# How to traverse cyclic directed graphs with modified DFS algorithm

OVERVIEW

I'm trying to figure out how to traverse directed cyclic graphs using some sort of DFS iterative algorithm. Here's a little mcve version of what I currently got implemented (it doesn't deal with cycles):

``````class Node(object):

def __init__(self, name):
self.name = name

def start(self):
print '{}_start'.format(self)

def middle(self):
print '{}_middle'.format(self)

def end(self):
print '{}_end'.format(self)

def __str__(self):
return "{0}".format(self.name)

class NodeRepeat(Node):

def __init__(self, name, num_repeats=1):
super(NodeRepeat, self).__init__(name)
self.num_repeats = num_repeats

def dfs(graph, start):
"""Traverse graph from start node using DFS with reversed childs"""

visited = {}
stack = [(start, "")]
while stack:
# To convert dfs -> bfs
# a) rename stack to queue
# b) pop becomes pop(0)
node, parent = stack.pop()
if parent is None:
if visited[node] < 3:
node.end()
visited[node] = 3
elif node not in visited:
if visited.get(parent) == 2:
parent.middle()
elif visited.get(parent) == 1:
visited[parent] = 2

node.start()
visited[node] = 1

stack.append((node, None))

# Maybe you want a different order, if it's so, don't use reversed
childs = reversed(graph.get(node, []))
for child in childs:
if child not in visited:
stack.append((child, node))

if __name__ == "__main__":
Sequence1 = Node('Sequence1')
MtxPushPop1 = Node('MtxPushPop1')
Rotate1 = Node('Rotate1')
Repeat1 = NodeRepeat('Repeat1', num_repeats=2)

Sequence2 = Node('Sequence2')
MtxPushPop2 = Node('MtxPushPop2')
Translate = Node('Translate')
Rotate2 = Node('Rotate2')
Rotate3 = Node('Rotate3')
Scale = Node('Scale')
Repeat2 = NodeRepeat('Repeat2', num_repeats=3)
Mesh = Node('Mesh')

cyclic_graph = {
Sequence1: [MtxPushPop1, Rotate1],
MtxPushPop1: [Sequence2],
Rotate1: [Repeat1],
Sequence2: [MtxPushPop2, Translate],
Repeat1: [Sequence1],
MtxPushPop2: [Rotate2],
Translate: [Rotate3],
Rotate2: [Scale],
Rotate3: [Repeat2],
Scale: [Mesh],
Repeat2: [Sequence2]
}

dfs(cyclic_graph, Sequence1)

print '-'*80

a = Node('a')
b = Node('b')
dfs({
a : [b],
b : [a]
}, a)
``````

The above code is testing a couple of cases, the first would be some sort of representation of the below graph: The second one is the simplest case of one graph containing one "infinite" loop `{a->b, b->a}`

REQUIREMENTS

• There won't exist such a thing like "infinite cycles", let's say when one "infinite cycle" is found, there will be a maximum threshold (global var) to indicate when to stop looping around those "pseudo-infinite cycles"
• All graph nodes are able to create cycles but there will exist a special node called `Repeat` where you can indicate how many iterations to loop around the cycle
• The above mcve I've posted is an iterative version of the traversal algorithm which doesn't know how to deal with cyclic graphs. Ideally the solution would be also iterative but if there exists a much better recursive solution, that'd be great
• The data structure we're talking about here shouldn't be called "directed acyclic graphs" really because in this case, each node has its children ordered, and in graphs node connections have no order.
• Everything can be connected to anything in the editor. You'll be able to execute any block combination and the only limitation is the execution counter, which will overflow if you made neverending loop or too many iterations.
• The algorithm will preserve start/middle/after node's method execution similarly than the above snippet

QUESTION

Could anyone provide some sort of solution which knows how to traverse infinite/finite cycles?

REFERENCES

If question is not clear yet at this point, you can read this more about this problem on this article, the whole idea will be using the traversal algorithm to implement a similar tool like the shown in that article.

Here's a screenshot showing up the whole power of this type of data structure I want to figure out how to traverse&run: • That a rendering engine you're working on? Looks quite good. Sep 12, 2016 at 15:51
• @EvilTak Agree, that's awesome! That rendering engine is not mine at all, I intend to create a similar tool to the ones I've referenced in my post! Here you can take a look to some of the amazing prods the author of such tool has been able to create. Of course, be aware of the size of those executables, no more than 4kb and 8kb, have fun ;-)
– BPL
Sep 12, 2016 at 15:56
• So if I'm understanding your problem correctly, you're trying to create an algorithm that searches for something in a directed cyclic graph, using a depth-first algorithm. You would also prefer an iterative solution over a recursive one. Is that correct? Sep 12, 2016 at 16:37
• What is the expected output for the first example you have given? Please just show the order of visiting the nodes, with the desired repeats. Sep 12, 2016 at 16:53
• Do you just want to visit every node, or is the order in which order the nodes are visited? For example why would bfs not work for you?
Sep 12, 2016 at 19:02

