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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright (c) 2009, Giampaolo Rodola'. All rights reserved.
# Use of this source code is governed by a BSD-style license that can be
# found in the LICENSE file.
"""psutil is a cross-platform library for retrieving information on
running processes and system utilization (CPU, memory, disks, network)
in Python.
"""
from __future__ import division
__author__ = "Giampaolo Rodola'"
__version__ = "2.1.3"
version_info = tuple([int(num) for num in __version__.split('.')])
__all__ = [
# exceptions
"Error", "NoSuchProcess", "AccessDenied", "TimeoutExpired",
# constants
"version_info", "__version__",
"STATUS_RUNNING", "STATUS_IDLE", "STATUS_SLEEPING", "STATUS_DISK_SLEEP",
"STATUS_STOPPED", "STATUS_TRACING_STOP", "STATUS_ZOMBIE", "STATUS_DEAD",
"STATUS_WAKING", "STATUS_LOCKED", "STATUS_WAITING", "STATUS_LOCKED",
"CONN_ESTABLISHED", "CONN_SYN_SENT", "CONN_SYN_RECV", "CONN_FIN_WAIT1",
"CONN_FIN_WAIT2", "CONN_TIME_WAIT", "CONN_CLOSE", "CONN_CLOSE_WAIT",
"CONN_LAST_ACK", "CONN_LISTEN", "CONN_CLOSING", "CONN_NONE",
# classes
"Process", "Popen",
# functions
"pid_exists", "pids", "process_iter", "wait_procs", # proc
"virtual_memory", "swap_memory", # memory
"cpu_times", "cpu_percent", "cpu_times_percent", "cpu_count", # cpu
"net_io_counters", "net_connections", # network
"disk_io_counters", "disk_partitions", "disk_usage", # disk
"users", "boot_time", # others
]
import sys
import os
import time
import signal
import warnings
import errno
import subprocess
try:
import pwd
except ImportError:
pwd = None
from psutil._common import memoize
from psutil._compat import property, callable, long, defaultdict
from psutil._compat import (wraps as _wraps,
PY3 as _PY3)
from psutil._common import (deprecated_method as _deprecated_method,
deprecated as _deprecated,
sdiskio as _nt_sys_diskio,
snetio as _nt_sys_netio)
from psutil._common import (STATUS_RUNNING, # NOQA
STATUS_SLEEPING,
STATUS_DISK_SLEEP,
STATUS_STOPPED,
STATUS_TRACING_STOP,
STATUS_ZOMBIE,
STATUS_DEAD,
STATUS_WAKING,
STATUS_LOCKED,
STATUS_IDLE, # bsd
STATUS_WAITING, # bsd
STATUS_LOCKED) # bsd
from psutil._common import (CONN_ESTABLISHED,
CONN_SYN_SENT,
CONN_SYN_RECV,
CONN_FIN_WAIT1,
CONN_FIN_WAIT2,
CONN_TIME_WAIT,
CONN_CLOSE,
CONN_CLOSE_WAIT,
CONN_LAST_ACK,
CONN_LISTEN,
CONN_CLOSING,
CONN_NONE)
if sys.platform.startswith("linux"):
import psutil._pslinux as _psplatform
from psutil._pslinux import (phymem_buffers, # NOQA
cached_phymem)
from psutil._pslinux import (IOPRIO_CLASS_NONE, # NOQA
IOPRIO_CLASS_RT,
IOPRIO_CLASS_BE,
IOPRIO_CLASS_IDLE)
# Linux >= 2.6.36
if _psplatform.HAS_PRLIMIT:
from _psutil_linux import (RLIM_INFINITY, # NOQA
RLIMIT_AS,
RLIMIT_CORE,
RLIMIT_CPU,
RLIMIT_DATA,
RLIMIT_FSIZE,
RLIMIT_LOCKS,
RLIMIT_MEMLOCK,
RLIMIT_NOFILE,
RLIMIT_NPROC,
RLIMIT_RSS,
RLIMIT_STACK)
# Kinda ugly but considerably faster than using hasattr() and
# setattr() against the module object (we are at import time:
# speed matters).
import _psutil_linux
try:
RLIMIT_MSGQUEUE = _psutil_linux.RLIMIT_MSGQUEUE
except AttributeError:
pass
try:
RLIMIT_NICE = _psutil_linux.RLIMIT_NICE
except AttributeError:
pass
try:
RLIMIT_RTPRIO = _psutil_linux.RLIMIT_RTPRIO
except AttributeError:
pass
try:
RLIMIT_RTTIME = _psutil_linux.RLIMIT_RTTIME
except AttributeError:
pass
try:
RLIMIT_SIGPENDING = _psutil_linux.RLIMIT_SIGPENDING
except AttributeError:
pass
del _psutil_linux
elif sys.platform.startswith("win32"):
import psutil._pswindows as _psplatform
from _psutil_windows import (ABOVE_NORMAL_PRIORITY_CLASS, # NOQA
BELOW_NORMAL_PRIORITY_CLASS,
HIGH_PRIORITY_CLASS,
IDLE_PRIORITY_CLASS,
NORMAL_PRIORITY_CLASS,
REALTIME_PRIORITY_CLASS)
from psutil._pswindows import CONN_DELETE_TCB # NOQA
elif sys.platform.startswith("darwin"):
import psutil._psosx as _psplatform
elif sys.platform.startswith("freebsd"):
import psutil._psbsd as _psplatform
elif sys.platform.startswith("sunos"):
import psutil._pssunos as _psplatform
from psutil._pssunos import (CONN_IDLE, # NOQA
CONN_BOUND)
else:
raise NotImplementedError('platform %s is not supported' % sys.platform)
__all__.extend(_psplatform.__extra__all__)
_TOTAL_PHYMEM = None
_POSIX = os.name == 'posix'
_WINDOWS = os.name == 'nt'
_timer = getattr(time, 'monotonic', time.time)
# =====================================================================
# --- exceptions
# =====================================================================
class Error(Exception):
"""Base exception class. All other psutil exceptions inherit
from this one.
"""
class NoSuchProcess(Error):
"""Exception raised when a process with a certain PID doesn't
or no longer exists (zombie).
"""
def __init__(self, pid, name=None, msg=None):
Error.__init__(self)
self.pid = pid
self.name = name
self.msg = msg
if msg is None:
if name:
details = "(pid=%s, name=%s)" % (self.pid, repr(self.name))
else:
details = "(pid=%s)" % self.pid
self.msg = "process no longer exists " + details
def __str__(self):
return self.msg
class AccessDenied(Error):
"""Exception raised when permission to perform an action is denied."""
def __init__(self, pid=None, name=None, msg=None):
Error.__init__(self)
self.pid = pid
self.name = name
self.msg = msg
if msg is None:
if (pid is not None) and (name is not None):
self.msg = "(pid=%s, name=%s)" % (pid, repr(name))
elif (pid is not None):
self.msg = "(pid=%s)" % self.pid
else:
self.msg = ""
def __str__(self):
return self.msg
class TimeoutExpired(Error):
"""Raised on Process.wait(timeout) if timeout expires and process
is still alive.
