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confluent/misc/slpscan.py
2021-02-18 09:04:46 -05:00

858 lines
30 KiB
Python

# vim: tabstop=4 shiftwidth=4 softtabstop=4
# Copyright 2017-2019 Lenovo
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This is extracting the confluent slp support into
# a standalone script, for use in environments that
# can't run full confluent and/or would prefer
# a utility style approach to SLP
import os
import random
import select
import socket
import struct
_slp_services = set([
'service:management-hardware.IBM:integrated-management-module2',
'service:lenovo-smm',
'service:lenovo-smm2',
'service:ipmi',
'service:lighttpd',
'service:management-hardware.Lenovo:lenovo-xclarity-controller',
'service:management-hardware.IBM:chassis-management-module',
'service:management-hardware.Lenovo:chassis-management-module',
'service:io-device.Lenovo:management-module',
])
# SLP has a lot of ambition that was unfulfilled in practice.
# So we have a static footer here to always use 'DEFAULT' scope, no LDAP
# predicates, and no authentication for service requests
srvreqfooter = b'\x00\x07DEFAULT\x00\x00\x00\x00'
# An empty instance of the attribute list extension
# which is defined in RFC 3059, used to indicate support for that capability
attrlistext = b'\x00\x02\x00\x00\x00\x00\x00\x00\x00\x00'
try:
IPPROTO_IPV6 = socket.IPPROTO_IPV6
except AttributeError:
IPPROTO_IPV6 = 41 # Assume Windows value if socket is missing it
def _parse_slp_header(packet):
packet = bytearray(packet)
if len(packet) < 16 or packet[0] != 2:
# discard packets that are obviously useless
return None
parsed = {
'function': packet[1],
}
(offset, parsed['xid'], langlen) = struct.unpack('!IHH',
bytes(b'\x00' + packet[7:14]))
parsed['lang'] = packet[14:14 + langlen].decode('utf-8')
parsed['payload'] = packet[14 + langlen:]
if offset:
parsed['offset'] = 14 + langlen
parsed['extoffset'] = offset
return parsed
def _pop_url(payload):
urllen = struct.unpack('!H', bytes(payload[3:5]))[0]
url = bytes(payload[5:5+urllen]).decode('utf-8')
if payload[5+urllen] != 0:
raise Exception('Auth blocks unsupported')
payload = payload[5+urllen+1:]
return url, payload
def _parse_SrvRply(parsed):
""" Modify passed dictionary to have parsed data
:param parsed:
:return:
"""
payload = parsed['payload']
if len(payload) < 4:
return
ecode, ucount = struct.unpack('!HH', bytes(payload[0:4]))
if ecode:
parsed['errorcode'] = ecode
payload = payload[4:]
parsed['urls'] = []
while ucount:
ucount -= 1
url, payload = _pop_url(payload)
parsed['urls'].append(url)
def _parse_slp_packet(packet, peer, rsps, xidmap):
parsed = _parse_slp_header(packet)
if not parsed:
return
addr = peer[0]
if '%' in addr:
addr = addr[:addr.index('%')]
mac = None
if addr in neightable:
identifier = neightable[addr]
mac = identifier
else:
identifier = addr
if (identifier, parsed['xid']) in rsps:
# avoid obviously duplicate entries
parsed = rsps[(identifier, parsed['xid'])]
else:
rsps[(identifier, parsed['xid'])] = parsed
if mac and 'hwaddr' not in parsed:
parsed['hwaddr'] = mac
if parsed['xid'] in xidmap:
parsed['services'] = [xidmap[parsed['xid']]]
if 'addresses' in parsed:
if peer not in parsed['addresses']:
parsed['addresses'].append(peer)
else:
parsed['addresses'] = [peer]
if parsed['function'] == 2: # A service reply
_parse_SrvRply(parsed)
def _v6mcasthash(srvtype):
# The hash algorithm described by RFC 3111
nums = bytearray(srvtype.encode('utf-8'))
hashval = 0
for i in nums:
hashval *= 33
hashval += i
hashval &= 0xffff # only need to track the lowest 16 bits
hashval &= 0x3ff
hashval |= 0x1000
return '{0:x}'.format(hashval)
def _generate_slp_header(payload, multicast, functionid, xid, extoffset=0):
if multicast:
flags = 0x2000
else:
flags = 0
packetlen = len(payload) + 16 # we have a fixed 16 byte header supported
if extoffset: # if we have an offset, add 16 to account for this function
# generating a 16 byte header
extoffset += 16
if packetlen > 1400:
# For now, we aren't intending to support large SLP transmits
# raise an exception to help identify if such a requirement emerges
raise Exception("TODO: Transmit overflow packets")
# We always do SLP v2, and only v2
header = bytearray([2, functionid])
# SLP uses 24 bit packed integers, so in such places we pack 32 then
# discard the high byte
header.extend(struct.pack('!IH', packetlen, flags)[1:])
# '2' below refers to the length of the language tag
header.extend(struct.pack('!IHH', extoffset, xid, 2)[1:])
