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I just invented a stupid little helper function:

def has_one(seq, predicate=bool):
    """Return whether there is exactly one item in `seq` that matches
    `predicate`, with a minimum of evaluation (short-circuit).
    """
    iterator = (item for item in seq if predicate(item))
    try:
        iterator.next()
    except StopIteration: # No items match predicate.
        return False
    try:
        iterator.next()
    except StopIteration: # Exactly one item matches predicate.
        return True
    return False # More than one item matches the predicate.

Because the most readable/idiomatic inline thing I could come up with was:

[predicate(item) for item in seq].count(True) == 1

... which is fine in my case because I know seq is small, but it just feels weird. Is there an idiom I’m forgetting here that prevents me from having to break out this helper?

Clarification

Looking back on it, this was kind of a crappily posed question, though we got some excellent answers! I was looking for either:

  • An obvious and readable inline idiom or stdlib function, eager evaluation being acceptable in this case.
  • A more obvious and readable helper function -- since it's breaking out a whole other function, only the minimum amount of evaluation seems acceptable.

@Stephan202 came up with a really cool idiom for the helper function and @Martin v. Löwis came up with a more simple inline idiom under the assumption that the predicate returns a bool. Thanks @ everybody for your help!

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1  
There's no question here. Or, if there is a question, it's well hidden. –  S.Lott Oct 17 '09 at 22:51
1  
@S.Lott: "Is there an idiom I’m forgetting here that prevents me from having to break out this helper?" –  Martin v. Löwis Oct 17 '09 at 22:55
    
In any case you have look at each item if there is zero or one match. Consider using something like this to see if there is exactly one even prime number. –  gnibbler Oct 17 '09 at 23:13
    
How could someone not like iterators? –  Stephan202 Oct 17 '09 at 23:32

8 Answers 8

up vote 2 down vote accepted

Not sure whether it is any better than the versions you proposed, however...

If predicate is guaranteed to return True/False only, then

sum(map(predicate, seq)) == 1

will do (although it won't stop at the second element)

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1  
i think stopping execution at the second item is the whole point of this exercise –  SilentGhost Oct 17 '09 at 23:03
    
@SilentGhost: I'm unsure. The version that he posted with the list comprehension doesn't; he just says it feels "weird" (for unspecified reasons). –  Martin v. Löwis Oct 17 '09 at 23:27
    
I like this better than the question's .count(True) for the inline idiom. The corresponding generator expression is uglier in this particular case, as sum(1 for item in seq if predicate(item)), so I think map is the way to go. Technically, though, the genexp doesn't rely on the predicate returning a bool. –  cdleary Oct 17 '09 at 23:49

How about calling any twice, on an iterator (Python 2.x and 3.x compatible)?

>>> def has_one(seq, predicate=bool):
...     seq = (predicate(e) for e in seq)
...     return any(seq) and not any(seq)
... 
>>> has_one([])
False
>>> has_one([1])
True
>>> has_one([0])
False
>>> has_one([1, 2])
False

any will take at most one element which evaluates to True from the iterator. If it succeeds the first time and fails the second time, then only one element matches the predicate.

Edit: I see Robert Rossney suggests a generalized version, which checks whether exactly n elements match the predicate. Let me join in on the fun, using all:

>>> def has_n(seq, n, predicate=bool):
...     seq = (predicate(e) for e in seq)
...     return all(any(seq) for _ in range(n)) and not any(seq)
... 
>>> has_n(range(0), 3)
False
>>> has_n(range(3), 3)
False
>>> has_n(range(4), 3)
True
>>> has_n(range(5), 3)
False
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I like it, another clever thing to do with iterators. –  Jochen Ritzel Oct 17 '09 at 23:45
1  
for python2 just use itertools.imap instead of map –  gnibbler Oct 17 '09 at 23:50
    
even better is seq = (x for x in seq if predicate(x)) since the 2.x filter is eager. –  Jochen Ritzel Oct 17 '09 at 23:52
    
@THC4K: yes, but we need a map, not a filter. Updated the answer (no more explicit map). –  Stephan202 Oct 18 '09 at 0:01
    
I really like this, but it would be nice if the n parameter had a default of 1 IMHO. –  Chris Lutz Oct 18 '09 at 0:33

Perhaps something like this is more to your taste?

def has_one(seq,predicate=bool):
    nwanted=1
    n=0
    for item in seq:
        if predicate(item):
            n+=1
            if n>nwanted:
                return False

    return n==nwanted

This is rather like the list comprehension example, but requires only one pass over one sequence. Compared to the second has_one function, and like the list comprehension code, it generalizes more easily to other counts. I've demonstrated this (hopefully without error...) by adding in a variable for the number of items wanted.

