LINQ标准查询运算符的执行方式-延时之流式处理

LINQ的延迟执行方式分两种，一种是流式处理，另一种是非流式处理。流式处理是指：当获取到的源元素足够计算时，就生成结果元素，不一定要获取全部源元素。

ToAsEnumerable

namespace ConsoleApp4

{

    class Program

    {

        static void Main(string[] args)

        {

            Clump<string> fruitClump =

                new Clump<string> { "apple", "passionfruit", "banana",

            "mango", "orange", "blueberry", "grape", "strawberry" };

            // 调用 Clump's Where() method with a predicate.

            IEnumerable<string> query1 =

                fruitClump.Where(fruit => fruit.Contains("o"));

            Console.WriteLine("query1 has been created.\n");

            // 强迫使用 System.Linq.Enumerable 的 Where() 方法.

            IEnumerable<string> query2 =

                fruitClump.AsEnumerable().Where(fruit => fruit.Contains("o"));

            // Display the output.

            Console.WriteLine("query2 has been created.");

        }

    }

    class Clump<T> : List<T>

    {

        // Custom implementation of Where().

        public IEnumerable<T> Where(Func<T, bool> predicate)

        {

            Console.WriteLine("In Clump's implementation of Where().");

            return Enumerable.Where(this, predicate);

        }

    }

}

Cast

//ArrayList 继承的是IEnumerable 而非IEnumerable<T>

System.Collections.ArrayList fruits = new System.Collections.ArrayList();

fruits.Add("mango");

fruits.Add("apple");

fruits.Add("lemon");

//OrderBy扩展的是IEnumerable<T>。因此通过Cast<T>转为IEnumerable<T>

IEnumerable<string> query =

    fruits.Cast<string>().OrderBy(fruit => fruit).Select(fruit => fruit);

foreach (string fruit in query)

{

    Console.WriteLine(fruit);

}

Concat 连接序列

Pet[] cats = GetCats();

Pet[] dogs = GetDogs();

IEnumerable<string> query =

    cats.Select(cat => cat.Name).Concat(dogs.Select(dog => dog.Name));

foreach (string name in query)

{

    Console.WriteLine(name);

}

//用另一个select重载试试
IEnumerable<string> query1 =
    cats.Select((pet, index) => { if (index == 2) { return pet.Name; } else { return ""; } })
    .Concat(dogs.Select(dog=>dog.Name))

DefaultIfEmpty 如果序列为空，则返回一个具有默认值的单例类集合

Pet defaultPet = new Pet { Name = "Default Pet", Age =  };

List<Pet> pets1 =

    new List<Pet>{ new Pet { Name="Barley", Age= },

           new Pet { Name="Boots", Age= },

           new Pet { Name="Whiskers", Age= } };

foreach (Pet pet in pets1.DefaultIfEmpty(defaultPet))

{

    Console.WriteLine("Name: {0}", pet.Name);

}

List<Pet> pets2 = new List<Pet>();

foreach (Pet pet in pets2.DefaultIfEmpty(defaultPet))

{

    Console.WriteLine("\nName: {0}", pet.Name);

}

Distinct 返回元素不重复的元素，可以使用默认比较器，也可以传个新的

Product product1 = new Product { Name = "apple", Code =  };

Product[] products = { product1,

           new Product { Name = "orange", Code =  },

          product1,

           new Product { Name = "lemon", Code =  } };

//在此处，使用默认比较器

IEnumerable<Product> noduplicates = products.Distinct();

//该不该生产当前结果元素，只需要判断之前的源元素有没有一样的，知道判断到有，就不生成

foreach (var product in noduplicates)

    Console.WriteLine(product.Name + " " + product.Code);

Except 返回序列之间的差值

double[] numbers1 = { 2.0, 2.0, 2.1, 2.2, 2.3, 2.3, 2.4, 2.5 };

double[] numbers2 = { 2.2 };

