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Contributors should go through the Contributing Guide to learn how you can contribute to the project.

Learn Python 3 Logo

Learn Python 3

by Ankit Mahato [About]
Version 2022.10

How to read this book?

This book can be consumed in 3 ways:

  • A nice web interface - Link Learn Python 3 Website
  • A Downloadable PDF - Link Learn Python 3 PDF
  • Directly on GitHub - Link

Table of Contents

Introduction

Introduction to Programming Languages

In today's digital era, we depend on computers, smartphones and the internet to perform a plethora of tasks, like:

  • A mathematical task, such as finding the square root of a number or solving a set of simultaneous equations.
  • A text-based task such as reading a document and performing search/replace.
  • Streaming and playing multimedia files containing audio and video.
  • Using a search engine to find and visit a website.
  • Playing an online multiplayer game with friends.
  • and many more...

Softwares play an important role as they translate human activity into corresponding machine instructions which are executed to accomplish these tasks.

A software is a collection of programs where each program provides a sequence of instructions specifying how the computer should act.

These instructions have to be provided in machine language or low level language (0s and 1s) that is difficult to read or write for a human being.

This led to the invention of high-level programming languages in which programs can be easily written and managed. The human-readable programs written using high-level languages are converted into computer-readable machine code or byte-code using compilers or interpreters.

There are many high-level programming languages that are currently in wide use.

Some of the popular languages are Java, C, C++, C#, Go, Swift, JavaScript, PHP, Dart, Kotlin and Python.

Introduction to Python

Guido van Rossum started the development of Python in December 1989. He released the first version (0.9.0) of Python for general public on February 20, 1991.

The language evolved over the next few decades and so did its definition, the current version of which is stated below:

Python is a high-level, interpreted, object-oriented programming language with dynamic semantics.

Let us break down and analyze the above definition to gain a better understanding of Python:

High-level

Python is a high-level programming language which can be used to write a program in natural language (english) making it readable, writable, shareable and manageable.

While developing a Python program one is not required to handle the various components of computer architecture like registers, memory addresses and call stacks which have to be handled if an assembly language or a low-level language is used for development.

Python includes high-level language features like variables, data structures (lists, dictionaries, etc.), objects, expressions, modules, classes, functions, loops, threads, file handling, string handling, error handling and other computer science abstraction concepts.

Interpreted

In traditional programming languages like C or C++, codes are compiled into computer-readable machine code before it can be executed.

Python is an interpreted language where the Python interpreter reads and executes the program line by line.

The process is more time consuming compared to compiled code execution, but allows faster development as one does not have to go through the entire compilation step during testing and debugging. Also, the code can run on any platform as long as it has a valid Python installation (which includes interpreter) as there is no generation of platform dependent binaries.

Object-oriented

Python does not enforce Object-oriented programming (OOP), but completely supports it.

A programmer can define Classes specifying the data in the form of attributes (or properties) and some programming logic in the form of member functions (or methods). Once a class is defined, the user can create an instance of that class which is known as an object.

In Python, everything (int, list, dict, etc.) is an object. We will cover more about objects in detail in the later sections.

Dynamic Semantics

As Python is an interpreted language in which the code is executed line-by-line, a python statement or expression is evaluated during run-time. This allows dynamic typing (type of a variable can change over its lifetime) and creation of dynamic objects during run-time, which provides more flexibility, usability and fewer lines of code as compared to statically-typed compiled languages like C/C++.

Advantages of Python

The key advantages of Python are as follows:

1. Easy to Learn

The Python programming language is easy to learn with low technical and conceptual overhead. This makes it an ideal language for beginners to learn programming.

2. Clear Syntax & Fewer Lines of Code

Python's simple and easy to learn syntax increases code readability and leads to fewer lines of code.

A typical task which requires an average of twenty lines of code in C and seven in Java can often be done with just one line in Python.

Also, due to fewer lines of code the chances of making any error is significantly reduced.

3. Open Source

Python is an open source programming language, so anyone can view and contribute to its source code.

4. Portable & Platform Independent

The Python programming language is portable & platform independent as it can work on any Linux, MacOS or Windows device.

5. Standard Library & Python Packages

Python has a rich and extensive Standard Library, a collection of predefined functions for various tasks.

Python programmers also have at their disposal the vast ecosystem of more than 250,000 community contributed libraries in the Python Package Index (PyPI), where one can find a solution to every conceivable task.

6. Web Application Development

Some of the most popular web development frameworks (django, flask, etc.) are written in Python. This coupled with the availability of packages to connect to any database makes Python a great choice for web application development.

Installing Python in Windows

Let's start with the Python 3 installation process on Windows operating system.

Step 1: Download Installer

Download the latest Windows installer from the Python Software Foundation website.

Step 1: Download Installer

Step 2: Install Python 3

Once the download is complete double-click and run it.

Step 2: Install Python 3

Select the checkbox ✅ Add Python 3.9 to PATH. This will enable you to install python packages and run python script via command-line.

Hit 🛡️ Install Now and complete the setup.

Step 3: Verify Installation

Once the setup is complete, click on the Start menu and open Python 3.9 -> IDLE (Python 3.9 64 bit) to launch the Python interpreter.

Step 3: Launch Python Interpreter

Python 3.9 is now successfully installed on your computer.

Step 3: Verify Installation

Installing Python in macOS (Apple)

Let's start with the Python 3 installation process on macOS operating system.

Step 1: Download Installer

Download the latest macOS installer from the Python Software Foundation website.

Step 1: Download Installer

Step 2: Install Python 3

Once the download is complete double-click and run it.

Step 2: Install Python 3

Hit Continue and complete the setup.

Step 3: Verify Installation

Once the setup is complete, click on the Launchpad -> IDLE to launch the Python interpreter.

Step 3: Verify Installation

Python 3.9 is now successfully installed on your computer.

Execution Modes

After installing the latest version of the Python interpreter, we can now write and execute some basic Python codes.

There are two ways to execute a Python program:

  1. Interactive Mode: When the IDLE application is launched, the Python interpreter or the Python shell pops up on the screen. User can interact with the Python interpreter and execute statements (single line or multiline code snippets) directly in this Python shell.
  2. Script Mode: This is the most commonly used method for executing a Python program. The entire Python program is written and saved in a file (.py extension) which can be executed using the IDLE application.

Interactive Mode of Execution

Let us execute some basic Python statements and interact with the Python shell.

Launching the Python Shell

To launch the IDLE application click [Windows Start Menu Button] -> [Python 3.9 Folder] -> [IDLE (Python 3.9 64 bit)].

Launch IDLE

The Python interpreter or the Python shell will pop-up on the screen.

Python Shell

The version (3.9) of the Python interpreter is displayed at the top of the window followed by the >>> symbol which indicates that the interpreter is ready to take instructions.

Python commands or statements can be input on this prompt. The input statements are executed instantaneously and any variable assignments are retained as long as the session is not terminated.

Basic Arithmetic

Let us perform some basic arithmetic operations in the interactive mode using an integer number (2) and a floating-point number (3.5):

>>> 2 + 2
4
>>> 2 * 3.5
7.0

It can be observed that the results of each of the above computations are displayed immediately in the shell.

Storing Values/Results

Instead of immediately displaying the results, they can also be stored in variables using the assignment symbol (=) as shown below:

>>> a = 2 + 2
>>> b = 2 * 3.5

The values of a and b can be accessed later for future calculations as shown below:

>>> a
4
>>> b
7.0
>>> a * 5
20
>>> b / 3
2.3333333333333335

Basic String Operation

Interactive mode is not just restricted to basic arithmetic or assignments. Let us join two strings - "Hello, " and "world!".

>>> "Hello, " + "world!"
'Hello, world!'

The complete functionality of Python is easily accessible to a user via the Interactive Mode.

This makes it convenient for testing and instant execution of small code snippets (single line or few lines of code), a feature not available in compiled languages like C, C++ and Java.

But, the statements cannot be saved for future use and have to retyped for re-execution. This disadvantage is overcome by the use of Python in Script Mode as described in the next section.

Script Mode of Execution

To write reusable codes, script mode is the most preferred mode of code execution.

File Creation

To create a new file using the IDLE application click [File] -> [New File]

Create New File

Write a simple Python program as shown below

a = 2 + 2
a

and save the script as example.py (.py file extension for all Python scripts) using [File] -> [Save As...]

Save File

Script Execution

Now run this script using [Run] -> [Run Module].

Execute File

It can be observed that the code has been executed, but no output is displayed on the console (or the standard output) as all outputs have to be explicitly specified when running a code in the script mode.

This can be done by using the print() function which is used in Python scripts to display output on the output stream. Let us quickly add the print() function in the above code and execute it.

a = 2 + 2
print(a)

Now, when you run the script you will observe that the value of a, that is 4, is now displayed on the console.

Python Fundamentals

Tokens: Introduction

When a Python code is executed, the Python interpreter reads each logical line and breaks it into a sequence of lexical units.

These lexical units are better known as tokens - the smallest individual units of a program. They are the building blocks of a Python code and can be classified into one of the following categories:

  • Keywords : Reserved words that convey special meaning when processed by the Python interpreter.
  • Identifiers : Names defined by the programmer to refer to objects that can represent variables, functions, classes, etc.
  • Literals : Values specified in the program which belong to exactly one of the Python's built-in data types.
  • Delimiters : Symbols that denote grouping, punctuation, and assignment/binding.
  • Operators : Symbols that can operate on data and compute results.

Tokens: Keywords

Keywords are reserved words that have special meaning when processed by the Python interpreter. They are case-sensitive and cannot be used for naming identifiers (class, function, variable or structure names).

The list of keywords in Python are provided below:

True False import
from as None
and or not
in is try
except finally raise
del global nonlocal
lambda def class
with if elif
else pass for
while continue break
assert return yield
async await

Tokens: Identifiers

Identifiers are used for defining the names of Python objects such as variables, functions, classes, modules, etc. The naming convention for identifiers is as follows:

  • Must begin with a lowercase character (a-z) or an uppercase character (A-Z) or underscore sign (_).
  • Followed by any number of letters (a-z, A-Z), digits (0-9), or underscores (_).
  • Should not be a keyword.
  • No special symbols are allowed like !, @, #, $, %, etc.

Some points to keep in mind while naming identifiers:

  • Identifiers are case-sensitive in nature and any difference in case of any character refers to a different identifier. e.g., length and Length are different identifiers.
  • Identifiers differing by only underscores are different. e.g., unitlength and unit_length are different identifiers.

It is also a good practice (although not compulsory) to follow the following procedure while naming identifiers:

  • Identifiers should be named carefully with an emphasis on clarity and readability. For example, in a program that calculates the area of a rectangle, a good choice for identifier names are - length, breadth and area.
  • Class names should start with uppercase character.
  • Identifiers starting with an underscore have special meaning in a program.
  • Variable, function and method names should be in lowercase characters, with underscores separating multiple words like area_of_square, area_of_triangle, etc.

Tokens: Literals

Literals are tokens in the source code which represent fixed or constant values. They are often used in assignment statements for initializing variables or in comparison expressions.

The various types of literals available in Python are as follows:

Numeric Literals

Numeric literals are used for representing numeric values in the source code. They can be of three types - integers, float point numbers and imaginary numbers.

Integer Literals

Integer literals are numbers without any fractional component.

In Python, integer literals can be written in four positional (base) numeral systems:

i. Decimal or base-10 Integer

A decimal integer literal consists of one or more digits (0-9) and cannot have any zeros preceding the first non-zero digit, except when the number is 0.

Example base-10 integers:

34
3283298
864
0

092 is not a valid decimal integer literal as a zero precedes the first non-zero digit 9.

ii. Binary or base-2 Integer

A binary integer or base-2 integer begins with 0b or 0B followed by binary digits 0-1.

For example, 27 can be written as a binary integer literal 0b11011.

iii. Octal or base-8 Integer

An octal integer or base-8 integer begins with 0o or 0O followed by octal digits 0-7.

For example, 27 can be written as an octal integer literal 0o33.

iv. Hexadecimal or base-16 Integer

A hexadecimal integer or base-16 integer begins with 0x or 0X followed by digits 0-9 or letters A-F (case insensitive).

For example, 27 can be written as a hexadecimal integer literal 0x1B or 0x1b.

Thus, it can be observed that number 27 can be written in the program as 27 (decimal), 0b11011 (binary), 0o33 (octal) or 0x1B (hexadecimal).

Underscores in Integer Literals

An optional character _ (underscore) is also allowed in an integer literal to group digits for enhanced readability.

One underscore can occur between digits, and after base specifiers like 0o.

They are ignored while determining the actual numerical value of the literal.

Some valid underscore usages are - 10_00_00_000, 0b_1110_0101, 0x23_123.

Floating Point Literals

Floating point literals are real numbers present in the source code. They contain fractional component and/or exponential component.

The fractional component includes the digits after the decimal point (.).

Example floating point literals:

3.4
.4
8.
3.4E2
3.4e-2

In the above example, .4 is equivalent to 0.4 and 8. is equivalent to 8.0.

The exponential component can be identified by the letter e or E followed by an optional sign (+ or -) and digits (0-9). This exponent is equivalent to multiplying the real number with the power of 10.

For example, 3.4E2 is equivalent to 3.4 x 10^2 or 340.0, whereas 3.4e-2 is equivalent to 3.4 x 10^-2 or .034.

Imaginary Literals

To specify complex numbers and perform complex number mathematics, Python supports imaginary literals which are given by real or integer number followed by the letter j or J which represents the unit imaginary number.

Example imaginary literals:

3.5j   
15.j    
12j     
.005j   
3e100j   
3.5e-10j

Points to Note

In Python,

  • there is no specialized literal such as a complex literal. A complex number is actually represented in the program using an expression comprising a real number (integer/float numeric literal) and an imaginary number (imaginary literal). For example, 1 + 2j consists of an integer literal (1) and a imaginary literal (2j).
  • numeric literals do not include the minus sign (-). - is actually a unary operator it combines with a numeric literal to represent negative numbers. For example, in -3.14 the numeric literal is 3.14 and - is an operator.

Boolean Literals

The reserved words True and False are also boolean literals which can be used to specify the truth value in a program.

String Literals

String literals are texts which can be specified in a variety of ways in Python:

  • Single quotes: 'python'
  • Double quotes: "python"
  • Triple quoted: '''Triple python''', """Three python""".

Triple quoted strings can also span multiple lines.

Example:

s = "I am a String"  

s1 = """A
multiline
String"""

s2 = '''Also a
multiline
String'''

The backslash (\) character can be used in a string literal to escape characters that otherwise have a special meaning, such as newline, linefeed, or the quote character.

Escape Sequence Meaning
\\ Backslash (\)
\' Single quote (')
\" Double quote (")
\a ASCII Bell (BEL)
\b ASCII Backspace (BS)
\f ASCII Form-feed (FF)
\n ASCII Linefeed (LF)
\r ASCII Carriage Return (CR)
\t ASCII Horizontal Tab (TAB)
\v ASCII Vertical Tab (VT)

Although \' and \" can be used to specify quote characters, Python allows embedding double quotes inside a single-quoted string ('My name is "Python".') and single quotes inside a double-quoted string ("Python's World").

String literals also support unicode characters which can be specified using \u escape sequence followed by the 4 letter unicode.

>>> print("E = mc\u00B2")
E = mc²

In the above example, \u00B2 is the unicode character which represents the 'SUPERSCRIPT TWO'.

Special Literal

None is a special literal which is used to denote the absence of value.

It should not be confused with 0 as 0 is an integer literal with a defined finite value, whereas None implies nothingness.

>>> a = None
>>> a
>>>

In the above example, the Python shell does not display any value of a as it is assigned as None which has no value.

Collection of Literals

Python has the provision for specifying a collection of literals in the source code using a special syntax known as "displays".

One can create specialized containers like list, set and dictionary using this syntax.

Some example collection of literals (displays) are provided below:

  • List: a = ['a', 'b', 'c']
  • Set: a = {'a', 'b', 'c'}
  • Dictionary: a = {'a':1, 'b':2, 'c':3}

List, set and dictionary will be covered in detail in later chapters.

Tokens: Operators

Operators are tokens which can be combined with values and variables to create expressions which evaluate to a single value. Python supports a rich set of operators:

+       -       *       **      
/       //      %      @        
<<      >>      
&       |       ^       ~       
:=      <       >       
<=      >=      ==      !=

Each of the above operators are covered in detail in the chapter - Operators.

Tokens: Delimiters

Delimiters are tokens which are useful for organizing a program and are used in statements, expressions, functions, literal collections, and various other code structures.

They can be classified based on utility as follows:

Grouping

(), [] and {} are delimiters used for:

  • grouping expressions which can be spread across multiple physical lines.
  • creating collection of literals like list display, dictionary display, set display.
  • creating parenthesized sub-expression having the highest operator precedence (evaluated first) in a complex expression.

Example

days = ['Sunday', 'Monday', 
        'Tuesday', 'Wednesday', 
        'Thursday', 'Friday', 
        'Saturday']

sum_6 = (1 + 2 +
         3 + 4 +
         5 + 6)

is equivalent to

days = ['Sunday', 'Monday', 'Tuesday', 'Wednesday', 'Thursday', 'Friday', 'Saturday']

sum_6 = (1 + 2 + 3 + 4 + 5 + 6)

Punctuation, Decoration and Annotation

Tokens in Python which are used for punctuation, decoration and annotation are:

.       ,       :
;       @       ->

Assignment/Binding

The assignment or binding delimiters are used for binding objects to names via assignment statements. The complete list of tokens are provided below:

=       +=      -=      *=
/=      //=     %=      **=
@=      &=      |=      ^=
<<=     >>=

Except =, the rest of the tokens have an operator followed by = character.

These delimiters are also known as augmented assignment operators as they perform an operation in combination with assignment.

Character Set

A set of valid characters that a programming language recognizes is known as its character set.

Python is a new age programming language which supports Unicode encoding standard. The default encoding for Python source code is UTF-8 (Unicode Transformation Format – 8-bit) which enables developers to use Unicode characters not only as literals, but also as identifiers.

This makes Python one of the very few programming languages that support multiple languages as shown in the example below:

Code

message = "हिन्दी में print करे"
print(message)

 = 1  # Devanagari Letter KA
 = 2  # Bengali Letter KA
 = 3  # Tamil Letter KA
 = 4  # Gujarati Letter KA
print( +  +  + )

Output

हिन्दी में print करे
10

Blocks and Indentation

In traditional programming languages like C++ or Java, programs are organised in form of code blocks.

Each code block contains one or more statements which are enclosed between braces - { and } and are executed sequentially.

A sample C++/Java code is provided below which checks for an input x.

C++

if (x < 10) {
    cout << "x is less than 10" << endl;
    if (x <= 5) {
        cout << "x is less than or equal to 5" << endl;
    }
    else {
        cout << "x is more than 5 but less than 10" << endl;
    }
}
else {
    cout << "x is not less than 10" << endl;
}

Java

if (x < 10) {
    System.out.println("x is less than 10");
    if (x <= 5) {
        System.out.println("x is less than or equal to 5");
    }
    else {
        System.out.println("x is more than 5 but less than 10");
    }  
}
else {
    System.out.print("x is not less than 10");
}

It can be seen how indentations (tab at the beginning of line) are added (not required by programming language) to the code to increase readability, which helps in guiding readers through the code.

Python

Code blocks in Python are inspired by this idea as it makes it easier to understand a Python code.

A block of code is denoted by line indentation, typically 4 spaces (preferred) or a tab. This indentation is used to determine the logical group of statements, with all statements within a group having the same level of indentation.

The corresponding Python code for the above C++/java examples is provided below.

Notice how the code blocks are indented according to the logic.

if x < 10:
    print("x is less than 10")
    if x <= 5:
        print("x is less than or equal to 5")
    else:
        print("x is more than 5 but less than 10")
else:
    print("x is not less than 10")

Comments

Python supports single-line comments and multi-line comments to enhance code readability via adding documentation.

