PBS is a unique subprocess wrapper that maps your system programs to Python functions dynamically. PBS helps you write shell scripts in Python by giving you the good features of Bash (easy command calling, easy piping) with all the power and flexibility of Python.
from pbs import ifconfig print ifconfig("eth0")
PBS is not a collection of system commands implemented in Python.
$> pip install pbs
The easiest way (and least magical way) to get up and running is to import pbs directly or import your program from pbs:
import pbs print pbs.ifconfig("eth0") from pbs import ifconfig print ifconfig("eth0")
The alternative way is to import all of your system programs by using star import. Note that this does not actually import every system program, but provides a dynamic lookup mechanism. This usage pattern is suited for one-file shell scripts:
from pbs import * print ifconfig("eth0") print du()
There are some important caveats when using star import, and the code will raise a warning to notify you of such. Please review the limitations under the last section "Limitations".
A less common usage pattern is through PBS Command wrapper, which takes a full path to a command and returns a callable object. This is useful for programs that have weird characters in their names or programs that aren't in your $PATH:
import pbs ffmpeg = pbs.Command("/usr/bin/ffmpeg") ffmpeg(movie_file)
The last usage pattern is for trying PBS through an interactive REPL. By default, this acts like a star import (so all of your system programs will be immediately available as functions):
$> python pbs.py
Commands work like you'd expect. Just call your program's name like a function:
# print the contents of this directory print ls("-l") # get the longest line of this file longest_line = wc(__file__, "-L") # get interface information print ifconfig("eth0")
Note that these aren't Python functions, these are running the binary commands on your system dynamically by resolving your PATH, much like Bash does. In this way, all the programs on your system are easily available in Python.
Keyword arguments also work like you'd expect: they get replaced with the long-form and short-form commandline option:
# resolves to "curl http://duckduckgo.com/ -o page.html --silent" curl("http://duckduckgo.com/", o="page.html", silent=True) # or if you prefer not to use keyword arguments, these do the same thing: curl("http://duckduckgo.com/", "-o page.html", "--silent") curl("http://duckduckgo.com/", "-o", "page.html", "--silent") # resolves to "adduser amoffat --system --shell=/bin/bash --no-create-home" adduser("amoffat", system=True, shell="/bin/bash", no_create_home=True) # or adduser("amoffat", "--system", "--shell /bin/bash", "--no-create-home")
Piping has become function composition:
# sort this directory by biggest file print sort(du(glob("*"), "-sb"), "-rn") # print the number of folders and files in /etc print wc(ls("/etc", "-1"), "-l")
PBS can redirect the standard and error output streams of a process to a file. This is done with the special _out and _err keyword arguments. You can pass a filename or a file object as the argument value. When the name of an already existing file is passed, the contents of the file will be overwritten.
ls(_out="files.list") ls("nonexistent", _err="error.txt")
PBS can also redirect the error output stream to the standard output stream, using the special _err_to_out=True keyword argument.
Sudo and With Contexts
Commands can be run within a "with" context. Popular commands using this might be "sudo" or "fakeroot":
with sudo: print ls("/root")
If you need to run a command in a with context AND call it, for example, specifying a -p prompt with sudo, you need to use the "_with" keyword argument. This let's the command know that it's being run from a with context so it can behave correctly.
with sudo(p=">", _with=True): print ls("/root")
Commands can be run in the background with the special _bg=True keyword argument:
# blocks sleep(3) print "...3 seconds later" # doesn't block p = sleep(3, _bg=True) print "prints immediately!" p.wait() print "...and 3 seconds later"
You can also pipe together background processes!
p = wc(curl("http://github.com/", silent=True, _bg=True), "--bytes") print "prints immediately!" print "byte count of github: %d" % int(p) # lazily completes
This lets you start long-running commands at the beginning of your script (like a file download) and continue performing other commands in the foreground.
"Which" finds the full path of a program, or returns None if it doesn't exist. This command is one of the few commands implemented as a Python function, and therefore doesn't rely on the "which" program actually existing.
print which("python") # "/usr/bin/python" print which("ls") # "/bin/ls" print which("some_command") # None if not which("supervisorctl"): apt_get("install", "supervisor", "-y")
Environment variables are available much like they are in Bash:
print HOME print SHELL print PS1
You can set enviroment variables the usual way, through the os.environ mapping:
import os os.environ["TEST"] = "123"
Now any new subprocess commands called from the script will be able to access that environment variable.
Exceptions are dynamically generated based on the return code of the command. This lets you catch a specific return code, or catch all error return codes through the base class ErrorReturnCode:
try: print ls("/some/non-existant/folder") except ErrorReturnCode_2: print "folder doesn't exist!" create_the_folder() except ErrorReturnCode: print "unknown error" exit(1)
Glob-expansion is not done on your arguments. For example, this will not work:
from pbs import du print du("*")
You'll get an error to the effect of "cannot access '*': No such file or directory". This is because the "*" needs to be glob expanded:
from pbs import du, glob print du(glob("*"))
You can access commandline arguments similar to Bash's $1, $2, etc by using ARG1, ARG2, etc:
print ARG1, ARG2 # if an argument isn't defined, it's set to None if ARG10 is None: do_something()
You can access the entire argparse/optparse-friendly list of commandline arguments through "ARGV". This is recommended for flexibility:
import argparse parser = argparse.ArgumentParser(prog="PROG") parser.add_argument("-x", default=3, type=int) ns = parser.parse_args(ARGV) print ns.x
PBS automatically handles underscore-dash conversions. For example, if you want to call apt-get:
apt_get("install", "mplayer", y=True)
PBS looks for "apt_get", but if it doesn't find it, replaces all underscores with dashes and searches again. If the command still isn't found, a CommandNotFound exception is raised.
Commands with other, less-commonly symbols in their names must be accessed directly through the "Command" class wrapper. The Command class takes the full path to the program as a string:
p27 = Command(which("python2.7")) print p27("-h")
The Command wrapper is also useful for commands that are not in your standard PATH:
script = Command("/tmp/temporary-script.sh") print script()
PBS's main limitations come from the use of star import. If you're interested as to why these limitations exist, please take a look at the source. In general, when using star import:
- Do the import as soon as possible, at the top of the script.
- Do not do the star import on an indented line (so don't do it from within an if statement, or function, etc)
- (Disabled anyway, but) Do not star import from the Python shell. If you want to muck around in a REPL shell, run PBS as a script, which will launch a REPL.
- (Disabled anyway, but) Do not star import from anywhere other than a main script.