lets go

目录

• 0。我们开始之前
• 1。简介或golang（GO）
• 2。基本
  • 2.1。在Golang说Hello World
  • 2.2。编译和运行代码
  • 2.4。变量，类型和关键字
  • 2.5。操作员和内置功能
  • 2.6。去关键字
  • 2.7。控制结构
  • 2.8。内置功能
  • 2.9。阵列，切片和地图
  • 2.10。结构
  • 2.11。嵌入
• 3。功能
  • 3.1。范围
  • 3.2。用作值
  • 3.3。回调
  • 3.4。延期代码
  • 3.5。 variadic参数
  • 3.6。恐慌和恢复
• 4。包
  • 4.1。标识符
  • 4.2。文档包
  • 4.3。创建一个软件包
  • 4.4。包装初始化
  • 4.5。程序执行订单
  • 4.6。安装第三方套餐
  • 4.7。测试包
  • 4.8。有用的软件包
• 5。指针
• 6。分配和构造函数
• 7。转换
• 8。接口
  • 8.1。什么是？
  • 8.2。空界面
  • 8.3。方法
  • 8.4。列出接口中的接口
  • 8.5。内省和反思
• 9。并发
  • 9.1。使其并行运行
  • 9.2。有关频道的更多信息
• 10。沟通
  • 10.1。 io.Reader
  • 10.2。命令行参数
  • 10.3。执行命令
  • 10.4。联网
• 11。模块（Golang版本> = 1.11）
  • 11.1。概念
  • 11.2。 Quickstart
  • 11.3。去代理
  • 11.4。工作区
  • 11.5。组织一个GO模块
    • 11.5.1。基本软件包
    • 11.5.2。基本命令
    • 11.5.3。包装或命令带有支持软件包
    • 11.5.4。多个软件包
    • 11.5.5。多个命令
    • 11.5.6。同一存储库中的软件包和命令
  • 11.5.7。服务器项目
• 12。
  • 12.1。与读者和作家一起
  • 12.2。用FMT格式化的IO
  • 12.3。缓冲io
  • 12.4。内存IO
• 13。编码和解码
  • 13.1。 JSON
• 14。网络编程
  • 14.1。 HTTP服务器
  • 14.2。模板
  • 14.3。请求和表格
  • 14.4。资产和文件
  • 14.5。中间件（基本）
  • 14.6。中间件（高级）
  • 14.7。会议
  • 14.8。 Websocket
• 15。远程程序调用（RPC），GRPC和Protobuf
  • 15.1。远程过程调用（RPC）
  • 15.2。 GRPC和Protobuf
• 16。新软件包
  • 16.1。 unique包装
• 新GO程序员的资源
  • 在线资源
  • 安装go＆配置工作空间
  • 文本编辑和IDE

查找Golang文档并不重要。有很多好的资源，只需选择一个并开始学习旅程即可。我主要跟随学习 - Miek Gieben。

注意：本文档中的每个示例都存储在按节命名的目录中。我假设X节中的每个命令都将在示例/X目录中执行，因此我不编写完整的路径到达脚本文件。

• Google支持的开源编程语言。
• 命令性语言
• 静态打字
• 编译到本机代码（无JVM）
• 语法令牌类似于c（bu tless括号和没有半色）和oberon-2的结构
• 是一个面向对象的语言吗？：是和否
  • 具有类型和方法，允许以对象为导向的编程样式，没有类型的层次结构（尽管有类型的嵌入）。
  • 没有类，而是用方法结构。
  • 接口
  • 功能 - 方法是一流的公民：
    • 方法比Java或C ++更通用：它们可以针对任何类型的数据定义，即使是内置类型，例如Plain，“ Unbox”整数。它们不仅限于结构（类）。
    • 方法可以返回多个值。
• 有关闭
• 指针，但不是指针算术
• 内置并发原语：goroutines和频道

• 以经典的方式开始：印刷“ Hello World”（Ken Thompson＆Dennies Ritchie在1970年代介绍C语言#til时开始了这一点）

 /* hello_world.go */
package main

import "fmt" // Implements formatted I/O

/* Say Hello-World */
func main () {
    fmt . Printf ( "Hello World" )
}

• 要构建Helloworld.go，只需输入：

go build helloworld.go # Return an executable called helloworld

• 运行上一个步骤结果

./helloworld

• 想在这两个步骤上发ombine吗？好的，戈兰得到了你。

go run helloworld.go

• 在变量名称之后，指定了该类型的变量中的大多数其他语言：a int。

 /* When you declare a variable it is assigned the "natural" null value for the type */
var a int // a has a value of 0
var s string // s is assigned the zero string, which is ""
a = 26
s = "hello"

/* Declaring & assigning in Go is a two step process, but they may be combined */
a := 26 // In this case the variable type is deduced from the value. A value of 26 indicates an int for example.
b := "hello" // The type should be string

/* Multiple var declarations may also be grouped (import & const also allow this) */
var (
    a int
    b string
)

/* Multiple variables of the same type ca also be declared on a single line */
var a , b int
a , b := 26 , 9

/* A special name for a variable is _, any value assigned to it is discarded. */
_ , b := 26 , 9

• 布尔： bool

• 数值：

  • GO具有大多数众所周知的类型，例如int它具有适合您的机器的长度（32位机器-32位，64位机器-64位）
  • （签名和未签名）整数的完整列表是int8 ， int16 ， int32 ， int64和byte （ uint8的别名）， uint8 ， uint16 ，UINT16， uint32 ， uint64 。
  • 对于浮点值，有float32 ， float64 ，漂浮。

   /* numerical_types.go */
  package main
  
  func main () {
      var a int
      var b int32
      b = a + a // Give an error: cannot use a + a (type int) as type int32 in assignment.
      b = b + 5
  }

• 常数：在编译时创建常数，并且只能是数字，字符串或布尔值。您可以使用iota列举价值。

 const (
    a = iota // First use of iota will yield 0. Whenever iota is used again on a new line its value is incremented with 1, so b has a vaue of 1.
    b
)

• 字符串：

  • GO中的字符串是包含在双引号中的UTF-8字符的序列。如果使用单个报价，则指一个字符（在UTF -8中编码） - 这不是GO中的string 。注意！在Python（我最喜欢的编程语言）中，我可以将它们都用于字符串分配。
  • Go中的绳子是不可变的。要更改字符串中的一个字符，您必须创建一个新字符。

   s1 := "Hello"
  c := [] rune ( s ) // Convert s1 to an array of runes
  c [ 0 ] := 'M'
  s2 := string ( c ) // Create a new string s2 with the alteration
  fmt . Printf ( "%s n " , s2 )

• 符文： Rune是int32的别名，（使用字符串中的字符迭代时使用）。

• 复合数： complex128 （64位真实零件）或complex32 。

• 错误：GO具有一个专门用于错误的内置类型，称为error.var e 。

• GO 1.18带来对通用类型的支持。 GO 1.18提供的通用实现遵循类型参数提案，并允许开发人员添加可选类型参数以输入和函数声明。结帐Golang的仿制药教程。

 package main

import "fmt"

type Number interface {
    int64 | float64
}

func main () {
    // Initialize a map for the integer values
    ints := map [ string ] int64 {
        "first" : 34 ,
        "second" : 12 ,
    }

    // Initialize a map for the float values
    floats := map [ string ] float64 {
        "first" : 35.98 ,
        "second" : 26.99 ,
    }

    fmt . Printf ( "Non-Generic Sums: %v and %v n " ,
        SumInts ( ints ),
        SumFloats ( floats ))

    fmt . Printf ( "Generic Sums: %v and %v n " ,
        SumIntsOrFloats [ string , int64 ]( ints ),
        SumIntsOrFloats [ string , float64 ]( floats ))

    fmt . Printf ( "Generic Sums, type parameters inferred: %v and %v n " ,
        SumIntsOrFloats ( ints ),
        SumIntsOrFloats ( floats ))

    fmt . Printf ( "Generic Sums with Constraint: %v and %v n " ,
        SumNumbers ( ints ),
        SumNumbers ( floats ))
}

// SumInts adds together the values of m.
func SumInts ( m map [ string ] int64 ) int64 {
    var s int64
    for _ , v := range m {
        s += v
    }
    return s
}

// SumFloats adds together the values of m.
func SumFloats ( m map [ string ] float64 ) float64 {
    var s float64
    for _ , v := range m {
        s += v
    }
    return s
}

// SumIntsOrFloats sums the values of map m. It supports both floats and integers
// as map values.
func SumIntsOrFloats [ K comparable , V int64 | float64 ]( m map [ K ] V ) V {
    var s V
    for _ , v := range m {
        s += v
    }
    return s
}

// SumNumbers sums the values of map m. Its supports both integers
// and floats as map values.
func SumNumbers [ K comparable , V Number ]( m map [ K ] V ) V {
    var s V
    for _ , v := range m {
        s += v
    }
    return s
}

• GO支持普通的数值操作员。

 Precedence    Operator(s)
Highest       * / % << >> & &^
            `+ -
            == != < <= > >=
            <-
            &&
Lowest        ||

• & bitwise和， |位或^位Xor， &^位分别清晰。

 break     default      func    interface   select
case      defer        go      map         struct
chan      else         goto    package     switch
const     fallthrough  if      range       type
continue  for          import  return      var

• var ， const ， package ， import在先前的部分中使用。
• func用于声明功能和方法。
• return用于从功能返回。
• go用于并发。
• select用于从不同类型的通信中进行选择。
• interface 。
• struct用于抽象数据类型。
• type 。

• if-else ：

 if x > 0 {
    return y
} esle {
    return x
}

if err := MagicFunction (); err != nil {
    return err
}

// do something

• goto ：使用goto ，您跳到了一个标签，该标签必须在当前功能中定义。

 /* goto_test */
/* Create a loop */
func gototestfunc () {
    i := 0
Here:
    fmt . Println ()
    i ++
    goto Here
}

• for ： for loop有三种形式，其中只有一种具有分号：

 for init ; condition ; post { } // aloop using the syntax borrowed from C
for condition { } // a while loop
for { } // a endless loop

sum := 0
for i := 0 ; i < 10 ; i ++ {
    sum = sum + i
}

• 休息并继续：

 for i := 0 ; i < 10 ; i ++ {
    if i > 5 {
        break
    }
    fmt . Println ( i )
}

/* With loops within loop you can specify a label after `break` to identify which loop to stop */
J: for j := 0 ; j < 5 ; j ++ {
    for i := 0 ; i < 10 ; i ++ {
        if i > 5 {
            break J
        }
        fmt . Println ( i )
    }
}