Before I start, Run the code on CodeSkulptor! I also hope that the comments elaborate what I have done enough. If you need more explanation, look at my explanation of the recursive approach below the code.

``````# If you don't want global variables, remove the indentation procedures
indent = -1

MAX_THRESHOLD = 10
INF = 1 << 63

def whitespace():
global indent
return '|  ' * (indent)

class Node:
def __init__(self, name, num_repeats=INF):
self.name = name
self.num_repeats = num_repeats

def start(self):
global indent
if self.name.find('Sequence') != -1:
print whitespace()
indent += 1
print whitespace() + '%s_start' % self.name

def middle(self):
print whitespace() + '%s_middle' % self.name

def end(self):
global indent
print whitespace() + '%s_end' % self.name
if self.name.find('Sequence') != -1:
indent -= 1
print whitespace()

def dfs(graph, start):
visits = {}
frontier = [] # The stack that keeps track of nodes to visit

# Whenever we "visit" a node, increase its visit count
frontier.append((start, start.num_repeats))
visits[start] = visits.get(start, 0) + 1

while frontier:
# parent_repeat_count usually contains vertex.repeat_count
# But, it may contain a higher value if a repeat node is its ancestor
vertex, parent_repeat_count = frontier.pop()

# Special case which signifies the end
if parent_repeat_count == -1:
vertex.end()
# We're done with this vertex, clear visits so that
# if any other node calls us, we're still able to be called
visits[vertex] = 0
continue

# Special case which signifies the middle
if parent_repeat_count == -2:
vertex.middle()
continue

# Send the start message
vertex.start()

# Add the node's end state to the stack first
# So that it is executed last
frontier.append((vertex, -1))

# No more children, continue
# Because of the above line, the end method will
# still be executed
if vertex not in graph:
continue

## Uncomment the following line if you want to go left to right neighbor
#### graph[vertex].reverse()

for i, neighbor in enumerate(graph[vertex]):
# The repeat count should propagate amongst neighbors
# That is if the parent had a higher repeat count, use that instead
repeat_count = max(1, parent_repeat_count)
if neighbor.num_repeats != INF:
repeat_count = neighbor.num_repeats

# We've gone through at least one neighbor node
# Append this vertex's middle state to the stack
if i >= 1:
frontier.append((vertex, -2))

# If we've not visited the neighbor more times than we have to, visit it
if visits.get(neighbor, 0) < MAX_THRESHOLD and visits.get(neighbor, 0) < repeat_count:
frontier.append((neighbor, repeat_count))
visits[neighbor] = visits.get(neighbor, 0) + 1

def dfs_rec(graph, node, parent_repeat_count=INF, visits={}):
visits[node] = visits.get(node, 0) + 1

node.start()

if node not in graph:
node.end()
return

for i, neighbor in enumerate(graph[node][::-1]):
repeat_count = max(1, parent_repeat_count)
if neighbor.num_repeats != INF:
repeat_count = neighbor.num_repeats

if i >= 1:
node.middle()

if visits.get(neighbor, 0) < MAX_THRESHOLD and visits.get(neighbor, 0) < repeat_count:
dfs_rec(graph, neighbor, repeat_count, visits)

node.end()
visits[node] = 0

Sequence1 = Node('Sequence1')
MtxPushPop1 = Node('MtxPushPop1')
Rotate1 = Node('Rotate1')
Repeat1 = Node('Repeat1', 2)

Sequence2 = Node('Sequence2')
MtxPushPop2 = Node('MtxPushPop2')
Translate = Node('Translate')
Rotate2 = Node('Rotate2')
Rotate3 = Node('Rotate3')
Scale = Node('Scale')
Repeat2 = Node('Repeat2', 3)
Mesh = Node('Mesh')

cyclic_graph = {
Sequence1: [MtxPushPop1, Rotate1],
MtxPushPop1: [Sequence2],
Rotate1: [Repeat1],
Sequence2: [MtxPushPop2, Translate],
Repeat1: [Sequence1],
MtxPushPop2: [Rotate2],
Translate: [Rotate3],
Rotate2: [Scale],
Rotate3: [Repeat2],
Scale: [Mesh],
Repeat2: [Sequence2]
}

dfs(cyclic_graph, Sequence1)

print '-'*40

dfs_rec(cyclic_graph, Sequence1)

print '-'*40

dfs({Sequence1: [Translate], Translate: [Sequence1]}, Sequence1)

print '-'*40

dfs_rec({Sequence1: [Translate], Translate: [Sequence1]}, Sequence1)
``````

The input and (well formatted and indented) output can be found here. If you want to see how I formatted the output, please refer to the code, which can also be found on CodeSkulptor.

