Python/graphs/tarjans_scc.py

from collections import deque


def tarjan(g):
    """
    Tarjan's algo for finding strongly connected components in a directed graph

    Uses two main attributes of each node to track reachability, the index of that node
    within a component(index), and the lowest index reachable from that node(lowlink).

    We then perform a dfs of the each component making sure to update these parameters
    for each node and saving the nodes we visit on the way.

    If ever we find that the lowest reachable node from a current node is equal to the
    index of the current node then it must be the root of a strongly connected
    component and so we save it and it's equireachable vertices as a strongly
    connected component.

    Complexity: strong_connect() is called at most once for each node and has a
    complexity of O(|E|) as it is DFS.
    Therefore this has complexity O(|V| + |E|) for a graph G = (V, E)
    """

    n = len(g)
    stack = deque()
    on_stack = [False for _ in range(n)]
    index_of = [-1 for _ in range(n)]
    lowlink_of = index_of[:]

    def strong_connect(v, index, components):
        index_of[v] = index  # the number when this node is seen
        lowlink_of[v] = index  # lowest rank node reachable from here
        index += 1
        stack.append(v)
        on_stack[v] = True

        for w in g[v]:
            if index_of[w] == -1:
                index = strong_connect(w, index, components)
                lowlink_of[v] = (
                    lowlink_of[w] if lowlink_of[w] < lowlink_of[v] else lowlink_of[v]
                )
            elif on_stack[w]:
                lowlink_of[v] = (
                    lowlink_of[w] if lowlink_of[w] < lowlink_of[v] else lowlink_of[v]
                )

        if lowlink_of[v] == index_of[v]:
            component = []
            w = stack.pop()
            on_stack[w] = False
            component.append(w)
            while w != v:
                w = stack.pop()
                on_stack[w] = False
                component.append(w)
            components.append(component)
        return index

    components = []
    for v in range(n):
        if index_of[v] == -1:
            strong_connect(v, 0, components)

    return components


def create_graph(n, edges):
    g = [[] for _ in range(n)]
    for u, v in edges:
        g[u].append(v)
    return g


if __name__ == "__main__":
    # Test
    n_vertices = 7
    source = [0, 0, 1, 2, 3, 3, 4, 4, 6]
    target = [1, 3, 2, 0, 1, 4, 5, 6, 5]
    edges = list(zip(source, target))
    g = create_graph(n_vertices, edges)

    assert [[5], [6], [4], [3, 2, 1, 0]] == tarjan(g)
increment 1 2018-10-19 12:48:28 +00:00			`from collections import deque`


			`def tarjan(g):`
			`"""`
			`Tarjan's algo for finding strongly connected components in a directed graph`

Set the Python file maximum line length to 88 characters (#2122) * flake8 --max-line-length=88 * fixup! Format Python code with psf/black push Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> 2020-06-16 08:09:19 +00:00			`Uses two main attributes of each node to track reachability, the index of that node`
			`within a component(index), and the lowest index reachable from that node(lowlink).`
increment 1 2018-10-19 12:48:28 +00:00
Set the Python file maximum line length to 88 characters (#2122) * flake8 --max-line-length=88 * fixup! Format Python code with psf/black push Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> 2020-06-16 08:09:19 +00:00			`We then perform a dfs of the each component making sure to update these parameters`
			`for each node and saving the nodes we visit on the way.`
increment 1 2018-10-19 12:48:28 +00:00
Set the Python file maximum line length to 88 characters (#2122) * flake8 --max-line-length=88 * fixup! Format Python code with psf/black push Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> 2020-06-16 08:09:19 +00:00			`If ever we find that the lowest reachable node from a current node is equal to the`
			`index of the current node then it must be the root of a strongly connected`
			`component and so we save it and it's equireachable vertices as a strongly`
increment 1 2018-10-19 12:48:28 +00:00			`connected component.`

Set the Python file maximum line length to 88 characters (#2122) * flake8 --max-line-length=88 * fixup! Format Python code with psf/black push Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> 2020-06-16 08:09:19 +00:00			`Complexity: strong_connect() is called at most once for each node and has a`
			`complexity of O(\|E\|) as it is DFS.`
increment 1 2018-10-19 12:48:28 +00:00			`Therefore this has complexity O(\|V\| + \|E\|) for a graph G = (V, E)`
			`"""`

			`n = len(g)`
			`stack = deque()`
			`on_stack = [False for _ in range(n)]`
			`index_of = [-1 for _ in range(n)]`
			`lowlink_of = index_of[:]`

			`def strong_connect(v, index, components):`
			`index_of[v] = index # the number when this node is seen`
			`lowlink_of[v] = index # lowest rank node reachable from here`
			`index += 1`
			`stack.append(v)`
			`on_stack[v] = True`

			`for w in g[v]:`
			`if index_of[w] == -1:`
			`index = strong_connect(w, index, components)`
psf/black code formatting (#1277) 2019-10-05 05:14:13 +00:00			`lowlink_of[v] = (`
			`lowlink_of[w] if lowlink_of[w] < lowlink_of[v] else lowlink_of[v]`
			`)`
increment 1 2018-10-19 12:48:28 +00:00			`elif on_stack[w]:`
psf/black code formatting (#1277) 2019-10-05 05:14:13 +00:00			`lowlink_of[v] = (`
			`lowlink_of[w] if lowlink_of[w] < lowlink_of[v] else lowlink_of[v]`
			`)`
increment 1 2018-10-19 12:48:28 +00:00
			`if lowlink_of[v] == index_of[v]:`
			`component = []`
			`w = stack.pop()`
			`on_stack[w] = False`
			`component.append(w)`
			`while w != v:`
			`w = stack.pop()`
			`on_stack[w] = False`
			`component.append(w)`
			`components.append(component)`
			`return index`

			`components = []`
			`for v in range(n):`
			`if index_of[v] == -1:`
			`strong_connect(v, 0, components)`

			`return components`


			`def create_graph(n, edges):`
			`g = [[] for _ in range(n)]`
			`for u, v in edges:`
			`g[u].append(v)`
			`return g`


psf/black code formatting (#1277) 2019-10-05 05:14:13 +00:00			`if __name__ == "__main__":`
increment 1 2018-10-19 12:48:28 +00:00			`# Test`
			`n_vertices = 7`
			`source = [0, 0, 1, 2, 3, 3, 4, 4, 6]`
			`target = [1, 3, 2, 0, 1, 4, 5, 6, 5]`
Delete empty junk file (#9062) * updating DIRECTORY.md * updating DIRECTORY.md * Delete empty junk file * updating DIRECTORY.md * Fix ruff errors * Fix more ruff errors --------- Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com> 2023-09-16 22:12:31 +00:00			`edges = list(zip(source, target))`
increment 1 2018-10-19 12:48:28 +00:00			`g = create_graph(n_vertices, edges)`

			`assert [[5], [6], [4], [3, 2, 1, 0]] == tarjan(g)`