• 范围：

  • range可用于循环。它可以在切片，阵列，字符串，地图和通道上循环。
  • range是一个迭代器，当调用时，它会返回“事物”循环的下一个键值对。

   list := [] string { "a" , "b" , "c" , "d" , "e" , "f" }
  for k , v := range list {
      // do some fancy thing with k & v
  }

• 转变：

  • 在找到匹配匹配之前，将表壳从上到下进行评估，并且如果switch没有表达式，则它将打开true 。
  • 因此，可以 - ＆IDOMATIC - 将if-else-if-else链写为switch 。

   /* Convert hexadecimal character to an int value */
  switch { // switch without condition = switch true
      case '0' <= c && c <= '9' :
          return c - '0'
      case 'a' <= c && c <= 'f' :
          return c - 'a' + 10
      case 'A' <= c && c <= 'F' :
          return c - 'A' + 10
  }
  return 0
  
  /* Automatic fall through */
  switch i {
      case 0 : fallthrough
      case 1 :
          f ()
      default :
          g ()
  }

 close      new        panic       complex
delete      make       recover     real
len         append     print       imag
cap         copy       println

• 关闭：用于频道通信。它关闭了通道（显然XD）
• 删除：用于删除地图中的条目。
• Len＆Cap：用于多种类型的多种类型， len用于返回Strring，地图，切片和数组的长度。
• 新：用于为用户定义的数据类型分配内存。
• 复制，附加： copy是用于复制切片。 append是用于串联切片。
• 恐慌，恢复：用于例外机制。
• 复杂，真实的，图像：所有内容都涉及复数。

• 简介：列表 - >数组，切片。 dict->地图

• 数组：

  • 数组由[n]<type>定义。

   var arr [ 10 ] int // The size is part of the type, fixed size
  arr [ 0 ] = 42
  arr [ 1 ] = 13
  fmt . Printf ( "The first element is %s n " , arr [ 0 ])
  
  // Initialize an array to something other than zero, using composite literal
  a := [ 3 ] int { 1 , 2 , 3 }
  a := [ ... ] int { 1 , 2 , 3 }

  • 数组是值类型：将一个数组分配给另一个数组副本所有元素。特别是，如果您将数组传递到一个函数，它将收到数组的副本，而不是指向它的指针。为了避免副本，您可以将指针传递给数组，但这是对数组而不是数组的指针。

• 切片：

  • 与数组类似，但是当添加新元素时，它可以增长。
  • 切片是指向（底层）数组的指针，切片是参考类型。

   // Init array primes
  primes := [ 6 ] int { 2 , 3 , 5 , 7 , 11 , 13 }
  
  // Init slice s
  var s [] int = primes [ 1 : 4 ]
  
  fmt . Println ( s ) // Return [3, 5, 7]
  
  /* slice_length_capacity.go */
  package main
  
  import "fmt"
  
  func main () {
      s := [] int { 2 , 3 , 5 , 7 , 11 , 13 }
      printSlice ( s )
  
      // Slice the slice to give it zero length.
      s = s [: 0 ]
      printSlice ( s )
  
      // Extend its length.
      s = s [: 4 ]
      printSlice ( s )
  
      // Drop its first two values.
      s = s [ 2 :]
      printSlice ( s )
  }
  
  func printSlice ( s [] int ) {
      fmt . Printf ( "len=%d cap=%d %v n " , len ( s ), cap ( s ), s )
  }

  • 切片是数组段的描述符。它由指向阵列的指针，段的长度及其容量（段的最大长度）组成。

   s := make ([] byte , 5 )

  • len是切片所指的元素数量。

  • cap是基础数组中的元素数量（从切片指针提到的元素开始）。

     s = s [ 2 : 4 ]

    • 切片不会复制切片的数据。它创建了一个指向原始数组的新切片。这使得切片操作效率与操纵阵列所指示的效率一样高。因此，修改重新布置的元素（不是切片本身）会修改原始切片的元素：

       d := [] byte { 'r' , 'o' , 'a' , 'd' }
      e := d [ 2 :]
      // e = []byte{'a', 'd'}
      e [ 1 ] = 'm'
      // e = []byte{'a', 'm'}
      // d = []byte{'r', 'o', 'a', 'm'}

      • 早些时候，我们将s切成比其容量短的长度。我们可以通过再次将其切成薄片来增强其能力。

       s = s [: cap ( s )]

  • 切片不能超出其能力。

   // Another example
  var array [ m ] int
  slice := array [: n ]
  // len(slice) == n
  // cap(slice) == m
  // len(array) == cap(array) == m

  • 为了扩展切片，有几个内置功能可以使生活更轻松： append和copy 。

   s0 := [] int { 0 , 0 }
  s1 := append ( s0 , 2 ) // same type as s0 - int.
  // If the original slice isn't big enough to fit the added values,
  // append will allocate a new slice that is big enough. So the slice
  // returned by append may refer to a different underlaying array than
  // the original slices does.
  s2 := append ( s1 , 3 , 5 , 7 )
  s3 := append ( s2 , s0 ... ) // []int{0, 0, 2, 3, 5, 7, 0, 0} - three dots used after s0 is needed make it clear explicit that you're appending another slice, instead of a single value
  
  var a = [ ... ] int { 0 , 1 , 2 , 3 , 4 , 5 , 6 , 7 }
  var s = make ([] int , 6 )
  // copy function copies slice elements from source to a destination
  // returns the number of elements it copied
  n1 := copy ( s , a [ 0 :]) // n1 = 6; s := []int{0, 1, 2, 3, 4, 5}
  n2 := copy ( s , s [ 2 :]) // n2 = 4; s := []int{2, 3, 4, 5, 4, 5}

• 地图：

  • Python有其词典。在Go中，我们有map类型。

   monthdays := map [ string ] int {
      "Jan" : 31 , "Feb" : 28 , "Mar" : 31 ,
      "Apr" : 30 , "May" : 31 , "Jun" : 30 ,
      "Jul" : 31 , "Aug" : 31 , "Sep" : 30 ,
      "Oct" : 31 , "Nov" : 30 , "Dec" : 31 , // A trailing comma is required
  }
  
  value , key := monthdays [ "Jan" ]

  • 仅在声明地图时使用make 。地图是参考类型。地图不是参考变量，其值是指向runtime.hmap结构的指针。

• 没有类，只有结构。结构可以具有方法：

 // A struct is a type. It's also a collection of fields

// Declaration
type Vertex struct {
    X , Y float64
}

// Creating
var v = Vertex { 1 , 2 }
var v = Vertex { X : 1 , Y : 2 } // Creates a struct by defining values with keys
var v = [] Vertex {{ 1 , 2 },{ 5 , 2 },{ 5 , 5 }} // Initialize a slice of structs

// Accessing members
v . X = 4

// You can declare methods on structs. The struct you want to declare the
// method on (the receiving type) comes between the the func keyword and
// the method name. The struct is copied on each method call(!)
func ( v Vertex ) Abs () float64 {
    return math . Sqrt ( v . X * v . X + v . Y * v . Y )
}

// Call method
v . Abs ()

// For mutating methods, you need to use a pointer (see below) to the Struct
// as the type. With this, the struct value is not copied for the method call.
func ( v * Vertex ) add ( n float64 ) {
    v . X += n
    v . Y += n
}

• 匿名结构：便宜，更安全，而不是使用map[string]intefaces 。
• 您可以检查定义自己的类型以获取更多信息。

• Go中没有子类别。相反，有接口和结构嵌入。

 // ReadWriter implementations must satisfy both Reader and Writer
type ReadWriter interface {
    Reader
    Writer
}

// Server exposes all the methods that Logger has
type Server struct {
    Host string
    Port int
    * log. Logger
}

// initialize the embedded type the usual way
server := & Server { "localhost" , 80 , log. New ( ... )}

// methods implemented on the embedded struct are passed through
server. Log ( ... ) // calls server.Logger.Log(...)

// the field name of the embedded type is its type name (in this case Logger)
var logger * log. Logger = server. Logger 

 // General Function
type mytype int
func ( p mytype ) funcname ( q , int ) ( r , s int ) { return 0 , 0 }
// p (optional) bind to a specific type called receiver (a function with a receiver is usually called a method)
// q - input parameter
// r,s - return parameters

• 可以按照您希望的任何顺序声明功能。
• GO不允许嵌套功能，但是您可以使用匿名功能解决此问题。

• 在GO中声明的任何函数之外声明的变量，功能中定义的变量是这些函数本地的。
• 如果名称重叠 - 局部变量被声明为具有与全局的名称相同的名称 - 当当前函数执行时，本地变量隐藏了全局一个。

• 与GO中的几乎所有内容一样，函数也只是值。

 import "fmt"

func main () {
    a := func () { // a is defined as an anonymous (nameless) function,
        fmt . Println ( "Hello" )
    }
    a ()
}

 func printit ( x int ) {
    fmt . Println ( "%v n " , x )
}

func callback ( y int , f func ( int )) {
    f ( y )
}

 /* Open a file & perform various writes & reads on it. */
func ReadWrite () bool {
    file . Open ( "file" )
    // Do your thing
    if failureX {
        file . Close ()
        return false
    }

    // Repeat a lot of code.
    if failureY {
        file . Close ()
        return false
    }
    file . Close ()
    return true
}

/* Same situation but using defer */
func ReadWrite () bool {
    file . Open ( "file" )
    defer file . Close () // add file.Close() to the defer list
    // Do your thing
    if failureX {
        return false
    }

    if failureY {
        return false
    }
    return true
}

• 可以将多个功能放在“延期列表”上。
• Defer函数按LIFO顺序执行。

 for i := 0 ; i < 5 ; i ++ {
    defer fmt . Printf ( "%d " , i ) // 4 3 2 1 0
}

• 使用defer您甚至可以更改返回值，前提是您使用命名的结果参数和函数字面的（ def func(x int) {/*....*/}(5) ）。

 func f () ( ret int )
    defer func () { // Initialized with zero
        ret ++
    }()
    return 0 // This will not be the returned value, because of defer. Ths function f will return 1
}

• 采用可变数量参数的函数称为变异函数。

 func func1 ( arg ... int ) { // the variadic parameter is just a slice.
    for _ , n := range arg {
        fmt . Printf ( "And the number is: %d n " , n )
    }
}

