How to choose a partition key in Azure Cosmos DB
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23 October 2023
19 October 2023
Can multiple datatype support in array and List in c#
Can multiple datatype support in array and List in c#
In C#, arrays are collections of elements that must all have the same data type. This means that all elements in a C# array must be of a uniform data type. For example, if you create an array of integers, you cannot store other data types such as strings or floats in the same array.
Here's an example of creating an array of integers in C#:
```csharp
int[] numbers = new int[] { 1, 2, 3, 4, 5 };
In this example, `numbers` is an array of integers, and you can only store integer values in it. Attempting to store a different data type in this array would result in a compilation error.
If you need to store multiple data types in a collection, you can use other data structures in C# such as `List<T>` from the `System.Collections.Generic` namespace. `List<T>` allows you to store elements of different data types because it is a generic collection that can be parameterized with any data type.
Here's an example of using `List<T>` to store elements of different data types:
```csharp
using System;
using System.Collections.Generic;
class Program
{
static void Main()
{
List<object> mixedList = new List<object>();
mixedList.Add(1); // integer
mixedList.Add("hello"); // string
mixedList.Add(3.14); // double
foreach (var item in mixedList)
{
Console.WriteLine(item);
}
}
}
In this example, `mixedList` is a `List<object>` that can store elements of different data types by treating them as `object`. However, it's important to note that using `List<object>` can lead to loss of type safety and may require explicit casting when retrieving elements from the list.
18 October 2023
Dependency Inversion Principle (DIP)
Dependency Inversion Principle (DIP)
The Dependency Inversion Principle (DIP) is one of the SOLID principles of object-oriented design. It suggests that high-level modules (e.g., business logic) should not depend on low-level modules (e.g., database access, external services). Instead, both high-level and low-level modules should depend on abstractions (interfaces or abstract classes).
In simpler terms, the Dependency Inversion Principle advocates that the direction of dependency should be toward abstractions, not concretions. This allows for decoupling between components, making the system more flexible, maintainable, and easier to extend.
Let's explore the Dependency Inversion Principle with an example in C#. Consider a scenario where you have a high-level module representing a class `BusinessLogic` that needs to save data to a database. Following DIP, you would define an interface representing the database operations:
```csharp
// Database interface representing the operations needed by BusinessLogic
public interface IDatabase
{
void SaveData(string data);
}
Now, the `BusinessLogic` class depends on the `IDatabase` interface, not on a specific database implementation. It can work with any class that implements this interface. For example:
```csharp
// High-level module depending on abstraction (IDatabase interface)
public class BusinessLogic
{
private readonly IDatabase _database;
public BusinessLogic(IDatabase database)
{
_database = database;
}
public void ProcessData(string data)
{
// Process data
Console.WriteLine("Processing data: " + data);
// Save data using the injected database implementation
_database.SaveData(data);
}
}
Now, you can have different database implementations that adhere to the `IDatabase` interface. For instance, let's create a `SqlServerDatabase` class:
```csharp
// Low-level module implementing IDatabase interface
public class SqlServerDatabase : IDatabase
{
public void SaveData(string data)
{
Console.WriteLine("Saving data to SQL Server database: " + data);
// Save data to SQL Server
}
}
In this example, the `BusinessLogic` class depends on the `IDatabase` interface, allowing for flexibility in the choice of database implementation. This adherence to abstraction instead of concretions is the essence of the Dependency Inversion Principle. It promotes the use of interfaces and abstractions to achieve loose coupling between components, making the system more modular and easier to maintain.
Interface Segregation Principle (ISP)
Interface Segregation Principle (ISP)
The Interface Segregation Principle (ISP) is one of the SOLID principles of object-oriented design. It states that no client should be forced to depend on methods it does not use. In simpler terms, it suggests that a class should not be forced to implement interfaces it doesn't use. Instead of having large interfaces with many methods, it's better to have smaller, more specific interfaces.
