check this well builded code from algorithmic thinking 182, and some util script for plotting and viewing a grah

```
import collections
import types
def loads(repstr):
"""
Return a new graph initialized by the contents of the string
repstr. The string should contain the representation generated by
a call to dumps.
"""
return eval(repstr)
def load(f):
"""
Return a new graph initialized by the contents of the file f. The
file should contain the representation generated by a call to
dump.
"""
return loads(f.read())
class BaseGraph:
"""
Abstract graph class that supports node and edge attributes.
"""
### Graph structure:
###
### g = {node: _nodetup}
### _nodetup = (attr, nbrs)
### nbrs = {node: attr}
_nodetup = collections.namedtuple('node', 'attr nbrs')
def __init__(self):
"""
Create an empty graph.
"""
self._nodes = {}
def __len__(self):
"""
Return the number of nodes in the graph (len(g) == g.node_count()).
"""
return self.node_count()
def __contains__(self, node):
"""
Returns true if node is in the graph, false otherwise.
"""
return self.has_node(node)
def __iter__(self):
"""
Create an iterator over the nodes in the graph.
"""
return self._nodes.__iter__()
def __getitem__(self, node):
"""
Return the neighbor dictionary for the node.
nbrs = g[k] is the same as nbrs = g.get_neighbors(k)
"""
return self.get_neighbors(node)
def __setitem__(self, node, nbrs):
"""
Set the neighbor dictionary for the node.
g[k] = nbrs is the same as g.set_neighbors(k, nbrs)
"""
self.set_neighbors(node, nbrs)
def _repstr(self):
"""
Helper function for __str__ that returns a string of the
internal graph representation.
"""
return str(self._nodes)
def _reprepr(self):
"""
Helper function for __repr__ that returns a string of the
internal graph representation that can be evaluated to
recreate the representation.
"""
s = self._repstr()
s = s.replace('node(', 'BaseGraph._nodetup(')
return s
def nodes(self):
"""
Returns a list of nodes in the graph.
"""
return self._nodes.keys()
def get_neighbors(self, node):
"""
Returns the neighbor dictionary {neighbor node: attr} for node
or raises a KeyError if node is not in the graph.
"""
return self._nodes[node].nbrs
def set_neighbors(self, node, neighbors):
"""
Set the neighbor dictionary for the node. Add node if it's
not in the graph.
Example:
g[0] = {1: None} -- node 0 has 1 neighbor (node 1)
and there is no edge attribute.
"""
if self.has_node(node):
if type(neighbors) != types.DictType:
raise TypeError("neighbors must be a dictionary, not " + type(neighbors).__name__)
self._nodes[node] = BaseGraph._nodetup(self._nodes[node].attr, neighbors)
else:
self._nodes[node] = BaseGraph._nodetup(None, neighbors)
def get_node_attr(self, node):
"""
Returns the attribute for node or raises KeyError if node is
not in the graph.
"""
return self._nodes[node].attr
def set_node_attr(self, node, attr):
"""
Sets the attribute for node to attr or raises KeyError if node
is not in the graph.
"""
if self.has_node(node):
self._nodes[node] = Graph._nodetup(attr, self._nodes[node].nbrs)
else:
raise KeyError(node)
def get_edge_attr(self, u, v):
"""
Returns the attribute for edge (u, v) or raises KeyError if
the edge is not in the graph.
"""
return self._nodes[u].nbrs[v]
def set_edge_attr(self, u, v, attr):
"""
Sets the attribute for edge (u, v) to attr or raises KeyError
if edge is not in the graph.
Must be overriden by subclasses
"""
raise NotImplementedError
def node_count(self):
"""
Returns the number of nodes in the graph.
"""
return len(self._nodes)
def edge_count(self):
"""
Returns the number of edges in the graph.
Must be overriden by subclasses.
"""
raise NotImplementedError
def add_node(self, node, attr = None):
"""
Add node to the graph with optional attribute attr. Does
nothing if node is already in the graph.
"""
if not self.has_node(node):
self._nodes[node] = Graph._nodetup(attr, {})
def add_edge(self, u, v, attr = None):
"""
Add edge (u, v) to the graph with optional attribute attr.
If nodes u or v are not in the graph, they will be added.
Must be overriden by subclasses.
"""
raise NotImplementedError
def remove_node(self, node):
"""
Remove node from the graph, if it exists. Raises KeyError if
node is not in the graph.
"""
self._nodes.pop(node)
for k, nk in self._nodes.iteritems():
nk.nbrs.pop(node, None)
def remove_edge(self, u, v):
"""
Remove edge from the graph, if it exists.
Must be overriden by subclasses.
"""
raise NotImplementedError
def has_node(self, node):
"""
Returns True if node is in the graph, False otherwise.
"""
return node in self._nodes
def has_edge(self, u, v):
"""
Returns True if edge (u, v) is in the graph, False otherwise.
"""
return (v in self._nodes[u].nbrs)
def dumps(self):
"""
Return a string representation of the graph that can
be used by loads to recreate the graph.
Must be overriden by subclass.
"""
raise NotImplementedError
def dump(self, f):
"""
Store a string representation to the file f that can be read
by load to recreate the graph.
"""
f.write(self.dumps())
def validate(self):
"""
Validates that the graph structure is consistent. Raises
UserWarning if inconsistent, does nothing otherwise.
Should be overriden by subclasses.