Single Line Comments

A single line comment begins with #. Everything between # and the end of line is ignored by the Python interpreter.

# A single line comment.
a = 1 # assign a

Multiline comments

A multiline comment begins with ''' or """ and ends with the same.

"""
I am
a multiline
comment.
"""

'''
I am
also a multiline
comment.
'''

As compared to single line comments, multiline comments should begin at the same indentation level corresponding to their code block.

For example,

"""
Begin program
here
"""
if x < 10:
    """
    Enter code block when x
    is less than 10
    """
    print("x is less than 10")
    if x <= 5:
        """
        Enter code block when x
        is less than or equal to 5
        """
        print("x is less than or equal to 5")
    else:
        """
        Enter code block when x
        is more than 5 but less than 10
        """
        print("x is more than 5 but less than 10")
else:
    """
    Enter code block when x
    is not less than 10
    """
    print("x is not less than 10")

Variables, Objects & Data Types

What are Objects & Variables?

A program is a sequence of instructions which often acts on information (data) provided by the user.

The process of creating, storing and manipulating this data helps in the computation of new data or the end result.

Variables are the fundamental building blocks of a program which provide a way to store, access and modify values during the life-cycle of a program.

Each variable has:

  • a name (handle),
  • a type or data-type (kind of data), and
  • a value (actual data).

In traditional programming languages like Java or C++, the type of the variable is pre-defined.

For example, if you want to use the value 1 inside the program, you can store it in a variable named a of type int.

int a = 1;

This a is synonymous to a box of fixed dimensions (fixed type) holding something (value 1) inside it.

Box 'a'

In case we want to change the contents of the box, we can replace it with something similar (same type).

a = 2;

Filled box 'a'

The contents of this box can be replicated and placed in a similar (same type) box:

int b = a;

Copy box 'a' contents

Multiple boxes can exist, each containing an item having the same value.

int x = 3;
int y = 3;
int z = 3;

Boxes 'x', 'y' & 'z'

As shown above, the programming languages in which the variables (named boxes) are declared along with their types (size of the boxes) are known as statically typed languages.

The size of these boxes cannot change later in the program until the variable is re-initialized with the same name and different type.

Python is a dynamically-typed language, where every value or data item (of any type like numeric, string, etc.) is an object.

The variable names are just name-tags pointing to the actual object containing data of any type.

As there is no need of any variable declaration in Python before usage, there is no concept of default value (an empty box or null) which exists in other programming languages.

Whenever a new object is created in Python, it is assigned a unique identity (ID) which remains the same throughout the lifetime of that object. This ID is the address of the object in memory and the built-in function id() returns the value of this address.

>>> a = 1
>>> id(a)
140407745943856
>>> a = 2
>>> id(a) 
140407745943888

In the above example, the ID of a changes as it points to a new object (2).

>>> b = a
>>> id(b)
140407745943888

Also, when a is assigned to b, instead of creating a new copy, b points to the same object as a.

Variables & Assignment Statements

A variable is uniquely identified by a name (identifier) and follows the same naming convention:

  • Must begin with a lowercase character (a-z) or an uppercase character (A-Z) or underscore sign (_).
  • Followed by any number of letters (a-z, A-Z), digits (0-9), or underscores (_).
  • Should not be a keyword.
  • No special symbols are allowed like !, @, #, $, %, etc.

Assignment

Variables can be bound to a reference of an object (of any type) using assignment statements.

You can create an object (data) and bind it's reference to a variable using equal sign (=):

count = 100       # integer
pi    = 3.141     # real number
name  = "Python"  # string

Here, L-value refers to the assignable variables (count, pi, name) on the left side of the assignment and R-value refers to the expression on the right side of the assignment operator that has a value (100, 3.141, "Python").

As variables are just references, you can rebind them to another object of same or different type:

a = 100       # integer 
a = 3.141     # real number
a = "Python"  # string

Deletion

The del statement can be used to unbind the reference to an object.

>>> a = 10
>>> del a
>>> a
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
NameError: name 'a' is not defined

Accessing a results in a NameError as the reference (variable) to the object holding value 10 is deleted.

The object is also automatically cleaned up from the memory if there is no other variable referencing to it (garbage collection).

Multiple Assignment

In Python, multiple assignment can be used to condense variables which are set to the same value:

>>> x = y = z = 'foo'
>>> x
'foo'
>>> y
'foo'
>>> z
'foo'

Tuple Swapping

In Python, a temporary variable is not required to swap values of two variables. Values can be directly swapped (tuple swapping) as shown below:

>>> a = 'Hello'
>>> b = 'World'
>>> b, a = a, b
>>> a
'World'
>>> b
'Hello'

Built-in Data Types

In Python, the type of a data (or value) is not linked to the variable, but to the actual object which contains it. This type is also known as the object's data type and is used for identifying the operations that can be performed on the data.

The following built-in data types are available in Python:

  • Numeric Types - int, float, complex, bool
  • Sequence Types - list, tuple, str
  • Set Type - set
  • Mapping Type - dict
  • Special Type - None

Often sequence, set and mapping types are also collectively known as iterables as they are a collection of items on which a user can traverse (iterate).

Numeric Types - int, float, complex, bool

Numeric data types are used for storing the following types of numbers:

Integer Numbers

Objects holding integer numbers like -1, 0, 200 are of int data type.

Real or Floating-point Numbers

Objects holding real or floating point numbers like -1.1, 3e2, 20.0 are of float data type.

Complex Numbers

Objects storing complex numbers like 2 + 1j, -3j, -1 + 2J are of type complex.

Each complex number has two parts, the real part which is a numeric integer or floating point literal, and the imaginary part which is an imaginary literal.

Boolean

The boolean data type (bool) is a subtype of int. It stores the evaluated value of expressions represented as keywords - True (integer value 1) and False (integer value 0).

Sequence Types - str, list, tuple

An ordered collection of items where each item can be accessed using an integer index is known as a sequence. The following three sequence data types are available in Python:

String

A string (str data type) is a sequence of zero or more unicode characters enclosed within a pair of single (') or double (") quotes.

Some example strings are - "42", 'hello', "python".

List

A list is sequence of items of same or different data types which are enclosed within brackets - [ ].

Some example lists are - [1, 2, 3], ['abc', 23, 3.14], ['edpunk', 'python'].

Tuple

A tuple is an immutable sequence of items of same or different data types which are enclosed within parentheses - ( ).

Some example tuples are - (1, 2, 3), ('abc', 23, 3.14), ('edpunk', 'python').

Set Type - set

A set is an unordered collection of unique items of same of different data types which are enclosed in curly braces - { }.

Some example sets are - {1, 2, 3}, {'abc', 23, 3.14}, {'edpunk', 'python'}.

Mapping Type - dict

dict is a mapping data type which stores values in the form of key-value pairs.

It is used for representing data where you can quickly access the value (any data type) corresponding to a key (any data type except list, set or dict), just like a dictionary where you can lookup the meaning of a given word.

Keys and corresponding values are separated by colon (:).

The key-value pairs are separated by comma (,) and enclosed within curly braces - { }.

Some example dictionaries are - {1: "a", 2: "b", 3: "c"}, {"name": "edpunk", "language": "python"}.

Special Type - None

None is a special data type which is used to denote the absence of value in an object.

It is neither 0 nor False as these are defined finite values, whereas None implies nothingness.

Type Checking

The built-in type() function can be used to fetch the data type of an object.

Examples:

>>> count = 100
>>> type(count)
<class 'int'>

>>> pi = 3.141
>>> type(pi)
<class 'float'>

>>> name = "Python"
>>> type(name)
<class 'str'>

This function can be used along with the is operator in an expression to test whether the object is of the given type.

>>> count = 100
>>> type(count) is int
True

The in operator can be used along with the type() function to test if the data type is one of the mentioned types.

# count is of type int or float
>>> type(count) in (int, float)
True

Type Casting

The process of converting the data type of an object from one type to another is known as Type Casting or Type Conversion.

The two kinds of type casting supported in Python are:

Implicit Type Casting

The Python interpreter automatically converts the data type without the need of user intervention when evaluating expressions to determine the final data type.

In the below example the final type of c is automatically determined as float by the Python interpreter.

>>> a = 1   # int
>>> b = 2.0 # float
>>> c = a + b
>>> c
3.0
>>> type(c)
<class 'float'>

Explicit Type Casting

When the type conversion is explicitly specified by the user using the various built-in functions available in Python, it is known as explicit type casting.

The built-in functions which can be used for explicit type casting are as follows:

1. int()

Creates an int from a bool, float or str containing integer characters (with or without sign).

>>> int(True)
1
>>> int(2.3)
2
>>> int("2")
2

2. float()

Creates a float from a bool, int or str containing floating point literals (with or without sign).

>>> float(True)
1.0
>>> float(2)
2.0
>>> float("2.3")
2.3

float() also accepts the following string inputs -

  • "Infinity"
  • "inf"
  • "nan" (not a number).
>>> float("Infinity") > 1
True
>>> float("nan")  
nan

Floating point literals can also contain the following characters -

  • ., which denotes the fractional part of a number.
  • e or E, which denotes the exponent part of a number.
>>> float("3.14")
3.14
>>> float("10.")
10.0
>>> float("1e100") 
1e+100
>>> float("3.14e-10")
3.14e-10

3. str()

Converts any object into a str.

>>> str(2)
'2'
>>> str([1, 2, 3, 4])
'[1, 2, 3, 4]'

4. tuple()

Creates a tuple from an iterable of type str, list, set or range.

>>> tuple('hello')
('h', 'e', 'l', 'l', 'o')
>>> tuple([1, 2, 3, 4])
(1, 2, 3, 4)
>>> tuple(range(6))
(0, 1, 2, 3, 4, 5)

5. list()

Creates a list from an iterable of type str, tuple, set or range.

>>> list('hello')
['h', 'e', 'l', 'l', 'o']
>>> list({1, 2, 3, 4})
[1, 2, 3, 4]
>>> list(range(6))
[0, 1, 2, 3, 4, 5]

6. set()

Creates a set from an iterable of type str, tuple, list or range.

>>> set('hello')
{'o', 'e', 'l', 'h'}
>>> set([1, 2, 3, 4])
{1, 2, 3, 4}
>>> set(range(6))
{0, 1, 2, 3, 4, 5}

Mutable & Immutable Data Types

Immutable Data Types

A data type is said to be immutable when the value of an object of that type cannot be modified.

The following data types are immutable:

  • int
  • float
  • complex
  • bool
  • tuple
  • str
  • None

You might be wondering if some of the above types are immutable then how are we able modify the values of variables?

In case of variable re-assignment, the original objects are not modified, but new objects (with new values) are created in a new memory location and are bound to the variables. The object containing the old value is destroyed if no other variable references it.

Let us take an example,

>>> a = 1
>>> id_a = id(a)
>>> a = 2
>>> id_a2 = id(a)
>>> id_a == id_a2
False

You can witness in the above example how the object containing the value 1 is different from the object containing the value 2, and a points to the latest object.

Sequence data types like strings and tuples are also immutable, i.e., no modifications are permitted to any item once it is created and any attempt to do so raises an error.

>>> s = "Hello"
>>> s[1] = "P"
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'str' object does not support item assignment
>>> t = (1, 2, 3)
>>> t[1] = 0
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'tuple' object does not support item assignment

Although, similar to numeric types the variables can be re-assigned to new sequences.

>>> s = "Hello"
>>> id_s = id(s)
>>> s = "Help"
>>> id_s2 = id(s)
>>> id_s == id_s2
False

>>> t = (1, 2, 3)
>>> id_t = id(t)
>>> t = (0, 2, 3)
>>> id_t2 = id(t)
>>> id_t == id_t2
False

Mutable Data Types

In Python, the following data types are mutable, i.e., any modification does not create a new object but modifies the existing object:

  • list
  • set
  • dict

Let us take a list and modify its contents.

>>> l = [1, 2, 3]
>>> id_l = id(l)
>>> l[0] = 0
>>> l
[0, 2, 3]
>>> id_l2 = id(l)
>>> id_l == id_l2
True

Let us take an example of a dictionary and add a new key:value pair.

>>> d = {"a": "apple", "b": "boy"}
>>> id_d = id(d)
>>> d["c"] = "cat"
>>> d
{'a': 'apple', 'b': 'boy', 'c': 'cat'}
>>> id_d2 = id(d)
>>> id_d == id_d2
True

Let us take an example of a set and add new item.

>>> s = {"apple", "bat"}
>>> id_s = id(s)
>>> s.add("cat")
>>> s
{'cat', 'apple', 'bat'}
>>> id_s2 = id(s)
>>> id_s == id_s2
True

In the above examples, the id of the objects (list, dict, set) do not change, which implies that no new objects are created and the original objects are modified.

Input / Output

How to Accept User Input

input() function is used to accept new input data from the user.

When this function is encountered in the code, the python interpreter waits for the user to type a response which is read as a string and assigned to a variable.

>>> name = input()
edpunk
>>> name
'edpunk'

The function also has an optional string argument which is used as a prompt message for the user.

>>> name2 = input("Enter name: ")
Enter name: EdPunk
>>> name2
'EdPunk'

User input can be converted into integer or floating point numbers using the type conversion functions int() and float().

>>> num = int(input("Enter n: "))
Enter n: 10
>>> type(num)
<class 'int'>
>>> num
10

>>> pi = float(input("Enter pi: "))
Enter pi: 3.14
>>> type(pi)
<class 'float'>
>>> pi
3.14

Displaying Output

The built-in print() function is used to display an output (value of variables, expressions, etc.) on the standard output.

Let us go through a program which computes the area of a rectangle and displays it:

Code

length = 10
breadth = 5
area = length * breadth
print("Area:", area)

Output

Area: 50

print() function can also be used to output the value of multiple objects when they are provided as arguments to the function.

Code

a = 2 + 2
b = 2 * 3.5
print(a, b)

Output

4 7.0

In the above code, the values of a and b are separated by a blank space (the default value of sep).

This property can be modified by providing any user defined separator using the sep option.

Let us modify the code and provide "," as the separator.

Code

a = 2 + 2
b = 2 * 3.5
print(a, b, sep=",")

Output

4,7.0

When expressions are provided as arguments to the print() function, output is the evaluated value of those expressions.

For example,

Code

print(2 + 2)
print(2 * 3.5)
print("Hello, " + "world!")

Output

4
7.0
Hello, world!

In the above code snippet, each print() function invocation creates a new line of output. This is because end parameter has the newline character ('\n') as the default value in the print() function.

This can be modified by the user as shown below:

Code

print(2 + 2, end=",")
print(2 * 3.5, end=";")
print("Hello, " + "world!")

Output

4,7.0;Hello, world!

Note

All non-keyword arguments or expressions are converted to strings and written to the output stream by the print() function. They are separated by sep and followed by end. An empty print() invocation writes end parameter (an empty line as end defaults to the newline character '\n').

Operators & Expressions

Introduction to Operators

Operators are symbols that perform a single simple task or operation on one or more values resulting in a single evaluated value.

The values on which these operators are applied are called operands.

Unary Operators

Unary operators are applied on a single operand positioned on right side of the operator.

Following are some unary operators available in Python:

  • + (plus): The unary + operator does not change the value of the operand.
  • - (minus): The unary - operator changes the sign of the operand.
  • ~ (bitwise NOT): The unary ~ results in the bit-wise inversion of the integer operand. The bit-wise inversion of x is defined as -(x+1).
>>> x = 5
>>> -x
-5
>>> +x
5
>>> ~x
-6

Binary Operators

Binary operators are applied on two operands.

For example, arithmetic operators (+, , *, /) evaluate the result of mathematical computation of two values.

Operators in Python

A rich set of operators are available in Python which can be categorized as follows:

  • Arithmetic Operators - +, , *, /, %, **, //
  • Relational Operators - ==, !=, >, >=, <, <=
  • Assignment Operators - +=, -=, *=, /=, %=, **=, //=
  • Logical Operators - not, or, and
  • Identity Operators - is, is not
  • Membership Operators - in, not in
  • Bitwise and Shift Operators - &, |, ^, ~, <<, >>

Arithmetic Operators

Arithmetic operations can be performed in Python using the following arithmetic operators:

Addition

The + operator adds the values of numeric operands.

>>> 2 + 3 
5
>>> 2 + 3.0
5.0 

In case the operands are of type str, list or tuple, the + operator concatenates these two sequences or strings.

>>> 'edpunk' + 'python' 
'edpunkpython'
>>> ["ed", "punk"] + ["python", ]
['ed', 'punk', 'python'] 

Subtraction

The - operator subtracts the value of operand on right from the value of operand on left.

>>> 2 - 3 
-1

Multiplication

The * operator multiplies the values of numeric operands.

>>> 2 * 3 
6

In case the operands are of type str, list or tuple, the * operator returns a sequence or string self-concatenated the specified number of times.

>>> "python" * 3 
'pythonpythonpython'
>>> ['ed', 'py'] * 3
['ed', 'py', 'ed', 'py', 'ed', 'py']

Division

The / operator divides the value of operand on left by the value of operand on right and returns the real number quotient.

>>> 6 / 2
3.0
>>> 5 / 2
2.5  

Floor Division

The // operator divides the value of operand on left by the value of operand on right and returns the integer quotient.

>>> 5 // 2 
2

Modulus

The % operator divides the value of operand on left by the value of operand on right and returns the remainder.

>>> 5 % 2
1

Exponent

The ** operator raises the left operand to the power of the right operand.

>>> 5 ** 2
25  

Relational Operators

Relational operators are useful for comparing the values of the operands to determine their relationship. Following relational operators are available in Python:

Equals to

The == operator returns True if the value of operand on left is same as the value of operand on right.

>>> 2 == 2
True
>>> 2 == 3
False

In case of sequence operands like str, list or tuple, the result is True if both the sequences are exactly the same.

>>> "python" == "python"
True
>>> "pypi" == "python"
False
>>> [1, 2, 3] == [1, 2, 3]
True

As a sequence is an ordered collection of items, so the order in which the items are positioned is very important.

>>> [2, 1, 3] == [1, 2, 3]
False

Not equal to

The != operator returns True if the value of operand on left is not equal to the value of operand on right.

>>> 2 != 2
False
>>> 2 != 3
True
>>> 'py' != 'oy'
True
>>> [2, 1, 3] != [1, 2, 3]
True
>>> [1, 2, 3] != [1, 2, 3]
False

Greater than

The > operator returns True if the value of operand on left is greater than the value of operand on right.

>>> 3 > 2
True
>>> 2 > 2
False

In case of strings operands, > operator perform comparison according to the Unicode code point (integer) of each character one-by-one.

The Unicode code point of a character can be obtained using the ord() function in Python.

The code point of first character of both operands are compared. In case they are equal, the code point of next character of both operands are compared and the process continues.

For example,

>>> "python" > "Python"
True

The code point of "p" (112) is greater than the code point of "P" (80). As 112 is greater than 80 the expression evaluates to True.

Let us take another example:

>>> "pYthon" > "python"
False

The code point of first character is same (112), so the next set of characters are compared. The code point of "Y" (89) is not greater than the code point of "y" (121) so the expression evaluates to False.

If two string operands p and q are of unequal lengths (len(p) < len(q)) and p is a substring of q such that q = pt where t is any string of length greater than 0, then q > p returns True.

>>> "python" > "py"
True

In case of sequence operands like list or tuple, the items are compared one-by-one starting from index 0.

>>> ["p","py","PY"] > ["p","Py","PY"]
True
>>> [1, 3] > [1, 2]
True
>>> [1, 3, 4] > [1, 2]
True

In the above examples, "py" is greater than "Py" and 3 is greater than 2 respectively.

