Some more typo correction.
Lists and Tuples
================
Lists
-----
Python provides an intuitive way to represent a group items, called *Lists*. The
items of a *List* are called its elements. Unlike C/C++, elements can be of any
type. A *List* is represented as a list of comma-sepated elements with square
brackets around them::
>>> a = [10, 'Python programming', 20.3523, 23, 3534534L]
>>> a
[10, 'Python programming', 20.3523, 23, 3534534L]
Common List Operations
~~~~~~~~~~~~~~~~~~~~~~
The following are some of the most commonly used operations on *Lists*.
~~~~~~~~
Indexing
~~~~~~~~
Individual elements of a *List* can be accessed using an index to the element.
The indices start at 0. One can also access the elements of the *List* in reverse
using negative indices.::
>>> a[1]
'Python programming'
>>> a[-1]
3534534L
It is important to note here that the last element of the *List* has an index of
-1.
~~~~~~~~~~~~~
Concatenating
~~~~~~~~~~~~~
Two or more *Lists* can be concatenated using the + operator::
>>> a + ['foo', 12, 23.3432, 54]
[10, 'Python programming', 20.3523, 'foo', 12, 23.3432, 54]
>>> [54, 75, 23] + ['write', 67, 'read']
[54, 75, 23, 'write', 67, 'read']
~~~~~~~
Slicing
~~~~~~~
A *List* can be sliced off to contain a subset of elements of the *List*. Slicing
can be done by using two indices separated by a colon, where the first index is
inclusive and the second index is exclusive. The resulting slice is also a *List*.::
>>> num = [1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> num[3:6]
[4, 5, 6]
>>> num[0:1]
[1]
>>> num[7:10]
[7, 8, 9]
The last example showed how to access last 3 elements of the *List*. There is a
small catch here. The second index 10 actually refers to the 11th element of the
*List* which is still valid, even though it doesn't exist because the second
index is exclusive and tells the Python interpreter to get the last element of
the *List*. But this can also be done in a much easier way using negative indices::
>>> num[-3:-1]
[7, 8, 9]
Excluding the first index implies that the slice must start at the beginning of
the *List*, while excluding the second index includes all the elements till the
end of the *List*. A third parameter to a slice, which is implicitly taken as 1
is the step of the slice. It is specified as a value which follows a colon after
the second index::
>>> num[:4]
[1, 2, 3, 4]
>>> num[7:]
[8, 9]
>>> num[-3:]
[7, 8, 9]
>>> num[:]
[1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> num[4:9:3]
[5, 8]
>>> num[3::2]
[4, 6, 8]
>>> num[::4]
[1, 5, 9]
~~~~~~~~~~~~~~
Multiplication
~~~~~~~~~~~~~~
A *List* can be multiplied with an integer to repeat itself::
>>> [20] * 5
[20, 20, 20, 20, 20]
>>> [42, 'Python', 54] * 3
[42, 'Python', 54, 42, 'Python', 54, 42, 'Python', 54]
~~~~~~~~~~
Membership
~~~~~~~~~~
**in** operator is used to find whether an element is part of the *List*. It
returns **True** if the element is present in the *List* or **False** if it is not
present. Since this operator returns a Boolean value it is called a Boolean
operator::
>>> names = ['Guido', 'Alex', 'Tim']
>>> 'Tim' in names
True
>>> 'Adam' in names
False
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Length, Maximum and Minimum
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Length of a *List* can be found out using the len function. The max function
returns the element with the largest value and the min function returns the
element with the smallest value::
>>> num = [4, 1, 32, 12, 67, 34, 65]
>>> len(num)
7
>>> max(num)
67
>>> min(num)
1
~~~~~~~~~~~~~~~~~
Changing Elements
~~~~~~~~~~~~~~~~~
Unlike Strings *Lists* are mutable, i.e. elements of a *List* can be manipulated::
>>> a = [1, 3, 5, 7]
>>> a[2] = 9
>>> a
[1, 3, 9, 7]
~~~~~~~~~~~~~~~~~
Deleting Elements
~~~~~~~~~~~~~~~~~
An element or a slice of a *List* can be deleted by using the **del** statement::
>>> a = [1, 3, 5, 7, 9, 11]
>>> del a[-2:]
>>> a
[1, 3, 5, 7]
>>> del a[1]
>>> a
[1, 5, 7]
~~~~~~~~~~~~~~~~
Assign to Slices
~~~~~~~~~~~~~~~~
In the same way, values can be assigned to individual elements of the *List*,
a *List* of elements can be assigned to a slice::
>>> a = [2, 3, 4, 5]
>>> a[:2] = [0, 1]
[0, 1, 4, 5]
>>> a[2:2] = [2, 3]
>>> a
[0, 1, 2, 3, 4, 5]
>>> a[2:4] = []
>>> a
[0, 1, 4, 5]
The last two examples should be particularly noted carefully. The last but one
example insert elements or a list of elements into a *List* and the last example
deletes a list of elements from the *List*.
