This is a generator expression. To get it to work in the standalone case, use braces:

```
y = (x for x in range(10))
```

and y becomes a generator. You can iterate over generators, so it works where an iterable is expected, such as the `sum`

function.

**Usage examples and pitfalls:**

```
>>> y = (x for x in range(10))
>>> y
<generator object <genexpr> at 0x0000000001E15A20>
>>> sum(y)
45
```

Be careful when keeping generators around, you can only go through them once. So after the above, if you try to use `sum`

again, this will happen:

```
>>> sum(y)
0
```

So if you pass a generator where actually a list or a set or something similar is expected, you have to be careful. If the function or class stores the argument and tries to iterate over it multiple times, you will run into problems. For example consider this:

```
def foo(numbers):
s = sum(numbers)
p = reduce(lambda x,y: x*y, numbers, 1)
print "The sum is:", s, "and the product:", p
```

it will fail if you hand it a generator:

```
>>> foo(x for x in range(1, 10))
The sum is: 45 and the product: 1
```

You can easily get a list from the values a generator produces:

```
>>> y = (x for x in range(10))
>>> list(y)
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
```

You can use this to fix the previous example:

```
>>> foo(list(x for x in range(1, 10)))
The sum is: 45 and the product: 362880
```

However keep in mind that if you build a list from a generator, you will need to store every value. This might use a lot more memory in situations where you have lots of items.

**Why use a generator in your situation?**

The much lower memory consumption is the reason why `sum(generator expression)`

is better than `sum(list)`

: The generator version only has to store a single value, while the list-variant has to store N values. Therefore you should always use a generator where you don't risk side-effects.