rteval/sysinfo/systopology.py - pub/scm/linux/kernel/git/jkacur/rteval - Git at Google

 # -*- coding: utf-8 -*-
 #
 #   Copyright 2016 - Clark Williams <williams@redhat.com>
 #
 #   This program is free software; you can redistribute it and/or modify
 #   it under the terms of the GNU General Public License as published by
 #   the Free Software Foundation; either version 2 of the License, or
 #   (at your option) any later version.
 #
 #   This program is distributed in the hope that it will be useful,
 #   but WITHOUT ANY WARRANTY; without even the implied warranty of
 #   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 #   GNU General Public License for more details.
 #
 #   You should have received a copy of the GNU General Public License along
 #   with this program; if not, write to the Free Software Foundation, Inc.,
 #   51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 #
 #   For the avoidance of doubt the "preferred form" of this code is one which
 #   is in an open unpatent encumbered format. Where cryptographic key signing
 #   forms part of the process of creating an executable the information
 #   including keys needed to generate an equivalently functional executable
 #   are deemed to be part of the source code.
 #

 import os, sys
 import os.path
 import glob

 def __sysread(path, obj):
     fp = open(os.path.join(path,obj), "r")
     return fp.readline().strip()

 #
 # class to provide access to a list of cpus
 #

 class Cpus(object):
     "Object that represents a group of system cpus"

     cpupath = '/sys/devices/system/cpu'

     def __init__(self, cpulist):
         if type(cpulist) is list:
             self.cpulist = cpulist
         elif type(cpulist) is str:
             self.cpulist = self.__expand_cpulist(cpulist)
         self.cpulist.sort()

     def __str__(self):
         return self.__collapse_cpulist(self.cpulist)

     def __contains__(self, cpu):
         return cpu in self.cpulist

     def __len__(self):
         return len(self.cpulist)


     # return the index of the last element of a sequence
     # that steps by one
     def __longest_sequence(self, cpulist):
         lim = len(cpulist)
         for idx,val in enumerate(cpulist):
             if idx+1 == lim:
                 break
             if int(cpulist[idx+1]) != (int(cpulist[idx])+1):
                 return idx
         return lim - 1


     #
     # collapse a list of cpu numbers into a string range
     # of cpus (e.g. 0-5, 7, 9)
     #
     def __collapse_cpulist(self, cpulist):
         if len(cpulist) == 0:
             return ""
         idx = self.__longest_sequence(cpulist)
         if idx == 0:
             seq = str(cpulist[0])
         else:
             if idx == 1:
                 seq = "%d,%d" % (cpulist[0], cpulist[idx])
             else:
                 seq = "%d-%d" % (cpulist[0], cpulist[idx])

         rest = self.__collapse_cpulist(cpulist[idx+1:])
         if rest == "":
             return seq
         return ",".join((seq, rest))

     # expand a string range into a list
     # don't error check against online cpus
     def __expand_cpulist(self, cpulist):
         '''expand a range string into an array of cpu numbers'''
         result = []
         for part in cpulist.split(','):
             if '-' in part:
                 a, b = part.split('-')
                 a, b = int(a), int(b)
                 result.extend(range(a, b + 1))
             else:
                 a = int(part)
                 result.append(a)
         return [ int(i) for i in list(set(result)) ]

     # returns the list of cpus tracked
     def getcpulist(self):
         return self.cpulist

     # find the nodeid of a particular cpu
     def getnodeid(self, n):
         cpupath = os.path.join(Cpus.cpupath,'cpu%d' % n)
         return int(self.__sysread(cpupath, "topology/physical_package_id"))

     # check whether cpu n is online
     def isonline(self, n):
         if n == 0:
             return True
         path = os.path.join(Cpus.cpupath,'cpu%d' % n)
         if os.path.exists(path):
             return self.__sysread(path, "online") == 1
         return False

 #
 # class to abstract access to NUMA nodes in /sys filesystem
 #

 class NumaNode(object):
     "class representing a system NUMA node"

     def __init__(self, path):
         self.path = path
         self.nodeid = int(os.path.basename(path)[4:].strip())
         self.cpus = Cpus(self.__sysread(self.path, "cpulist"))
         self.getmeminfo()

     def __contains__(self, cpu):
         return cpu in self.cpus

     def __len__(self):
         return len(self.cpus)

     def __str__(self):
         return self.getcpustr()

     def __sysread(self, path, element):
         fp = open(os.path.join(path,element), "r")
         return fp.readline().strip()

