### The `range`

objects are special:

Python will compare `range`

objects as *Sequences*. What that essentially means is that *the comparison doesn't evaluate ***how** they represent a given sequence but rather **what** they represent.

The fact that the `start`

, `stop`

and `step`

parameters are completely different plays no difference here because *they all represent an empty list when expanded*:

For example, the first `range`

object:

```
list(range(0)) # []
```

and the second `range`

object:

```
list(range(2, 2, 2)) # []
```

*Both represent an empty list* and since two empty lists compare equal (`True`

) so will the `range`

objects that *represent* them.

As a result, you can have completely different *looking* `range`

objects; if they represent the same sequence they will *compare* equal:

```
range(1, 5, 100) == range(1, 30, 100)
```

Both represent a list with a single element `[1]`

so these two will also compare equal.

### No, `range`

objects are *really* special:

Do note, though, that even though the comparison doesn't evaluate *how* they represent a sequence the result of comparing *can be achieved* using **solely** the values of `start`

, `step`

along with the `len`

of the `range`

objects; this has very interesting implications with the speed of comparisons:

```
r0 = range(1, 1000000)
r1 = range(1, 1000000)
l0 = list(r0)
l1 = list(r1)
```

Ranges compares super fast:

```
%timeit r0 == r1
The slowest run took 28.82 times longer than the fastest. This could mean that an intermediate result is being cached
10000000 loops, best of 3: 160 ns per loop
```

on the other hand, the lists..

```
%timeit l0 == l1
10 loops, best of 3: 27.8 ms per loop
```

Yeah..

As **@SuperBiasedMan** noted, this only applies to the range objects in Python 3. Python 2 `range()`

is a plain ol' function that returns a list while the `2.x`

`xrange`

object doesn't have the comparing capabilies (*and not only these..*) that `range`

objects have in Python 3.

Look at **@ajcr's answer** for quotes directly from the source code on Python 3 `range`

objects. It's documented in there what the comparison between two different ranges actually entails: Simple quick operations. The `range_equals`

function is utilized in the `range_richcompare`

function for `EQ`

and `NE`

cases and assigned to the `tp_richcompare`

slot for `PyRange_Type`

types.

I believe the implementation of `range_equals`

is pretty readable (because it is nice as simple) to add here:

```
/* r0 and r1 are pointers to rangeobjects */
/* Check if pointers point to same object, example:
>>> r1 = r2 = range(0, 10)
>>> r1 == r2
obviously returns True. */
if (r0 == r1)
return 1;
/* Compare the length of the ranges, if they are equal
the checks continue. If they are not, False is returned. */
cmp_result = PyObject_RichCompareBool(r0->length, r1->length, Py_EQ);
/* Return False or error to the caller
>>> range(0, 10) == range(0, 10, 2)
fails here */
if (cmp_result != 1)
return cmp_result;
/* See if the range has a lenght (non-empty). If the length is 0
then due to to previous check, the length of the other range is
equal to 0. They are equal. */
cmp_result = PyObject_Not(r0->length);
/* Return True or error to the caller.
>>> range(0) == range(2, 2, 2) # True
(True) gets caught here. Lengths are both zero. */
if (cmp_result != 0)
return cmp_result;
/* Compare the start values for the ranges, if they don't match
then we're not dealing with equal ranges. */
cmp_result = PyObject_RichCompareBool(r0->start, r1->start, Py_EQ);
/* Return False or error to the caller.
lens are equal, this checks their starting values
>>> range(0, 10) == range(10, 20) # False
Lengths are equal and non-zero, steps don't match.*/
if (cmp_result != 1)
return cmp_result;
/* Check if the length is equal to 1.
If start is the same and length is 1, they represent the same sequence:
>>> range(0, 10, 10) == range(0, 20, 20) # True */
one = PyLong_FromLong(1);
if (!one)
return -1;
cmp_result = PyObject_RichCompareBool(r0->length, one, Py_EQ);
Py_DECREF(one);
/* Return True or error to the caller. */
if (cmp_result != 0)
return cmp_result;
/* Finally, just compare their steps */
return PyObject_RichCompareBool(r0->step, r1->step, Py_EQ);
```

I've also scattered some of my own comments here; look at *@ajcr's answer* for the Python equivalent.

`is`

and`==`

.