\index{list} \index{type!list}
Like a string, a list is a sequence of values. In a string, the values are characters; in a list, they can be any type. The values in lists are called elements or sometimes items.
\index{element} \index{sequence} \index{item}
There are several ways to create a new list; the simplest is to enclose the elements in square brackets ("[" and "]"):
[10, 20, 30, 40]
['crunchy frog', 'ram bladder', 'lark vomit']
The first example is a list of four integers. The second is a list of three strings. The elements of a list don't have to be the same type. The following list contains a string, a float, an integer, and (lo!) another list:
['spam', 2.0, 5, [10, 20]]
A list within another list is nested.
\index{nested list} \index{list!nested}
A list that contains no elements is called an empty list; you can create
one with empty brackets, []
.
\index{empty list} \index{list!empty}
As you might expect, you can assign list values to variables:
>>> cheeses = ['Cheddar', 'Edam', 'Gouda']
>>> numbers = [17, 123]
>>> empty = []
>>> print(cheeses, numbers, empty)
['Cheddar', 'Edam', 'Gouda'] [17, 123] []
\index{assignment}
\index{list!element} \index{access} \index{index} \index{} \index{bracket operator} \index{operator!bracket}
The syntax for accessing the elements of a list is the same as for accessing the characters of a string: the bracket operator. The expression inside the brackets specifies the index. Remember that the indices start at 0:
>>> print(cheeses[0])
Cheddar
Unlike strings, lists are mutable because you can change the order of items in a list or reassign an item in a list. When the bracket operator appears on the left side of an assignment, it identifies the element of the list that will be assigned.
\index{mutability}
>>> numbers = [17, 123]
>>> numbers[1] = 5
>>> print(numbers)
[17, 5]
The one-th element of numbers
, which used to be 123, is
now 5.
\index{index!starting at zero} \index{zero, index starting at}
You can think of a list as a relationship between indices and elements. This relationship is called a mapping; each index "maps to" one of the elements.
\index{item assignment} \index{assignment!item}
List indices work the same way as string indices:
-
Any integer expression can be used as an index.
-
If you try to read or write an element that does not exist, you get an
IndexError
.
\index{exception!IndexError} \index{IndexError}
- If an index has a negative value, it counts backward from the end of the list.
\index{list!index} \index{list!membership} \index{membership!list} \index{in operator} \index{operator!in}
The in
operator also works on lists.
>>> cheeses = ['Cheddar', 'Edam', 'Gouda']
>>> 'Edam' in cheeses
True
>>> 'Brie' in cheeses
False
\index{list!traversal} \index{traversal!list} \index{for loop} \index{loop!for} \index{statement!for}
The most common way to traverse the elements of a list is with a
for
loop. The syntax is the same as for strings:
for cheese in cheeses:
print(cheese)
This works well if you only need to read the elements of the list. But
if you want to write or update the elements, you need the indices. A
common way to do that is to combine the functions range
and
len
:
\index{looping!with indices} \index{index!looping with}
for i in range(len(numbers)):
numbers[i] = numbers[i] * 2
This loop traverses the list and updates each element. len
returns the number of elements in the list. range
returns a
list of indices from 0 to i
gets the index of the next
element. The assignment statement in the body uses i
to
read the old value of the element and to assign the new value.
\index{item update} \index{update!item}
A for
loop over an empty list never executes the body:
for x in empty:
print('This never happens.')
Although a list can contain another list, the nested list still counts as a single element. The length of this list is four:
\index{nested list} \index{list!nested}
['spam', 1, ['Brie', 'Roquefort', 'Pol le Veq'], [1, 2, 3]]
\index{list!operation}
The +
operator concatenates lists:
\index{concatenation!list} \index{list!concatenation}
>>> a = [1, 2, 3]
>>> b = [4, 5, 6]
>>> c = a + b
>>> print(c)
[1, 2, 3, 4, 5, 6]
Similarly, the *
operator repeats a list a given number of times:
\index{repetition!list} \index{list!repetition}
>>> [0] * 4
[0, 0, 0, 0]
>>> [1, 2, 3] * 3
[1, 2, 3, 1, 2, 3, 1, 2, 3]
The first example repeats four times. The second example repeats the list three times.
