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0
mirror of https://git.kernel.org/pub/scm/network/wireless/iwd.git synced 2024-12-22 13:02:44 +01:00
iwd/tools/test-runner
James Prestwood 2e55e00662 test-runner: start haveged in foreground
haveged was forking itself which then prevented test-runner from
cleaning it up.
2021-02-26 10:09:56 -06:00

1651 lines
42 KiB
Python
Executable File

#!/usr/bin/python3
import argparse
import os
import shutil
import ctypes
import fcntl
import shlex
import sys
import subprocess
import atexit
import time
import unittest
import importlib
import signal
import pyroute2
import multiprocessing
import re
from configparser import ConfigParser
from prettytable import PrettyTable
from termcolor import colored
from glob import glob
from collections import namedtuple
from time import sleep
import dbus.mainloop.glib
from gi.repository import GLib
libc = ctypes.cdll['libc.so.6']
libc.mount.argtypes = (ctypes.c_char_p, ctypes.c_char_p, ctypes.c_char_p, \
ctypes.c_ulong, ctypes.c_char_p)
# Using ctypes to load the libc library is somewhat low level. Because of this
# we need to define our own flags/options for use with mounting.
MS_NOSUID = 2
MS_NODEV = 4
MS_NOEXEC = 8
MS_STRICTATIME = 1 << 24
STDIN_FILENO = 0
TIOCSTTY = 0x540E
config = None
intf_id = 0
TEST_MAX_TIMEOUT = 120
dbus.mainloop.glib.DBusGMainLoop(set_as_default=True)
def dbg(*s):
'''
Allows prints if stdout has been re-directed
'''
print(*s, file=sys.__stdout__)
def exit_vm():
if config:
for p in config.ctx.processes:
print("Process %s still running!" % p.name)
if config.ctx and config.ctx.results:
print_results(config.ctx.results)
os.sync()
RB_AUTOBOOT = 0x01234567
#
# Calling 'reboot' or 'shutdown' from a shell (e.g. os.system('reboot'))
# is not the same the POSIX reboot() and will cause a kernel panic since
# we are the init process. The libc.reboot() allows the VM to exit
# gracefully.
#
libc.reboot(RB_AUTOBOOT)
def path_exists(path):
'''
Searches PATH as well as absolute paths.
'''
if shutil.which(path):
return True
try:
os.stat(path)
except:
return False
return True
def find_binary(list):
'''
Returns a binary from 'list' if its found in PATH or on a
valid absolute path.
'''
for path in list:
if path_exists(path):
return path
return None
def mount(source, target, fs, flags, options=''):
'''
Python wrapper for libc mount()
'''
ret = libc.mount(source.encode(), target.encode(), fs.encode(), flags,
options.encode())
if ret < 0:
errno = ctypes.get_errno()
raise Exception("Could not mount %s (%d)" % (target, errno))
MountInfo = namedtuple('MountInfo', 'fstype target options flags')
mount_table = [
MountInfo('sysfs', '/sys', '', MS_NOSUID|MS_NOEXEC|MS_NODEV),
MountInfo('proc', '/proc', '', MS_NOSUID|MS_NOEXEC|MS_NODEV),
MountInfo('devpts', '/dev/pts', 'mode=0620', MS_NOSUID|MS_NOEXEC),
MountInfo('tmpfs', '/dev/shm', 'mode=1777', MS_NOSUID|MS_NODEV|MS_STRICTATIME),
MountInfo('tmpfs', '/run', 'mode=0755', MS_NOSUID|MS_NODEV|MS_STRICTATIME),
MountInfo('tmpfs', '/tmp', '', 0),
MountInfo('tmpfs', '/usr/share/dbus-1', 'mode=0755', MS_NOSUID|MS_NOEXEC|MS_NODEV|MS_STRICTATIME),
MountInfo('debugfs', '/sys/kernel/debug', '', 0)
]
DevInfo = namedtuple('DevInfo', 'target linkpath')
dev_table = [
DevInfo('/proc/self/fd', '/dev/fd'),
DevInfo('/proc/self/fd/0', '/dev/stdin'),
DevInfo('/proc/self/fd/1', '/dev/stdout'),
DevInfo('/proc/self/fd/2', '/dev/stderr')
]
# Partial DBus config. The remainder (<listen>) will be filled in for each
# namespace that is created so each individual dbus-daemon has its own socket
# and address.
dbus_config = '''
<!DOCTYPE busconfig PUBLIC \
"-//freedesktop//DTD D-Bus Bus Configuration 1.0//EN" \
"http://www.freedesktop.org/standards/dbus/1.0/\
busconfig.dtd\">
<busconfig>
<type>system</type>
<limit name=\"reply_timeout\">2147483647</limit>
<auth>ANONYMOUS</auth>
<allow_anonymous/>
<policy context=\"default\">
<allow user=\"*\"/>
<allow own=\"*\"/>
<allow send_type=\"method_call\"/>
<allow send_type=\"signal\"/>
<allow send_type=\"method_return\"/>
<allow send_type=\"error\"/>
<allow receive_type=\"method_call\"/>
<allow receive_type=\"signal\"/>
<allow receive_type=\"method_return\"/>
<allow receive_type=\"error\"/>
<allow send_destination=\"*\" eavesdrop=\"true\"/>
<allow eavesdrop=\"true\"/>
</policy>
'''
class Process:
'''
Start a process. If 'wait' is True the constructor will start
the process and wait for it to exit. No PID is tracked in this
case.
