本文基于
koa 3.0.0-alpha.1版本源码进行剖析
因为
koa的源码量非常少,然而体现的思维十分经典和难以记忆,如果忽然要手写koa代码,可能还不肯定能很快写进去,因而本文将集中于如何了解以及记忆koa的代码本文一些代码块为了演示不便,可能有一些语法排列谬误,因而本文所有代码均能够视为伪代码
文章内容
- 从
0到1推导koa 3.0.0-alpha.1版本源码的实现,一步一步欠缺简化版koa的手写逻辑 - 剖析罕用中间件
koa-router的源码以及进行对应的手写 - 剖析罕用中间件
koa-bodyparser的源码以及进行对应的手写
外围代码剖析&手写
2.1 koa-compose
const Koa = require('koa');
const app = new Koa();
app.use(async (ctx, next) => {
console.log("中间件1 start");
await next();
console.log("中间件1 end");
});
app.use(async (ctx, next) => {
console.log("中间件2 start");
await next();
console.log("中间件2 end");
});
app.use(async (ctx, next) => {
console.log("中间件3 start");
await next();
console.log("中间件3 end");
});
app.listen(3000);下面代码块中间件运行流程如下所示
下面的运行流程看起来就跟咱们平时开发不太一样,咱们能够看一个类似的场景,比方上面
- 咱们在
fn1()中执行一系列的业务逻辑 - 然而咱们在
fn1()遇到了await fn2(),因而咱们得期待fn2()执行结束后能力持续前面的业务逻辑
function fn1() {
console.log("fn1执行业务逻辑1");
await fn2();
console.log("fn1执行业务逻辑2")
}async function fn2() {
console.log("fn2执行业务逻辑1");
}咱们将fn2作为参数传入
async function fn2() {
console.log("fn2执行业务逻辑1");
}
function fn1(fn2) {
console.log("fn1执行业务逻辑1");
await fn2();
console.log("fn1执行业务逻辑2")
}如果咱们有fn3、fn4呢?
async function fn1(fn2) {
console.log("fn1执行业务逻辑1");
await fn2();
console.log("fn1执行业务逻辑2")
}
async function fn2(fn3) {
console.log("fn2执行业务逻辑1");
await fn3();
console.log("fn2执行业务逻辑2")
}
async function fn3(fn4) {
console.log("fn3执行业务逻辑1");
await fn4();
console.log("fn3执行业务逻辑2")
}
async function fn4() {
console.log("fn4执行业务逻辑1");
console.log("fn4执行业务逻辑2")
}那如果咱们还有fn5、fn6….呢?
咱们应用怎么的逻辑进行这种function的嵌套?
咱们能够从下面代码发现,每一个fnX()传递的都是上一个fn(X+1)()
2.1.1 应用middleware遍历所有fn
咱们能够先应用一个数组进行fn的增加
middleware.push(fn);当咱们取出一个fn时,咱们应该传入下一个fn,即
let fn = middleware[i];
fn(middleware[i+1]);如果咱们想要程序传入context
let fn = middleware[i];
fn(context, middleware[i+1]);应用middleware整合下面的逻辑,如上面所示
- 咱们应用
app.use((ctx, next))传入的next()须要强制返回一个Promise,因为它能够应用await,因而咱们应用Promise.resolve()包裹fn()返回的值,避免返回的不是Promise - 在调用
fn()的时候,会传入下一个中间件作为第二个参数:middleware[i + 1]
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
function dispatch(i) {
let fn = middleware[i];
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, middleware[i + 1]));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.1.2 链式调用
async function fn1(fn2) {
console.log("fn1执行业务逻辑1");
await fn2();
console.log("fn1执行业务逻辑2")
}
async function fn2(fn3) {
console.log("fn2执行业务逻辑1");
await fn3();
console.log("fn2执行业务逻辑2")
}
async function fn3() {
console.log("fn3执行业务逻辑1");
console.log("fn3执行业务逻辑2")
}咱们如何实现
fn1->fn2->fn3的链式调用呢?
