forked from SigmaQuan/Better-Python-59-Ways
-
Notifications
You must be signed in to change notification settings - Fork 0
/
item_36_use_subprocess.py
238 lines (184 loc) · 8 KB
/
item_36_use_subprocess.py
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
# Chapter 5: concurrency and parallelism
import subprocess
import time
import os
# Concurrency is when a computer does many different things seemingly at the
# same time. For example, on a computer with one CPU core, the operating
# system will rapidly change which program is running on the single processor.
# This interleaves execution of the programs, providing the illusion that the
# programs are running simultaneously.
# Parallelism is actually doing many different things at the same time.
# Computers with multiple CPU cores can execute multiple programs
# simultaneously. Each CPU core runs the instructions of a separate program,
# allowing each program to make forward progress during the same instant.
# Within a single program, concurrency is a tool that makes it easier for
# programmers to solve certain types of problems. Concurrent programs enable
# many distinct paths of execution to make forward progress in a way that
# seems to be both simultaneous and independent.
# The key difference between parallelism and concurrency is speedup. When two
# distinct paths of execution in a program make forward progress in parallel,
# the time it takes to do the total work is cut in half; the speed of
# execution is faster by a factor of two. In contrast, concurrent programs
# may run thousands of separate paths of execution seemingly in parallel but
# provide no speedup for the total work.
# Python makes it easy to write concurrent programs. Python can also be used
# to do parallel work through system calls, sub-processes and C-extensions.
# But it can be very difficult to make concurrent Python code truly run in
# parallel. It's important to understand how to best utilize Python in these
# subtly different situations.
# Item 36: use subprocess to manage child processes.
# Python has battle-hardened libraries for running and managing child
# processes. This makes Python a great language for gluing other tools
# together, such as command-line utilities. When existing shell scripts get
# complicated, as they often do over time, graduating them to a rewrite in
# Python is a natural choice for the sake of readability and maintainability.
# Child processes started by Python are able to run in parallel, enabling you
# to use Python to consume all of the CPU cores of your machine and maximize
# the throughput of your programs. Although Python itself may be CPU bound
# ("see Item 37: Use threads for blocking I/O, avoid for parallelism"), it's
# easy to use Python to drive and coordinate CPU-intensive workloads.
# Python has had many ways to run sub-processes over the years, including
# popen, popen2, and os.exec*. With the Python of today, the best and simplest
# choice for managing child processes is to use the subprocess built-in module.
# Running a child process with subprocess is simple. Here, the Popen
# constructor starts the process. The communicate method reads the child
# process's output and waits for termination.
proc = subprocess.Popen(
['echo', 'Hello from the child!'],
stdout=subprocess.PIPE
)
out, err = proc.communicate()
print(out.decode('utf-8'))
# Hello from the child!
# Child processes will run independently from their parent process, the Python
# interpreter. Their status can be polled periodically while Python does other
# work.
proc = subprocess.Popen(['sleep', '0.0001'])
while proc.poll() is None:
print('Working...')
# some time-consuming work here
total = 0
for i in range(1000):
total += i
print(total)
print('Exit status', proc.poll())
# Working...
# 499500
# Working...
# 499500
# Working...
# 499500
# Exit status 0
# Decoupling the child process from the parent means that the parent process
# is free to run many child processes in parallel. You can do this by starting
# all the child processes together upfront.
def run_sleep(period):
proc = subprocess.Popen(['sleep', str(period)])
return proc
start = time.time()
procs = []
for _ in range(10):
proc = run_sleep(0.0001)
procs.append(proc)
# Later, you can wait for them to finish their I/O and terminate with the
# communicate method.
for proc in procs:
proc.communicate()
end = time.time()
print('Finished in %.3f seconds' % (end-start))
# Finished in 0.008 seconds
# Note
# If these process ran in sequence, the total delay would be 1 second, not the
# 0.008 second I measured.
# You can also pipe data from your Python program into a subprocess and
# retrieve its output. This allows you to utilize other programs to do work
# in parallel. For example, say you want to use the openssl command-line tool
# to encrypt some data. Starting the child process with command-line arguments
# and I/O pipes is easy.
# Here, I pipe random bytes into the encryption function, but in practice this
# would be user input, a file handle, a network socket, etc.:
def run_openssl(data):
env = os.environ.copy()
env['password'] = b'\xe24U\n\xd0Q13S\x11'
proc = subprocess.Popen(
['openssl', 'enc', '-des3', '-pass', 'env:password'],
env=env,
stdin=subprocess.PIPE,
stdout=subprocess.PIPE
)
proc.stdin.write(data)
proc.stdin.flush() # Ensure the child gets input
return proc
procs = []
for _ in range(3):
data = os.urandom(10)
proc = run_openssl(data)
procs.append(proc)
# The child processes will run in parallel and consume their input. Here, I
# wait for them to finish and then retrieve their final output:
for proc in procs:
out, err = proc.communicate()
print(out[-10:])
# b'\xc9/"\xf4\x902S\xa5z\x98'
# b'\xa7\x1d\xd1\x7f\x91\xa3\x14\x82\xb5\x83'
# b'Nh_\x82\xfc\x8c+DH\xb0'
# You can also create chains of parallel processes just like UNIX pipes,
# connecting the output of one child process into the input of another, and
# so on. Here's a function that starts a child process that will cause the
# md5 command-line tool to consume an input stream:
def run_md5(input_stdin):
proc = subprocess.Popen(
['md5sum'],
stdin=input_stdin,
stdout=subprocess.PIPE
)
return proc
# Note
# Python's hashlib built-in module provides the md5 function, so running a
# subprocess like this isn't always necessary. The goal here is to demonstrate
# how sub-processes can pipe inputs and outputs.
# Now, I can kick off a set of openssl processes to encrypt some data and
# another set of processes to md5 hash the encrypted output.
input_procs = []
hash_procs = []
for _ in range(3):
data = os.urandom(10)
proc = run_openssl(data)
input_procs.append(proc)
hash_proc = run_md5(proc.stdout)
hash_procs.append(hash_proc)
# The I/O between the child processes will happen automatically once you get
# them started. All you need to do is wait for them to finish and print the
# final output.
for proc in input_procs:
proc.communicate()
for proc in hash_procs:
out, err = proc.communicate()
print(out.strip())
# b'e8afc9c05add1f659486b28f54fdbfbe -'
# b'8e1b214eb900553421a9fef43e93479b -'
# b'd9d4a0381bb3d04e961c3d7a9ba84ee9 -'
# If you're worried about the child processes never finishing or somehow
# blocking on input or output pipes, then be sure to pass the timeout
# parameter to the communicate method. This will cause an exception to be
# raised if the child process hasn't responded within a time period, giving
# you a chance to terminate the misbehaving child.
proc = run_sleep(10)
try:
proc.communicate(timeout=0.1)
except subprocess.TimeoutExpired:
proc.terminate()
proc.wait()
print('Exit status', proc.poll())
# Exit status -15
# Unfortunately, the timeout parameter is only available in Python 3.3 and
# later. In earlier versions of Python, you'd need to use the select built-in
# module on proc.stdin, proc.stdout, and proc.stderr in order to enforce
# timeouts on I/O.
# Things to remember
# 1. Use the subprocess to run child processes and manage their input and
# output streams.
# 2. Child processes run in parallel with the Python interpreter, enabling you
# to maximize your CPU usage.
# 3. Use the timeout parameter with communicate to avoid deadlocks and hanging
# child processes.