Right, on to the explanation. The easier to understand but much more inefficient recursive solution, which I'll use to help explain, follows:

``````def dfs_rec(graph, node, parent_repeat_count=INF, visits={}):
visits[node] = visits.get(node, 0) + 1

node.start()

if node not in graph:
node.end()
return

for i, neighbor in enumerate(graph[node][::-1]):
repeat_count = max(1, parent_repeat_count)
if neighbor.num_repeats != INF:
repeat_count = neighbor.num_repeats

if i >= 1:
node.middle()

if visits.get(neighbor, 0) < MAX_THRESHOLD and visits.get(neighbor, 0) < repeat_count:
dfs_rec(graph, neighbor, repeat_count, visits)

node.end()
visits[node] = 0
``````
1. The first thing we do is visit the node. We do this by incrementing the number of visits of the node in the dictionary.
2. We then raise the `start` event of the node.
3. We do a simple check to see if the node is a childless (leaf) node or not. If it is, we raise the `end` event and return.
4. Now that we've established that the node has neighbors, we iterate through each neighbor. Side Note: I reverse the neighbor list (by using `graph[node][::-1]`) in the recursive version to maintain the same order (right to left) of traversal of neighbors as in the iterative version.
1. For each neighbor, we first calculate the repeat count. The repeat count propagates (is inherited) through from the ancestor nodes, so the inherited repeat count is used unless the neighbor contains a repeat count value.
2. We raise the `middle` event of the current node (not the neighbor) if the second (or greater) neighbor is being processed.
3. If the neighbor can be visited, the neighbor is visited. The visitability check is done by checking whether the neighbor has been visited less than a) `MAX_THRESHOLD` times (for pseudo-infinite cycles) and b) the above calculated repeat count times.
5. We're now done with this node; raise the `end` event and clear its visits in the hashtable. This is done so that if some other node calls it again, it does not fail the visitability check and/or execute for less than the required number of times.
• Could you please post the final version here in your answer instead CodeSkulptor? The one you pasted here is badly indented/formatted. And the one in CodeSkulptor isn't consider MAX_THRESHOLD so I don't know which one to evaluate. Btw, your version on CodeSkulptor is using global variables to deal with indentation and is not using the same classes I had used in my mcve (Node & NodeRepeat)
– BPL
Sep 13, 2016 at 0:11
• @BPL I can do that. Do you not want to use global variables? I mean, you won't be using that printing code in your editor, will you? Sep 13, 2016 at 2:56
• Printing/Debugging code is a little nice/cool extra, that's why I haven't mentioned it as a requirement. I always prefer to avoid global variables in my code. Debugging the node execution will be handy to add some node profiling. Btw, my first version of the editor will be using python code to render the scene graph but probably in future versions I'll be using a c++ player, the editor will be able to create executables directly (but that's out of the question here).
– BPL
Sep 13, 2016 at 9:45
• @BPL makes sense. I'd avoid global variables too. Have you checked out the latest edits? They seem to do what you want. Sep 13, 2016 at 9:55
• Yeah, I have checked them. The only minor details I find with your versions IMHO are the usage of this hacky line `frontier.append((start, start.num_repeats if isinstance(start, NodeRepeat) else 2 << 31))` and the usage of global variables. For the rest, your algorithm seem is meeting requirements but I'll need to check it out graphically once I got the first draft of my editor running. Btw, your answer is looking nice! I'm sure if you edit&clean a bit and add its counterpart recursive version will help you get some good ammount of upvotes, you deserve it for the effort.
– BPL
Sep 13, 2016 at 10:16

As per comment66244567 - reducing the graph to a tree by ignoring links to visited nodes and performing a breadth-first search, as this would produce a more natural-looking (and likely more balanced) tree:

``````def traverse(graph,node,process):
seen={node}
current_level=[node]
while current_level:
next_level=[]
for node in current_level:
process(node)
next_level.append(child)
current_level=next_level
``````

With your graph and `def process(node): print node`, this produces:

``````In : traverse(cyclic_graph,Sequence1,process)
Sequence1
MtxPushPop1
Rotate1
Sequence2
Repeat1
MtxPushPop2
Translate
Rotate2
Rotate3
Scale
Repeat2
Mesh
``````

The other BFS algorithm, iterative deepening DFS (uses less memory at the cost of speed) isn't going to win you anything in this case: since you have to store references to visited nodes, you already consume O(n) memory. Neither you need to produce intermediate results (but you can anyway - e.g. `yield` something after processing a level).

• Thanks for your answer! But I don't see how your version is sticking to the requirements. For instance, where are start/middle/end methods going to be executed?
– BPL
Sep 13, 2016 at 9:39
• The redefinition of `__hash__()` isn't required because that is the default definition. Sep 13, 2016 at 16:46
• @BPL they are supposed to be in `process()`. The question is about traversing the graph, and what you do with each node is irrelevant to that - so traversing is gonna be disjoint from processing and shall allow any processing rather than just what you gave as example. Writing the necessary `process()` is trivial, so I didn't clutter the answer with unnecessary details. Sep 13, 2016 at 22:29
• @ivan_pozdeev Alright, thanks for the answer in any case! Once I got the basics of my editor implemented this week I'll tweak & test your algorithm as well. Just let you know right now the best candidate for validation&bounties is Evil Tak's answer so far (in case you care about that :))
– BPL
Sep 13, 2016 at 22:39
• SO answers are also supposed to be useful for future readers, not just one person, and irrelevant details are detrimental for that goal. Sep 14, 2016 at 13:25