No iterator is created here, and no iteration occurs. The `range`

object is implemented such that Python computes the value of `R[5]`

on-demand in constant time.^{1}

If the index `i`

is not negative, the computation boils down to:

```
i * step + start
```

So in the case of your code `R[5]`

, this would be `5*1 + 1`

which is 6.

If the index `i`

is negative, the length of `R`

is added to `i`

first, and then the value is computed as before:

```
(i + len(R)) * step + start
```

### Python-internals

When you write `R[5]`

, this Python syntax is eventually translated into a call to `PyObject_GetItem`

, which inspects the object `R`

to see how it should proceed to find the item at index 5.

`PyObject_GetItem`

first checks the `tp_as_mapping`

slot of the `range`

type. This is not null; it holds a reference to a struct called `range_as_mapping`

. `PyObject_GetItem`

then checks to see what is in the `mp_subscript`

field of this struct:

```
static PyMappingMethods range_as_mapping = {
(lenfunc)range_length, /* mp_length */
(binaryfunc)range_subscript, /* mp_subscript */
(objobjargproc)0, /* mp_ass_subscript */
};
```

As you can see in the snippet above, it finds the `range_subscript`

function occupying the `mp_subscript`

field.^{2}

Now `range_subscript`

inspects the arguments it was passed (`R`

and `5`

) to decide if a single index or a slice was requested. The integer `5`

means that just a single index is needed and so the function delegates the computation of the value to `compute_range_item`

. This function performs the computation to return the integer 6 as outlined in the first part of this answer.

^{1} I have assumed you are using CPython: other Python implementations may implement the `range`

object differently.

^{2} If you were to call `len(R)`

, you can see the internal function in `mp_length`

that is called to compute the length of `R`

(cf. Why is "1000000000000000 in range(1000000000000001)" so fast in Python 3?).