(For LaTeX drawings of graphs, see the graph_latex module.)
All graphs have an associated Sage graphics object, which you can display:
sage: G = graphs.WheelGraph(15)
sage: P = G.plot()
sage: P.show() # long time
If you create a graph in Sage using the Graph command, then plot that graph, the positioning of nodes is determined using the spring-layout algorithm. For the special graph constructors, which you get using graphs.[tab], the positions are preset. For example, consider the Petersen graph with default node positioning vs. the Petersen graph constructed by this database:
sage: petersen_spring = Graph({0:[1,4,5], 1:[0,2,6], 2:[1,3,7], 3:[2,4,8], 4:[0,3,9], 5:[0,7,8], 6:[1,8,9], 7:[2,5,9], 8:[3,5,6], 9:[4,6,7]})
sage: petersen_spring.show() # long time
sage: petersen_database = graphs.PetersenGraph()
sage: petersen_database.show() # long time
For all the constructors in this database (except the octahedral, dodecahedral, random and empty graphs), the position dictionary is filled in, instead of using the spring-layout algorithm.
Plot options
Here is the list of options accepted by plot() and the constructor of GraphPlot.
partition | A partition of the vertex set. If specified, plot will show each cell in a different color. vertex_colors takes precedence. |
dist | The distance between multiedges. |
vertex_labels | Whether or not to draw vertex labels. |
edge_color | The default color for edges. |
spring | Use spring layout to finalize the current layout. |
pos | The position dictionary of vertices |
loop_size | The radius of the smallest loop. |
color_by_label | Whether to color the edges according to their labels. This also accepts a function or dictionary mapping labels to colors. |
iterations | The number of times to execute the spring layout algorithm. |
talk | Whether to display the vertices in talk mode (larger and white). |
edge_labels | Whether or not to draw edge labels. |
vertex_size | The size to draw the vertices. |
dim | The dimension of the layout – 2 or 3. |
edge_style | The linestyle of the edges. It should be one of “solid”, “dashed”, “dotted”, dashdot”, or “-”, “–”, ”:”, “-.”, respectively. This currently only works for directed graphs, since we pass off the undirected graph to networkx. |
layout | A layout algorithm – one of : “acyclic”, “circular” (plots the graph with vertices evenly distributed on a circle), “ranked”, “graphviz”, “planar”, “spring” (traditional spring layout, using the graph’s current positions as initial positions), or “tree” (the tree will be plotted in levels, depending on minimum distance for the root). |
vertex_shape | The shape to draw the vertices. Currently unavailable for Multi-edged DiGraphs. |
vertex_colors | Dictionary of vertex coloring : each key is a color recognizable by matplotlib, and each corresponding entry is a list of vertices. If a vertex is not listed, it looks invisible on the resulting plot (it does not get drawn). |
by_component | Whether to do the spring layout by connected component – a boolean. |
heights | A dictionary mapping heights to the list of vertices at this height. |
graph_border | Whether or not to draw a frame around the graph. |
max_dist | The max distance range to allow multiedges. |
prog | Which graphviz layout program to use – one of “circo”, “dot”, “fdp”, “neato”, or “twopi”. |
edge_colors | a dictionary specifying edge colors: each key is a color recognized by matplotlib, and each entry is a list of edges. |
tree_orientation | The direction of tree branches – ‘up’, ‘down’, ‘left’ or ‘right’. |
save_pos | Whether or not to save the computed position for the graph. |
tree_root | A vertex designation for drawing trees. A vertex of the tree to be used as the root for the layout='tree' option. If no root is specified, then one is chosen close to the center of the tree. Ignored unless layout='tree' |
Default options
This module defines two dictionaries containing default options for the plot() and show() methods. These two dictionaries are sage.graphs.graph_plot.DEFAULT_PLOT_OPTIONS and sage.graphs.graph_plot.DEFAULT_SHOW_OPTIONS, respectively.
Obviously, these values are overruled when arguments are given explicitly.