# we only do english (in SLP world, it's not like non-english appears...)
header.extend(b'en')
return header
def _generate_attr_request(service, xid):
service = service.encode('utf-8')
payload = bytearray(struct.pack('!HH', 0, len(service)) + service)
payload.extend(srvreqfooter)
header = _generate_slp_header(payload, False, functionid=6, xid=xid)
return header + payload
def _generate_request_payload(srvtype, multicast, xid, prlist=''):
prlist = prlist.encode('utf-8')
payload = bytearray(struct.pack('!H', len(prlist)) + prlist)
srvtype = srvtype.encode('utf-8')
payload.extend(struct.pack('!H', len(srvtype)) + srvtype)
payload.extend(srvreqfooter)
extoffset = len(payload)
payload.extend(attrlistext)
header = _generate_slp_header(payload, multicast, functionid=1, xid=xid,
extoffset=extoffset)
return header + payload
def _find_srvtype(net, net4, srvtype, addresses, xid):
"""Internal function to find a single service type
Helper to do singleton requests to srvtype
:param net: Socket active
:param srvtype: Service type to do now
:param addresses: Pass through of addresses argument from find_targets
:return:
"""
data = _generate_request_payload(srvtype, True, xid)
if addresses is not None:
for addr in addresses:
for saddr in socket.getaddrinfo(addr, 427):
if saddr[0] == socket.AF_INET:
net4.sendto(data, saddr[4])
elif saddr[0] == socket.AF_INET6:
net.sendto(data, saddr[4])
else:
net4.setsockopt(socket.SOL_SOCKET, socket.SO_BROADCAST, 1)
v6addrs = []
v6hash = _v6mcasthash(srvtype)
# do 'interface local' and 'link local'
# it shouldn't make sense, but some configurations work with interface
# local that do not work with link local
v6addrs.append(('ff01::1:' + v6hash, 427, 0, 0))
v6addrs.append(('ff02::1:' + v6hash, 427, 0, 0))
for idx in list_interface_indexes():
# IPv6 multicast is by index, so lead with that
net.setsockopt(IPPROTO_IPV6, socket.IPV6_MULTICAST_IF, idx)
for sa in v6addrs:
try:
net.sendto(data, sa)
except socket.error:
# if we hit an interface without ipv6 multicast,
# this can cause an error, skip such an interface
# case in point, 'lo'
pass
for i4 in list_ips():
if 'broadcast' not in i4:
continue
addr = i4['addr']
bcast = i4['broadcast']
net4.setsockopt(socket.IPPROTO_IP, socket.IP_MULTICAST_IF,
socket.inet_aton(addr))
try:
net4.sendto(data, ('239.255.255.253', 427))
except socket.error as se:
# On occasion, multicasting may be disabled
# tolerate this scenario and move on
if se.errno != 101:
raise
net4.sendto(data, (bcast, 427))
def _grab_rsps(socks, rsps, interval, xidmap):
r = None
res = select.select(socks, (), (), interval)
if res:
r = res[0]
while r:
for s in r:
(rsp, peer) = s.recvfrom(9000)
refresh_neigh()
_parse_slp_packet(rsp, peer, rsps, xidmap)
res = select.select(socks, (), (), interval)
if not res:
r = None
else:
r = res[0]
def _parse_attrlist(attrstr):
attribs = {}
previousattrlen = None
attrstr = stringify(attrstr)
while attrstr:
if len(attrstr) == previousattrlen:
raise Exception('Looping in attrstr parsing')
previousattrlen = len(attrstr)
if attrstr[0] == '(':
if ')' not in attrstr:
attribs['INCOMPLETE'] = True
return attribs
currattr = attrstr[1:attrstr.index(')')]
if '=' not in currattr: # Not allegedly kosher, but still..
