Other answers have pointed out that the result of `random()`

is always *strictly* less than `1.0`

; however, that's only half the story.

If you're computing `randrange(n)`

as `int(random() * n)`

, you *also* need to know that for any Python float `x`

satisfying `0.0 <= x < 1.0`

, and any positive integer `n`

, it's true that `0.0 <= x * n < n`

, so that `int(x * n)`

is strictly less than `n`

.

There are two things that could go wrong here: first, when we compute `x * n`

, `n`

is implicitly converted to a float. For large enough `n`

, that conversion might alter the value. But if you look at the Python source, you'll see that it only uses the `int(random() * n)`

method for `n`

smaller than `2**53`

(here and below I'm assuming that the platform uses IEEE 754 doubles), which is the range where the conversion of `n`

to a float is guaranteed not to lose information (because `n`

can be represented exactly as a float).

The second thing that could go wrong is that the result of the multiplication `x * n`

(which is now being performed as a product of floats, remember) probably won't be exactly representable, so there will be some rounding involved. If `x`

is close enough to `1.0`

, it's conceivable that the rounding will round the result up to `n`

itself.

To see that this can't happen, we only need to consider the largest possible value for `x`

, which is (on almost all machines that Python runs on) `1 - 2**-53`

. So we need to show that `(1 - 2**-53) * n < n`

for our positive integer `n`

, since it'll always be true that `random() * n <= (1 - 2**-53) * n`

.

**Proof** (Sketch) Let `k`

be the unique integer `k`

such that `2**(k-1) < n <= 2**k`

. Then the next float down from `n`

is `n - 2**(k-53)`

. We need to show that `n*(1-2**53)`

(i.e., the actual, unrounded, value of the product) is closer to `n - 2**(k-53)`

than to `n`

, so that it'll always be rounded down. But a little arithmetic shows that the distance from `n*(1-2**-53)`

to `n`

is `2**-53 * n`

, while the distance from `n*(1-2**-53)`

to `n - 2**(k-53)`

is `(2**k - n) * 2**-53`

. But `2**k - n < n`

(because we chose `k`

so that `2**(k-1) < n`

), so the product *is* closer to `n - 2**(k-53)`

, so it *will* get rounded down (assuming, that is, that the platform is doing some form of round-to-nearest).

So we're safe. Phew!

`int(random.random() * n)`

still isn't a perfect way to generate integers that are uniformly distributed in`range(n)`

; there's a bias that's insignificant for small`n`

but becomes significant as`n`

becomes large. I've opened a Python bug for this at bugs.python.org/issue9025 – Mark Dickinson Jun 22 '10 at 8:45