IEnumerable<double> onlyInFirstSet = numbers1.Except(numbers2);

foreach (double number in onlyInFirstSet)

    Console.WriteLine(number);

GroupJoin 两个序列进行分组联接

Person magnus = new Person { Name = "Hedlund, Magnus" };

Person terry = new Person { Name = "Adams, Terry" };           

Pet barley = new Pet { Name = "Barley", Owner = terry };

Pet boots = new Pet { Name = "Boots", Owner = terry };

Pet daisy = new Pet { Name = "Daisy", Owner = magnus };

List<Person> people = new List<Person> { magnus, terry };

List<Pet> pets = new List<Pet> { barley, boots, daisy };

//Pet的Owner和Person关联

var query =

    people.GroupJoin(pets,

                     person => person,

                     pet => pet.Owner,

                     (person, petCollection) =>

                         new

                         {

                             OwnerName = person.Name,

                             Pets = petCollection.Select(pet => pet.Name)

                         });

foreach (var obj in query)

{

    Console.WriteLine("{0}:", obj.OwnerName);

    foreach (string pet in obj.Pets)

    {

        Console.WriteLine("  {0}", pet);

    }

}

Intersect 求序列交集

Product product = new Product { Name = "apple", Code =  };

Product[] store1 = { product,

           new Product { Name = "orange", Code =  } };

Product[] store2 = { product,

           new Product { Name = "lemon", Code =  } };

//在这里 使用默认比较器求差值

var products = store1.Intersect(store2); 

foreach(var item in products)

{

    Console.WriteLine(item.Name);

}

Join基于匹配建对序列的元素进行关联

Person magnus = new Person { Name = "Hedlund, Magnus" };

Person terry = new Person { Name = "Adams, Terry" };

Person charlotte = new Person { Name = "Weiss, Charlotte" };

Pet barley = new Pet { Name = "Barley", Owner = terry };

Pet boots = new Pet { Name = "Boots", Owner = terry };

Pet whiskers = new Pet { Name = "Whiskers", Owner = charlotte };

Pet daisy = new Pet { Name = "Daisy", Owner = magnus };

List<Person> people = new List<Person> { magnus, terry, charlotte };

List<Pet> pets = new List<Pet> { barley, boots, whiskers, daisy };

//pet的owner和person关联

var query =

    people.Join(pets,

                person => person,

                pet => pet.Owner,

                (person, pet) =>

                    new { OwnerName = person.Name, Pet = pet.Name });

foreach (var obj in query)

{

    Console.WriteLine(

        "{0} - {1}",

        obj.OwnerName,

        obj.Pet);

}

OfType 根据指定类型筛选序列指定的元素

System.Collections.ArrayList fruits = new System.Collections.ArrayList();

fruits.Add("Mango");

fruits.Add("Orange");

fruits.Add("Apple");

fruits.Add(3.0);

fruits.Add("Banana");

// Apply OfType() to the ArrayList.

IEnumerable<string> query1 = fruits.OfType<string>();

Console.WriteLine("Elements of type 'string' are:");

foreach (string fruit in query1)

{

    Console.WriteLine(fruit);

}

Console.WriteLine("Elements of type 'int' are:");

IEnumerable<double> query2 = fruits.OfType<double>();

foreach (var num in query2)

{

    Console.WriteLine(num);

}

Range 生成指定范围内的序列

IEnumerable<int> squares = Enumerable.Range(, ).Select(x => x * x);

foreach (int num in squares)

{

    Console.WriteLine(num);

}

Repeat生成一个包含重复值的序列

IEnumerable<string> strings =

Enumerable.Repeat("I like programming.", );

foreach (String str in strings)

{

    Console.WriteLine(str);

}

Select 将序列中的每个元素投影到新表单

string[] fruits = { "apple", "banana", "mango", "orange",

          "passionfruit", "grape" };

var query =

    fruits.Select((fruit, index) => new { index,str=fruit.Substring(,index)});

foreach (var obj in query)