If two sequences are of unequal lengths and the smaller sequence is the starting subsequence of the larger one, then the larger sequence is considered greater than the smaller one.

>>> [1, 2, 4] > [1, 2]
True

Greater than or equal to

The >= operator returns True if the value of operand on left is greater than or equal to the value of operand on right.

>>> 3 >= 3
True
>>> 2 >= 3
False

In case of sequence operands (str, list, tuple), the comparison operation performed is along the same lines as the > operator discussed above.

>>> "python" >= "Python"
True
>>> "python" >= "python"
True
>>> ["py", "py", "PY"] >= ["py", "Py", "PY"]
True
>>> [1, 2] >= [1, 2]
True
>>> [1, 2, 4] >= [1, 2]
True

Less than

The < operator returns True if the value of operand on left is less than the value of operand on right.

>>> 2 < 3
True
>>> 3 < 3
False

In case of sequence operands (str, list, tuple), the comparison operation performed is along the same lines as the > operator discussed above.

>>> "file" < "Pile"
False
# f(102) is > P(80)
>>> "py" < "python"
True
>>> ["Py", "PY"] < ["py", "PY"]
True
>>> ['a', 2] < ['a', 3]
True
>>> [1, 2] < [1, 2, 4]
True

Less than or equal to

The <= operator returns True if the value of operand on left is lesser than or equal to the value of operand on right.

>>> 2 <= 3
True
>>> 3 <= 3
True

In case of sequence operands (str, list, tuple), the comparison operation performed is along the same lines as the > operator discussed above.

>>> "file" <= "Pile"
False
# f(102) is > P(80)
>>> "py" <= "python"
True
>>> ["Py", "PY"] <= ["py", "PY"]
True
>>> ['a', 3] <= ['b', 2]
True
>>> [1, 2] <= [1, 2, 4]
True

Assignment Operators

The assignment symbol (=) serves as a delimiter between the name and value in an assignment statement.

It binds (or rebinds) a value (data, variable, expression) on the right to the target variable on the left.

>>> x = 1
>>> x
1
>>> y = x
>>> y
1
>>> y = "python"
>>> y
'python'

Binary operators can be combined with the assignment symbol to create Augmented Assignment Operators.

These operators perform the binary operation on the two operands and assign the result to the original target (left operand).

If <op> is a binary operator, then the expression a <op>= b containing the augmented assignment operator is equivalent to a = a <op> b.

+=

The += operator adds a value (right operand) to the variable (left operand) and assigns the result to that variable.

>>> a = 2
>>> a += 3
>>> a
5
>>> x = "hello"
>>> y = "world"
>>> x += y
>>> x
'helloworld'

-=

The -= operator subtracts a value (right operand) from the variable (left operand) and assigns the result to that variable.

>>> a = 3
>>> a -= 2
>>> a
1

*=

The *= operator multiplies a value (right operand) to the variable (left operand) and assigns the result to that variable.

>>> a = 3
>>> a *= 2
>>> a
6
>>> x = "hi"
>>> x *= 3
>>> x
'hihihi'

/=

The /= operator divides the variable (left operand) by a value (right operand) and assigns the result to that variable.

>>> a = 4
>>> a /= 2
>>> a
2.0

//=

The //= operator floor divides the variable (left operand) by a value (right operand) and assigns the result to that variable.

>>> a = 5
>>> a //= 2
>>> a
2

**=

The **= operator raises the variable (left operand) to a power (right operand) and assigns the result to that variable.

>>> a = 4
>>> a **= 2
>>> a
16

%=

The %= operator computes modulus of the variable (left operand) and a value (right operand) and assigns the result to that variable.

>>> a = 4
>>> a %= 3
>>> a
1

Logical Operators

Expressions using logical operators evaluate to a boolean value (True or False) based on the logical state of the operands.

Logical State of Operands

In Python, all values except 0, None, False, "", '', (), [], {} have their logical state as True.

bool() built-in function can be used to determine the logical state of literals, variables or expressions.

The logical state of the following literals is False.

>>> bool(False)
False
>>> bool(0)
False
>>> bool([])
False
>>> bool(None)
False
>>> bool("")
False
>>> bool([])
False
>>> bool(())
False
>>> bool({})
False

Some example literals having boolean state as True are provided below.

>>> bool(True)
True
>>> bool(1)
True
>>> bool(2.0)
True
>>> bool(100)
True
>>> bool("python")
True
>>> bool(["py", "thon"])
True

not

The logical state of an operand can be reversed (False to True, and vice versa) using the logical not operator.

>>> n = 5
>>> bool(n)
True
>>> bool(not n)
False

or

The logical or operator returns True if the logical state of any of the two operands is True.

>>> True or False
True
>>> bool(1 or 0)
True
>>> False or False
False

and

The logical and operator returns True if the logical state of both the operands is True.

>>> True and True
True
>>> True and False
False
>>> bool(10 and 20)
True
>>> bool(1 and 0)
False

Identity Operators

We have already witnessed how Python treats every value or data item as an object.

The relational operator == can be used to test whether the operands contain the same value.

>>> n = 1
>>> n2 = 1
>>> n == n2
True

This operator however does not check if both the operands are referring to the same object or different objects.

The identity operators is and is not are used to test whether two objects have the same or different identity (pointing to the same location in memory) respectively.

a is b is equivalent to id(a) == id(b), where id() is the built-in function which returns the identity of an object.

>>> n = 1
>>> n2 = 1
>>> n is n2
True

In the above example, both variables n and n2 point to that same memory location (same object).

>>> l = [1, 2, 3]
>>> l2 = [1, 2, 3]
>>> l == l2
True
>>> l is l2
False

In the above example, both lists l and l2 although contain items with same values, are actually two different objects occupying different memory locations.

Membership Operators

The operators in and not in test whether a value is present or not present in an iterable (string, list, tuple, set, dictionary).

>>> 1 in [1, 2, 3]
True
>>> "ed" in ["ed", "py", "hi"]
True
>>> "ed" in ("ed", "py", "hi")
True
>>> 'ed' in {'ed': 1, 'py': 2}
True

>>> "pen" not in ["pencil", "ink"]
True
>>> "pen" not in ["pen", "ink"]
False

Expressions

Literals (constants), identifiers (variables) and operators can be combined to form an expression which always evaluates to a single value.

For example, 40 + marks is an expression containing a literal (40), a variable (marks) and an operator (+).

Some valid expressions are provided below:

  • 10
  • a
  • -a
  • a - 10
  • a + b
  • 4.0 * 3.5
  • a == b
  • c in d
  • a is T
  • "Hello" + "World"
  • 15 - a*4
  • 3*num + 9/4 - 10%count**2

As shown above, standalone literals (like 10) and variables (like a) are considered as expressions, but standalone operators are not expressions.

Chained Expression

Comparison operators can be chained together in Python.

For example, lower <= age <= upper is a valid chained expression which is equivalent to the expression -

lower <= age and age <= upper.

If a, b, c, …, y, z are expressions and op1, op2, …, opN are comparison operators, then the chained expression a op1 b op2 c ... y opN z is equivalent to a op1 b and b op2 c and ... y opN z.

Conditional Expression

Python does not have ternary operators (?:) like other programming languages. Hence, the keywords if and else are used to create conditional expressions which evaluates to a value based on the given condition.

For example,

var = t_val if cond else f_val

If the above condition cond evaluates to True, then the variable var is assigned t_val, else it is assigned f_val.

>>> value = 1 if 2 > 3 else -1
>>> value
-1

Operator Precedence with Examples

While studying mathematics in middle school, we came across the BODMAS (Bracket, Of, Division, Multiplication, Addition, and Subtraction) rule which helps us in understanding how mathematical expressions are computed in the presence of multiple operators (of, x, /, +, -).

In Python, we have a large number of operators and a similar rule to determine the order of evaluation of an expression. This is known as operator precedence where the operator with higher precedence is evaluated before the operator with lower precedence in an expression.

The table below presents the precedence of operators in Python from highest to lowest. Operators in the same row have the same precedence, so in such cases the expression is evaluated from left to right.

Operator Description
(expressions...) Parenthesized expression (Group)
** Exponentiation
+x, -x, ~x Unary positive, Unary negative, Bitwise NOT
*, @, /, //, % Multiplication, Matrix multiplication, Division, Floor division, Remainder
+, - Addition, Subtraction
<<, >> Shifts
& Bitwise AND
^ Bitwise XOR
| Bitwise OR
in, not in, is, is not, <, <=, >, >=, !=, == Membership, Identity & Comparisons
not x Boolean NOT
and Boolean AND
or Boolean OR
:= Assignment expression

Exercises

Example 1

Evaluate the expression

15 - 2 * 4

Solution

Step: * has higher precedence over -
15 - 2 * 4
= 15 - 8
= 7

Example 2

Evaluate the expression

15 - 2 + 4

Solution

Step: - and + have the same order of precedence so the expression is evaluated left to right
15 - 2 + 4
= 13 + 4
= 17

Example 3

Evaluate the expression

15 - (2 + 4)

Solution

Parenthesized expression (...) has the highest precedence so + is evaluated first
15 - (2 + 4)
= 15 - 6
= 9

Example 4

Evaluate the expression

3 * 2 + 9 / 4 - 10 % 2 ** 2

Step 1

** takes precedence
3 * 2 + 9 / 4 - 10 % 2 ** 2
= 3 * 2 + 9 / 4 - 10 % 4

Step 2

*, / and % have the same precedence so they are evaluated left to right.
3 * 2 + 9 / 4 - 10 % 4
= 6 + 2.25 - 2

Step 3

+ and - evaluation
6 + 2.25 - 2
= 6.25

Example 5

Evaluate the expression

20 / 4 // 2 * 2 - 4 + 20

Step 1

*, /, // and % have the same precedence so they are evaluated left to right.
20 / 4 // 2 * 2 - 4 + 20
= 5 // 2 * 2 - 4 + 20
= 2 * 2 - 4 + 20
= 4 - 4 + 20

Step 2

+ and - evaluation
4 - 4 + 20
= 20

Example 6

Evaluate the expression

not 6 <= 4 and 3 ** 3 > 12 / 3

Step 1

** takes precedence
not 6 <= 4 and 3 ** 3 > 12 / 3
= not 6 <= 4 and 27 > 12 / 3

Step 2

/ is next in line of precedence
not 6 <= 4 and 27 > 12 / 3
= not 6 <= 4 and 27 > 4

Step 3

Comparison operators are next in line of precedence
not 6 <= 4 and 27 > 4
= not False and True

Step 4

Boolean NOT is evaluated
not False and True
= True and True

Step 5

Boolean AND is evaluated
True and True
= True

Errors & Exception Handling

Error Types

A program contains "bug(s)" when it is unable to execute or produces an output which is different from what is expected. These bugs are generally introduced by a programmer unknowingly.

The process of identifying and eliminating these bugs or errors is known as debugging.

The three major types of errors are:

  • Syntax Error
  • Runtime Error
  • Logical Error

Syntax Error

Syntax error occurs when the program contains any statement that does not follow the prescribed Python rules or syntax which makes it difficult for the Python interpreter to parse (understand) and execute it.

Some common syntax errors are:

  • Missing/Misspelled keyword
  • Missing colon or brackets
  • Empty block
  • Incorrect position of keyword
  • Incorrect block indentation

Script Mode

When a code containing syntactically incorrect statement is executed using script mode via IDLE, an error dialog box is displayed.

Syntax Error Dialog

On closing the dialog box, the incorrect part of the code, the potential cause of error, is highlighted in red.

Syntax Error Highlighted

This error has to be rectified to execute the program correctly.

Interactive Mode

When a syntactically incorrect statement is executed in the Python console (interactive mode), the Python interpreter displays it and also adds a little arrow (^) pointing at the entry point or token where the error was detected.

Example

>>> while True print('Hi!')
  File "<stdin>", line 1
    while True print('Hi!')
               ^
SyntaxError: invalid syntax

In the above example there is a syntax error with ^ pointing to print function which the parser is unable to understand as there is a missing : (colon) after True.

Runtime Error

A runtime error occurs when the program is terminated prematurely by the Python interpreter as it is unable to execute a statement although it is correct syntactically.

Some runtime error examples are:

  • ImportError: Raised when the import statement has trouble loading a module or any definition from a module.
  • IOError: Raised when the interpreter is not able to open the file specified in the program.
  • ZeroDivisionError: Raised when a number is divided or mod by zero.
  • NameError: Raised when an identifier is encountered which has not been defined.
  • ValueError: Raised when an argument or operand is of required data type, but has undesired value.
  • IndexError: Raised when the provided index in a sequence (string, list, tuple, etc.) is out of range.
  • KeyError: Raised when a dictionary key is not found in the set of existing keys.
  • TypeError: Raised while performing an operation on incompatible types.
  • IndentationError: Raised when the indentation of a statement or code block is incorrect.

Runtime Error Examples

ZeroDivisionError

n = 100
d = 0
print(n/d)
Traceback (most recent call last):
  File "/Users/name/Desktop/test.py", line 3, in <module>
    print(n/d)
ZeroDivisionError: division by zero

NameError

n = 100
print(d)
Traceback (most recent call last):
  File "/Users/name/Desktop/test.py", line 2, in <module>
    print(d)
NameError: name 'd' is not defined

KeyError

d = {1: "1st", 2: "2nd"}
print(d[3])
Traceback (most recent call last):
  File "/Users/name/Desktop/test.py", line 2, in <module>
    print(d[3])
KeyError: 3

TypeError

n =1
s = "a"
tot = n + s
Traceback (most recent call last):
  File "/Users/name/Desktop/test.py", line 3, in <module>
    tot = n + s
TypeError: unsupported operand type(s) for +: 'int' and 'str'

Logical Error

Logical error or Semantic error is caused when the issue lies in the underlying meaning of the code which leads to an incorrect output.

As compared to syntax or runtime error there is no termination of the program.

Debugging a logical error requires inspection of the entire code as no guiding error message is displayed.

Example

Let us write a program to calculate the average of two numbers

n = 10
m = 20
avg = n + m / 2
print("Average:", avg)

On executing the script the result is

Average: 20.0

This is incorrect as there is a logical error in the code.

Since / has a higher precedence over +, m / 2 is being computed first.

We can modify the code to get rid of the logical error.

n = 10
m = 20
avg = (n + m) / 2
print("Average:", avg)

On executing the script, we now obtain the correct result

Average: 15.0

Exceptions

We have witnessed that even if a program is syntactically correct, its execution may lead to a run-time error.

This error detected during execution is known as an exception which is an object created by the Python interpreter containing information regarding the error like type of error, file name and the location of the error (line number, token) in the program.

Some of the built-in exceptions that are raised by the Python interpreter are - ImportError, ZeroDivisionError, NameError, ValueError, IndexError, KeyError, TypeError and IndentationError.

Apart from the Python interpreter, a programmer can also trigger and raise an exception (along with a custom message) in the code using raise or assert statement.

raise

The raise statement can be used to throw an exception in a program. The exception may or may not contain the custom error message (recommended).

Let us consider a program which accepts two numbers (a and b) from the user and prints the result a/b.

Code

a = int(input("Enter a: "))
b = int(input("Enter b: "))
print("a/b =", a/b)

Output

Enter a: 10
Enter b: 0
Traceback (most recent call last):
  File "/Users/name/test.py",
   line 3, in <module>
    print("a/b =", a/b)
ZeroDivisionError: division by zero

It can be observed that the Python interpreter raises a ZeroDivisionError when the value of b is entered as 0.

Now we can modify the above code to raise an exception for such scenarios.

Code

a = int(input("Enter a: "))
b = int(input("Enter b: "))
if b==0:
    raise Exception()
print("a/b =", a/b)

Output

Enter a: 10
Enter b: 0
Traceback (most recent call last):
  File "/Users/name/test.py",
   line 4, in <module>
    raise Exception()
Exception

An exception is raised, but it is not helpful.

Let us add some custom error message.

Code

a = int(input("Enter a: "))
b = int(input("Enter b: "))
if b==0:
    raise Exception("b is zero")
print("a/b =", a/b)

Output

Enter a: 10
Enter b: 0
Traceback (most recent call last):
  File "/Users/name/test.py",
   line 4, in <module>
    raise Exception("b is zero")
Exception: b is zero

We can also raise any specific type of error as per the program logic as shown below:

Code

a = int(input("Enter a: "))
b = int(input("Enter b: "))
if b==0:
    raise ValueError("The value of b cannot be zero")
print("a/b =", a/b)

Output

Enter a: 10
Enter b: 0
Traceback (most recent call last):
  File "/Users/name/test.py",
   line 4, in <module>
    raise ValueError("The value of b cannot be zero")
ValueError: The value of b cannot be zero

assert

An assert statement is often used during code development to act like a safety valve which notifies the programmer in case the test expression is evaluated as False.

If the test expression’s value is True, the code execution continues normally.

An AssertionError is raised if the value is False.

Code

a = 3
b = 4
assert a == b
c = 5

Output

Traceback (most recent call last):
  File "/Users/name/test.py",
   line 3, in <module>
    assert a == b
AssertionError

The statement also allows for a message to be attached to the AssertionError.

Code

a = 3
b = 4
assert a == b, "a is not equal to b"
c = 5

Output:

Traceback (most recent call last):
  File "/Users/name/test.py",
   line 3, in <module>
    assert a == b, "a is not equal to b"
AssertionError: a is not equal to b

Exception Handling

Exception handling is the process of properly handling an exception which can potentially crash a program during execution.

When an error occurs, the program throws an exception.

The runtime system attempts to find an exception handler, a block of code that can handle a particular type of error. Once located, the suitable exception handler catches the exception and executes the code block which can attempt to recover from the error. In case the error is unrecoverable, the handler provides a way to gently exit the program.

The try statement in Python specifies the exception handlers and/or cleanup code for a code block.

The various parts of a try statement are:

  • try block: The block of statements within which an exception might be thrown.
  • except clause(s): One or more exception handlers. Each except clause handles a particular type of exception. In case an exception of a particular type occurs in the try block, the corresponding except clause code block is executed.
  • else clause: An optional else clause can also be included after the last except block. In case no exception is raised, none of the except blocks are executed. In this case, the else code block is executed.
  • finally clause: An optional finally clause can be added at the end of the try statement which includes a block of statements that are executed regardless of whether or not any error occurred inside the try block. This block is usually setup for code cleanup and closing all open file objects.

Here's the general form of these statements:

try:
    [code block]
except [exception1 [as identifier1]]:
    [exception code block 1]
except [exception2 [as identifier2]]:
    [exception code block 2]
...
...
else:
    [code block executes if no error]
finally:
    [code block always executed]

Control Flow

Introduction to Control Flow

A simple Python program can be treated as a block of code where each statement is executed by the Python interpreter in a sequential order from top to bottom.

But, in real world we would like to have some control over the execution of code such as:

  • skip or execute a block (set of statements) based on certain conditions
  • execute a block repeatedly
  • redirect execution to another set of statements
  • breaking up the execution

This control over the flow of execution is provided by Control Flow Statements.

They can be categorized as:

  • Sequential
  • Selection
  • Iteration/Repetition
  • Jump
  • Procedural Abstraction - A sequence of statements are referenced as a single function or method call
  • Recursion - Calling a method/function in the same method/function
  • Exception Handling

Sequential Flow

By default the code statements in Python are executed in Sequential order.

The below flow chart demonstrates how 3 statements are executed in a sequential order.

Sequential Flow

For example,

a = 2
b = 3
c = a*b
print(c)

The above code will be executed in the following sequential order:

Sequential Flow of Code

Selection Statements: if .. else

Selection statements, also known as Decision making statements, control the flow of a program based on the outcome of one or many test expression(s). If the condition is satisfied (True) then the code block is executed. There is also a provision to execute another code block if the condition is not satisfied.