"""
def __init__(self, seconds, pid=None, name=None):
Error.__init__(self)
self.seconds = seconds
self.pid = pid
self.name = name
self.msg = "timeout after %s seconds" % seconds
if (pid is not None) and (name is not None):
self.msg += " (pid=%s, name=%s)" % (pid, repr(name))
elif (pid is not None):
self.msg += " (pid=%s)" % self.pid
def __str__(self):
return self.msg
# push exception classes into platform specific module namespace
_psplatform.NoSuchProcess = NoSuchProcess
_psplatform.AccessDenied = AccessDenied
_psplatform.TimeoutExpired = TimeoutExpired
# =====================================================================
# --- Process class
# =====================================================================
def _assert_pid_not_reused(fun):
"""Decorator which raises NoSuchProcess in case a process is no
longer running or its PID has been reused.
"""
@_wraps(fun)
def wrapper(self, *args, **kwargs):
if not self.is_running():
raise NoSuchProcess(self.pid, self._name)
return fun(self, *args, **kwargs)
return wrapper
class Process(object):
"""Represents an OS process with the given PID.
If PID is omitted current process PID (os.getpid()) is used.
Raise NoSuchProcess if PID does not exist.
Note that most of the methods of this class do not make sure
the PID of the process being queried has been reused over time.
That means you might end up retrieving an information referring
to another process in case the original one this instance
refers to is gone in the meantime.
The only exceptions for which process identity is pre-emptively
checked and guaranteed are:
- parent()
- children()
- nice() (set)
- ionice() (set)
- rlimit() (set)
- cpu_affinity (set)
- suspend()
- resume()
- send_signal()
- terminate()
- kill()
To prevent this problem for all other methods you can:
- use is_running() before querying the process
- if you're continuously iterating over a set of Process
instances use process_iter() which pre-emptively checks
process identity for every yielded instance
"""
def __init__(self, pid=None):
self._init(pid)
def _init(self, pid, _ignore_nsp=False):
if pid is None:
pid = os.getpid()
else:
if not _PY3 and not isinstance(pid, (int, long)):
raise TypeError('pid must be an integer (got %r)' % pid)
if pid < 0:
raise ValueError('pid must be a positive integer (got %s)'
% pid)
self._pid = pid
self._name = None
self._exe = None
self._create_time = None
self._gone = False
self._hash = None
# used for caching on Windows only (on POSIX ppid may change)
self._ppid = None
# platform-specific modules define an _psplatform.Process
# implementation class
self._proc = _psplatform.Process(pid)
self._last_sys_cpu_times = None
self._last_proc_cpu_times = None
# cache creation time for later use in is_running() method
try:
self.create_time()
except AccessDenied:
# we should never get here as AFAIK we're able to get
# process creation time on all platforms even as a
# limited user
pass
except NoSuchProcess:
if not _ignore_nsp:
msg = 'no process found with pid %s' % pid
raise NoSuchProcess(pid, None, msg)
else:
self._gone = True
# This pair is supposed to indentify a Process instance
# univocally over time (the PID alone is not enough as
# it might refer to a process whose PID has been reused).
# This will be used later in __eq__() and is_running().
self._ident = (self.pid, self._create_time)
def __str__(self):
try:
pid = self.pid
name = repr(self.name())
except NoSuchProcess:
details = "(pid=%s (terminated))" % self.pid
except AccessDenied:
details = "(pid=%s)" % (self.pid)
else:
details = "(pid=%s, name=%s)" % (pid, name)
return "%s.%s%s" % (self.__class__.__module__,
self.__class__.__name__, details)
def __repr__(self):
return "<%s at %s>" % (self.__str__(), id(self))
def __eq__(self, other):
# Test for equality with another Process object based
# on PID and creation time.
if not isinstance(other, Process):
return NotImplemented
return self._ident == other._ident
def __ne__(self, other):
return not self == other
def __hash__(self):
if self._hash is None:
self._hash = hash(self._ident)
return self._hash
# --- utility methods
def as_dict(self, attrs=[], ad_value=None):
"""Utility method returning process information as a
hashable dictionary.
If 'attrs' is specified it must be a list of strings
reflecting available Process class' attribute names
(e.g. ['cpu_times', 'name']) else all public (read
only) attributes are assumed.
'ad_value' is the value which gets assigned in case
AccessDenied exception is raised when retrieving that
particular process information.
"""
excluded_names = set(
['send_signal', 'suspend', 'resume', 'terminate', 'kill', 'wait',
'is_running', 'as_dict', 'parent', 'children', 'rlimit'])
retdict = dict()
ls = set(attrs or [x for x in dir(self) if not x.startswith('get')])
for name in ls:
if name.startswith('_'):
continue
if name.startswith('set_'):
continue
if name.startswith('get_'):
msg = "%s() is deprecated; use %s() instead" % (name, name[4:])
warnings.warn(msg, category=DeprecationWarning, stacklevel=2)
name = name[4:]
if name in ls:
continue
if name == 'getcwd':
msg = "getcwd() is deprecated; use cwd() instead"
warnings.warn(msg, category=DeprecationWarning, stacklevel=2)
name = 'cwd'
if name in ls:
continue
if name in excluded_names:
continue
try:
attr = getattr(self, name)
if callable(attr):
ret = attr()
else:
ret = attr
except AccessDenied:
ret = ad_value
except NotImplementedError:
# in case of not implemented functionality (may happen
# on old or exotic systems) we want to crash only if
# the user explicitly asked for that particular attr
if attrs:
raise
continue
retdict[name] = ret
return retdict
def parent(self):
"""Return the parent process as a Process object pre-emptively
checking whether PID has been reused.
If no parent is known return None.
"""
ppid = self.ppid()
if ppid is not None:
try:
parent = Process(ppid)
if parent.create_time() <= self.create_time():
return parent
# ...else ppid has been reused by another process
except NoSuchProcess:
pass
def is_running(self):
"""Return whether this process is running.
It also checks if PID has been reused by another process in
which case return False.
"""
if self._gone:
return False
try:
# Checking if PID is alive is not enough as the PID might
# have been reused by another process: we also want to
# check process identity.
# Process identity / uniqueness over time is greanted by
# (PID + creation time) and that is verified in __eq__.
return self == Process(self.pid)
except NoSuchProcess:
self._gone = True
return False
# --- actual API
@property
def pid(self):
"""The process PID."""
return self._pid
def ppid(self):
"""The process parent PID.
