Difference between revisions of "Multi-Paradigm Programming and Scripting"

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Revision as of 21:54, 4 November 2019


Why Multi-Paradigm Programming and Scripting?
  • Universal programming constructs (invariant of language), their functions, uses and how different paradigms/languages employ them.
  • Improved background for choosing appropriate languages:



Content of this course
Programming Constructs:
  • The compilation process
  • Data types (strongly-typed, weakly-typed)
  • Pointers
  • Variables and Invariants
  • Conditionals (Selection)
  • Sequence
  • Repetition
  • Routines
  • Concurrency
 Programming Paradigms & Languages:
  • Abstraction (machine to very-high-level)
  • Mark-up
  • Imperative & Declarative
  • Procedural
  • Parallel & Concurrent
  • Functional
  • Event-Driven
  • Multi-Paradigm Languages
  • Interpreted Languages
  • Comparison of all to Object Oriented Paradigm
 Scripting:
  • Interpreters and system commands
  • Shell Scripting (Linux/UNIX)
  • PowerShell Scripting (Windows)
  • System Programming & Scripting
 Applications of Shell Scripting:
  • Job Control
  • Glue Code / Wrappers
  • Automating Tasks
  • Data Processing / Transformation
  • System uses
  • I/O tasks and functions



Some important programming concepts


High level - Low Level Programming


Compilation vs Interpretation

https://medium.com/@DHGorman/a-crash-course-in-interpreted-vs-compiled-languages-5531978930b6

https://guide.freecodecamp.org/computer-science/compiled-versus-interpreted-languages/


Speaking simplistically, compiled languages are those which are written in one language and, before being run, translated or "compiled" into another language, called the target language (typically in machine language that the processor can execute). Once the translation is complete, the executable code is either run or set aside to run later. Some common compiled languages include C, C++, Delphi and Rust.

The compiler translates the high-level source program into an equivalent target program (typically in machine language).


The alternative to using a compiler (for a compiled language) is using an interpreter (for interpreted languages). Interpreted languages are "interpreted" live in their original source code, although in reality they are merely compiled at runtime. What this allows for is a lot more flexibility, especially when it comes to a program adaptively modifying its structure. This flexibility does have a cost; interpreted languages are considered significantly slower.

Interpreters will run through a program line by line and execute each command.



Advantages and Disadvantages

Compiled Languages:

  • Advantages:
  • Programs compiled into native code at compile time usually tend to be faster than those translated at run time, due to the overhead of the translation process.
  • Disadvantages:
  • Additional time needed to complete the entire compilation step before testing, and Platform dependence of the generated binary code.


Interpreted Languages:

  • Advantages:
  • Greater flexibility
  • Better diagnostics (error messages)
  • An Interpreted language gives implementations some additional flexibility over compiled implementations. Because interpreters execute the source program code themselves, the code itself is platform independent (Java's byte code, for example). Other features include dynamic typing, and smaller executable program size.
  • Disadvantages:
  • The most notable disadvantage is typical execution speed compared to compiled languages.
Interpreted languages were once known to be significantly slower than compiled languages. But, with the development of just-in-time compilation, that gap is shrinking.



Phases of Compilation

Phases of compilation.png


  • Scanning:
  • Parsing:
  • Semantic analysis:
  • Intermediate form :
  • Optimization:
  • Code generation phase :



Procedural - Functional and Object-Oriented Programming

https://medium.com/@sho.miyata.1/the-object-oriented-programming-vs-functional-programming-debate-in-a-beginner-friendly-nutshell-24fb6f8625cc


Can we do Object-Oriented Programming with ANSI-C? Yes! this book explains how to do it: https://www.cs.rit.edu/~ats/books/ooc.pdf


https://www.codecademy.com/articles/cpp-object-oriented-programming

https://owlcation.com/stem/Use-Of-Object-Oriented-Programming

https://searchapparchitecture.techtarget.com/definition/object-oriented-programming-OOP

https://www.geeksforgeeks.org/object-oriented-programming-oops-concept-in-java/

http://ee402.eeng.dcu.ie/introduction/chapter-1---introduction-to-object-oriented-programming


Object-oriented programming (OOP) is a programming language paradigm structured around objects (which consists of both data and behaviors[Functions-Methods]). This is in contrast to conventional Functional programming paradigm that is structured based on actions (logic) and only loosely connects data and behaviors.


