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Let's assume the following given class definition:

class Numeric(object):
  def __init__(self, signal):
    self.signal = signal

Now, with the requirement that Numeric doesn't inherit from numpy.ndarray, how do I have to extend that definition that Numeric behaves like a numpy.ndarray?

edit: signal should be a np.ndarray (or similar, like quantities.Quantity). I have the following scenarious in mind:

import numpy as np
import quantities as pq

a = Numeric(pq.Quantity([1,2,3], 'mV'))
b = Numeric(pq.Quantity([1,3,5], 's'))
c = Numeric(np.array([10,20,30]))

a = Numeric(np.array([1,2,3]))
b = Numeric(np.array([1,3,5]))
a * c
a * b
a * np.array([3,4,5])


import matplotlib.pyplot as plt
share|improve this question
Where does this requirement come from? – wim Feb 29 '12 at 12:24
Is there any particular bit of ndarray's behaviour that you want? It's quite a big thing. – Thomas K Feb 29 '12 at 12:53
You'll never get full ndarray behavior without subclassing, since some Numpy operations like asarray behave differently depending on whether they get an ndarray instance or something else. – larsmans Feb 29 '12 at 13:00
The requirement comes from SQLAlchemy when I want to map the object to a table. – Philipp der Rautenberg Feb 29 '12 at 13:08
I would like to use arithmetic functions and things like plot(Numeric(np.array([1,2,3])). – Philipp der Rautenberg Feb 29 '12 at 13:14

With a decorator for adapting numpy-functions and an implementation of __array__ within Numeric I can solve most problems:

def adapt_signal_functions(cls):
  def generateAdjustedFunction(functionName):
    print functionName
    def foo(self, *args, **kwargs):
      function = getattr(self.signal.__class__, functionName)
      return function(self.signal, *args, **kwargs)
    return foo
  functionNames = [
  for functionName in functionNames:
    foo = generateAdjustedFunction(functionName)
    setattr(cls, functionName, foo)
  return cls

class Numeric(object):
  def __init__(self, signal):
    self.signal = signal

  def adapt_quantity(self):
    if hasattr(self.signal, '_dimensionality'):
      self._dimensionality = self.signal._dimensionality
      self.dimensionality = self.signal.dimensionality

  def __array__(self):
    return self.signal

With that I can do:

import numpy as np
import quantities as pq

a = Numeric(pq.Quantity([1,2,3], 'mV'))
b = Numeric(pq.Quantity([1,3,5], 's'))
c = Numeric(np.array([10,20,30]))
n =  np.array([1,2,3])

a * a
a * c
a * n

print type(a * n) == type(a.signal *  n)
# >>> True
print type(a * c) == type(a.signal *  c.signal)
# >>> True

Return types correspond to the equivalent return type of Numeric.signal.

One problem remains:

print type(n * a) == type(n * a.signal)
# >>> False

Any ideas, how to fix that?

share|improve this answer
What is "quantities"? Is that something defined in SQLAlchemy? Or something you defined yourself? (Or something else?) – Edward Loper Feb 29 '12 at 17:02
@EdwardLoper - I'd assume it's this unit conversion library: – Joe Kington Feb 29 '12 at 17:43
Exactly, and pq.Quantity inherits from numpy.ndarray. – Philipp der Rautenberg Mar 1 '12 at 19:13

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