List of Keywords
List of Keywords in Python
False | class | finally | is | return |
None | continue | for | lambda | try |
True | def | from | nonlocal | while |
and | del | global | not | with |
as | elif | if | or | yield |
assert | else | import | pass | |
break | except | in | raise |
The above keywords may get altered in different versions of Python. Some extra might get added or some might be removed. You can always get the list of keywords in your current version by typing the following in the prompt.
>>> import keyword
>>> print(keyword.kwlist)
['False', 'None', 'True', 'and', 'as', 'assert', 'break', 'class', 'continue', 'def', 'del', 'elif', 'else', 'except', 'finally', 'for', 'from', 'global', 'if', 'import', 'in', 'is', 'lambda', 'nonlocal', 'not', 'or', 'pass', 'raise', 'return', 'try', 'while', 'with', 'yield']
Description of Keywords in Python with examples
True, False
True
and False
are truth values in Python. They are the results of comparison operations or logical (Boolean) operations in Python. For example:
>>> 1 == 1
True
>>> 5 > 3
True
>>> True or False
True
>>> 10 <= 1
False
>>> 3 > 7
False
>>> True and False
False
Here we can see that the first three statements are true so the interpreter returns True
and returns False
for the remaining three statements. True
and False
in python is same as 1
and 0
. This can be justified with the following example:
>>> True == 1
True
>>> False == 0
True
>>> True + True
2
None
None
is a special constant in Python that represents the absence of a value or a null value. It is an object of its own datatype, the NoneType
. We cannot create multiple None
objects but can assign it to variables. These variables will be equal to one another. We must take special care that None
does not imply False
, 0
or any empty list, dictionary, string etc. For example:
>>> None == 0
False
>>> None == []
False
>>> None == False
False
>>> x = None
>>> y = None
>>> x == y
True
Void functions that do not return anything will return a None
object automatically. None
is also returned by functions in which the program flow does not encounter a return statement. For example:
def a_void_function():
a = 1
b = 2
c = a + b
x = a_void_function()
print(x)
Output
None
This program has a function that does not return a value, although it does some operations inside. So when we print x, we get None
which is returned automatically (implicitly). Similarly, here is another example:
def improper_return_function(a):
if (a % 2) == 0:
return True
x = improper_return_function(3)
print(x)
Output
None
Although this function has a return
statement, it is not reached in every case. The function will return True
only when the input is even. So, if we give the function an odd number, None
is returned implicitly.
and, or , not
and
, or
, not
are the logical operators in Python. and
will result into True
only if both the operands are True
. The truth table for and
is given below:
A | B | A and B |
---|---|---|
True | True | True |
True | False | False |
False | True | False |
False | False | False |
or
will result into True
if any of the operands is True
. The truth table for or
is given below:
A | B | A or B |
---|---|---|
True | True | True |
True | False | True |
False | True | True |
False | False | False |
not
operator is used to invert the truth value. The truth table for not
is given below:
A | not A |
---|---|
True | False |
False | True |
some example of their usage are given below
>>> True and False
False
>>> True or False
True
>>> not False
True
as
as
is used to create an alias while importing a module. It means giving a different name (user-defined) to a module while importing it. As for example, Python has a standard module called math
. Suppose we want to calculate what cosine pi is using an alias. We can do it as follows using as
:
>>> import math as myAlias
>>>myAlias.cos(myAlias.pi)
-1.0
Here we imported the math
module by giving it the name myAlias
. Now we can refer to the math
module with this name. Using this name we calculated cos(pi) and got -1.0
as the answer.
assert
assert
is used for debugging purposes. While programming, sometimes we wish to know the internal state or check if our assumptions are true. assert
helps us do this and find bugs more conveniently. assert
is followed by a condition. If the condition is true, nothing happens. But if the condition is false, AssertionError
is raised. For example:
>>> a = 4
>>> assert a < 5
>>> assert a > 5
Traceback (most recent call last):
File "<string>", line 301, in runcode
File "<interactive input>", line 1, in <module>
AssertionError
For our better understanding, we can also provide a message to be printed with the AssertionError
.
>>> a = 4
>>> assert a > 5, "The value of a is too small"
Traceback (most recent call last):
File "<string>", line 301, in runcode
File "<interactive input>", line 1, in <module>
AssertionError: The value of a is too small
At this point we can note that,
assert condition, message
is equivalent to,
if not condition:
raise AssertionError(message)
break, continue
break
and continue
are used inside for
and while
loops to alter their normal behavior. break
will end the smallest loop it is in and control flows to the statement immediately below the loop. continue
causes to end the current iteration of the loop, but not the whole loop. This can be illustrated with the following two examples:
for i in range(1,11):
if i == 5:
break
print(i)
Output
1 2 3 4
Here, the for
loop intends to print numbers from 1 to 10. But the if
condition is met when i is equal to 5 and we break from the loop. Thus, only the range 1 to 4 is printed.