Here is how to define the default size of a graph drawing to be [6,6]. The first two calls to show() use this option, while the third does not (a value for figsize is explicitly given):
sage: sage.graphs.graph_plot.DEFAULT_SHOW_OPTIONS['figsize'] = [6,6]
sage: graphs.PetersenGraph().show() # long time
sage: graphs.ChvatalGraph().show() # long time
sage: graphs.PetersenGraph().show(figsize=[4,4]) # long time
We can now reset the default to its initial value, and now display graphs as previously:
sage: sage.graphs.graph_plot.DEFAULT_SHOW_OPTIONS['figsize'] = [4,4]
sage: graphs.PetersenGraph().show() # long time
sage: graphs.ChvatalGraph().show() # long time
Note
While DEFAULT_PLOT_OPTIONS affects both G.show() and G.plot(), settings from DEFAULT_SHOW_OPTIONS only affects G.show().
In order to define a default value permanently, you can add a couple of lines to Sage’s startup scripts. Example
sage: import sage.graphs.graph_plot
sage: sage.graphs.graph_plot.DEFAULT_SHOW_OPTIONS['figsize'] = [4,4]
Index of methods and functions
GraphPlot.set_pos() | Sets the position plotting parameters for this GraphPlot. |
GraphPlot.set_vertices() | Sets the vertex plotting parameters for this GraphPlot. |
GraphPlot.set_edges() | Sets the edge (or arrow) plotting parameters for the GraphPlot object. |
GraphPlot.show() | Shows the (Di)Graph associated with this GraphPlot object. |
GraphPlot.plot() | Returns a graphics object representing the (di)graph. |
GraphPlot.layout_tree() | Compute a nice layout of a tree. |
_circle_embedding() | Sets some vertices on a circle in the embedding of a graph G. |
_line_embedding() | Sets some vertices on a line in the embedding of a graph G. |
Sets some vertices on a circle in the embedding of a graph G.
This method modifies the graph’s embedding so that the vertices
listed in vertices appear in this ordering on a circle of given
radius and center. The shift parameter is actually a rotation of
the circle. A value of shift=1 will replace in the drawing the
-th element of the list by the
-th. Non-integer values are
admissible, and a value of
corresponds to a rotation of the
circle by an angle of
(where
is the number of
vertices set on the circle).
EXAMPLE:
sage: from sage.graphs.graph_plot import _circle_embedding
sage: g = graphs.CycleGraph(5)
sage: _circle_embedding(g, [0, 2, 4, 1, 3], radius=2, shift=.5)
sage: g.show()
Sets some vertices on a line in the embedding of a graph G.
This method modifies the graph’s embedding so that the vertices of vertices appear on a line, where the position of vertices[0] is the pair first and the position of vertices[-1] is last. The vertices are evenly spaced.
EXAMPLE:
sage: from sage.graphs.graph_plot import _line_embedding
sage: g = graphs.PathGraph(5)
sage: _line_embedding(g, [0, 2, 4, 1, 3], first=(-1, -1), last=(1, 1))
sage: g.show()
Bases: sage.structure.sage_object.SageObject
Returns a GraphPlot object, which stores all the parameters needed for plotting (Di)Graphs. A GraphPlot has a plot and show function, as well as some functions to set parameters for vertices and edges. This constructor assumes default options are set. Defaults are shown in the example below.
EXAMPLE:
sage: from sage.graphs.graph_plot import GraphPlot
sage: options = {
... 'vertex_size':200,
... 'vertex_labels':True,
... 'layout':None,
... 'edge_style':'solid',
... 'edge_color':'black',
... 'edge_colors':None,
... 'edge_labels':False,
... 'iterations':50,
... 'tree_orientation':'down',
... 'heights':None,
... 'graph_border':False,
... 'talk':False,
... 'color_by_label':False,
... 'partition':None,
... 'dist':.075,
... 'max_dist':1.5,
... 'loop_size':.075}
sage: g = Graph({0:[1,2], 2:[3], 4:[0,1]})
sage: GP = GraphPlot(g, options)
Compute a nice layout of a tree.
