python的多线程比多进程效率高
Python中单线程、多线程和多进程的效率对比实验实例python的多进程性能要明显优于多线程,因为cpython的gil对性能做了约束。
python是运行在解释器中的语言,查找资料知道,python中有一个全局锁(gil),在使用多进程(thread)的情况下,不能发挥多核的优势。而使用多进程(multiprocess),则可以发挥多核的优势真正地提高效率。
对比实验
资料显示,如果多线程的进程是cpu密集型的,那多线程并不能有多少效率上的提升,相反还可能会因为线程的频繁切换,导致效率下降,推荐使用多进程;如果是io密集型,多线程进程可以利用io阻塞等待时的空闲时间执行其他线程,提升效率。所以我们根据实验对比不同场景的效率
| 操作系统 | cpu | 内存 | 硬盘 |
|---|---|---|---|
| windows 10 | 双核 | 8gb | 机械硬盘 |
(1)引入所需要的模块
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import requestsimport timefrom threading import threadfrom multiprocessing import process |
(2)定义cpu密集的计算函数
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def count(x, y): # 使程序完成150万计算 c = 0 while c < 500000: c += 1 x += x y += y |
(3)定义io密集的文件读写函数
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def write(): f = open("test.txt", "w") for x in range(5000000): f.write("testwrite\n") f.close() def read(): f = open("test.txt", "r") lines = f.readlines() f.close() |
(4) 定义网络请求函数
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_head = { 'user-agent': 'mozilla/5.0 (windows nt 10.0; wow64) applewebkit/537.36 (khtml, like gecko) chrome/48.0.2564.116 safari/537.36'}url = "http://www.tieba.com"def http_request(): try: webpage = requests.get(url, headers=_head) html = webpage.text return {"context": html} except exception as e: return {"error": e} |
(5)测试线性执行io密集操作、cpu密集操作所需时间、网络请求密集型操作所需时间
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# cpu密集操作t = time.time()for x in range(10): count(1, 1)print("line cpu", time.time() - t) # io密集操作t = time.time()for x in range(10): write() read()print("line io", time.time() - t) # 网络请求密集型操作t = time.time()for x in range(10): http_request()print("line http request", time.time() - t) |
输出
cpu密集:95.6059999466、91.57099986076355 92.52800011634827、 99.96799993515015
io密集:24.25、21.76699995994568、21.769999980926514、22.060999870300293
网络请求密集型: 4.519999980926514、8.563999891281128、4.371000051498413、4.522000074386597、14.671000003814697
(6)测试多线程并发执行cpu密集操作所需时间
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counts = []t = time.time()for x in range(10): thread = thread(target=count, args=(1,1)) counts.append(thread) thread.start() e = counts.__len__()while true: for th in counts: if not th.is_alive(): e -= 1 if e <= 0: breakprint(time.time() - t) |
output: 99.9240000248 、101.26400017738342、102.32200002670288
(7)测试多线程并发执行io密集操作所需时间
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def io(): write() read() t = time.time()ios = []t = time.time()for x in range(10): thread = thread(target=count, args=(1,1)) ios.append(thread) thread.start() e = ios.__len__()while true: for th in ios: if not th.is_alive(): e -= 1 if e <= 0: breakprint(time.time() - t) |
output: 25.69700002670288、24.02400016784668
(8)测试多线程并发执行网络密集操作所需时间
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t = time.time()ios = []t = time.time()for x in range(10): thread = thread(target=http_request) ios.append(thread) thread.start() e = ios.__len__()while true: for th in ios: if not th.is_alive(): e -= 1 if e <= 0: breakprint("thread http request", time.time() - t) |
output: 0.7419998645782471、0.3839998245239258、0.3900001049041748
(9)测试多进程并发执行cpu密集操作所需时间
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counts = []t = time.time()for x in range(10): process = process(target=count, args=(1,1)) counts.append(process) process.start()e = counts.__len__()while true: for th in counts: if not th.is_alive(): e -= 1 if e <= 0: breakprint("multiprocess cpu", time.time() - t) |
output: 54.342000007629395、53.437999963760376
(10)测试多进程并发执行io密集型操作
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t = time.time()ios = []t = time.time()for x in range(10): process = process(target=io) ios.append(process) process.start() e = ios.__len__()while true: for th in ios: if not th.is_alive(): e -= 1 if e <= 0: breakprint("multiprocess io", time.time() - t) |
output: 12.509000062942505、13.059000015258789
(11)测试多进程并发执行http请求密集型操作
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t = time.time()httprs = []t = time.time()for x in range(10): process = process(target=http_request) ios.append(process) process.start() e = httprs.__len__()while true: for th in httprs: if not th.is_alive(): e -= 1 if e <= 0: breakprint("multiprocess http request", time.time() - t) |
output: 0.5329999923706055、0.4760000705718994
实验结果
| cpu密集型操作 | io密集型操作 | 网络请求密集型操作 | |
|---|---|---|---|
| 线性操作 | 94.91824996469 | 22.46199995279 | 7.3296000004 |
| 多线程操作 | 101.1700000762 | 24.8605000973 | 0.5053332647 |
| 多进程操作 | 53.8899999857 | 12.7840000391 | 0.5045000315 |
通过上面的结果,我们可以看到:
多线程在io密集型的操作下似乎也没有很大的优势(也许io操作的任务再繁重一些就能体现出优势),在cpu密集型的操作下明显地比单线程线性执行性能更差,但是对于网络请求这种忙等阻塞线程的操作,多线程的优势便非常显著了
多进程无论是在cpu密集型还是io密集型以及网络请求密集型(经常发生线程阻塞的操作)中,都能体现出性能的优势。不过在类似网络请求密集型的操作上,与多线程相差无几,但却更占用cpu等资源,所以对于这种情况下,我们可以选择多线程来执行
以上所述是小编给大家介绍的python单线程多线程和多进程效率对比详解整合,希望对大家有所帮助,如果大家有任何疑问请给我留言,小编会及时回复大家的。在此也非常感谢大家对开心学习网网站的支持!
原文链接:https://blog.csdn.net/Jailman/article/details/78427936