在上一节中,最后返回了一个resolver,本质上就是一个Resolver对象:
resolver = new Resolver(fileSystem);
这个对象的构造函数非常简单,只是简单的继承了Tapable,并接收了fileSystem参数:
function Resolver(fileSystem) {
Tapable.call(this);
this.fileSystem = fileSystem;
}
module.exports = Resolver;
resolve
而在make事件流中,调用的正是该类的原型方法resolve,现在可以进行看一眼了:
/*
context => { issuer: '', compiler: undefined }
path => 'd:\\workspace\\doc'
request => './input.js'
callback => [Function]
*/
Resolver.prototype.resolve = function resolve(context, path, request, callback) {
if (arguments.length === 3) {
throw new Error("Signature changed: context parameter added");
}
var resolver = this;
// 包装参数
var obj = {
context: context,
path: path,
request: request
}; var localMissing;
var log;
// message => resolve './input.js' in 'd:\\workspace\\doc'
var message = "resolve '" + request + "' in '" + path + "'"; function writeLog(msg) {
log.push(msg);
} function logAsString() {
return log.join("\n");
} function onError(err, result) { /**/ } function onResolve(err, result) { /**/ }
// 这两个并不存在
onResolve.missing = callback.missing;
onResolve.stack = callback.stack;
// 调用另一个原型方法
return this.doResolve("resolve", obj, message, onResolve);
};
需要注意的是,该方法会在webpack编译期间被调用多次,这里的参数仅仅是第一次被调用时的。
doResolve
简单的说,resolve方法将参数进行二次包装后,调用了另外一个原型方法doResolve,源码整理如下:
/*
type => 'resolve'
request =>
{
context: { issuer: '', compiler: undefined },
path: 'd:\\workspace\\doc',
request: './input.js'
}
message => resolve './input.js' in 'd:\\workspace\\doc'
callback => doResolve()
*/
Resolver.prototype.doResolve = function doResolve(type, request, message, callback) {
var resolver = this;
// stackLine => resolve: (d:\workspace\doc) ./input.js
var stackLine = type + ": (" + request.path + ") " +
(request.request || "") + (request.query || "") +
(request.directory ? " directory" : "") +
(request.module ? " module" : "");
var newStack = [stackLine];
// 暂无
if (callback.stack) { /**/ }
// 没这个事件流
resolver.applyPlugins("resolve-step", type, request);
// before-resolve
var beforePluginName = "before-" + type;
// 检测是否存在对应的before事件流
if (resolver.hasPlugins(beforePluginName)) { /**/ }
// 走正常流程
else {
runNormal();
}
}
由于callback的missing、stack属性均为undefined,所以会直接跳过那个if判断。
而事件流resolve-step、before-resolve也不存在,所以会直接走最后的else,进入runNormal方法。
这里全面描述一下doResolve,方法内部有5个函数,分别名为beforeInnerCallback、runNormal、innerCallback、runAfter、afterInnerCallback,所有的callback函数都负责包装对应事件流的回调函数。
源码如下:
// 先判断是否存在before-type事件流
if (resolver.hasPlugins(beforePluginName)) {
// 触发完调用回调
resolver.applyPluginsAsyncSeriesBailResult1(beforePluginName, request, createInnerCallback(beforeInnerCallback, {
log: callback.log,
missing: callback.missing,
stack: newStack
}, message && ("before " + message), true));
}
// 不存在跳过直接触发type事件流
else {
runNormal();
} function beforeInnerCallback(err, result) {
if (arguments.length > 0) {
if (err) return callback(err);
if (result) return callback(null, result);
return callback();
}
// 这里进入下一阶段
runNormal();
} // 触发type事件流
function runNormal() {
if (resolver.hasPlugins(type)) { /**/ } else {
runAfter();
}
} function innerCallback(err, result) { /**/ }
// 触发after-type
function runAfter() {
var afterPluginName = "after-" + type;
// 这里就是直接调用callback了
if (resolver.hasPlugins(afterPluginName)) { /**/ } else {
callback();
}
} function afterInnerCallback(err, result) { /**/ }
可以看到逻辑很简单,每一个事件流type存在3个类型:before-type、type、after-type,doResolve会尝试依次触发每一个阶段的事件流。
在上面的例子中,因为不存在before-resolve事件流,所以会调用runNormal方法去触发resolve的事件流。
如果存在,触发对应的事件流,并在回调函数中触发下一阶段的事件流。
所以这里的调用就可以用一句话概括:尝试触发before-resolve、resolve、after-resolve事件流后,调用callback。
unsafeCache
resolve事件流均来源于上一节第三部分注入的开头,如下:
// resolve
if (unsafeCache) {
plugins.push(new UnsafeCachePlugin("resolve", cachePredicate, unsafeCache, cacheWithContext, "new-resolve"));
plugins.push(new ParsePlugin("new-resolve", "parsed-resolve"));
} else {
plugins.push(new ParsePlugin("resolve", "parsed-resolve"));
