nethttp和gin 路由

net/http 路由注册

func test1() {
    http.HandleFunc("/", func(w http.ResponseWriter, r *http.Request) {
        fmt.Fprintf(w, "Hello world!")
    })
    err := http.ListenAndServe(":9001", nil)
    if err != nil {
        log.Fatal("ListenAndServer:", err)
    }
}

在使用ListenAndServe这个方法时,系统就会给我们指派一个路由器,DefaultServeMux是系统默认使用的路由器,如果ListenAndServe这个方法的第2个参数传入nil,系统就会默认使用DefaultServeMux。当然,这里也可以传入自定义的路由器。

先看http.HandleFunc("/", ...),从HandleFunc方法点进去,如下:

func HandleFunc(pattern string, handler func(ResponseWriter, *Request)) {
    DefaultServeMux.HandleFunc(pattern, handler)
}

在这里调用了DefaultServeMuxHandleFunc方法,这个方法有两个参数,pattern是匹配的路由规则,handler表示这个路由规则对应的处理方法,并且这个处理方法有两个参数。

在我们书写的代码示例中,pattern对应/handler对应sayHello,当我们在浏览器中输入http://localhost:9001时,就会触发匿名函数。

我们再顺着DefaultServeMuxHandleFunc方法继续点下去,如下:

func (mux *ServeMux) HandleFunc(pattern string, handler func(ResponseWriter, *Request)) {
    if handler == nil {
        panic("http: nil handler")
    }
    mux.Handle(pattern, HandlerFunc(handler))
}

在这个方法中,路由器又调用了Handle方法,注意这个Handle方法的第2个参数,将之前传入的handler这个响应方法强制转换成了HandlerFunc类型。

这个HandlerFunc类型到底是个什么呢?如下:

type HandlerFunc func(ResponseWriter, *Request)

看来和我们定义的"/“的匿名函数的类型都差不多。但是!!! 这个HandlerFunc默认实现了ServeHTTP接口!这样HandlerFunc对象就有了ServeHTTP方法!如下:

// ServeHTTP calls f(w, r).
func (f HandlerFunc) ServeHTTP(w ResponseWriter, r *Request) {
    f(w, r)
}

接下来,我们返回去继续看muxHandle方法,也就是这段代码mux.Handle(pattern, HandlerFunc(handler))。这段代码做了哪些事呢?源码如下

// Handle registers the handler for the given pattern.
// If a handler already exists for pattern, Handle panics.
func (mux *ServeMux) Handle(pattern string, handler Handler) {
    mux.mu.Lock()
    defer mux.mu.Unlock()

    if pattern == "" {
        panic("http: invalid pattern")
    }
    if handler == nil {
        panic("http: nil handler")
    }
    if _, exist := mux.m[pattern]; exist {
        panic("http: multiple registrations for " + pattern)
    }

    if mux.m == nil {
        mux.m = make(map[string]muxEntry)
    }
    e := muxEntry{h: handler, pattern: pattern}
    mux.m[pattern] = e
    if pattern[len(pattern)-1] == '/' {
        mux.es = appendSorted(mux.es, e)
    }

    if pattern[0] != '/' {
        mux.hosts = true
    }
}

主要就做了一件事,向DefaultServeMuxmap[string]muxEntry中增加对应的路由规则和handler

map[string]muxEntry是个什么鬼?

  • map是一个字典对象,它保存的是key-value
  • [string]表示这个字典的keystring类型的,这个key值会保存我们的路由规则。
  • muxEntry是一个实例对象,这个对象内保存了路由规则对应的处理方法。
  • mux.es 为模糊匹配 有长倒短排序 比如有路由/hello/ 访问/hello/world 时没有路由 会落到/hello/

找到相应代码,如下:

