NetworkX is mostly for graph analysis, PyGraphviz mostly for drawing, and they're designed to work together. However, there's at least one respect in which NetworkX's graph drawing (via MatPlotLib) is superior to PyGraphviz's graph drawing (via Graphviz), namely that NetworkX has a spring layout algorithm (accessible via the spring_layout function) specifically for directed graphs while PyGraphviz has several spring layout algorithms (accessible via the neato program, and others) that lay out directed graphs as if they were undirected graphs. The only Graphviz / PyGraphviz layout program that really handles direction in a graph is dot, but dot creates hierarchical layouts, not force-directed layouts.

Here is an example that shows the difference between NetworkX and PyGraphviz for spring layouts of directed graphs:

import networkx as nx
import pygraphviz as pgv
import matplotlib.pyplot as ppt

edgelist = [(1,2),(1,9),(3,2),(3,9),(4,5),(4,6),(4,9),(5,9),(7,8),(7,9)]

nxd = nx.DiGraph()
nxu = nx.Graph()
gvd = pgv.AGraph(directed=True)
gvu = pgv.AGraph()


pos1 = nx.spring_layout(nxd)

pos2 = nx.spring_layout(nxu)







The third and fourth figures drawn are basically identical but for the arrowheads (the whole figure has been rotated, but apart from that, there's no difference). However, the first and second figures are differently laid out - and not just because NetworkX's layout algorithm introduces an element of randomness.

Repeatedly running the code above shows that this is not a chance occurrence. NetworkX's spring_layout function was apparently written on the assumption that if there is an arc from one node to another, the second node should be closer to the centre of the graph than the first (i.e. that if the graph described in edgelist is directed, node 2 should be closer to node 9 than nodes 1 and 3 are, node 6 should be closer to node 9 than node 4 is, and node 8 should be closer to node 9 than node 7 is; this doesn't always work perfectly as we see from nodes 4 and 5 in the first figure above, but that's a small issue compared to getting both 2 and 9 near the centre and the 'error' from my point of view is very slight). In other words, NetworkX's spring_layout is both hierarchical and force-directed.

That is a nice feature, because it makes core/periphery structures more obvious in directed graphs (where, depending on the assumptions you're working with, nodes without incoming arcs can be considered to be part of the periphery even if they have large numbers of outgoing arcs). @skyebend has explained below why most layout algorithms treat directed graphs as if they were undirected, but the graphs above show (a) that NetworkX treats them differently, and (b) that it does so in a principled way that is helpful for analysis.

Can this be replicated using PyGraphviz / Graphviz?

Unfortunately the documentation and the commented source code for NetworkX's spring_layout (actually fruchterman_reingold_layout) function provide no clue as to why NetworkX produces the result that it does.

This is the result of using PyGraphviz to draw the network using the NetworkX spring_layout function (see my own answer to this question below). 5_pygraphviz_plus_networkx.png: (http://farm9.staticflickr.com/8378/8520231183_e7dfe21ab4.jpg)


Okay, I think I figured it out so I'm going to answer my own question. I don't think it can be done in PyGraphviz per se. However, one can instruct PyGraphviz to take the node positions from NetworkX but peg them (using !) so that the neato program is prevented from actually doing anything except rubber-stamping the node positions calculated by spring_layout. Add the following lines of code to the above:

for k,v in pos1.iteritems():


The result is not perfect -- I had to multiply the co-ordinates by 10 in order to stop the nodes from being drawn on top of each other, which is (obviously) a kludge -- but it's an improvement, i.e. the nodes with 0 indegree are on the outside (benefit of laying out with NetworkX) and there are proper arrowheads that don't get swallowed up by the nodes themselves (benefit of drawing with PyGraphviz).

I am aware that this isn't strictly what I asked for, though (i.e. a solution using PyGraphviz / Graphviz itself).

If somebody can provide a better solution I'll be happy!

EDIT: Nobody's provided a better solution to the problem as articulated above, so I'm going to accept my own answer to signal that it actually works. However, I'm also voting up skyebend's answer because - although it doesn't solve the problem - it's a very useful contribution to understanding the underlying issues.

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Graphviz also has an fdp and sfdp layout mode for doing force directed placement of nodes which is analogous to a spring layout. I'm not familiar with NetworkX, but it seems gvu.layout(prog='fdp') might work? If NetworkX allows passing additional arguments to Graphviz there are a number of configurable layout parameters you could tweak that may give you a layout closer to what you want. See Graphviz docs: http://www.graphviz.org/content/attrs

However, the fdp layouts treat the network as an undirected graph. Most 'spring' layouts I know of also treat networks as undirected because they must transform them into a Euclidean space (the screen) in which distances are symmetric. One exception would be 'magnetic' spring layouts which also attempt to align arcs so they are pointing in a similar direction to convey hierarchy, as a sort neato/dot hybrid.

Algorithm implementations may also differ in how they transform the network distances in an directed network to undirected weights/distances to be optimized by the layout. You may want to do this step explicitly yourself if you want more control over the way directed arcs are interpreted.

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  • Thanks for explaining why most spring layouts treat networks as undirected, but the solution you provide (i.e. using fdp or sfdp instead of neato) does not address my problem (as you acknowledge when you write that "the fdp layouts treat the network as an undirected graph"), and there does not appear to be a Graphviz layout parameter that will produce the effect I'm after. I'm going to include screenshots above so you can see what I mean. (It would certainly help if the NetworkX documentation explained what was going on!) – Westcroft_to_Apse Mar 2 '13 at 11:57
  • I'm curious to know whether the NetworkX spring_layout might be analogous to those "'magnetic' spring layouts which also attempt to align arcs so they are pointing in a similar direction to convey hierarchy" - on the evidence of the images I've linked to above, what it seems to be doing is not trying to make the arcs point in the same direction, but trying to make them point towards the centre of the graph. – Westcroft_to_Apse Mar 2 '13 at 12:38
  • I guess I'm not clear what image you are trying to achieve. I don't know Python, but from looking at the FR layout code you linked to, it seems like it is not explicitly handling asymmetry in the graph, and is trying to optimize only on 'out' ties, which seems like it may be giving odd results. For example, in the image you linked to, why should nodes 7 and 8 be so much closer than 7 and 9? The pygraphviz layouts you link to look much more consistent and clearer to my eye. – skyebend Mar 3 '13 at 23:21
  • Which of the two approaches is "clearer" depends on what you want clarified. In social network analysis, one of the key concepts is core vs periphery, and the NetworkX layout clearly shows which nodes belong to which, while the various Graphviz layouts obscure the core-periphery structure completely. That 7 and 8 are closer together than 7 and 9 is not an "odd result" from this point of view but an example of the very thing that makes NetworkX layouts so valuable for real-world data (as opposed to the toy data I'm using here): 7 and 8 are in the periphery of the graph, while 9 is in the core. – Westcroft_to_Apse Mar 4 '13 at 12:43
  • I'm voting up your answer because even though it doesn't solve my specific problem, it's a really useful contribution. (Sorry for not doing this sooner - I was hoping someone was going to post an actual solution, but - unless you count the kludge I've provided in my own answer to the question - nobody has.) – Westcroft_to_Apse May 13 '13 at 11:46

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