Hi Tiago,
sometimes, when delete the graph and create a new one, then plot it, the
plotted graph is shown upside down (in terms of the node text). So how could
we control the orientation of the graph? Or which parameter we should use to
always make node text shown in a correct orientation. Thanks a lot.
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Hi,
I'm suffering from the same issue mentioned in this post:
https://git.skewed.de/count0/graph-tool/issues/174
Namely, I'm trying to draw a graph that includes a lot of self-looping
edges, and my labels are being printed upside down. If I remove the
self-loops the labels are shown the right way up.
Is there a fix for it?
Thanks,
Charlie
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Dear Tiago,
I have a directed graph of about half a million nodes and approximately a
million edges following scale free behaviour and a power law degree
distribution. To test some of my hypothesis, I would like to generate random
smaller graphs (about 50 up to 200 nodes) representative of the big one.
When I used a sample function that samples straight away from the real
distribution of the big network, I have following problems:
- I generate unconnected nodes with both 0 in AND out degree.
- I generate small sub parts of a few nodes that are not connected to the
main graph.
- If only sampling from nodes with at least 1 degree, the generated graph is
coherent, but not representative anymore as I need a big portion of nodes
with either only one in or one out degree.
Here is the part of my script I used for that, where samples are drawn from
dictionaries of the degrees:
def sample_in():
a=np.random.randint(num)
k_in = in_degrees[a]
return k_in
def sample_out():
if sample_in()==0:
b=np.random.randint(num_out)
k_out=out_zero_zeros.values()[b]
return k_out
else:
b=np.random.randint(num)
k_out=out_degrees[b]
return k_out
N=200
g=gt.random_graph(N, lambda:(sample_in(), sample_out()),
model="constrained-configuration", directed=True)
I also tried sampling from a list of tuples as you have mentioned before in
the forum, but I didn't receive any results, as the tuples randomly drawn
from my list might not be combinable.
degs=[(7,1),(4,3),(5,6),(2,4),(6,8),(2,0),(3,5),(0,3),(2,7),(2,1)]
g = gt.random_graph(4, lambda i: degs[i], directed=True)
- Is there any option I could active that would help me in those cases I
described above?
- Is there a better way how to create representative small networks?
Any help on that issue will be much appreciated.
Best wishes,
Jana
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I am curious what is being used to calculate the standard deviation of the
average in gt.vertex_average and gt.edge_average
>>> t2=gt.Graph()
>>> t2.add_vertex(2)
>>> t2.add_edge(t2.vertex(0), t2.vertex(1))
>>> gt.vertex_average(t2, "in")
(0.5, 0.35355339059327373)
Now, shouldn't std be σ(n)=sqrt(((0-0.5)^2+(1-0.5)^2)/2)=0.5 ?
also q(n-1)=sqrt((0.5^2+0.5^2)/(2-1))~=0.70710
0.3535 is sqrt(2)/4 which happens to be σ(n-1)/2, so it seems there is some
relation to that.
A little bigger graph.
>>> t3=gt.Graph()
>>> t3.add_vertex(5)
>>> t3.add_edge(t3.vertex(0), t3.vertex(1))
>>> gt.vertex_average(t3, "in")
(0.2, 0.17888543819998318)
Now, we should have 0,1,0,0,0 series for vertex incoming degree.
So Windows calc gives σ(n)=0.4 and σ(n-1)~=0.44721, so where does 0.1788854
come from ?
Reason, I am asking because, I have a large graph, where the average looks
quite alright but the std makes no sense, as going by the histogram, degree
values are quite a bit more distributed than the std would indicate.
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Hi,
I was wondering if there is any way to assign vertex properties while
adding edges to the graph. for example using "add_edge_list" I can assign
edge properties but later I have to iterate through all vertices again to
assign their properties.
I know this is not a problem when the vertex property is of the type "int"
or "float" because then one can use "vprop.a = values", but in case of
"string" and "object" this method doesn't work
What would be the best/fastest way to handle this situation.
I guess it would be very helpful to extend the "add_edge_list" function to
accept vertex property in some way.
cheers,
--
Mohsen

I ran mcmc_equilibrate on a nested block state model in a weighted graph. As
per instructions, I copied the initially computed state in another object
with increased hierarchy depth to 10. However, this fixed the depth to 10.
Everything computed afterwards has depth 10 even if is clear that after 3 or
4 levels the nodes converge to one.
There are many empty branches and when I try to plot it with empty_branches
= False, I get an error stating it is not a tree.
RuntimeError: Invalid hierarchical tree: No path from source to target.
Did anybody perform any similar analyses?
The hierarchy after mcmc_equilibrate:
<NestedBlockState object, with base <BlockState object with 24 blocks (24
nonempty), degree-corrected, with 1 edge covariate, for graph <Graph
object, undirected, with 230 vertices and 11230 edges, edges filtered by
(<PropertyMap object with key type 'Edge' and value type 'bool', for
Graph 0x7fc3a89f1210, at 0x7fc3a64911d0>, False), vertices filtered by
(<PropertyMap object with key type 'Vertex' and value type 'bool', for Graph
0x7fc3a89f1210, at 0x7fc3a64912d0>, False) at 0x7fc3a89f1210>, at
0x7fc3a6491950>, and 10 levels of sizes [(230, 24), (24, 5), (5, 1), (1, 1),
(1, 1), (1, 1), (1, 1), (1, 1), (1, 1), (1, 1)] at 0x7fc3a6491590>
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Hello:
I am intrigued by a mention of 'attractor' in the doc on graph_tool.topology.label_components.
I have encountered attractors in dynamical systems, but don't know how to interpret this mention in the context of graph components
I searched without success for an explanation on the web.
Can you point me to some accessible references?
Thanks
JP