6 Anal-dpt menyimpan Cara Untuk Meningkatkan Anda Kode C #

Tidak ada yang irks saya lebih daripada harus menggali melalui kode sampah. Bekerja di sebuah perusahaan konsultan perangkat lunak, saya telah melihat seluruh membunuh itu. Dan aku melemparkan di komputer saya memantau cukup sebagai hasil untuk memberikan, cantik kecoklatan hijau warna. Kode yang buruk merusak perangkat keras. Dan jiwa-jiwa.

Petunjuk tunggal terbesar yang pengembang baik tidak tahu apa yang mereka lakukan atau hanya tidak peduli tentang kode mereka adalah inkonsistensi. Kita semua memiliki preferensi yang berbeda dan gaya coding, tapi ketika pengembang tidak bisa memilih pendekatan tertentu untuk mengambil mereka datang dari sebagai sangat amatir, dan untuk alasan yang baik. Kode tidak konsisten sulit dibaca, dan dengan demikian sulit untuk memodifikasi di masa depan.

Sebagian besar (atau bahkan keseluruhan) dari daftar di bawah ini berkisah menulis secara konsisten gaya dan konsisten menampilkan kode C #. Sebagian besar daftar ini diakui dpt menyimpan dubur, tetapi semua itu dijamin untuk meningkatkan kualitas dan pembacaan kode Anda.

1. Gunakan fitur Analisis Kode dalam Visual Studio.

Fitur Kode Analisis ini adalah dubur dpt menyimpan oleh alam, karena Anda cepat menemukan ketika Anda mulai menggunakannya untuk pertama kalinya. Mereka adalah, bagaimanapun, layak dan berat mereka di emas, mereka adalah cara yang paling segera yang efektif untuk meningkatkan C # kode.

Setiap kali Anda membangun kode Anda, Analisis Kode akan memeriksanya untuk memastikan bahwa daftar besar dan berkembang dari "praktek terbaik" terpenuhi, dan akan membuat peringatan dalam Daftar Kesalahan Anda jika mereka tidak. Anda tidak dapat memanggil kode Anda "baik" kode kecuali lewat analisis kode Visual Studio dengan terbang warna. Ada pengecualian untuk aturan ini, tetapi mereka sedikit dan jauh antara.

Mengaktifkan Analisis Kode di # Visual C proyek Anda Studio 2005 atau 2008 tergantung pada apakah Anda bekerja dengan sebuah aplikasi Windows atau Web.

Untuk aplikasi Windows, masuk ke Solution Explorer dan klik dua simpul Properties proyek. Dari sini, pilih tab Analisis Kode di sisi kiri. Periksa Analisis Kode Enable pada kotak cek Build, dan Anda berada pada jalan. Anda akan melihat bahwa Anda dapat mengaktifkan dan menonaktifkan salah satu pemeriksaan berbagai individu, tapi saya sarankan meninggalkan mereka semua diperiksa kecuali Anda telah menemukan sebuah peringatan bahwa Anda yakin Anda dapat mengabaikan. Seperti yang saya dinyatakan sebelumnya, Analisis Kode hampir selalu benar.

Untuk aplikasi Web, pergi ke Solution Explorer dan pilih node root untuk website Anda. Lalu pergi ke menu Menganalisis dan pilih Konfigurasi Kode Analisis. Dari sini, periksa Analisis Kode Enable pada kotak cek Build dan Anda berada pada jalan.

2. Gunakan daerah secara konsisten dan efektif.

Tidak ada yang suka menggali melalui file kode besar untuk menemukan metode tertentu, dan C # 's daerah membantu memecahkan masalah ini. Berikut ini sebuah contoh:

#region Private Variables

private int x;
private int y;

#endregion

#region Public Properties

public int X
{
    get
    {
        return x;
    }
}

public int Y
{
    get
    {
        return y;
    }
}

#endregion

In Visual Studio, regions can be collapsed or expanded using the +/- buttons to the left of the region names in the code window. This helps to make it much easier to find a particular method you are looking for. There are many ways to organize your code with region statements, but I prefer to separate the code by type of construct (variables, constructors, event handlers, methods, properties, etc.) and access modifier (public, internal, protected, or private).

3.  Handle white space consistently.

C# ignores white space, which means you can put extra spaces and lines pretty much wherever you like.  Or, if you’re insane, you can jam ten-thousand lines of code into a very angry single line of actual text, separated only by semicolons.