fn1(fn2(fn3))回到咱们下面实现的koa源码
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
function dispatch(i) {
let fn = middleware[i];
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, middleware[i + 1]));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
console.log("fn2执行业务逻辑2")
});
app.listen(200);如下面所示,咱们执行了fn1(context, fn2),然而咱们fn2()并没有传入fn3,这导致了链式调用被中断了,而且fn2()也不肯定会返回Promise,因而咱们须要对上面代码进行调整
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
function dispatch(i) {
let fn = middleware[i];
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch(i + 1)));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);fn(context, middleware[i + 1])调整为fn(context, dispatch(i + 1))
这样咱们就能够实现
fn2()返回的是Promise.resolve(),无论fn2()返回什么,都是一个Promisefn2(context, dispatch(i + 1))的第二个参数传入了fn3,并且fn3是一个Promise
2.1.3 细节优化
2.1.3.1 app.use返回this
app.use()返回本人自身,能够应用链式调用
let app = {
use(fn) {
middleware.push(fn);
return this;
}
}
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
}).use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
console.log("fn2执行业务逻辑2")
});2.1.3.2 dispatch()返回办法
dispatch(i + 1)返回的是一个执行结束的Promise状态,不是一个办法,须要改成bind
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
function dispatch(i) {
let fn = middleware[i];
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.1.3.3 最初一个中间件返回空的Promise.resolve
最初一个中间件调用next()时没有执行的办法,应该间接返回一个空的办法,比方下面代码中
console.log("fn2执行业务逻辑1")await next(): 此时的next()应该是一个空的Promise办法console.log("fn2执行业务逻辑2")
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
function dispatch(i) {
let fn = middleware[i];
if (i === middleware.length) {
return Promise.resolve();
}
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.1.3.4 阻止中间件中反复调用next()
阻止一个中间件反复调用next()办法,应用index记录以后的i,如果发现i<=index,阐明反复调用了某一个中间件的next()办法
let middleware = [];
let context = {};
let app = {
use(fn) {
middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return new Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
return Promise.resolve();
}
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
}
return dispatch(0);
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.1.3.5 欠缺错误处理逻辑
- 反复调用
next()抛出谬误 - 执行
fn()过程中出错
将dispatch()的外层再包裹一个新的function(),而后咱们就能够应用这个function()进行对立的then()和catch()解决,即上面代码中的
let fn = compose(this.middleware)fn().then(() => {}).catch(err => {})
function compose(middleware) {
// 返回也是一个Promise,可能是Promise.resolve(),也有可能是Promise.reject()
return function (context) {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
return Promise.resolve();
}
try {
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
} catch (err) {
return Promise.reject(err)
}
}
return dispatch(0);
}
}
let app = {
middleware: [],
use(fn) {
this.middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
let fn = compose(this.middleware);
let context = {};
fn(context).then(() => {
// 失常执行最终触发
console.log("fn执行结束!");
}).catch(error => {
console.error("fn执行谬误", error);
});
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);运行下面代码,失去的后果为:
2.1.3.6 兼容compose传入next()办法
compose()返回的function(context)减少传入参数next,能够在内部进行定义传入,而后判断
- 当
i等于middleware.length时,middleware[i]必定为空,判断最初一个next()是否为空 - 如果最初一个
next()不为空,则继续执行最初一次next() - 如果最初一个
next()为空,则间接返回空的Promise.resolve,跟下面咱们解决i等于middleware.length时的逻辑一样
function compose(middleware) {
// 返回也是一个Promise,可能是Promise.resolve(),也有可能是Promise.reject()
return function (context, next) {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
// middleware[i]必定为空,判断最初一个next()是否为空
// 如果不为空,则继续执行最初一次
// 如果为空,则返回Promise.resolve()
fn = next;
}
if (!fn) {
return Promise.resolve();
}
try {
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
} catch (err) {
return Promise.reject(err)
}
}
return dispatch(0);
}
}
let app = {
middleware: [],
use(fn) {
this.middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
let fn = compose(this.middleware);
let context = {};
const next = function () {
console.log("最初一个next()!");
}
fn(context, next).then(() => {
// 失常执行最终触发
console.log("fn执行结束!");
}).catch(error => {
console.error("fn执行谬误", error);
});
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.1.3.7 解决middleware不为数组时谬误的抛出
function compose(middleware) {
if (!Array.isArray(middleware)) throw new TypeError('Middleware stack must be an array!')
for (const fn of middleware) {
if (typeof fn !== 'function') throw new TypeError('Middleware must be composed of functions!')
}
// 返回也是一个Promise,可能是Promise.resolve(),也有可能是Promise.reject()
return function (context, next) {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
// middleware[i]必定为空,判断最初一个next()是否为空
// 如果不为空,则继续执行最初一次
// 如果为空,则返回Promise.resolve()
fn = next;
}
if (!next) {
return Promise.resolve();
}
try {
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
} catch (err) {
return Promise.reject(err)
}
}
return dispatch(0);
}
}
let app = {
middleware: [],
use(fn) {
this.middleware.push(fn);
return this;
},
listen(...args) {
this.callback();
},
callback() {
let fn = compose(this.middleware);
let context = {};
const next = function () {
console.log("最初一个next()!");
}
fn(context, next).then(() => {
// 失常执行最终触发
console.log("fn执行结束!");
}).catch(error => {
console.error("fn执行谬误", error);
});
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);至此,咱们曾经齐全实现了官网
koa-compose的残缺代码!