This process can be demonstrated using the below flowchart:

Selection Flow

Python supports if compound statement which provides this control. The if statement comprises:

  • if keyword followed by the test expression, a colon : and an indented block of code which gets executed if the condition is satisfied
  • (optional) one or many elif clause followed by their test conditions and their corresponding code blocks
  • (optional) else clause and the corresponding code block which gets executed if none of the above conditions (if, elif) are satisfied

An example if statement is provided below:

'''
age - age of loan applicant
emp - is employed (bool)
cscore - credit scrore of applicant
'''
result = None
if age < 26 and not emp:
    result = "Loan rejected"
elif age > 35 and cscore < 600:
    result = "Loan rejected"
else:
    result = "Loan approved"
print(result)

The control flow view of the above code is:

Selection in Flow of Code

Examples

Let us go through some programming problems which utilize selection statements.

1. Absolute Value

Write a program to output the magnitude of difference between two numbers using conditional statement.

Code

n1 = int(input("Enter 1st number: "))
n2 = int(input("Enter 2nd number: "))

if n1 > n2:
    diff = n1 - n2
else:
    diff = n2 - n1

print("The difference of", n1, "and", n2, "is", diff)

Output

Enter 1st number: 12
Enter 2nd number: 15
The difference of 12 and 15 is 3

2. Sorting 3 Numbers

Write a program to accept 3 numbers from the user and print them in ascending order of value.

Code

a = int(input("Enter 1st number: "))
b = int(input("Enter 2nd number: "))
c = int(input("Enter 3rd number: "))

if b < a: 
    # Swapping the values of a and b
    a, b = b, a 
          
if c < b: 
    b, c = c, b 
    if b < a: 
        a, b = b, a

print("The numbers in sorted order:", a, ",", b, ",", c)

Output

Enter 1st number: 9
Enter 2nd number: 2
Enter 3rd number: 6
The numbers in sorted order: 2 , 6 , 9

3. Divisibility

Write a program to accept two numbers and test if the first number is divisible by the second number.

Code

a = int(input("Enter 1st number: "))
b = int(input("Enter 2nd number: "))

if a % b == 0: 
    print(a, "is divisible by", b)
else:
    print(a, "is not divisible by", b)

Output

Enter 1st number: 9
Enter 2nd number: 2
9 is not divisible by 2

Enter 1st number: 9
Enter 2nd number: 3
9 is divisible by 3

Iteration: for

Iteration statements, also known as Looping statements, allow repeated execution of a code block.

Python provides for and while statements to perform iteration.

The for statement can be used to iterate over the items of a sequence (list, string, tuple, range). It can also be used to iterate over unordered sequences like set and dict.

This process can be demonstrated using the below flowchart:

Iteration in Flow of Code Python

Let us go through some code examples to demonstrate how for statement can be used to iterate over sequences.

List Iteration

Code

cars = ["Hyundai", "Honda", 
        "Ford", "Toyota", 
        "BMW", "Volkswagen"]
for make in cars:
    print(make)

Output

Hyundai
Honda
Ford
Toyota
BMW
Volkswagen

Tuple Iteration

Code

cars = ("Hyundai", "Honda", 
        "Ford", "Toyota", 
        "BMW", "Volkswagen")
for make in cars:
    print(make)

Output

Hyundai
Honda
Ford
Toyota
BMW
Volkswagen

String Iteration

Code

name = "python"
for char in name:
    print(char)

Output

p
y
t
h
o
n

Range Iteration

The range type represents an immutable sequence of numbers that is usually used in for loops for looping a certain number of times. range object always take the same (small) amount of memory, no matter the size of the range it represents, which is an advantage over a regular list or tuple.

Syntax: range(stop) or
range(start, stop[, step])

>>> range(10)
range(0, 10)
>>> list(range(10))
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> list(range(1, 10, 2))
[1, 3, 5, 7, 9]

range() function is widely used in a for statement to control the number of iterations and provide the index value (i) of each iteration.

Example #1

Print multiples of 5 starting from 0 to 20.

Code

for i in range(5):
    print(i*5)

Output

0
5
10
15
20

Example #2

Print all integers from 2 to 5 including the boundary values.

Code

for i in range(2, 6):
    print(i)

Output

2
3
4
5

Example #3

Print all odd numbers between 2 and 10.

Code

for i in range(3, 10, 2):
    print(i)

or

for i in range(2, 10):
    if i % 2 != 0:
        print(i)

Output

3
5
7
9

Example #4

Print the index of all occurrences of o in python programming.

Code

s = "python programming"
for i in range(len(s)):
    if s[i] == "o":
        print(i)

Output

4
9

Exercises

Let us go through some programming problems which utilize the for iteration statement.

1. Compound Interest

Write a program to calculate the total compound interest payable for given principal, interest rate (compounded annually) and total time (in years).

Code

prin = float(input("Enter the principal amount: "))
rate = float(input("Enter the annual interest rate: "))
time = int(input("Enter the loan duration (in years): "))

amt = prin
for n in range(time):
    amt += rate*amt/100

print("Total interest payable:", amt - prin)

Output

Enter the principal amount: 500000
Enter the annual interest rate: 5
Enter the loan duration (in years): 3
Total interest payable: 78812.5

2. Factorial

The factorial of a positive integer n, denoted by n!, is the product of all positive integers less than or equal to n.
n! = n×(n-1)×(n-2)...3×2×1
Write a program to calculate n! for a given n (assume n is greater than 0).

Code

n = int(input("Enter n: "))

factorial = 1
for i in range(1, n+1):
    factorial *= i

print("n! :", factorial)

Output

Enter n: 6
n! : 720

Iteration: while

while statement repeatedly executes a code block as long as the test condition is satisfied.

Usually there is a statement at the end of the code block which updates the value of the variable being used in the test expression, so the the loop does not execute infinitely.

A flowchart of the process is provided below:

while loop Iteration in Flow of Code

For example, let us traverse a list and print the position(index) and value of each element until we reach the end of the list.

Code

cars = ["Hyundai", "Honda", 
        "Ford", "Toyota", 
        "BMW", "Volkswagen"]
i = 0  
while i<len(cars):    
    print(i, cars[i])
    i+=1

Output

0 Hyundai
1 Honda
2 Ford
3 Toyota
4 BMW
5 Volkswagen

In the above example, the test condition is i<len(cars) and the update statement is i+=1.

Exercises

Let us go through some programming problems which utilize the while iteration statement.

1. Compound Interest

Write a program to calculate the total compound interest payable for given principal, interest rate (compounded annually) and total time (in years).

Code

prin = float(input("Enter the principal amount: "))
rate = float(input("Enter the annual interest rate: "))
time = int(input("Enter the loan duration (in years): "))

amt = prin
while time > 0:
    amt += rate*amt/100
    time = time - 1

print("Total interest payable:", amt - prin)

Output

Enter the principal amount: 500000
Enter the annual interest rate: 5
Enter the loan duration (in years): 3
Total interest payable: 78812.5

2. Factorial

The factorial of a positive integer n, denoted by n!, is the product of all positive integers less than or equal to n.
n! = n×(n-1)×(n-2)...3×2×1
Write a program to calculate n! for a given n (assume n is greater than 0).

Code

n = int(input("Enter n: "))

factorial = 1
while n > 0:
    factorial *= n
    n = n - 1

print("n! :", factorial)

Output

Enter n: 6
n! : 720

Jump Statements

Jump statements are used to (abruptly) alter the flow of execution.

Some of the jump statements available in Python are:

pass

A pass statement acts as a placeholder and performs null (no) operation.

Various reasons for using the keyword pass are provided below:

1. Syntactical Requirement

Using pass becomes a syntactical requirement for cases where the Python interpreter can raise a SyntaxError due to missing statements.

The below code will execute successfully without any operation in the loop

for i in range(6):
    pass  

whereas without pass

for i in range(6):

will throw the following SyntaxError

File "<ipython-input-18-f2ba5099d499>", line 1
    for i in range(6):
                    ^
SyntaxError: unexpected EOF while parsing

Similarly, inside an if

if 2 < 3:
    pass  

whereas without pass

if 2 < 3:

will throw the following SyntaxError

File "<ipython-input-20-068861cce0a8>", line 1
    if 2 < 3:
            ^
SyntaxError: unexpected EOF while parsing

2. Skipping Code Execution

pass can be used to skip code execution for certain cases.

For example,

Code

l = [2, 3, 4, 5, 6]
for i in l:
    if i%3 == 0:
        pass
    else:
        print(i, "is not divisible by 3")

Output

2 is not divisible by 3
4 is not divisible by 3
5 is not divisible by 3

3. Placeholders

pass can be used to create valid empty functions and classes as placeholders which can be modified in the future versions of code.

def emptyFunction():
    pass

class EmptyClass:
    pass

break

The break statement is used to terminate the execution of immediately enclosing for or while statement.

The below code will terminate the for loop when i is equal to 4

for i in range(10):
    print(i)
    if i == 4:
        break
0
1
2
3
4

In a while statement,

i =0
while i <10:
    print(i)
    if i == 4:
        break
    i+=1

break will terminate the while loop when i is equal to 4

0
1
2
3
4

continue

continue statement is used to skip the execution of successive statements and start the next iteration.

The below code will skip all candidates for an interview who have less than 4 years of work experience.

people =  [{"name": "ABC", "experience": 6},
           {"name": "EFG", "experience": 2},
           {"name": "JKL", "experience": 5},
           {"name": "XYZ", "experience": 3},]
for candidate in people:
    if candidate["experience"]<4:
        continue  
    print(candidate["name"], "is selected for interview")

Output:

ABC is selected for interview
JKL is selected for interview

Nested Loops

When a loop is present inside another loop, it is known as a nested loop.

For each iteration of the outer loop, the inner loop undergoes complete iteration. Thus, if the outer loop has to undergo n iterations and the inner loop has to undergo m iterations, the code block inside the inner loop executes n x m times.

Let us go through a nested loop example:

Factorial

Write a program to print the factorial of all numbers in the range 1 to 10 (inclusive).

Code

for n in range(1, 11):
    factorial = 1
    for i in range(1, n+1):
        factorial *= i
    print(n,"! =", factorial)

Output

1 ! = 1
2 ! = 2
3 ! = 6
4 ! = 24
5 ! = 120
6 ! = 720
7 ! = 5040
8 ! = 40320
9 ! = 362880
10 ! = 3628800

Nested Loop - break

A break statement inside the inner loop terminates only the inner loop whereas the outer loop is not affected.

To develop a better understanding, let us write a program to find all prime numbers between 2 and 40.

Code

for n in range(2, 40):
    i = 2
    while i < n/2:
        if n%i == 0:
            break
        i+=1
    if i>n/2:
        print(n,"is prime")

Output

2 is prime
3 is prime
5 is prime
7 is prime
11 is prime
13 is prime
17 is prime
19 is prime
23 is prime
29 is prime
31 is prime
37 is prime

Strings

Strings: Introduction & Creation

A String (str) is an immutable sequence of Unicode characters which is used to handle textual data in Python.

They can be specified by enclosing within:

  • Single quotes: 'embedded "double" quotes are allowed'
  • Double quotes: "embedded 'single' quotes are allowed"
  • Triple quotes: '''Three single quotes''', """Three double quotes""".

Triple quoted strings can also span multiple lines.

Some examples are provided below:

s = "I am a String"  

s1 = """A
multiline
String"""

s2 = '''Also a
multiline
String'''

Escape Characters

The backslash (\) character can be used in a string to escape characters that otherwise have a special meaning, such as newline, linefeed, or the quote character.

Escape Sequence Meaning
\\ Backslash (\)
\' Single quote (')
\" Double quote (")
\a ASCII Bell (BEL)
\b ASCII Backspace (BS)
\f ASCII Form-feed (FF)
\n ASCII Linefeed (LF)
\r ASCII Carriage Return (CR)
\t ASCII Horizontal Tab (TAB)
\v ASCII Vertical Tab (VT)

Although \' and \" can be used to specify quote characters, Python allows embedding double quotes inside a single-quoted string ('My name is "Python".') and single quotes inside a double-quoted string ("Python's World").

Unicode Support

Python string objects support Unicode characters.

A unicode character can be specified as \u followed by the 4 letter unicode (\uXXXX).

>>> print("E = mc\u00B2")
E = mc²

In the above example, \u00B2 is the unicode character which represents the 'SUPERSCRIPT TWO'.

Other Types to String

In case you want to create a string object from other data types, just use the built-in str() function as follows:

>>> str(9)
'9'

>>> str(10.0)
'10.0'

Accessing Characters of a String

Python strings are "immutable", i.e., the state (value) of the objects cannot be modified after they are created.

Using the standard [ ] syntax and zero-based indexing, characters can be accessed in a string.

If s = "hello",

  • s[0] will result in h
  • s[2] will result in l
  • s[5] will result in IndexError: string index out of range as the length of string is 5 (index 0 to 4)
  • s[2] = 'p' will result in TypeError: 'str' object does not support item assignment as s is immutable

Python also supports negative indexing, i.e., you can access the values of a string from right to left.

Index of -1 denotes the last character of the string, -2 is the second last character and so forth.

If s = "hello",

  • s[-1] will result in o
  • s[-4] will result in e
  • s[-6] will result in IndexError: string index out of range as the length of string is 5 (negative index -1 to -5)

Length of String

The built-in function len() returns the length of a string which is useful during string traversal or other string operations.

>>> len("hello")
5

>>> s = "sample text"
>>> len(s)
11

>>> p = "python"
>>> l = len(p)
>>> p[l-1]
'n'

String Operations

We can perform various operations on a string (sequence of characters) such as slicing, membership, concatenation and repetition.

Slicing

In Python, a character in a string can be easily accessed using its index.

>>> s = "Hello"
>>> s[1]
'e' 

Python also provides a way to access a substring from a string. This substring is known as a slice and it can be obtained using the slice operator [n:m] which returns the part of the string from the start index (n) to the end index (m), including the first but excluding the last.

>>> s = "Hello"
>>> s[1:3]
'el' 

If the start index (n) is omitted, the default value of n is set as 0 which denotes the beginning of the string. If the end index (m) is omitted, the substring ends at the last character of the string.

>>> s = "Hello"
>>> s[:3]
'Hel'
>>> s[3:]
'lo'
>>> s[:]
'Hello'

Negative indexing is also supported in the slice operator.

>>> s = "Hello"
>>> s[-4:-2]
'el'

In the above example, -4 is equivalent to len(s) - 4 = 5 - 4 = 1 and -2 is equivalent to 5 - 2 = 3. Thus, s[-4:-2] is same as s[1:3].

The slice operator also allows the usage of a third index which is known as step as it allows a user to step over (skip) characters.

>>> s = "Hello"
>>> s[0:5:2]
'Hlo'

In the above example, the substring begins at the start of the string, takes a step size of 2 skipping e and ends at the last character again skipping the 4th character l.

Membership

in and not in operators can be used to determine whether a substring is present/not present in a string.

>>> s = "Hello"
>>> "lo" in s
True
>>> "lp" not in s
True

Concatenation

The + operator can be used to join two strings.

>>> s1 = "Hello"
>>> s2 = "Python" 
>>> s1 + s2
'HelloPython'
>>> s1 + "World"
'HelloWorld'

Repetition

The * operator repeats a string the number of times as specified by the integer operand.

>>> s = "Hello"
>>> s*3
'HelloHelloHello'

Introduction to String Methods

Apart from the built-in function len() which returns the length of the string, String objects have access to several specialized functions (methods) that can:

  1. Convert Case of Strings
  2. Check Characters of a String
  3. Split a String
  4. Strip Characters from a String
  5. Checking for Prefix or Suffix in a String
  6. Find & Replace Characters in a String

Let us discuss these methods in detail in the coming sections.

Convert Case of Strings

The following methods are useful in converting the case of the characters in a string:

lower()

All cased characters are converted into lowercase.

>>> "PYthon".lower()
'python'

upper()

All cased characters are converted into uppercase.

>>> "PYthon".upper()
'PYTHON'

swapcase()

Uppercase characters are converted into lowercase and lowercase characters are converted into uppercase.

>>> "PYthon".swapcase()
'pyTHON'

capitalize()

First character is capitalized and rest all characters are lowercased.

>>> "hello py".capitalize()
'Hello py'

title()

For each word present in the string, the first character is uppercased and the remaining characters are lowercased.

>>> "hello python".title()
'Hello Python'

Check Characters of a String

The following methods are used to check the type of characters in a string.

isalpha()

Returns True if all characters in the string are letters (A-Z a-z).

>>> "HelloPython".isalpha()
True

>>> "Hello Python".isalpha()
False  # contains whitespace

>>> "HelloPython2".isalpha()
False  # contains digit

isdigit()

Returns True if all characters in the string are digits.

>>> "Hello24".isdigit()
False  # contains alphabets
>>> "24".isdigit()
True

isalnum()

Returns True if all characters in the string are alphanumeric (Alphabets or Numeric).

>>> "02".isalnum()
True
>>> "HelloPython".isalnum()
True
>>> "Hello Python v2".isalnum()
False  # contains whitespace
>>> "HelloPythonv2".isalnum()
True

isascii()

Returns True if the string is empty or all characters in the string are ASCII.

>>> "".isascii()
True
>>> "HelloPython".isascii()
True
>>> "Hello Py \u00B2".isascii()
False
>>> "पा से python".isascii()
False

islower()

Returns True if all characters are lowercase.

>>> "hello".islower()
True
>>> "Hello".islower()
False

isupper()

Returns True if all characters are uppercase.

>>> "HELLO".isupper()
True
>>> "Hello".isupper()
False

isspace()

Returns True if there are only whitespace characters in the string. Some popular whitespace characters are (space), \t (tab), \n (newline), \r (carriage return), \f (form feed) and \v (vertical tab).

>>> "        ".isspace()
True

istitle()

Returns True if the string is title-cased, i.e., the first character of every word in the string is uppercased and the remaining characters are lowercased.

>>> "Hello World".istitle()
True
>>> "Hello world".istitle()
False
>>> "hello world".istitle()
False

Split a String

Split methods help in splitting/partitioning a string.

partition()

partition(sep) method splits the string when the separator (sep) is encountered for the first time, and returns a tuple with three items (string before separator, separator, string after separator).

>>> "Hi|Ed|Punk".partition('|')
('Hi', '|', 'Ed|Punk')

split()

split(sep=None, maxsplit=-1) method splits a string into a list based on a string separator (sep).

If sep is not specified, it defaults to None, where whitespace is regarded as separator, and the string is stripped of all leading and trailing whitespaces after which it is split into words contained in the string.

>>> "Hi|Ed|Punk".split('|')
['Hi', 'Ed', 'Punk']
>>> "Hi Ed Punk".split()
['Hi', 'Ed', 'Punk']
>>> "    Hi Ed Punk   ".split()
['Hi', 'Ed', 'Punk']

If maxsplit is provided, at most maxsplit number of splits are performed and the list will contain a maximum of maxsplit+1 elements.

maxsplit when not specified defaults to -1, which implies that there is no limit on the number of splits.

>>> "Hi|Ed|Punk|v2".split('|', 2)
['Hi', 'Ed', 'Punk|v2']

Strip Characters from a String

Strip methods are useful in removing leading and/or trailing characters in a string.

They accept an optional argument chars which specifies the set of characters which have to be removed.

If no arguments are provided then chars defaults to ASCII whitespace and the method removes all leading and/or trailing spaces from the string.

lstrip()

All leading (on the left) characters are removed from the string.

>>> "   Hello|World   ".lstrip()
'Hello|World   '
>>> "www.edpunk.cc".lstrip('w.')
'edpunk.cc'

rstrip()

All trailing (on the right) characters are removed from the string.

>>> "   Hello|World   ".rstrip()
'   Hello|World'
>>> "www.edpunk.cc".rstrip('.c')
'www.edpunk'

strip()

All leading and trailing characters are removed from the string.

