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# Need help figuring out performance bottleneck

I'm working on my scala chops and implemented a small graph Api to track vertices and edges added to graph. I have basic GraphLike Trait, and have an Undirected Graph class ( `UnDiGraph`) and a Directed graph class (`DiGraph` ) that extend the `GraphLike` trait. Here is some of the listing

``````trait GraphLike[T] {
val vertices: Map[T, VertexLike[T]]
def addEdge( a:T, b:T ): GraphLike[T]
def addVertex( vert: VertexLike[T] ): GraphLike[T]
def adjacency( t:T ): Option[ List[T] ]  =
{
if ( vertices contains t )
else
None
}
def vertNum: Integer = vertices size
def edgeNum: Integer =
{
def summer( sum: Integer, ms: Map[T, VertexLike[T] ] ): Integer =
{
if ( ms.isEmpty )
sum
else
}
summer( 0, vertices )
}
def getVertex( t: T ): VertexLike[T] =
{
vertices( t )
}
def edgeExists( a:T, b:T ): Boolean =
{
try
{
if( vertices( a ).adjList contains b )
true
else
false
}catch {
case ex: NoSuchElementException => false
}
}
}
``````

Heres what the Directe Graph Looks like.

``````class DiGraph[T](val vertices: Map[ T, VertexLike[ T ] ] = Map.empty ) extends GraphLike[T] {
def makeVertex( t:T ): VertexLike[T] = new Vertex( t )

def addEdge( a:T, b:T ): GraphLike[T] =
{
//Make sure vertices exist
if( edgeExists(a, b) )
this
else {
try {
vertices(b)
vertices(a)
} catch {
}
addVertex( vertices( a ) + b )
}
}
def addVertex( t:T ): DiGraph[T] =
{
if( vertices contains t ) this
else
new DiGraph[T]( vertices + ( t -> makeVertex(t) ) )
}
def addVertex( vert: VertexLike[T] ): DiGraph[T] =
{
new DiGraph[T]( vertices + ( vert.apply -> vert ) )
}
}
``````

Vertices are stored in a Map going from type T to VertexLike[T]. Vertex Like basically holds an adjacency list for the specific Vertex. Heres what VertexLike looks like:

``````trait VertexLike[T]
{
def addEdgeTo( dest: T ): VertexLike[T]
def +( dest: T) = addEdgeTo(dest)
def apply: T
}

class Vertex[T](t: T, adj: List[T] = List() ) extends VertexLike[T]
{
def apply() = t
def addEdgeTo( dest: T ) =
this
else
new Vertex[T]( t, dest :: adjList )
}
``````

( Yes... i realize the apply method in the class is useless and it only works on objects. Realized that a little later ).

Anyways, I have a sample graph where I have about 80,000 vertices. Adding the vertices to the Graph is taking just way too long. I tried to do things functionally and in an immutable way. Whenever you add a vertex or an edge to a graph, you get a new graph ( I tried to make sure the constuctors of the graph types weren't doing much ). This is the client code that I use to create my graph from my data.

``````def GraphInstantiater: GraphLike[Int] =
{
println( "Total number of Vertices: " + synMap.keys.size )
def vertexAdder( ls: Iterable[Int], graph:GraphLike[Int] ): GraphLike[Int] =

val gr = vertexAdder( synMap.keys, new DiGraph[Int]( Map() ) )
println( "Vertices added. Total: %d".format( gr.vertices.size ) )
gr
}
``````

I know constructing new graphs will take cycles but is it really all that great given that I'm not doing much in the constructors. Would repeatedly creating the Map of vertices keep causing problems ( its one of the parameters of the graph class ). Any ideas on what the bottlenecks are in this method would be much appreciated. Also if you need any additional information, please let me know.

-
If all the elements of your graph are immutable forever, and you create a new graph by adding/updating/removing a node, then you can make a new graph by 1) creating ONLY the new nodes that were effected by the change 2) otherwise having everything be references to the original graph. Similar concept to copy-on-write semantics – Patashu May 3 '13 at 4:11
He's already doing exactly that (he's using immutable maps which do share their common elements by reference) – Régis Jean-Gilles May 3 '13 at 6:12
Should this be posted in codereview.stackexchange.com ? – Dahdahm May 3 '13 at 13:16
I was not aware about codereview... I will post there... thanks... – Kartik Aiyer May 4 '13 at 16:48

As a complement to you answer: you indeed inadvertently traverse the whole `synMap.keys` every time you call `ls.tail`.

What happens is:

• `Map.key` returns the value of `Map.keySet`, which is a custom immutable `Set`.
• that `Set` overrides a few things, but leaves `tail` and `drop` to their default implementation. Its `tail` implementation (from `TraversableLike`) just calls `drop`.
• And that's where everything falls apart: it gets its implementation of `drop` from `IterableLike`, and that only does what you can do with an `Iterable`: iterate. So a new builder is created, the head of the iterator is dropped, then the iterator is added to the builder, which traverses all your keys, and a new collection (the tail) is returned.

You can probably avoid the conversion to a list altogether by using an iterator, with something like:

``````def vertexAdder( ls: Iterator[Int], graph:GraphLike[Int] ): GraphLike[Int] = {
if(!ls.hasNext)
graph
else
val h = ls.next
}
``````

and then:

``````val gr = vertexAdder( synMap.keysIterator, new DiGraph[Int]( Map() ) )
``````

As a side note, it is a bit sad that `Set` doesn't provides its own version of `tail`. It could maybe just takes the head of its own iterator and returns itself minus that element.

-

Oh wow... I figured out what was going on. In the GraphInstantiater method, the very first call which passes synMap.keys, keys returns an iterable[Int]. Looks like taking tail on this is a long process, most likely going through the whole set of keys each time.

changing the call to

``````val gr = vertexAdder( synMap.keys.toList, new DiGraph[Int]( Map() ) )
``````

made everything go faster. Does anyone know what is the underlying implementation of the container returned when you call `keys` on a Map ?

-