\index{slice operator} \index{operator!slice} \index{index!slice} \index{list!slice} \index{slice!list}
The slice operator also works on lists:
>>> t = ['a', 'b', 'c', 'd', 'e', 'f']
>>> t[1:3]
['b', 'c']
>>> t[:4]
['a', 'b', 'c', 'd']
>>> t[3:]
['d', 'e', 'f']
If you omit the first index, the slice starts at the beginning. If you omit the second, the slice goes to the end. So if you omit both, the slice is a copy of the whole list.
\index{list!copy} \index{slice!copy} \index{copy!slice}
>>> t[:]
['a', 'b', 'c', 'd', 'e', 'f']
Since lists are mutable, it is often useful to make a copy before performing operations that fold, spindle, or mutilate lists.
\index{mutability}
A slice operator on the left side of an assignment can update multiple elements:
\index{slice!update} \index{update!slice}
>>> t = ['a', 'b', 'c', 'd', 'e', 'f']
>>> t[1:3] = ['x', 'y']
>>> print(t)
['a', 'x', 'y', 'd', 'e', 'f']
\index{list!method} \index{method, list}
Python provides methods that operate on lists. For example,
append
adds a new element to the end of a list:
\index{append method} \index{method!append}
>>> t = ['a', 'b', 'c']
>>> t.append('d')
>>> print(t)
['a', 'b', 'c', 'd']
extend
takes a list as an argument and appends all of the
elements:
\index{extend method} \index{method!extend}
>>> t1 = ['a', 'b', 'c']
>>> t2 = ['d', 'e']
>>> t1.extend(t2)
>>> print(t1)
['a', 'b', 'c', 'd', 'e']
This example leaves t2
unmodified.
sort
arranges the elements of the list from low to high:
\index{sort method} \index{method!sort}
>>> t = ['d', 'c', 'e', 'b', 'a']
>>> t.sort()
>>> print(t)
['a', 'b', 'c', 'd', 'e']
Most list methods are void; they modify the list and return
None
. If you accidentally write t = t.sort()
,
you will be disappointed with the result.
\index{void method} \index{method!void} \index{None special value} \index{special value!None}
\index{element deletion} \index{deletion, element of list}
There are several ways to delete elements from a list. If you know the
index of the element you want, you can use pop
:
\index{pop method} \index{method!pop}
>>> t = ['a', 'b', 'c']
>>> x = t.pop(1)
>>> print(t)
['a', 'c']
>>> print(x)
b
pop
modifies the list and returns the element that was
removed. If you don't provide an index, it deletes and returns the last
element.
If you don't need the removed value, you can use the del
statement:
\index{del statement} \index{statement!del}
>>> t = ['a', 'b', 'c']
>>> del t[1]
>>> print(t)
['a', 'c']
If you know the element you want to remove (but not the index), you can
use remove
:
\index{remove method} \index{method!remove}
>>> t = ['a', 'b', 'c']
>>> t.remove('b')
>>> print(t)
['a', 'c']
The return value from remove
is None
.
\index{None special value} \index{special value!None}
To remove more than one element, you can use del
with a
slice index:
>>> t = ['a', 'b', 'c', 'd', 'e', 'f']
>>> del t[1:5]
>>> print(t)
['a', 'f']
As usual, the slice selects all the elements up to, but not including, the second index.
There are a number of built-in functions that can be used on lists that allow you to quickly look through a list without writing your own loops:
>>> nums = [3, 41, 12, 9, 74, 15]
>>> print(len(nums))
6
>>> print(max(nums))
74
>>> print(min(nums))
3
>>> print(sum(nums))
154
>>> print(sum(nums)/len(nums))
25
The sum()
function only works when the list elements are
numbers. The other functions (max()
, len()
,
etc.) work with lists of strings and other types that can be comparable.
We could rewrite an earlier program that computed the average of a list of numbers entered by the user using a list.