• GO没有例外机制：您不能异常。相反，它使用了恐慌和恢复机制。
  • 恐慌：内置功能，可以刺激控制和开始恐慌。当功能F调用pacnic时，执行F停止时，F型中的任何延迟功能均正常执行，然后F返回其呼叫者。对于来电者，F然后表现得像恐慌。该过程继续堆叠，直到当前Goroutine中的所有功能都返回，此时程序崩溃了。恐慌可以通过直接引起恐慌来发起。它们也可能是由运行时错误引起的，例如越野阵列访问。
  • 恢复：内置功能，可以重新控制恐慌的goroutine。恢复仅在延期函数内有用。在正常执行期间，恢复的呼叫将返回NIL，并且没有其他效果。如果当前的goroutine感到恐慌，恢复的调用将捕获恐慌和恢复正常执行的值。

 /* defer_panic_recover.go */
package main

import "fmt"

func main () {
    f ()
    fmt . Println ( "Returned normally from f." )
}

func f () {
    defer func () {
        if r := recover (); r != nil {
            fmt . Println ( "Recovered in f" , r )
        }
    }()
    fmt . Println ( "Calling g." )
    g ( 0 )
    fmt . Println ( "Returned normally from g." )
}

func g ( i int ) {
    if i > 3 {
        fmt . Println ( "Panicking!" )
        panic ( fmt . Sprintf ( "%v" , i ))
    }
    defer fmt . Println ( "Defer in g" , i )
    fmt . Println ( "Printing in g" , i )
    g ( i + 1 )
}
/* Result */
// Calling g.
// Printing in g 0
// Printing in g 1
// Printing in g 2
// Printing in g 3
// Panicking!
// Defer in g 3
// Defer in g 2
// Defer in g 1
// Defer in g 0
// Recovered in f 4
// Returned normally from f.

• 仍然不了解这些如何工作？不用担心，我明白了。使用Inanc Gunmus的Praticial Visual效果简化了Go Go Defer。
• 有关延期的其他有用链接：
  • 5次延期 - 第一部分
  • 5次延期 - 第二部分
• 查看用例
• 要优雅处理恐慌，请检查手柄提示。

• 软件包是功能和数据的集合。
• 软件包名称的约定是使用小写字符 - 该文件不必匹配软件包名称。

 package even

func Even ( i int ) bool { // starts with capital -> exported
    return i % 2 == 0
}

func odd ( i int ) bool { // start with lower-case -> private
    return i % 2 == 1
}

• 构建包裹

mkdir $GOPATH /src/even
cp even.go $GOPATH /src/even
go build
go install

• 现在，您可以使用import "even"中的程序中的包裹使用。

• GO的惯例是使用骆驼而不是强调编写多词名称。
• GO中的约定是软件包名称是小写，单词名称。
• 覆盖默认软件包名称： import bar "bytes" 。
• 另一个惯例是软件包名称是其源目录的基本名称； src/compress/gzip中的软件包被导入为compress/gzip但具有name gzip ，而不是compress/gzip 。
• 命名事物时避免口吃。
• 制作ring.Ring package的新实例的功能（ container/ring ）通常称为NewRing ，但是由于Ring是该软件包导出的唯一类型，因为软件包被称为ring ，因此称为New 。包装的客户将其视为ring.New 。

• 每个软件包都应有一个包评论**。
• 当一个包由多个文件组成时，软件包注释仅应在1个文件中出现。
• 一个常见的惯例（在真正的大包装中）是拥有一个单独的doc.go 。仅包含包裹注释的文档。

 /*
    The regexp package implements a simple library for
    regular expressions.

    The syntax of the regular expressions accepted is:

    regexp:
        concatenation { '|' concatenation }
*/
package regexp

• 每个定义的（和导出）函数应具有相同的文本线，以记录该函数的行为。

• 有两种类型的软件包：可执行软件包（主要应用程序，因为您将运行它）和公用事业软件包（无法自行执行，而是通过提供实用程序功能和其他导入资产来增强可执行软件包的功能）。
• 如果变量名称以大写为单位，请GO导出变量。所有其他不以大写字母开头的变量都是包裹的私有变量。
• 对于可执行软件包，具有main函数的文件是输入文件进行执行。

• 软件包范围 - 范围是代码块中的一个区域，可以访问定义变量。软件包范围是包装中的一个区域，在软件包中可以从软件包中访问已声明的变量（跨软件包中的所有文件）。该区域是包装中任何文件的最高块。您不允许在同一软件包中重新解析使用同名的全局变量
• 可变初始化。
• init函数：像main函数一样，初始化软件包时，go调用init函数。它不需要任何参数，也不会返回任何值。 init函数被隐含地声明。您可以在文件或软件包中具有多个init功能。在文件中执行init函数的顺序将按照其外观顺序。
• 软件包别名：下划线是GO中的特殊字符，充当null容器。
• 要记住的主要事情是，导入的软件包仅初始化一次。因此，如果您的软件包中有许多导入语句，则在主软件包执行的使用寿命中，仅将导入的软件包初始化一次。

go run * .go
├── Main package is executed
├── All imported packages are initialized
|  ├── All imported packages are initialized (recursive definition)
|  ├── All global variables are initialized
|  └── init functions are called in lexical file name order
└── Main package is initialized
   ├── All global variables are initialized
   └── init functions are called in lexical file name order

安装第三方软件包只是将远程代码克隆到本地src/<package>目录中。不幸的是，GO不支持软件包版本或提供软件包管理器，但建议在这里等待。

• 写作测试涉及testing软件包和程序go test 。
• 来源Golang写作单位测试
• GO中的单元测试只是语言的任何其他方面，例如格式化或命名。
• 例子：

 package main

func Sum ( x int , y int ) int {
    return x + y
}

func main () {
    Sum ( 5 , 5 )
}

// Testcase
package main

import "testing"

func TestSum ( t * testing. T ) {
    total := Sum ( 5 , 5 )
    if total != 10 {
       t . Errorf ( "Sum was incorrect, got: %d, want: %d." , total , 10 )
    }
}

• 测试表是测试输入和输出值的集合（切片数组）。例子：

 package main

import "testing"

func TestSum ( t * testing. T ) {
    tables := [] struct {
        x int
        y int
        n int
    }{
        { 1 , 1 , 2 },
        { 1 , 2 , 3 },
        { 2 , 2 , 4 },
        { 5 , 2 , 7 },
    }

    for _ , table := range tables {
        total := Sum ( table . x , table . y )
        if total != table . n {
            t . Errorf ( "Sum of (%d+%d) was incorrect, got: %d, want: %d." , table . x , table . y , total , table . n )
        }
    }
}

• 启动测试：

  • 在与测试相同的目录中，这将拾取匹配packagename_test.go的任何文件：go：

  go test

  • 通过完全合格的软件包名称：

  go test github.com/username/package

• HTTP测试：

  • net/http/httptest子包装促进了HTTP服务器和客户端代码的测试自动化。
  • 编写HTTP服务器代码时，毫无疑问，您将以强大可重复的方式测试您的代码，而无需设置一些脆弱的代码线束即可模拟端到端测试。类型httptest.ResponseRecorder专门旨在通过检查测试函数中的HTTP.ResponseWriter的状态更改，以提供单位测试功能来行使HTTP处理程序方法。
  • 为HTTP客户端创建测试代码的涉及更多，因为您实际上需要运行的服务器进行正确的测试。幸运的是，软件包httptest提供类型httptest.Server以编程方式创建服务器来测试客户端请求并将模拟响应发送给客户端。

• 语句覆盖范围： go test工具具有用于语句的内置代码覆盖。

$ go test -cover
PASS
coverage: 50.0% of statements
ok      github.com/alexellis/golangbasics1    0.009s
# Generate a HTML coverage report.
$ go test -cover -coverprofile=c.out
$ go tool cover -html=c.out -o coverage.html

• 代码基准：基准测试的目的是测量代码的性能。 GO测试命令行工具具有支持基准指标的自动生成和测量的支持。与单元测试相似，测试工具使用基准功能来指定要测量的代码的哪些部分。

  • 运行基准

    $ > go test -bench=.
     PASS
     BenchmarkVectorAdd-2 2000000 761 ns/op
     BenchmarkVectorSub-2 2000000 788 ns/op
     BenchmarkVectorScale-2 5000000 269 ns/op
     BenchmarkVectorMag-2 5000000 243 ns/op
     BenchmarkVectorUnit-2 3000000 507 ns/op
     BenchmarkVectorDotProd-2 3000000 549 ns/op
     BenchmarkVectorAngle-2 2000000 659 ns/op
     ok github.com/vladimirvivien/learning-go/ch12/vector 14.123s

  • 跳过测试功能

     > go test -bench=. -run=NONE -v
     PASS
     BenchmarkVectorAdd-2 2000000 791 ns/op
     BenchmarkVectorSub-2 2000000 777 ns/op
    Code Testing
    [ 314 ]
     ...
     BenchmarkVectorAngle-2 2000000 653 ns/op
     ok github.com/vladimirvivien/learning-go/ch12/vector 14.069s

  • 比较基准：比较实现相似功能的不同算法的性能。使用性能基准测试算法将表明哪些实现可能更加计算和内存效率。

• 隔离依赖关系：定义单位测试的关键因素是与运行时依赖关系或协作者隔离。检查依赖注入。

• FMT ：软件包fmt通过类似于C的printf ＆ scanf功能实现了格式的I/O。格式动词源自C，但更简单。一些可以使用的动词（％序列）：

  • ％v，默认格式的值，当打印结构时，加上标志（％+v）添加了字段名称。
  • ％＃v，该值的go-syntax表示。
  • ％t，值类型的GO-Sytanx表示。

• IO ：该软件包为I/O原始词提供了基本接口。它的主要工作是将此类原语的现有实现（例如包装os中的原始）包含在抽象功能的共享公共接口中，以及其他一些相关的原始界面。

• Bufio ：此软件包实现了缓冲的I/O。它包含一个io.reader或io.Writer对象，创建另一个对象（读取器或作者），该对象也实现了接口，但为文本I/O提供了缓冲和一些帮助。

• 排序：排序软件包提供了用于分类数组和用户定义集合的原始内容。

• STRCONV ：STRCONV软件包实现了基本数据类型的字符串表示的转换。

• OS ：OS软件包为操作系统功能提供了独立于平台的接口。设计类似于Unix。

• 同步：软件包同步提供了基本的同步基原始人，例如相互排除锁。

• 标志：标志软件包实现命令行标志解析。

• 编码/JSON ：编码/JSON软件包实现了RFC 4627中定义的JSON对象的编码和解码。

• HTML/模板：用于生成文本输出（例如HTML）的数据驱动模板。

• NET/HTTP ：NET/HTTP软件包实现HTTP请求，答复和URLS＆提供可扩展的HTTP服务器和基本HTTP客户端的解析。

• 不安全：不安全的软件包包含围绕GO程序类型安全的操作。通常，您不需要此软件包，但是值得一提的是不安全的GO程序。

• 反思：反射软件包实现运行时反射，允许程序用任意类型来操纵对象。典型的用途是使用静态类型接口{}的值，并通过调用TypeOf提取其动态类型信息，该typeof返回具有接口类型的对象。