On Windows the return value is cached after first call.
"""
# On POSIX we don't want to cache the ppid as it may unexpectedly
# change to 1 (init) in case this process turns into a zombie:
# https://github.com/giampaolo/psutil/issues/321
# http://stackoverflow.com/questions/356722/
# XXX should we check creation time here rather than in
# Process.parent()?
if _POSIX:
return self._proc.ppid()
else:
if self._ppid is None:
self._ppid = self._proc.ppid()
return self._ppid
def name(self):
"""The process name. The return value is cached after first call."""
if self._name is None:
name = self._proc.name()
if _POSIX and len(name) >= 15:
# On UNIX the name gets truncated to the first 15 characters.
# If it matches the first part of the cmdline we return that
# one instead because it's usually more explicative.
# Examples are "gnome-keyring-d" vs. "gnome-keyring-daemon".
try:
cmdline = self.cmdline()
except AccessDenied:
pass
else:
if cmdline:
extended_name = os.path.basename(cmdline[0])
if extended_name.startswith(name):
name = extended_name
self._proc._name = name
self._name = name
return self._name
def exe(self):
"""The process executable as an absolute path.
May also be an empty string.
The return value is cached after first call.
"""
def guess_it(fallback):
# try to guess exe from cmdline[0] in absence of a native
# exe representation
cmdline = self.cmdline()
if cmdline and hasattr(os, 'access') and hasattr(os, 'X_OK'):
exe = cmdline[0] # the possible exe
# Attempt to guess only in case of an absolute path.
# It is not safe otherwise as the process might have
# changed cwd.
if (os.path.isabs(exe)
and os.path.isfile(exe)
and os.access(exe, os.X_OK)):
return exe
if isinstance(fallback, AccessDenied):
raise fallback
return fallback
if self._exe is None:
try:
exe = self._proc.exe()
except AccessDenied:
err = sys.exc_info()[1]
return guess_it(fallback=err)
else:
if not exe:
# underlying implementation can legitimately return an
# empty string; if that's the case we don't want to
# raise AD while guessing from the cmdline
try:
exe = guess_it(fallback=exe)
except AccessDenied:
pass
self._exe = exe
return self._exe
def cmdline(self):
"""The command line this process has been called with."""
return self._proc.cmdline()
def status(self):
"""The process current status as a STATUS_* constant."""
return self._proc.status()
def username(self):
"""The name of the user that owns the process.
On UNIX this is calculated by using *real* process uid.
"""
if _POSIX:
if pwd is None:
# might happen if python was installed from sources
raise ImportError(
"requires pwd module shipped with standard python")
return pwd.getpwuid(self.uids().real).pw_name
else:
return self._proc.username()
def create_time(self):
"""The process creation time as a floating point number
expressed in seconds since the epoch, in UTC.
The return value is cached after first call.
"""
if self._create_time is None:
self._create_time = self._proc.create_time()
return self._create_time
def cwd(self):
"""Process current working directory as an absolute path."""
return self._proc.cwd()
def nice(self, value=None):
"""Get or set process niceness (priority)."""
if value is None:
return self._proc.nice_get()
else:
if not self.is_running():
raise NoSuchProcess(self.pid, self._name)
self._proc.nice_set(value)
if _POSIX:
def uids(self):
"""Return process UIDs as a (real, effective, saved)
namedtuple.
"""
return self._proc.uids()
def gids(self):
"""Return process GIDs as a (real, effective, saved)
namedtuple.
"""
return self._proc.gids()
def terminal(self):
"""The terminal associated with this process, if any,
else None.
"""
return self._proc.terminal()
def num_fds(self):
"""Return the number of file descriptors opened by this
process (POSIX only).
"""
return self._proc.num_fds()
# Linux, BSD and Windows only
if hasattr(_psplatform.Process, "io_counters"):
def io_counters(self):
"""Return process I/O statistics as a
(read_count, write_count, read_bytes, write_bytes)
namedtuple.
Those are the number of read/write calls performed and the
amount of bytes read and written by the process.
"""
return self._proc.io_counters()
# Linux and Windows >= Vista only
if hasattr(_psplatform.Process, "ionice_get"):
def ionice(self, ioclass=None, value=None):
"""Get or set process I/O niceness (priority).
On Linux 'ioclass' is one of the IOPRIO_CLASS_* constants.
'value' is a number which goes from 0 to 7. The higher the
value, the lower the I/O priority of the process.
On Windows only 'ioclass' is used and it can be set to 2
(normal), 1 (low) or 0 (very low).
Available on Linux and Windows > Vista only.
"""
if ioclass is None:
if value is not None:
raise ValueError("'ioclass' must be specified")
return self._proc.ionice_get()
else:
return self._proc.ionice_set(ioclass, value)
# Linux only
if hasattr(_psplatform.Process, "rlimit"):
def rlimit(self, resource, limits=None):
"""Get or set process resource limits as a (soft, hard)
tuple.
'resource' is one of the RLIMIT_* constants.
'limits' is supposed to be a (soft, hard) tuple.
See "man prlimit" for further info.
Available on Linux only.
"""
if limits is None:
return self._proc.rlimit(resource)
else:
return self._proc.rlimit(resource, limits)
# Windows and Linux only
if hasattr(_psplatform.Process, "cpu_affinity_get"):
def cpu_affinity(self, cpus=None):
"""Get or set process CPU affinity.
If specified 'cpus' must be a list of CPUs for which you
want to set the affinity (e.g. [0, 1]).
"""
if cpus is None:
return self._proc.cpu_affinity_get()
else:
self._proc.cpu_affinity_set(cpus)
if _WINDOWS:
def num_handles(self):
"""Return the number of handles opened by this process
(Windows only).
"""
return self._proc.num_handles()
def num_ctx_switches(self):
"""Return the number of voluntary and involuntary context
switches performed by this process.
"""
return self._proc.num_ctx_switches()
def num_threads(self):
"""Return the number of threads used by this process."""
return self._proc.num_threads()
def threads(self):
"""Return threads opened by process as a list of
(id, user_time, system_time) namedtuples representing
thread id and thread CPU times (user/system).
"""
return self._proc.threads()
@_assert_pid_not_reused
def children(self, recursive=False):
"""Return the children of this process as a list of Process
instances, pre-emptively checking whether PID has been reused.
If recursive is True return all the parent descendants.
Example (A == this process):
A ─┐
│
├─ B (child) ─┐
│ └─ X (grandchild) ─┐
│ └─ Y (great grandchild)
├─ C (child)
└─ D (child)
>>> import psutil
>>> p = psutil.Process()
>>> p.children()
B, C, D
>>> p.children(recursive=True)
B, X, Y, C, D
Note that in the example above if process X disappears
process Y won't be listed as the reference to process A
is lost.