>>> "   Hello|World   ".strip()
'Hello|World'
>>> "www.edpunk.cc".strip('cw.')
'edpunk'

Check Prefix or Suffix in a String

startswith() and endswith() methods are used check whether a string starts or ends with the provided substring (or a tuple of substrings).

>>> "Hello Py".startswith("He")
True
>>> "Hello Py".startswith(("He","P"))
True
>>> "Py Hello".startswith(("He","P"))
True
>>> "Hello Py".endswith("y")
True
>>> "Hello Py".endswith(("p","y"))
True
>>> "Py Hello".endswith(("o","n"))
True

Find & Replace Characters in a String

The following string methods are useful for locating substring in a string.

count()

count(sub[, start[, end]]) returns the number of non-overlapping occurrences of a substring sub in the range [start, end].

start and end are optional parameters and they default to 0 and len(string) respectively.

>>> s = "she sells sea shells"
>>> s.count("she")
2
>>> s.count("she", 5)
1
>>> s.count("she", 5, 10)
0
>>> s.count("she", 5, 17)
1

It has to be noted that the method counts non-overlapping occurrences, so it does not start a new matching process until the current substring matching is complete.

>>> s = "valhala alala"
>>> s.count("al")
4
>>> s.count("ala")
2

In the above example, ala is counted twice as the first occurrence is in valh"ala" and the next occurrence is in "ala"la. Although ala can be located again in al"ala", it overlaps with the occurrence "ala"la, hence it is not counted.

find()

find(sub[, start[, end]]) returns the lowest index in the string where substring sub is located in the range [start, end].

start and end are optional parameters and they default to 0 and len(string) respectively.

The method returns -1 in case the substring is not present.

>>> s = "she sells sea shells"
>>> s.find("she")
0
>>> s.find("she", 5)
14
>>> s.find("see")
-1
>>> s.find("she", 5, 10)
-1
>>> s.find("she", 5, 17)
14

rfind()

rfind(sub[, start[, end]]) returns the highest index in the string where substring sub is located in the range [start, end].

start and end are optional parameters and they default to 0 and len(string) respectively.

The method returns -1 in case the substring is not present.

>>> s = "she sells sea shells"
>>> s.rfind("she")
14
>>> s.rfind("she", 0, 12)
0
>>> s.rfind("see")
-1
>>> s.rfind("she", 5)
14

index()

index(sub[, start[, end]]) is similar to find(sub[, start[, end]]), but instead of returning -1 it raises ValueError when the substring is not found.

>>> s = "she sells sea shells"
>>> s.index("she")
0
>>> s.index("she", 5)
14
>>> s.index("see")
Traceback (most recent call last):
  File "<stdin>", line 1,
   in <module>
ValueError: substring not found
>>> s.index("she", 5, 10)
Traceback (most recent call last):
  File "<stdin>", line 1,
   in <module>
ValueError: substring not found
>>> s.index("she", 5, 17)
14

rindex()

s.rindex(sub[, start[, end]]) is similar to rfind(sub[, start[, end]]), but instead of returning -1 it raises ValueError when the substring is not found.

>>> s = "she sells sea shells"
>>> s.rindex("she")
14
>>> s.rindex("she", 0, 12)
0
>>> s.rindex("see")
Traceback (most recent call last):
  File "<stdin>", line 1,
   in <module>
ValueError: substring not found
>>> s.rindex("she", 5)
14

replace()

replace(oldsub, newsub[, count]) returns a copy of the string with all occurrences of oldsub substring replaced by newsub.

count is an optional parameter which when provided, only replaces the first count occurrences from the string.

>>> s = "Oh Python! Oh"
>>> s.replace("Oh", "Hi")
'Hi Python! Hi'
>>> s.replace("Oh", "Hi", 1)
'Hi Python! Oh'

Traversing a String

for and while statements are useful for traversing a string.

Using for

As a string is a sequence of characters, the for statement can be used to iterate over a string as shown below.

Code

name = "python"
for char in name:
    print(char)

Output

p
y
t
h
o
n

Using while

A while statement can be used to traverse a string by iterating on the value of index till the last character index.

Code

name = "python"
i = 0
while i < len(name):
    print(name[i])
    i += 1

Output

p
y
t
h
o
n

List

What is a Python List? How to Create a List?

The most common and widely used collections in Python are lists which store an ordered group of objects (of any datatype) which might have some logical relation. This marks a considerable difference from arrays (in traditional languages) and makes Python an ideal language for handling real-life data which is not type-bound.

Let us create a list of attributes of a particular vehicle available for sale in a car dealership:

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]

In this list:

  • "BMW" is the make of the vehicle,
  • "Z4" is the model of the vehicle,
  • 2019 is the year when the vehicle was manufactured,
  • 4 represents the number of wheels,
  • "Red" is the color of the vehicle, and
  • True tells us that the vehicle up for sale is brand new.

This method of creating a list from a collection of literals is known as list display.

Notice, how this list contains items of multiple data types - str, int and bool.

Apart from the list display shown above, the built-in list() function can also be used to create new lists.

If no arguments are provided to the list() function, an empty list is created.

>>> l = list()
>>> l
[]

If a string, tuple or set is passed as an argument, list() functions converts them into a list.

>>> l = list("abcd")
>>> l
['a', 'b', 'c', 'd']
>>> l = list({1, 2, 3})
>>> l
[1, 2, 3]
>>> l = list((1, 2, 3, 4))
>>> l
[1, 2, 3, 4]

Accessing Items of a List

Lists use zero-based indexing, where 0 is the index of the first element and len(list) - 1 is the index of the last element.

For example,

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[0]
'BMW'
>>> l[2]
2019

Length of List

The built-in len() function can be used to return the length of the list.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> len(l)
6

Negative Indexing

Just like str, sequence types like list support negative indexing, i.e., you can access the values of list from the end.

Index of -1 denotes the last item in the list, -2 the second last item and so forth.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[-1]
True
>>> l[-3]
4

Modifying a List

As lists are mutable, the assignment operator can be used to modify or replace a single item in the list at a given index.

>>> l = ["BMW", "Z4", "Red"]
>>> l[2] = "Black"
>>> l
['BMW', 'Z4', 'Black']

Removing Item from a List

del statement can be used to delete an item at a given index of a list.

>>> l = ["BMW", "Z4", "Red"]
>>> del l[1]
>>> l
['BMW', 'Red']

List Operations

We can perform various operations on a list (collection of items) such as membership, concatenation, repetition and slicing.

Membership

in and not in can be used to detect the membership of an item in a list.

>>> l = ["BMW", "Z4", "Red"]
>>> "Red" in l
True
>>> "Gold" in l
False
>>> "Gold" not in l
True    

Concatenation

+ operator can be used to join two lists to create a new list.

>>> l = ["BMW", "Z4"]
>>> k = [2019, "Red"]
>>> l + k
['BMW', 'Z4', 2019, 'Red']

+= operator joins two lists and assigns it to the target list.

>>> l = ["BMW", "Z4"]
>>> l += [2019, "Red"]
>>> l
['BMW', 'Z4', 2019, 'Red']  

Repetition

The * operator repeats the items of a list the number of times as specified by the integer operand.

>>> l = [1, 2]
>>> l*3
[1, 2, 1, 2, 1, 2]

Slicing

A subset of list l can be obtained using the list slice notation given as l[i:j], where the item at start index i is included, but the item at end index j is excluded.

For example, the slice notation [1:4] refers to items from index 1 to index 3 (i.e. 4-1).

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[1:4]
['Z4', 2019, 4]

The slice notation l[i:j:k] can also include a third number known as the stepper. Here, a list is sliced from start index i to end index (j) - 1 with a step of k items.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[1:4:2]
['Z4', 4]

Slice notations also have some useful defaults. 0 is the default for the first number and size of the list is the default for the second number.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[2:]
[2019, 4, 'Red', True]
>>> l[:4]
['BMW', 'Z4', 2019, 4]

Slice notation also supports negative indexing.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[-4:]
[2019, 4, 'Red', True]
>>> l[:-2]
['BMW', 'Z4', 2019, 4]
>>> l[-4:-1]
[2019, 4, 'Red']   

Slice notation can be used to replace multiple items in a list.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[:2] = ["Kia", "Sonet"]
>>> l
['Kia', 'Sonet', 2019, 4, 'Red', True]

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> l[1:5:2] = ["Sonet", 2]
>>> l
['BMW', 'Sonet', 2019, 2, 'Red', True]

Slice notation can also be used to delete multiple items in a list.

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> del l[:2]
>>> l
[2019, 4, 'Red', True]

>>> l = ["BMW", "Z4", 2019, 
...       4, "Red", True]
>>> del l[:5:2]
>>> l
['Z4', 4, True]

Traversing a List

List Traversal is the process of visiting every item in a list, usually from the first item to the last item, and executing some instruction on the accessed item.

Python provides 2 ways to traverse a list:

Direct Traversal

As a list is an ordered collection of items, the for statement can be used to directly and sequentially access each item.

Code

l = ["BMW", "Z4", 2019, 
     4, "Red", True]
for item in l:
    print(item)

Output

BMW
Z4
2019
4
Red
True

Location or Index Based Traversal

In location based or index based traversal the value of index starts at 0 and increments as long as it is lesser than the length of the list.

This index value can be used to access the item at that index in a list using the index operator [].

for statement can be used to iterate over the index of the list using the range() and len() functions.

Code

l = ["BMW", "Z4", 2019, 
     4, "Red", True]
for i in range(len(l)):
    print(i, l[i])

Output

0 BMW
1 Z4
2 2019
3 4
4 Red
5 True

This method is also useful when you need to modify the items of a list (without altering the length of list) during traversal.

For example, let us convert each item of the list into a string.

Code

l = ["BMW", "Z4", 2019, 
     4, "Red", True]
for i in range(len(l)):
    # modifying item value
    l[i] = str(l[i])
print(l)

Output

['BMW', 'Z4', '2019', '4', 'Red', 'True']

A while statement can be used to traverse a list by iterating on the value of index till the last item index.

Code

l = ["BMW", "Z4", 2019, 
     4, "Red", True]
i = 0
while i < len(l):
    print(l[i])
    i += 1

Output

BMW
Z4
2019
4
Red
True

Built-in Functions that can be used for a List

Built-in functions max(), min() and sum() are used to calculate the maximum, minimum and sum of items in a list, respectively.

>>> l = [4, 8, 2, 1, 3]
>>> min(l)
1
>>> max(l)
8
>>> sum(l)
18

Introduction to List Methods

List objects have access to several specialized functions (methods) that can be used to:

  1. Add Items to a List
  2. Remove Items from a List
  3. Count or Locate Items in a List
  4. Sort a List
  5. Reverse a List
  6. Copy the Contents of a List

Let us discuss these methods in detail in the coming sections.

Adding Items to a List

append() method adds an item (passed as an argument) to the end of a list.

>>> l = ["T", "C", 2, 4]
>>> l.append(2.5)
>>> l
['T', 'C', 2, 4, 2.5]

If the item has to be added at a particular index, insert() method can be used.

>>> l = ["T", "C", 2, 4]
>>> l.insert(3, 2.5)
>>> l
['T', 'C', 2, 2.5, 4]

extend() method appends each item of the argument list at the end of the target list.

>>> l = ["T", "C", 2, 4]
>>> l.extend([2.5, "SE"])
>>> l
['T', 'C', 2, 4, 2.5, 'SE']  

Removing Items from a List

clear() method removes all items from the list.

>>> l = ["T", "C", 2, 4, "S"]
>>> l.clear()
>>> l
[]

remove() method removes the first occurrence of an item from the list.

>>> l = ["Hi", "Ed", "Py", "Hi"]
>>> l.remove("Hi")
>>> l
['Ed', 'Py', 'Hi']

If an index is provided, pop() method removes the item at that index, else the last item is removed from the list.

>>> l = ["T", "C", 2, 4, "S"]
>>> item = l.pop()
>>> item
'S'
>>> l
['T', 'C', 2, 4]

>>> l = ["T", "C", 2, 4, "S"]
>>> item = l.pop(2)
>>> item
2
>>> l
['T', 'C', 4, 'S']

Counting or Locating Items in a List

An item x can be located in a list using the index(x[, i[, j]]) method which returns the first occurrence of the item at or after index i and before index j.

In case i and j are not specified they default to i=0 and j=len(l).

>>> l = [34, 4, 6, 23, 4]
>>> l.index(4)
1
>>> l.index(4, 3)
4
>>> l.index(6, 1, 4)
2

count() method can be used to count the occurrence(s) of an item in a list.

>>> l = [34, 4, 6, 23]
>>> l.count(4)
1
>>> l = ["it", "is", "it", "I"]
>>> l.count("it")
2

Reversing Items

reverse() method can be used to reverse a list in-place.

>>> l = ["T", "C", 2, 4, "S"]
>>> l.reverse()
>>> l
['S', 4, 2, 'C', 'T']

If you do not wish to modify the existing list and create a new list with items in reverse order, use the built-in function reversed() nested in the built-in list().

>>> l = ["T", "C", 2, 4, "S"]
>>> new_l = list(reversed(l))
>>> new_l
['S', 4, 2, 'C', 'T']
>>> l
['T', 'C', 2, 4, 'S']

Sorting a List

Python lists have a built-in sort() method which sorts the items in-place using < comparisons between items.

The method also accepts 2 key-worded arguments:

  • key is used to specify a function which is called on each list element prior to making the comparisons.
  • reverse is a boolean which specifies whether the list is to be sorted in descending order.
>>> l = [34, 4, 6, 23]
>>> l.sort()
>>> l
[4, 6, 23, 34]

>>> l = [34, 4, 6, 23]
>>> l.sort(reverse=True)
>>> l
[34, 23, 6, 4]

>>> l = ["Oh", "Hi", "Py", "ed"]
>>> l.sort()
>>> l
['Hi', 'Oh', 'Py', 'ed']

>>> l = ["Oh", "Hi", "Py", "ed"]  
# lowercase the words before sorting
>>> l.sort(key=str.lower)  
>>> l
['ed', 'Hi', 'Oh', 'Py']

If you do not wish to modify the existing list and create a new list with sorted items in, use the built-in sorted() function which returns a new sorted list.

>>> l = [34, 4, 6, 23]
>>> new_l = sorted(l)
>>> new_l
[4, 6, 23, 34]

Copying a List

In Python, we can create an object (data) and bind its reference to a variable using the assignment operator (=).

As multiple collections or items in collections can point to the same mutable object, a copy is required so one can change one copy without changing the other.

Let us take an example:

>>> old_l = [1, 2, 3]

# Copying old list into a new list
>>> new_l = old_l

# Checking if both lists are 
# pointing to the same object
>>> id(new_l)==id(old_l)
True

# Adding element to new list
>>> new_l.append(4)
>>> new_l
[1, 2, 3, 4]
>>> old_l
[1, 2, 3, 4]

It can be seen how the assignment operator does not create a new copy of the list.

The copy() method can be used to create a new list containing the items of the original list.

>>> old_l = [1, 2, 3]

# Copying old list into a new list
>>> new_l = old_l.copy()

# Checking if both lists are 
# pointing to the same object
>>> id(new_l)==id(old_l)
False

# Adding element to new list
>>> new_l.append(4)
>>> new_l
[1, 2, 3, 4]
>>> old_l
[1, 2, 3]

Assigning a slice of the entire list ([:]) is also equivalent to creating a new copy.

>>> old_l = [1, 2, 3]

# Copying old list into a new list
# using slice notation
>>> new_l = old_l[:]

# Checking if both lists are 
# pointing to the same object
>>> id(new_l)==id(old_l)
False

# Adding element to new list
>>> new_l.append(4)
>>> new_l
[1, 2, 3, 4]
>>> old_l
[1, 2, 3]

Nested List

A list of lists is also known as a nested list.

Previously, we learnt how to create a list of attributes of a particular vehicle available for sale in a dealership.

Let us now create a nested list containing some details of vehicles available for sale.

# Make Model Year No_of_wheels
l = [["Kia", "Sonnet", 2019, 4],
  ["Toyota", "Camry", 2018, 4],
  ["BMW", "Z4", 2015, 4],
  ["BMW", "S1000", 2016, 2],
  ["KTM", "390", 2019, 2],
  ]

Thus, nested list is useful in representing a dataset where each item is a list (datum) containing the attributes of an observation.

l[i][j] is the syntax to fetch the j+1th item of the list at index i of the nested list l.

>>> l[2][1]
'Z4'

List Comprehension

A short and succinct way of creating a new list by transforming an existing list is via list comprehension.

Also, due to the optimizations present in the Python interpreter, there are performance benefits of using list comprehension.

Member-wise Operation

List comprehension can be used to make a new list where each element is the result of some operations applied to each member of another sequence or iterable.

For example, to create a new list where each item is squared.

>>> l = [2, 3, 4, 5, 6, 8]
>>> l2 = [i**2 for i in l]
>>> l2
[4, 9, 16, 25, 36, 64]

Filtering or Subsequence

List comprehension can also be used to create a subsequence of those elements that satisfy a certain condition.

For example, to create a new list where each item is divisible by 2.

>>> l = [2, 3, 4, 5, 6, 8]
>>> l2 = [i for i in l if i%2==0]
>>> l2
[2, 4, 6, 8]

Sample Programs

1. Min, Max and Mean

Write a program to find the minimum, maximum and mean of values stored in a list input by user.

a) Without Using Built-in Functions

Code

#create an empty list
l = []

n = int(input("Enter length of list: "))
for i in range(n):
    val = float(input("Enter item: "))
    #append marks in the list 
    l.append(val)

# Set first item as the default min value
minval = l[0]
# Set first item as the default max value
maxval = l[0]
# Store sum of items
s = 0
for val in l:
    # check if item value is smaller than current min val
    if val < minval:
        minval = val
    # check if item value is greater than current max val
    if val > maxval:
        maxval = val
    s += val

print("Minimum :", minval)
print("Maximum :", maxval)
print("Mean :", s/n)

Output

Enter length of list: 5
Enter item: 3
Enter item: 2
Enter item: 6
Enter item: 9
Enter item: 1
Minimum : 1.0
Maximum : 9.0
Mean : 4.2

b) Using Built-in Functions

Code

#create an empty list
l = []

n = int(input("Enter length of list: "))
for i in range(n):
    val = float(input("Enter item: "))
    #append marks in the list 
    l.append(val)

print("Minimum :", min(l))
print("Maximum :", max(l))
print("Mean :", sum(l)/n)

Output

Enter length of list: 5
Enter item: 3
Enter item: 2
Enter item: 6
Enter item: 9
Enter item: 1
Minimum : 1.0
Maximum : 9.0
Mean : 4.2

2. Linear Search

Write a program to enter a list and then check if the number entered by a user is present in that list.