2.2 Node.js原生http模块
Koa是基于中间件模式的HTTP服务框架,底层原理就是封装了Node.js的http原生模块
在下面实现
koa-compose中间件的根底上,咱们减少Node.js的http原生模块,根本就是Koa的外围代码的实现
2.2.1 原生代码示例
const http = require('http');
const server = http.createServer((req, res)=> {
res.end(`this page url = ${req.url}`);
});
server.listen(3001, function() {
console.log("the server is started at port 3001")
})2.2.2 减少原生http模块的相干代码
欠缺listen()和callback()的相干办法,减少原生http模块的相干代码
function compose(middleware) {
if (!Array.isArray(middleware)) throw new TypeError('Middleware stack must be an array!')
for (const fn of middleware) {
if (typeof fn !== 'function') throw new TypeError('Middleware must be composed of functions!')
}
// 返回也是一个Promise,可能是Promise.resolve(),也有可能是Promise.reject()
return function (context, next) {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
// middleware[i]必定为空,判断最初一个next()是否为空
// 如果不为空,则继续执行最初一次
// 如果为空,则返回Promise.resolve()
fn = next;
}
if (!next) {
return Promise.resolve();
}
try {
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
} catch (err) {
return Promise.reject(err)
}
}
return dispatch(0);
}
}
let app = {
middleware: [],
use(fn) {
this.middleware.push(fn);
return this;
},
listen(...args) {
const server = http.createServer(this.callback());
return server.listen(...args);
},
callback() {
let fn = compose(this.middleware);
return (req, res) => {
let context = {};
this.handleRequest(context, fn);
}
},
handleRequest(context, fn) {
const next = function () {
console.log("最初一个next()!");
}
fn(context, next).then(() => {
// 失常执行最终触发
console.log("fn执行结束!");
}).catch(error => {
console.error("fn执行谬误", error);
});
}
};
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2")
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2")
});
app.listen(200);2.3 初始化context
将app={}的模式欠缺为class Koa的模式,而后在构造函数中初始化context、request、response的初始化,在callback()进行http.createServer()回调函数req和res的赋值
createContext(req, res) {
const context = Object.create(this.context);
const request = (context.request = Object.create(this.request));
const response = (context.response = Object.create(this.response));
context.app = request.app = response.app = this;
context.req = request.req = response.req = req;
context.res = request.res = response.res = res;
request.ctx = response.ctx = context;
request.response = response;
response.request = request;
context.originalUrl = request.originalUrl = req.url;
context.state = {};
return context;
}残缺代码如下所示
const context = require("./context.js");
const request = require("./request.js");
const response = require("./response.js");
function compose(middleware) {
if (!Array.isArray(middleware)) throw new TypeError("Middleware stack must be an array!");
for (const fn of middleware) {
if (typeof fn !== "function") throw new TypeError("Middleware must be composed of functions!");
}
// 返回也是一个Promise,可能是Promise.resolve(),也有可能是Promise.reject()
return function (context, next) {
// 要求每一个fn返回都是一个Promise
let index = -1;
function dispatch(i) {
if (i <= index) {
return Promise.reject(new Error("next()反复调用屡次"));
}
index = i;
let fn = middleware[i];
if (i === middleware.length) {
// middleware[i]必定为空,判断最初一个next()是否为空
// 如果不为空,则继续执行最初一次
// 如果为空,则返回Promise.resolve()
fn = next;
}
if (!next) {
return Promise.resolve();
}
try {
// 可能返回只是一个一般的数据,因而须要应用Promise.resolve()进行包裹返回一个Promise数据
return Promise.resolve(fn(context, dispatch.bind(null, i + 1)));
} catch (err) {
return Promise.reject(err);
}
}
return dispatch(0);
};
}
class Koa {
constructor() {
this.middleware = [];
this.context = Object.create(context);
this.request = Object.create(request);
this.response = Object.create(response);
}
createContext(req, res) {
const context = Object.create(this.context);
const request = (context.request = Object.create(this.request));
const response = (context.response = Object.create(this.response));
context.app = request.app = response.app = this;
context.req = request.req = response.req = req;
