What is the simplest way to plot a decomposition tree in Mathematica?

I would like to plot a "decomposition tree" in Mathematica.

I have a function `f` that takes an object and returns all the components of that object as a list. For the purpose of this question, let's just decompose Mathematica expressions as follows (my actual `f` relies on an external database to decompose different kinds of objects, so I can't easily post it):

``````f[e_?AtomQ] := {}
f[e_] := List @@ e
``````

I would like to create a tree plot that shows how an object is decomposed as we recursively keep applying `f`. For the particular example `f` above, we should get something very similar to the output of `TreeForm`, except that a full expression should be displayed (rather than just a head) at each node. The children of a node are going to be its components as returned by `f`.

Note that elements can repeat in a decomposition tree like this, but not elements are repeated in the output of `TreePlot` as it works with graphs. One idea would be to generate a unique "internal name" for each node, construct a graph, and use TreePlot, setting it to display the actual form of the nodes rather than their "internal name"

-

``````tf[x_] := f[x] /. {{} :> x, r_ :> x @@ tf /@ r}
``````

If any of the terms are not inert, this "simple" (?) approach will not work.

-
Hackish in a way, but it's the kind of simple solution I was hoping for. And the objects I decompose are stored as strings, so very suitable there (no accidental evaluation). –  Szabolcs Apr 13 '11 at 23:37
can you suggest a way compatible with this solution to change the font of the nodes? (Needed to display glyphs not present in the default font.) –  Szabolcs May 5 '11 at 10:36
@Szabolcs You can use the `VertexRenderingFunction` option of `TreeForm` to take complete control over the node appearance, e.g. `VertexRenderingFunction->(Inset[Framed[Style[#2, FontFamily->"Webdings"], Background->LightYellow], #1]&)`. –  WReach May 5 '11 at 14:32
ah, so obvious! I was all along on the wrong track, trying to manipulate the nodes directly ... –  Szabolcs May 5 '11 at 15:31

I am not sure it answers your question, but here is how I would implement rudimentary TreeForm:

``````decompose[expr_?AtomQ] := expr
decompose[expr_] := Block[{lev = Level[expr, {1}]},
Sow[Thread[expr -> lev]]; decompose /@ lev;]

treeForm[expr_] := Reap[decompose[expr]][[-1, 1]] // Flatten
``````

Then:

EDIT Yes you are right, this is not a tree. To make it a tree, each expression should carry with it its position. Kind of like so:

``````ClearAll[treePlot, node, decompose2];
SetAttributes[{treePlot, node, decompose2}, HoldAll];
decompose2[expr_] /; AtomQ[Unevaluated[expr]] := node[expr];
decompose2[expr_] := Module[{pos, list},
pos = SortBy[
Position[Unevaluated[expr], _, {0, Infinity}, Heads -> False],
Length];
list = Extract[Unevaluated[expr], pos, node];
ReplaceList[
list, {___, node[e1_, p1_], ___, node[e2_, p2_], ___} /;
Length[p2] == Length[p1] + 1 &&
Most[p2] == p1 :> (node[e1, p1] -> node[e2, p2])]
]
``````

Then

``````treePlot2[expr_] :=
Module[{data = decompose2[a^2 + Subscript[b, 2] + 3 c], gr, vlbls},
gr = Graph[data];
vlbls = Table[vl -> (HoldForm @@ {vl[[1]]}), {vl, VertexList[gr]}];
Graph[data, VertexLabels -> vlbls, ImagePadding -> 50]
]
``````

-
your plot is not really a tree, as both `a^2` and `b_2` have an edge pointing to the same node labelled 2. This is exactly the challenge (and why I mentioned that perhaps it's necessary to use an "internal name" for node): I need branching at every step, and elements are allowed to be repeated in the tree. We should have two nodes labelled `2` here, one branching from `a^2`, the other from `b_2`. –  Szabolcs Apr 13 '11 at 13:09
@Szabolcs Please see the edit to my response –  Sasha Apr 13 '11 at 17:44
This is brilliant coding but there is a small error. The treeplot2 function should read: Module[{data = decompose2[expr], gr, vlbls}, gr = Graph[data]; vlbls = Table[vl -> (HoldForm @@ {vl[[1]]}), {vl, VertexList[gr]}]; Graph[data, VertexLabels -> vlbls, ImagePadding -> 50] ], –  mathlawguy Jan 20 '13 at 15:52