What are you describing is called **rejection sampling**, and is a bad idea. For example if you wanted only numbers `>0.999`

, it would take **1000 times longer** to generate them.

**Best way**

The correct way to do this is to use another sampling technique, such as using the inverse of the CDF (cumulative density function), and doing `[inverseCDF(random()) for _ in range(10)]`

. In your case, this would be, like GaretJax suggests, `[0.5+random()/2 for _ in range(10)]`

**Intent**

I think your intent was being able to further filter based on the entire expression of a list comprehension. In that case, you would put your iterable (here with parentheses rathern than [...] for laziness, though it doesn't matter) inside another comprehension:

```
[r for r in (random.random() for x in range(10)) if r>0.5]
```

For a better solution along these lines that can handle rejection, see the "Solution with list comprehensions only" section or eryksun's answer.

**Solution with generators**

(see below for a list-comprehension only solution)

You can do this for any linear range. If your rejection function is arbitrarily complex however, a general way to do rejection sampling would be as follows. (Again, a very bad idea unless you know what you're doing and efficiency doesn't matter.)

```
from random import random
from itertools import *
def randoms():
while True:
yield random()
def rejectionSample(pred, n):
return islice(filter(pred, randoms()), n)
```

Example:

```
>>> print( list(rejectionSample(lambda x:x>0.5)) )
[0.6656564857979361, 0.9850389778418555, 0.9607471536139308, 0.9191328900300356, 0.810783093197139]
```

You could also do something like:

```
def rejectionSample(pred, n):
count = 0
while count<n:
r = random()
if pred(r):
yield r
count += 1
```

**Solution with list comprehensions only**

However since you want to use list comprehensions *only*, this means **the expression-part of your comprehension cannot fail**, so you have to somehow embed a while loop in the comprehension. This is impossible to do with a single lambda function alone, but we can pull it off as long as we have some recursive/loopy primitive, for example...

```
[next(filter(pred,randoms())) for _ in range(10)]
```

(If you really wanted a one-liner list comprehension, `randoms()`

can be rewritten as `(random() for _ in count())`

.) Again, this is unnecessary if you easily find the analytic inverse cumulative distribution function for your particular distribution.

**edit**: I take that back... it... **is possible**... with just lambdas...

**DEAR GOD HAVE MERCY WHAT HORRORS HAVE I UNLEASHED UPON THE WORLD NOOOOOO**

```
[
(lambda f:f(f,random()))(lambda self,r:r if r>0.5 else self(self,random()))
for _ in range(10)
]
```

`[random.random() + 0.5 for _ in range(10)]`

I don't think that's what you were asking, though! :) – Joe Kington Aug 1 '11 at 4:40