attribs[currattr] = None
else:
attrname, attrval = currattr.split('=', 1)
attribs[attrname] = []
for val in attrval.split(','):
if val[:3] == '\\FF': # we should make this bytes
finalval = bytearray([])
for bnum in attrval[3:].split('\\'):
if bnum == '':
continue
finalval.append(int(bnum, 16))
val = finalval
if 'uuid' in attrname and len(val) == 16:
lebytes = struct.unpack_from(
'<IHH', memoryview(val[:8]))
bebytes = struct.unpack_from(
'>HHI', memoryview(val[8:]))
val = '{0:08X}-{1:04X}-{2:04X}-{3:04X}-' \
'{4:04X}{5:08X}'.format(
lebytes[0], lebytes[1], lebytes[2], bebytes[0],
bebytes[1], bebytes[2]
).lower()
attribs[attrname].append(val)
attrstr = attrstr[attrstr.index(')'):]
elif attrstr[0] == ','[0]:
attrstr = attrstr[1:]
elif ',' in attrstr:
currattr = attrstr[:attrstr.index(',')]
attribs[currattr] = None
attrstr = attrstr[attrstr.index(','):]
else:
currattr = attrstr
attribs[currattr] = None
attrstr = None
return attribs
def _parse_attrs(data, parsed, xid=None):
headinfo = _parse_slp_header(data)
if xid is None:
xid = parsed['xid']
if headinfo['function'] != 7 or headinfo['xid'] != xid:
return
payload = headinfo['payload']
if struct.unpack('!H', bytes(payload[:2]))[0] != 0:
return
length = struct.unpack('!H', bytes(payload[2:4]))[0]
attrstr = bytes(payload[4:4+length])
parsed['attributes'] = _parse_attrlist(attrstr)
def fix_info(info, handler):
if '_attempts' not in info:
info['_attempts'] = 10
if info['_attempts'] == 0:
return
info['_attempts'] -= 1
_add_attributes(info)
handler(info)
def _add_attributes(parsed):
xid = parsed.get('xid', 42)
attrq = _generate_attr_request(parsed['services'][0], xid)
target = None
# prefer reaching out to an fe80 if present, to be highly robust
# in face of network changes
for addr in parsed['addresses']:
if addr[0].startswith('fe80'):
target = addr
# however if no fe80 seen, roll with the first available address
if not target:
target = parsed['addresses'][0]
if len(target) == 4:
net = socket.socket(socket.AF_INET6, socket.SOCK_STREAM)
else:
net = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
try:
net.settimeout(2.0)
net.connect(target)
except socket.error:
return
try:
net.sendall(attrq)
rsp = net.recv(8192)
net.close()
_parse_attrs(rsp, parsed, xid)
except Exception as e:
# this can be a messy area, just degrade the quality of rsp
# in a bad situation
return
def unicast_scan(address):
pass
def query_srvtypes(target):
"""Query the srvtypes advertised by the target
:param target: A sockaddr tuple (if you get the peer info)
"""
payload = b'\x00\x00\xff\xff\x00\x07DEFAULT'
header = _generate_slp_header(payload, False, functionid=9, xid=1)
packet = header + payload
if len(target) == 2:
net = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
elif len(target) == 4:
net = socket.socket(socket.AF_INET6, socket.SOCK_STREAM)
else:
raise Exception('Unrecognized target {0}'.format(repr(target)))
tries = 3
connected = False
while tries and not connected:
tries -= 1
try:
net.settimeout(1.0)
net.connect(target)
connected = True
except socket.error:
pass
if not connected:
return [u'']
net.sendall(packet)
rs = net.recv(8192)
net.close()
parsed = _parse_slp_header(rs)
if parsed:
payload = parsed['payload']
if payload[:2] != '\x00\x00':
return
stypelen = struct.unpack('!H', bytes(payload[2:4]))[0]
stypes = payload[4:4+stypelen].decode('utf-8')
return stypes.split(',')
def rescan(handler):
known_peers = set([])
for scanned in scan():
for addr in scanned['addresses']:
ip = addr[0].partition('%')[0] # discard scope if present
if ip not in neightable:
continue
if addr in known_peers:
break
known_peers.add(addr)
else:
handler(scanned)