for i in range(1,11):
if i == 5:
continue
print(i)
Output
1 2 3 4 6 7 8 9 10
Here we use continue
for the same program. So, when the condition is met, that iteration is skipped. But we do not exit the loop. Hence, all the values except 5 is printed out.
class
class
is used to define a new user-defined class in Python. Class is a collection of related attributes and methods that try to represent a real world situation. This idea of putting data and functions together in a class is central to the concept of object-oriented programming (OOP). Classes can be defined anywhere in a program. But it is a good practice to define a single class in a module. Following is a sample usage:
class ExampleClass:
def function1(parameters):
…
def function2(parameters):
…
def
def
is used to define a user-defined function. Function is a block of related statements, which together does some specific task. It helps us organize code into manageable chunks and also to do some repetitive task. The usage of def
is shown below:
def function_name(parameters):
…
del
del
is used to delete the reference to an object. Everything is object in Python. We can delete a variable reference using del
>>> a = b = 5
>>> del a
>>> a
Traceback (most recent call last):
File "<string>", line 301, in runcode
File "<interactive input>", line 1, in <module>
NameError: name 'a' is not defined
>>> b
5
Here we can see that the reference of the variable a was deleted. So, it is no longer defined. But b still exists.
del
is also used to delete items from a list or a dictionary:
>>> a = ['x','y','z']
>>> del a[1]
>>> a
['x', 'z']
if, else, elif
if, else, elif
are used for conditional branching or decision making. When we want to test some condition and execute a block only if the condition is true, then we use if
and elif
. elif
is short for else if. else
is the block which is executed if the condition is false. This will be clear with the following example:
def if_example(a):
if a == 1:
print('One')
elif a == 2:
print('Two')
else:
print('Something else')
if_example(2)
if_example(4)
if_example(1)
Output
Two Something else One
Here, the function checks the input number and prints the result if it is 1 or 2. Any input other than this will cause the else
part of the code to execute.
except, raise, try
except, raise, try
are used with exceptions in Python. Exceptions are basically errors that suggests something went wrong while executing our program. IOError
, ValueError
, ZeroDivisionError
, ImportError
, NameError
, TypeError
etc. are few examples of exception in Python. try...except
blocks are used to catch exceptions in Python. We can raise an exception explicitly with the raise
keyword. Following is an example:
def reciprocal(num):
try:
r = 1/num
except:
print('Exception caught')
return
return r
print(reciprocal(10))
print(reciprocal(0))
Output
0.1 Exception caught None
Here, the function reciprocal()
returns the reciprocal of the input number. When we enter 10, we get the normal output of 0.1. But when we input 0, a ZeroDivisionError
is raised automatically. This is caught by our try…except
block and we return None
. We could have also raised the ZeroDivisionError
explicitly by checking the input and handled it elsewhere as follows:
if num == 0:
raise ZeroDivisionError('cannot divide')
finally
finally
is used with try…except
block to close up resources or file streams. Using finally
ensures that the block of code inside it gets executed even if there is an unhandled exception. For example:
try:
Try-block
except exception1:
Exception1-block
except exception2:
Exception2-block
else:
Else-block
finally:
Finally-block
Here if there is an exception in the Try-block
, it is handled in the except
or else
block. But no matter in what order the execution flows, we can rest assured that the Finally-block
is executed even if there is an error. This is useful in cleaning up the resources.
for
for
is used for looping. Generally we use for
when we know the number of times we want to loop. In Python we can use it with any type of sequence like a list or a string. Here is an example in which for
is used to traverse through a list of names:
names = ['John','Monica','Steven','Robin']
for i in names:
print('Hello '+i)
Output
Hello John Hello Monica Hello Steven Hello Robin
from, import
import
keyword is used to import modules into the current namespace. from…import
is used to import specific attributes or functions into the current namespace. For example:
import math
will import the math
module. Now we can use the cos()
function inside it as math.cos()
. But if we wanted to import just the cos()
function, this can done using from
as
from math import cos
now we can use the function simply as cos()
, no need to write math.cos()
.
global
global
is used to declare that a variable inside the function is global (outside the function). If we need to read the value of a global variable, it is not necessary to define it as global
. This is understood. But if we need to modify the value of a global variable inside a function, then we must declare it with global
. Otherwise a local variable with that name is created. Following example will help us clarify this.
globvar = 10
def read1():
print(globvar)
def write1():
global globvar
globvar = 5
def write2():
globvar = 15
read1()
write1()
read1()
write2()
read1()
Output
10 5 5
Here, the read1()
function is just reading the value of globvar
. So, we do not need to declare it as global
. But the write1()
function is modifying the value, so we need to declare the variable as global
. We can see in our output that the modification did take place (10 is changed to 5). The write2()
also tries to modify this value. But we have not declared it as global
. Hence, a new local variable globvar
is created which is not visible outside this function. Although we modify this local variable to 15, the global variable remains unchanged. This is clearly visible in our output.
in
in
is used to test if a sequence (list, tuple, string etc.) contains a value. It returns True
if the value is present, else it returns False
. For example:
>>> a = [1, 2, 3, 4, 5]
>>> 5 in a
True
>>> 10 in a
False
The secondary use of in
is to traverse through a sequence in a for
loop.
for i in 'hello':
print(i)
Output
h e l l o
is
is
is used in Python for testing object identity. While the ==
operator is used to test if two variables are equal or not, is
is used to test if the two variables refer to the same object. It returns True
if the objects are identical and False
if not.
