccessor <- false
FOR successor IN path[-1].successors DO
IF successor.color = white THEN
hasSuccessor <- true
successor.d, successor.color <- ++time, gray
path <- Append(path, successor)
BREAK
FI
OD
IF NOT hasSuccessor THEN
lastVertex <- Pop(path)
lastVertex.f, lastVertex.color <- ++time, black
FI
OD
END
This approach is similar to the iterative solution from the exercises, but it does not keep the index of the next successor, therefore it always iterates through all of them, which raises the time complexity.
My iterative solution with iterators
On the other hand, we do not actually have to depend on the representation of the graph. In this case, we just somehow obtain the iterator (which yields all of the succesors) and keep it in the stack.
PROCEDURE DFS(G, start) IS
path <- [ (start, Iterator(start.successors)) ]
time <- 1
start.d, start.color <- time, gray
WHILE NOT Empty(path) DO
lastVertex, successors <- path[-1]
IF NOT MoveNext(successors) THEN
Pop(path)
lastVertex.f, lastVertex.color <- ++time, black
ELSE IF successors.Current.color = white THEN
nextVertex <- successors.Current
nextVertex.d, nextVertex.color <- ++time, gray
path <- Append(path, (nextVertex, Iterator(nextVertex.successors)))
FI
OD
END
( The way we manipulate with the iterators is closest to the C# implementation. Apart from the Iterator thing :) In case you tried to implement it in C++, you would more than likely need to change the check, since you would get first successor right at the beginning )
So here we don't keep indices, but the iterators. We can also check existence of other successors easily: by the iterator moving after the last successor.
Closer explanation of the iterator shenanigans follows. In the beginning, either start or when pushing new vertex, we are pushing an iterator that points just before the first successor. When populating lastVertex and successors in the while-loop, we take the element from the top of the stack. MoveNext returns true if there is an element, i.e. successor in this case. If it returns false we have nothing to do and we pop the vertex from the stack (also set finishing time and color). If we have successor we check if it has been already visited or not. If has not, we set discovery time and color accordingly, also we add it to stack.
Implementation
In case you want to play around with the code. At the beginning there is a link to the C# implementation that can be used. It has a basic representation of graph and includes BFS/DFS implementation in classes.
In Program.cs you can also find a method that returns graph we used on the seminar.