First, the program to compute an average without a list:
\VerbatimInput{../code3/avenum.py}
In this program, we have count
and total
variables to keep the number and running total of the user's numbers as
we repeatedly prompt the user for a number.
We could simply remember each number as the user entered it and use built-in functions to compute the sum and count at the end.
\VerbatimInput{../code3/avelist.py}
We make an empty list before the loop starts, and then each time we have a number, we append it to the list. At the end of the program, we simply compute the sum of the numbers in the list and divide it by the count of the numbers in the list to come up with the average.
\index{list} \index{string} \index{sequence}
A string is a sequence of characters and a list is a sequence of values,
but a list of characters is not the same as a string. To convert from a
string to a list of characters, you can use list
:
\index{list!function} \index{function!list}
>>> s = 'spam'
>>> t = list(s)
>>> print(t)
['s', 'p', 'a', 'm']
Because list
is the name of a built-in function, you should
avoid using it as a variable name. I also avoid the letter
"l" because it looks too much like the number "1".
So that's why I use "t".
The list
function breaks a string into individual letters.
If you want to break a string into words, you can use the
split
method:
\index{split method} \index{method!split}
>>> s = 'pining for the fjords'
>>> t = s.split()
>>> print(t)
['pining', 'for', 'the', 'fjords']
>>> print(t[2])
the
Once you have used split
to break the string into a list of
words, you can use the index operator (square bracket) to look at a
particular word in the list.
You can call split
with an optional argument called a
delimiter that specifies which characters to use as
word boundaries. The following example uses a hyphen as a delimiter:
\index{optional argument} \index{argument!optional} \index{delimiter}
>>> s = 'spam-spam-spam'
>>> delimiter = '-'
>>> s.split(delimiter)
['spam', 'spam', 'spam']
join
is the inverse of split
. It takes a list
of strings and concatenates the elements. join
is a string
method, so you have to invoke it on the delimiter and pass the list as a
parameter:
\index{join method} \index{method!join} \index{concatenation}
>>> t = ['pining', 'for', 'the', 'fjords']
>>> delimiter = ' '
>>> delimiter.join(t)
'pining for the fjords'
In this case the delimiter is a space character, so join
puts a space between words. To concatenate strings without spaces, you
can use the empty string, "", as a delimiter.
\index{empty string} \index{string!empty}
Usually when we are reading a file we want to do something to the lines other than just printing the whole line. Often we want to find the "interesting lines" and then parse the line to find some interesting part of the line. What if we wanted to print out the day of the week from those lines that start with "From "?
From [email protected] Sat Jan 5 09:14:16 2008
The split
method is very effective when faced with this
kind of problem. We can write a small program that looks for lines where
the line starts with "From ", split
those lines, and then
print out the third word in the line:
\VerbatimInput{../code3/search5.py} \begin{trinketfiles} ../code3/mbox-short.txt \end{trinketfiles}
The program produces the following output:
Sat
Fri
Fri
Fri
...
Later, we will learn increasingly sophisticated techniques for picking the lines to work on and how we pull those lines apart to find the exact bit of information we are looking for.
\index{object} \index{value}
If we execute these assignment statements:
a = 'banana'
b = 'banana'
we know that a
and b
both refer to a string,
but we don't know whether they refer to the same string. There are two
possible states:
\index{aliasing}
In one case, a
and b
refer to two different
objects that have the same value. In the second case, they refer to the
same object.
\index{is operator} \index{operator!is}
To check whether two variables refer to the same object, you can use the
is
operator.
>>> a = 'banana'
>>> b = 'banana'
>>> a is b
True
In this example, Python only created one string object, and both
a
and b
refer to it.
But when you create two lists, you get two objects:
>>> a = [1, 2, 3]
>>> b = [1, 2, 3]
>>> a is b
False
In this case we would say that the two lists are equivalent, because they have the same elements, but not identical, because they are not the same object. If two objects are identical, they are also equivalent, but if they are equivalent, they are not necessarily identical.