// 路由器
type ServeMux struct {
    mu    sync.RWMutex
    m     map[string]muxEntry
    es    []muxEntry // slice of entries sorted from longest to shortest.
    hosts bool       // whether any patterns contain hostnames
}

type muxEntry struct {
    h       Handler
    pattern string
}

// 路由响应方法
type Handler interface {
    ServeHTTP(ResponseWriter, *Request)
}

net/http 运行

第二部分主要就是研究这句代码err := http.ListenAndServe(":9001",nil),也就是ListenAndServe这个方法。从这个方法点进去,如下:

func ListenAndServe(addr string, handler Handler) error {
    server := &Server{Addr: addr, Handler: handler}
    return server.ListenAndServe()
}

在这个方法中,初始化了一个server对象,然后调用这个server对象的ListenAndServe方法,在这个方法中,如下:

func (srv *Server) ListenAndServe() error {
    if srv.shuttingDown() {
        return ErrServerClosed
    }
    addr := srv.Addr
    if addr == "" {
        addr = ":http"
    }
    ln, err := net.Listen("tcp", addr)
    if err != nil {
        return err
    }
    return srv.Serve(ln)
}

在这个方法中,调用了net.Listen("tcp", addr),也就是底层用TCP协议搭建了一个服务,然后监控我们设置的端口。

代码的最后,调用了srvServe方法,如下:

func (srv *Server) Serve(l net.Listener) error {
    if fn := testHookServerServe; fn != nil {
        fn(srv, l) // call hook with unwrapped listener
    }

    origListener := l
    l = &onceCloseListener{Listener: l}
    defer l.Close()

    if err := srv.setupHTTP2_Serve(); err != nil {
        return err
    }

    if !srv.trackListener(&l, true) {
        return ErrServerClosed
    }
    defer srv.trackListener(&l, false)

    baseCtx := context.Background()
    if srv.BaseContext != nil {
        baseCtx = srv.BaseContext(origListener)
        if baseCtx == nil {
            panic("BaseContext returned a nil context")
        }
    }

    var tempDelay time.Duration // how long to sleep on accept failure

    ctx := context.WithValue(baseCtx, ServerContextKey, srv)
    for {
        rw, err := l.Accept()
        if err != nil {
            select {
            case <-srv.getDoneChan():
                return ErrServerClosed
            default:
            }
            if ne, ok := err.(net.Error); ok && ne.Temporary() {
                if tempDelay == 0 {
                    tempDelay = 5 * time.Millisecond
                } else {
                    tempDelay *= 2
                }
                if max := 1 * time.Second; tempDelay > max {
                    tempDelay = max
                }
                srv.logf("http: Accept error: %v; retrying in %v", err, tempDelay)
                time.Sleep(tempDelay)
                continue
            }
            return err
        }
        connCtx := ctx
        if cc := srv.ConnContext; cc != nil {
            connCtx = cc(connCtx, rw)
            if connCtx == nil {
                panic("ConnContext returned nil")
            }
        }
        tempDelay = 0
        c := srv.newConn(rw)
        c.setState(c.rwc, StateNew, runHooks) // before Serve can return
        go c.serve(connCtx)
    }
}

最后3段代码比较重要,也是Go语言支持高并发的体现,如下:

c := srv.newConn(rw)
c.setState(c.rwc, StateNew, runHooks) // before Serve can return
go c.serve(connCtx)

上面那一大坨代码,总体意思是进入方法后,首先开了一个for循环,在for循环内时刻Accept请求,请求来了之后,会为每个请求创建一个Conn,然后单独开启一个goroutine,把这个请求的数据当做参数扔给这个Conn去服务:go c.serve()。用户的每一次请求都是在一个新的goroutine去服务,每个请求间相互不影响。

connserve方法中,有一句代码很重要,如下:

serverHandler{c.server}.ServeHTTP(w, w.req)