"""
if hasattr(_psplatform, 'ppid_map'):
# Windows only: obtain a {pid:ppid, ...} dict for all running
# processes in one shot (faster).
ppid_map = _psplatform.ppid_map()
else:
ppid_map = None
ret = []
if not recursive:
if ppid_map is None:
# 'slow' version, common to all platforms except Windows
for p in process_iter():
try:
if p.ppid() == self.pid:
# if child happens to be older than its parent
# (self) it means child's PID has been reused
if self.create_time() <= p.create_time():
ret.append(p)
except NoSuchProcess:
pass
else:
# Windows only (faster)
for pid, ppid in ppid_map.items():
if ppid == self.pid:
try:
child = Process(pid)
# if child happens to be older than its parent
# (self) it means child's PID has been reused
if self.create_time() <= child.create_time():
ret.append(child)
except NoSuchProcess:
pass
else:
# construct a dict where 'values' are all the processes
# having 'key' as their parent
table = defaultdict(list)
if ppid_map is None:
for p in process_iter():
try:
table[p.ppid()].append(p)
except NoSuchProcess:
pass
else:
for pid, ppid in ppid_map.items():
try:
p = Process(pid)
table[ppid].append(p)
except NoSuchProcess:
pass
# At this point we have a mapping table where table[self.pid]
# are the current process' children.
# Below, we look for all descendants recursively, similarly
# to a recursive function call.
checkpids = [self.pid]
for pid in checkpids:
for child in table[pid]:
try:
# if child happens to be older than its parent
# (self) it means child's PID has been reused
intime = self.create_time() <= child.create_time()
except NoSuchProcess:
pass
else:
if intime:
ret.append(child)
if child.pid not in checkpids:
checkpids.append(child.pid)
return ret
def cpu_percent(self, interval=None):
"""Return a float representing the current process CPU
utilization as a percentage.
When interval is 0.0 or None (default) compares process times
to system CPU times elapsed since last call, returning
immediately (non-blocking). That means that the first time
this is called it will return a meaningful 0.0 value.
When interval is > 0.0 compares process times to system CPU
times elapsed before and after the interval (blocking).
In this case is recommended for accuracy that this function
be called with at least 0.1 seconds between calls.
Examples:
>>> import psutil
>>> p = psutil.Process(os.getpid())
>>> # blocking
>>> p.cpu_percent(interval=1)
2.0
>>> # non-blocking (percentage since last call)
>>> p.cpu_percent(interval=None)
2.9
>>>
"""
blocking = interval is not None and interval > 0.0
num_cpus = cpu_count()
if _POSIX:
timer = lambda: _timer() * num_cpus
else:
timer = lambda: sum(cpu_times())
if blocking:
st1 = timer()
pt1 = self._proc.cpu_times()
time.sleep(interval)
st2 = timer()
pt2 = self._proc.cpu_times()
else:
st1 = self._last_sys_cpu_times
pt1 = self._last_proc_cpu_times
st2 = timer()
pt2 = self._proc.cpu_times()
if st1 is None or pt1 is None:
self._last_sys_cpu_times = st2
self._last_proc_cpu_times = pt2
return 0.0
delta_proc = (pt2.user - pt1.user) + (pt2.system - pt1.system)
delta_time = st2 - st1
# reset values for next call in case of interval == None
self._last_sys_cpu_times = st2
self._last_proc_cpu_times = pt2
try:
# The utilization split between all CPUs.
# Note: a percentage > 100 is legitimate as it can result
# from a process with multiple threads running on different
# CPU cores, see:
# http://stackoverflow.com/questions/1032357
# https://github.com/giampaolo/psutil/issues/474
overall_percent = ((delta_proc / delta_time) * 100) * num_cpus
except ZeroDivisionError:
# interval was too low
return 0.0
else:
return round(overall_percent, 1)
def cpu_times(self):
"""Return a (user, system) namedtuple representing the
accumulated process time, in seconds.
This is the same as os.times() but per-process.
"""
return self._proc.cpu_times()
def memory_info(self):
"""Return a tuple representing RSS (Resident Set Size) and VMS
(Virtual Memory Size) in bytes.
On UNIX RSS and VMS are the same values shown by 'ps'.
On Windows RSS and VMS refer to "Mem Usage" and "VM Size"
columns of taskmgr.exe.
"""
return self._proc.memory_info()
def memory_info_ex(self):
"""Return a namedtuple with variable fields depending on the
platform representing extended memory information about
this process. All numbers are expressed in bytes.
"""
return self._proc.memory_info_ex()
def memory_percent(self):
"""Compare physical system memory to process resident memory
(RSS) and calculate process memory utilization as a percentage.
"""
rss = self._proc.memory_info()[0]
# use cached value if available
total_phymem = _TOTAL_PHYMEM or virtual_memory().total
try:
return (rss / float(total_phymem)) * 100
except ZeroDivisionError:
return 0.0
def memory_maps(self, grouped=True):
"""Return process' mapped memory regions as a list of nameduples
whose fields are variable depending on the platform.
If 'grouped' is True the mapped regions with the same 'path'
are grouped together and the different memory fields are summed.
If 'grouped' is False every mapped region is shown as a single
entity and the namedtuple will also include the mapped region's
address space ('addr') and permission set ('perms').
"""
it = self._proc.memory_maps()
if grouped:
d = {}
for tupl in it:
path = tupl[2]
nums = tupl[3:]
try:
d[path] = map(lambda x, y: x + y, d[path], nums)
except KeyError:
d[path] = nums
nt = _psplatform.pmmap_grouped
return [nt(path, *d[path]) for path in d] # NOQA
else:
nt = _psplatform.pmmap_ext
return [nt(*x) for x in it]
def open_files(self):
"""Return files opened by process as a list of
(path, fd) namedtuples including the absolute file name
and file descriptor number.
"""
return self._proc.open_files()
def connections(self, kind='inet'):
"""Return connections opened by process as a list of
(fd, family, type, laddr, raddr, status) namedtuples.
The 'kind' parameter filters for connections that match the
following criteria:
Kind Value Connections using
inet IPv4 and IPv6
inet4 IPv4
inet6 IPv6
tcp TCP
tcp4 TCP over IPv4
tcp6 TCP over IPv6
udp UDP
udp4 UDP over IPv4
udp6 UDP over IPv6
unix UNIX socket (both UDP and TCP protocols)
all the sum of all the possible families and protocols
"""
return self._proc.connections(kind)
if _POSIX:
def _send_signal(self, sig):
try:
os.kill(self.pid, sig)
except OSError:
err = sys.exc_info()[1]
if err.errno == errno.ESRCH:
self._gone = True
raise NoSuchProcess(self.pid, self._name)
if err.errno == errno.EPERM:
raise AccessDenied(self.pid, self._name)
raise
@_assert_pid_not_reused
def send_signal(self, sig):
"""Send a signal to process pre-emptively checking whether
PID has been reused (see signal module constants) .