A traditional functional/procedural(*) program is structured based on actions (logic). In general, a functional program take an input data, process it and produces a result. In other words, the data, stored in variables, is passed to defined functions which perform some action and modify it or create new data. The program is centralized around the actions (logic):

  • Take input data
  • Process the data
  • Produces a result


The object-oriented paradigm allows us to structure the program as a collection of objects that consist of both data and behaviors[Functions-Methods]. So, in object-oriented programming, data and functions are tied together in an entity called object. We can said that one of the main aim of OOP is to bind together the data and the functions that operate on them so that no other part of the code can access this data except that function. These data in OOPs are known as properties and functions used to modify properties are called methods.


The object-oriented programming approach encourages:

  • Modularisation: where the application can be decomposed into modules.
  • Software re-use: where an application can be composed from existing and new modules.


Major benefits of using OOPs:

  • Encapsulation : Objects created in OOPs are able to hide certain parts of code from programmer. This prevents unintentional modification in the code which may cause unwanted outcomes.
  • Code Reuse : Objects created in OOPs can easily be reused in other programs.
  • Software Maintenance : Code written in OOPs is easy to debug and maintain.
  • Design Benefits : OOPs needs extensive design planning which certainly provide design benefits over traditional style.


For simple programming tasks, use of procedural programming style is well suited but as the program becomes complex and software architecture becomes large, object oriented programming is suitable to create modular designs and patterns. This makes it particularly useful when you create larger programs.


There are four major benefits to object-oriented programming:

  • Encapsulation: in OOP, you bundle code into a single unit where you can determine the scope of each piece of data.
  • Abstraction: by using classes, you are able to generalize your object types, simplifying your program.
  • Inheritance: because a class can inherit attributes and behaviors from another class, you are able to reuse more code.
  • Polymorphism: one class can be used to create many objects, all from the same flexible piece of code.



Languages evaluation criteria

https://www.cs.scranton.edu/~mccloske/courses/cmps344/sebesta_chap1.html


Readability Writability Reliability Cost Other criteria

This refers to the ease with which programs (in the language under consideration) can be understood. This is especially important for software maintenance.

  • Simplicity:
  • Orthogonality:
  • Data Types:
  • Syntax Design:

This is a measure of how easily a language can be used to develop programs for a chosen problem domain.

  • Simplicity and Orthogonality:
  • Support for Abstraction:
  • Expressivity:

This is the property of performing to specifications under all conditions.

  • Type Checking:
  • Aliasing:

The following contribute to the cost of using a particular language:

  • Training programmers: cost is a function of simplicity of language
  • Writing and maintaining programs: cost is a function of readability and writability.
  • Compiling programs: for very large systems, this can take a significant amount of time.
  • Executing programs: Having to do type checking and/or index-boundary checking at run-time is expensive. There is a tradeoff between this item and the previous one (compilation cost), because optimizing compilers take more time to work but yield programs that run more quickly.
  • Language Implementation System: e.g., Java is free, Ada not
  • Lack of reliability: software failure could be expensive (e.g., loss of business, liability issues)
  • Portability: the ease with which programs that work on one platform can be modified to work on another. This is strongly influenced by to what degree a language is standardized.
  • Generality: Applicability to a wide range of applications.
  • Well-definedness: Completeness and precision of the language's official definition.



Imperative versus declarative code

https://medium.com/front-end-weekly/imperative-versus-declarative-code-whats-the-difference-adc7dd6c8380



Imperative paradigm

Procedural and object-oriented programming belong under imperative paradigm that you know from languages like C, C++, C#, PHP, Java and of course Assembly.

Your code focuses on creating statements that change program states by creating algorithms that tell the computer how to do things. It closely relates to how hardware works. Typically your code will make use of conditinal statements, loops and class inheritence.

Example of imperative code in JavaScript is: 

class Number {

    constructor (number = 0) {
        this.number = number;
    }
  
    add (x) {
        this.number = this.number + x;
    }
    
}

const myNumber = new Number (5);
myNumber.add (3);
console.log (myNumber.number); // 8



Declarative paradigm

Logic, functional and domain-specific languages belong under declarative paradigms and they are not always Turing-complete (they are not always universal programming languages). Examples would be HTML, XML, CSS, SQL, Prolog, Haskell, F# and Lisp.

Declarative code focuses on building logic of software without actually describing its flow. You are saying what without adding how. For example with HTML you use to tell browser to display an image and you don’t care how it does that.


Example of declarative code in JavaScript is: 

const sum = a => b => a + b;
console.log (sum (5) (3)); // 8



Names - Variables

A name is a string of characters used to identify some entity in a program. Variable names are the most common names in the programs.

  • Are names case sensitive?
  • Length?
  • etc...