• OS/EXEC ：OS/EXEC软件包运行外部命令。

• Go有指针，但没有指针，因此它们的作用更像是参考，而不是您从C中知道的指针。

  • 指针是一个存储另一个变量的地址的变量。因此，指针是存储值的位置。并非每个值都有一个地址，但是每个变量都可以。
  • 引用是指另一个值的变量。
  • 没有指针算术。你不能写信。也就是说，除非您为其分配另一个地址，否则您不能更改地址p点。

   var p * int
  p ++

  • 想了解更多吗？检查本文或另一篇this 。

• 指针很有用。请记住，当您在GO中调用函数时，变量是逐个价值的。因此，为了效率和修改传递值的功能的可能性，我们有指示。

• 指针类型（ *类型）和地址的运算符 *：如果将变量声明为var x int ，则表达式&x （x of x of x of x of x int）会产生一个指向整数变量的指针（类型* int的值）。如果此值称为p ，我们说“ p向x ”或等效地“ p包含x的地址”。 p点写的变量*p 。表达式*p产生该变量的值，一个int ，但由于*p表示变量，因此它也可能出现在分配的左侧，在这种情况下，分配会更新变量。参考

   x := 1
  p := & x          // p, of type *int, points to x
  fmt . Println ( * p )  // "1"
  * p = 2           // equivalent to x = 2
  fmt . Println ( x )   // "2"

• 所有新声明的变量均分配了其零值，而指示也没有什么不同。新宣布的指针，或者只是指向一无所有的指针具有尼尔值。

 var p * int // declare a pointer
fmt . Printf ( "%v" , p )

var i int
p = & i // Make p point to i

fmt . Printf ( "%v" , p ) // Print somthing like 0x7ff96b81c000a

• 指针插图：

 // Go program to illustrate the
// concept of the Pointer to Pointer
package main

import "fmt"

// Main Function
func main () {

        // taking a variable
        // of integer type
    var V int = 100

    // taking a pointer
    // of integer type
    var pt1 * int = & V

    // taking pointer to
    // pointer to pt1
    // storing the address
    // of pt1 into pt2
    var pt2 * * int = & pt1

    fmt . Println ( "The Value of Variable V is = " , V )
    fmt . Println ( "Address of variable V is = " , & V )

    fmt . Println ( "The Value of pt1 is = " , pt1 )
    fmt . Println ( "Address of pt1 is = " , & pt1 )

    fmt . Println ( "The value of pt2 is = " , pt2 )

    // Dereferencing the
    // pointer to pointer
    fmt . Println ( "Value at the address of pt2 is or *pt2 = " , * pt2 )

    // double pointer will give the value of variable V
    fmt . Println ( "*(Value at the address of pt2 is) or **pt2 = " , * * pt2 )
}

// The Value of Variable V is =  100
// Address of variable V is =  0x414020
// The Value of pt1 is =  0x414020
// Address of pt1 is =  0x40c128
// The value of pt2 is =  0x40c128
// Value at the address of pt2 is or *pt2 =  0x414020
// *(Value at the address of pt2 is) or **pt2 =  100

• 检查指针与参考。

• Go也有垃圾收集。

• 为了分配记忆，GO有2个原始词， new ＆ make 。

• 新分配；初始化。

  • 新（t）返回 *t指向ZerodT。
  • 使（t）返回初始化的T。
  • 制造仅用于切片，地图，通道。

• 构造者和compiste文字

 // A lot of boiler plate
func NewFile ( fd int , name string ) * File {
    if fd < 0 {
        return nil
    }
    f := new ( File )
    f . fd = fd
    f . name = name
    f . dirinfo = nil
    f . nepipe = 0
    return f
}
// Using a composite literal
func NewFile ( fd int , name string ) * File {
    if fd < 0 {
        return nil
    }
    f := File { fd , name , nil . 0 }
    return & f // Return the address of a local variable. The storage associated with the variable survives after the function returns.
    // return &File{fd, name, nil, 0}
    // return &File{fd: fd, name: name}
}

• 作为限制情况，如果复合文字根本不包含字段，则它将为该类型创建零值。表达式new(File) ＆＆ &File{}是等效的。

• 还可以为阵列，切片和地图创建复合文字，而字段标签是指数或适当的地图键。

 ar := [ ... ] string { Enone : "no error" , Einval : "invalid argument" }
sl := [] string { Enone : "no error" , Einval : "invalid argument" }
ma := map [ int ] string { Enone : "no error" , Einval : "invalid argument" }

• 定义自己的类型

 /* defining_own_type.go */
package main

import "fmt"

type NameAge struct {
    name string // both non exported fiedls
    age  int
}

func main () {
    a := new ( NameAge )
    a . name = "Kien"
    a . age = 25
    fmt . Printf ( "%v n " , a ) // &{Kien, 25}
}

• 有关结构字段的更多信息

 struct {
    x , y int
    A * [] int
    F func ()
}

• 方法：

  • 创建一个将类型作为参数的函数：

   func doSomething1 ( n1 * NameAge , n2 int ) { /* */ }
  // method call
  var n * NameAge
  n . doSomething1 ( 2 )

  • 创建一个在类型上工作的函数：

   func ( n1 * NameAge ) doSomething2 ( n2 int ) { /* */ }

注意：如果x是可寻址＆x的方法集，则包含m，xm（）是（＆x）.m（）的速记。

• 假设我们有：

 // A mutex is a data type with two methods, Lock & Unlock
type Mutex struct { /* Mutex fields */ }
func ( m * Mutex ) Lock () { /* Lock impl */ }
func ( m * Mutext ) Unlock { /* Unlock impl */ }

// NewMutex is equal to Mutex, but it does not have any of the methods of Mutex.
type NewMutex Mutex
// PrintableMutex hash inherited the method set from Mutex, contains the methods
// Lock & Unlock bound to its anonymous field Mutex
type PrintableMutex struct { Mutex }

 FROM    b []byte    i []int    r []rune    s string    f float32    i int
TO
[]byte  .                                  []byte(s)
[]int               .                      []int(s)
[]rune                                     []rune(s)
string  string(b)   string(i)  string(r)   .
float32                                                .            float32(i)
int                                                    int(f)       .

• float64的工作与float32相同
• 从string到字节或符文

 mystring := "hello this is string"
byteslice := [] byte ( mystring )
runeslice := [] rune ( string )

• 从一个字节或符文到字符串

 b := [] byte { 'h' , 'e' , 'l' , 'l' , 'o' } // Composite literal
s := string ( b )
i := [] rune ( 26 , 9 , 1994 )
r := string ( i )

• 对于数字值：

  • 转换为具有特定（位）长度的整数： uint8(int) 。
  • 从浮点到整数值： int(float32) 。这会从浮点值中丢弃分数部分。
  • 以及围绕float32(int)其他方式

• 用户定义的类型和转换

 type foo struct { int } // Anonymous struct field
type bar foo            // bar is an alias for foo

var b bar = bar { 1 } // Declare `b` to be a `bar`
var f foo = b      // Assign `b` to `f` --> Cannot use b (type bar) as type foo in assignment
var f foo = foo ( b ) // OK! 

• 每种类型都有一个接口，这是为该类型定义的一组方法。

 /* a struct type S with 1 field, 2 methods */
type S struct { i int }
func ( p * S ) Get () int { return p . i }
func ( p * S ) Put ( v int ) { p . i = v }

/* an interface type */
type I interface {
    Get () int
    Put () int
}
/* S is a valid implementation for interface I */

• S是对Ineterface I的有效实现。GO程序可以通过接口的另一个含义来使用此事实，这是接口值：

 func f ( p I ) {
    fmt . Println ( p . Get ())
    p . Put ( 1 )
}
var s S
/* Because S implements I, we can call the
function f passing in a pointer to a value
of type S */
/* The reason we need to take the address of s,
rather than a value of type S, is because
we defined the methods on s to operae on pointers */
f ( & s )

• 您不需要声明某种类型是否实现接口的事实意味着可以实现鸭子打字的形式。这不是纯鸭打字，因为在可能的情况下，GO complier会静态检查该类型是否实现了地面。但是，GO确实具有纯粹的动态方面，因为您可以将一个接口转换为另一个接口。在一般情况下，该转换在运行时进行检查。如果转换无效 - 如果存储在现有接口值中的值的类型无法满足其要转换的接口，则该程序将在运行时错误中失败。

  • 鸭打字 - 如果看起来像鸭子，并且像鸭子一样颤抖，那就是鸭子。这意味着，如果它具有匹配接口的一组方法，则可以在不明确定义您的类型实现该接口的情况下使用该接口。

   package main
  
  import "fmt"
  
  type Duck interface {
      Quack ()
  }
  
  type Donald struct {
  }
  
  func ( d Donald ) Quack () {
      fmt . Println ( "quack quack!" )
  }
  
  type Daisy struct {
  }
  
  func ( d Daisy ) Quack () {
      fmt . Println ( "-quack -quack" )
  }
  
  func sayQuack ( duck Duck ) {
      duck . Quack ()
  }
  
  type Dog struct {
  }
  
  func ( d Dog ) Bark () {
      fmt . Println ( "go go" )
  }
  
  func main () {
      donald := Donald {}
      sayQuack ( donald ) // quack
      daisy := Daisy {}
      sayQuack ( daisy ) // --quack
      dog := Dog ()
      sayQuack ( dog ) // compile error - cannot use dog (type Dog) as type Duck
  }

• GO的接口让您像纯动态语言一样使用duck typing ，但仍有编译器捕获明显的错误，例如传递带有Read方法的对象的int ，或者像以错误数量的参数调用Read方法一样。

• 让我们定义另一个类型的R，也将实现接口I。

 type R struct { i int }
func ( p * R ) Get () int { return p . i }
func ( p * R ) Put ( v int ) { p . i = v }

func f ( p I ) {
    switch t := p .( type ) {
        case * S :
        case * R :
        default :
    }
}

• 创建一个具有空接口作为参数的通用函数

 func g ( something interface {}) int {
    return something .( I ). Get ()
}

• .(I)是一种类型的断言，它将something转换为类型I的接口。如果我们有类型，则可以调用Get()函数。

 s = new ( S )
fmt . Println ( g ( s ))

• 方法是具有接收器的函数。

• 您可以在任何类型上定义方法（非本地类型除外，这包括内置类型：类型int不能具有方法）。

• 接口类型的方法

  • 一个接口定义了一组方法。一种方法包含实际代码。
  • 接口是定义，方法是实现。

• 按照惯例，一个方法名称和-er后缀命名：读者，作者，格式化，...