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I liked Stephan202's answer, but I like this one a little more, even though it's two lines instead of one. I like it because it's just as crazy but a tiny bit more explicit about how its craziness works:

def has_one(seq):
    g = (x for x in seq)
    return any(g) and not any(g)

Edit:

Here's a more generalized version that supports a predicate:

def has_exactly(seq, count, predicate = bool):
    g = (predicate(x) for x in seq)
    while(count > 0):
        if not any(g):
            return False
        count -= 1
    if count == 0:
        return not any(g)
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It's clever, but I think that's probably a bad thing. I wouldn't blame people for looking at it concluding it never returns true. –  cdleary Oct 17 '09 at 23:43
1  
I like this one too, but it does not allow a predicate to be passed. Anyway, given that, how about g = iter(seq)? –  Stephan202 Oct 17 '09 at 23:46
    
@cdleary, isn't that part of being an idiom in this case? –  gnibbler Oct 17 '09 at 23:49
    
@gnibbler: You could probably make a case for it, but I don't particularly like idioms that seem to violate fundamental laws of logic. (Law of the excluded middle is slightly more universal than Python ;-) –  cdleary Oct 17 '09 at 23:53
    
I'd certainly add a comment explaining what it's doing in production code. –  Robert Rossney Oct 17 '09 at 23:56

How about ...

import functools
import operator

def exactly_one(seq):
    """
    Handy for ensuring that exactly one of a bunch of options has been set.
    >>> exactly_one((3, None, 'frotz', None))
    False
    >>> exactly_one((None, None, 'frotz', None))
    True
    """
    return 1 == functools.reduce(operator.__add__, [1 for x in seq if x])
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3  
functools.reduce(operator.__add__, ...) is what sum is for! –  cdleary Oct 23 '09 at 0:15
    
+1: for the exactly_one() name. sum(1 for x in seq if x) == 1 –  J.F. Sebastian Nov 24 '09 at 21:11

Look, Ma! No rtfm("itertools"), no dependency on predicate() returning a boolean, minimum evaluation, just works!

Python 1.5.2 (#0, Apr 13 1999, 10:51:12) [MSC 32 bit (Intel)] on win32
Copyright 1991-1995 Stichting Mathematisch Centrum, Amsterdam
>>> def count_in_bounds(seq, predicate=lambda x: x, low=1, high=1):
...     count = 0
...     for item in seq:
...         if predicate(item):
...             count = count + 1
...             if count > high:
...                 return 0
...     return count >= low
...
>>> seq1 = [0, 0, 1, 0, 1, 0, 1, 0, 0, 0]
>>> count_in_bounds(seq1)
0
>>> count_in_bounds(seq1, low=3, high=3)
1
>>> count_in_bounds(seq1, low=3, high=4)
1
>>> count_in_bounds(seq1, low=4, high=4)
0
>>> count_in_bounds(seq1, low=0, high=3)
1
>>> count_in_bounds(seq1, low=3, high=3)
1
>>>
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Here's modified @Stephan202's answer:

from itertools import imap, repeat

def exactly_n_is_true(iterable, n, predicate=None):
    it = iter(iterable) if predicate is None else imap(predicate, iterable)
    return all(any(it) for _ in repeat(None, n)) and not any(it)

Differences:

  1. predicate() is None by default. The meaning is the same as for built-in filter() and stdlib's itertools.ifilter() functions.

  2. More explicit function and parameters names (this is subjective).

  3. repeat() allows large n to be used.

Example:

if exactly_n_is_true(seq, 1, predicate):
   # predicate() is true for exactly one item from the seq
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This and this straightforward counting-loop solutions are definitely clearest.

For the sport of it, here is a variation on the any(g) and not any(g) theme that looks less magic on the surface - but it's actually similarly fragile when one comes to debug/modify it (you can't exchange the order, you have to understand how the short-circuiting and hands off a single iterator between two short-circuiting consumers...).

def cumulative_sums(values):
    s = 0
    for v in values:
        s += v
        yield s

def count_in_bounds(iterable, start=1, stop=2):
    counter = cumulative_sums(bool(x) for x in iterable)
    return (start in counter) and (stop not in counter)

It's trivial to also take a predicate instead of bool but I think it's better to follow any() and all() in leaving that to the caller - it's easy to pass a generator expression if needed.

Taking arbitrary [start, stop) is a nice bonus, but it's not as generic as I'd like. It's tempting to pass stop=None to emulate e.g. any(), which works, but always consumes all input; the proper emulation is kinda awkward:

def any(iterable):
  return not count_in_bounds(iterable, 0, 1)

def all(iterable):
  return count_in_bounds((not x for x in iterable), 0, 1)

Taking a variable number of bounds and specifying which should return True/False would get out of hand.
Perhaps a simple saturating counter is the best primitive:

def count_true(iterable, stop_at=float('inf')):
    c = 0
    for x in iterable:
        c += bool(x)
        if c >= stop_at:
            break
    return c

def any(iterable):
    return count_true(iterable, 1) >= 1

def exactly_one(iterable):
    return count_true(iterable, 2) == 1

def weird(iterable):
    return count_true(iterable, 10) in {2, 3, 5, 7}

all() still requires negating the inputs, or a matching count_false() helper.

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