'''
def __init__(self, args, wait=False, env=None, ctx=None, check=False,
outfile=None, namespace=None, need_out=False, cleanup=None):
self.killed = False
self.args = args
self.wait = wait
self.name = args[0]
self.ret = None
self.ctx = ctx
self.write_fds = []
self.io_watch = None
self.cleanup = cleanup
if not namespace:
self.output_name = '/tmp/%s-out' % self.name
else:
self.output_name = '/tmp/%s-%s-out' % (self.name, namespace)
if namespace:
self.args = ['ip', 'netns', 'exec', namespace]
self.args.extend(args)
#
# For simplicity all processes will write to a temp file
# (/tmp/<name>-out). If any verbose options are required this file
# will get an IO watch and write out any bytes to the needed FDs.
#
self.stdout = open(self.output_name, 'a+')
self.io_position = self.stdout.tell()
if ctx:
# Verbose requested, add stdout/stderr to write FD list
if self.name in ctx.args.verbose:
self.write_fds.append(sys.__stdout__)
self.write_fds.append(sys.__stderr__)
# Add output file to FD list
if outfile:
try:
f = open(outfile, 'w')
except Exception as e:
dbg(e)
exit(0)
if ctx.args.log_uid:
os.fchown(f.fileno(), int(ctx.args.log_uid), int(ctx.args.log_gid))
self.write_fds.append(f)
# Add log file to FD list
if ctx.args.log:
test = os.path.basename(os.getcwd())
test_dir = '%s/%s' % (ctx.args.log, test)
if not path_exists(test_dir):
os.mkdir(test_dir)
os.chown(test_dir, int(ctx.args.log_uid),
int(ctx.args.log_gid))
f = open('%s/%s' % (test_dir, args[0]), 'a+')
os.fchown(f.fileno(), int(ctx.args.log_uid), int(ctx.args.log_gid))
self.write_fds.append(f)
#
# Only add an IO watch for long running processes. If
# the process is being waited for, the log/outfile bits
# will be handled after the process exists.
#
if self.write_fds != [] and not wait and not check:
self.io_watch = GLib.io_add_watch(self.stdout, GLib.IO_IN,
self.io_callback)
self.pid = subprocess.Popen(self.args, stdout=self.stdout, stderr=subprocess.STDOUT,
env=env, cwd=os.getcwd())
print("Starting process {}".format(self.pid.args))
if not wait and not check:
return
self.pid.wait()
self.killed = True
self.stdout.seek(self.io_position)
self.out = self.stdout.read()
self.stdout.seek(0, 2)
self.ret = self.pid.returncode
#
# No IO callback for wait/check=True processes so write out
# the data to any FD's now.
#
if len(self.write_fds) > 0:
for fd in self.write_fds:
fd.write(self.out)
fd.close()
self.write_fds = []
print("%s returned %d" % (args[0], self.ret))
if check and self.ret != 0:
raise subprocess.CalledProcessError(returncode=self.ret, cmd=self.args)
def io_callback(self, source, cb_condition):