On Windows only SIGTERM is valid and is treated as an alias
for kill().
"""
if _POSIX:
self._send_signal(sig)
else:
if sig == signal.SIGTERM:
self._proc.kill()
else:
raise ValueError("only SIGTERM is supported on Windows")
@_assert_pid_not_reused
def suspend(self):
"""Suspend process execution with SIGSTOP pre-emptively checking
whether PID has been reused.
On Windows this has the effect ot suspending all process threads.
"""
if _POSIX:
self._send_signal(signal.SIGSTOP)
else:
self._proc.suspend()
@_assert_pid_not_reused
def resume(self):
"""Resume process execution with SIGCONT pre-emptively checking
whether PID has been reused.
On Windows this has the effect of resuming all process threads.
"""
if _POSIX:
self._send_signal(signal.SIGCONT)
else:
self._proc.resume()
@_assert_pid_not_reused
def terminate(self):
"""Terminate the process with SIGTERM pre-emptively checking
whether PID has been reused.
On Windows this is an alias for kill().
"""
if _POSIX:
self._send_signal(signal.SIGTERM)
else:
self._proc.kill()
@_assert_pid_not_reused
def kill(self):
"""Kill the current process with SIGKILL pre-emptively checking
whether PID has been reused.
"""
if _POSIX:
self._send_signal(signal.SIGKILL)
else:
self._proc.kill()
def wait(self, timeout=None):
"""Wait for process to terminate and, if process is a children
of os.getpid(), also return its exit code, else None.
If the process is already terminated immediately return None
instead of raising NoSuchProcess.
If timeout (in seconds) is specified and process is still alive
raise TimeoutExpired.
To wait for multiple Process(es) use psutil.wait_procs().
"""
if timeout is not None and not timeout >= 0:
raise ValueError("timeout must be a positive integer")
return self._proc.wait(timeout)
# --- deprecated APIs
_locals = set(locals())
@_deprecated_method(replacement='children')
def get_children(self):
pass
@_deprecated_method(replacement='connections')
def get_connections(self):
pass
if "cpu_affinity" in _locals:
@_deprecated_method(replacement='cpu_affinity')
def get_cpu_affinity(self):
pass
@_deprecated_method(replacement='cpu_affinity')
def set_cpu_affinity(self, cpus):
pass
@_deprecated_method(replacement='cpu_percent')
def get_cpu_percent(self):
pass
@_deprecated_method(replacement='cpu_times')
def get_cpu_times(self):
pass
@_deprecated_method(replacement='cwd')
def getcwd(self):
pass
@_deprecated_method(replacement='memory_info_ex')
def get_ext_memory_info(self):
pass
if "io_counters" in _locals:
@_deprecated_method(replacement='io_counters')
def get_io_counters(self):
pass
if "ionice" in _locals:
@_deprecated_method(replacement='ionice')
def get_ionice(self):
pass
@_deprecated_method(replacement='ionice')
def set_ionice(self, ioclass, value=None):
pass
@_deprecated_method(replacement='memory_info')
def get_memory_info(self):
pass
@_deprecated_method(replacement='memory_maps')
def get_memory_maps(self):
pass
@_deprecated_method(replacement='memory_percent')
def get_memory_percent(self):
pass
@_deprecated_method(replacement='nice')
def get_nice(self):
pass
@_deprecated_method(replacement='num_ctx_switches')
def get_num_ctx_switches(self):
pass
if 'num_fds' in _locals:
@_deprecated_method(replacement='num_fds')
def get_num_fds(self):
pass
if 'num_handles' in _locals:
@_deprecated_method(replacement='num_handles')
def get_num_handles(self):
pass
@_deprecated_method(replacement='num_threads')
def get_num_threads(self):
pass
@_deprecated_method(replacement='open_files')
def get_open_files(self):
pass
if "rlimit" in _locals:
@_deprecated_method(replacement='rlimit')
def get_rlimit(self):
pass
@_deprecated_method(replacement='rlimit')
def set_rlimit(self, resource, limits):
pass
@_deprecated_method(replacement='threads')
def get_threads(self):
pass
@_deprecated_method(replacement='nice')
def set_nice(self, value):
pass
del _locals
# =====================================================================
# --- Popen class
# =====================================================================
class Popen(Process):
"""A more convenient interface to stdlib subprocess module.
It starts a sub process and deals with it exactly as when using
subprocess.Popen class but in addition also provides all the
properties and methods of psutil.Process class as a unified
interface:
>>> import psutil
>>> from subprocess import PIPE
>>> p = psutil.Popen(["python", "-c", "print 'hi'"], stdout=PIPE)
>>> p.name()
'python'
>>> p.uids()
user(real=1000, effective=1000, saved=1000)
>>> p.username()
'giampaolo'
>>> p.communicate()
('hi\n', None)
>>> p.terminate()
>>> p.wait(timeout=2)
0
>>>
For method names common to both classes such as kill(), terminate()
and wait(), psutil.Process implementation takes precedence.
Unlike subprocess.Popen this class pre-emptively checks wheter PID
has been reused on send_signal(), terminate() and kill() so that
you don't accidentally terminate another process, fixing
http://bugs.python.org/issue6973.
For a complete documentation refer to:
http://docs.python.org/library/subprocess.html
"""
def __init__(self, *args, **kwargs):
# Explicitly avoid to raise NoSuchProcess in case the process
# spawned by subprocess.Popen terminates too quickly, see:
# https://github.com/giampaolo/psutil/issues/193
self.__subproc = subprocess.Popen(*args, **kwargs)
self._init(self.__subproc.pid, _ignore_nsp=True)
def __dir__(self):
return sorted(set(dir(Popen) + dir(subprocess.Popen)))
def __getattribute__(self, name):
try:
return object.__getattribute__(self, name)
except AttributeError:
try:
return object.__getattribute__(self.__subproc, name)
except AttributeError:
raise AttributeError("%s instance has no attribute '%s'"
% (self.__class__.__name__, name))
def wait(self, timeout=None):
if self.__subproc.returncode is not None:
return self.__subproc.returncode
ret = super(Popen, self).wait(timeout)
self.__subproc.returncode = ret
return ret
# =====================================================================
# --- system processes related functions
# =====================================================================
def pids():
"""Return a list of current running PIDs."""
return _psplatform.pids()
def pid_exists(pid):
"""Return True if given PID exists in the current process list.