     # read info about memory attached to this node
     def getmeminfo(self):
         self.meminfo = {}
         for l in open(os.path.join(self.path, "meminfo"), "r"):
             elements = l.split()
             key=elements[2][0:-1]
             val=int(elements[3])
             if len(elements) == 5 and elements[4] == "kB":
                 val *= 1024
             self.meminfo[key] = val

     # return list of cpus for this node as a string
     def getcpustr(self):
         return str(self.cpus)

     # return list of cpus for this node
     def getcpulist(self):
         return self.cpus.getcpulist()

 #
 # Class to abstract the system topology of numa nodes and cpus
 #
 class SysTopology(object):
     "Object that represents the system's NUMA-node/cpu topology"

     cpupath = '/sys/devices/system/cpu'
     nodepath = '/sys/devices/system/node'

     def __init__(self):
         self.nodes = {}
         self.getinfo()

     def __len__(self):
         return len(self.nodes.keys())

     def __contains__(self, node):
         for n in self.nodes:
             if self.nodes[n].nodeid == node:
                 return True
         return False

     def __getitem__(self, key):
         return self.nodes[key]

     def __iter__(self):
         self.current = 0
         return self

     def next(self):
         if self.current >= len(self.nodes):
             raise StopIteration
         n = self.nodes[self.current]
         self.current += 1
         return n

     def __sysread(self, path, obj):
         fp = open(os.path.join(path, obj), "r")
         return fp.readline().strip()

     def getinfo(self):
         nodes = glob.glob(os.path.join(SysTopology.nodepath, 'node[0-9]*'))
         if not nodes:
             raise RuntimeError, "No valid nodes found in %s!" % SysTopology.nodepath
         nodes.sort()
         for n in nodes:
             node = int(os.path.basename(n)[4:])
             self.nodes[node] = NumaNode(n)

     def getnodes(self):
         return self.nodes.keys()

     def getcpus(self, node):
         return self.nodes[node]


 if __name__ == "__main__":

     def unit_test():
         s = SysTopology()
         print "number of nodes: %d" % len(s)
         for n in s:
             print "node[%d]: %s" % (n.nodeid, n)
         print "system has numa node 0: %s" % (0 in s)
         print "system has numa node 2: %s" % (2 in s)
         print "system has numa node 24: %s" % (24 in s)

     unit_test()
	# -- coding: utf-8 --
	#
	# Copyright 2016 - Clark Williams <williams@redhat.com>
	#
	# This program is free software; you can redistribute it and/or modify
	# it under the terms of the GNU General Public License as published by
	# the Free Software Foundation; either version 2 of the License, or
	# (at your option) any later version.
	#
	# This program is distributed in the hope that it will be useful,
	# but WITHOUT ANY WARRANTY; without even the implied warranty of
	# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	# GNU General Public License for more details.
	#
	# You should have received a copy of the GNU General Public License along
	# with this program; if not, write to the Free Software Foundation, Inc.,
	# 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
	#
	# For the avoidance of doubt the "preferred form" of this code is one which
	# is in an open unpatent encumbered format. Where cryptographic key signing
	# forms part of the process of creating an executable the information
	# including keys needed to generate an equivalently functional executable
	# are deemed to be part of the source code.
	#

	import os, sys
	import os.path
	import glob

	def __sysread(path, obj):
	fp = open(os.path.join(path,obj), "r")
	return fp.readline().strip()

	#
	# class to provide access to a list of cpus
	#

	class Cpus(object):
	"Object that represents a group of system cpus"

	cpupath = '/sys/devices/system/cpu'

	def __init__(self, cpulist):
	if type(cpulist) is list:
	self.cpulist = cpulist
	elif type(cpulist) is str:
	self.cpulist = self.__expand_cpulist(cpulist)
	self.cpulist.sort()

	def __str__(self):
	return self.__collapse_cpulist(self.cpulist)

	def __contains__(self, cpu):
	return cpu in self.cpulist

	def __len__(self):
	return len(self.cpulist)


	# return the index of the last element of a sequence
	# that steps by one
	def __longest_sequence(self, cpulist):
	lim = len(cpulist)
	for idx,val in enumerate(cpulist):
	if idx+1 == lim:
	break
	if int(cpulist[idx+1]) != (int(cpulist[idx])+1):
	return idx
	return lim - 1