}
UnsafeCachePlugin
这个unsafeCache虽然不知道是啥,但是一般不会去设置,默认情况下是true,因此进入UnsafeCachePlugin插件,构造函数如下:
/*
source => resolve
filterPredicate => function(){return true}
cache => {}
withContext => false
target => new-resolve
*/
function UnsafeCachePlugin(source, filterPredicate, cache, withContext, target) {
this.source = source;
this.filterPredicate = filterPredicate;
this.withContext = withContext;
this.cache = cache || {};
this.target = target;
}
基本上只是对传入参数的获取,直接看事件流的内容:
function getCacheId(request, withContext) {
// 直接用配置对象的字符串形式作为缓存对象key
// 貌似vue源码的compile也是这样的
return JSON.stringify({
context: withContext ? request.context : "",
path: request.path,
query: request.query,
request: request.request
});
}
UnsafeCachePlugin.prototype.apply = function(resolver) {
var filterPredicate = this.filterPredicate;
var cache = this.cache;
var target = this.target;
var withContext = this.withContext;
// 这里注入resolve事件流
/*
request =>
{
context: { issuer: '', compiler: undefined },
path: 'd:\\workspace\\doc',
request: './input.js'
}
callback => createInnerCallback(innerCallback,{...})
*/
resolver.plugin(this.source, function(request, callback) {
// 这里永远是true
if (!filterPredicate(request)) return callback();
// 尝试获取缓存
var cacheId = getCacheId(request, withContext);
var cacheEntry = cache[cacheId];
if (cacheEntry) {
return callback(null, cacheEntry);
}
// 这里再次调用了doResolve函数
// target => new-resolve
resolver.doResolve(target, request, null, createInnerCallback(function(err, result) {
if (err) return callback(err);
if (result) return callback(null, cache[cacheId] = result);
callback();
}, callback));
});
};
这样就很明显了,resolve事件只是为了获取缓存,如果不存在缓存,就再次调用doResolve方法,这一次传入的type为new-resolve。
ParsePlugin
new-resolve事件流并不存在before-xxx或者after-xxx的情况,所以直接看事件流本身。注入地点在UnsafeCachePlugin插件的后面。
从上面的if/else可以看出,无论如何都会调用该插件,只是会根据unsafeCache的值来决定是否取缓存。
这个插件内容比较简单暴力,简答过一下:
// source => new-resolve
// target => parsed-resolve
function ParsePlugin(source, target) {
this.source = source;
this.target = target;
}
module.exports = ParsePlugin; ParsePlugin.prototype.apply = function(resolver) {
var target = this.target;
resolver.plugin(this.source, function(request, callback) {
// 解析
var parsed = resolver.parse(request.request);
// 合并对象
var obj = Object.assign({}, request, parsed);
if (request.query && !parsed.query) {
obj.query = request.query;
}
if (parsed && callback.log) {
if (parsed.module)
callback.log("Parsed request is a module");
if (parsed.directory)
callback.log("Parsed request is a directory");
}
// 触发target的doResolve
resolver.doResolve(target, obj, null, callback);
});
};
基本上都是一个套路了,触发事件流,做点什么,然后最后调用doResolve触发下一轮。
这里的核心就是parse方法,估计跟vue源码的parse差不多,比较麻烦,下一节再讲。
Resolver.prototype.parse
这个parse方法超级简单,如下:
Resolver.prototype.parse = function parse(identifier) {
if (identifier === "") return null;
var part = {
request: "",
query: "",
module: false,
directory: false,
file: false
};
// 根据问号切割参数
var idxQuery = identifier.indexOf("?");
if (idxQuery === 0) {
part.query = identifier;
} else if (idxQuery > 0) {
part.request = identifier.slice(0, idxQuery);
part.query = identifier.slice(idxQuery);
} else {
part.request = identifier;
}
if (part.request) {
// 判断是文件还是文件夹
part.module = this.isModule(part.request);
part.directory = this.isDirectory(part.request);
// 去掉文件夹最后的斜杠
if (part.directory) {
part.request = part.request.substr(0, part.request.length - 1);
}
}
return part;
};
/*
匹配以下内容开头的字符串
1 => .
2 => ./ or .\
3 => ..
4 => ../ or ..\
5 => /
6 => A-Z:/ or A-Z:\
*/
var notModuleRegExp = /^\.$|^\.[\\\/]|^\.\.$|^\.\.[\/\\]|^\/|^[A-Z]:[\\\/]/i;
Resolver.prototype.isModule = function isModule(path) {
return !notModuleRegExp.test(path);
};
/*
匹配以\ or /结尾的字符串
*/
var directoryRegExp = /[\/\\]$/i;
Resolver.prototype.isDirectory = function isDirectory(path) {
return directoryRegExp.test(path);
};
内容很简单,就做了2件事:
1、根据问号切割参数
2.、判断是文件还是文件夹
最后返回了信息组成的对象。