\index{equivalence} \index{identity}
Until now, we have been using "object" and "value" interchangeably, but
it is more precise to say that an object has a value. If you execute
a = [1,2,3]
, a
refers to a list object whose
value is a particular sequence of elements. If another list has the same
elements, we would say it has the same value.
\index{object} \index{value}
\index{aliasing} \index{reference!aliasing}
If a
refers to an object and you assign b = a
,
then both variables refer to the same object:
>>> a = [1, 2, 3]
>>> b = a
>>> b is a
True
The association of a variable with an object is called a reference. In this example, there are two references to the same object.
\index{reference}
An object with more than one reference has more than one name, so we say that the object is aliased.
\index{mutability}
If the aliased object is mutable, changes made with one alias affect the other:
>>> b[0] = 17
>>> print(a)
[17, 2, 3]
Although this behavior can be useful, it is error-prone. In general, it is safer to avoid aliasing when you are working with mutable objects.
\index{immutability}
For immutable objects like strings, aliasing is not as much of a problem. In this example:
a = 'banana'
b = 'banana'
it almost never makes a difference whether a
and
b
refer to the same string or not.
\index{list!as argument} \index{argument} \index{argument!list} \index{reference} \index{parameter}
When you pass a list to a function, the function gets a reference to the
list. If the function modifies a list parameter, the caller sees the
change. For example, delete_head
removes the first element from a
list:
def delete_head(t):
del t[0]
Here's how it is used:
>>> letters = ['a', 'b', 'c']
>>> delete_head(letters)
>>> print(letters)
['b', 'c']
The parameter t
and the variable letters
are
aliases for the same object.
It is important to distinguish between operations that modify lists and
operations that create new lists. For example, the append
method modifies a list, but the +
operator creates a new
list:
\index{append method} \index{method!append} \index{list!concatenation} \index{concatenation!list}
>>> t1 = [1, 2]
>>> t2 = t1.append(3)
>>> print(t1)
[1, 2, 3]
>>> print(t2)
None
>>> t3 = t1 + [3]
>>> print(t3)
[1, 2, 3]
>>> t1 is t3
False
This difference is important when you write functions that are supposed to modify lists. For example, this function does not delete the head of a list:
def bad_delete_head(t):
t = t[1:] # WRONG!
The slice operator creates a new list and the assignment makes
t
refer to it, but none of that has any effect on the list
that was passed as an argument.
\index{slice operator} \index{operator!slice}
An alternative is to write a function that creates and returns a new
list. For example, tail
returns all but the first element
of a list:
def tail(t):
return t[1:]
This function leaves the original list unmodified. Here's how it is used:
>>> letters = ['a', 'b', 'c']
>>> rest = tail(letters)
>>> print(rest)
['b', 'c']
Exercise 1: Write a function called chop
that takes a list and modifies
it, removing the first and last elements, and returns None
. Then write a function
called middle
that takes a list and returns a new list that contains all but
the first and last elements.
\index{debugging}
Careless use of lists (and other mutable objects) can lead to long hours of debugging. Here are some common pitfalls and ways to avoid them:
-
Don't forget that most list methods modify the argument and return
None
. This is the opposite of the string methods, which return a new string and leave the original alone.If you are used to writing string code like this:
word = word.strip()
It is tempting to write list code like this:
t = t.sort() # WRONG!
\index{sort method} \index{method!sort}
Because
sort
returnsNone
, the next operation you perform witht
is likely to fail.Before using list methods and operators, you should read the documentation carefully and then test them in interactive mode. The methods and operators that lists share with other sequences (like strings) are documented at:
docs.python.org/library/stdtypes.html#common-sequence-operations
The methods and operators that only apply to mutable sequences are documented at:
docs.python.org/library/stdtypes.html#mutable-sequence-types
-
Pick an idiom and stick with it.
\index{idiom}
Part of the problem with lists is that there are too many ways to do things. For example, to remove an element from a list, you can use
pop
,remove
,del
, or even a slice assignment.To add an element, you can use the
append
method or the+
operator. But don't forget that these are right:t.append(x) t = t + [x]
And these are wrong:
t.append([x]) # WRONG! t = t.append(x) # WRONG! t + [x] # WRONG! t = t + x # WRONG!