	#
	# collapse a list of cpu numbers into a string range
	# of cpus (e.g. 0-5, 7, 9)
	#
	def __collapse_cpulist(self, cpulist):
	if len(cpulist) == 0:
	return ""
	idx = self.__longest_sequence(cpulist)
	if idx == 0:
	seq = str(cpulist[0])
	else:
	if idx == 1:
	seq = "%d,%d" % (cpulist[0], cpulist[idx])
	else:
	seq = "%d-%d" % (cpulist[0], cpulist[idx])

	rest = self.__collapse_cpulist(cpulist[idx+1:])
	if rest == "":
	return seq
	return ",".join((seq, rest))

	# expand a string range into a list
	# don't error check against online cpus
	def __expand_cpulist(self, cpulist):
	'''expand a range string into an array of cpu numbers'''
	result = []
	for part in cpulist.split(','):
	if '-' in part:
	a, b = part.split('-')
	a, b = int(a), int(b)
	result.extend(range(a, b + 1))
	else:
	a = int(part)
	result.append(a)
	return [ int(i) for i in list(set(result)) ]

	# returns the list of cpus tracked
	def getcpulist(self):
	return self.cpulist

	# find the nodeid of a particular cpu
	def getnodeid(self, n):
	cpupath = os.path.join(Cpus.cpupath,'cpu%d' % n)
	return int(self.__sysread(cpupath, "topology/physical_package_id"))

	# check whether cpu n is online
	def isonline(self, n):
	if n == 0:
	return True
	path = os.path.join(Cpus.cpupath,'cpu%d' % n)
	if os.path.exists(path):
	return self.__sysread(path, "online") == 1
	return False

	#
	# class to abstract access to NUMA nodes in /sys filesystem
	#

	class NumaNode(object):
	"class representing a system NUMA node"

	def __init__(self, path):
	self.path = path
	self.nodeid = int(os.path.basename(path)[4:].strip())
	self.cpus = Cpus(self.__sysread(self.path, "cpulist"))
	self.getmeminfo()

	def __contains__(self, cpu):
	return cpu in self.cpus

	def __len__(self):
	return len(self.cpus)

	def __str__(self):
	return self.getcpustr()

	def __sysread(self, path, element):
	fp = open(os.path.join(path,element), "r")
	return fp.readline().strip()

	# read info about memory attached to this node
	def getmeminfo(self):
	self.meminfo = {}
	for l in open(os.path.join(self.path, "meminfo"), "r"):
	elements = l.split()
	key=elements[2][0:-1]
	val=int(elements[3])
	if len(elements) == 5 and elements[4] == "kB":
	val *= 1024
	self.meminfo[key] = val

	# return list of cpus for this node as a string
	def getcpustr(self):
	return str(self.cpus)

	# return list of cpus for this node
	def getcpulist(self):
	return self.cpus.getcpulist()

	#
	# Class to abstract the system topology of numa nodes and cpus
	#
	class SysTopology(object):
	"Object that represents the system's NUMA-node/cpu topology"

	cpupath = '/sys/devices/system/cpu'
	nodepath = '/sys/devices/system/node'

	def __init__(self):
	self.nodes = {}
	self.getinfo()

	def __len__(self):
	return len(self.nodes.keys())

	def __contains__(self, node):
	for n in self.nodes:
	if self.nodes[n].nodeid == node:
	return True
	return False

	def __getitem__(self, key):
	return self.nodes[key]

	def __iter__(self):
	self.current = 0
	return self

	def next(self):
	if self.current >= len(self.nodes):
	raise StopIteration
	n = self.nodes[self.current]
	self.current += 1
	return n

	def __sysread(self, path, obj):
	fp = open(os.path.join(path, obj), "r")
	return fp.readline().strip()

	def getinfo(self):
	nodes = glob.glob(os.path.join(SysTopology.nodepath, 'node[0-9]*'))
	if not nodes:
	raise RuntimeError, "No valid nodes found in %s!" % SysTopology.nodepath
	nodes.sort()
	for n in nodes:
	node = int(os.path.basename(n)[4:])
	self.nodes[node] = NumaNode(n)

	def getnodes(self):
	return self.nodes.keys()

	def getcpus(self, node):
	return self.nodes[node]



	if __name__ == "__main__":

	def unit_test():
	s = SysTopology()
	print "number of nodes: %d" % len(s)
	for n in s:
	print "node[%d]: %s" % (n.nodeid, n)
	print "system has numa node 0: %s" % (0 in s)
	print "system has numa node 2: %s" % (2 in s)
	print "system has numa node 24: %s" % (24 in s)

	unit_test()