Names with special characters:

  • PHP: All variable names must begin with dollar signs
  • Perl: All variable names begin with special characters, which specify the variable's type
  • Ruby: Variable names that begin with @ are instance variables; those that begin with @@ are class variables


Case sensitivity names:

  • Names in the C-based languages are case sensitive. Not in others languages.



Variables

A variable is an abstraction of a memory cell.

Variables can be characterized as a sextuplet (six parts) of attributes:

  • Name
  • Address
  • Value
  • Type
  • Lifetime
  • Scope


Address: The memory address with which it is associated.

  • A variable may have different addresses at different times during execution.
  • A variable may have different addresses at different places in a program.
  • If two variable names can be used to access the same memory location, they are called aliases.
  • Aliases are created via pointers, reference variables, C and C++ unions
  • Two pointer variables are aliases when they point to the same memory location. The same is true for reference variables.
  • Aliases are harmful to readability (program readers must remember all of them).


Type: Determines the range of values of variables and the set of operations that are defined for values of that type; in the case of floating point, type also determines the precision

For example, the int type in Java specifies a value range of -2147483648 to 2147483647


Value: The value of a variable is the contents of the memory cell or cells associated with the variable:

  • The l-value of a variable is its address
  • The r-value of a variable is its value



Binding

A binding is an association between an entity and an attribute, such as between a variable and its type or value, or between an operation and a symbol.


Binding time is the time at which a binding takes place. Bindings can take place at:

  • Language design time
  • Language implementation time
  • Compile time
  • Load time
  • Link time
  • Run time


For example:

  • The asterisk symbol (*) is usually bound to the multiplication operation at language design time. At compile time, a variable in a Java program is bound to a particular data type.
  • Language design time: Bind operator symbols to operations
  • Language implementation time: Bind floating point type to a representation
  • Compile time: Bind a variable to a type in C or Java
  • Load time: Bind a C or C++ static variable to a memory cell
  • Runtime: Bind a nonstatic local variable to a memory cell



Static vs Dynamic Binding

https://techdifferences.com/difference-between-static-and-dynamic-binding.html


A binding is static if it first occurs before run time and remains unchanged throughout program execution.


A binding is dynamic if it first occurs during execution or can change during execution of the program.



Static vs Dynamic Binding in Java

https://www.geeksforgeeks.org/static-vs-dynamic-binding-in-java/



Static Binding:

The binding which can be resolved at compile time by compiler is known as static or early binding. Binding of all the static, private and final methods is done at compile-time .


Why binding of static, final and private methods is always a static binding?

Static binding is better performance wise (no extra overhead is required). Compiler knows that all such methods cannot be overridden and will always be accessed by object of local class. Hence compiler doesn’t have any difficulty to determine object of class (local class for sure). That’s the reason binding for such methods is static. Let’s see by an example: 

public class NewClass 
{ 
    public static class superclass 
    { 
        static void print() 
        { 
            System.out.println("print in superclass."); 
        } 
    } 
    public static class subclass extends superclass 
    { 
        static void print() 
        { 
            System.out.println("print in subclass."); 
        } 
    } 
  
    public static void main(String[] args) 
    { 
        superclass A = new superclass(); 
        superclass B = new subclass(); 
        A.print(); 
        B.print(); 
    } 
}

Output: 

print in superclass.
print in superclass.

As you can see, in both cases print method of superclass is called. Lets see how this happens:

  • We have created one object of subclass and one object of superclass with the reference of the superclass.
  • Since the print method of superclass is static, compiler knows that it will not be overridden in subclasses and hence compiler knows during compile time which print method to call and hence no ambiguity.

As an exercise, reader can change the reference of object B to subclass and then check the output.



Dynamic Binding:

In Dynamic binding compiler doesn’t decide the method to be called. Overriding is a perfect example of dynamic binding. In overriding both parent and child classes have same method . Let’s see by an example: 

public class NewClass 
{ 
    public static class superclass 
    { 
        void print() 
        { 
            System.out.println("print in superclass."); 
        } 
    } 
  
    public static class subclass extends superclass 
    { 
        @Override
        void print() 
        { 
            System.out.println("print in subclass."); 
        } 
    } 
  
    public static void main(String[] args) 
    { 
        superclass A = new superclass(); 
        superclass B = new subclass(); 
        A.print(); 
        B.print(); 
    } 
}

Output: 

print in superclass.
print in subclass.


Here the output differs. But why? Let’s break down the code and understand it thoroughly:

  • Methods are not static in this code.
  • During compilation, the compiler has no idea as to which print has to be called since compiler goes only by referencing variable not by type of object and therefore the binding would be delayed to runtime and therefore the corresponding version of print will be called based on type on object.