• 指针和非点方法接收器。

   func ( s * MyStruct ) pointerMethod () {} // method on pointer
  func ( s MyStruct ) valueMethod () {} // method on value

  • 在类型上定义方法时，接收器的行为就像是对方法的参数。是否将接收器定义为值还是指针是相同的问题，就像函数参数应该是值还是指针。
  • 第一：该方法是否需要修改接收器？如果确实如此，则接收器必须是指针（切片和地图充当参考，因此他们的故事有些微妙，但是例如，要在方法中更改切片的长度，接收器仍然必须是指针）。否则，它应该是价值。

   package main
  
  import "fmt"
  
  type Mutatable struct {
      a int
      b int
  }
  
  func ( m Mutatable ) StayTheSame () {
      m . a = 5
      m . b = 7
  }
  
  func ( m * Mutatable ) Mutate () {
      m . a = 5
      m . b = 7
  }
  
  func main () {
      m := & Mutatable { 0 , 0 }
      fmt . Println ( m )
      m . StayTheSame ()
      fmt . Println ( m )
      m . Mutate ()
      fmt . Println ( m )
  }

  • 第二：效率。如果接收器很大，例如一个大struct ，则使用指针接收器会便宜得多。
  • 第三：一致性。如果该类型的某些方法必须具有指针接收器，则其余也应该具有指针，因此无论使用该类型如何，方法集都保持一致。
  • 对于基本类型，切片和小struct等类型，值接收器非常便宜，因此除非方法的语义需要指针，否则值接收器是有效且清晰的。

• 类型开关：类型开关就像常规开关语句，但是类型开关中的情况指定类型（非值），这些类型与给定接口值保持的值类型进行了比较。

 package main

import "fmt"

func do ( i interface {}) {
    switch v := i .( type ) {
    case int :
        fmt . Printf ( "Twice %v is %v n " , v , v * 2 )
    case string :
        fmt . Printf ( "%q is %v bytes long n " , v , len ( v ))
    default :
        fmt . Printf ( "I don't know about type %T! n " , v )
    }
}

func main () {
    do ( 21 )
    do ( "hello" )
    do ( true )
}

// Twice 21 is 42
// "hello" is 5 bytes long
// I don't know about type bool!

• 这里更多示例。

• 首先，不要在平行和并发之间搞砸。
• Goroutines是GO并发能力的中心实体。 Goroutine具有一个简单的模型：它是与同一地址空间中其他Goroutines并行执行的函数。它是轻巧的，几乎不超过堆栈空间的分配。堆栈开始很小，因此它们便宜，并且可以根据需要分配（和释放）堆存储来生长。
  • Goroutine vs OS线程。
  • 最大goroutines数

 ready ( "Tea" , 2 ) // Normal function call
go ready ( "Tea" , 2 ) // .. Bum! Here is goroutine

/* X ready example */
package main

import (
    "fmt"
    "time"
)

func ready ( w string , sec int ) {
    time . Sleep ( time . Duration ( sec ) * time . Second )
    fmt . Println ( w , "is ready!" )
}

func main () {
    go ready ( "Tea" , 2 ) // Tea is ready - After 2 second (3)
    go ready ( "Coffee" , 1 ) // Coffee is ready - After 1 second (2)
    fmt . Println ( "I'm waiting" ) // Right away (1)
    // If did not wait for the goroutines, the program would be terminated
    // immediately & any running goroutines would die with it!
    time . Sleep ( 5 * time . Second )
}

• 实际上，我们不知道我们应该等待多长时间，直到所有Goroutine都退出。为了解决此问题，我们需要某种机制，使我们能够与Goroutines -Channel进行通信。可以将通道与Unix Shell中的双向管道进行比较：您可以从中发送并接收值。

 /* Define a channel, we must also define the type of
the values we can send on the channel */
ci := make ( chan int )
cs := make ( chan string )
cf := make ( chan interface {})
ci <- 1 // Send the integer 1 to the channel ci
<- ci    // Receive an integer from the channel ci
i := <- ci // Receive from the channel ci & store it in i

• 将其放入上一个示例（准备就绪）。

 package main

import (
    "fmt"
    "time"
)

var c chan int

func ready ( w string , sec int ) {
    time . Sleep ( time . Duration ( sec ) * time . Second )
    fmt . Println ( w , "is ready!" )
    c <- 1
}

func main () {
    c = make ( chan int )
    go ready ( "Tea" , 2 )
    go ready ( "Coffee" , 1 )
    fmt . Println ( "I'm waiting" )
    <- c // Wait until we receive a value from the channel
    <- c
}

• 缓冲通道：

  • 缓冲通道具有容量。

    • 当Goroutine尝试将资源发送到缓冲频道并且通道已满时，该频道将锁定Goroutine，并使其等待直到缓冲区可用。
    • 当Goroutine尝试从缓冲通道接收而缓冲通道为空时，该频道将锁定Goroutine并使其等待直到发送资源。

  • 缓冲通道用于执行异步通讯。

  • 缓冲渠道没有这样的保证。

  • 仅当频道中没有值的值时，接收才会阻止。

  • 仅当没有可用的缓冲区以放置要发送的值时，发送才会阻止。

• 未封闭的频道：

  • 未封闭的渠道没有能力，因此需要两个goroutines准备进行任何交换。

    • 当Goroutine试图将资源发送到和未封闭的频道，并且没有Goroutine等待接收资源时，该频道将锁定发送的Goroutine并使其等待。
    • 当Goroutine试图从一个未封闭的频道接收，并且没有Goroutine等待发送资源时，该频道将锁定接收的Goroutine并使其等待。

  • 未封闭的通道用于在Goroutines之间执行同步通信。未封闭的通道提供了保证，即在发送和接收的瞬间进行2个goroutines之间的交换。

  • 同步是在通道上发送和接收之间的相互作用的基础。

 unbuffered := make ( chan int ) // Unbuffered channel of integer type
buffered := make ( chan int , 10 )    // Buffered channel of integer type

• 您可以查看Ardanlabs博客文章以获取更多详细信息。这些图片是从那里拍摄的。
• 如果我们不知道我们开始了多少个goroutines怎么办？这是另一个内置的进来的地方： select 。

L: for {
    select {
    case <- c :
        i ++
        if i > 1 {
            break L
        }
    }
}

 package main

import "fmt"

func fibonacci ( c , quit chan int ) {
    x , y := 0 , 1
    for {
        select {
        case c <- x :
            x , y = y , x + y
        case <- quit :
            fmt . Println ( "quit" )
            return
        }
    }
}

func main () {
    c := make ( chan int )
    quit := make ( chan int )
    go func () {
        for i := 0 ; i < 10 ; i ++ {
            fmt . Println ( <- c )
        }
        quit <- 0
    }()
    fibonacci ( c , quit )
}
// 2
// 3
// 5
// 8
// 13
// 21
// 34
// quit 

 // Default selection
// The default case in a select is run if no other case is ready.

// Use a default case to try a send or receive without blocking:

// select {
// case i := <-c:
//     // use i
// default:
//     // receiving from c would block
// }
package main

import (
    "fmt"
    "time"
)

func main () {
    tick := time . Tick ( 100 * time . Millisecond )
    boom := time . After ( 500 * time . Millisecond )
    for {
        select {
        case <- tick :
            fmt . Println ( "tick." )
        case <- boom :
            fmt . Println ( "BOOM!" )
            return
        default :
            fmt . Println ( "    ." )
            time . Sleep ( 50 * time . Millisecond )
        }
    }
}

• 当我们的goroutines同时运行时，它们没有并行运行！ （再过一次，请确保您知道并发不是Parral的！）

• 使用runtime.GOMAXPROCS(n)或设置环境变量GOMAXPROCS您可以设置可以并行运行的Goroutines数量。

  • GomaxProcs设置了可以同时执行并返回上一个设置的最大CPU数。如果n <1，则不会更改当前设置。调度程序改进时，此通话将消失。>

• 从版本1.5及以上， GOMAXPROCS默认为CPU内核数。

• 注意：

 ch := make ( chan type , value )
// if value == 0 -> unbuffered
// if value > 0 -> buffer value elements

• 频道关闭时，阅读方需要知道这一点

 x , ok = <- ch
/ * Where ok is set to True the channel is not closed & we 'v e read something
Otherwise ok is set to False . In that case the channel was closed & the value
received is a zero value of the channel 's type .