表示serverHandler也实现了ServeHTTP接口,ServeHTTP方法实现如下:

func (sh serverHandler) ServeHTTP(rw ResponseWriter, req *Request) {
    handler := sh.srv.Handler
    if handler == nil {
        handler = DefaultServeMux
    }
    if req.RequestURI == "*" && req.Method == "OPTIONS" {
        handler = globalOptionsHandler{}
    }

    if req.URL != nil && strings.Contains(req.URL.RawQuery, ";") {
        var allowQuerySemicolonsInUse int32
        req = req.WithContext(context.WithValue(req.Context(), silenceSemWarnContextKey, func() {
            atomic.StoreInt32(&allowQuerySemicolonsInUse, 1)
        }))
        defer func() {
            if atomic.LoadInt32(&allowQuerySemicolonsInUse) == 0 {
                sh.srv.logf("http: URL query contains semicolon, which is no longer a supported separator; parts of the query may be stripped when parsed; see golang.org/issue/25192")
            }
        }()
    }

    handler.ServeHTTP(rw, req)
}

在这里如果handler为空(这个handler就可以理解为是我们自定义的路由器),就会使用系统默认的DefaultServeMux,代码的最后调用了DefaultServeMuxServeHTTP()

func (mux *ServeMux) ServeHTTP(w ResponseWriter, r *Request) {
    if r.RequestURI == "*" {
        if r.ProtoAtLeast(1, 1) {
            w.Header().Set("Connection", "close")
        }
        w.WriteHeader(StatusBadRequest)
        return
    }
    h, _ := mux.Handler(r)  //这里返回的h是Handler接口对象
    h.ServeHTTP(w, r)  //调用Handler接口对象的ServeHTTP方法实际上就调用了我们定义的sayHello方法
}
func (mux *ServeMux) Handler(r *Request) (h Handler, pattern string) {

    // CONNECT requests are not canonicalized.
    if r.Method == "CONNECT" {
        // If r.URL.Path is /tree and its handler is not registered,
        // the /tree -> /tree/ redirect applies to CONNECT requests
        // but the path canonicalization does not.
        if u, ok := mux.redirectToPathSlash(r.URL.Host, r.URL.Path, r.URL); ok {
            return RedirectHandler(u.String(), StatusMovedPermanently), u.Path
        }

        return mux.handler(r.Host, r.URL.Path)
    }

    // All other requests have any port stripped and path cleaned
    // before passing to mux.handler.
    host := stripHostPort(r.Host)
    path := cleanPath(r.URL.Path)

    // If the given path is /tree and its handler is not registered,
    // redirect for /tree/.
    if u, ok := mux.redirectToPathSlash(host, path, r.URL); ok {
        return RedirectHandler(u.String(), StatusMovedPermanently), u.Path
    }

    if path != r.URL.Path {
        _, pattern = mux.handler(host, path)
        u := &url.URL{Path: path, RawQuery: r.URL.RawQuery}
        return RedirectHandler(u.String(), StatusMovedPermanently), pattern
    }

    return mux.handler(host, r.URL.Path)
}


func (mux *ServeMux) handler(host, path string) (h Handler, pattern string) {
    mux.mu.RLock()
    defer mux.mu.RUnlock()

    // Host-specific pattern takes precedence over generic ones
    if mux.hosts {
        h, pattern = mux.match(host + path)
    }
    if h == nil {
        h, pattern = mux.match(path)
    }
    if h == nil {
        h, pattern = NotFoundHandler(), ""
    }
    return
}

func (mux *ServeMux) match(path string) (h Handler, pattern string) {
    // Check for exact match first.
    v, ok := mux.m[path]
    if ok {
        return v.h, v.pattern
    }

    // Check for longest valid match.  mux.es contains all patterns
    // that end in / sorted from longest to shortest.
    for _, e := range mux.es {
        if strings.HasPrefix(path, e.pattern) {
            return e.h, e.pattern
        }
    }
    return nil, ""
}

它会根据用户请求的URL到路由器里面存储的map中匹配,匹配成功就会返回存储的handler,调用这个handlerServeHTTP()就可以执行到相应的处理方法了,这个处理方法实际上就是我们刚开始定义的sayHello(),只不过这个sayHello()HandlerFunc又包了一层,因为HandlerFunc实现了ServeHTTP接口,所以在调用HandlerFunc对象的ServeHTTP()时,实际上在ServeHTTP ()的内部调用了我们的sayHello()