Important points

  • Private, final and static members (methods and variables) use static binding while for virtual methods (In Java methods are virtual by default) binding is done during run time based upon run time object.
  • Static binding uses Type information for binding while Dynamic binding uses Objects to resolve binding.
  • Overloaded methods are resolved (deciding which method to be called when there are multiple methods with same name) using static binding while overridden methods using dynamic binding, i.e, at run time.



Statically and Dynamically typed languages


Statically typed languages:

A language is statically typed if the type of a variable is known at compile time. For some languages this means that you as the programmer must specify what type each variable is (e.g.: Java, C, C++); other languages offer some form of type inference, the capability of the type system to deduce the type of a variable (e.g.: OCaml, Haskell, Scala, Kotlin)

The main advantage here is that all kinds of checking can be done by the compiler, and therefore a lot of trivial bugs are caught at a very early stage.

Examples: C, C++, Java, Rust, Go, Scala



Dynamically typed languages:

A language is dynamically typed if the type is associated with run-time values, and not named variables/fields/etc. This means that you as a programmer can write a little quicker because you do not have to specify types every time (unless using a statically-typed language with type inference).

Examples: Perl, Ruby, Python, PHP, JavaScript

Most scripting languages have this feature as there is no compiler to do static type-checking anyway, but you may find yourself searching for a bug that is due to the interpreter misinterpreting the type of a variable. Luckily, scripts tend to be small so bugs have not so many places to hide.

Most dynamically typed languages do allow you to provide type information, but do not require it. One language that is currently being developed, Rascal, takes a hybrid approach allowing dynamic typing within functions but enforcing static typing for the function signature.



Data type

A data type, in programming, is a classification that specifies which type of value a variable has and what type of mathematical, relational or logical operations can be applied to it without causing an error. A string, for example, is a data type that is used to classify text and an integer is a data type used to classify whole numbers.



Descriptor: It's the collection of the attributes of a variable.

Ex.:

Compile-time descriptor for a single-dimensional array
Compile-time descriptor for a multidimensional array


Example
Primitive Data Types
  • Primitive data types are those not defined in terms of other data types.
  • Almost all programming languages provide a set of primitive data types
 Integer byte
short
int
long
Floating Point float
double
Complex Each value consists of two floats, the real part and the imaginary part
Boolean
Character
  • Stored as numeric codings
  • Most commonly used coding: ASCII


Character Strings

Design issues
  • Values are sequences of characters
  • Is it a primitive type or just a special kind of array?
  • Should the length of strings be static or dynamic?
Arrays An array is a homogeneous aggregate of data elements in which an individual element is identified by its position in the aggregate, relative to the first element.


Index Syntax

  • Fortran and Ada use parentheses. Most other languages use brackets.


Rectangular and Jagged Arrays:

  • A rectangular array is a multi-dimensional array in which all of the rows have the same number of elements and all columns have the same number of elements
  • A jagged matrix has rows with varying number of elements

Possible when multi-dimensional arrays actually appear as arrays of arrays

  • C, C++, and Java support jagged arrays
  • F# and C# support rectangular arrays and jagged arrays


Slices:

  • A slice is some substructure of an array; nothing more than a referencing mechanis
  • Slices are only useful in languages that have array operations. Ex. Python, Ruby
Slicing in Python:
Python
vector = [2, 4, 6, 8, 10, 12, 14, 16]
mat = [[1, 2, 3], [4, 5, 6], [7, 8, 9]]

vector (3:6) is a three-element array
mat[0][0:2] is the first and second element of the first row of mat


Ruby supports slices with the slice method: list.slice(2, 2)

Associative Arrays An associative array is an unordered collection of data elements that are indexed by an equal number of values called keys:

Ex:

Python: Dictionary

C++: Associative arrays

Perl: Associative Arrays

Associative Arrays in Perl
# Names begin with %; literals are delimited by parentheses
%hi_temps = ("Mon" => 77, "Tue" => 79, "Wed" => 65, ...);

# Subscripting is done using braces and keys
$hi_temps{"Wed"} = 83;

# Elements can be removed with delete
delete $hi_temps{"Tue"};
Record A record is a possibly heterogeneous aggregate of data elements in which the individual elements are identified by names
Enumeration All possible values, which are named constants, are provided in the definition.

No enumeration variable can be assigned a value outside its defined range

C# example:
enum days {mon, tue, wed, thu, fri, sat, sun};

Pointer A pointer type variable has a range of values that consists of memory addresses and a special value, nil.
  • Provide the power of indirect addressing
  • Provide a way to manage dynamic memory
  • A pointer can be used to access a location in the area where storage is dynamically created (usually called a heap)

Pointer

Pointers store address of variables or a memory location.