• 您可以在此处找到有关并发的更多信息。

• 构建块与外界交流（FIELS，目录，网络和执行其他程序）。
• go i/o的中心是io.Reader ＆ io.Writer接口。

• io.Reader是该语言中的重要界面。需要从某些内容中读取的功能（如果不是全部）功能，以io.Reader为输入。
• 写作方io.Writer具有Write方法。
• 如果您想到程序或软件包中的新类型，并且使其满足io.Reader或io.Writer界面，则可以在该类型上使用整个标准GO库。

• 命令行的参数可通过String Slide os.Args内部提供。
• flag软件包具有更复杂的接口，还提供了一种解析标志的方法。

• os/exec软件包具有运行外部命令的功能，并且是从GO程序中执行命令的首要方法。

 import "os/exec"

cmd := exec . Command ( "/bin/ls" , "-l" )
// Just run without doing anything with the returned data
err := cmd . Run ()
// Capturing the standard output
buf , err := cmd . Output () // buf is byte slice

• 所有与网络相关的类型和功能都可以在软件包net中找到。
• 其中最重要的功能之一是Dial 。当您Dial远程系统时，功能返回Conn接口类型，可用于发送和接收信息。函数Dial整齐地抽象了网络家族和运输。

 conn , e := Dial ( "tcp" , "192.0.32.10:80" )
conn , e := Dial ( "udp" , "192.0.32.10:80" )
conn , e := Dial ( "tcp" , "[2620:0:2d0:200::10]:80" )

GO 1.11包括对模块的初步支持，GO GO的新依赖关系管理系统，该系统使依赖版本信息明确且更易于管理。

• 模块：相关的GO软件包的集合，它们一起版本为一个单元。
• 总结存储库，模块和软件包之间的关系：
  • 存储库包含一个或多个GO模块。
  • 每个模块包含一个或多个GO软件包。
  • 每个软件包由单个目录中的一个或多个GO源文件组成。
• go.mod ：一个模块由在树的根目录中使用go.mod文件的GO源文件树定义。模块源代码可能位于Gopath之外。有四个指令： module ， require ， replace ， exclude 。
• 版本选择：如果您向源代码添加了新的导入，该源require尚未被启用go.mod ，诸如“ Go Build”和“ Go Go test”之类的大多数GO命令都会自动查找正确的模块，并将该新的直接依赖性的最高require添加到模块的go.mod 。例如，如果您的新导入对应于最新标记的发行版本为v1.2.3的依赖项M，则您的模块的go.mod最终将获得require M v1.2.3 ，这表明模块M是允许版本> = v1.2.3（and <v2，给定的V2，v2与V1不相容）。
• 语义导入版本：遵循导入兼容性规则和SEMVER的结果称为语义导入版本，其中主要版本包含在导入路径中 - 这确保了导入路径随时由于兼容性中断而导致的主要版本增量。
• 由于语义导入版本控制，选择“ GO”模块的代码必须遵守以下规则：
  • 关注SEMVER（带有v1.2.3之类的标签）。
  • 如果模块是V2版本或更高版本，则必须在go.mod文件中使用的模块路径末端的模块的主要版本作为A /vN包含（例如， module github.com/my/mod/v2 ， require github.com/my/mod/v2 v2.0.0 ）和package import import import（eg， import "github.com/my/mod/v2/mypkg" 。
  • 如果模块是版本V0或V1，则不在模块路径或导入路径中包含主要版本。
• 从GO 1.11开始，GO命令可以在当前目录或任何父目录具有go.mod $GOPATH/src使用模块使用。 （在$GOPATH/src内部，为了兼容，即使找到了go.mod ，GO命令仍在旧的GOPATH模式下运行）
• 从GO 1.13开始，模块模式将是所有开发的默认值。
• Check Go Modules wiki for updated information.

• Go Module's hello-world: init module and add dependencies.

 # Create a directory outside of your GOPATH:
$ mkdir -p /tmp/scratchpad/hello
$ cd /tmp/scratchpad/hello
# Initialize a new module:
$ go mod init github.com/you/hello

go: creating new go.mod: module github.com/you/hello
# Write your code
$ cat << EOF > hello.go
package main

import (
    "fmt"
    "rsc.io/quote"
)

func main() {
    fmt.Println(quote.Hello())
}
EOF

# Introduce `go mod tidy`
# Tidy makes sure go.mod matches the source code in the module.
# It adds any missing modules necessary to build the current module's
# packages and dependencies, and it removes unused modules that
# don't provide any relevant packages. It also adds any missing entries
# to go.sum and removes any unnecessary ones
$ go mod tidy                                                                                                                                              t/s/hello ﳑ  
go: finding module for package rsc.io/quote
go: downloading rsc.io/quote v1.5.2
go: found rsc.io/quote in rsc.io/quote v1.5.2
go: downloading rsc.io/sampler v1.3.0
go: downloading golang.org/x/text v0.0.0-20170915032832-14c0d48ead0c

$ cat go.mod

module github.com/you/hello

require rsc.io/quote v1.5.2

# Add a new dependency often brings in other indirect dependencies too
# List the current module and all its dependencies
$ go list -m all
github.com/you/hello
golang.org/x/text v0.0.0-20170915032832-14c0d48ead0c
rsc.io/quote v1.5.2
rsc.io/sampler v1.3.0

# In addition to go.mod, there is a go.sum file containing the expected
# cryptographic hashes of the content of specific module versions
$ cat go.sum                                                                                                                                                    t/s/hello ﳑ  
golang.org/x/text v0.0.0-20170915032832-14c0d48ead0c h1:qgOY6WgZOaTkIIMiVjBQcw93ERBE4m30iBm00nkL0i8=
golang.org/x/text v0.0.0-20170915032832-14c0d48ead0c/go.mod h1:NqM8EUOU14njkJ3fqMW+pc6Ldnwhi/IjpwHt7yyuwOQ=
rsc.io/quote v1.5.2 h1:w5fcysjrx7yqtD/aO+QwRjYZOKnaM9Uh2b40tElTs3Y=
rsc.io/quote v1.5.2/go.mod h1:LzX7hefJvL54yjefDEDHNONDjII0t9xZLPXsUe+TKr0=
rsc.io/sampler v1.3.0 h1:7uVkIFmeBqHfdjD+gZwtXXI+RODJ2Wc4O7MPEh/QiW4=
rsc.io/sampler v1.3.0/go.mod h1:T1hPZKmBbMNahiBKFy5HrXp6adAjACjK9JXDnKaTXpA=

# Build & run
$ go build
$ ./hello

Hello, world.

• Upgrade your dependencies:

 # From the output of go list -m all, we're using an untagged version of golang.org/x/text
# Let's upgrade to the latest tagged version
$ go get golang.org/x/text                                                                                                                                      t/s/hello ﳑ  
go: downloading golang.org/x/text v0.7.0
go: upgraded golang.org/x/text v0.0.0-20170915032832-14c0d48ead0c = > v0.7.0

$ cat go.mod                                                                                                                                                    t/s/hello ﳑ  
module github.com/you/hello

go 1.19

require rsc.io/quote v1.5.2

require (
        golang.org/x/text v0.7.0 // indirect
        rsc.io/sampler v1.3.0 // indirect
)

$ go list -m all                                                                                                                                                t/s/hello ﳑ  
github.com/you/hello
golang.org/x/mod v0.6.0-dev.0.20220419223038-86c51ed26bb4
golang.org/x/sys v0.0.0-20220722155257-8c9f86f7a55f
golang.org/x/text v0.7.0
golang.org/x/tools v0.1.12
rsc.io/quote v1.5.2
rsc.io/sampler v1.3.0

• Remove unused dependencies: If you want to remove any dependencies, just simple run go mod tidy and Go does the rest.
• Go modules takes care of versioning, but it doesn't necessarily take care of modules disappearing off the Internet or the Internet not being available. If a module is not available, the code cannot be built. Go Proxy will mitigate disappearing modules to some extent by mirroring modules, but it may not do it for all modules for all time. That's why go tool provides go mod vendor command.
  • go mod vendor command constructs a directory named vendor in the main module's root directory that contains copies of all packages needed to support builds and tests of packages in the main modules.
  • go mod vendor also creates the file vendor/modules.txt that contains a list of vendored packages and the module versions they were copied from.
  • You can check in vendor to your Version Control System, then copy this around.

$ go mod vendor

# Main module's directory structure
$ tree -L 3
├── go.mod
├── go.sum
├── hello.go
└── vendor
    ├── golang.org
    │   └── x
    ├── modules.txt
    └── rsc.io
        ├── quote
        └── sampler

• Started from Go 1.13, go tool defaults to downloading modules from the public Go module mirror: https://proxy.golang.org and also defaults to validating downloaded modules (regardless of source) against the public Go checksum database at https://sum.golang.org.
• If you want to change the default Go proxy, you can use the following command:

 export GOPROXY=https://goproxy.io,direct

• The go command defaults to downloading modules from the public Go module mirror, therefore if you have private code, you most likely should configure the GOPRIVATE setting (such as go env -w GOPRIVATE=*.corp.com,github.com/secret/repo ), or the more fine-grained variants GONOPROXY or GONOSUMDB that support less frequent use cases. See the documentation for more details.

• Go introduces the concept of workspaces in 1.18. Workspaces allows you to create projects of several modules that share a common list of dependencies through a new file called go.work . The dependencies in this file can span multiple modules and anything declared in the go.work file will override dependencies in the module's go.mod .
  • A workspace is a collection of modules on disk that are used as the main modules when running minimal version selection (MVS).
  • A workspace can be declared in a go.work file that specifies relative paths to the module directories of each the modules in the workspace. When no go.work file exists, the workspace consists of the single module containing the current directory.
    • Lexical elements in go.work files are defined in exactly the same way as for go.mod files.
    • 在这里查看。

 go 1.18

use . / my / first / thing
use . / my / second / thing

// or
// use (
//     ./my/first/thing
//     ./my/second/thing
// )

replace example . com / bad / thing v1 .4 .5 = > example . com / good / thing v1 .4 .5

• 例子：

$ mkdir workspace
$ cd workspace
# Create hello module
$ mkdir hello
$ cd hello
$ go mod init eaxmple.com/hello
go: creating new go.mod: module example.com/hello
$ cat << EOF > hello.go
package main

import (
    "fmt"

    "golang.org/x/example/stringutil"
)

func main() {
    fmt.Println(stringutil.Reverse("Hello"))
}
EOF

$ go mod tidy
go: finding module for package golang.org/x/example/stringutil
go: found golang.org/x/example/stringutil in golang.org/x/example v0.0.0-20220412213650-2e68773dfca0

$ go run example.com/hello
olleH

# Create the workspace
$ cd ../
$ go work init ./hello
$ tree
.
├── go.work
└── hello
    ├── go.mod
    ├── go.sum
    └── hello.go

1 directory, 4 files

# Go command includes all the modules in the workspace as main modules. This allow us to refer to a package in the module
# even outside the module.
$ go run example.com/hello
olleH

# Download and modify the golang.org/x/example module
$ git clone https://go.googlesource.com/example
Cloning into ' example ' ...
remote: Total 165 (delta 27), reused 165 (delta 27)
Receiving objects: 100% (165/165), 434.18 KiB | 1022.00 KiB/s, done.
Resolving deltas: 100% (27/27), done.
# Add module to the workspace
$ go work use ./example
$ tree -L 1
.
├── example
├── go.work
└── hello

2 directories, 1 file

$ cat go.work
go 1.20

use (
    ./example
    ./hello
)

$ cd example/stringutil
# Create a new file
$ cat << EOF > toupper.go
package stringutil

import "unicode"

// ToUpper uppercases all the runes in its argument string.
func ToUpper(s string) string {
    r := []rune(s)
    for i := range r {
        r[i] = unicode.ToUpper(r[i])
    }
    return string(r)
}
EOF

# Modify hello program
$ cd ../../hello
$ cat << EOF > hello.go
package main

import (
    "fmt"

    "golang.org/x/example/stringutil"
)

func main() {
    fmt.Println(stringutil.ToUpper("Hello"))
}
EOF

$ cd ..
# Go command finds the example.com/hello module specified in the command line
# in the hello directory specified by the go.work file, and similiarly
# resolves the golang.org/x/example import using the go.work file.
$ go run example.com/hello
HELLO

Source: https://go.dev/doc/modules/layout

Go projects can include packages, command-line programs or a combination of the two. This guide is organized by project type.

