Tarjan's strongly connected components algorithm
Tarjan's algorithm is an algorithm in graph theory for finding the strongly connected components of a directed graph. It runs in linear time, matching the time bound for alternative methods including Kosaraju's algorithm and the path-based strong component algorithm. Tarjan's algorithm is named for its inventor, Robert Tarjan.
Overview
The algorithm takes a directed graph as input, and produces a partition of the graph's vertices into the graph's strongly connected components. Each vertex of the graph appears in exactly one of the strongly connected components. Any vertex that is not on a directed cycle forms a strongly connected component all by itself: for example, a vertex whose in-degree or out-degree is 0, or any vertex of an acyclic graph.The basic idea of the algorithm is this: a depth-first search begins from an arbitrary start node. As usual with depth-first search, the search visits every node of the graph exactly once, declining to revisit any node that has already been visited. Thus, the collection of search trees is a spanning forest of the graph. The strongly connected components will be recovered as certain subtrees of this forest. The roots of these subtrees are called the "roots" of the strongly connected components. Any node of a strongly connected component might serve as a root, if it happens to be the first node of a component that is discovered by search.
Stack invariant
Nodes are placed on a stack in the order in which they are visited. When the depth-first search recursively visits a nodev
and its descendants, those nodes are not all necessarily popped from the stack when this recursive call returns. The crucial invariant property is that a node remains on the stack after it has been visited if and only if there exists a path in the input graph from it to some node earlier on the stack. In other words it means that in the DFS a node would be only removed from the stack after all its connected paths have been traversed. When the DFS will backtrack it would remove the nodes on a single path and return back to the root in order to start a new path.At the end of the call that visits
v
and its descendants, we know whether v
itself has a path to any node earlier on the stack. If so, the call returns, leaving v
on the stack to preserve the invariant. If not, then v
must be the root of its strongly connected component, which consists of v
together with any nodes later on the stack than v
. The connected component rooted at v
is then popped from the stack and returned, again preserving the invariant.Bookkeeping
Each nodev
is assigned a unique integer v.index
, which numbers the nodes consecutively in the order in which they are discovered. It also maintains a value v.lowlink
that represents the smallest index of any node known to be reachable from v
through v
's DFS subtree, including v
itself. Therefore v
must be left on the stack if v.lowlink < v.index
, whereas v must be removed as the root of a strongly connected component if v.lowlink v.index
. The value v.lowlink
is computed during the depth-first search from v
, as this finds the nodes that are reachable from v
.The algorithm in pseudocode
algorithm tarjan isinput: graph G =
output: set of strongly connected components
index := 0
S := empty stack
for each v in V do
if v.index is undefined then
strongconnect
end if
end for
function strongconnect
// Set the depth index for v to the smallest unused index
v.index := index
v.lowlink := index
index := index + 1
S.push
v.onStack := true
// Consider successors of v
for each in E do
if w.index is undefined then
// Successor w has not yet been visited; recurse on it
strongconnect
v.lowlink := min
else if w.onStack then
// Successor w is in stack S and hence in the current SCC
// If w is not on stack, then is an edge pointing to an SCC already found and must be ignored
// Note: The next line may look odd - but is correct.
// It says w.index not w.lowlink; that is deliberate and from the original paper
v.lowlink := min
end if
end for
// If v is a root node, pop the stack and generate an SCC
if v.lowlink = v.index then
start a new strongly connected component
repeat
w := S.pop
w.onStack := false
add w to current strongly connected component
while w ≠ v
output the current strongly connected component
end if
end function
The
index
variable is the depth-first search node number counter. S
is the node stack, which starts out empty and stores the history of nodes explored but not yet committed to a strongly connected component. Note that this is not the normal depth-first search stack, as nodes are not popped as the search returns up the tree; they are only popped when an entire strongly connected component has been found.The outermost loop searches each node that has not yet been visited, ensuring that nodes which are not reachable from the first node are still eventually traversed. The function
strongconnect
performs a single depth-first search of the graph, finding all successors from the node v
, and reporting all strongly connected components of that subgraph.When each node finishes recursing, if its lowlink is still set to its index, then it is the root node of a strongly connected component, formed by all of the nodes above it on the stack. The algorithm pops the stack up to and including the current node, and presents all of these nodes as a strongly connected component.
Note that
v.lowlink := min is the correct way to update
v.lowlink if
w is on stack. Because
w is on the stack already,
is a back-edge in the DFS tree and therefore
w is not in the subtree of
v. Because
v.lowlink takes into account nodes reachable only through the nodes in the subtree of
v we must stop at
w and use
w.index instead of
w.lowlink''.Complexity
Time Complexity: The Tarjan procedure is called once for each node; the forall statement considers each edge at most once. The algorithm's running time is therefore linear in the number of edges and nodes in G, i.e..In order to achieve this complexity, the test for whether
w
is on the stack should be done in constant time.This may be done, for example, by storing a flag on each node that indicates whether it is on the stack, and performing this test by examining the flag.
Space Complexity: The Tarjan procedure requires two words of supplementary data per vertex for the
index
and lowlink
fields, along with one bit for onStack
and another for determining when index
is undefined. In addition, one word is required on each stack frame to hold v
and another for the current position in the edge list. Finally, the worst-case size of the stack S
must be . This gives a final analysis of where is the machine word size. The variation of Nuutila and Soisalon-Soininen reduced this to and, subsequently, that of Pearce requires only.Additional remarks
While there is nothing special about the order of the nodes within each strongly connected component, one useful property of the algorithm is that no strongly connected component will be identified before any of its successors. Therefore, the order in which the strongly connected components are identified constitutes a reverse topological sort of the DAG formed by the strongly connected components.Donald Knuth described Tarjan's algorithm as one of his favorite implementations in the book The Stanford GraphBase.
He also wrote: