In diesem Artikel werden 200 Codezeilen verwendet, um ein asynchrones, nicht blockierendes Miniatur-WebFramework zu vervollständigen: Snow. Es hat einen sehr guten Referenzwert. Werfen wir einen Blick auf den Editor unten.
Tornado, das Web-Framework von Python, ist berühmt für seine asynchrone Nichtblockierung. In diesem Artikel werden 200 Codezeilen verwendet, um ein asynchrones, nicht blockierendes Miniatur-Webframework zu vervollständigen: Snow.
1. Quellcode
Dieser Artikel basiert auf nicht-blockierendem Socket- und IO-Multiplexing, um ein asynchrones, nicht-blockierendes Web-Framework zu implementieren, darunter viele asynchrone, nicht blockierende -blockierende Web-Frameworks Interne Prinzipien des Frameworks.
#!/usr/bin/env python # -*- coding:utf-8 -*- import re import socket import select import time class HttpResponse(object): """ 封装响应信息 """ def init(self, content=''): self.content = content self.headers = {} self.cookies = {} def response(self): return bytes(self.content, encoding='utf-8') class HttpNotFound(HttpResponse): """ 404时的错误提示 """ def init(self): super(HttpNotFound, self).init('404 Not Found') class HttpRequest(object): """ 用户封装用户请求信息 """ def init(self, conn): self.conn = conn self.header_bytes = bytes() self.header_dict = {} self.body_bytes = bytes() self.method = "" self.url = "" self.protocol = "" self.initialize() self.initialize_headers() def initialize(self): header_flag = False while True: try: received = self.conn.recv(8096) except Exception as e: received = None if not received: break if header_flag: self.body_bytes += received continue temp = received.split(b'\r\n\r\n', 1) if len(temp) == 1: self.header_bytes += temp else: h, b = temp self.header_bytes += h self.body_bytes += b header_flag = True @property def header_str(self): return str(self.header_bytes, encoding='utf-8') def initialize_headers(self): headers = self.header_str.split('\r\n') first_line = headers[0].split(' ') if len(first_line) == 3: self.method, self.url, self.protocol = headers[0].split(' ') for line in headers: kv = line.split(':') if len(kv) == 2: k, v = kv self.header_dict[k] = v class Future(object): """ 异步非阻塞模式时封装回调函数以及是否准备就绪 """ def init(self, callback): self.callback = callback self._ready = False self.value = None def set_result(self, value=None): self.value = value self._ready = True @property def ready(self): return self._ready class TimeoutFuture(Future): """ 异步非阻塞超时 """ def init(self, timeout): super(TimeoutFuture, self).init(callback=None) self.timeout = timeout self.start_time = time.time() @property def ready(self): current_time = time.time() if current_time > self.start_time + self.timeout: self._ready = True return self._ready class Snow(object): """ 微型Web框架类 """ def init(self, routes): self.routes = routes self.inputs = set() self.request = None self.async_request_handler = {} def run(self, host='localhost', port=9999): """ 事件循环 :param host: :param port: :return: """ sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM) sock.bind((host, port,)) sock.setblocking(False) sock.listen(128) sock.setblocking(0) self.inputs.add(sock) try: while True: readable_list, writeable_list, error_list = select.select(self.inputs, [], self.inputs,0.005) for conn in readable_list: if sock == conn: client, address = conn.accept() client.setblocking(False) self.inputs.add(client) else: gen = self.process(conn) if isinstance(gen, HttpResponse): conn.sendall(gen.response()) self.inputs.remove(conn) conn.close() else: yielded = next(gen) self.async_request_handler[conn] = yielded self.polling_callback() except Exception as e: pass finally: sock.close() def polling_callback(self): """ 遍历触发异步非阻塞的回调函数 :return: """ for conn in list(self.async_request_handler.keys()): yielded = self.async_request_handler[conn] if not yielded.ready: continue if yielded.callback: ret = yielded.callback(self.request, yielded) conn.sendall(ret.response()) self.inputs.remove(conn) del self.async_request_handler[conn] conn.close() def process(self, conn): """ 处理路由系统以及执行函数 :param conn: :return: """ self.request = HttpRequest(conn) func = None for route in self.routes: if re.match(route[0], self.request.url): func = route[1] break if not func: return HttpNotFound() else: return func(self.request) snow.py
2. Verwendung
from snow import Snow from snow import HttpResponse def index(request): return HttpResponse('OK') routes = [ (r'/index/', index), ] app = Snow(routes) app.run(port=8012)
2. Asynchrone Nichtblockierung: Timeout
from snow import Snow from snow import HttpResponse from snow import TimeoutFuture request_list = [] def async(request): obj = TimeoutFuture(5) yield obj def home(request): return HttpResponse('home') routes = [ (r'/home/', home), (r'/async/', async), ] app = Snow(routes) app.run(port=8012)
3. Asynchrones Nichtblockieren: Warten Basierend auf dem Warten Modus kann die automatische Vervollständigung abgeschlossen werden. Anpassungsvorgang
from snow import Snow from snow import HttpResponse from snow import Future request_list = [] def callback(request, future): return HttpResponse(future.value) def req(request): obj = Future(callback=callback) request_list.append(obj) yield obj def stop(request): obj = request_list[0] del request_list[0] obj.set_result('done') return HttpResponse('stop') routes = [ (r'/req/', req), (r'/stop/', stop), ] app = Snow(routes) app.run(port=8012)
Das obige ist der detaillierte Inhalt vonAngepasster Beispielcode für ein asynchrones, nicht blockierendes Python-Webframework. Für weitere Informationen folgen Sie bitte anderen verwandten Artikeln auf der PHP chinesischen Website!