Code

#create an empty list
l = []

n = int(input("Enter length of list: "))
for i in range(n):
    val = input("Enter item: ")
    #append marks in the list 
    l.append(val)

search = input("Enter search value: ")

found = False
for i in range(n):
    if l[i] == search:
        found = True
        break
if found:
    print("Search value located at index", i)
else:
    print("Search value not found")

Output

Enter length of list: 4
Enter item: 2
Enter item: 6
Enter item: 3
Enter item: 7
Enter search value: 3
Search value located at index 2

Enter length of list: 4
Enter item: 2
Enter item: 6
Enter item: 3
Enter item: 7
Enter search value: 1
Search value not found

3. Frequency of Elements

Write a program to enter a list and then print the frequency of elements present in that list.

a) Without Using Built-in Functions

Code

#create an empty list
l = []

n = int(input("Enter length of list: "))
for i in range(n):
    val = input("Enter item: ")
    #append marks in the list 
    l.append(val)

# Let us create two lists 
# 1. to store unique items 
items = []
# 2. to store the count of unique items
counts = []

for val in l:
    if val not in items:
        items.append(val)
        counts.append(1)
    else:
        for idx in range(len(items)):
            if items[idx] == val:
                counts[idx] += 1

print("Frequency of Elements")
for idx in range(len(items)):
    print(items[idx], "-", counts[idx])

Output

Enter length of list: 8
Enter item: 2
Enter item: 3
Enter item: 3
Enter item: 4
Enter item: 2
Enter item: 5
Enter item: 6
Enter item: 6
Frequency of Elements
2 - 2
3 - 2
4 - 1
5 - 1
6 - 2

b) Using Built-in Functions

Code

l = []

n = int(input("Enter length of list: "))
for i in range(n):
    val = input("Enter item: ")
    #append marks in the list 
    l.append(val)

# List to store unique items 
items = []

print("Frequency of Elements")
for val in l:
    if val not in items:
        items.append(val)
        print(val, "-", l.count(val))

Output

Enter length of list: 8
Enter item: 2
Enter item: 3
Enter item: 3
Enter item: 4
Enter item: 2
Enter item: 5
Enter item: 6
Enter item: 6
Frequency of Elements
2 - 2
3 - 2
4 - 1
5 - 1
6 - 2

Tuple

List vs Tuple

Tuples are like lists, with a difference - they are immutable. This means that once initialized a user cannot modify its value, which makes it a useful feature to ensure the sanctity of data and guarantee that it is not being modified by the program.

How to Create Tuple?

Tuples are declared using parentheses ( ), with successive items separated by a comma ,.

>>> l = ("Hi", "Ed", "Punk")
>>> type(l)
<class 'tuple'>

tuple()

Apart from the method shown above, the built-in tuple() function can also be used to create new tuples.

If no arguments are provided to the tuple() function, an empty tuple is created.

>>> t = tuple()
>>> t
()

If a string, tuple or set is passed as an argument, tuple() functions converts them into a tuple.

>>> t = tuple("abcd")
>>> t
('a', 'b', 'c', 'd')
>>> t = tuple({1, 2, 3})
>>> t
(1, 2, 3)
>>> t = tuple([1, 2, 3, 4])
>>> t
(1, 2, 3, 4)

What is a Singleton?

In case a tuple has only 1 item, it is known as a singleton.

It is a good practice to include a trailing comma to avoid the Python interpreter from treating it as a value inside regular parentheses as shown in the examples below.

>>> regular_string = ("Hi")
>>> regular_string
'Hi'
>>> type(regular_string)
<class 'str'> 

>>> regular_int = (1)
>>> regular_int
1
>>> type(regular_int)
<class 'int'>     

>>> str_tuple = ("Hi", ) 
>>> type(str_tuple)
<class 'tuple'>

>>> int_tuple = (1, ) 
>>> type(int_tuple)
<class 'tuple'>

Accessing Items of a Tuple

Tuples use zero-based indexing, where 0 is the index of the first element and len(tuple) - 1 is the index of the last element.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[0]
'BMW'
>>> t[2]
2019

Length of Tuple

The built-in len() function can be used to return the length of the tuple.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> len(t)
6

Negative Indexing

Just like list, tuple supports negative indexing, i.e., you can access the values of tuple from the end. Index of -1 denotes the last item in the tuple, -2 is the second last item and so forth.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[-1]
True
>>> t[-3]
4

Tuples are Immutable

Tuples are immutable, i.e., no modifications are permitted once it is created and any attempt to do so raises an error.

>>> t = ("BMW", "Z4", 2019)
>>> t[1] = "Charger"
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'tuple' object does not support item assignment

Tuple Operations

We can perform various operations on a tuple such as membership, concatenation, repetition and slicing.

Membership

in and not in can be used to detect the membership of an item in a tuple.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> "Red" in t
True
>>> "Gold" in t
False
>>> "Gold" not in t
True    

Concatenation

+ operator can be used to join two tuples to create a new tuple.

>>> t = ("BMW", "Z4")
>>> u = (2019, "Red")
>>> t+u
('BMW', 'Z4', 2019, 'Red')

Repetition

The * operator creates a new tuple with items of a tuple repeated the number of times as specified by the integer operand.

>>> t = (1, 2)
>>> t*3
(1, 2, 1, 2, 1, 2)

Tuple Slicing

A subset of tuple t can be obtained using the tuple slice notation given as t[i:j], where the item at index i is included, but the item at index j is excluded.

For example, the slice notation [1:4] refers to items from index 1 to index 3 (i.e. 4-1).

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[1:4]
('Z4', 2019, 4)

The slice notation t[i:j:k] can also include a third number known as the step. Here, a tuple is sliced from start index i to end index (j) - 1 with a step of k items.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[1:4:2]
('Z4', 4)

Slice notations also have some useful defaults.

0 is the default for the first number and size of the tuple is the default for the second number.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[2:]
(2019, 4, 'Red', True)
>>> t[:4]
('BMW', 'Z4', 2019, 4)

Slice notation also supports negative indexing.

>>> t = ("BMW", "Z4", 2019, 
...       4, "Red", True)
>>> t[-4:]
(2019, 4, 'Red', True)
>>> t[:-2]
('BMW', 'Z4', 2019, 4)
>>> t[-4:-1]
(2019, 4, 'Red')

Traversing a Tuple

Tuple Traversal is the process of visiting every item in a tuple, usually from the first item to the last item, and executing some instruction on the accessed item.

Python provides 2 ways to traverse a tuple:

Direct Traversal

As a tuple is an ordered collection of items, the for statement can be used to directly and sequentially access each item.

Code

t = ("BMW", "Z4", 2019, 
     4, "Red", True)
for item in t:
    print(item)

Output

BMW
Z4
2019
4
Red
True

Location or Index Based Traversal

In location based or index based traversal the value of index starts at 0 and increments as long as it is lesser than the length of the tuple.

This index value can be used to access the item at that index in a tuple using the index operator [].

for statement can be used to iterate over the index of the tuple using the range() and len() functions.

Code

t = ("BMW", "Z4", 2019, 
     4, "Red", True)
for i in range(len(t)):
    print(t[i])

Output

BMW
Z4
2019
4
Red
True

A while statement can be used to traverse a tuple by iterating on the value of index.

Code

t = ("BMW", "Z4", 2019, 
     4, "Red", True)
index = 0
while index < len(t):
    print(t[index])
    index += 1

Output

BMW
Z4
2019
4
Red
True

Built-in Functions that can be used for a Tuple

Built-in functions max(), min() and sum() can be used to calculate the maximum, minimum and sum of items in a tuple, respectively.

>>> t = (4, 8, 2, 1, 3)
>>> min(t)
1
>>> max(t)
8
>>> sum(t)
18

Locating Items in a Tuple

As compared to a list, tuple supports only methods that do not try to modify it.

An item x can be located in a tuple using the index(x[, i[, j]]) method which returns the first occurrence of the item at or after index i and before index j. In case i and j are not specified they default to i=0 and j=len(t).

>>> t = (34, 4, 6, 23, 4)
>>> t.index(4)
1
>>> t.index(4, 3)
4
>>> t.index(6, 1, 4)
2

Counting the Occurrence of an Item

count() method can be used to count the occurrence(s) of an item in a tuple.

>>> t = (34, 4, 6, 23, 4)
>>> t.count(4)
2
>>> t = ("it", "is", "it", "I")
>>> t.count("it")
2

New Tuple with Reversed Items

To create a new tuple with items in reverse order, use the built-in function reversed() nested in the built-in tuple().

>>> t = ("T", "C", 2, 4, "S")
>>> new_t = tuple(reversed(t))
>>> new_t
('S', 4, 2, 'C', 'T')
>>> t
('T', 'C', 2, 4, 'S')

New Tuple with Sorted Items

To create a new tuple with sorted items, use the built-in sorted(x,[key, reverse]) function which returns a new sorted tuple.

The method optionally accepts 2 keyword (named) arguments:

  • key which is used to specify a function which is called on each tuple element prior to making the comparisons, and
  • reverse is a boolean which specifies whether the tuple is to be sorted in descending order.
>>> t = (34, 4, 6, 23, 9)
>>> tuple(sorted(t))
(4, 6, 9, 23, 34)
>>> tuple(sorted(t, reverse=True))
(34, 23, 9, 6, 4)

>>> t = ("Oh", "Hi", "Py", "it")
>>> tuple(sorted(t))
('Hi', 'Oh', 'Py', 'it')
# lowercase the words before sorting
>>> tuple(sorted(t, key=str.lower))
('Hi', 'it', 'Oh', 'Py')

Nested Tuple

A tuple of tuples is also known as a nested tuple.

Let us create a nested tuple containing the details of all vehicles available for sale.

# Make Model Year No_of_wheels
t = (
    ("Kia", "Sonnet", 2019, 4),
    ("Toyota", "Camry", 2018, 4),
    ("BMW", "Z4", 2015, 4),
    ("BMW", "S1000", 2016, 2),
    ("KTM", "390", 2019, 2),
)

t[i][j] is the syntax to fetch the j+1 th item of the tuple at index i of the nested tuple t.

>>> t[2][1]
'Z4'

As compared to a nested list, a nested tuple is useful in representing a dataset (such as a table fetched from a database) where it is important to ensure the sanctity of data as the code cannot modify it because tuples are immutable.

Understanding the Immutable Nature of Tuples

Just like lists, the += operation works for a tuple and adds new item(s) to it.

>>> t = ("Hi", "Ed", "Punk")
>>> t += (1, 2)
>>> t
('Hi', 'Ed', 'Punk', 1, 2)

But tuples are immutable right?
Then how are we able to modify it.

To understand it better, let us revisit what happens when we apply += operator on a list.

>>> l = ["Hi", "Ed", "Punk"]
>>> id_l = id(l)
>>> l += [1, 2]
>>> l
['Hi', 'Ed', 'Punk', 1, 2]
>>> id(l) == id_l
True

In case of a list, the modified list l still points at the same object.

Now, let us add items to a tuple.

>>> t = ("Hi", "Ed", "Punk")
>>> id_t = id(t)
>>> t += (1, 2)
>>> t
('Hi', 'Ed', 'Punk', 1, 2)
>>> id(t) == id_t
False

In case of a tuple, the modified tuple is actually a completely new tuple with contents of the original tuple and the extension.

The original tuple is not modified as it is immutable. But, as t is no longer pointing to the original tuple, it is freed from memory.

Thus, it is recommended that instead of +=, append() and extend() methods should be employed to add new items programmatically as it will raise an error in case the code is trying to modify a tuple.

>>> l = ["Hi", "Ed", "Punk"]
>>> l.extend([1, 2])
>>> l
['Hi', 'Ed', 'Punk', 1, 2]

>>> t = ("Hi", "Ed", "Punk")
>>> t.extend((1, 2))
Traceback (most recent call last):
    File "<stdin>", line 1, in <module>
AttributeError: 'tuple' object has no attribute 'extend'

Dictionary

What is a Dictionary?

Python provides a mapping type collection which contains keys, and values corresponding to those keys.

This collection is known as a dictionary (type dict) , where each key is unique and can be used to easily store or retrieve values (any data-type including string, int, float, list).

Dictionaries are indexed by keys (any immutable type - numbers, string, tuple) as compared to lists which are indexed by a range of numbers.

How to Create a Dictionary

An empty dictionary can be created using a pair of braces - {} or using the built-in function dict() which is also a constructor.

>>> d = {}
>>> type(d)
<class 'dict'>

>>> d = dict()
>>> d
{}
>>> type(d)
<class 'dict'>

To create a new dictionary with some initial values, one can use:

Key: Value Pairs

A sequence of key: value pairs separated by commas in braces - {}.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d
{'yr': 20, 'name': 'Ed', 18: True}

Sequence of (key, value) Tuples

A sequence of (key, value) tuples can be passed as an argument to the dict() function.

>>> l = [("yr",20), ("name","Ed"), 
...      (18,True)]
>>> d = dict(l)
>>> d
{'yr': 20, 'name': 'Ed', 18: True}

Keyword/Named Arguments

Keys and values can be passed as keyword arguments to the dict() function.

>>> d = dict(yr=20, name="Ed", 
...          is18=True)
>>> d
{'yr': 20, 'name': 'Ed', 'is18': True}

One of the limitations of this method is that the keys of the dictionary are only of type string and their names must be within the namespace of an identifier.

Key and Value Lists

There might cases when there is a need to combine two lists where keys are in one list and the corresponding values are available in another list.

The built-in zip() function is useful for combining two lists into tuple pairs.

The zipped iterator can be passed as an argument to the dict() to create a new mapping collection.

>>> m = ["yr", "name", 18]
>>> n = [20, "Ed", True]
>>> list(zip(m, n))
[('yr', 20), ('name', 'Ed'), (18, True)]
>>> dict(zip(m, n))
{'yr': 20, 'name': 'Ed', 18: True}

Keys with Default Value

dict.fromkeys(iterable[, value]) can be used to create new dictionary with items of an iterable as keys with an optional value (default - None) corresponding to the keys.

>>> l = ["yr", "name", 18]
>>> dict.fromkeys(l)
{'yr': None, 'name': None, 18: None}
>>> dict.fromkeys(l, 0)
{'yr': 0, 'name': 0, 18: 0}

Accessing Items (Key:Value) of a Dictionary

Index Operator []

d[x] can be used to access the value corresponding to a key x in a dictionary d.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d["yr"]
20

get()

get(key[, default]) method can also be used to fetch the value for a key if key is in the dictionary, else a default value is returned.

If default is not provided, None is the default value returned.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d.get("name") 
'Ed'
>>> d.get("version") is None
True
>>> d.get("version", "1.0")
'1.0'

This is an elegant method of fetching a value from a dictionary and it should be used in real life software codes as it never raises a KeyError.

Updating a Dictionary

Index Operator []

d[x] = y can be used to add the value y corresponding to a key x in a dictionary d.

In case key x already exists, assignment updates or overwrites the value corresponding to it.

>>> d = {"yr": 20, 18: True}
>>> d["name"] = 'Ed'
>>> d
{'yr': 20, 18: True, 'name': 'Ed'}

>>> d["name"] = 'Py'
>>> d
{'yr': 20, 18: True, 'name': 'Py'}

update()

update() method can be used to add new items or update existing items in a dict.

This method accepts the following:

1. Dictionary

>>> d = {"yr": 20, 18: True}
>>> d.update({"name": 'Ed'})
>>> d
{'yr': 20, 18: True, 'name': 'Ed'}

>>> d.update({"yr": 15, 18: False})
>>> d
{'yr': 15, 18: False, 'name': 'Ed'}

2. Sequence of (key, value) pairs

>>> d = {"yr": 20, 18: True}
>>> d.update([("name", 'Ed'), 
...            ('yr', 15)])
>>> d 
{'yr': 15, 18: True, 'name': 'Ed'}

3. Key-worded arguments

>>> d = {"yr": 20, 18: True}
>>> d.update(name="Ed", yr=15)
>>> d
{'yr': 15, 18: True, 'name': 'Ed'}

setdefault()

setdefault(key[, default]) method returns a value corresponding to a key.

If the key is not present in the dictionary, it is inserted with the provided default value.

If no default value is provided, the value is set as None.

>>> d = {"yr": 20, 18: True}
>>> d.setdefault("name")
>>> d
{'yr': 20, 18: True, 'name': None}

>>> d = {"yr": 20, 18: True}
>>> d.setdefault("name", "Ed")
'Ed'
>>> d
{'yr': 20, 18: True, 'name': 'Ed'}

Removing an Item (Key:Value) from a Dictionary

del

del keyword can be used to remove a key: value pair.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> del d["name"]
>>> d
{'yr': 20, 18: True}

clear()

clear() method can be used to clear all values of a dictionary.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d.clear()
>>> d
{}

pop()

pop(key[, default]) method can be used to remove a key: value pair.

In case the key is not present in the dictionary, the method returns the value of argument default provided by the user.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d.pop("name")
'Ed'
>>> d
{'yr': 20, 18: True}

>>> d.pop("name")
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
KeyError: 'name'

>>> d.pop("name", "Punk")
'Punk'

popitem()

popitem() can be used to destructively iterate over a dictionary removing and returning a (key, value) pair in LIFO (Last Item First Out) order.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d.popitem()
(18, True)
>>> d.popitem()
('name', 'Ed')
>>> d.update({"name": "py"})
>>> d
{'yr': 20, 'name': 'py'}
>>> d.popitem()
('name', 'py')
>>> d.popitem()
('yr', 20)
>>> d
{}

Dictionary Operations

Membership

in keyword can be used to test the presence of a key in a dictionary.

>>> d = {"yr": 20, 18: True}
>>> "yr" in d
True

Similarly, not in can be used to determine the absence of a key.

>>> "name" not in d
True

Union

The | (union) operator can be used to merge two dictionaries.

>>> d = {"yr": 20, 18: True}
>>> n = {"name": "Ed"}
>>> d | n
{'yr': 20, 18: True, 'name': 'Ed'}

In case of common keys between the two operands (dictionaries), the values of the operand on the right takes priority.

>>> d = {"yr": 20, 18: True}
>>> n = {"yr": 15, "name": "Ed"}
>>> d | n
{'yr': 15, 18: True, 'name': 'Ed'}

In the above example, both d and n shared a common key yr. The value corresponding to yr in n gets priority.

The |= (union) augmented assignment operator can be used to update the dictionary with keys and values from another dictionary or an iterable of (key, value) pairs.

>>> d = {"book": "Python", "year": 1990}
>>> dnew = {"author": "Guido"}
>>> d |= dnew
>>> d
{'book': 'Python', 'year': 1990, 'author': 'Guido'}

If both the dictionaries share a common key, then the value corresponding to the key in the right operand is the updated value.

>>> d = {"book": "Python", "year": 1990}
>>> dnew = {"author": "Guido", "year": 2000}
>>> d |= dnew
>>> d
{'book': 'Python', 'year': 2000, 'author': 'Guido'}

In the above example, both d and dnew shared a common key year. The value (1990) corresponding to year in d is updated with the new value.

The |= operator also works in case the right operand is an iterable instead of a dictionary as shown in the example below.

>>> d = {"book": "Python", "year": 1990}
>>> inew = [("author", "Guido"), ("year", 2000)]
>>> d |= inew
>>> d
{'book': 'Python', 'year': 2000, 'author': 'Guido'}

Traversing a Dictionary

Compared to position based indexing of list or tuple, dictionaries are indexed based on the key.

Direct Traversal

for loop can be used to directly iterate over the keys of a dict.

d = {"yr": 20, "name": "Ed", 
     18: True}
for key in d:
    print(key,":", d[key])

Output

yr : 20
name : Ed
18 : True

Traversing Using Dictionary Methods

Dictionary methods items(), keys() and values() can be used to fetch the items, keys and values in a dictionary, respectively.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> d.keys()
dict_keys(['yr', 'name', 18])
>>> d.values()
dict_values([20, 'Ed', True])
>>> d.items()
dict_items([('yr', 20), ('name', 'Ed'), (18, True)])

dict_keys, dict_values and dict_items are iterables that can be used in a for statement to traverse the dictionary.

Code

d = {"yr": 20, "name": "Ed", 
     18: True}
for key in d.keys():
    print(key)

Output

yr
name
18

Code

d = {"yr": 20, "name": "Ed", 
     18: True}
for value in d.values():
    print(value)

Output

20
Ed
True

Code

d = {"yr": 20, "name": "Ed", 
     18: True}
for key, value in d.items():
    print(key,":", value)

Output

yr : 20
name : Ed
18 : True

Built-in Functions for a Dictionary

Number of Items

len() can be used to fetch the number of items in the dictionary.

>>> d = {"yr": 20, "name": "Ed", 
...       18: True}
>>> len(d)
3

Min and Max

The min() and max() built-in functions return the minimum and maximum value among the keys of a dictionary.