Here are a few things to consider, though:

• Code with more white space is generally much easier to read.  Less condensed code is easier on the eyes and with screen real estate being as ample as it is these days, there’s little reason to try and jam your code into as few lines as possible.  For the most part, bigger is better.
• Even though code blocks, such as if and while statements, do allow you to omit the curly braces, this generally makes your code harder to read.  The general consensus is to always use curly braces even when there is only one line of code you are executing between them.
• Consistency, consistency, consistency.  If you put new lines after you close blocks of code, be sure you do it everywhere.  Don’t “feel it out.”  Come up with your own strategy (preferably similar or the same to most other peoples’ strategies) and stick to it.

4.  Always specify your access modifiers and choose them carefully.

C# access modifiers are simply the public, internal, protected, and private keywords that you typically place in front of variables, properties, and methods.  Though these are often overlooked, they provide meaning to the functionality behind your code and help to better define the structure of your code through encapsulation.

Here are some grossly oversimplified definitions and uses for the four modifiers.  These definitions are lacking some detail, but should be plenty of information to handle the vast majority of circumstances:

Private members are only accessible to the class in which they live.  All variables, properties, methods, etc. that do not need to be accessed outside the immediate class should be marked as private.

Protected members are accessible to the class in which they live, as well as any classes that derive from (extend) the class.  The protected modifier should be used on variables, properties, methods, etc. that may need to be accessed by classes that may derive from (extend) the current class.

Internal members are accessible everywhere within the current project, but are inaccessible by other projects that might reference the current project.  In other words, using the internal modifier specifies that only classes within the current EXE or DLL file can access the member.  The internal modifier should be used on all variables, properties, methods, etc. that need to be available to other classes within the project, but should not be available outside the project.

Public members are accessible everywhere, period.  There are no restrictions to their access.  This particular modifier is often overused, as the internal modifier is overlooked.  The public modifier should only be used for members or classes that are or would possibly be needed outside of the current project.

As far as defining classes, typically only internal or public are used, depending on if they need to be accessible outside the project.  This, however, does not account for nested classes, which can have any of the four access modifiers.  Always specify your access modifiers to avoid confusion as to when and where the class or member can be used.

5.  Learn the ways to properly use exceptions and stick to them.

C# exceptions are extremely powerful and convenient, but when used incorrectly, they can both slow your application down and hinder output to the end user.

There are two basic rules of thumb to using exceptions properly:

• Never catch an exception when you can check for and prevent the error instead.  A typical scenario is trying to open a file that you’re not entirely sure really exists.  You can wrap the file open code in a try catch, or you can use File.Exists to determine if the file exists before attempting to open it.  Exceptions in C# are expensive, so you only want an exception to be raised if a true error occurs.  If you can predict that it might happen for a particular reason, you should be able to check to make sure that it won’t happen before proceeding.  This will help to improve performance significantly.
• Also, never catch the root Exception class, or any high-level, broad exception.  If you catch an Exception class, and you incorrectly assume that the user didn’t fill in a particular field as a result, the user will see your incorrect error message and be unable to see the actual error that occurred.  This is unacceptable.  Instead, research the methods you are calling to determine the particular types of exceptions they raise, and catch these specific exceptions.  This way, if something occurs that you didn’t expect, the end user will see the detailed error message anyway.  The MSDN documentation does a great job of providing you with all of the details you need regarding every exception that is possible for every single method in the .NET framework.

6.  ALWAYS use using statements.

In case you’re not familiar with the syntax of using statements, here is an example:

using (StreamWriter writer = new StreamWriter("C:\\file.txt"))
{
    writer.WriteLine("Hello!");
}

Using statements can be used wherever you’re instantiating an object that is IDisposable (can be disposed using the Dispose method).  If you don’t actively dispose objects that support the IDisposable interface, you’re asking for all sorts of performance and memory leak trouble.  Here are the advantages of using statements over calling the Dispose method directly:

• Even if an exceptio Berikut ini sebuah contoh:

  
  #region Private Variables
  
  private int x;
  private int y;
  
  #endregion
  
  #region Public Properties
  
  public int X
  {
      get
      {
          return x;
      }
  }
  
  public int Y
  {
      get
      {
          return y;
      }
  }
  
  #endregion
  

  In Visual Studio, regions can be collapsed or expanded using the +/- buttons to the left of the region names in the code window. This helps to make it much easier to find a particular method you are looking for. There are many ways to organize your code with region statements, but I prefer to separate the code by type of construct (variables, constructors, event handlers, methods, properties, etc.) and access modifier (public, internal, protected, or private).

  3.  Handle white space consistently.

  C# ignores white space, which means you can put extra spaces and lines pretty much wherever you like.  Or, if you’re insane, you can jam ten-thousand lines of code into a very angry single line of actual text, separated only by semicolons.