Let's explore the Interface Segregation Principle with an example in C#. Imagine you have an interface called `IWorker` that represents different tasks a worker can do:
```csharp
public interface IWorker
{
void Work();
void Eat();
void Sleep();
}
In this interface, a worker can work, eat, and sleep. However, consider a scenario where you have different types of workers - regular workers who do all tasks, and part-time workers who only work and eat. If both types of workers are forced to implement the `IWorker` interface as it is, it would violate the Interface Segregation Principle because the part-time workers would be implementing methods they don't use (`Sleep` method).
A better approach would be to segregate the interface into smaller interfaces, each representing a specific functionality. For example:
```csharp
public interface IWorkable
{
void Work();
}
public interface IEatable
{
void Eat();
}
public interface ISleepable
{
void Sleep();
}
Now, the regular workers can implement all three interfaces, while the part-time workers only need to implement `IWorkable` and `IEatable`, avoiding the unnecessary implementation of the `Sleep` method.
Here's an implementation of regular and part-time workers using the segregated interfaces:
```csharp
public class RegularWorker : IWorkable, IEatable, ISleepable
{
public void Work()
{
Console.WriteLine("Regular worker is working.");
}
public void Eat()
{
Console.WriteLine("Regular worker is eating.");
}
public void Sleep()
{
Console.WriteLine("Regular worker is sleeping.");
}
}
public class PartTimeWorker : IWorkable, IEatable
{
public void Work()
{
Console.WriteLine("Part-time worker is working.");
}
public void Eat()
{
Console.WriteLine("Part-time worker is eating.");
}
}
By adhering to the Interface Segregation Principle, you create more specialized and cohesive interfaces, leading to more maintainable and flexible code. Classes and objects can implement only the interfaces that are relevant to them, avoiding unnecessary dependencies and ensuring that clients are not forced to depend on methods they don't use.
Liskov Substitution Principle (LSP)
Liskov Substitution Principle (LSP)
The principle states that objects of a superclass should be replaceable with objects of a subclass without affecting the correctness of the program.
Certainly! Let's demonstrate the Liskov Substitution Principle (LSP) with an example involving addition and subtraction operations in C#.
First, let's define an interface `IOperation` representing different mathematical operations:
```csharp
// Operation interface
public interface IOperation
{
int Apply(int x, int y);
}
Next, we implement two classes, `Addition` and `Subtraction`, representing addition and subtraction operations, respectively:
```csharp
// Addition class implementing IOperation interface
public class Addition : IOperation
{
public int Apply(int x, int y)
{
return x + y;
}
}
// Subtraction class implementing IOperation interface
public class Subtraction : IOperation
{
public int Apply(int x, int y)
{
return x - y;
}
}
Now, let's create a calculator class `Calculator` that performs addition and subtraction operations based on the Liskov Substitution Principle:
```csharp
// Calculator class adhering to the Liskov Substitution Principle
public class Calculator
{
public int PerformOperation(IOperation operation, int x, int y)
{
return operation.Apply(x, y);
}
}
In this implementation, both `Addition` and `Subtraction` classes implement the `IOperation` interface. The `Calculator` class takes any object that implements `IOperation` and performs the operation without knowing the specific class being used, demonstrating the Liskov Substitution Principle.
Here's how you can use these classes:
```csharp
class Program
{
static void Main()
{
Calculator calculator = new Calculator();
IOperation addition = new Addition();
int result1 = calculator.PerformOperation(addition, 10, 5);
Console.WriteLine("Addition Result: " + result1); // Output: 15
IOperation subtraction = new Subtraction();
int result2 = calculator.PerformOperation(subtraction, 10, 5);
Console.WriteLine("Subtraction Result: " + result2); // Output: 5
}
}
In this example, both `Addition` and `Subtraction` classes can be substituted wherever an `IOperation` object is expected, without altering the correctness of the program, adhering to the Liskov Substitution Principle.
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