def snoop(handler, protocol=None):
"""Watch for SLP activity
handler will be called with a dictionary of relevant attributes
:param handler:
:return:
"""
try:
active_scan(handler, protocol)
except Exception as e:
raise
net = socket.socket(socket.AF_INET6, socket.SOCK_DGRAM)
net.setsockopt(IPPROTO_IPV6, socket.IPV6_V6ONLY, 1)
slpg = socket.inet_pton(socket.AF_INET6, 'ff01::123')
slpg2 = socket.inet_pton(socket.AF_INET6, 'ff02::123')
for i6idx in list_interface_indexes():
mreq = slpg + struct.pack('=I', i6idx)
net.setsockopt(IPPROTO_IPV6, socket.IPV6_JOIN_GROUP, mreq)
mreq = slpg2 + struct.pack('=I', i6idx)
net.setsockopt(IPPROTO_IPV6, socket.IPV6_JOIN_GROUP, mreq)
net4 = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
net.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
net4.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
for i4 in list_ips():
if 'broadcast' not in i4:
continue
slpmcast = socket.inet_aton('239.255.255.253') + \
socket.inet_aton(i4['addr'])
try:
net4.setsockopt(socket.IPPROTO_IP, socket.IP_ADD_MEMBERSHIP,
slpmcast)
except socket.error as e:
if e.errno != 98:
raise
# socket in use can occur when aliased ipv4 are encountered
net.bind(('', 427))
net4.bind(('', 427))
while True:
try:
newmacs = set([])
r, _, _ = select.select((net, net4), (), (), 60)
# clear known_peers and peerbymacaddress
# to avoid stale info getting in...
# rely upon the select(0.2) to catch rapid fire and aggregate ip
# addresses that come close together
# calling code needs to understand deeper context, as snoop
# will now yield dupe info over time
known_peers = set([])
peerbymacaddress = {}
while r:
for s in r:
(rsp, peer) = s.recvfrom(9000)
ip = peer[0].partition('%')[0]
if peer in known_peers:
continue
if ip not in neightable:
update_neigh()
if ip not in neightable:
continue
known_peers.add(peer)
mac = neightable[ip]
if mac in peerbymacaddress:
peerbymacaddress[mac]['addresses'].append(peer)
else:
q = query_srvtypes(peer)
if not q or not q[0]:
# SLP might have started and not ready yet
# ignore for now
known_peers.discard(peer)
continue
# we want to prioritize the very well known services
svcs = []
for svc in q:
if svc in _slp_services:
svcs.insert(0, svc)
else:
svcs.append(svc)
peerbymacaddress[mac] = {
'services': svcs,
'addresses': [peer],
}
newmacs.add(mac)
r, _, _ = select.select((net, net4), (), (), 0.2)
for mac in newmacs:
peerbymacaddress[mac]['xid'] = 1
_add_attributes(peerbymacaddress[mac])
peerbymacaddress[mac]['hwaddr'] = mac
peerbymacaddress[mac]['protocol'] = protocol
for srvurl in peerbymacaddress[mac].get('urls', ()):
if len(srvurl) > 4:
srvurl = srvurl[:-3]
if srvurl.endswith('://Athena:'):
continue
if 'service:ipmi' in peerbymacaddress[mac]['services']:
continue
if 'service:lightttpd' in peerbymacaddress[mac]['services']:
currinf = peerbymacaddress[mac]
curratt = currinf.get('attributes', {})
if curratt.get('System-Manufacturing', [None])[0] == 'Lenovo' and curratt.get('type', [None])[0] == 'LenovoThinkServer':
peerbymacaddress[mac]['services'] = ['service:lenovo-tsm']
else:
continue
handler(peerbymacaddress[mac])
except Exception as e:
raise
def active_scan(handler, protocol=None):
known_peers = set([])
for scanned in scan():
for addr in scanned['addresses']:
ip = addr[0].partition('%')[0] # discard scope if present
if ip not in neightable:
continue
if addr in known_peers:
break
known_peers.add(addr)
else:
scanned['protocol'] = protocol
handler(scanned)
def scan(srvtypes=_slp_services, addresses=None, localonly=False):
"""Find targets providing matching requested srvtypes
This is a generator that will iterate over respondants to the SrvType
requested.