总结

  1. 调用http.ListenAndServe(":9090",nil)
  2. 实例化server
  3. 调用serverListenAndServe()
  4. 调用serverServe方法,开启for循环,在循环中Accept请求
  5. 对每一个请求实例化一个Conn,并且开启一个goroutine为这个请求进行服务go c.serve()
  6. 读取每个请求的内容c.readRequest()
  7. 调用serverHandlerServeHTTP(),如果handler为空,就把handler设置为系统默认的路由器DefaultServeMux
  8. 调用handlerServeHTTP() =>实际上是调用了DefaultServeMuxServeHTTP()
  9. ServeHTTP()中会调用路由对应处理handler
  10. 在路由对应处理handler中会执行sayHello()

有一个需要注意的点: DefaultServeMux和路由对应的处理方法handler都实现了ServeHTTP接口,他们俩都有ServeHTTP方法,但是方法要达到的目的不同,在DefaultServeMuxServeHttp()里会执行路由对应的处理handlerServeHttp()

自定义个简单的路由

package mux

import (
    "net/http"
    "strings"
)

type muxEntry struct {
    h TesthandleFunc
}

type TesthandleFunc func(http.ResponseWriter, *http.Request)

type TestHandler struct {
    routes map[string]map[string]muxEntry
}


func (h *TestHandler) ServeHTTP(w http.ResponseWriter, r *http.Request) {
    method := strings.ToUpper(r.Method)
    path := r.URL.Path
    if route, ok := h.routes[method]; ok {
        if entry, ok := route[path]; ok {
            entry.h(w, r)
            return
        }
    }
    w.WriteHeader(http.StatusNotFound)
}

func Newhandler() *TestHandler {
    return &TestHandler{routes: make(map[string]map[string]muxEntry)}
}

func (h *TestHandler) Handle(method, path string, handler TesthandleFunc) {
    method = strings.ToUpper(method)
    if _, ok := h.routes[method]; !ok {
        h.routes[method] = make(map[string]muxEntry)
    }
    h.routes[method][path] = muxEntry{handler}
}
package main

import (
    "fmt"
    "net/http"
    "study/mux"
)

func main() {
    handler := mux.Newhandler()
    handler.Handle("GET", "/hello", func(rw http.ResponseWriter, r *http.Request) {
        rw.Write([]byte("Hello World"))
    })
    handler.Handle("Post", "/hello/world", func(rw http.ResponseWriter, r *http.Request) {
        fmt.Fprintln(rw, "你好")
    })
    http.ListenAndServe(":9002", handler)
}

自定义context

package router

import (
    "encoding/json"
    "net/http"
    "strings"
)

type Context struct {
    w http.ResponseWriter
    r *http.Request
}

func (c *Context) Json(code int, v interface{}) {
    c.w.Header().Set("Content-Type", "application/json")
    c.w.WriteHeader(code)
    s, _ := json.Marshal(v)
    c.w.Write(s)
}

type Routerfunc func(c *Context)

type RouterHandler struct {
    routes map[string]map[string]Routerfunc
}

func NewRouterHandler() *RouterHandler {
    return &RouterHandler{routes: make(map[string]map[string]Routerfunc)}
}

func (h *RouterHandler) ServeHTTP(w http.ResponseWriter, r *http.Request) {
    method := strings.ToUpper(r.Method)
    path := r.URL.Path
    c := &Context{w: w, r: r}
    if route, ok := h.routes[method]; ok {
        if h, ok := route[path]; ok {
            h(c)
            return
        }
    }
    w.WriteHeader(http.StatusNotFound)
}

func (h *RouterHandler) Handle(method, path string, handler Routerfunc) {
    method = strings.ToUpper(method)
    if _, ok := h.routes[method]; !ok {
        h.routes[method] = make(map[string]Routerfunc)
    }
    h.routes[method][path] = handler
}

func (r *RouterHandler) Run(addr string) error {
    return http.ListenAndServe(addr, r)
}