INPUT:
root – the root vertex.
orientation – Whether to place the root at the top or at the bottom :
- orientation="down" – children are placed below their parent
- orientation="top" – children are placed above their parent
EXAMPLES:
sage: T = graphs.RandomLobster(25,0.3,0.3)
sage: T.show(layout='tree',tree_orientation='up') # indirect doctest
sage: from sage.graphs.graph_plot import GraphPlot
sage: G = graphs.HoffmanSingletonGraph()
sage: T = Graph()
sage: T.add_edges(G.min_spanning_tree(starting_vertex=0))
sage: T.show(layout='tree',tree_root=0) # indirect doctest
Returns a graphics object representing the (di)graph.
INPUT:
The options accepted by this method are to be found in the documentation of the sage.graphs.graph_plot module, and the show() method.
Note
See the module's documentation for information on default values of this method.
We can specify some pretty precise plotting of familiar graphs:
sage: from math import sin, cos, pi
sage: P = graphs.PetersenGraph()
sage: d = {'#FF0000':[0,5], '#FF9900':[1,6], '#FFFF00':[2,7], '#00FF00':[3,8], '#0000FF':[4,9]}
sage: pos_dict = {}
sage: for i in range(5):
... x = float(cos(pi/2 + ((2*pi)/5)*i))
... y = float(sin(pi/2 + ((2*pi)/5)*i))
... pos_dict[i] = [x,y]
...
sage: for i in range(10)[5:]:
... x = float(0.5*cos(pi/2 + ((2*pi)/5)*i))
... y = float(0.5*sin(pi/2 + ((2*pi)/5)*i))
... pos_dict[i] = [x,y]
...
sage: pl = P.graphplot(pos=pos_dict, vertex_colors=d)
sage: pl.show()
Here are some more common graphs with typical options:
sage: C = graphs.CubeGraph(8)
sage: P = C.graphplot(vertex_labels=False, vertex_size=0, graph_border=True)
sage: P.show()
sage: G = graphs.HeawoodGraph().copy(sparse=True)
sage: for u,v,l in G.edges():
... G.set_edge_label(u,v,'(' + str(u) + ',' + str(v) + ')')
sage: G.graphplot(edge_labels=True).show()
The options for plotting also work with directed graphs:
sage: D = DiGraph( { 0: [1, 10, 19], 1: [8, 2], 2: [3, 6], 3: [19, 4], 4: [17, 5], 5: [6, 15], 6: [7], 7: [8, 14], 8: [9], 9: [10, 13], 10: [11], 11: [12, 18], 12: [16, 13], 13: [14], 14: [15], 15: [16], 16: [17], 17: [18], 18: [19], 19: []}, implementation='networkx' )
sage: for u,v,l in D.edges():
... D.set_edge_label(u,v,'(' + str(u) + ',' + str(v) + ')')
sage: D.graphplot(edge_labels=True, layout='circular').show()
This example shows off the coloring of edges:
sage: from sage.plot.colors import rainbow
sage: C = graphs.CubeGraph(5)
sage: R = rainbow(5)
sage: edge_colors = {}
sage: for i in range(5):
... edge_colors[R[i]] = []
sage: for u,v,l in C.edges():
... for i in range(5):
... if u[i] != v[i]:
... edge_colors[R[i]].append((u,v,l))
sage: C.graphplot(vertex_labels=False, vertex_size=0, edge_colors=edge_colors).show()
With the partition option, we can separate out same-color groups of vertices:
sage: D = graphs.DodecahedralGraph()
sage: Pi = [[6,5,15,14,7],[16,13,8,2,4],[12,17,9,3,1],[0,19,18,10,11]]
sage: D.show(partition=Pi)
Loops are also plotted correctly:
sage: G = graphs.PetersenGraph()
sage: G.allow_loops(True)
sage: G.add_edge(0,0)
sage: G.show()
sage: D = DiGraph({0:[0,1], 1:[2], 2:[3]}, loops=True)
sage: D.show()
sage: D.show(edge_colors={(0,1,0):[(0,1,None),(1,2,None)],(0,0,0):[(2,3,None)]})
More options:
sage: pos = {0:[0.0, 1.5], 1:[-0.8, 0.3], 2:[-0.6, -0.8], 3:[0.6, -0.8], 4:[0.8, 0.3]}
sage: g = Graph({0:[1], 1:[2], 2:[3], 3:[4], 4:[0]})
sage: g.graphplot(pos=pos, layout='spring', iterations=0).plot()
sage: G = Graph()
sage: P = G.graphplot().plot()
sage: P.axes()
False
sage: G = DiGraph()
sage: P = G.graphplot().plot()
sage: P.axes()
False
We can plot multiple graphs:
sage: T = list(graphs.trees(7))
sage: t = T[3]
sage: t.graphplot(heights={0:[0], 1:[4,5,1], 2:[2], 3:[3,6]}).plot()
sage: T = list(graphs.trees(7))
sage: t = T[3]
sage: t.graphplot(heights={0:[0], 1:[4,5,1], 2:[2], 3:[3,6]}).plot()
sage: t.set_edge_label(0,1,-7)
sage: t.set_edge_label(0,5,3)
sage: t.set_edge_label(0,5,99)
sage: t.set_edge_label(1,2,1000)
sage: t.set_edge_label(3,2,'spam')
sage: t.set_edge_label(2,6,3/2)
sage: t.set_edge_label(0,4,66)
sage: t.graphplot(heights={0:[0], 1:[4,5,1], 2:[2], 3:[3,6]}, edge_labels=True).plot()
sage: T = list(graphs.trees(7))
sage: t = T[3]
sage: t.graphplot(layout='tree').show()
The tree layout is also useful:
sage: t = DiGraph('JCC???@A??GO??CO??GO??')
sage: t.graphplot(layout='tree', tree_root=0, tree_orientation="up").show()
More examples:
sage: D = DiGraph({0:[1,2,3], 2:[1,4], 3:[0]})
sage: D.graphplot().show()
sage: D = DiGraph(multiedges=True, sparse=True)
sage: for i in range(5):
... D.add_edge((i,i+1,'a'))
... D.add_edge((i,i-1,'b'))
sage: D.graphplot(edge_labels=True,edge_colors=D._color_by_label()).plot()
sage: g = Graph({}, loops=True, multiedges=True, sparse=True)
sage: g.add_edges([(0,0,'a'),(0,0,'b'),(0,1,'c'),(0,1,'d'),
... (0,1,'e'),(0,1,'f'),(0,1,'f'),(2,1,'g'),(2,2,'h')])
sage: g.graphplot(edge_labels=True, color_by_label=True, edge_style='dashed').plot()
The edge_style option may be provided in the short format too:
sage: g.graphplot(edge_labels=True, color_by_label=True, edge_style='--').plot()
TESTS:
Make sure that show options work with plot also:
sage: g = Graph({})
sage: g.plot(title='empty graph', axes=True)
Check for invalid inputs:
sage: p = graphs.PetersenGraph().plot(egabrag='garbage')
Traceback (most recent call last):
...
ValueError: Invalid input 'egabrag=garbage'
Sets the edge (or arrow) plotting parameters for the GraphPlot object.
This function is called by the constructor but can also be called to make updates to the vertex options of an existing GraphPlot object. Note that the changes are cumulative.