In case of string keys, they return the first and last occurring strings alphabetically.

>>> d = {"yr": 20, "name": "Ed", 
...       "is18": True}
>>> min(d)
'is18'
>>> max(d)
'yr'

>>> d = {2: "b", 3: "c", 1: "a"}
>>> min(d)
1
>>> max(d)
3

list()

To get the list of all keys in a dictionary, use the list() built-in function.

>>> d = {"book": "Python", "year": 1990, "author": "Guido"}
>>> list(d)
['book', 'year', 'author']

sorted()

To get a sorted list of keys, you can use the sorted() built-in function.

>>> d = {"book": "Python", "year": 1990, "author": "Guido"}
>>> sorted(d)
['author', 'book', 'year']

Creating a Copy of a Dictionary

A new copy of a dictionary can be made using copy() method:

>>> old_d = {"a": 1, "b": 2}
>>> new_d = old_d.copy()

# Checking if both dicts are 
# pointing to the same object
>>> new_d is old_d
False

>>> new_d["c"] = 3
>>> new_d["b"] = 4
>>> new_d
{'a': 1, 'b': 4, 'c': 3}
>>> old_d
{'a': 1, 'b': 2}

Nested Dictionary

When the value in a key:value pair of a dictionary is of type dict, it is known as a nested dictionary.

In simple terms, it is a dictionary inside a dictionary.

Records of a table can be represented as a nested dict with primary key as the outer dict keys.

d = { 1: {"name": "Amar", "age": 19},
      2: {"name": "Ria", "age": 20},
      3: {"name": "Rao", "age": 18}}

print(d[1])
print(d[2]["name"])

Output

{'name': 'Amar', 'age': 19}
Ria

Sample Programs

Frequency of Characters

Write a program to count the number of times a character appears in a given string.

Code

d = {}
s = input("Enter string: ")
for c in s:
    if c in d:
        d[c] += 1
    else:
        d[c] = 1

print("Frequency of characters")
for key in d:
    print(key, "-", d[key])

Output

Enter string: pythondata
Frequency of characters
p - 1
y - 1
t - 2
h - 1
o - 1
n - 1
d - 1
a - 2

Salary Book

Write a program to enter employee names and their salaries as input and store them in a dictionary.

Code

n = int(input("Enter number of employees: "))
emp = dict()  
for cnt in range(n):
    name = input("Enter employee name: ") 
    salary = int(input("Enter salary: ")) 
    emp[name] = salary

print("Employee Name & Salary") 
for key in emp:
    print(key, '-', emp[key])

Output

Enter number of employees: 3
Enter employee name: Anil Raj
Enter salary: 12000
Enter employee name: Dinesh Kumar
Enter salary: 15000
Enter employee name: Sam Singh
Enter salary: 10000
Employee Name & Salary
Anil Raj - 12000
Dinesh Kumar - 15000
Sam Singh - 10000

Python Standard Library

Built-in Functions

Python has a rich and extensive Standard Library which gives it an edge over traditional programming languages.

Python Standard Library contains 69 built-in functions that are commonly used by programmers which saves a lot of time as they can be directly used in a program.

We have already used some functions in the previous sections like input(), output(), len(), sum(), min(), max(), list(), dict(), etc.

Some of the widely used functions can be categorized as follows:

  • Mathematical Functions
  • Type Functions
  • Input/Output Functions
  • Base/Unicode Functions

Mathematical Functions

abs()

abs(x) returns the absolute value or magnitude of x of type int, float or complex number.

>>> abs(-2.3)
2.3
>>> abs(-10)
10
>>> abs(2 + 2j)
2.8284271247461903

round()

round(x [,ndigits]) rounds off x (float) to ndigits precision after the decimal point.

In case ndigits is not provided, it rounds off to the nearest integer.

>>> round(2.33462398)
2
>>> round(2.33462398, 3)
2.335

sum()

sum(sequence [,start]) returns the sum of items in a sequence of type list, tuple, range or set.

If a second argument start is provided, it is added to the sum.

>>> sum([1, 2, -1])
2
>>> sum((1, 2, -1))
2
>>> sum([1, 2, -1], 10)
12

min()

min(sequence) returns the minimum value of items in a sequence of type list, tuple, range, str or set.

Apart from iterables, min(arg1, arg2, ..) also accepts multiple arguments arg1, arg2 .. of numeric type and returns the smallest among these arguments.

>>> min([1, 2, -1])
-1
>>> min(1, 2, -1)
-1

# character with minimum
# ASCII value in a String
>>> min("hello")
'e'

max()

max(sequence) returns the maximum value of items in a sequence of type list, tuple, range, str or set.

Apart from iterables, max(arg1, arg2, ..) also accepts multiple arguments arg1, arg2 .. of numeric type and returns the largest among these arguments.

>>> max([1, 2, -1])
2
>>> max(1, 2, -1)
2

# character with maximum
# ASCII value in a String
>>> max("hello")
'o'

pow()

pow(base, exp [,mod]) raises a base (int, float) to the power exp (int, float), i.e. base**exp.

If mod (int) is provided (base**exp) % mod is returned.

>>> pow(3, 2, 7)
2
>>> pow(1.4141, 2)
1.9996788099999998

divmod()

divmod(a, b) returns a tuple (a // b, a % b) consisting of the quotient and remainder when a (int, float) is divided by b (int, float).

>>> divmod(23, 3.5)
(6.0, 2.0)
>>> divmod(-10, 7)
(-2, 4)

Type Functions

Python has built-in functions to handle various aspects of datatypes such as checking and conversion.

Type Checking

type() and isinstance() builtin functions are used for checking the data type of objects.

Check out Type Checking section in the chapter Variable, Objects & Data Types to learn more about it in detail.

Built-in Type Functions

We have previously discussed the various built-in data types available in Python.

The following functions are often used to assign a default value or create an empty collection when no arguments are provided:

Function Default Value
bool() False
int() 0
float() 0.0
complex() 0j
str() ''
list() []
tuple() ()
set() set()
frozenset() frozenset()
dict() {}

The Type Casting section of the chapter Variable, Objects & Data Types covers these functions in detail in case any argument is passed.

I/O Functions

Python provides the following built-in functions to handle user input and result output:

input()

input() function can be used to accept a user input and assign it to a variable.

When this function is encountered in the code, the python interpreter waits for the user to type a response which is read as a string.

Code

name = input("Enter name: ")
print("Hello,", name)

Output

Enter name: Python
Hello, Python

print()

The built-in print() function can be used to display an output (value of variables, expressions, etc.) on the standard output.

For example, the below code computes the area of a rectangle and displays it:

Code

length = 10
breadth = 5
area = length * breadth
print("Area:", area)

Output

Area: 50

Both, input() and print() functions are covered in detail in the chapter Input & Output.

open()

open() function is used to open a file and return the corresponding file object.

This function supports various modes useful for reading from a file and writing to a file.

An example usage of open() function is shown below:

f = open('data.txt', 'r+')
# f is the file object which 
# can perform read and write
# operations on the file

This function is covered in detail in the chapter File Handling.

Base/Unicode Conversion Functions

bin()

Converts an int to a binary (base-2) string prefixed with '0b'.

>>> bin(9)
'0b1001'

oct()

Converts an int to an octal (base-8) string prefixed with '0o'.

>>> oct(9)
'0o11'

hex()

Converts an int to a lowercase hexadecimal (base-16) string prefixed with "0x".

>>> hex(29)
'0x1d'

ord()

Returns the integer Unicode code point for the given Unicode character str.

>>> ord("a")
97
>>> ord("β")
946

chr()

Converts the integer Unicode code point into the corresponding Unicode string.

>>> chr(97)
'a'
>>> chr(946)
'β'

What are Built-in Modules?

Apart from built-in functions, the Python Standard Library also contains a wide range of built-in modules which are a group of functions organized based on functionality.

Some commonly used modules are:

  • math - Mathematical functions
  • random - Generate pseudo-random numbers
  • statistics - Statistical functions
  • copy - Create shallow and deep copy of objects

Accessing Modules

A module can be accessed in a program using the import statement.

>>> import math

The above import statement loads all the functions available in the math module. To access any function in the module, simply type the module name followed by a period (.), followed by the function name.

>>> import math
>>> math.pow(3, 2)
9.0

Instead of loading all the functions in a module, the from statement can be used to access only specified functions.

>>> from math import pow
>>> pow(3, 2)
9.0

math Module

math module provides mathematical functions and constants as defined by the C standard.

Constants

The following frequently used mathematical constants are available in math module:

  • pi : π = 3.141592… (to available precision)
  • e : e = 2.718281… (to available precision)
  • tau : τ = 2π = 6.283185… (to available precision)
>>> import math
>>> math.pi
3.141592653589793
>>> math.e
2.718281828459045
>>> math.tau
6.283185307179586

Functions

Following useful mathematical functions are available in the math module:

fabs()

fabs(x) returns the absolute value of x.

>>> import math
>>> math.fabs(-3.24)
3.24

gcd()

gcd(a, b) returns the greatest common divisor of integers a and b.

>>> import math
>>> math.gcd(54, 24)
6

ceil()

ceil(x) returns the smallest integer greater than or equal to x.

>>> import math
>>> math.ceil(2.13) 
3

floor()

floor(x) returns the largest integer less than or equal to x.

>>> import math
>>> math.floor(2.13) 
2

fmod()

fmod(x, y) returns the value of the expression x - n*y such that the result has the same sign as x and magnitude less than |y| for some integer n.

This function should be preferred when working with floating point numbers as compared to x % y that should be used when working with integers.

>>> import math
>>> math.fmod(2.14, 0.5)
0.14000000000000012
>>> math.fmod(-2.14, 0.5)
-0.14000000000000012

pow()

pow(x, y) raises x to the power of y.

>>> import math
>>> math.pow(5, 2)
25.0

sqrt()

sqrt(x) returns the square root of x.

>>> import math
>>> math.sqrt(25)
5.0

sin(), cos() & tan()

sin(x), cos(x) and tan(x) return the sine, cosine and tangent of x (radians) respectively.

>>> import math
>>> math.cos(math.pi/3)
0.5000000000000001
>>> math.sin(math.pi/2)
1.0
>>> math.tan(math.pi/4)
0.9999999999999999

factorial()

factorial(n) computes the factorial of a positive integer n which is the product of all positive integers less than or equal to n.
n! = n×(n-1)×(n-2)...3×2×1,
where 0! = 1

>>> import math
>>> math.factorial(5) 
120

random Module

random module provides access to functions which can generate random numbers.

random()

random() function draws a random float in the half open interval [0.0, 1.0) with a uniform probability.

>>> import random
>>> random.random()
0.6857133962949904

Random Integer from Range

randrange(stop) is used to randomly select an integer from a range 0 to stop (excluding).

>>> import random
>>> random.randrange(10)
5

randrange(start, stop) is used to randomly select an integer from a range start to stop (excluding).

>>> import random
>>> random.randrange(5, 10)
8

randint(a, b) is an alias for randrange(a, b+1), provides an interface to generate a random integer N such that a <= N <= b (includes boundaries).

>>> import random
>>> random.randint(10, 20)
12

statistics Module

statistics module provides functions that are useful for calculating mathematical statistics of numeric (Real-valued) data.

Mean

mean(data) returns the arithmetic mean or average value of data (list or tuple of int or float).

>>> from statistics import mean
>>> mean([1, 2, 3, 6])
3

Median

median(data) returns the median or middle value of data (list or tuple of int or float) using the common "mean of middle two" method.

>>> from statistics import median
>>> median([1, 2, 3, 6])
2.5

Mode

mode(data) returns the most commonly occurring value in the data (list or tuple of int, str or float).

If there are multiple modes with the same count, the first occurrence in the sequence is returned.

>>> from statistics import mode
>>> mode([1, 2, 3, 6])
1
>>> mode([1, 2, 2, 3, 6])
2
>>> mode(["a", "b", "a", "c"])
'a'

copy Module

Limitation of Shallow Copy

copy() method does not recurse to create copies of the child objects, so if the child objects are mutable (example nested list) any modification in the child object will get reflected in the both the parent objects.

>>> old_list = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]

# Copying old list into a new list
>>> new_list = old_list.copy()

# Checking if both lists are pointing to the same object
>>> id(new_list)==id(old_list)
False

# Checking if items of both lists are pointing to the same objects
>>> [id(new_list[idx])==id(old_list[idx]) for idx in range(len(old_list))]
[True, True, True]

# Modify new list
>>> new_list[1][1] = 0
>>> new_list
[[1, 2, 3], [4, 0, 6], [7, 8, 9]]
>>> old_list
[[1, 2, 3], [4, 0, 6], [7, 8, 9]]

As we can see in the output, new_list[1][1] was modified which is reflected in both new_list and old_list.

The copy module provides the deepcopy() function which is helpful in mitigating this issue.

Deep Copy - deepcopy(x[, memo])

Deep copy overcomes the shortcomings of copy() and recursively creates copies of the child objects found in the original list. This leads to the creation of an independent copy of the original.

>>> import copy
>>> old_list = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]

# Copying old list into a new list
>>> new_list = copy.deepcopy(old_list)

# Checking if both lists are pointing to the same object
>>> id(new_list)==id(old_list)
False

# Checking if items of both lists are pointing to the same objects
>>> [id(new_list[idx])==id(old_list[idx]) for idx in range(len(old_list))]
[False, False, False]

# Modify new list
>>> new_list[1][1] = 0
>>> new_list
[[1, 2, 3], [4, 0, 6], [7, 8, 9]]
>>> old_list
[[1, 2, 3], [4, 5, 6], [7, 8, 9]]

Note the change in the id() equality of the children for [True, True, True] to [False, False, False]. As we can see in the output, new_list[1][1] was modified which gets reflected only in the new_list.

File Handling

File Handling in Python - Introduction & Overview

So far we have written programs which accept input from the user via keyboard and display the generated output on the standard output (console).

This activity has the following disadvantages:

  • Feasible for small inputs, but cumbersome in case of large inputs.
  • The entire input has to be entered every time the program is executed.
  • The output generated is not saved for sharing or later use.

Just like words can be written on a piece of paper, information can be stored on a computer disk as a named location or a file.

Python comes with the in-built ability to interact with files. Through file handling, Python programs can read a file to provide input data and output the results into a file for later use.

Text Files vs Binary Files - Use Case, File Formats, Examples

Primarily, there are two types of files:

Text File

A text file is the simplest way to store information in a human readable text format (sequence of ASCII or Unicode characters), which includes numeric values.

It is easy to view and modify the contents of a text file using any text editor like notepad or even IDLE.

Even the python script is stored as a text file given by the extension .py. .txt is the most popular extension used for a generic text file.

Although text files do not have any structure, there are international standards defining some rules for creating specialized text files like:

  • .csv, where each row is a set of comma separated values. This is the most popular data exchange format.
  • .tsv, similar to CSV but the values are separated by tabs instead of commas.
  • .xml and .json are popular web data exchange formats.
  • .html files are text files with contents written in the Hypertext Markup Language designed to display contents in a web browser.

Binary File

Although the contents of a text file is human readable, in reality this information is stored on the disk in form of machine readable bytes (1s and 0s) one character at a time. This makes the format simple to be operated by any application, but it is less efficient and consumes more memory (greater file size).

In a binary file, the contents are also stored in form of bytes, but these bytes do not directly translate into ASCII or Unicode characters.

Rather these bytes can represent anything like:

  • Complex Data Structures
  • Image
  • Audio
  • Video

and more.

As there is no simple rule to determine the basic unit of information, so opening a binary file in a text editor will display garbage values and even a single bit of change can corrupt the entire file and make it unreadable. Hence, specialized softwares are required to read and write binary files.

Python has a built-in pickle module which has implemented protocols to read and write binary files having .dat or .pickle file extension. pickle is a Python specific binary file format which can serialize any Python data structure (lists, dictionaries, etc) or code object into a binary file. This byte-content of this file can then be de-serialized and used later in any computer running Python.

File Opening & Closing

A text or binary file can be opened using the built-in open(file_name, mode='r') function.

The parameters of the function are explained below:

file_name

file_name is a required string parameter specifying the path of the file to be opened.

It can either be an absolute path or a relative path as shown below:

  • 'fname.txt' is the relative path of a text file residing in the current working directory from where the python script is being executed.
  • '../fname.txt' is the relative path of a text file outside the current directory where the python script is being executed.
  • '/Users/edpunk/Documents/fname.txt' is the absolute path of a text file which can be opened by the python script from any location as long as it is in the same system.

mode

mode is an optional string parameter which specifies the mode in which the file has to be opened. It defaults to 'r' which means open for reading in text mode.

The available modes are:

mode purpose
'r' Opens the file for reading (default).
't' Opens the file in text mode (default).
'w' Opens the file for writing, truncating (emptying) the file if it already exists.
'x' Same as 'w', but it fails if the file already exists.
'a' Opens the file for writing, where any new data is added at the end. It creates a new file if the file does not exists.
'b' Opens the file in binary mode.
'rb' Opens the file in binary and read-only mode.
'wb' Opens the file for writing in binary mode, truncating (emptying) the file if it already exists.
'+' Allows both read and write operations on a file.
'r+' Opens the file in read and write mode. It throws an error in case the file does not exists. If the file already exists, new data is overwritten on top of the existing data if the position of stream is not moved to the end of the file.
'r+b' Opens the file in binary read and write mode. It does not truncate the file if it already exists.
'w+' Opens the file in read and write mode. It creates a new file or truncates the contents of the file if it already exists.
'w+b' Opens the file in binary read and write mode. It creates a new file or truncates the contents of the file if it already exists.
'a+' Opens the file in read and append mode. It creates a new file if it does not exist. If the file already exists, new data is automatically added at the end of the file after existing data.
'a+b' Opens the file in binary read and append mode.

After opening a file and performing some file operations, it can be safely closed using the close() method.

For example, let us write a program to open a file data.txt in read and append mode and close the file object in the successive statement.

f = open('data.txt', 'a+')
f.close()

File Reading

Opening a file using the open() function creates and returns a file object on which the following activities can be performed:

Sequential Reading

The following three methods can be used on a file object to sequentially read the contents of a file:

read()

read(size = -1) method is used to read size numbers of bytes of data from a file at a time.

In case size is not specified, it reads and returns the entire content of the file.

Example

Let us consider a file named info.txt containing the below text:

Hello World
Thank You

Code

>>> f = open('info.txt', 'r')
>>> print(f.read(3))
Hel
>>> print(f.read(4))
lo W
>>> f.close()

>>> f = open('info.txt', 'r')
>>> print(f.read())
Hello World
Thank You
>>> f.close()

readline()

readline(size = -1) method without any arguments is used to read and return one line at a time from the given file.

If size is specified, it returns at most size bytes of data or the data until it encounters the newline character.

Example

Let us consider a file named info.txt containing the below text:

Hello World
Thank You

Code

>>> f = open('info.txt', 'r')
>>> f.readline(3)
'Hel'

# Remaining data (byte size < 20) 
# until it encounters newline
>>> f.readline(20)
'lo World\n'
>>> f.close()

>>> f = open('info.txt', 'r')
>>> f.readline()
'Hello World\n'
>>> f.close()

Since readline() returns one row at a time, it can be used in a while statement to iterate over the data row-wise. Once it reaches the end of file it returns an empty string.

Code

f = open('info.txt', 'r')
line = f.readline()
while line:
    # Removes newline
    # character from the 
    # end of the line
    line = line.strip()
    
    print(line)
    
    # read the next line
    line = f.readline()
f.close()

Output

Hello World
Thank You

for statement can also be used to traverse the file row-wise without any requirement of the readline() method. Simply iterating over the file object returns the data one row at a time.

Code

f = open('info.txt', 'r')
for line in f:
    # Removes newline
    # character from the 
    # end of the line
    line = line.strip()
    print(line)
f.close()

Output

Hello World
Thank You

readlines()

readlines() method returns a list of strings representing the lines (along with the newline character) of text file content.