This is faster than doing "pid in psutil.pids()" and
should be preferred.
"""
if pid < 0:
return False
elif pid == 0 and _POSIX:
# On POSIX we use os.kill() to determine PID existence.
# According to "man 2 kill" PID 0 has a special meaning
# though: it refers to <<every process in the process
# group of the calling process>> and that is not we want
# to do here.
return pid in pids()
else:
return _psplatform.pid_exists(pid)
_pmap = {}
def process_iter():
"""Return a generator yielding a Process instance for all
running processes.
Every new Process instance is only created once and then cached
into an internal table which is updated every time this is used.
Cached Process instances are checked for identity so that you're
safe in case a PID has been reused by another process, in which
case the cached instance is updated.
The sorting order in which processes are yielded is based on
their PIDs.
"""
def add(pid):
proc = Process(pid)
_pmap[proc.pid] = proc
return proc
def remove(pid):
_pmap.pop(pid, None)
a = set(pids())
b = set(_pmap.keys())
new_pids = a - b
gone_pids = b - a
for pid in gone_pids:
remove(pid)
for pid, proc in sorted(list(_pmap.items()) +
list(dict.fromkeys(new_pids).items())):
try:
if proc is None: # new process
yield add(pid)
else:
# use is_running() to check whether PID has been reused by
# another process in which case yield a new Process instance
if proc.is_running():
yield proc
else:
yield add(pid)
except NoSuchProcess:
remove(pid)
except AccessDenied:
# Process creation time can't be determined hence there's
# no way to tell whether the pid of the cached process
# has been reused. Just return the cached version.
yield proc
def wait_procs(procs, timeout=None, callback=None):
"""Convenience function which waits for a list of processes to
terminate.
Return a (gone, alive) tuple indicating which processes
are gone and which ones are still alive.
The gone ones will have a new 'returncode' attribute indicating
process exit status (may be None).
'callback' is a function which gets called every time a process
terminates (a Process instance is passed as callback argument).
Function will return as soon as all processes terminate or when
timeout occurs.
Typical use case is:
- send SIGTERM to a list of processes
- give them some time to terminate
- send SIGKILL to those ones which are still alive
Example:
>>> def on_terminate(proc):
... print("process {} terminated".format(proc))
...
>>> for p in procs:
... p.terminate()
...
>>> gone, alive = wait_procs(procs, timeout=3, callback=on_terminate)
>>> for p in alive:
... p.kill()
"""
def check_gone(proc, timeout):
try:
returncode = proc.wait(timeout=timeout)
except TimeoutExpired:
pass
else:
if returncode is not None or not proc.is_running():
proc.returncode = returncode
gone.add(proc)
if callback is not None:
callback(proc)
if timeout is not None and not timeout >= 0:
msg = "timeout must be a positive integer, got %s" % timeout
raise ValueError(msg)
gone = set()
alive = set(procs)
if callback is not None and not callable(callback):
raise TypeError("callback %r is not a callable" % callable)
if timeout is not None:
deadline = _timer() + timeout
while alive:
if timeout is not None and timeout <= 0:
break
for proc in alive:
# Make sure that every complete iteration (all processes)
# will last max 1 sec.
# We do this because we don't want to wait too long on a
# single process: in case it terminates too late other
# processes may disappear in the meantime and their PID
# reused.
max_timeout = 1.0 / len(alive)
if timeout is not None:
timeout = min((deadline - _timer()), max_timeout)
if timeout <= 0:
break
check_gone(proc, timeout)
else:
check_gone(proc, max_timeout)
alive = alive - gone
if alive:
# Last attempt over processes survived so far.
# timeout == 0 won't make this function wait any further.
for proc in alive:
check_gone(proc, 0)
alive = alive - gone
return (list(gone), list(alive))
# =====================================================================
# --- CPU related functions
# =====================================================================
@memoize
def cpu_count(logical=True):
"""Return the number of logical CPUs in the system (same as
os.cpu_count() in Python 3.4).
If logical is False return the number of physical cores only
(hyper thread CPUs are excluded).
Return None if undetermined.
The return value is cached after first call.
If desired cache can be cleared like this:
>>> psutil.cpu_count.cache_clear()
"""
if logical:
return _psplatform.cpu_count_logical()
else:
return _psplatform.cpu_count_physical()
def cpu_times(percpu=False):
"""Return system-wide CPU times as a namedtuple.
Every CPU time represents the seconds the CPU has spent in the given mode.
The namedtuple's fields availability varies depending on the platform:
- user
- system
- idle
- nice (UNIX)
- iowait (Linux)
- irq (Linux, FreeBSD)
- softirq (Linux)
- steal (Linux >= 2.6.11)
- guest (Linux >= 2.6.24)
- guest_nice (Linux >= 3.2.0)
When percpu is True return a list of nameduples for each CPU.
First element of the list refers to first CPU, second element
to second CPU and so on.
The order of the list is consistent across calls.
"""
if not percpu:
return _psplatform.cpu_times()
else:
return _psplatform.per_cpu_times()
_last_cpu_times = cpu_times()
_last_per_cpu_times = cpu_times(percpu=True)
def cpu_percent(interval=None, percpu=False):
"""Return a float representing the current system-wide CPU
utilization as a percentage.
When interval is > 0.0 compares system CPU times elapsed before
and after the interval (blocking).
When interval is 0.0 or None compares system CPU times elapsed
since last call or module import, returning immediately (non
blocking). That means the first time this is called it will
return a meaningless 0.0 value which you should ignore.
In this case is recommended for accuracy that this function be
called with at least 0.1 seconds between calls.
When percpu is True returns a list of floats representing the
utilization as a percentage for each CPU.
First element of the list refers to first CPU, second element
to second CPU and so on.
The order of the list is consistent across calls.
