def AsArea(self):
'''! \brief Return the area which is the union of all infrastructure's footprint.
'''
out = []
for i in self.Instrastructures():
out.extend(i.vertices())
if out:
a = base_polygon(geometry_rubberband().Solve(out))
b = a.Centroid()
return position_descriptor(b.x, b.y, a)
else:
return None
def AsArea(self):
'''! \brief Return the area which is the union of all infrastructure's footprint.
'''
out = []
for i in self.Instrastructures():
out.extend(i.vertices())
if out:
a = base_polygon(geometry_rubberband().Solve(out))
b = a.Centroid()
return position_descriptor(b.x, b.y, a)
else:
return None
def EchelonFootprint(self, force= False):
'''! \brief return the footprint for the entire echelon.
If there is no echelon, return the ordinary footprint.
If there is no Echelon Footprint, but an echelon, compute it recursively.
To get the percieved footprint, ask agent_CO.SolveFootprint()
'''
# Echelon Test
if self.Echelon() and self.Subordinates():
if self.has_key('Echelon Footprint') and not force:
return self['Echelon Footprint']
else:
V = self.Footprint().vertices()
for i in self.Subordinates():
V += i.EchelonFootprint(force).vertices()
self['Echelon Footprint'] = geometry_rubberband().Solve(V)
return self['Echelon Footprint']
return self.Footprint()
def EchelonFootprint(self, force=False):
"""! \brief return the footprint for the entire echelon.
If there is no echelon, return the ordinary footprint.
If there is no Echelon Footprint, but an echelon, compute it recursively.
To get the percieved footprint, ask agent_CO.SolveFootprint()
"""
# Echelon Test
if self.Echelon() and self.Subordinates():
if self.has_key("Echelon Footprint") and not force:
return self["Echelon Footprint"]
else:
V = self.Footprint().vertices()
for i in self.Subordinates():
V += i.EchelonFootprint(force).vertices()
self["Echelon Footprint"] = geometry_rubberband().Solve(V)
return self["Echelon Footprint"]
return self.Footprint()
