# graph algorithms: reachability from adjacency map

I have a dependency graph that I have represented as a Map<Node, Collection<Node>> (in Java-speak, or f(Node n) -> Collection[Node] as a function; this is a mapping from a given node n to a collection of nodes that depend on n). The graph is potentially cyclic*.

Given a list badlist of nodes, I would like to solve a reachability problem: i.e. generate a Map<Node, Set<Node>> badmap that represents a mapping from each node N in the list badlist to a set of nodes which includes N or other node that transitively depends on it.

Example:

(x -> y means node y depends on node x)
n1 -> n2
n2 -> n3
n3 -> n1
n3 -> n5
n4 -> n2
n4 -> n5
n6 -> n1
n7 -> n1


This can be represented as the adjacency map {n1: [n2], n2: [n3], n3: [n1, n5], n4: [n2, n5], n6: [n1], n7: [n1]}.

If badlist = [n4, n5, n1] then I expect to get badmap = {n4: [n4, n2, n3, n1, n5], n5: [n5], n1: [n1, n2, n3, n5]}.

I'm floundering with finding graph algorithm references online, so if anyone could point me at an efficient algorithm description for reachability, I'd appreciate it. (An example of something that is not helpful to me is http://www.cs.fit.edu/~wds/classes/cse5081/reach/reach.html since that algorithm is to determine whether a specific node A is reachable from a specific node B.)

*cyclic: if you're curious, it's because it represents C/C++ types, and structures can have members which are pointers to the structure in question.

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In Python:

def reachable(graph, badlist):
stack = [root]
visited = set()
while stack:
v = stack.pop()
if v in visited: continue
stack.extend(graph[v])

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ok, that's pretty simple. For some reason I got hung up on the fact that you have to re-execute the for root in badlist loop without benefit of the knowledge gained on previous executions of the loop. So maybe it's possible to optimize for speed... but what you have is pretty simple. –  Jason S Sep 1 '11 at 20:43
@Jason This is asymptotically optimal for graphs of bounded in-degree (i.e., number of different structure types referenced by a structure). I'd be surprised if the bottleneck weren't elsewhere. –  quaint Sep 1 '11 at 20:56
@Jason: If you want to optimize that algorithm for speed, put the mark bit in the vertex itself rather than looking it up in an external visited set. –  Jon Harrop Nov 7 '11 at 16:00

You maybe should build a reachability matrix from your adjacency list for fast searches. I just found the paper Course Notes for CS336: Graph Theory - Jayadev Misra which describes how to build the reachability matrix from a adjacency matrix.

If A is your adjacency matrix, the reachability matrix would be R = A + A² + ... + A^n where n is the number of nodes in the graph. A², A³, ... can be calculated by:

• A² = A x A
• A³ = A x A²
• ...

For the matrix multiplication the logical or is used in place of + and the logical and is used in place of x. The complexity is O(n^4).

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+1 for interestingness, but my badlist is a very small number of nodes compared to the total # of nodes in the graph (badlist typically has size 4-10, whereas total # of nodes is in the tens of thousands), so I'm not sure that's either efficient or easy to implement for my purposes. –  Jason S Sep 1 '11 at 21:31

here's what I ended up using, based on @quaint's answer:

(requires a few Guava classes for convenience)

static public <T> Set<T> findDependencies(
T rootNode,
Multimap<T, T> dependencyGraph)
{
Set<T> dependencies = Sets.newHashSet();
for (T node = rootNode; node != null; node = todo.poll())
{
if (dependencies.contains(node))
continue;
Collection<T> directDependencies =
dependencyGraph.get(node);
if (directDependencies != null)
}
return dependencies;
}
static public <T> Multimap<T,T> findDependencies(
Iterable<T> rootNodes,
Multimap<T, T> dependencyGraph)
{
Multimap<T, T> dependencies = HashMultimap.create();
for (T rootNode : rootNodes)
dependencies.putAll(rootNode,
findDependencies(rootNode, dependencyGraph));
return dependencies;
}
static public void testDependencyFinder()
{
Multimap<Integer, Integer> dependencyGraph =
HashMultimap.create();
dependencyGraph.put(1, 2);
dependencyGraph.put(2, 3);
dependencyGraph.put(3, 1);
dependencyGraph.put(3, 5);
dependencyGraph.put(4, 2);
dependencyGraph.put(4, 5);
dependencyGraph.put(6, 1);
dependencyGraph.put(7, 1);
Multimap<Integer, Integer> dependencies =
findDependencies(ImmutableList.of(4, 5, 1), dependencyGraph);
System.out.println(dependencies);
// prints {1=[1, 2, 3, 5], 4=[1, 2, 3, 4, 5], 5=[5]}
}

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Here's a working Java solution:

// build the example graph
Map<Node, Collection<Node>> graph = new HashMap<Node, Collection<Node>>();
graph.put(n1, Arrays.asList(new Node[] {n2}));
graph.put(n2, Arrays.asList(new Node[] {n3}));
graph.put(n3, Arrays.asList(new Node[] {n1, n5}));
graph.put(n4, Arrays.asList(new Node[] {n2, n5}));
graph.put(n5, Arrays.asList(new Node[] {}));
graph.put(n6, Arrays.asList(new Node[] {n1}));
graph.put(n7, Arrays.asList(new Node[] {n1}));

Node[] badlist = {n4, n5, n1};
Map<Node, Collection<Node>> badmap = new HashMap<Node, Collection<Node>>();

Stack<Node> toExplore = new Stack<Node>();
Collection<Node> reachable = new HashSet<Node>(toExplore);
while(toExplore.size() > 0) {
Node aNode = toExplore.pop();
for(Node n : graph.get(aNode)) {
if(! reachable.contains(n)) {
toExplore.push(n);
}
}
}