  Here are a few things to consider, though:

  • Code with more white space is generally much easier to read.  Less condensed code is easier on the eyes and with screen real estate being as ample as it is these days, there’s little reason to try and jam your code into as few lines as possible.  For the most part, bigger is better.
  • Even though code blocks, such as if and while statements, do allow you to omit the curly braces, this generally makes your code harder to read.  The general consensus is to always use curly braces even when there is only one line of code you are executing between them.
  • Consistency, consistency, consistency.  If you put new lines after you close blocks of code, be sure you do it everywhere.  Don’t “feel it out.”  Come up with your own strategy (preferably similar or the same to most other peoples’ strategies) and stick to it.

  4.  Always specify your access modifiers and choose them carefully.

  C# access modifiers are simply the public, internal, protected, and private keywords that you typically place in front of variables, properties, and methods.  Though these are often overlooked, they provide meaning to the functionality behind your code and help to better define the structure of your code through encapsulation.

  Here are some grossly oversimplified definitions and uses for the four modifiers.  These definitions are lacking some detail, but should be plenty of information to handle the vast majority of circumstances:

  Private members are only accessible to the class in which they live.  All variables, properties, methods, etc. that do not need to be accessed outside the immediate class should be marked as private.

  Protected members are accessible to the class in which they live, as well as any classes that derive from (extend) the class.  The protected modifier should be used on variables, properties, methods, etc. that may need to be accessed by classes that may derive from (extend) the current class.

  Internal members are accessible everywhere within the current project, but are inaccessible by other projects that might reference the current project.  In other words, using the internal modifier specifies that only classes within the current EXE or DLL file can access the member.  The internal modifier should be used on all variables, properties, methods, etc. that need to be available to other classes within the project, but should not be available outside the project.

  Public members are accessible everywhere, period.  There are no restrictions to their access.  This particular modifier is often overused, as the internal modifier is overlooked.  The public modifier should only be used for members or classes that are or would possibly be needed outside of the current project.

  As far as defining classes, typically only internal or public are used, depending on if they need to be accessible outside the project.  This, however, does not account for nested classes, which can have any of the four access modifiers.  Always specify your access modifiers to avoid confusion as to when and where the class or member can be used.

  5.  Learn the ways to properly use exceptions and stick to them.

  C# exceptions are extremely powerful and convenient, but when used incorrectly, they can both slow your application down and hinder output to the end user.

  There are two basic rules of thumb to using exceptions properly:

  • Never catch an exception when you can check for and prevent the error instead.  A typical scenario is trying to open a file that you’re not entirely sure really exists.  You can wrap the file open code in a try catch, or you can use File.Exists to determine if the file exists before attempting to open it.  Exceptions in C# are expensive, so you only want an exception to be raised if a true error occurs.  If you can predict that it might happen for a particular reason, you should be able to check to make sure that it won’t happen before proceeding.  This will help to improve performance significantly.
  • Also, never catch the root Exception class, or any high-level, broad exception.  If you catch an Exception class, and you incorrectly assume that the user didn’t fill in a particular field as a result, the user will see your incorrect error message and be unable to see the actual error that occurred.  This is unacceptable.  Instead, research the methods you are calling to determine the particular types of exceptions they raise, and catch these specific exceptions.  This way, if something occurs that you didn’t expect, the end user will see the detailed error message anyway.  The MSDN documentation does a great job of providing you with all of the details you need regarding every exception that is possible for every single method in the .NET framework.

  6.  ALWAYS use using statements.

  In case you’re not familiar with the syntax of using statements, here is an example:

  
  using (StreamWriter writer = new StreamWriter("C:\\file.txt"))
  {
      writer.WriteLine("Hello!");
  }
  

  Using statements can be used wherever you’re instantiating an object that is IDisposable (can be disposed using the Dispose method).  If you don’t actively dispose objects that support the IDisposable interface, you’re asking for all sorts of performance and memory leak trouble.  Here are the advantages of using statements over calling the Dispose method directly:

  • Even if an exception is raised within your using statement block, the runtime will still ensure that the object gets properly disposed.  This is automatic with the using statement and is impossible without it.  Before using statements were added in .NET 2.0, you had to attempt to dispose of your objects within a catch block, which was far from error-prone.  Never take this approach.
  • Using statements help to visually define the scope of a variable that requires disposing.  You can quickly and easily see the start and end of the lifetime of the variable.  Once you are in the habit of consistently using using statements to dispose of objects you will very rarely (if ever) forget to dispose of an object, because of the block nature of the statement.
  • Using statements even allow you to return from a method within the statement.  The object is still disposed of properly in this situation.  In other words, if you use a using statement, the object is GUARANTEED to be disposed of despite any and all circumstances.  That’s a pretty big and valuable promise.

  There is much more to writing good C# code than these 6 rules, but these are the rules that I see consistently broken that are driving me to an early grave.  Let me know in the comments if you think I’m missing something important or disagree with any of my statements.