前面一篇文章分析到了最上面的一层SessionManager,本篇开始分析一下里面的一层Request。
进入SessionManager里面的request方法:
open func request(
_ url: URLConvertible,
method: HTTPMethod = .get,
parameters: Parameters? = nil,
encoding: ParameterEncoding = URLEncoding.default,
headers: HTTPHeaders? = nil)
-> DataRequest
{
var originalRequest: URLRequest?
do {
originalRequest = try URLRequest(url: url, method: method, headers: headers)
let encodedURLRequest = try encoding.encode(originalRequest!, with: parameters)
return request(encodedURLRequest)
} catch {
return request(originalRequest, failedWith: error)
}
}
有个do...catch语句,基本上不会遇到,但是这么牛逼的框架必须考虑到二货随便传参进来!除非像我这么干,的确会干到catch里面:
Alamofire.request("urlStr………………")
.responseJSON { (response) in
print(response)
}
请求连接错误.png
do语句里面第一句就是个很简单的原始请求初始化保存起来先,第二句有个
encoding.encode方法,虽然入参是ParameterEncoding类型,但是默认值是一个URLEncoding的类型,所以直接干进URLEncoding.encode方法,进行进一步的分析。
encode.png
直接上源码:
public func encode(_ urlRequest: URLRequestConvertible, with parameters: Parameters?) throws -> URLRequest {
var urlRequest = try urlRequest.asURLRequest()
guard let parameters = parameters else { return urlRequest }
if let method = HTTPMethod(rawValue: urlRequest.httpMethod ?? "GET"), encodesParametersInURL(with: method) {
guard let url = urlRequest.url else {
throw AFError.parameterEncodingFailed(reason: .missingURL)
}
if var urlComponents = URLComponents(url: url, resolvingAgainstBaseURL: false), !parameters.isEmpty {
let percentEncodedQuery = (urlComponents.percentEncodedQuery.map { $0 + "&" } ?? "") + query(parameters)
urlComponents.percentEncodedQuery = percentEncodedQuery
urlRequest.url = urlComponents.url
}
} else {
if urlRequest.value(forHTTPHeaderField: "Content-Type") == nil {
urlRequest.setValue("application/x-www-form-urlencoded; charset=utf-8", forHTTPHeaderField: "Content-Type")
}
urlRequest.httpBody = query(parameters).data(using: .utf8, allowLossyConversion: false)
}
return urlRequest
}
这么一坨代码if...else...语句占绝大部分,我们直接看这个判断语句,if里有一个encodesParametersInURL方法,字面意思就是编码参数到url里面,干进去看看是个什么东西:
private func encodesParametersInURL(with method: HTTPMethod) -> Bool {
switch destination {
case .queryString:
return true
case .httpBody:
return false
default:
break
}
switch method {
case .get, .head, .delete:
return true
default:
return false
}
}
也就是说GET/DELETE/HEAD方法的请求,是需要将参数直接拼接在请求连接的后面的。我们实实在在来个GET请求:
let urlStr = "http://3g.163.com/touch/reconstruct/article/list/BA10TA81wangning/10-2.html"
Alamofire.request(urlStr, parameters: ["type":"1","page":"1"])
.responseJSON { (response) in
print(response)
}
在encode方法里打上断点会发现如下图:
请求参数拼接.png
再来个特殊点的:
let urlStr = "http://3g.163.com/touch/reconstruct/article/list/BA10TA81wangning/10-2.html?name=box"
Alamofire.request(urlStr, parameters: ["type":"1","page":"1"])
.responseJSON { (response) in
print(response)
}
连接里带参的其他拼接.png
相信已经清楚了,这个拼接就是这么好用!进入这个
query方法,瞄一眼:
private func query(_ parameters: [String: Any]) -> String {
var components: [(String, String)] = []
for key in parameters.keys.sorted(by: <) {
let value = parameters[key]!