None, Empty Lists, and Initialization
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
An *Empty List* is a *List* with no elements and is simply represented as
[]. A *None List* is one with all elements in it being **None**. It serves
the purpose having a container list of some fixed number of elements with
no value::
>>> a = []
>>> a
[]
>>> n = [None] * 10
>>> n
[None, None, None, None, None, None, None, None, None, None]
Nested Lists
~~~~~~~~~~~~
As mentioned earlier, a List can contain elements of any data type. This also
implies a *List* can have a *Lists* themselves as its elements. These are
called as *Nested Lists*. There is no limit on the depth of the *Nested Lists*::
>>> a = [1, [1, 2, 3], 3, [1, [1, 2, 3]], 7]
List Methods
~~~~~~~~~~~~
A method is a function that is coupled to an object. More about objects
and its methods are discussed in Advanced Python module. In general, a
method is called like::
object.method(arguments)
For now, it is enough to know that a list of elements is an object and
so *List* methods can be called upon them. Also some of the methods change
the *List* in-place, meaning it modifies the existing list instead of creating
a new one, while other methods don't. It must be noted as we run through
the *List* methods.
Some of the most commonly used *List* methods are as follows:
~~~~~~
append
~~~~~~
The *append* method is used to append an object at the end of the list::
>>> prime = [2, 3, 5]
>>> prime.append(7)
>>> prime
[2, 3, 5, 7]
It is important to note that append changes the *List* in-place.
~~~~~
count
~~~~~
The *count* method returns the number of occurences of a particular element
in a list::
>>> [1, 4, 4, 9, 9, 9].count(9)
3
>>> tlst = ['Python', 'is', 'a', 'beautiful', 'language']
>>> tlst.count('Python')
1
~~~~~~
extend
~~~~~~
The *extend* method extends the list on which it is called by the list supplied
as argument to it::
>>> a = [1, 2, 3]
>>> b = [4, 5, 6]
>>> a.extend(b)
[1, 2, 3, 4, 5, 6]
This is an in-place method. This method is equivalent to using the + operator, but
using the + operator returns a new list.
~~~~~
index
~~~~~
The *index* method returns the index position of the element in the list
specified as argument::
>>> a = [1, 2, 3, ,4, 5]
>>> a.index(4)
3
~~~~~~
insert
~~~~~~
The *insert* method is used to insert an element specified as the second
argument to the list at the position specified by the first argument::
>>> a = ['Python', 'is', 'cool']
>>> a.insert(2, 'so')
>>> a
['Python', 'is', 'so', 'cool']
The *insert* method changes the *List* in-place.
~~~
pop
~~~
The *pop* method removes an element from the list. The index position
of the element to be removed can be specified as an argument to the
*pop* method, if not it removes the last element by default::
>>> a = [1, 2, 3, 4, 5]
>>> a.pop()
>>> a
5
>>> a.pop(2)
>>> a
3
The *pop* method changes the *List* in-place.
