Mercurial > public > think_complexity
view GraphWorld.py @ 27:78116556b491
Exercise 1 in chapter 5.1 (Zipf's law).
author | Brian Neal <bgneal@gmail.com> |
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date | Sat, 05 Jan 2013 16:38:24 -0600 |
parents | e87731ed81fc |
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""" Code example from Complexity and Computation, a book about exploring complexity science with Python. Available free from http://greenteapress.com/complexity Copyright 2011 Allen B. Downey. Distributed under the GNU General Public License at gnu.org/licenses/gpl.html. """ import string import random import math from itertools import chain try: from Gui import Gui, GuiCanvas except ImportError: from swampy.Gui import Gui, GuiCanvas from Graph import Vertex from Graph import Edge from Graph import Graph class GraphCanvas(GuiCanvas): """a GraphCanvas is a canvas that knows how to draw Vertices and Edges""" def draw_vertex(self, v, r=0.45): """draw a Vertex as a yellow circle with radius (r) and text (v.label)""" tag = 'v%d' % id(self) try: color = v.color except: color = 'yellow' self.circle(v.pos, r, color, tags=tag) self.text(v.pos, v.label, 'black', tags=tag) return tag def draw_edge(self, e): """draw an Edge as a line between the positions of the Vertices it connects""" v, w = e tag = self.line([v.pos, w.pos]) return tag class GraphWorld(Gui): """GraphWorld is a Gui that has a Graph Canvas and control buttons.""" def __init__(self): Gui.__init__(self) self.title('GraphWorld') self.setup() def setup(self): """Create the widgets.""" self.ca_width = 400 self.ca_height = 400 xscale = self.ca_width / 20 yscale = self.ca_height / 20 # canvas self.col() self.canvas = self.widget(GraphCanvas, scale=[xscale, yscale], width=self.ca_width, height=self.ca_height, bg='white') # buttons self.row() self.bu(text='Clear', command=self.clear) self.bu(text='Quit', command=self.quit) self.endrow() def show_graph(self, g, layout): """Draws the Vertices and Edges of Graph (g) using the positions in Layout (layout). """ # copy the positions from the layout into the Vertex objects for v in g.vertices(): v.pos = layout.pos(v) # draw the edges and store the tags in self.etags, which maps # from Edges to their tags c = self.canvas self.etags = {} for v in g: self.etags[v] = [c.draw_edge(e) for e in g.out_edges(v)] # draw the vertices and store their tags in a list self.vtags = [c.draw_vertex(v) for v in g] def clear(self): """Delete all canvas items.""" tags = chain(self.vtags, *self.etags.itervalues()) for tag in tags: self.canvas.delete(tag) class Layout(dict): """A Layout is a mapping from vertices to positions in 2-D space.""" def __init__(self, g): for v in g.vertices(): self[v] = (0, 0) def pos(self, v): """Returns the position of this Vertex as a tuple.""" return self[v] def distance_between(self, v1, v2): """Computes the Euclidean distance between two vertices.""" x1, y1 = self.pos(v1) x2, y2 = self.pos(v2) dx = x1 - x2 dy = y1 - y2 return math.sqrt(dx**2 + dy**2) def sort_by_distance(self, v, others): """Returns a list of the vertices in others sorted in increasing order by their distance from v.""" t = [(self.distance_between(v, w), w) for w in others] t.sort() return [w for (d, w) in t] class CircleLayout(Layout): """Creates a layout for a graph with the vertices equally spaced around the perimeter of a circle.""" def __init__(self, g, radius=9): """Creates a layout for Graph (g)""" vs = g.vertices() theta = math.pi * 2 / len(vs) for i, v in enumerate(vs): x = radius * math.cos(i * theta) y = radius * math.sin(i * theta) self[v] = (x, y) class RandomLayout(Layout): """Create a layout with each Vertex at a random position in [[-max, -max], [max, max]].""" def __init__(self, g, max=10): """Creates a layout for Graph (g)""" self.max = max for v in g.vertices(): self[v] = self.random_pos() def random_pos(self): """choose a random position and return it as a tuple""" x = random.uniform(-self.max, self.max) y = random.uniform(-self.max, self.max) return x, y def spread_vertex(self, v, others, min_dist=1.0): """Keep choosing random positions for v until it is at least min_dist units from the vertices in others. Each time it fails, it relaxes min_dist by 10%. """ while True: t = [(self.distance_between(v, w), w) for w in others] d, w = min(t) if d > min_dist: break min_dist *= 0.9 self[v] = self.random_pos() def spread_vertices(self): """Moves the vertices around until no two are closer together than a minimum distance.""" vs = self.keys() others = vs[:] for v in vs: others.remove(v) self.spread_vertex(v, others) others.append(v) def main(script, n='10', *args): # create n Vertices n = int(n) labels = string.ascii_lowercase + string.ascii_uppercase vs = [Vertex(c) for c in labels[:n]] # create a graph and a layout g = Graph(vs) g.add_all_edges() layout = CircleLayout(g) # draw the graph gw = GraphWorld() gw.show_graph(g, layout) gw.mainloop() if __name__ == '__main__': import sys main(*sys.argv)