Example

Let us consider a file named info.txt containing the below text:

Hello World
Thank You

Code

>>> f = open('info.txt', 'r')
>>> f.readlines()
['Hello World\n', 'Thank You']

Ad-hoc Reading

The following two methods can be used on a file object to randomly access contents of a file:

tell()

tell() returns the current byte position (integer) of the file object in the file.

Let us consider the same file info.txt for the below example:

>>> f = open('info.txt', 'r')
>>> f.read(4)
'Hell'
>>> f.tell()
4

seek()

seek(offset, reference=0) can be used to seek a location in the file object which is offset bytes from the provided reference.

The default value for reference is 0 which stands for the beginning of the file. For this default reference, the offset has to be a whole number (>=0).

Other allowed values of reference are:

  • 1, which denotes that the offset will be calculated from the current position of the file object (offset can be positive or negative)
  • 2, which denotes that the offset is calculated from the end of the file (offset is negative)

Note: In text files (those opened without a b in the mode string), only seek relative to the beginning of the file (reference = 0) is allowed. reference = 1 or 2 is only valid when the file is opened in binary mode.

Let us consider the same file info.txt for the below example:

>>> f.seek(6)
6

# Hello World\nThank You
#       ^
# Position of file pointer
# after seek.

>>> f.read()
'World\nThank You'
>>> f.tell()
21

>>> f.seek(12)
12

# Hello World\nThank You
#              ^
# Position of file pointer
# after seek.

>>> f.read()
'Thank You'

Writing a File

The following modes support file writing:

  • Writing from the beginning of a file : r+, r+b, w, x, wb, w+, w+b.
  • Appending at the end of an existing file : a, ab, a+, a+b.

The following methods can be used to write data in a file:

write()

write(s) method is useful for writing a string s into a file.

>>> s = "Hi World\nThank You"
>>> f = open("info.txt", "w")
>>> f.write(s)
21   
# Number of characters written

>>> f.close()

Now, on opening info.txt using a text editor, the following content is displayed.

Hi World
Thank You

writelines()

writelines(lines) method writes a list of strings into a file.

This method does not add the line separator (newline character \n), so they should be present at the end of each string.

>>> lines = ["Hi World\n", 
...          "Thank You\n"]
>>> f = open("info.txt", "w")
>>> f.writelines(lines)
>>> f.close()

Now, on opening info.txt using a text editor, the following content is displayed.

Hi World
Thank You

Note the empty line at the end which is added due to the \n at the end of the last string.

Reading & Writing Binary Files using pickle Module

In Python, the protocols to read and write binary files (.dat or .pickle file extension) have been implemented in the built-in pickle module.

pickle is a Python specific binary file format which can not only be used to store binary data, but also store any Python object.

This process of translating data structures (lists, dictionaries, etc.) and code objects (classes, functions, etc.) into bytes that can be stored in a binary file is known as Serialization. This binary file can be stored on disk or shared and it can be de-serialized and used later via Python.

Dumping Data

The dump() function can be used to write the pickled representation of any data or object into a file.

Syntax: pickle.dump(obj,file)

where:

  • obj is the object to be written
  • file is an open file object (opened in binary write wb or append ab mode).
>>> import pickle
>>> l = [["Anita","Maths",83], 
...      ["Amar","Maths",95],
...      ["Ani","Maths",90]]
>>> f = open("marks.dat", "wb")
>>> pickle.dump(l, f)
>>> f.close()

Loading Data

The load() function can be used to read the pickled representation of an object or data from a file.

Syntax: pickle.load(file)

where file is an open file object (opened in binary read mode rb).

>>> import pickle
>>> f = open("marks.dat", "rb")
>>> l = pickle.load(f)
>>> f.close()
>>> l
[['Anita', 'Maths', 83], ['Amar', 'Maths', 95], ['Ani', 'Maths', 90]]

Example: Traversing a Binary File

Write a program which performs the following Record Keeping activities:

  • Accept some student marks as input and write the data in a binary file
  • read all data from the file
  • add some more data to the file
  • show the entire contents of the file

Code

import pickle

# Open file in binary write mode
f = open("marks.dat", "wb")

# Enter student marks data
flag = 1
while flag != 0:
    name = input("Enter student name: ")
    subject = input("Enter subject: ")
    marks = float(input("Enter marks: "))
    rec = [name, subject, marks]
    pickle.dump(rec, f)
    flag = int(input("Enter 1 to add more or 0 to terminate: "))
f.close()

# read contents of file and display
f = open("marks.dat", "rb")

print("File contents:")

# Iteratively read all pickle objects written 
# in the file until the end of fie is reached
try:
    while True:
        rec = pickle.load(f)
        print(rec)
except EOFError:
    print("End of file reached")
    f.close()

# Add more data
f = open("marks.dat", "ab")
flag = 1
while flag != 0:
    name = input("Enter student name: ")
    subject = input("Enter subject: ")
    marks = float(input("Enter marks: "))
    rec = [name, subject, marks]
    pickle.dump(rec, f)
    flag = int(input("Enter 1 to add more or 0 to terminate: "))
f.close()

# show all contents
f = open("marks.dat", "rb")

print("File contents after appending:")
try:
    while True:
        rec = pickle.load(f)
        print(rec)
except EOFError:
    print("End of file reached")
    f.close()

Input/Output

Enter student name: Anita
Enter subject: Maths
Enter marks: 83
Enter 1 to add more or 0 to terminate: 1
Enter student name: Amar
Enter subject: Maths
Enter marks: 95
Enter 1 to add more or 0 to terminate: 0
File contents:
['Anita', 'Maths', 83.0]
['Amar', 'Maths', 95.0]
End of file reached
Enter student name: Akash
Enter subject: Science
Enter marks: 92
Enter 1 to add more or 0 to terminate: 1
Enter student name: Ira
Enter subject: Science
Enter marks: 99
Enter 1 to add more or 0 to terminate: 0
File contents after appending:
['Anita', 'Maths', 83.0]
['Amar', 'Maths', 95.0]
['Akash', 'Science', 92.0]
['Ira', 'Science', 99.0]
End of file reached

Reading & Writing a CSV File using csv Module

Comma-separated value (CSV) file format is one of the most common data serialization and exchange format where each row is a set of values separated by a delimiter.

The main rules for creating a CSV file are:

  • Each field is separated by a delimiter. Comma (,) is the default delimiter used in CSV files, but other delimiters (;, \t, |, etc.) can also be used.
  • If any field value contains a delimiter, it must be surrounded by a pair of quote characters (usually double-quotes character " ).
  • There is an optional single header line which contains the names of the fields.

An example CSV file containing the marks data is given below:

Name,Subject,Marks
Anita,Maths,83.0
Amar,Maths,95.0
Akash,Science,92.0
Ira,Science,99.0

To demonstrate why quote characters are required, let us have a look at the below contents of a CSV file which contains the average marks of some subjects (separated by comma) for each student.

Name,Average Of,Marks
Anita,"Accounting,Maths",83.0
Amar,"Accounting,Maths",95.0
Akash,"Physics,Chemistry,Biology",92.0
Ira,"Physics,Chemistry,Biology",99.0

Python has built-in csv module which provides utilities to read and write CSV files.

Reading CSV File

csv.reader(csvfile, delimiter=',', quotechar='"') function is used to return the reader object which iterates over CSV file line-by-line and returns it as a list of strings.

The csvfile file object should be opened with newline='' argument as the csv module has its own newline handling which correctly interprets the newlines depending on platform or in case they are embedded inside quoted fields.

Example #1

Let us write a program to read the contents of marks.csv.

marks.csv

Name,Subject,Marks
Anita,Maths,83.0
Amar,Maths,95.0
Akash,Science,92.0
Ira,Science,99.0

Code

import csv
with open('marks.csv', 
           newline='') as f:
    reader = csv.reader(f)
    for row in reader:
        print(row)

Output

['Name', 'Subject', 'Marks']
['Anita', 'Maths', '83.0']
['Amar', 'Maths', '95.0']
['Akash', 'Science', '92.0']
['Ira', 'Science', '99.0']

Example #2

Let us write a program to read the contents of marks2.csv.

Note the change in delimiter & quote character.

marks2.csv

Name|Average Of|Marks
Anita|^Accounting|Maths^|83.0
Amar|^Accounting|Maths^|95.0
Akash|^Physics|Chemistry|Biology^|92.0
Ira|^Physics|Chemistry|Biology^|99.0

Code

import csv
with open('marks2.csv', 
           newline='') as f:
    reader = csv.reader(f, 
                delimiter='|', 
                quotechar='^')
    for row in reader:
        print(row)

Output

['Name', 'Average Of', 'Marks']
['Anita', 'Accounting|Maths', '83.0']
['Amar', 'Accounting|Maths', '95.0']
['Akash', 'Physics|Chemistry|Biology', '92.0']
['Ira', 'Physics|Chemistry|Biology', '99.0']

Writing CSV File

csv.writer(csvfile, delimiter=',', quotechar='"') function returns a writer object which converts data in form of a list into delimited strings which is passed down to the file object for writing.

All non-string data in the list are automatically converted into string before it is written.

The methods writerow(row) or writerows(rows) can be used to write a row (list of strings) or list of rows to a CSV file.

Example #3

Write a program to create a CSV file containing subject-wise marks of students delimited by semi-colon (;).

Solution #1: Using writerow()

import csv

h = ["Name","Subject","Marks"]

marks = [["Anita","Maths",83.0],
       ["Amar","Maths",95.0],
       ["Akash","Science",92.0],
       ["Ira","Science",99.0]]

with open('marks.csv', 'w', 
           newline='') as f:
    writer = csv.writer(f, 
                 delimiter=';')

    # Writing header
    writer.writerow(h)

    #Writing Data
    for row in marks:
        writer.writerow(row)

Solution #2: Using writerows()

import csv

h = ["Name","Subject","Marks"]

marks = [["Anita","Maths",83.0],
       ["Amar","Maths",95.0],
       ["Akash","Science",92.0],
       ["Ira","Science",99.0]]

with open('marks.csv', 'w', 
          newline='') as f:
    writer = csv.writer(f, 
                 delimiter=';')

    # Writing header
    writer.writerow(h)

    #Writing Data
    writer.writerows(marks)

Output - marks.csv

Name;Subject;Marks
Anita;Maths;83.0
Amar;Maths;95.0
Akash;Science;92.0
Ira;Science;99.0

User Defined Functions, Modules & Packages

User Defined Functions

The built-in functions and modules of the Python Standard Library add tremendous value by performing generic operations and can be utilised by developers for any task.

But, at times a programmer needs to perform a set of operations for a specific task multiple times. In such cases instead of rewriting the statements again and again, the block of code can be wrapped into a function which can be called anytime in the scope of the program.

User-defined functions make the program more:

  • Organized, as a block of code is now replaced by a single function call which performs a specific task.
  • Manageable, due to reduction of code length.
  • Reusable, as the user defined function can be used anywhere in the current program or it can also be imported in another program.

Function Structure

Let us take a deep dive into a user defined function (provided below) and understand its various components:

def adder(f, s, t = None):
    """
    Returns the sum of f, s and t.
    If t is not provided, 
    return the sum of f and s. 
    """
    s = f + s
    if t:
        s += t
    return s

Function Header

def adder(f, s, t = None):

The function header begins with the keyword def.

The function name follows the def keyword. As it is an identifier, the same nomenclature is followed while naming it. adder is the name of the function in the above example.

The function name is followed by a pair of parenthesis ( ).

In case any parameters are required by the function, they are enclosed inside the parentheses. f, s, t = None are the three parameters of the function.

Finally, the function header ends with a colon.

Function Body

The body of the function consists of one or more Python statements which have the same amount of indentation (4 spaces) from the function header.

It is a good practice to include the documentation string at the beginning of the function body that briefly explains how it works. This docstring can either be a single-line or a multiline string literal. In the above example the docstring is:

    """
    Returns the sum of f, s and t.
    If t is not provided, 
    return the sum of f and s. 
    """

This docstring is followed by a series of statements which represent the set of instructions to be executed. The set of instructions in the above example are

    s = f + s
    if t:
        s += t

The code block finally ends with a return statement which returns one or more values.

    return s

In the above example the value of s is returned which is the sum.

A missing return statement or a return statement returning no value implies that the function returns None. These functions are known as void functions which display the result of statements via print() function.

Parameters and Arguments

def adder(f, s, t = None):
    """
    Returns the sum of f, s and t.
    If t is not provided, 
    return the sum of f and s. 
    """
    s = f + s
    if t:
        s += t
    return s

After defining the above function, let us now invoke or call the function:

fst = 20
snd = 10
trd = 10
sm1 = adder(fst, snd, trd)
sm2 = adder(fst, snd)

f, s and t are known as positional parameters as they have a defined position in the function definition.

Also there is a provision to assign a default value to a parameter using =.

In the above example t has a default value of None.

Arguments are the values passed to a function (or method) when it is called. In the above example fst, snd and trd are the arguments. Since t has a default value, the function can be invoked with or without the trd argument as shown for sm2.

Argument values are assigned to the corresponding function parameters that are available as local variables inside the function.

Thus, value of fst is assigned to f and snd is assigned to s. In case there is no third argument, t has the default value None.

The values of sm1 and sm2 after executing the script are:

>>> sm1
40
>>> sm2
30

Scope of Variables

In Python, every variable has a well defined scope, i.e., it is accessible by a part of the program and it cannot be accessed from outside its scope.

Based on their scope, there are two types of variables:

Local Variables

Local variables are defined inside a function or a code block and can only be accessed where they are defined.

They exist only during the execution of the function or the code block.

Code

def triple(a):
    result = 3*a
    # variable result 
    # is accessible locally
    print("local:", result)

# Outputs value of result
# inside the function 
triple(3)

# Throws an error as result is 
# not accessible outside the scope 
# of function triple()
print("outside:", result)

Output

local: 9
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
NameError: name 'result' is not defined

Global Variables

Variables defined outside any function or code block are known as global variables.

They are often used to specify mathematical constants, file path or other such values and can be accessed anywhere in the source code (by functions or code blocks).

Below example demonstrates how the global variable n can be accessed by all the functions.

Code

n = 10

def uno():
  print(n)

def tres():
  print(n*3)

uno()
tres()

Output

10
30

In case a variable is defined inside a function with the same name as that of a global variable, then the variable is considered as a local variable and all references made to the variable point to this local variable.

Code

n = 10

# local n inside the
# function
def uno():
  n = 5
  print(n)

# global n inside the
# function
def tres():
  print(n*3)

uno()
tres()

Output

5
30

Any changes made to a global variable inside a code block or a function can modify it for that session. This can have an impact on all the code blocks/functions that access and use it.

To modify the value of a global variable one can use the global keyword as shown in the example below.

Code

n = 10

# function modifies the 
# value of global n
def uno():
  global n
  n = 5
  print(n)

def tres():
  print(n*3)

uno()
tres()

Output

5
15

Passing Objects of Mutable Type to a Function

When mutable objects (list, dict) are provided as an argument to a function, any modification made to the corresponding parameters in the body of the function leads to the modification of the original object.

Hence, care should be taken while passing mutable objects.

Passing a List

Code

def repeat(l):
    for i in range(len(l)):
        l[i] = l[i]*2

l = [1, 2, 3]
print(l)
repeat(l)
# l is modified
print(l)

Output

[1, 2, 3]
[2, 4, 6]

Passing a Dictionary

Code

def repeat(d):
    for i in d.keys():
        d[i] = d[i]*2

d = {'a':1, 'b':2, 'c':3}
print(d)
repeat(d)
# d is modified
print(d)

Output

{'a': 1, 'b': 2, 'c': 3}
{'a': 2, 'b': 4, 'c': 6}

What is a Module? How to Create a Module?

Once a function is defined in the Python interpreter, it can be called any number of times. But, these function definitions are lost upon exiting the interpreter.

To solve this problem we can create a python script with the function definitions at the beginning of the file, followed by the rest of the code which includes statements invoking the defined functions.

But, this process is tedious and not manageable as what makes user-defined functions powerful is that the programmer can - Write once, and use many times.

Instead of repeating the function definition again and again for each new program, one can put all the function definitions in a file from which the required function can be imported and invoked either in script mode or interactive mode.

This file (.py extension) is known as a module and it is the most basic form of reusable code accessible by other programs.

Let us create a new file basics.py containing the following functions:

def adder(f, s, t = None):
    """
    Returns the sum of f, s and t.
    If t is not provided, 
    return the sum of f and s. 
    """
    s = f + s
    if t:
        s += t
    return s

def tripler(a):
    """
    Multiplies a by 3 and 
    returns it
    """
    result = 3*a
    return result

After saving the basics.py file, reopen IDLE and create a new file test.py in the same directory as basics.py.

The name of the file is the module name which is also available as the value of the global variable __name__ in the module.

Import the functions of the basics module in test.py by executing the following statement.

import basics

The above import statement loads all the functions available in the basics module. To access any function in the module, simply type the module name followed by a period (.), followed by the function name.

Code

import basics
sa = basics.adder(20, 10, 10)
st = basics.tripler(20)
print(sa)
print(st)

Output

40
60

The as keyword can also be used to create an alias which makes it easier and more manageable to use in the program.

Code

import basics as ba
sa = ba.adder(20, 10, 10)
st = ba.tripler(20)
print(sa)
print(st)

Output

40
60

Instead of loading all the functions in a module, the from statement can be used to access only specified functions.

Code

from basics import adder
sa = adder(20, 10, 10)
print(sa)

Output

40

To import all functions and global variables in the module the * wildcard character can be used.

Code

from basics import *
sa = adder(20, 10, 10)
st = tripler(20)

Output

40
60

The above method of using * to import the contents of a module is not recommended as it can clutter the namespace and cause issues if there are conflicts between the identifiers defined by the programmer and those defined in the module/package.

Executable Scripts / Modules

Apart from containing definitions, a module can also contain block of code which is executed whenever the stand-alone script is run in script mode. The block has to be enclosed in an if statement as shown below:

if __name__ == '__main__':
    ...code to be executed...

Using the above pattern, a file can be imported or executed directly.

Let us undertake an example module (save it as multi.py) which multiplies two numbers:

def multiply(a, b):
    return a * b

f = int(input("Enter a: "))
s = int(input("Enter b: "))
print(multiply(f, s))

Now when we try to load all functions from the module it automatically executes the input assignment statements and prints the output.

>>> from test import *
Enter a: 4
Enter b: 5
20
>>> 

Let us modify the code:

def multiply(a, b):
    return a * b

if __name__ == '__main__':
    f = int(input("Enter a: "))
    s = int(input("Enter b: "))
    print(multiply(f, s))

Now, the block will execute only if the script is executed directly and not when the file is imported as a module.

>>> from test import *
>>> multiply(4, 5)
20

What is a Package? Introduction to PyPi. How to Create a Python Package?

A collection of modules which can work together to provide a common functionality is known as a package.

These modules are present in a folder along with the __init__.py file which tells Python that this folder is a package.

A package can also contain subfolders (sub-packages), each containing their respective __init__.py files.

Let us take the example of a package called restaurant which consists of various modules to perform activities such as order booking, reservation, staff attendance, etc.

Here is a possible structure for the package:

restaurant/
    __init__.py
    orders.py
    reservation.py
    employee.py
    inventory.py

A package is simply the directory containing sub-packages and modules, but when this package or a collection of packages are made available for others to use (eg. via PyPI) it is known as a library.

For example, restaurant can be called a library if it provides reusable codes to manage a restaurant and is built using multiple packages which handle the various aspects of a restaurant like human resource management, inventory management, order fulfillment and billing, etc.

One should note that the above definition is not strict and often the terms package and library are used interchangeably.

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