Examples:
>>> # blocking, system-wide
>>> psutil.cpu_percent(interval=1)
2.0
>>>
>>> # blocking, per-cpu
>>> psutil.cpu_percent(interval=1, percpu=True)
[2.0, 1.0]
>>>
>>> # non-blocking (percentage since last call)
>>> psutil.cpu_percent(interval=None)
2.9
>>>
"""
global _last_cpu_times
global _last_per_cpu_times
blocking = interval is not None and interval > 0.0
def calculate(t1, t2):
t1_all = sum(t1)
t1_busy = t1_all - t1.idle
t2_all = sum(t2)
t2_busy = t2_all - t2.idle
# this usually indicates a float precision issue
if t2_busy <= t1_busy:
return 0.0
busy_delta = t2_busy - t1_busy
all_delta = t2_all - t1_all
busy_perc = (busy_delta / all_delta) * 100
return round(busy_perc, 1)
# system-wide usage
if not percpu:
if blocking:
t1 = cpu_times()
time.sleep(interval)
else:
t1 = _last_cpu_times
_last_cpu_times = cpu_times()
return calculate(t1, _last_cpu_times)
# per-cpu usage
else:
ret = []
if blocking:
tot1 = cpu_times(percpu=True)
time.sleep(interval)
else:
tot1 = _last_per_cpu_times
_last_per_cpu_times = cpu_times(percpu=True)
for t1, t2 in zip(tot1, _last_per_cpu_times):
ret.append(calculate(t1, t2))
return ret
# Use separate global vars for cpu_times_percent() so that it's
# independent from cpu_percent() and they can both be used within
# the same program.
_last_cpu_times_2 = _last_cpu_times
_last_per_cpu_times_2 = _last_per_cpu_times
def cpu_times_percent(interval=None, percpu=False):
"""Same as cpu_percent() but provides utilization percentages
for each specific CPU time as is returned by cpu_times().
For instance, on Linux we'll get:
>>> cpu_times_percent()
cpupercent(user=4.8, nice=0.0, system=4.8, idle=90.5, iowait=0.0,
irq=0.0, softirq=0.0, steal=0.0, guest=0.0, guest_nice=0.0)
>>>
interval and percpu arguments have the same meaning as in
cpu_percent().
"""
global _last_cpu_times_2
global _last_per_cpu_times_2
blocking = interval is not None and interval > 0.0
def calculate(t1, t2):
nums = []
all_delta = sum(t2) - sum(t1)
for field in t1._fields:
field_delta = getattr(t2, field) - getattr(t1, field)
try:
field_perc = (100 * field_delta) / all_delta
except ZeroDivisionError:
field_perc = 0.0
field_perc = round(field_perc, 1)
if _WINDOWS:
# XXX
# Work around:
# https://github.com/giampaolo/psutil/issues/392
# CPU times are always supposed to increase over time
# or at least remain the same and that's because time
# cannot go backwards.
# Surprisingly sometimes this might not be the case on
# Windows where 'system' CPU time can be smaller
# compared to the previous call, resulting in corrupted
# percentages (< 0 or > 100).
# I really don't know what to do about that except
# forcing the value to 0 or 100.
if field_perc > 100.0:
field_perc = 100.0
elif field_perc < 0.0:
field_perc = 0.0
nums.append(field_perc)
return _psplatform.scputimes(*nums)
# system-wide usage
if not percpu:
if blocking:
t1 = cpu_times()
time.sleep(interval)
else:
t1 = _last_cpu_times_2
_last_cpu_times_2 = cpu_times()
return calculate(t1, _last_cpu_times_2)
# per-cpu usage
else:
ret = []
if blocking:
tot1 = cpu_times(percpu=True)
time.sleep(interval)
else:
tot1 = _last_per_cpu_times_2
_last_per_cpu_times_2 = cpu_times(percpu=True)
for t1, t2 in zip(tot1, _last_per_cpu_times_2):
ret.append(calculate(t1, t2))
return ret
# =====================================================================
# --- system memory related functions
# =====================================================================
def virtual_memory():
"""Return statistics about system memory usage as a namedtuple
including the following fields, expressed in bytes:
- total:
total physical memory available.
- available:
the actual amount of available memory that can be given
instantly to processes that request more memory in bytes; this
is calculated by summing different memory values depending on
the platform (e.g. free + buffers + cached on Linux) and it is
supposed to be used to monitor actual memory usage in a cross
platform fashion.
- percent:
the percentage usage calculated as (total - available) / total * 100
- used:
memory used, calculated differently depending on the platform and
designed for informational purposes only:
OSX: active + inactive + wired
BSD: active + wired + cached
LINUX: total - free
- free:
memory not being used at all (zeroed) that is readily available;
note that this doesn't reflect the actual memory available
(use 'available' instead)
Platform-specific fields:
- active (UNIX):
memory currently in use or very recently used, and so it is in RAM.
- inactive (UNIX):
memory that is marked as not used.
- buffers (BSD, Linux):
cache for things like file system metadata.
- cached (BSD, OSX):
cache for various things.
- wired (OSX, BSD):
memory that is marked to always stay in RAM. It is never moved to disk.
- shared (BSD):
memory that may be simultaneously accessed by multiple processes.
The sum of 'used' and 'available' does not necessarily equal total.
On Windows 'available' and 'free' are the same.
"""
global _TOTAL_PHYMEM
ret = _psplatform.virtual_memory()
# cached for later use in Process.memory_percent()
_TOTAL_PHYMEM = ret.total
return ret
def swap_memory():
"""Return system swap memory statistics as a namedtuple including
the following fields:
- total: total swap memory in bytes
- used: used swap memory in bytes
- free: free swap memory in bytes
- percent: the percentage usage
- sin: no. of bytes the system has swapped in from disk (cumulative)
- sout: no. of bytes the system has swapped out from disk (cumulative)
'sin' and 'sout' on Windows are meaningless and always set to 0.
"""
return _psplatform.swap_memory()
# =====================================================================
# --- disks/paritions related functions
# =====================================================================
def disk_usage(path):
"""Return disk usage statistics about the given path as a namedtuple
including total, used and free space expressed in bytes plus the
percentage usage.
"""
return _psplatform.disk_usage(path)
def disk_partitions(all=False):
"""Return mounted partitions as a list of
(device, mountpoint, fstype, opts) namedtuple.
'opts' field is a raw string separated by commas indicating mount
options which may vary depending on the platform.
If "all" parameter is False return physical devices only and ignore
all others.
"""
return _psplatform.disk_partitions(all)
def disk_io_counters(perdisk=False):
"""Return system disk I/O statistics as a namedtuple including
the following fields:
- read_count: number of reads
- write_count: number of writes
- read_bytes: number of bytes read
- write_bytes: number of bytes written
- read_time: time spent reading from disk (in milliseconds)
- write_time: time spent writing to disk (in milliseconds)
If perdisk is True return the same information for every
physical disk installed on the system as a dictionary
with partition names as the keys and the namedutuple
described above as the values.
On recent Windows versions 'diskperf -y' command may need to be
executed first otherwise this function won't find any disk.