Gin

type Engine struct {
    RouterGroup

    pool     sync.Pool
    trees    methodTrees
}// trie

type RouterGroup struct {
    basePath string
    engine   *Engine
}

func (engine *Engine) ServeHTTP(w http.ResponseWriter, req *http.Request) {
    c := engine.pool.Get().(*Context) // 从pool 拿出一个context
    c.writermem.reset(w) // 记录http.ResponseWriter 及 *http.Request
    c.Request = req
    c.reset() // 重置上一个留下的值

    engine.handleHTTPRequest(c)

    engine.pool.Put(c) // 把用完的context放回池子
}
// get: /bac

添加路由

func (group *RouterGroup) handle(httpMethod, relativePath string, handlers HandlersChain) IRoutes {
    absolutePath := group.calculateAbsolutePath(relativePath)
    handlers = group.combineHandlers(handlers)
    group.engine.addRoute(httpMethod, absolutePath, handlers)
    return group.returnObj()
}

Context

type Context struct {
    Request   *http.Request
    Writer    ResponseWriter

    Params   Params
    handlers HandlersChain
    index    int8
    fullPath string

    engine       *Engine
    params       *Params
    skippedNodes *[]skippedNode

    // This mutex protect Keys map
    mu sync.RWMutex

    // Keys is a key/value pair exclusively for the context of each request.
    Keys map[string]interface{}

    // Errors is a list of errors attached to all the handlers/middlewares who used this context.
    Errors errorMsgs

    // Accepted defines a list of manually accepted formats for content negotiation.
    Accepted []string

    // queryCache use url.ParseQuery cached the param query result from c.Request.URL.Query()
    queryCache url.Values

    // formCache use url.ParseQuery cached PostForm contains the parsed form data from POST, PATCH,
    // or PUT body parameters.
    formCache url.Values

    // SameSite allows a server to define a cookie attribute making it impossible for
    // the browser to send this cookie along with cross-site requests.
    sameSite http.SameSite
}

func (c *Context) Next() {
    c.index++
    for c.index < int8(len(c.handlers)) {
        c.handlers[c.index](c)
        c.index++
    }
}
func (engine *Engine) handleHTTPRequest(c *Context) {
    httpMethod := c.Request.Method
    rPath := c.Request.URL.Path
    unescape := false
    if engine.UseRawPath && len(c.Request.URL.RawPath) > 0 {
        rPath = c.Request.URL.RawPath
        unescape = engine.UnescapePathValues
    }

    if engine.RemoveExtraSlash {
        rPath = cleanPath(rPath)
    }

    // Find root of the tree for the given HTTP method
    t := engine.trees
    for i, tl := 0, len(t); i < tl; i++ {
        if t[i].method != httpMethod {
            continue
        }
        root := t[i].root
        // Find route in tree
        value := root.getValue(rPath, c.params, c.skippedNodes, unescape)
        if value.params != nil {
            c.Params = *value.params
        }
        if value.handlers != nil {
            c.handlers = value.handlers
            c.fullPath = value.fullPath
            c.Next()
            c.writermem.WriteHeaderNow()
            return
        }
        if httpMethod != http.MethodConnect && rPath != "/" {
            if value.tsr && engine.RedirectTrailingSlash {
                redirectTrailingSlash(c)
                return
            }
            if engine.RedirectFixedPath && redirectFixedPath(c, root, engine.RedirectFixedPath) {
                return
            }
        }
        break
    }

    if engine.HandleMethodNotAllowed {
        for _, tree := range engine.trees {
            if tree.method == httpMethod {
                continue
            }
            if value := tree.root.getValue(rPath, nil, c.skippedNodes, unescape); value.handlers != nil {
                c.handlers = engine.allNoMethod
                serveError(c, http.StatusMethodNotAllowed, default405Body)
                return
            }
        }
    }
    c.handlers = engine.allNoRoute
    serveError(c, http.StatusNotFound, default404Body)
}