A `sum`

solution adding up `True`

valuesis correct, probably more efficient than an explicit loop, and definitely the most concise:

```
if sum(i % 2 == 0 for i in lst) == n:
```

However, it relies on understanding that in an integer context like addition, `True`

counts as `1`

and `False`

as `0`

. You may not want to count on that. In which case you can rewrite it (squiguy's answer):

```
if sum(1 for i in lst if i % 2 == 0) == n:
```

But you might want to factor this out into a function:

```
def count_matches(predicate, iterable):
return sum(predicate(i) for i in iterable)
```

And at that point, it might arguably be more readable to `filter`

the list and count the length of the resulting filtered iterable instead:

```
def ilen(iterable):
return sum(1 for _ in iterable)
def count_matches(predicate, iterable):
return ilen(filter(predicate, iterable))
```

However, the down side of all of these variations—as with any use of `map`

or `filter`

is that your predicate has to be a *function*, not just an expression. That's fine when you just wanted to check that `some_function(x)`

returns True, but when you want to check `x % 2 == 0`

, you have to go to the extra step of wrapping it in a function, like this:

```
if count_matches(lambda x: x %2 == 0, lst) == n
```

… at which point I think you lose more readability than you gain.

Since you asked for the fastest—even though that's probably misguided, since I'm sure any of these solutions are more than fast enough for almost any app, and this is unlikely to be a hotspot anyway—here are some tests with 64-bit CPython 3.3.2 on my computer with a length of 250:

```
32.9 µs: sum(not x % 2 for x in lst)
33.1 µs: i=0\nfor x in lst: if not x % 2: i += 1\n
34.1 µs: sum(1 for x in lst if not x % 2)
34.7 µs: i=0\nfor x in lst: if x % 2 == 0: i += 1\n
35.3 µs: sum(x % 2 == 0 for x in lst)
37.3 µs: sum(1 for x in lst if x % 2 == 0)
52.5 µs: ilen(filter(lambda x: not x % 2, lst))
56.7 µs: ilen(filter(lambda x: x % 2 == 0, lst))
```

So, as it turns out, at least in 64-bit CPython 3.3.2 whether you use an explicit loop, sum up False and True, or sum up 1s if True makes very little difference; using `not`

instead of `== 0`

makes a bigger difference in some cases than the others; but even the worst of these is only 12% worse than the best.

So I would use whichever one you find most readable. And, if the slowest one isn't fast enough, the fastest one probably isn't either, which means you will probably need to rearrange your app to use NumPy, run your app in PyPy instead of CPython, write custom Cython or C code, or do something else a lot more drastic than just reorganizing this trivial algorithm.

For comparison, here's some NumPy implementations (assuming `lst`

is a `np.ndarray`

rather than a `list`

):

```
6.4 µs: len(lst) - np.count_nonzero(lst % 2)
8.5 µs: np.count_nonzero(lst % 2 == 0)
17.5 µs: np.sum(lst % 2 == 0)
```

Even the most obvious translation to NumPy is almost twice as fast; with a bit of work you can get it 3x faster still.

And here's the result of running the exact same code in PyPy (3.2.3/2.1b1) instead of CPython:

```
14.6 µs: sum(not x % 2 for x in lst)
```

More than twice as fast with no change in the code at all.