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Created October 16, 2011 08:24
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Strongly Connected Components algorithm implemented in Scala using ScalaZ
/*
This is implemented following the instructions in "The Design and Analysis of
Computer Algorithms, AHO Hopcroft Ullman, 1974".
The implementation uses a DFS to find the strongly connected components (SCCs)
of a graph. During the DFS the vertices are placed on a stack in the order
they are visited. Whenever a root is found, all vertices of the corresponding
SSC are on the top of the stack and are popped.
A root of a SCC is found by keeping track of the DFN (depth first number) and
LLN (lowlink number) of each vertex. When a vertex (v) is first encountered
it is marked as visited and LLN(v) is set to DFN(v). Each adjacent vertex (w)
is then considered.
- If w is unvisited recurse with w. set LLN(w) to the smallest of LLN(w)
& LLN(v).
- If w is visited AND w was visited before v AND w is on the stack then set
LLN(v) to the smallest of DFN(w) and LLN(v).
If, after all the adjacent vertexes have been considered, the LLN(v) is the
same as DFN(v) then v the root of the current SSC.
When there are no vertexes un-visited the algorithm is done.
@author Mads Hartmann Jensen.
*/
package dk.itu.sdg.javaparser
import scala.collection.immutable.{ HashMap }
object Graph {
import scalaz._
import Scalaz._
type Component = List[Vertex]
// Simple data structure for now.
case class Vertex(label: String)
case class Edge(from: Vertex, to: Vertex)
case class G(start: Vertex, vertices: List[Vertex], edges: List[Edge])
case class State(graph: G,
count: Int,
visited: Map[Vertex, Boolean],
dfNumber: Map[Vertex, Int],
lowlinks: Map[Vertex,Int],
stack: List[Vertex],
components: List[Component])
def initial(g: G) = State (
graph = g,
count = 1,
visited = g.vertices.map { (_,false) } toMap,
dfNumber = Map(),
lowlinks = Map(),
stack = Nil,
components = Nil
)
def components(g: G): List[Component] = {
def run: scalaz.State[State, State] = for {
next <- next
cont <- search(next)
st <- gets( (s: State) => s )
} yield if (cont) run ! st else st
(run ! (search(g.start) ~> initial(g))).components
}
def search(v: Vertex): scalaz.State[State, Boolean] = for {
_ <- visited(v)
_ <- push(v)
_ <- setDFNumber(v)
_ <- setLowlink(v)
_ <- incrementCounter
_ <- processAdjacents(v)
_ <- getComponents(v)
s <- gets ( (st: State) => st )
} yield s.visited.exists( _._2 == false)
def processAdjacents(v: Vertex) = for {
adjacents <- adjacent(v)
_ <- modify ( (st: State) => adjacents.foldLeft(st)( (s: State, w: Vertex) => processVertex(v,w,s) ) )
} yield Unit
def getComponents(v: Vertex) = for {
_ <- modify( (s: State) => {
if (s.lowlinks(v) == s.dfNumber(v)) {
val index = s.stack.indexOf(v)
val (comp,rest) = s.stack.splitAt( index + 1 )
s.copy ( stack = rest, components = s.components :+ comp)
} else s
})
} yield Unit
def processVertex(current: Vertex, adjacent: Vertex, st: State): State = (for {
visited <- isVisited(adjacent)
_ <- if (visited) wasVisited(current, adjacent) else wasntVisited(current, adjacent)
s <- gets ((sta: State) => sta)
} yield s) ~> st
def next = for { s <- gets ( (st: State) => st ) }
yield s.visited.find( _._2 == false ).map( _._1 ).get
def adjacent(v: Vertex) = for {
s <- gets ( (st: State) => st )
vertices = for { edge <- s.graph.edges if edge.from == v } yield edge.to
} yield vertices
def wasntVisited(current: Vertex, adjacent: Vertex) = for {
_ <- search(adjacent)
_ <- modify( (s: State) => {
val min = smallest( s.lowlinks(adjacent), s.lowlinks(current) )
s.copy( lowlinks = s.lowlinks.updated(current, min))
})
} yield Unit
def wasVisited(current: Vertex, adjacent: Vertex) = modify( (s: State) => {
if (s.dfNumber(adjacent) < s.dfNumber(current) && s.stack.contains(adjacent)) {
val min = smallest( s.dfNumber(adjacent), s.lowlinks(current) )
s.copy( lowlinks = s.lowlinks.updated(current, min))
} else s
})
def isVisited(w: Vertex) = for { s <- gets ( (st: State) => st ) } yield s.visited(w)
def visited(v: Vertex) = modify( (s: State) => s.copy( visited = s.visited.updated(v,true)))
def push(v: Vertex) = modify( (s: State) => s.copy( stack = v :: s.stack))
def setDFNumber(v: Vertex) = modify( (s: State) => s.copy( dfNumber = s.dfNumber.updated(v, s.count)) )
def setLowlink(v: Vertex) = modify( (s: State) => s.copy( lowlinks = s.lowlinks.updated(v, s.count)) )
def incrementCounter = modify( (s: State) => s.copy( count = s.count + 1 ))
def smallest(x: Int, y: Int): Int = if (x < y) x else y
/* Playground. */
def main(args: Array[String]): Unit = {
// Example taken from page 187, figure 5.13
val v1 = Vertex("V1")
val v2 = Vertex("V2")
val v3 = Vertex("V3")
val v4 = Vertex("V4")
val v5 = Vertex("V5")
val v6 = Vertex("V6")
val v7 = Vertex("V7")
val v8 = Vertex("V8")
val vertices = List(v1,v2,v3,v4,v5,v6,v7,v8)
val edges = List(
Edge(v1, v2),
Edge(v1, v5),
Edge(v1, v4),
Edge(v2, v3),
Edge(v2, v4),
Edge(v3, v1),
Edge(v4, v3),
Edge(v5, v4),
Edge(v6, v8),
Edge(v6, v7),
Edge(v7, v5),
Edge(v8, v4),
Edge(v8, v6),
Edge(v8, v7))
val g = G(v1, vertices, edges)
println("found components: " + components(g).mkString("\n","\n",""))
}
}
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