For the sake of completeness, the `in`

operator may be used as a boolean operator testing for attribute membership. It is hence usable in an `if..else`

statement (see below for the full documentation extract).

When using the `in`

operator, (e.g `obj in container`

) the interpreter first looks if `container`

has a `__contains__`

method. If it does not but if the `container`

defines the `__iter__`

method, python will then iterate on all values contained in the object and test for equality i.e. it will basically perform something like

```
for value in container:
if value == obj:
return True
return False
```

Finally, if neither methods are defined, the interpreter looks for the `__getitem__`

method to iterate over the container and would still test for equality of any value with `obj`

.
You may also look at the comparison operator documentation.

Now, in your case, the `range([start], stop[, step])`

function [documentation] actually returns a list (beware that this list does **not** hold the last element so `range(1, 5) == [1, 2, 3, 4]`

), which defines the `__contains__`

method:

```
>>> type(range(1, 10))
list
>>> hasattr(list, '__contains__')
True
>>> 4 in range(1, 10)
True
```

so this is perfectly authorized to write `x in range(1, 10)`

. As other answers point out, your problem is actually a type problem solved by casting the input data into an integer (as `"3" == 3`

is False).
However, if you solely intend to test if the input value is properly bounded, I would definitively recommend you to use comparison operator

```
>>> if 1 <= x < 10:
... print 'ok'
... else:
... print 'ko'
```

as it looks more readable *and* you are not constructing an obsolete list so you would minimize your memory footprint.

Note that to avoid the implicit construction of the list, you could use the `xrange`

function that returns an iterator rather than a list and that in this case, as values are evaluated lazily, `xrange`

does not define the `__contains__`

method but it defines the `__iter__`

method so everything would still work fine!

```
>>> type(xrange(1, 10))
xrange
>>> hasattr(xrange, '__contains__')
False
>>> hasattr(xrange, '__iter__')
True
>>> 4 in xrange(1, 10)
True
```

Finally, here is the extract from the python documentation about `in`

operator

The operators in and not in test for collection membership. x in s evaluates to true if x is a member of the collection s, and false otherwise. x not in s returns the negation of x in s. The collection membership test has traditionally been bound to sequences; an object is a member of a collection if the collection is a sequence and contains an element equal to that object. However, it make sense for many other object types to support membership tests without being a sequence. In particular, dictionaries (for keys) and sets support membership testing.

For the list and tuple types, x in y is true if and only if there exists an index i such that x == y[i] is true.

For the Unicode and string types, x in y is true if and only if x is a substring of y. An equivalent test is y.find(x) != -1. Note, x and y need not be the same type; consequently, u'ab' in 'abc' will return True. Empty strings are always considered to be a substring of any other string, so "" in "abc" will return True.

Changed in version 2.3: Previously, x was required to be a string of length 1.

For user-defined classes which define the `__contains__`

() method, x in y is true if and only if y.`__contains__`

(x) is true.

For user-defined classes which do not define `__contains__`

() but do define `__iter__`

(), x in y is true if some value z with x == z is produced while iterating over y. If an exception is raised during the iteration, it is as if in raised that exception.

Lastly, the old-style iteration protocol is tried: if a class defines `__getitem__`

(), x in y is true if and only if there is a non-negative integer index i such that x == y[i], and all lower integer indices do not raise IndexError exception. (If any other exception is raised, it is as if in raised that exception).

The operator not in is defined to have the inverse true value of in.

The operators is and is not test for object identity: x is y is true if and only if x and y are the same object. x is not y yields the inverse truth value. [7]

`range(1,5)`

does not include the number 5. – interjay Aug 27 '12 at 10:46