# VertexCoordinate Rules and VertexList from GraphPlot Graphic

Is there any way of abstracting the vertex order that GraphPlot applies to VertexCoordinate Rules from the (FullForm or InputForm) of the graphic produced by GraphPlot? I do not want to use the GraphUtilities function VertexList. I am also aware of GraphCoordinates, but both of these functions work with the graph, NOT the graphics output of GraphPlot.

For example,

``````gr1 = {1 -> 2, 2 -> 3, 3 -> 4, 4 -> 5, 5 -> 6, 6 -> 1};
gp1 = GraphPlot[gr1, Method -> "CircularEmbedding",
VertexLabeling -> True];

Last@(gp1 /. Graphics[Annotation[x___], ___] :>  {x})
``````

gives the following list of six coordinate pairs:

VertexCoordinateRules -> {{2., 0.866025}, {1.5, 1.73205}, {0.5, 1.73205}, {0., 0.866025}, {0.5, 1.3469*10^-10}, {1.5, 0.}}

How do I know which rule applies to which vertex, and can I be certain that this is the same as that given by VertexList[gr1]?

For example

`````` Needs["GraphUtilities`"];
gr2 = SparseArray@
Map[# -> 1 &, EdgeList[{2 -> 3, 3 -> 4, 4 -> 5, 5 -> 6}]];

VertexList[gr2]
``````

gives {1, 2, 3, 4, 5}

But ....

``````    gp2 = GraphPlot[gr2, VertexLabeling -> True,
VertexCoordinateRules ->
Last@(gp1 /. Graphics[Annotation[x___], ___] :>  {x})[[2]]]];
Last@(gp2 /. Graphics[Annotation[x___], ___] :>  {x})
``````

gives SIX coordinate sets:

VertexCoordinateRules -> {{2., 0.866025}, {1.5, 1.73205}, {0.5, 1.73205}, {0., 0.866025}, {0.5, 1.3469*10^-10}, {1.5, 0.}}

How can I abstract the correct VertexList for VertexCoordinateRules for gr2, for example?

(I am aware that I can correct things by taking the VertexList after generating gr2 as follows, for example)

``````VertexList@
SparseArray[
Map[# -> 1 &, EdgeList[{2 -> 3, 3 -> 4, 4 -> 5, 5 -> 6}]], {6, 6}]
``````

{1, 2, 3, 4, 5, 6}

but the information I need appears to be present in the GraphPlot graphic: how can I obtain it?

(The reason I convert the graph to an adjacency matrix it that, as pointed out by Carl Woll of Wolfram, it allows me to include an 'orphan' node, as in gp2)

-
btw, another way to represent disconnected graphs with edge list is to have i->i edges for every node. May need SelfLoopStyle->None during plotting –  Yaroslav Bulatov Nov 22 '10 at 19:44
Yes, that's true! I used to use it before I learned of Carl Woll's method. I sometimes need to show self-loops and (for now) prefer the adjacency matrix method. –  TomD Nov 22 '10 at 20:51
I think both are useful -- adjacency matrix is more convenient if you are examining graphs or doing modifications that don't change the number of vertices, whereas edgelist is better when you need to do things like splitting graph into two –  Yaroslav Bulatov Nov 22 '10 at 21:19

With vertex labeling, one way is to get coordinates of the labels. Notice that output of GraphPlot is in GraphicsComplex where coordinates of coordinate aliases are as first label, you can get it as

``````points = Cases[gp1, GraphicsComplex[points_, __] :> points, Infinity] // First
``````

Looking at `FullForm` you'll see that labels are in text objects, extract them as

``````labels = Cases[gp1, Text[___], Infinity]
``````

The actual label seems to be two levels deep so you get

``````actualLabels = labels[[All, 1, 1]];
``````

Coordinate alias is the second parameter so you get them as

`````` coordAliases = labels[[All, 2]]
``````

Actual coordinates were specified in GraphicsComplex, so we get them as

`````` actualCoords = points[[coordAliases]]
``````

There a 1-1 correspondence between list of coordinates and list of labels, so you can use Thread to return them as list of "label"->coordinate pairs.