~~~~~~
remove
~~~~~~
The *remove* method removes the first occurence of an element supplied as a
parameter::
>>> a = [1, 2, 3, 4, 2, 5, 2]
>>> a.remove(2)
>>> a
[1, 3, 4, 2, 5, 2]
~~~~~~~
reverse
~~~~~~~
The *reverse* method reverses elements in the list. It is important to note
here that *reverse* method changes the list in-place and doesn't return any
thing::
>>> a = ['guido', 'alex', 'tim']
>>> a.reverse()
>>> a
['tim', 'alex', 'guido']
~~~~
sort
~~~~
The *sort* method is used to sort the elements of the list. The *sort* method
also sorts in-place and does not return anything::
>>> a = [5, 1, 3, 7, 4]
>>> a.sort()
>>> a
[1, 3, 4, 5, 7]
In addition to the sort method on a *List* object we can also use the built-in
**sorted** function. This function takes the *List* as a parameter and returns
a sorted copy of the list. However the original list is left intact::
>>> a = [5, 1, 3, 7, 4]
>>> b = sorted(a)
>>> b
[1, 3, 4, 5, 7]
>>> a
[5, 1, 3, 7, 4]
List Comprehensions
~~~~~~~~~~~~~~~~~~~
List Comprehension is a convenvience utility provided by Python. It is a
syntatic sugar to create *Lists*. Using *List Comprehensions* one can create
*Lists* from other type of sequential data structures or other *Lists* itself.
The syntax of *List Comprehensions* consists of a square brackets to indicate
the result is a *List* within which we include at least one **for** clause and
multiple **if** clauses. It will be more clear with an example::
>>> num = [1, 2, 3]
>>> sq = [x*x for x in num]
>>> sq
[1, 4, 9]
>>> all_num = [1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> even = [x for x in all_num if x%2 == 0]
The syntax used here is very clear from the way it is written. It can be
translated into english as, "for each element x in the list all_num,
if remainder of x divided by 2 is 0, add x to the list."
Tuples
------
*Tuples* are sequences just like *Lists*, but they are immutable. In other
words *Tuples* provides a way to represent a group of items, where the group
of items cannot be changed in any way. The syntax of a *Tuple* is also very
similar to *List*. A *Tuple* is represented with the list of items, called
elements of the *Tuple* separated by comma, with the entire list being enclosed
in parenthesis. It is not compulsory to use parenthesis around a *Tuple* but
it may be necessary in some of the cases::
>>> a = 1, 2, 3
>>> a
(1, 2, 3)
>>> b = 1,
>>> b
(1,)
It is interesting to note the second example. Just a value followed by a comma
automatically makes that an element of a *Tuple* with only one element. It is
also important to note that, irrespective of input having a parenthesis, the
output always has a parenthesis.
The first example is also known as *Tuple packing*, because values are being
packed into a tuple. It is also possible to do *Tuple unpacking* which is more
interesting. It is better to understand that by example. Say we have a
co-ordinate pair from which we need to separate x and y co-ordinates::
>>> a = (1, 2)
>>> x, y = a
>>> x
1
>>> y
2
*Tuple unpacking* also has several other use-cases of which the most interesting
one is to swap the values of two variables. Using programming languages like C
would require anywhere around 10 lines of code and an extra temporary variable
to do this (including all the #include stuff). Python does it in the most
intuitive way in just one line. Say we want to swap the co-ordinates in the
above example::
>>> x, y = y, x
>>> x
2
>>> y
1
Common Tuple Operations
~~~~~~~~~~~~~~~~~~~~~~~
There is no need to introduce all the *Tuple* operations again, since *Tuples*
support the following operations that *List* supports in exactly the same way:
* Indexing
* Concatenating
* Slicing
* Membership
* Multiplication
* Length, Maximum, Minimum
The following examples illustrate the above operations::
>>> a = (1, 2, 3, 4, 5, 6)
>>> a[5]
6
>>> b = (7, 8, 9)
>>> a + b
(1, 2, 3, 4, 5, 6, 7, 8, 9)
>>> a[3:5]
(4, 5)
>>> 5 in a
True
>>> c = (1,)
>>> c * 5
(1, 1, 1, 1, 1)
>>> len(a)
6
>>> max(a)
6
>>> min(a)
1
However the following *List* operations are not supported by *Tuples* because
*Tuples* cannot be changed once they are created:
* Changing elements
* Deleting elements
* Assigning to slices
Similarity to *Lists* leads to the questions like, why not *Lists* only? Why do
we even want *Tuples*? Can we do the same with *Lists*? And the answer is **Yes**
we can do it, but *Tuples* are helpful at times, like we can return Tuples from
functions. They are also returned by some built-in functions and methods. And
also there are some use cases like co-ordinate among other things. So *Tuples*
are helpful.
Conclusion
----------
This section on *Lists* and *Tuples* introduces almost all the necessary
machinary required to work on *Lists* and *Tuples*. Topics like how to
iterate through these data structures will be introduced in the later
sections.