>>> True is True
True
>>> False is False
True
>>> None is None
True
We know that there is only one instance of True
, False
and None
in Python, so they are identical.
>>> [] == []
True
>>> [] is []
False
>>> {} == {}
True
>>> {} is {}
False
An empty list or dictionary is equal to another empty one. But they are not identical objects as they are located separately in memory. This is because list and dictionary are mutable (value can be changed).
>>> '' == ''
True
>>> '' is ''
True
>>> () == ()
True
>>> () is ()
True
Unlike list and dictionary, string and tuple are immutable (value cannot be altered once defined). Hence, two equal string or tuple are identical as well. They refer to the same memory location.
lambda
lambda
is used to create an anonymous function (function with no name). It is an inline function that does not contain a return
statement. It consists of an expression that is evaluated and returned. For example:
a = lambda x: x*2
for i in range(1,6):
print(a(i))
Output
2 4 6 8 10
Here, we have created an inline function that doubles the value, using the lambda
statement. We used this to double the values in a list containing 1 to 5.
nonlocal
The use of nonlocal
keyword is very much similar to the global
keyword. nonlocal
is used to declare that a variable inside a nested function (function inside a function) is not local to it, meaning it lies in the outer inclosing function. If we need to modify the value of a non-local variable inside a nested function, then we must declare it with nonlocal
. Otherwise a local variable with that name is created inside the nested function. Following example will help us clarify this.
def outer_funciton():
a = 5
def inner_function():
nonlocal a
a = 10
print("Inner function: ",a)
inner_function()
print("Outer function: ",a)
outer_funciton()
Output
Inner function: 10 Outer function: 10
Here, the inner_function()
is nested within the outer_function
. The variable a is in the outer_function()
. So, if we want to modify it in the inner_function()
, we must declare it as nonlocal
. Notice that a is not a global variable. Hence, we see from the output that the variable was successfully modified inside the nested inner_function()
. The result of not using the nonlocal
keyword is as follows:
def outer_funciton():
a = 5
def inner_function():
a = 10
print("Inner function: ",a)
inner_function()
print("Outer function: ",a)
outer_funciton()
Output
Inner function: 10 Outer function: 5
Here, we do not declare that the variable a inside the nested function is nonlocal
. Hence, a new local variable with the same name is created, but the non-local a is not modified as seen in our output.
pass
pass
is a null statement in Python. Nothing happens when it is executed. It is used as a placeholder. Suppose we have a function that is not implemented yet, but we want to implement it in the future. Simply writing,
def function(args):
in the middle of a program will give us IndentationError
. Instead of this, we construct a blank body with the pass
statement.
def function(args):
pass
We can do the same thing in an empty class
as well.
class example:
pass
return
return
statement is used inside a function to exit it and return a value. If we do not return a value explicitly, None
is returned automatically. This is verified with the following example.
def func_return():
a = 10
return a
def no_return():
a = 10
print(func_return())
print(no_return())
Output
10 None
while
while
is used for looping in Python. The statements inside a while
loop continue to execute until the condition for the while
loop evaluates to False
or a break
statement is encountered. Following program illustrates this.
i = 5
while(i):
print(i)
i = i – 1
Output
5 4 3 2 1
Note that 0 is equal to False
.
with
with
statement is used to wrap the execution of a block of code within methods defined by the context manager. Context manager is a class that implements __enter__
and __exit__
methods. Use of with
statement ensures that the __exit__
method is called at the end of the nested block. This concept is similar to the use of try…finally
block. Here, is an example.
with open('example.txt', 'w') as my_file:
my_file.write('Hello world!')
This example writes the text Hello world!
to the file example.txt
. File objects have __enter__
and __exit__
method defined within them, so they act as their own context manager. First the __enter__
method is called, then the code within with
statement is executed and finally the __exit__
method is called. __exit__
method is called even if there is an error. It basically closes the file stream.
yield
yield
is used inside a function like a return
statement. But yield
returns a generator. Generator is an iterator that generates one item at a time. A large list of value will take up a lot of memory. Generators are useful in this situation as it generates only one value at a time instead of storing all the values in memory. For example,
>>> g = (2**x for x in range(100))
will create a generator g which generates powers of 2 up to the number two raised to the power 99. We can generate the numbers using the next()
function as shown below.
>>> next(g)
1
>>> next(g)
2
>>> next(g)
4
>>> next(g)
8
>>> next(g)
16
And so on… This type of generator is returned by the yield
statement from a function. Here is an example.
def generator():
for i in range(6):
yield i*i
g = generator()
for i in g:
print(i)
Output
0 1 4 9 16 25
Here, the function generator()
returns a generator that generates square of numbers from 0 to 5. This is printed in the for
loop.