EXAMPLES:
sage: g = Graph({}, loops=True, multiedges=True, sparse=True)
sage: g.add_edges([(0,0,'a'),(0,0,'b'),(0,1,'c'),(0,1,'d'),
... (0,1,'e'),(0,1,'f'),(0,1,'f'),(2,1,'g'),(2,2,'h')])
sage: GP = g.graphplot(vertex_size=100, edge_labels=True, color_by_label=True, edge_style='dashed')
sage: GP.set_edges(edge_style='solid')
sage: GP.plot()
sage: GP.set_edges(edge_color='black')
sage: GP.plot()
sage: d = DiGraph({}, loops=True, multiedges=True, sparse=True)
sage: d.add_edges([(0,0,'a'),(0,0,'b'),(0,1,'c'),(0,1,'d'),
... (0,1,'e'),(0,1,'f'),(0,1,'f'),(2,1,'g'),(2,2,'h')])
sage: GP = d.graphplot(vertex_size=100, edge_labels=True, color_by_label=True, edge_style='dashed')
sage: GP.set_edges(edge_style='solid')
sage: GP.plot()
sage: GP.set_edges(edge_color='black')
sage: GP.plot()
TESTS:
sage: G = Graph("Fooba")
sage: G.show(edge_colors={'red':[(3,6),(2,5)]})
Verify that default edge labels are pretty close to being between the vertices in some cases where they weren’t due to truncating division (trac ticket #10124):
sage: test_graphs = graphs.FruchtGraph(), graphs.BullGraph()
sage: tol = 0.001
sage: for G in test_graphs:
... E=G.edges()
... for e0, e1, elab in E:
... G.set_edge_label(e0, e1, '%d %d' % (e0, e1))
... gp = G.graphplot(save_pos=True,edge_labels=True)
... vx = gp._plot_components['vertices'][0].xdata
... vy = gp._plot_components['vertices'][0].ydata
... for elab in gp._plot_components['edge_labels']:
... textobj = elab[0]
... x, y, s = textobj.x, textobj.y, textobj.string
... v0, v1 = map(int, s.split())
... vn = vector(((x-(vx[v0]+vx[v1])/2.),y-(vy[v0]+vy[v1])/2.)).norm()
... assert vn < tol
Sets the position plotting parameters for this GraphPlot.
EXAMPLES:
This function is called implicitly by the code below:
sage: g = Graph({0:[1,2], 2:[3], 4:[0,1]})
sage: g.graphplot(save_pos=True, layout='circular') # indirect doctest
GraphPlot object for Graph on 5 vertices
The following illustrates the format of a position dictionary, but due to numerical noise we do not check the values themselves:
sage: g.get_pos()
{0: [...e-17, 1.0],
1: [-0.951..., 0.309...],
2: [-0.587..., -0.809...],
3: [0.587..., -0.809...],
4: [0.951..., 0.309...]}
sage: T = list(graphs.trees(7))
sage: t = T[3]
sage: t.plot(heights={0:[0], 1:[4,5,1], 2:[2], 3:[3,6]})
TESTS:
Make sure that vertex locations are floats. Not being floats isn’t a bug in itself but makes it too easy to accidentally introduce a bug elsewhere, such as in set_edges() (trac ticket #10124), via silent truncating division of integers:
sage: g = graphs.FruchtGraph()
sage: gp = g.graphplot()
sage: set(map(type, flatten(gp._pos.values())))
set([<type 'float'>])
sage: g = graphs.BullGraph()
sage: gp = g.graphplot(save_pos=True)
sage: set(map(type, flatten(gp._pos.values())))
set([<type 'float'>])
Sets the vertex plotting parameters for this GraphPlot. This function is called by the constructor but can also be called to make updates to the vertex options of an existing GraphPlot object. Note that the changes are cumulative.
EXAMPLES:
sage: g = Graph({}, loops=True, multiedges=True, sparse=True)
sage: g.add_edges([(0,0,'a'),(0,0,'b'),(0,1,'c'),(0,1,'d'),
... (0,1,'e'),(0,1,'f'),(0,1,'f'),(2,1,'g'),(2,2,'h')])
sage: GP = g.graphplot(vertex_size=100, edge_labels=True, color_by_label=True, edge_style='dashed')
sage: GP.set_vertices(talk=True)
sage: GP.plot()
sage: GP.set_vertices(vertex_colors='pink', vertex_shape='^')
sage: GP.plot()
Shows the (Di)Graph associated with this GraphPlot object.
INPUT:
This method accepts all parameters of sage.plot.graphics.Graphics.show().
Note
EXAMPLE:
sage: C = graphs.CubeGraph(8)
sage: P = C.graphplot(vertex_labels=False, vertex_size=0, graph_border=True)
sage: P.show()