Try out each of these examples in interactive mode to make sure you understand what they do. Notice that only the last one causes a runtime error; the other three are legal, but they do the wrong thing.
-
Make copies to avoid aliasing.
\index{aliasing!copying to avoid} \index{copy!to avoid aliasing}
If you want to use a method like
sort
that modifies the argument, but you need to keep the original list as well, you can make a copy.orig = t[:] t.sort()
In this example you could also use the built-in function
sorted
, which returns a new, sorted list and leaves the original alone. But in that case you should avoid usingsorted
as a variable name! -
Lists,
split
, and filesWhen we read and parse files, there are many opportunities to encounter input that can crash our program so it is a good idea to revisit the guardian pattern when it comes to writing programs that read through a file and look for a "needle in the haystack".
Let's revisit our program that is looking for the day of the week on the from lines of our file:
From [email protected] Sat Jan 5 09:14:16 2008
Since we are breaking this line into words, we could dispense with the use of
startswith
and simply look at the first word of the line to determine if we are interested in the line at all. We can usecontinue
to skip lines that don't have "From" as the first word as follows:fhand = open('mbox-short.txt') for line in fhand: words = line.split() if words[0] != 'From' : continue print(words[2])
This looks much simpler and we don't even need to do the
rstrip
to remove the newline at the end of the file. But is it better?python search8.py Sat Traceback (most recent call last): File "search8.py", line 5, in <module> if words[0] != 'From' : continue IndexError: list index out of range
It kind of works and we see the day from the first line (Sat), but then the program fails with a traceback error. What went wrong? What messed-up data caused our elegant, clever, and very Pythonic program to fail?
You could stare at it for a long time and puzzle through it or ask someone for help, but the quicker and smarter approach is to add a
print
statement. The best place to add the print statement is right before the line where the program failed and print out the data that seems to be causing the failure.Now this approach may generate a lot of lines of output, but at least you will immediately have some clue as to the problem at hand. So we add a print of the variable
words
right before line five. We even add a prefix "Debug:" to the line so we can keep our regular output separate from our debug output.for line in fhand: words = line.split() print('Debug:', words) if words[0] != 'From' : continue print(words[2])
When we run the program, a lot of output scrolls off the screen but at the end, we see our debug output and the traceback so we know what happened just before the traceback.
Debug: ['X-DSPAM-Confidence:', '0.8475'] Debug: ['X-DSPAM-Probability:', '0.0000'] Debug: [] Traceback (most recent call last): File "search9.py", line 6, in <module> if words[0] != 'From' : continue IndexError: list index out of range
Each debug line is printing the list of words which we get when we
split
the line into words. When the program fails, the list of words is empty[]
. If we open the file in a text editor and look at the file, at that point it looks as follows:X-DSPAM-Result: Innocent X-DSPAM-Processed: Sat Jan 5 09:14:16 2008 X-DSPAM-Confidence: 0.8475 X-DSPAM-Probability: 0.0000 Details: http://source.sakaiproject.org/viewsvn/?view=rev&rev=39772
The error occurs when our program encounters a blank line! Of course there are "zero words" on a blank line. Why didn't we think of that when we were writing the code? When the code looks for the first word (
word[0]
) to check to see if it matches "From", we get an "index out of range" error.This of course is the perfect place to add some guardian code to avoid checking the first word if the first word is not there. There are many ways to protect this code; we will choose to check the number of words we have before we look at the first word:
fhand = open('mbox-short.txt') count = 0 for line in fhand: words = line.split() # print('Debug:', words) if len(words) == 0 : continue if words[0] != 'From' : continue print(words[2])
First we commented out the debug print statement instead of removing it, in case our modification fails and we need to debug again. Then we added a guardian statement that checks to see if we have zero words, and if so, we use
continue
to skip to the next line in the file.We can think of the two
continue
statements as helping us refine the set of lines which are "interesting" to us and which we want to process some more. A line which has no words is "uninteresting" to us so we skip to the next line. A line which does not have "From" as its first word is uninteresting to us so we skip it.The program as modified runs successfully, so perhaps it is correct. Our guardian statement does make sure that the
words[0]
will never fail, but perhaps it is not enough. When we are programming, we must always be thinking, "What might go wrong?"