context.res = request.res = response.res = res;
request.ctx = response.ctx = context;
request.response = response;
response.request = request;
context.originalUrl = request.originalUrl = req.url;
context.state = {};
return context;
}
use(fn) {
this.middleware.push(fn);
return this;
}
listen(...args) {
const server = http.createServer(this.callback());
return server.listen(...args);
}
callback() {
let fn = compose(this.middleware);
return (req, res) => {
let context = this.createContext(req, res);
this.handleRequest(context, fn);
};
}
handleRequest(context, fn) {
const next = function () {
console.log("最初一个next()!");
};
fn(context, next)
.then(() => {
// 失常执行最终触发
console.log("fn执行结束!");
})
.catch((error) => {
console.error("fn执行谬误", error);
});
}
}
const app = new Koa();
app.use(async (ctx, next) => {
console.log("fn1执行业务逻辑1");
await next();
await next();
console.log("fn1执行业务逻辑2");
});
app.use(async (ctx, next) => {
console.log("fn2执行业务逻辑1");
await next();
console.log("fn2执行业务逻辑2");
});
app.listen(200);
2.4 欠缺响应数据的逻辑
由下面初始化context的代码能够晓得,咱们曾经将http原生模块的req和res都放入到context中,因而咱们在执行结束中间件后,咱们应该对context.res进行解决,返回对应的值
handleRequest(context, fn) {
const next = function () {
console.log("最初一个next()!");
};
const handleResponse = () => {
return this.handleResponse(context);
};
fn(context, next)
.then(handleResponse)
.catch((error) => {
console.error("fn执行谬误", error);
});
}
handleResponse(ctx) {
const res = ctx.res;
let body = ctx.body;
if (!body) {
return res.end();
}
if (typeof body !== "string") {
body = JSON.stringify(body);
}
res.end(body);
}至此,咱们实现了一个简化版本的
Koa,残缺代码放在github mini-koa
常见中间件剖析&手写
3.1 koa-router
3.1.1 不应用koa-router
在不应用koa-router中间件时,咱们须要手动依据ctx.request.url去判断路由,如上面代码所示
const Koa = require("koa");
const fs = require("fs");
const app = new Koa();
function readFile(path) {
return new Promise((resolve, reject) => {
let htmlUrl = `../front/${path}`;
fs.readFile(htmlUrl, "utf-8", (err, data) => {
if (err) {
reject(err);
} else {
resolve(data);
}
});
});
}
async function parseUrl(url) {
let base = "404.html";
switch (url) {
case "/":
base = "index.html";
break;
case "/login.html":
base = "login.html";
break;
case "/home.html":
base = "home.html";
break;
}
// 从本地读取出该门路下html文件的内容,而后返回给客户端
const data = await readFile(base);
return data;
}
app.use(async (ctx) => {
let url = ctx.request.url;
// 判断这个url是哪一个申请
const htmlContent = await parseUrl(url);
ctx.status = 200;
ctx.body = htmlContent;
});
app.listen(3000);
console.log("[demo] route is starting at port 3000");因而咱们手写koa-router时,咱们须要关注几个问题:
- 依据
ctx.path判断是否合乎注册的路由,如果合乎,则触发注册的办法 -
咱们须要依据
path、methods进行对应数据结构的构建3.1.2 应用koa-router的具体示例
const app = new Koa();
const router = new Router();
router.get("/", (ctx, next) => {
// ctx.router available
});
router.get("/home", (ctx, next) => {
// ctx.router available
});
app.use(router.routes());3.1.3 依据示例实现koa-router
依据methods初始化所有办法,造成this["get"]、this["put"]的数据结构,提供给内部调用注册路由
当有新的申请产生时,会触发中间件的逻辑执行,会依据目前ctx.path和ctx.method去寻找之前是否有注册过的门路,如果有则触发注册门路的callback进行逻辑的执行
function Router(opts) {
this.register = function (path, methods, callback, opts) {
this.stack.push({
path,
methods,
middleware: callback,
opts,
});
return this;
};
this.routes = function () {
// 返回所有注册的路由
return async (ctx, next) => {
// 每次执行中间件时,判断是否有合乎register()的路由
const path = ctx.path;
const method = ctx.method.toUpperCase();
let callback;
for (const item of this.stack) {
if (path === item.path && item.methods.indexOf(method) >= 0) {
// 找到对应的路由
callback = item.middleware;
break;
}
}
if (callback) {
callback(ctx, next);
return;
}
await next();
};
};
this.opts = opts || {};
this.methods = this.opts.methods || ["HEAD", "OPTIONS", "GET", "PUT", "PATCH", "POST", "DELETE"];
this.stack = [];
// 依据methods初始化所有办法,造成this["get"]、this["put"]的数据结构
for (const _method of this.methods) {
this[_method.toLowerCase()] = this[_method] = function (path, callback) {
this.register(path, [_method], callback);
};
}