:param srvtypes: An iterable list of the service types to find
:param addresses: An iterable of addresses/ranges. Default is to scan
local network segment using multicast and broadcast.
Each address can be a single address, hyphen-delimited
range, or an IP/CIDR indication of a network.
:return: Iterable set of results
"""
net = socket.socket(socket.AF_INET6, socket.SOCK_DGRAM)
net4 = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
# increase RCVBUF to max, mitigate chance of
# failure due to full buffer.
net.setsockopt(socket.SOL_SOCKET, socket.SO_RCVBUF, 16777216)
net4.setsockopt(socket.SOL_SOCKET, socket.SO_RCVBUF, 16777216)
# SLP is very poor at scanning large counts and managing it, so we
# must make the best of it
# Some platforms/config default to IPV6ONLY, we are doing IPv4
# too, so force it
#net.setsockopt(IPPROTO_IPV6, socket.IPV6_V6ONLY, 0)
# we are going to do broadcast, so allow that...
initxid = random.randint(0, 32768)
xididx = 0
xidmap = {}
# First we give fast repsonders of each srvtype individual chances to be
# processed, mitigating volume of response traffic
rsps = {}
for srvtype in srvtypes:
xididx += 1
_find_srvtype(net, net4, srvtype, addresses, initxid + xididx)
xidmap[initxid + xididx] = srvtype
_grab_rsps((net, net4), rsps, 0.1, xidmap)
# now do a more slow check to work to get stragglers,
# but fortunately the above should have taken the brunt of volume, so
# reduced chance of many responses overwhelming receive buffer.
_grab_rsps((net, net4), rsps, 1, xidmap)
# now to analyze and flesh out the responses
for id in rsps:
for srvurl in rsps[id].get('urls', ()):
if len(srvurl) > 4:
srvurl = srvurl[:-3]
if srvurl.endswith('://Athena:'):
continue
if 'service:ipmi' in rsps[id]['services']:
continue
if localonly:
for addr in rsps[id]['addresses']:
if 'fe80' in addr[0]:
break
else:
continue
_add_attributes(rsps[id])
if 'service:lighttpd' in rsps[id]['services']:
currinf = rsps[id]
curratt = currinf.get('attributes', {})
if curratt.get('System-Manufacturing', [None])[0] == 'Lenovo' and curratt.get('type', [None])[0] == 'LenovoThinkServer':
currinf['services'] = ['service:lenovo-tsm']
serialnumber = curratt.get('Product-Serial', curratt.get('SerialNumber', None))
if serialnumber:
curratt['enclosure-serial-number'] = serialnumber
mtm = curratt.get('Machine-Type', curratt.get('Product-Name', None))
if mtm:
mtm[0] = mtm[0].rstrip()
curratt['enclosure-machinetype-model'] = mtm
else:
continue
del rsps[id]['payload']
del rsps[id]['function']
del rsps[id]['xid']
yield rsps[id]
# vim: tabstop=4 shiftwidth=4 softtabstop=4
# Copyright 2016 Lenovo
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# A consolidated manage of neighbor table information management.
# Ultimately, this should use AF_NETLINK, but in the interest of time,
# use ip neigh for the moment
import subprocess
import os
neightable = {}
neightime = 0
import re
_validmac = re.compile('..:..:..:..:..:..')
def update_neigh():
global neightable
global neightime
neightable = {}
if os.name == 'nt':
return
ipn = subprocess.Popen(['ip', 'neigh'], stdin=subprocess.PIPE,
stdout=subprocess.PIPE,
stderr=subprocess.PIPE)
(neighdata, err) = ipn.communicate()
neighdata = stringify(neighdata)
for entry in neighdata.split('\n'):
entry = entry.split(' ')
if len(entry) < 5 or not entry[4]:
continue
if entry[0] in ('192.168.0.100', '192.168.70.100', '192.168.70.125'):
# Note that these addresses are common static ip addresses
# that are hopelessly ambiguous if there are many
# so ignore such entries and move on
# ideally the system network steers clear of this landmine of
# a subnet, but just in case
continue
if not _validmac.match(entry[4]):
continue
neightable[entry[0]] = entry[4]
neightime = os.times()[4]
def refresh_neigh():
global neightime
if os.name == 'nt':
return
if os.times()[4] > (neightime + 30):
update_neigh()
# vim: tabstop=4 shiftwidth=4 softtabstop=4
# Copyright 2014 IBM Corporation
# Copyright 2015-2017 Lenovo
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# Various utility functions that do not neatly fit into one category or another
import base64
import hashlib
import netifaces
import os
import re
import socket
import ssl
import struct
def stringify(instr):
# Normalize unicode and bytes to 'str', correcting for
# current python version
if isinstance(instr, bytes) and not isinstance(instr, str):
return instr.decode('utf-8', errors='replace')
elif not isinstance(instr, bytes) and not isinstance(instr, str):
return instr.encode('utf-8')
return instr
def list_interface_indexes():