components += queryComponents(fromKey: key, value: value)
}
return components.map { "\($0)=\($1)" }.joined(separator: "&")
}
joined(separator: "&")熟悉不熟悉,就是在每两项中间插入一个&,里面有一个queryComponents方法,干进去看一看:
public func queryComponents(fromKey key: String, value: Any) -> [(String, String)] {
var components: [(String, String)] = []
if let dictionary = value as? [String: Any] {
for (nestedKey, value) in dictionary {
components += queryComponents(fromKey: "\(key)[\(nestedKey)]", value: value)
}
} else if let array = value as? [Any] {
for value in array {
components += queryComponents(fromKey: arrayEncoding.encode(key: key), value: value)
}
} else if let value = value as? NSNumber {
if value.isBool {
components.append((escape(key), escape(boolEncoding.encode(value: value.boolValue))))
} else {
components.append((escape(key), escape("\(value)")))
}
} else if let bool = value as? Bool {
components.append((escape(key), escape(boolEncoding.encode(value: bool))))
} else {
components.append((escape(key), escape("\(value)")))
}
return components
}
看到了很骚的递归操作queryComponents,因为参进来的参数是个对象,鬼知道是什么类型,所以需要一层一层的转换到最终的一个元组类型,里面的escape又是个什么鬼,干进去:
public func escape(_ string: String) -> String {
let generalDelimitersToEncode = ":#[]@" // does not include "?" or "/" due to RFC 3986 - Section 3.4
let subDelimitersToEncode = "!$&'()*+,;="
var allowedCharacterSet = CharacterSet.urlQueryAllowed
allowedCharacterSet.remove(charactersIn: "\(generalDelimitersToEncode)\(subDelimitersToEncode)")
var escaped = ""
//==========================================================================================================
//
// Batching is required for escaping due to an internal bug in iOS 8.1 and 8.2. Encoding more than a few
// hundred Chinese characters causes various malloc error crashes. To avoid this issue until iOS 8 is no
// longer supported, batching MUST be used for encoding. This introduces roughly a 20% overhead. For more
// info, please refer to:
//
// - https://github.com/Alamofire/Alamofire/issues/206
//
//==========================================================================================================
if #available(iOS 8.3, *) {
escaped = string.addingPercentEncoding(withAllowedCharacters: allowedCharacterSet) ?? string
} else {
let batchSize = 50
var index = string.startIndex
while index != string.endIndex {
let startIndex = index
let endIndex = string.index(index, offsetBy: batchSize, limitedBy: string.endIndex) ?? string.endIndex
let range = startIndex..<endIndex
let substring = string[range]
escaped += substring.addingPercentEncoding(withAllowedCharacters: allowedCharacterSet) ?? String(substring)
index = endIndex
}
}
return escaped
}
里面重要的就是CharacterSet.urlQueryAllowed和addingPercentEncoding最终出来的就是经过百分号编码的字符串。最后来个完美的视图:
数组里的元组拼接.png
那么除了GET/HEAD/DELETE方法其他的请求方法是如何做的?直接看else分支:
if urlRequest.value(forHTTPHeaderField: "Content-Type") == nil {
urlRequest.setValue("application/x-www-form-urlencoded; charset=utf-8", forHTTPHeaderField: "Content-Type")
}
urlRequest.httpBody = query(parameters).data(using: .utf8, allowLossyConversion: false)
很明显是将百分号编码后的参数进行转换成data赋值给request的httpBody即可。到此可以正式进入request方法了:
open func request(_ urlRequest: URLRequestConvertible) -> DataRequest {
var originalRequest: URLRequest?
do {
originalRequest = try urlRequest.asURLRequest()
let originalTask = DataRequest.Requestable(urlRequest: originalRequest!)
let task = try originalTask.task(session: session, adapter: adapter, queue: queue)
let request = DataRequest(session: session, requestTask: .data(originalTask, task))
delegate[task] = request
if startRequestsImmediately { request.resume() }
return request
} catch {
return request(originalRequest, failedWith: error)
}
}
看到DataRequest.Requestable这样的操作,第一反应是这个类的静态方法,进去看一眼:
open class DataRequest: Request {
// MARK: Helper Types
struct Requestable: TaskConvertible {
let urlRequest: URLRequest
func task(session: URLSession, adapter: RequestAdapter?, queue: DispatchQueue) throws -> URLSessionTask {
do {
let urlRequest = try self.urlRequest.adapt(using: adapter)
return queue.sync { session.dataTask(with: urlRequest) }
} catch {
throw AdaptError(error: error)
}
}
}
...