Exercise 2: Figure out which line of the above program is still not properly guarded. See if you can construct a text file which causes the program to fail and then modify the program so that the line is properly guarded and test it to make sure it handles your new text file.
Exercise 3: Rewrite the guardian code in the above example without
two if
statements. Instead, use a compound logical
expression using the or
logical operator with a single
if
statement.
aliasing : A circumstance where two or more variables refer to the same object. \index{aliasing}
delimiter : A character or string used to indicate where a string should be split. \index{delimiter}
element : One of the values in a list (or other sequence); also called items. \index{element}
equivalent : Having the same value. \index{equivalent}
index : An integer value that indicates an element in a list. \index{index} \index{}
identical : Being the same object (which implies equivalence). \index{identical}
list : A sequence of values. \index{list}
list traversal : The sequential accessing of each element in a list. \index{list!traversal}
nested list : A list that is an element of another list. \index{nested list}
object : Something a variable can refer to. An object has a type and a value. \index{object}
reference : The association between a variable and its value. \index{reference}
\index{Romeo and Juliet}
Exercise 4: Find all unique words in a file
Shakespeare used over 20,000 words in his works. But how would you determine that? How would you produce the list of all the words that Shakespeare used? Would you download all his work, read it and track all unique words by hand?
Let's use Python to achieve that instead. List all unique words, sorted in alphabetical
order, that are stored in a file romeo.txt
containing a subset of Shakespeare's work.
To get started, download a copy of the file
www.py4e.com/code3/romeo.txt.
Create a list of unique words, which will contain the final result.
Write a program to open the file romeo.txt
and read it line
by line. For each line, split the line into a list of words using the
split
function. For each word, check to see if the word is already in the list
of unique words. If the word is not in the list of unique words, add it to the list.
When the program completes, sort and print the list of unique words in
alphabetical order.
Enter file: romeo.txt
['Arise', 'But', 'It', 'Juliet', 'Who', 'already',
'and', 'breaks', 'east', 'envious', 'fair', 'grief',
'is', 'kill', 'light', 'moon', 'pale', 'sick', 'soft',
'sun', 'the', 'through', 'what', 'window',
'with', 'yonder']
Exercise 5: Minimalist Email Client.
MBOX (mail box) is a popular file format to store and share a collection of
emails. This was used by early email servers and desktop apps. Without getting
into too many details, MBOX is a text file, which stores emails consecutively.
Emails are separated by a special line which starts with From
(notice the space).
Importantly, lines starting with From:
(notice the colon) describes the email
itself and does not act as a separator.
Imagine you wrote a minimalist email app, that lists the email of the senders
in the user's Inbox and counts the number of emails.
Write a program to read through the mail box data and when
you find line that starts with "From", you will split the line into
words using the split
function. We are interested in who
sent the message, which is the second word on the From line.
From [email protected] Sat Jan 5 09:14:16 2008
You will parse the From line and print out the second word for each From line, then you will also count the number of From (not From:) lines and print out a count at the end. This is a good sample output with a few lines removed:
python fromcount.py
Enter a file name: mbox-short.txt
[email protected]
[email protected]
[email protected]
[...some output removed...]
[email protected]
[email protected]
[email protected]
[email protected]
There were 27 lines in the file with From as the first word
Exercise 6:
Rewrite the program that prompts the user for a list of
numbers and prints out the maximum and minimum of the numbers at the end
when the user enters "done". Write the program to store the numbers the
user enters in a list and use the max()
and
min()
functions to compute the maximum and minimum numbers
after the loop completes.
Enter a number: 6
Enter a number: 2
Enter a number: 9
Enter a number: 3
Enter a number: 5
Enter a number: done
Maximum: 9.0
Minimum: 2.0