# Getting the interface indexes in a portable manner
# would be better, but there's difficulty from a python perspective.
# For now be linux specific
try:
for iface in os.listdir('/sys/class/net/'):
if not os.path.exists('/sys/class/net/{0}/ifindex'.format(iface)):
continue
ifile = open('/sys/class/net/{0}/ifindex'.format(iface), 'r')
intidx = int(ifile.read())
ifile.close()
yield intidx
except (IOError, OSError):
# Probably situation is non-Linux, just do limited support for
# such platforms until other people come along
for iface in netifaces.interfaces():
addrinfo = netifaces.ifaddresses(iface).get(socket.AF_INET6, [])
for addr in addrinfo:
v6addr = addr.get('addr', '').partition('%')[2]
if v6addr:
yield(int(v6addr))
break
return
def list_ips():
# Used for getting addresses to indicate the multicast address
# as well as getting all the broadcast addresses
for iface in netifaces.interfaces():
addrs = netifaces.ifaddresses(iface)
if netifaces.AF_INET in addrs:
for addr in addrs[netifaces.AF_INET]:
yield addr
def randomstring(length=20):
"""Generate a random string of requested length
:param length: The number of characters to produce, defaults to 20
"""
chunksize = length // 4
if length % 4 > 0:
chunksize += 1
strval = base64.urlsafe_b64encode(os.urandom(chunksize * 3))
return stringify(strval[0:length])
def securerandomnumber(low=0, high=4294967295):
"""Return a random number within requested range
Note that this function will not return smaller than 0 nor larger
than 2^32-1 no matter what is requested.
The python random number facility does not provide characteristics
appropriate for secure rng, go to os.urandom
:param low: Smallest number to return (defaults to 0)
:param high: largest number to return (defaults to 2^32-1)
"""
number = -1
while number < low or number > high:
number = struct.unpack("I", os.urandom(4))[0]
return number
def monotonic_time():
"""Return a monotoc time value
In scenarios like timeouts and such, monotonic timing is preferred.
"""
# for now, just support POSIX systems
return os.times()[4]
def get_certificate_from_file(certfile):
cert = open(certfile, 'r').read()
inpemcert = False
prunedcert = ''
for line in cert.split('\n'):
if '-----BEGIN CERTIFICATE-----' in line:
inpemcert = True
if inpemcert:
prunedcert += line
if '-----END CERTIFICATE-----' in line:
break
return ssl.PEM_cert_to_DER_cert(prunedcert)
def get_fingerprint(certificate, algo='sha512'):
if algo == 'sha256':
return 'sha256$' + hashlib.sha256(certificate).hexdigest()
elif algo == 'sha512':
return 'sha512$' + hashlib.sha512(certificate).hexdigest()
raise Exception('Unsupported fingerprint algorithm ' + algo)
def cert_matches(fingerprint, certificate):
if not fingerprint or not certificate:
return False
algo, _, fp = fingerprint.partition('$')
newfp = None
if algo in ('sha512', 'sha256'):
newfp = get_fingerprint(certificate, algo)
return newfp and fingerprint == newfp
numregex = re.compile('([0-9]+)')
def naturalize_string(key):
"""Analyzes string in a human way to enable natural sort
:param nodename: The node name to analyze
:returns: A structure that can be consumed by 'sorted'
"""
return [int(text) if text.isdigit() else text.lower()
for text in re.split(numregex, key)]
def natural_sort(iterable):
"""Return a sort using natural sort if possible
:param iterable:
:return:
"""
try:
return sorted(iterable, key=naturalize_string)
except TypeError:
# The natural sort attempt failed, fallback to ascii sort
return sorted(iterable)
if __name__ == '__main__':
print(repr(list(scan(addresses=['10.240.52.189']))))