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Python is an interpreted, high-level and general-purpose, dynamically typed programming language
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It is also Object oriented, modular oriented and a scripting language.
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In Python, everything is considered as an Object.
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A python file has an extension of .py
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Python follows Indentation to separate code blocks instead of flower brackets({}).
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We can run a python file by the following command in cmd(Windows) or shell(mac/linux).
$ python <filename.py>
or$ python3 <filename.py>
- Open up a terminal/cmd
- Create the program: nano/cat > nameProgram.py
- Write the program and save it
- python nameProgram.py
Data Type | Description |
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int | Integer values [0, 1, -2, 3] |
float | Floating point values [0.1, 4.532, -5.092] |
char | Characters [a, b, @, !, `] |
str | Strings [abc, AbC, A@B, sd!, `asa] |
bool | Boolean Values [True, False] |
complex | Complex numbers [2+3j, 4-1j] |
- As of python3.8 there are 35 keywords
Keyword | Description | Category |
---|---|---|
True | Boolean value for not False or 1 | Value Keyword |
False | Boolean Value for not True or 0 | Value Keyword |
None | No Value | Value keyword |
and | returns true if both (oprand) are true (other language && ) | Operator keyword |
or | returns true of either operands is true (other language | |
in | returns true if word is in iterator | Operator keyword |
is | returns true if id of variables are same | Operator keyword |
not | returns opposite Boolean value | Operator Keyword |
if | get into block if expression is true | conditional |
elif | for more than 1 if checks | conditional |
else | this block will be executed if condition is false | conditional |
for | used for looping | iteration |
while | used for looping | iteration |
break | get out of loop | iteration |
continue | skip for specific condition | iteration |
def | make user defined function | structure |
class | make user defined classes | structure |
lambda | make anonymous function | structure |
with | execute code within context manager's scope | structure |
as | alias for something | structure |
pass | used for making empty structures(declaration) | structure |
return | get value(s) from function, get out of function | returning keyword |
yield | yields values instead of returning (are called generators) | returning keyword |
import | import libraries/modules/packages | import |
from | import specific function/classes from modules/packages | import |
try | this block will be tried to get executed | exception handling |
except | is any exception/error has occured it'll be executed | exception handling |
finally | It'll be executed no matter exception occurs or not | exception handling |
raise | throws any specific error/exception | exception handling |
assert | throws an AssertionError if condition is false | exception handling |
async | used to define asynchronous functions/co-routines | asynchronous programming |
await | used to specify a point when control is taken back | asynchronous programming |
del | deletes/unsets any user defined data | variable handling |
global | used to access variables defined outside of function | variable handling |
nonlocal | modify variables from different scopes | variable handling |
Operator | Description |
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( ) | grouping parenthesis, function call, tuple declaration |
[ ] | array indexing, also declaring lists etc. |
! | relational not, complement, ! a yields true or false |
~ | bitwise not, ones complement, ~a |
- | unary minus, - a |
+ | unary plus, + a |
* | multiply, a * b |
/ | divide, a / b |
% | modulo, a % b |
+ | add, a + b |
- | subtract, a - b |
<< | shift left, left operand is shifted left by right operand bits (multiply by 2) |
>> | shift right, left operand is shifted right by right operand bits (divide by 2) |
< | less than, result is true or false, a %lt; b |
<= | less than or equal, result is true or false, a <= b |
> | greater than, result is true or false, a > b |
>= | greater than or equal, result is true or false, a >= b |
== | equal, result is true or false, a == b |
!= | not equal, result is true or false, a != b |
& | bitwise and, a & b |
^ | bitwise exclusive or XOR, a ^ b |
| | bitwise or, a |
&&, and | relational and, result is true or false, a < b && c >= d |
||, or | relational or, result is true or false, a < b || c >= d |
= | store or assignment |
+= | add and store |
-= | subtract and store |
*= | multiply and store |
/= | divide and store |
%= | modulo and store |
<<= | shift left and store |
>>= | shift right and store |
&= | bitwise and and store |
^= | bitwise exclusive or and store |
|= | bitwise or and store |
, | separator as in ( y=x,z=++x ) |
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List is a collection which is ordered and changeable. Allows duplicate members.
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Lists are created using square brackets:
thislist = ["apple", "banana", "cherry"]
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List items are ordered, changeable, and allow duplicate values.
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List items are indexed, the first item has index
[0]
, the second item has index[1]
etc. -
The list is changeable, meaning that we can change, add, and remove items in a list after it has been created.
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To determine how many items a list has, use the
len()
function. -
A list can contain different data types:
list1 = ["abc", 34, True, 40, "male"]
- It is also possible to use the list() constructor when creating a new list
thislist = list(("apple", "banana", "cherry")) # note the double round-brackets
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pop() function removes the last value in the given list by default.
thislist = ["apple", "banana", "cherry"] print(thislist.pop()) # cherry print(thislist.pop(0)) #apple
- Tuple is a collection which is ordered and unchangeable. Allows duplicate members.
- A tuple is a collection which is ordered and unchangeable.
- Tuples are written with round brackets.
thistuple = ("apple", "banana", "cherry")
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Tuple items are ordered, unchangeable, and allow duplicate values.