NOTE : throughout this document, file/package names are entirely arbitrary

• A basic Go package has all its code in the project's root directory. The project consists of a single module, which consists of a single package. The package name matches the last path component of the module name. For a very simple package requiring a single Go file, the project structure is:

project-root-directory/
  go.mod
  modname.go
  modname_test.go
  auth.go
  auth_test.go
  hash.go
  hash_test.go

• The code in modname.go declares the package with:

 package modname

// ... package code here 

• A basic executable program (or command-line tool) is structured according to its complexity and code size. The simplest program can consist of a single Go file where func main is defined. Larger programs can have their code split across multiple files, all declaring package main:

project-root-directory/
  go.mod
  auth.go
  auth_test.go
  client.go
  main.go

• Here the main.go file contains func main , but this is just a convention. The “main” file can also be called modname.go (for an appropriate value of modname) or anything else.

• Larger packages or commands may benefit from splitting off some functionality into supporting packages. Initially, it's recommended placing such packages into a directory named internal ; this prevents other modules from depending on packages we don't necessarily want to expose and support for external uses. Since other projects cannot import code from our internal directory, we're free to refactor its API and generally move things around without breaking external users. The project structure for a package is thus:

project-root-directory/
  internal/
    auth/
      auth.go
      auth_test.go
    hash/
      hash.go
      hash_test.go
  go.mod
  modname.go
  modname_test.go

• A module can consist of multiple importable packages; each package has its own directory, and can be structured hierarchically. Here's a sample project structure:

project-root-directory/
  go.mod
  modname.go
  modname_test.go
  auth/
    auth.go
    auth_test.go
    token/
      token.go
      token_test.go
  hash/
    hash.go
  internal/
    trace/
      trace.go

• As a reminder, we assume that the module line in go.mod says:

 module github . com / someuser / modname 

• Multiple programs in the same repository will typically have separate directories:

project-root-directory/
  go.mod
  internal/
    ... shared internal packages
  prog1/
    main.go
  prog2/
    main.go

• In each directory, the program's Go files declare package main . A top-level internal directory can contain shared packages used by all commands in the repository.
• A common convention is placing all commands in a repository into a cmd directory; while this isn't strictly necessary in a repository that consists only of commands, it's very useful in a mixed repository that has both commands and importable packages, as we will discuss next.

• Sometimes a repository will provide both importable packages and installable commands with related functionality. Here's a sample project structure for such a repository:

project-root-directory/
  go.mod
  modname.go
  modname_test.go
  auth/
    auth.go
    auth_test.go
  internal/
    ... internal packages
  cmd/
    prog1/
      main.go
    prog2/
      main.go

• Go is a common language choice for implementing servers. There is a very large variance in the structure of such projects, given the many aspects of server development: protocols (REST? gRPC?), deployments, front-end files, containerization, scripts and so on. We will focus our guidance here on the parts of the project written in Go.
• Server projects typically won't have packages for export, since a server is usually a self-contained binary (or a group of binaries). Therefore, it's recommended to keep the Go packages implementing the server's logic in the internal directory. Moreover, since the project is likely to have many other directories with non-Go files, it's a good idea to keep all Go commands together in a cmd directory:

project-root-directory/
  go.mod
  internal/
    auth/
      ...
    metrics/
      ...
    model/
      ...
  cmd/
    api-server/
      main.go
    metrics-analyzer/
      main.go
    ...
  ... the project ' s other directories with non-Go code

• In case the server repository grows packages that become useful for sharing with other projects, it's best to split these off to separate modules.

Go models data input and output as a stream that flows from sources to targets. Data sources, such as files, network connections, or even some in-memory objects , can be modeled as streams of bytes from which data can be read or written to.

The most common usage of the fmt package is for writting to standard output and reading from standard input.

 type metalloid struct {
    name string
    number int32
    weight float64
}

func main () {
    var metalloids = [] metalloid {
        { "Boron" , 5 , 10.81 },
         ...
         { "Polonium" , 84 , 209.0 },
    }
     file , _ := os . Create ( "./metalloids.txt" )
     defer file . Close ()
     for _ , m := range metalloids {
        fmt . Fprintf (
            file ,
            "%-10s %-10d %-10.3f n " ,
            m . name , m . number , m . weight ,
        )
     }
}

The bufio package offers several functions to do buffered writing of IO streams using an `io.Writer interface.

In bytes package offers common primitives to achieve streaming IO on blocks of bytes stored in memory, represented by the bytes.Buffer byte. Since the bytes.Buffer type implements both io.Reader and io.Writer interfaces it is a great option to stream data into or out of memory using streaming IO primitives.

• Go's standard library comes packed with some great encoding and decoding packages covering a wide array of encoding schemes. Everything from CSV, XML, JSON, and even gob - a Go specific encoding format - is covered, and all of these packages are incredibly easy to get started with.

• Go offers built-in support for JSON encoding and decoding, including to and from built-in and custom data types.
• There are two types of data:
  • 结构化数据
  • Unstructured data
• Marshal and Unmarshal Structured data (Decoding JSON into structs)
  • json package will assign values only to fields found in the JSON; other fields will just keep their Go zero values.

 package main

import (
    "encoding/json"
    "fmt"
)

type Measurement struct {
    Height int
    Weight int
}

type Person struct {
    Name string
    Age  int
    Measurement Measurement // Nested object
}

func main () {
    bob := & Person {
        Name : "Bob" ,
        Age :  20 ,
    }
    bobRaw , _ := json . Marshal ( bob )
    fmt . Println ( string ( bobRaw ))

    // Raw data without Measurement field
    aliceRaw := [] byte ( `{"name": "Alice", "age": 23}` )
    var alice Person

    if err := json . Unmarshal ( aliceRaw , & alice ); err != nil {
        panic ( err )
    }
    fmt . Printf ( "%+v n " , alice )
}
// {"Name":"Bob","Age":20,"Measurement":{"Height":190,"Weight":75}}
// {Name:Alice Age:23 Measurement:{Height:0 Weight:0}}

• JSON struct tags - custom field names: Somtimes we want a different attribute name than the one provided in your JSON data.

 package main

import (
        "encoding/json"
        "fmt"
)

type Measurement struct {
        Height int `json:"height"`
        Weight int `json:"weight"`
}

type Person struct {
        Name        string      `json:"who"`
        Age         int         `json:"how old"`
        Measurement Measurement `json:"mm"`
}

func main () {
        bob := & Person {
                Name : "Bob" ,
                Age :  20 ,
        }
        bobRaw , _ := json . Marshal ( bob )
        fmt . Println ( string ( bobRaw ))

        // Raw data without Measurement field
        aliceRaw := [] byte ( `{"who": "Alice", "how old": 23, "mm": {"height": 150, "weight": 40}}` )
        var alice Person

        if err := json . Unmarshal ( aliceRaw , & alice ); err != nil {
                panic ( err )
        }
        fmt . Printf ( "%+v" , alice )
}
// {"who":"Bob","how old":20,"mm":{"height":0,"weight":0}}
// {Name:Alice Age:23 Measurement:{Height:150 Weight:40}}

• Decoding JSON to Maps - Unstructured Data

 package main

import (
    "encoding/json"
    "fmt"
)

func main () {
    // Raw data without Measurement field
    aliceRaw := [] byte ( `{"name": "Alice", "age": 23, "measurement": {"height": 150, "weight": 40}}` )
    var alice map [ string ] interface {}

    if err := json . Unmarshal ( aliceRaw , & alice ); err != nil {
        panic ( err )
    }
    // the object stored in the "mesurement" key is also stored
    // as a map[string]interface{} type, and its type is asserted
    // the interface{} type
    measurement := alice [ "measurement" ].( map [ string ] interface {})
    fmt . Printf ( "%+v n " , alice )
    fmt . Printf ( "%+v n " , measurement )
}

// map[age:23 measurement:map[height:150 weight:40] name:Alice]
// map[height:150 weight:40]

• Ignore empty fields: In some cases, we would want to ignore a field in our JSON output, if its value is empty. We can use the omitempty property.

 package main

import (
    "encoding/json"
    "fmt"
)

type Measurement struct {
    Height int `json:"height"`
    Weight int `json:"weight"`
    }

type Person struct {
    Name        string      `json:"name"`
    Age         int         `json:"age,omitempty"`
    Measurement Measurement `json:"measurement"`
}

func main () {
    bob := & Person {
        Name : "Bob" ,
        Measurement : Measurement {
            Height : 190 ,
            Weight : 75 ,
        },
    }
    bobRaw , _ := json . Marshal ( bob )
    fmt . Println ( string ( bobRaw ))
}

// Age field is ignored
// {"name":"Bob","measurement":{"height":190,"weight":75}}

• About the Advanced Encoding and Decoding techniques, you can check this blog.

NOTE : There are a lot more helpful things in tips-notes. You may want to check it out.

Go Web Example

A basic HTTP server has a few key jobs to take care of:

• Process dynamic request : Process incoming requests from users who browse the website, log into their accounts or post images.
• Serve static assets : Serve JavaScript, CSS & images to browsers to create a dynamic experience for the user.
• Accept connections : The HTTP Server must listen on a specific port to be able to accept connections from the Internet.

 package main

import (
    "fmt"
    "net/http"
)

func main () {
    // Process dynamic request
    http . HandleFunc ( "/" , func ( w http. ResponseWriter , r * http. Request ) {
        fmt . Fprintf ( w , "Welcome to my website!" )
    })

    // Serving static assets
    fs := http . FileServer ( http . Dir ( "static/" ))
    http . Handle ( "/static/" , http . StripPrefix ( "/static/" , fs ))

    // Accept connections
    http . ListenAndServe ( ":80" , nil )
}

A simple logging middleware.