"""
rawdict = _psplatform.disk_io_counters()
if not rawdict:
raise RuntimeError("couldn't find any physical disk")
if perdisk:
for disk, fields in rawdict.items():
rawdict[disk] = _nt_sys_diskio(*fields)
return rawdict
else:
return _nt_sys_diskio(*[sum(x) for x in zip(*rawdict.values())])
# =====================================================================
# --- network related functions
# =====================================================================
def net_io_counters(pernic=False):
"""Return network I/O statistics as a namedtuple including
the following fields:
- bytes_sent: number of bytes sent
- bytes_recv: number of bytes received
- packets_sent: number of packets sent
- packets_recv: number of packets received
- errin: total number of errors while receiving
- errout: total number of errors while sending
- dropin: total number of incoming packets which were dropped
- dropout: total number of outgoing packets which were dropped
(always 0 on OSX and BSD)
If pernic is True return the same information for every
network interface installed on the system as a dictionary
with network interface names as the keys and the namedtuple
described above as the values.
"""
rawdict = _psplatform.net_io_counters()
if not rawdict:
raise RuntimeError("couldn't find any network interface")
if pernic:
for nic, fields in rawdict.items():
rawdict[nic] = _nt_sys_netio(*fields)
return rawdict
else:
return _nt_sys_netio(*[sum(x) for x in zip(*rawdict.values())])
def net_connections(kind='inet'):
"""Return system-wide connections as a list of
(fd, family, type, laddr, raddr, status, pid) namedtuples.
In case of limited privileges 'fd' and 'pid' may be set to -1
and None respectively.
The 'kind' parameter filters for connections that fit the
following criteria:
Kind Value Connections using
inet IPv4 and IPv6
inet4 IPv4
inet6 IPv6
tcp TCP
tcp4 TCP over IPv4
tcp6 TCP over IPv6
udp UDP
udp4 UDP over IPv4
udp6 UDP over IPv6
unix UNIX socket (both UDP and TCP protocols)
all the sum of all the possible families and protocols
"""
return _psplatform.net_connections(kind)
# =====================================================================
# --- other system related functions
# =====================================================================
def boot_time():
"""Return the system boot time expressed in seconds since the epoch.
This is also available as psutil.BOOT_TIME.
"""
# Note: we are not caching this because it is subject to
# system clock updates.
return _psplatform.boot_time()
def users():
"""Return users currently connected on the system as a list of
namedtuples including the following fields.
- user: the name of the user
- terminal: the tty or pseudo-tty associated with the user, if any.
- host: the host name associated with the entry, if any.
- started: the creation time as a floating point number expressed in
seconds since the epoch.
"""
return _psplatform.users()
# =====================================================================
# --- deprecated functions
# =====================================================================
@_deprecated(replacement="psutil.pids()")
def get_pid_list():
return pids()
@_deprecated(replacement="list(process_iter())")
def get_process_list():
return list(process_iter())
@_deprecated(replacement="psutil.users()")
def get_users():
return users()
@_deprecated(replacement="psutil.virtual_memory()")
def phymem_usage():
"""Return the amount of total, used and free physical memory
on the system in bytes plus the percentage usage.
Deprecated; use psutil.virtual_memory() instead.
"""
return virtual_memory()
@_deprecated(replacement="psutil.swap_memory()")
def virtmem_usage():
return swap_memory()
@_deprecated(replacement="psutil.phymem_usage().free")
def avail_phymem():
return phymem_usage().free
@_deprecated(replacement="psutil.phymem_usage().used")
def used_phymem():
return phymem_usage().used
@_deprecated(replacement="psutil.virtmem_usage().total")
def total_virtmem():
return virtmem_usage().total
@_deprecated(replacement="psutil.virtmem_usage().used")
def used_virtmem():
return virtmem_usage().used
@_deprecated(replacement="psutil.virtmem_usage().free")
def avail_virtmem():
return virtmem_usage().free
@_deprecated(replacement="psutil.net_io_counters()")
def network_io_counters(pernic=False):
return net_io_counters(pernic)
def test():
"""List info of all currently running processes emulating ps aux
output.
"""
import datetime
from psutil._compat import print_
today_day = datetime.date.today()
templ = "%-10s %5s %4s %4s %7s %7s %-13s %5s %7s %s"
attrs = ['pid', 'cpu_percent', 'memory_percent', 'name', 'cpu_times',
'create_time', 'memory_info']
if _POSIX:
attrs.append('uids')
attrs.append('terminal')
print_(templ % ("USER", "PID", "%CPU", "%MEM", "VSZ", "RSS", "TTY",
"START", "TIME", "COMMAND"))
for p in process_iter():
try:
pinfo = p.as_dict(attrs, ad_value='')
except NoSuchProcess:
pass
else:
if pinfo['create_time']:
ctime = datetime.datetime.fromtimestamp(pinfo['create_time'])
if ctime.date() == today_day:
ctime = ctime.strftime("%H:%M")
else:
ctime = ctime.strftime("%b%d")
else:
ctime = ''
cputime = time.strftime("%M:%S",
time.localtime(sum(pinfo['cpu_times'])))
try:
user = p.username()
except KeyError:
if _POSIX:
if pinfo['uids']:
user = str(pinfo['uids'].real)
else:
user = ''
else:
raise
except Error:
user = ''
if _WINDOWS and '\\' in user:
user = user.split('\\')[1]
vms = pinfo['memory_info'] and \
int(pinfo['memory_info'].vms / 1024) or '?'
rss = pinfo['memory_info'] and \
int(pinfo['memory_info'].rss / 1024) or '?'
memp = pinfo['memory_percent'] and \
round(pinfo['memory_percent'], 1) or '?'
print_(templ % (user[:10],
pinfo['pid'],
pinfo['cpu_percent'],
memp,
vms,
rss,
pinfo.get('terminal', '') or '?',
ctime,
cputime,
pinfo['name'].strip() or '?'))
def _replace_module():
"""Dirty hack to replace the module object in order to access
deprecated module constants, see:
http://www.dr-josiah.com/2013/12/properties-on-python-modules.html
"""
class ModuleWrapper(object):
def __repr__(self):
return repr(self._module)
__str__ = __repr__
@property
def NUM_CPUS(self):
msg = "NUM_CPUS constant is deprecated; use cpu_count() instead"
warnings.warn(msg, category=DeprecationWarning, stacklevel=2)
return cpu_count()
@property
def BOOT_TIME(self):
msg = "BOOT_TIME constant is deprecated; use boot_time() instead"
warnings.warn(msg, category=DeprecationWarning, stacklevel=2)
return boot_time()
@property
def TOTAL_PHYMEM(self):
msg = "TOTAL_PHYMEM constant is deprecated; " \
"use virtual_memory().total instead"
warnings.warn(msg, category=DeprecationWarning, stacklevel=2)
return virtual_memory().total
mod = ModuleWrapper()
mod.__dict__ = globals()
mod._module = sys.modules[__name__]
sys.modules[__name__] = mod
_replace_module()
del property, memoize, division, _replace_module
if sys.version_info < (3, 0):
del num
if __name__ == "__main__":
test()