}
明显是个结构体, urlRequest就是结构体构造的时候传进去的参数,这个结构体内部包含一个返回URLSessionTask的task方法,内部同步创建返回一个URLSessionDataTask对象。
let request = DataRequest(session: session, requestTask: .data(originalTask, task))
看到这个代码,直接干进去DataRequest找它的初始化方法,没有!!!找父类Request的初始化方法:
init(session: URLSession, requestTask: RequestTask, error: Error? = nil) {
self.session = session
switch requestTask {
case .data(let originalTask, let task):
taskDelegate = DataTaskDelegate(task: task)
self.originalTask = originalTask
case .download(let originalTask, let task):
taskDelegate = DownloadTaskDelegate(task: task)
self.originalTask = originalTask
case .upload(let originalTask, let task):
taskDelegate = UploadTaskDelegate(task: task)
self.originalTask = originalTask
case .stream(let originalTask, let task):
taskDelegate = TaskDelegate(task: task)
self.originalTask = originalTask
}
delegate.error = error
delegate.queue.addOperation { self.endTime = CFAbsoluteTimeGetCurrent() }
}
这个RequestTask类型是个枚举,里面的值看名字就能想到是干嘛用的,就是这么通俗易懂,数据/下载/上传/数据流:
enum RequestTask {
case data(TaskConvertible?, URLSessionTask?)
case download(TaskConvertible?, URLSessionTask?)
case upload(TaskConvertible?, URLSessionTask?)
case stream(TaskConvertible?, URLSessionTask?)
}
这种通过枚举的方式来提供接口的标识方法,可以方便的根据不同的标识走不同的逻辑,在我们日常的开发中的确有太多的地方可以这么干。
delegate[task] = request
这句代码是不是让人很费解,这种操作有什么意义?看着像数组的赋值或者是字典的赋值,进入SessionDelegate的源码找一找:
/// Access the task delegate for the specified task in a thread-safe manner.
open subscript(task: URLSessionTask) -> Request? {
get {
lock.lock() ; defer { lock.unlock() }
return requests[task.taskIdentifier]
}
set {
lock.lock() ; defer { lock.unlock() }
requests[task.taskIdentifier] = newValue
}
}
用这种Swift下标的方式进行赋值和取值,让人觉得非常清晰,如果想从SessionDelegate对象里面拿到request,直接拿比较困难,但是从SessionDelegate对象里面拿到task就很容易,那么这样一赋值,再通过task拿到这个request就方便很多。来个图证明一下:
通过task找到Request.png
疑问来了,为毛不直接这里实现掉?直接点进去看一看这个方法里面的具体东西:
func urlSession(
_ session: URLSession,
downloadTask: URLSessionDownloadTask,
didFinishDownloadingTo location: URL)
{
temporaryURL = location
guard
let destination = destination,
let response = downloadTask.response as? HTTPURLResponse
else { return }
let result = destination(location, response)
let destinationURL = result.destinationURL
let options = result.options
self.destinationURL = destinationURL
do {
if options.contains(.removePreviousFile), FileManager.default.fileExists(atPath: destinationURL.path) {
try FileManager.default.removeItem(at: destinationURL)
}
if options.contains(.createIntermediateDirectories) {
let directory = destinationURL.deletingLastPathComponent()
try FileManager.default.createDirectory(at: directory, withIntermediateDirectories: true)
}
try FileManager.default.moveItem(at: location, to: destinationURL)
} catch {
self.error = error
}
}
这么一坨文件操作,你让一个大佬级别的来做合适吗?不合适!直接交给干苦力的活就可以了。图片中第一个if判断是判断用户在外面有没有自己的处理回调闭包downloadTaskDidFinishDownloadingToURL,如果有,就直接交给用户处理,没有的话框架自己处理掉。
到此,本篇主要分析了Request的参数处理,以及SessionDelegate和TaskDelegate的关系。解析在一步一步的深入,一步一步的细化:
细化思想.png
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