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I want to construct a value in a list comprehension, but also filter on that value. For example:

[expensive_function(x) for x in generator where expensive_function(x) < 5]

I want to avoid calling expensive_function twice per iteration.

The generator may return an infinite series, and list comprehensions aren't lazily evaluated. So this wouldn't work:

[y in [expensive_function(x) for x in generator where expensive_function(x)] where y < 5]

I could write this another way, but it feels right for a list comprehension and I'm sure this is a common usage pattern (possible or not!).

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Are any of the answers worthy of being accepted? If not, what information are you still looking for? –  Ethan Furman Mar 9 '12 at 23:23
    
Sorry forgot to mark this one. Thank you for your answer! –  Joe Mar 11 '12 at 2:28
    
No problem. Was hoping you just needed a reminder. :) –  Ethan Furman Mar 11 '12 at 5:02
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4 Answers

up vote 10 down vote accepted

If generator may be infinite, you do not want to use a list comprehension. And not everything has to be a one-liner.

def filtered_gen(gen):
    for item in gen:
        result = expensive_function(item)
        if result < 5:
            yield result
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2  
Should the last two occurrences of item be replaced by result? –  Chris Jan 6 '12 at 17:10
    
@Chris: Yes, thanks. –  Ethan Furman Jan 6 '12 at 18:22
    
+1 to this. You can use itertools and generator expressions, but this is much easier to understand. –  user97370 Jan 6 '12 at 20:14
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you should make 2 list comprehension:

ys_all = (expensive(x) for x in xs)
ys_filtered = (y for y in ys_all if y <5)

or

from itertools import imap, ifilter
ys = ifilter(lambda y : y < 5, imap(expensive, xs))
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Nope. Not if xs is infinite. Sadly Python doesn't have Haskell list comprehensions. Something, somewhere, would blow up. –  Joe Jan 6 '12 at 17:17
    
updated answer with iterators –  Simon Jan 6 '12 at 17:59
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I'm going to answer the part of the question about how to capture intermediate results in a list comprehension for use in a condition, and ignore the question of a list comprehension built from an infinite generator (which obviously isn't going to work), just in case anyone looking for an answer to the question in the title comes here.

So, you have a list comprehension like this:

[expensive_function(x) for x in xrange(5) if expensive_function(x) % 2 == 0]

And you want to avoid calculating expensive_function twice when it passes your filter. Languages with more expressive comprehension syntax (Scala, Haskell, etc) allow you to simply assign names to expressions calculated from comprehension variables, which lets you do things like the following:

# NOT REAL PYTHON
[result for x in xrange(5) for result = expensive_function(x) if result % 2 == 0]

But you can easily emulate this by turning the assignment result = expensive_function(x) into another for iteration over a sequence of one element:

[result for x in xrange(5) for result in (expensive_function(x),) if result % 2 == 0]

And the proof:

>>> def expensive_function(x):
        print 'expensive_function({})'.format(x)
        return x + 10
>>> [expensive_function(x) for x in xrange(5) if expensive_function(x) % 2 == 0]
expensive_function(0)
expensive_function(0)
expensive_function(1)
expensive_function(2)
expensive_function(2)
expensive_function(3)
expensive_function(4)
expensive_function(4)
[10, 12, 14]
>>> [result for x in xrange(5) for result in (expensive_function(x),) if result % 2 == 0]
expensive_function(0)
expensive_function(1)
expensive_function(2)
expensive_function(3)
expensive_function(4)
[10, 12, 14]
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Warning This is a bit convoluted but does the job. I will use an example to explain it.

Let say expensive_function = math.sin

infinite generator = collections.count(0.1,0.1)

then

[z for z in (y if y < 5 else next(iter([])) 
     for y in (math.sin(x) for x in itertools.count(0.1,0.1)))]

is

[0.09983341664682815,
 0.19866933079506122,
 0.2955202066613396,
 0.3894183423086505,
 0.479425538604203]

So your problem boils down to

[z for z in (y if y < 0.5 else next(iter([])) \
         for y in (expensive_function(x) for x in generator))]

The trick is to force a StopIteration from a generator and nothing elegant than next(iter([]))

Here expensive_function is only called once per iteration.

Extend the Infinite Generator with a Finite Generator, with the Stop Condition. As the generator won't allow raise StopIteration, we opt for a convoluted way i.e. next(iter([])) And now you have a Finite Generator, which can be used in a List Comprehension

As OP was concerned with the application of the above method for a non-monotonic function here is a fictitious non-monotonic function

Expensive Non-Monotonic Function f(x) = random.randint(1,100)*x

Stop Condition = < 7

[z for z in (y if y < 7 else next(iter([])) for y in 
      (random.randint(1,10)*x for x in itertools.count(0.1,0.1)))]

[0.9,
 0.6000000000000001,
 1.8000000000000003,
 4.0,
 0.5,
 6.0,
 4.8999999999999995,
 3.1999999999999997,
 3.5999999999999996,
 5.999999999999999]

Btw: sin in true sense is non-monotonic over the entire range (0,2pi)

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Crazy! This is subtly different, because sin is a non-monotonic function (I didn't say that expensive_function is monotonic, but it is!) and this halts the first time the condition is not true, not continuing for all conditions where the condition is true. That said, if it were non-monotonic, this would result in an infinite evaluation... –  Joe Jan 6 '12 at 17:18
    
@Joe, This will work even for non-monotonic function. See my update –  Abhijit Jan 6 '12 at 17:30
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