}3.2 koa-bodyparser
该中间件能够简化申请体的解析流程
当咱们不应用
koa-bodyparser时,如上面所示
3.2.1 不应用koa-bodyparser
GET申请
query是格式化好的参数对象,比方query={a:1, b:2}querystring是申请字符串,比方querystring="a=1&b=2"
let request = ctx.request;
let query = request.query;
let queryString = request.querystring;
// 也能够间接省略request,const {query, querystring} = requestPOST申请
没有封装具体的办法,须要手动解析ctx.req这个原生的node.js对象
如上面例子所示,ctx.req获取到formData为"userName=22&nickName=22323&email=32323"
咱们须要将formData解析为{userName: 22, nickName: 22323, email: 32323}
home.post("b", async (ctx) => {
const body = await parseRequestPostData(ctx);
ctx.body = body;
});
async function parseRequestPostData(ctx) {
return new Promise((resolve, reject) => {
const req = ctx.req;
let postData = "";
req.addListener("data", (data) => {
postData = postData + data;
});
req.addListener("end", () => {
if (postData) {
let parseData = transStringToObject(postData);
resolve(parseData);
} else {
resolve("没有数据");
}
});
});
}
async function transStringToObject(data) {
let result = {};
let dataList = data.split("&");
for (let [index, queryString] of dataList.entries()) {
let itemList = queryString.split("=");
result[itemList[0]] = itemList[1];
}
return result;
}3.2.2 应用koa-bodyparser的具体示例
const Koa = require("koa");
const fs = require("fs");
const app = new Koa();
const Router = require("koa-router");
const bodyParser = require("koa-bodyparser");
// post申请参数解析示例
home.get("form", async (ctx) => {
let html = `
<h1>koa2 request post demo</h1>
<form method="POST" action="/b">
<p>userName</p>
<input name="userName" /><br/>
<p>nickName</p>
<input name="nickName" /><br/>
<p>email</p>
<input name="email" /><br/>
<button type="submit">submit</button>
</form>
`;
ctx.body = html;
});
home.post("b", async (ctx) => {
// 一般解析逻辑
// const body = await parseRequestPostData(ctx);
// ctx.body = body;
// 应用koa-bodyparser会主动解析表单的数据而后放在ctx.request.body中
let postData = ctx.request.body;
ctx.body = postData;
});
let router = new Router();
router.use("/", home.routes()); //http://localhost:3000
app.use(bodyParser()); // 这个中间件的注册应该放在router之前!
app.use(router.routes());
app.listen(3002);3.2.3 依据示例实现koa-bodyparser
当ctx.method是POST申请时,主动解析ctx.request.body,次要分为:
form类型json类型text类型
依据不同的类型调用不同的解析办法,而后赋值给ctx.request.body
/**
* 注册对应的监听办法,进行request流数据的读取
* @param req
*/
function readStreamBody(req) {
return new Promise((resolve, reject) => {
let postData = "";
req.addListener("data", (data) => {
postData = postData + data;
});
req.addListener("end", () => {
if (postData) {
resolve(postData);
} else {
resolve("没有数据");
}
});
});
}
async function parseQuery(data) {
let result = {};
let dataList = data.split("&");
for (let [index, queryString] of dataList.entries()) {
let itemList = queryString.split("=");
result[itemList[0]] = itemList[1];
}
return result;
}
async function parseJSON(ctx, data) {
let result = {};
try {
result = JSON.parse(data);
} catch (e) {
ctx.throw(500, e);
}
return result;
}
function bodyParser() {
return async (ctx, next) => {
if (!ctx.request.body && ctx.method === "POST") {
let body = await readStreamBody(ctx.request.req);
// With Content-Type: text/html; charset=utf-8
// this.is('html'); // => 'html'
// this.is('text/html'); // => 'text/html'
// this.is('text/', 'application/json'); // => 'text/html'
//
// When Content-Type is application/json
// this.is('json', 'urlencoded'); // => 'json'
// this.is('application/json'); // => 'application/json'
// this.is('html', 'application/'); // => 'application/json'
//
// this.is('html'); // => false
let result;
if (ctx.request.is("application/x-www-form-urlencoded")) {
result = await parseQuery(body);
} else if (ctx.request.is("application/json")) {
result = await parseJSON(ctx, body);
} else if (ctx.request.is("text/plain")) {
result = body;
}
ctx.request.body = result;
}
await next();
};
}
module.exports = bodyParser;参考
- Koa.js 设计模式-学习笔记
- Koa2进阶学习笔记
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