 // basic-middleware.go
package main

import (
    "fmt"
    "log"
    "net/http"
)

func logging ( f http. HandlerFunc ) http. HandlerFunc {
    return func ( w http. ResponseWriter , r * http. Request ) {
        log . Println ( r . URL . Path )
        f ( w , r )
    }
}

func foo ( w http. ResponseWriter , r * http. Request ) {
    fmt . Fprintln ( w , "foo" )
}

func bar ( w http. ResponseWriter , r * http. Request ) {
    fmt . Fprintln ( w , "bar" )
}

func main () {
    http . HandleFunc ( "/foo" , logging ( foo ))
    http . HandleFunc ( "/bar" , logging ( bar ))

    http . ListenAndServe ( ":8080" , nil )
}

• A middleware in itself simple takes a http.HandleFunc as one of its parameters, wraps it & returns a new http.HandlerFunc for the server to call.

• Define a new type Middleware which makes it eventually easier to chain multiple middlewares together.

• How a new middleware is created, boilerplate code:

 func newMiddleware () Middleware {

    // Create a new Middleware
    middleware := func ( next http. HandlerFunc ) http. HandlerFunc {

        // Define the http.HandlerFunc which is called by the server eventually
        handler := func ( w http. ResponseWriter , r * http. Request ) {

            // ... do middleware things

            // Call the next middleware/handler in chain
            next ( w , r )
        }

        // Return newly created handler
        return handler
    }

    // Return newly created middleware
    return middleware
}

• Show me code! Ok, a full example is here:

 // advanced-middleware.go
package main

import (
    "fmt"
    "log"
    "net/http"
    "time"
)

type Middleware func (http. HandlerFunc ) http. HandlerFunc

// Logging logs all requests with its path & the time it took to process
func Logging () Middleware {

    // Create a new Middleware
    return func ( f http. HandlerFunc ) http. HandlerFunc {

        // Define the http.HandlerFunc
        return func ( w http. ResponseWriter , r * http. Request ) {

            // Do middleware things
            start := time . Now ()
            defer func () { log . Println ( r . URL . Path , time . Since ( start )) }()

            // Call the next middleware/handler in chain
            f ( w , r )
        }
    }
}

// Method ensures that url can only be requested with a specific method, else returns a 400 Bad Request
func Method ( m string ) Middleware {

    // Create a new Middleware
    return func ( f http. HandlerFunc ) http. HandlerFunc {

        // Define the http.HandlerFunc
        return func ( w http. ResponseWriter , r * http. Request ) {

            // Do middleware things
            if r . Method != m {
                http . Error ( w , http . StatusText ( http . StatusBadRequest ), http . StatusBadRequest )
                return
            }

            // Call the next middleware/handler in chain
            f ( w , r )
        }
    }
}

// Chain applies middlewares to a http.HandlerFunc
func Chain ( f http. HandlerFunc , middlewares ... Middleware ) http. HandlerFunc {
    for _ , m := range middlewares {
        f = m ( f )
    }
    return f
}

func Hello ( w http. ResponseWriter , r * http. Request ) {
    fmt . Fprintln ( w , "hello world" )
}

func main () {
    http . HandleFunc ( "/" , Chain ( Hello , Method ( "GET" ), Logging ()))
    http . ListenAndServe ( ":8080" , nil )
}

This section is mainly taken from: https://github.com/zalopay-oss/go-advanced/blob/master/ch3-rpc/ch3-01-rpc-go.md

• A remote procedure call (RPC) is when a computer program causes a procedure (subroutine) to execute in a different address space (commonly on another computer on a shared network), which is written as if it were a normal (local) procedure call, without the programmer explicitly writing the details for the remote interaction.

• Write a simple example with net/rpc library.

 // 13/rpc/rpcserver/main.go
package main

import (
	"log"
	"net"
	"net/rpc"
)

type HelloService struct {}

// Only methods that satisfy these criteria will be made available for remote access; other methods will be ignored:
// - the method's type is exported.
// - the method is exported.
// - the method has two arguments, both exported (or builtin) types.
// - the method's second argument is a pointer.
// - the method has return type error.
// func (t *T) MethodName(argType T1, replyType *T2) error
func ( p * HelloService ) Hello ( request string , reply * string ) error {
	* reply = "Hello " + request
	return nil
}

func main () {
	rpc . RegisterName ( "HelloService" , new ( HelloService ))
	listener , err := net . Listen ( "tcp" , ":8081" )
	if err != nil {
		log . Fatal ( "Listen TCP error:" , err )
	}

	log . Println ( "Server is ready" )

	for {
		// accept connection
		conn , err := listener . Accept ()
		if err != nil {
			log . Fatal ( "Accept error:" , err )
		}

		// serve client in another goroutine
		go func () {
			log . Println ( "Accept new client:" , conn . RemoteAddr ())
			rpc . ServeConn ( conn )
		}()
	}
}

 // 13/rpc/rpcclient/main.go
package main

import (
	"log"
	"net/rpc"
)

func main () {
	client , err := rpc . Dial ( "tcp" , "localhost:8081" )
	if err != nil {
		log . Fatal ( "Dialing error:" , err )
	}

	var reply string

	if err = client . Call ( "HelloService.Hello" , "Kien" , & reply ); err != nil {
		log . Fatal ( err )
	}

	log . Println ( reply )
}

• Run it:

 # Server
$ go run examples/13/rpc/rpcserver/main.go
2023/08/09 16:29:29 Server is ready
2023/08/09 16:29:30 Accept new client: 127.0.0.1:38728
2023/08/09 16:29:31 Accept new client: 127.0.0.1:38734

# Client
$ go run examples/13/rpc/rpcclient/main.go
2023/08/09 16:29:30 Hello Kien

$ go run examples/13/rpc/rpcclient/main.go
2023/08/09 16:29:31 Hello Kien

• Protocol Buffers, also referred as protobuf , is Google's language-neutral, platform-neutral, extensible mechanism for serializing structured data. Protocol Buffers are smaller, faster, and simpler that provides high performance than other standards such as XML and JSON.
• By using protocol buffers, you can define your structured data, then you generate source code for your choice of programming language using the protocol buffer compiler named protoc , to write and read your structured data using it. The current version of protocol buffers is proto3 . The proto3 version currently supports generated code in variety of languages including C++, Go, Java, Python, Ruby, and C#.
• Install protoc :

 # Ubuntu
# https://grpc.io/docs/protoc-installation/#install-using-a-package-manager
$ sudo apt install -y protobuf-compiler
# install go plugin
$ go install github.com/golang/protobuf/protoc-gen-go@latest

• Prepare hello.proto :

 // version proto3
syntax = "proto3" ;
// generated package name
package main ;
message String {
    string value = 1 ;
}

• Generate Golang source code:

• gRPC is a high performance, open-source remote procedure call (RPC) framework that can run anywhere. It enables client and server applications to communicate transparently, and makes it easier to build connected systems.

• The gRPC server implements the service interface and runs an RPC server to handle client calls to its service methods. On the client side, the client has a stub (referred to as just a client in some languages) that provides the same methods as the server.

• By default, gRPC uses Protocol Buffers as the Interface Definition Language (IDL) and as its underlying message interchange format.

This section is about the new packages be added.

Source: https://go.dev/blog/unique

• The standard library of Go 1.23 now includes the new unique package. The purposes behind this package is to enable the canonicalization of comparable values. In other words, this package lets you deduplicate values so that they point to a single, canonical, unique copy, while efficiently managing the canonical copies under the hood (interning).
• At high level, interning is very simple:
  • Interning is re-using objects of equal value on-demand instead of creating new objects.
  • For interning is a common application of interning, where many strings with identical values are needed in the same program. For example, if the name "Kien" appears 100 times, by interning you ensure only one "Kien" is actually allocated memory.

 var internPool map [ string ] string

// Intern returns a string that is equal to s but that may share storage with
// a string previously passed to Intern.
func Intern ( s string ) string {
    pooled , ok := internPool [ s ]
    if ! ok {
        // Clone the string in case it's part of some much bigger string.
        // This should be rare, if interning is being used well.
        pooled = strings . Clone ( s )
        internPool [ pooled ] = pooled
    }
    return pooled
}

• This implementation is super simple and works well enough for some cases, but it has a few problems:
  • It never removes strings from the pool.
  • It cannot be safely used by multiple goroutines concurrently.
  • It only works with strings, even though the idea is quite general.
• The new unique package introduces a function similar to Intern called Make. But it also differs from Intern in two important ways:
  • It accepts values of any comparable type.
  • It returns a wrapper value, a Handle[T], from which the canonical value can be retrieved. A Handle[T] has the property that two Handle[T] values are equal if and only if the values used to create them are equal. The comparison of two Handle[T] values is cheap: it comes down to a pointer comparison.
• A real-world example: Look no further than the net/netip package in the standard library, which interns values of type addrDetail , part of the netip.Addr structure.
  • Since many IP addresses are likely to use the same zone and this zone is part of their identity, it makes a lot of sense to canonicalize them.
  • The deduplication of zones reduces the average memory footprint of each netip.Addr , while the fact that they're canonicalized mean netip.Addr values are more efficient to compare, since comparing zone names becaomes a simple pointer comparison.

 // Addr represents an IPv4 or IPv6 address (with or without a scoped
// addressing zone), similar to net.IP or net.IPAddr.
type Addr struct {
    // Other irrelevant unexported fields...

    // Details about the address, wrapped up together and canonicalized.
    z unique. Handle [ addrDetail ]
}

// addrDetail indicates whether the address is IPv4 or IPv6, and if IPv6,
// specifies the zone name for the address.
type addrDetail struct {
    isV6   bool   // IPv4 is false, IPv6 is true.
    zoneV6 string // May be != "" if IsV6 is true.
}

var z6noz = unique . Make ( addrDetail { isV6 : true })

// WithZone returns an IP that's the same as ip but with the provided
// zone. If zone is empty, the zone is removed. If ip is an IPv4
// address, WithZone is a no-op and returns ip unchanged.
func ( ip Addr ) WithZone ( zone string ) Addr {
    if ! ip . Is6 () {
        return ip
    }
    if zone == "" {
        ip . z = z6noz
        return ip
    }
    ip . z = unique . Make ( addrDetail { isV6 : true , zoneV6 : zone })
    return ip
}

There is the page lists a few resources for programmers interested in learning about the Golang.

Oops, actually you can refer to awesome-go for a complete list.

• Official Golang Documetation
• Community-driven initiatives
• The Go programming language tour
• Go by example
• Effective Go
• Go Code Review Comments
• Uber's Golang guide
• Go styleguide
• Dave Cheney's Blog
  • Praticial Go: Real world advice for writing matintainable Go programs
• Go101
• Zalopay's Go-advanced
• Practical Go Lessions
• 100 Go Mistakes and How to Avoid Them

• How to write Go code
• Five suggestions for setting up a Go project

• vim-go
• GoLand, Jetbrains