A pointer is a variable that stores the address of another variable. Unlike other variables that hold values of a certain type, pointer holds the address of a variable. For example, an integer variable holds (or you can say stores) an integer value, however an integer pointer holds the address of a integer variable. https://beginnersbook.com/2014/01/c-pointers/

C Pointers.jpg



Pointers in C and CPP

Pointer memory representation.png
How-pointer-works-in-C.png


To use pointers in C, we must understand below two operators: % and *

Ampersand (&):

It is used to access the address of a variable to a pointer. The unary operator & (ampersand) returns the address of that variable.

For example &x gives us the address of the variable. 

// The output of this program can be different in different runs.
// Note that The program prints address of a variable and a variable
// can be assigned different address in different runs. 
#include <stdio.h> 

int main() 
{ 
    int x; 
 
    // Prints address of x 
    printf("%p", &x); 
  
    return 0; 
}

Unary (Asterisk) (*) : It is used for two things:

To declare a pointer variable:

  • When a pointer variable is declared in C/C++, there must have a * before its name.
 
// C program to demonstrate declaration of 
// pointer variables. 
#include <stdio.h> 
int main() 
{ 
    int x = 10; 
  
    // 1) Since there is * in declaration, ptr becomes a pointer
    // varaible (a variable that stores address of another variable)
    // 2) Since there is int before *, ptr is pointer to an integer 
    // type variable 
    int *ptr; 
  
    // & operator before x is used to get address of x.
    // The address of x is assigned to ptr. 
    ptr = &x; 
  
    return 0; 
}

To access the value stored in the address.

  • The unary operator (*) returns the value of the variable located at the address specified by its operand.


 
// C program to demonstrate use of * for pointers in C 
#include <stdio.h> 
  
int main() 
{ 
    // A normal integer variable 
    int Var = 10; 
  
    // A pointer variable that holds address of var. 
    int *ptr = &Var; 
  
    // This line prints value at address stored in ptr. 
    // Value stored is value of variable "var" 
    printf("Value of Var = %d\n", *ptr); 
  
    // The output of this line may be different in different 
    // runs even on same machine. 
    printf("Address of Var = %p\n", ptr); 
  
    // We can also use ptr as lvalue (Left hand 
    // side of assignment) 
    *ptr = 20; // Value at address is now 20 
  
    // This prints 20 
    printf("After doing *ptr = 20, *ptr is %d\n", *ptr); 
  
    return 0; 
}



Object-Oriented Paradigm


Overriding

https://www.techopedia.com/definition/24010/overriding

Overriding is an object-oriented programming feature that enables a child class to provide different implementation for a method that is already defined and/or implemented in its parent class or one of its parent classes. The overriden method in the child class should have the same name, signature, and parameters as the one in its parent class.

Overriding enables handling different data types through a uniform interface. Hence, a generic method could be defined in the parent class, while each child class provides its specific implementation for this method.



C++ Inheritance

https://www.w3schools.com/cpp/cpp_inheritance.asp

https://www.tutorialspoint.com/cplusplus/cpp_interfaces.htm



Reflection

A programming language that supports reflection allows its programs to have runtime access to their types and structure and to be able to dynamically modify their behavior

  • The types and structure of a program are called metadata
  • The process of a program examining its metadata is called introspection
  • Interceding in the execution of a program is called intercession


Uses of reflection for software tools:

  • Class browsers need to enumerate the classes of a program
  • Visual IDEs use type information to assist the developer in building type correct code
  • Debuggers need to examine private fields and methods of classes
  • Test systems need to know all of the methods of a class


Downsides of Reflection:

  • Performance costs
  • Exposes private fields and methods
  • Voids the advantages of early type checking
  • Some reflection code may not run under a security manager, making code nonportable



Reflection in Java

  • Limited support from java.lang.Class
  • Java runtime instantiates an instance of Class for each object in the program
  • The getClass method of Class returns the Class object of an object
float[] totals = new float[100];
Class fltlist = totals.getClass();
Class stg = "hello".getClass();
  • If there is no object, use class field:
Class stg = String.class;
  • Class has four useful methods:
getMethod searches for a specific public method of a class
getMethods returns an array of all public methods of a class
getDeclaredMethod searches for a specific method of a class
getDeclaredMethods returns an array of all methods of a class
The Method class defines the invoke method, which is used to execute the method found by getMethod



Some tutorials


Examples from Introduction to Programming Using Python 3

http://www.cs.armstrong.edu/liang/py/ExampleByChapters.html



C++ tutorial

http://www.cplusplus.com/doc/tutorial/program_structure/



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