here's a function that this all together

``````getLabelCoordinateMap[gp1_] :=
Module[{points, labels, actualLabels, coordAliases, actualCoords},
points =
Cases[gp1, GraphicsComplex[points_, __] :> points, Infinity] //
First;
labels = Cases[gp1, Text[___], Infinity];
actualLabels = labels[[All, 1, 1]];
coordAliases = labels[[All, 2]];
actualCoords = points[[coordAliases]];
];
getLabelCoordinateMap[gp1]
``````

Not that this only works on labelled GraphPlot. For ones without labels you could try to extract from other graphics objects, but you may get different results depending on what objects you extract the mapping from because there seems to be a bug which sometimes assigns line endpoints and vertex labels to different vertices. I've reported it. The way to work around the bug is to either always use explicit vertex->coordinate specification for VertexCoordinateList, or always use "adjacency matrix" representation. Here's an example of discrepancy

``````graphName = {"Grid", {3, 3}};
gp1 = GraphPlot[Rule @@@ GraphData[graphName, "EdgeIndices"],
VertexCoordinateRules -> GraphData[graphName, "VertexCoordinates"],
VertexLabeling -> True]
VertexCoordinateRules -> GraphData[graphName, "VertexCoordinates"],
VertexLabeling -> True]
``````

BTW, as an aside, here are the utility functions I use for converting between adjacency matrix and edge rule representation

``````edges2mat[edges_] := Module[{a, nodes, mat, n},
(* custom flatten to allow edges be lists *)

nodes = Sequence @@@ edges // Union // Sort;
nodeMap = (# -> (Position[nodes, #] // Flatten // First)) & /@
nodes;
n = Length[nodes];
mat = (({#1, #2} -> 1) & @@@ (edges /. nodeMap)) //
SparseArray[#, {n, n}] &
];
mat2edges[mat_List] := Rule @@@ Position[mat, 1];
mat2edges[mat_SparseArray] :=
Rule @@@ (ArrayRules[mat][[All, 1]] // Most)
``````
-
Thanks! I appreciate your help. I learned an awful lot from your answer. Your edges2mat is also a goodie. –  TomD Nov 23 '10 at 10:23

If you execute `FullForm[gp1]` you'll get a bunch of output which I won't post here. Near the start of the output you'll find a `GraphicsComplex[]`. This is, essentially, a list of points and then a list of uses of those points. So, for your graphic `gp1` the beginning of the GraphicsComplex is:

``````GraphicsComplex[
List[List[2., 0.866025], List[1.5, 1.73205], List[0.5, 1.73205],
List[0., 0.866025], List[0.5, 1.3469*10^-10], List[1.5, 0.]],
List[List[RGBColor[0.5, 0., 0.],
Line[List[List[1, 2], List[2, 3], List[3, 4], List[4, 5],
List[5, 6], List[6, 1]]]],
``````

The first outermost list defines the positions of 6 points. The second outermost list defines a bunch of lines between those points, using the numbers of the points within the first list. It's probably easier to understand if you play around with this.

EDIT: In response to OP's comment, if I execute:

``````FullForm[GraphPlot[{3 -> 4, 4 -> 5, 5 -> 6, 6 -> 3}]]
``````

I get

``````    Graphics[Annotation[GraphicsComplex[List[List[0.`,0.9997532360813222`],
List[0.9993931236462025`,1.0258160108662504`],List[1.0286626995939243`,
0.026431169015735057`],List[0.02872413637035287`,0.`]],List[List[RGBColor[0.5`,0.`,0.`],
Line[List[List[1,2],List[2,3],List[3,4],List[4,1]]]],List[RGBColor[0,0,0.7`],
Tooltip[Point[1],3],Tooltip[Point[2],4],Tooltip[Point[3],5],Tooltip[Point[4],6]]],
List[]],Rule[VertexCoordinateRules,List[List[0.`,0.9997532360813222`],
List[0.9993931236462025`,1.0258160108662504`],
List[1.0286626995939243`,0.026431169015735057`],List[0.02872413637035287`,0.`]]]],
Try `Transpose@{First /@ #[[1, 1, 2, 1, 2, 1]], #[[1, 1, 1]]} &[gp1]` –  Timo Nov 22 '10 at 16:21