"""
raise UserWarning('unable to validate graph - no validate method')
class DiGraph(BaseGraph):
"""
Directed graph class that supports node and edge attributes.
"""
def __init__(self, graphrepr = None):
"""
Create a new DiGraph.
If the optional graphrepr argument is not provided the graph
will be empty. Otherwise, graphrepr will be used as the
internal representation and will be validated. The graphrepr
argument should primarily be used by load or loads.
"""
BaseGraph.__init__(self)
if graphrepr:
self._nodes = graphrepr
self.validate()
def __str__(self):
"""
Return a string representation of the graph.
"""
return 'DiGraph(' + self._repstr() + ')'
def edge_count(self):
"""
Returns the number of edges in the graph.
"""
edges = 0
for n in self._nodes:
edges += len(self._nodes[n].nbrs)
return edges
def set_edge_attr(self, u, v, attr):
"""
Sets the attribute for edge (u, v) to attr or raises KeyError
if edge is not in the graph.
"""
if self.has_node(u):
if v in self._nodes[u].nbrs:
self._nodes[u].nbrs[v] = attr
else:
raise KeyError(v)
else:
raise KeyError(u)
def add_edge(self, u, v, attr = None):
"""
Add edge (u, v) to the graph with optional attribute attr.
If nodes u or v are not in the graph, they will be added.
"""
if not self.has_node(u):
self.add_node(u)
if not self.has_node(v):
self.add_node(v)
self._nodes[u].nbrs[v] = attr
def remove_edge(self, u, v):
"""
Remove edge from the graph, if it exists.
"""
if self.has_node(u):
self._nodes[u].nbrs.pop(v, None)
def dumps(self):
"""
Return a string representation of the graph that can
be used by loads to recreate the graph.
"""
return 'DiGraph(' + self._reprepr() + ')'
def validate(self):
"""
Validates that the graph structure is consistent. If node a
is a neighbor of node b, then node a must be a node in the
graph. If this holds for all neighbors, then do nothing. If
not, raises a UserWarning.
"""
for n, nt in self._nodes.iteritems():
for nbr in nt.nbrs:
if nbr not in self._nodes:
# Missing node
msg = ('node ' + str(n) + ' has a neighbor (' +
str(nbr) + ') that is not a node in the graph')
raise UserWarning(msg)
class Graph(BaseGraph):
"""
Undirected graph class that supports node and edge attributes.
"""
def __init__(self, graphrepr = None):
"""
Create a new Graph.
If the optional graphrepr argument is not provided the graph
will be empty. Otherwise, graphrepr will be used as the
internal representation and will be validated. The graphrepr
argument should primarily be used by load or loads.
"""
BaseGraph.__init__(self)
if graphrepr:
self._nodes = graphrepr
self.validate()
def __str__(self):
"""
Return a string representation of the graph.
"""
return 'Graph(' + self._repstr() + ')'
def edge_count(self):
"""
Returns the number of edges in the graph.
"""
edges = 0
for n in self._nodes:
edges += len(self._nodes[n].nbrs)
return edges / 2
def set_edge_attr(self, u, v, attr):
"""
Sets the attribute for edge (u, v) to attr or raises KeyError
if edge is not in the graph.
"""
if v not in self._nodes[u].nbrs:
raise KeyError(v)
if u not in self._nodes[v].nbrs:
raise KeyError(u)
self._nodes[u].nbrs[v] = attr
self._nodes[v].nbrs[u] = attr
def add_edge(self, u, v, attr = None):
"""
Add edge (u, v) to the graph with optional attribute attr.
If nodes u or v are not in the graph, they will be added.
"""
if not self.has_node(u):
self.add_node(u)
if not self.has_node(v):
self.add_node(v)
self._nodes[u].nbrs[v] = attr
self._nodes[v].nbrs[u] = attr
def remove_edge(self, u, v):
"""
Remove edge from the graph, if it exists.
"""
if self.has_node(u) and self.has_node(v):
self._nodes[u].nbrs.pop(v, None)
self._nodes[v].nbrs.pop(u, None)
def dumps(self):
"""
Return a string representation of the graph that can
be used by loads to recreate the graph.
"""
return 'Graph(' + self._reprepr() + ')'
def validate(self):
"""
Validates that the graph structure is consistent. If node a
is a neighbor of node b, then node b must be a neighbor of
node a and they must both have the same attribute. If this
holds for all neighbors, then do nothing. If not, raises a
UserWarning.
"""
for n, nt in self._nodes.iteritems():
for nbr in nt.nbrs:
if nbr not in self._nodes:
# Missing node
msg = ('node ' + str(n) + ' has a neighbor (' +
str(nbr) + ') that is not a node in the graph')
raise UserWarning(msg)
elif n not in self._nodes[nbr].nbrs:
# Missing edge
msg = ('edge from ' + str(n) + ' to ' +
str(nbr) + ', but not from ' +
str(nbr) + ' to ' + str(n))
raise UserWarning(msg)
elif self._nodes[n].nbrs[nbr] != self._nodes[nbr].nbrs[n]:
# Mismatched attribute
msg = ('edge attributes for edge (' + str(n) +
', ' + str(nbr) + ') are mismatched: ' +
str(self._nodes[n].nbrs[nbr]) + ' and ' +
str(self._nodes[nbr].nbrs[n]))
raise UserWarning(msg)
```