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I have the following code that is the bottleneck in my Python code:

def get_payoff(self,  actual, predicted):
    if abs(actual - 1.0) < 1e-5:  # if actual == 1
        if predicted < 0.5:
            return self.fn_payoff * (0.5 - predicted)
        elif predicted > 0.5:
            return self.tp_payoff * (predicted - 0.5)
        else:
            return 0
    else:
        if predicted < 0.5:
            return self.tn_payoff * (0.5 - predicted)
        elif predicted > 0.5:
            return self.fp_payoff * (predicted - 0.5)
        else:
            return 0

def get_total_payoff(self):
    total_payoff = 0
    for target_element, prediction_element in zip(np.nditer(self.target), np.nditer(predictions)):
        total_payoff += self.get_payoff(target_element, prediction_element)

fn_payoff, tp_payoff, tn_payoff, and fp_payoff are all floats. self.target and self.predictions are both numpy ndarrays.

I assume there's some way to do replace the for loop in get_total_payoff with some kind of numpy vectorization, but I don't know how to handle the if/then statements to do the vectorization properly.

3
  • 1
    def float get_payoff() -- Er, is that a typo or are you using an obscure statically-typed variant of Python?
    – user395760
    Feb 13, 2014 at 21:54
  • Oops, I was converting the Cythonized version to python for the question and I forgot to remove that. I'll fix it Feb 13, 2014 at 21:57
  • Is predictions supposed to be a global variable? Feb 13, 2014 at 22:23

2 Answers 2

2

The key for vectorizing functions which use different expressions based on a condition is using np.choose. Also, in your case, predict-0.5 and 0.5-predict can be replaced by abs(predict-0.5), plus special handling of the case where predict==0.5 (I'm guessing the special handling is there for correct handling of NaN's).

import numpy as np

class A(object):
    def __init__(self):
        self.fn_payoff = 222.
        self.tn_payoff = 444.
        self.fp_payoff = 777.
        self.tp_payoff = 888.
        self.target = np.array([ 0.3, 1., 2. ])
        self.predictions = np.array([ 0.4, 0.5, 1.7 ])

    def get_payoff(self,  actual, predicted):
        if abs(actual - 1.0) < 1e-5:  # if actual == 1
            if predicted < 0.5:
                return self.fn_payoff * (0.5 - predicted)
            elif predicted > 0.5:
                return self.tp_payoff * (predicted - 0.5)
            else:
                return 0
        else:
            if predicted < 0.5:
                return self.tn_payoff * (0.5 - predicted)
            elif predicted > 0.5:
                return self.fp_payoff * (predicted - 0.5)
            else:
                return 0

    def get_total_payoff(self):
        total_payoff = 0
        for target_element, prediction_element in zip(np.nditer(self.target), np.nditer(self.predictions)):
            total_payoff += self.get_payoff(target_element, prediction_element)
        return total_payoff

    def get_total_payoff_VECTORIZED(self):
        actual_mask = np.abs(self.target - 1) < 1e-5
        predict_mask = self.predictions < 0.5
        payoff_n = np.choose(actual_mask, [ self.tn_payoff, self.fn_payoff ])
        payoff_p = np.choose(actual_mask, [ self.fp_payoff, self.tp_payoff ])
        payoff = np.choose(predict_mask, [ payoff_p, payoff_n ]) * abs(self.predictions-0.5)
        payoff[self.predictions==0.5] = 0
        return payoff.sum()

a = A()
print a.get_total_payoff()
=> 976.8
print a.get_total_payoff_VECTORIZED()
=> 976.8
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def _get_payoff(self, actual, predicted):
    pred_factor = numpy.abs(0.5 - predicted)
    payoff_selector = 2*numpy.isclose(actual, 1) + (predicted < 0.5)
    payoff = numpy.choose(payoff_selector,
                          [
                              self.fp_payoff,
                              self.tn_payoff,
                              self.tp_payoff,
                              self.fn_payoff,
                          ])
    return numpy.sum(payoff * pred_factor)

def get_total_payoff(self):
    return self._get_payoff(self.target, predictions)

We use numpy.choose to generate an array of payoff selections and multiply that with an array of absolute differences between 0.5 and the prediction values, then sum. numpy.isclose is used to test whether the actual values are close to 1. We can ignore the predicted == 0.5 case, since multiplying by numpy.abs(0.5 - predicted) gives the correct result of 0 anyway. If self.target and predictions are guaranteed to be 1D, numpy.dot is likely to perform better than separately multiplying and summing.

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  • 1
    You can only ignore the predicted==0.5 case if what you multiply by is not NaN. Otherwise, you get NaN, not 0.
    – shx2
    Feb 13, 2014 at 22:19
  • 1
    @shx2: We're multiplying by one of the 4 payoff factors, though. I doubt those are NaN. If they are, it's not clear whether the output should also have NaNs. Feb 13, 2014 at 22:22
  • 1
    I'm just pointing out that in that case your function differs from the original. Not clear that's what the OP wants.
    – shx2
    Feb 13, 2014 at 22:27

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