-
Tuple items are indexed, the first item has index
[0]
, the second item has index[1]
etc. -
When we say that tuples are ordered, it means that the items have a defined order, and that order will not change.
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Tuples are unchangeable, meaning that we cannot change, add or remove items after the tuple has been created.
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Since tuple are indexed, tuples can have items with the same value:
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Tuples allow duplicate values:
thistuple = ("apple", "banana", "cherry", "apple", "cherry")
- To determine how many items a tuple has, use the
len()
function:
thistuple = ("apple", "banana", "cherry")
print(len(thistuple))
- To create a tuple with only one item, you have to add a comma after the item, otherwise Python will not recognize it as a tuple.
thistuple = ("apple",)
print(type(thistuple))
# NOT a tuple
thistuple = ("apple")
print(type(thistuple))
- It is also possible to use the tuple() constructor to make a tuple.
thistuple = tuple(("apple", "banana", "cherry")) # note the double round-brackets
print(thistuple)
- Set is a collection which is unordered and unindexed. No duplicate members.
- A set is a collection which is both unordered and unindexed.
thisset = {"apple", "banana", "cherry"}
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Set items are unordered, unchangeable, and do not allow duplicate values.
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Unordered means that the items in a set do not have a defined order.
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Set items can appear in a different order every time you use them, and cannot be referred to by index or key.
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Sets are unchangeable, meaning that we cannot change the items after the set has been created.
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Duplicate values will be ignored.
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To determine how many items a set has, use the
len()
method.
thisset = {"apple", "banana", "cherry"}
print(len(thisset))
- Set items can be of any data type:
set1 = {"apple", "banana", "cherry"}
set2 = {1, 5, 7, 9, 3}
set3 = {True, False, False}
set4 = {"abc", 34, True, 40, "male"}
- It is also possible to use the
set()
constructor to make a set.
thisset = set(("apple", "banana", "cherry")) # note the double round-brackets
- frozenset() is just an immutable version of Set. While elements of a set can be modified at any time, elements of the frozen set remain the same after creation.
set1 = {"apple", "banana", "cherry"}
frzset=frozenset(set1)
print(frzset)
- Dictionary is a collection which is unordered and changeable. No duplicate members.
- Dictionaries are used to store data values in key:value pairs.
- Dictionaries are written with curly brackets, and have keys and values:
thisdict = {
"brand": "Ford",
"model": "Mustang",
"year": 1964
}
- Dictionary items are presented in key:value pairs, and can be referred to by using the key name.
thisdict = {
"brand": "Ford",
"model": "Mustang",
"year": 1964
}
print(thisdict["brand"])
- Dictionaries are changeable, meaning that we can change, add or remove items after the dictionary has been created.
- Dictionaries cannot have two items with the same key.
- Duplicate values will overwrite existing values.
- To determine how many items a dictionary has, use the
len()
function.
print(len(thisdict))
- The values in dictionary items can be of any data type
thisdict = {
"brand": "Ford",
"electric": False,
"year": 1964,
"colors": ["red", "white", "blue"]
}
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pop() Function is used to remove a specific value from a dictionary. You can only use key bot the value. Unlike Lists you have to give a value to this function
car = { "brand": "Ford", "model": "Mustang", "year": 1964 } x = car.pop("model") print(x)# Mustang print(car)#{'brand': 'Ford', 'year': 1964}
if condition:
pass
elif condition2:
pass
else:
pass
Python has two primitive loop commands:
- while loops
- for loops
- With the
while
loop we can execute a set of statements as long as a condition is true. - Example: Print i as long as i is less than 6
i = 1
while i < 6:
print(i)
i += 1
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The while loop requires relevant variables to be ready, in this example we need to define an indexing variable, i, which we set to 1.
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With the
break
statement we can stop the loop even if the while condition is true -
With the continue statement we can stop the current iteration, and continue with the next.
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With the else statement we can run a block of code once when the condition no longer is true.
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A for loop is used for iterating over a sequence (that is either a list, a tuple, a dictionary, a set, or a string).
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This is less like the for keyword in other programming languages, and works more like an iterator method as found in other object-orientated programming languages.
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With the for loop we can execute a set of statements, once for each item in a list, tuple, set etc.
fruits = ["apple", "banana", "cherry"]
for x in fruits:
print(x)
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The for loop does not require an indexing variable to set beforehand.
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To loop through a set of code a specified number of times, we can use the range() function.
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The range() function returns a sequence of numbers, starting from 0 by default, and increments by 1 (by default), and ends at a specified number.
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The range() function defaults to increment the sequence by 1, however it is possible to specify the increment value by adding a third parameter: range(2, 30, 3).
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The else keyword in a for loop specifies a block of code to be executed when the loop is finished. A nested loop is a loop inside a loop.
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The "inner loop" will be executed one time for each iteration of the "outer loop":
adj = ["red", "big", "tasty"]
fruits = ["apple", "banana", "cherry"]
for x in adj:
for y in fruits:
print(x, y)
- for loops cannot be empty, but if you for some reason have a for loop with no content, put in the pass statement to avoid getting an error.
for x in [0, 1, 2]:
pass
def function_name():
return
function_name()
- We need not to specify the return type of the function.
- Functions by default return
None
- We can return any datatype.