{

    Console.WriteLine("{0}", obj);

}

SelectMany 将序列的每个元素投影到 IEnumerable<T> ,然后，每个元素投影到的结果序列合并成一个大的序列。

PetOwner[] petOwners =

{

  new PetOwner { Name="Higa",

      Pets = new List<string>{ "Scruffy", "Sam" } },

  new PetOwner { Name="Ashkenazi",

      Pets = new List<string>{ "Walker", "Sugar" } },

  new PetOwner { Name="Price",

      Pets = new List<string>{ "Scratches", "Diesel" } },

  new PetOwner { Name="Hines",

      Pets = new List<string>{ "Dusty" } }

};

//想要的结果，Higa养猪人都有哪些猪，排成一行行的结果。

// {Owner=Higa, Pet=Scruffy}

// {Owner=Higa, Pet=Sam}

var query = petOwners.Where(owner=>owner.Name=="Higa")

    .SelectMany(owner => owner.Pets, (owner, pet) => new { owner = owner.Name, pet });

foreach(var obj in query)

{

    Console.WriteLine(obj);

}

Skip 跳过指定数量的元素，返回一个剩下元素组成的新序列

int[] grades = { , , , , , ,  };

IEnumerable<int> lowerGrades =

    grades.Skip();

foreach (int grade in lowerGrades)

{

    Console.WriteLine(grade);

}

//返回结果

//70

//56

//92

//98

//

SkipWhile 当条件为true，前面的元素忽略，剩下的元素组成一个新序列。
下面有坑，请注意。

int[] grades = { , , , , , ,  };

IEnumerable<int> newGrades =

     grades.SkipWhile(grade => grade >= );

foreach (int grade in newGrades)

{

    Console.WriteLine(grade);

}

Console.WriteLine("\n");

//排序之后的跳过

IEnumerable<int> lowerGrades =

     grades.OrderByDescending(g=>g).SkipWhile(grade => grade >= );

foreach (int grade in lowerGrades)

{

    Console.WriteLine(grade);

}

控制台输出结果：
59
82
70
56
92
98
85

70
59
5

Take从序列的开头返回指定数量的相邻元素

int[] grades = { , , , , , ,  };

IEnumerable<int> newGrades =

    grades.Take();

foreach (int grade in newGrades)

{

    Console.WriteLine(grade);

}

TakeWhile 只要指定的条件为 true，就会返回序列的元素，从开头开始取，直到不满足条件，剩下的元素也不返回了。

string[] fruits = { "apple", "banana", "mango", "orange",

          "passionfruit", "grape" };

IEnumerable<string> query =

    fruits.TakeWhile(fruit => String.Compare("orange", fruit, true)!= );

foreach (string fruit in query)

{

    Console.WriteLine(fruit);

}

Console.WriteLine("\n");

IEnumerable<string> query1 =

    fruits.TakeWhile(fruit => String.Compare("apple", fruit, true) == );

foreach (string fruit in query1)

{

    Console.WriteLine(fruit);

}

/*

 输出结果:

 apple

 banana

 mango

 apple

*/

Union 生成两个序列的并集

跑了好些示例，发现只要通过标准运算符生成的元素如果要通过判断相等操作，都有比较器可以传入的函数。

int[] ints1 = { , , , , , , ,  };

int[] ints2 = { , , , , , , ,  };

IEnumerable<int> union = ints1.Union(ints2);

foreach (int num in union)

{

    Console.Write("{0} ", num);

}

Where 基于条件筛选序列，太常用了。

List<string> fruits =

    new List<string> { "apple", "passionfruit", "banana", "mango",

                    "orange", "blueberry", "grape", "strawberry" };

IEnumerable<string> query = fruits.Where(fruit => fruit.Length < );

foreach (string fruit in query)

{

    Console.WriteLine(fruit);

}

/*

 This code produces the following output:

 apple

 mango

 grape

*/