#
# The file will have already been written to, meaning the seek
# position points to EOF. This is why the position is saved so
# we can seek to where we were last time, read data, and seek
# back to EOF.
#
source.seek(self.io_position)
data = source.read()
self.io_position += len(data)
source.seek(self.io_position)
if len(data) == 0:
return True
for f in self.write_fds:
f.write(data)
return True
def __del__(self):
print("Del process %s" % self.args)
if not self.killed:
self.kill()
os.remove(self.output_name)
def kill(self, force=False):
print("Killing process %s" % self.args)
if self.killed:
return
if force:
self.pid.kill()
else:
self.pid.terminate()
self.pid.wait(timeout=15)
self.pid = None
if self.ctx and self in self.ctx.processes:
self.ctx.processes.remove(self)
self.ctx = None
for f in self.write_fds:
f.close()
self.write_fds = []
if self.io_watch:
GLib.source_remove(self.io_watch)
self.io_watch = None
if self.cleanup:
self.cleanup()
self.cleanup = None
self.stdout.close()
self.killed = True
def wait_for_socket(self, socket, wait):
waited = 0
while not os.path.exists(socket):
sleep(0.5)
waited += 0.5
if waited > wait:
raise Exception("Timed out waiting for socket")
def __str__(self):
return str(self.args) + '\n'
class Interface:
def __init__(self, name, config):
self.name = name
self.ctrl_interface = '/var/run/hostapd/' + name
self.config = config
def __del__(self):
Process(['iw', 'dev', self.name, 'del'], True)
def set_interface_state(self, state):
Process(['ifconfig', self.name, state], True)
class Radio:
def __init__(self, name):
self.name = name
# hostapd will reset this if this radio is used by it
self.use = 'iwd'
self.interface = None
def __del__(self):
print("Removing radio %s" % self.name)
self.interface = None
def create_interface(self, config, use):
global intf_id
ifname = 'wln%s' % intf_id
intf_id += 1
self.interface = Interface(ifname, config)
self.use = use
Process(['iw', 'phy', self.name, 'interface', 'add', ifname,
'type', 'managed'], True)
return self.interface
def __str__(self):
ret = self.name + ':\n'
ret += '\tUsed By: %s ' % self.use
if self.interface:
ret += '(%s)' % self.interface.name
ret += '\n'
return ret
class VirtualRadio(Radio):
'''
A subclass of 'Radio' specific to mac80211_hwsim radios.
TODO: Using D-Bus to create and destroy radios is more desireable
than the command line.
'''
def __init__(self, name, config=None):
self.disable_cipher = None
self.disable_iftype = None
hwsim = importlib.import_module('hwsim').Hwsim()
if config:
self.disable_iftype = config.get('iftype_disable', None)
self.disable_cipher = config.get('cipher_disable', None)
self._radio = hwsim.radios.create(name, p2p_device=True,
iftype_disable=self.disable_iftype,
cipher_disable=self.disable_cipher)
super().__init__(self._radio.name)
def __del__(self):
super().__del__()
# If the radio was moved into a namespace this will fail
try:
self._radio.remove()
except:
pass
self._radio = None
def __str__(self):
ret = super().__str__()
if self.disable_iftype:
ret += '\tDisabled interface types: %s\n' % self.disable_iftype
if self.disable_cipher:
ret += '\tDisabled ciphers: %s\n' % self.disable_cipher
ret += '\tPath: %s' % self._radio.path
ret += '\n'
return ret
class HostapdInstance:
'''
A single instance of hostapd. In reality all hostapd instances
are started as a single process. This class just makes things
convenient for communicating with one of the hostapd APs.
'''
def __init__(self, config, radio):
self.radio = radio
self.config = config
self.intf = radio.create_interface(self.config, 'hostapd')
self.intf.set_interface_state('up')
def __del__(self):
print("Removing HostapdInstance %s" % self.config)
self.intf.set_interface_state('down')
self.radio = None
self.intf = None
def __str__(self):
ret = 'Hostapd (%s)\n' % self.intf.name
ret += '\tConfig: %s\n' % self.config
return ret
class Hostapd:
'''
A set of running hostapd instances. This is really just a single
process since hostapd can be started with multiple config files.
'''
def __init__(self, ctx, radios, configs, radius):
self.ctx = ctx
if len(configs) != len(radios):
raise Exception("Config (%d) and radio (%d) list length not equal" % \
(len(configs), len(radios)))
print("Initializing hostapd instances")
ctx.start_process(['ip', 'link', 'set', 'eth0', 'up'], wait=True)
ctx.start_process(['ip', 'link', 'set', 'eth1', 'up'], wait=True)
self.global_ctrl_iface = '/var/run/hostapd/ctrl'
self.instances = [HostapdInstance(c, r) for c, r in zip(configs, radios)]
ifaces = [rad.interface.name for rad in radios]
ifaces = ','.join(ifaces)
args = ['hostapd', '-g', self.global_ctrl_iface]
if ifaces:
args.extend(['-i', ifaces])
#
# Config files should already be present in /tmp. This appends
# ctrl_interface and does any variable replacement. Currently
# this is just any $ifaceN occurrences.
#
for c in configs:
full_path = '/tmp/%s' % c
args.append(full_path)
self._rewrite_config(full_path)
if radius:
args.append(radius)
if ctx.is_verbose('hostapd'):
args.append('-d')
self.process = ctx.start_process(args)
self.process.wait_for_socket(self.global_ctrl_iface, 30)
def _rewrite_config(self, config):
'''
Replaces any $ifaceN values with the correct interface
names as well as appends the ctrl_interface path to
the config file.
'''
with open(config, 'r+') as f:
data = f.read()
to_replace = []
for match in re.finditer(r'\$iface[0-9]+', data):
tag = data[match.start():match.end()]
idx = tag.split('iface')[1]
to_replace.append((tag, self.instances[int(idx)].intf.name))
for r in to_replace:
data = data.replace(r[0], r[1], 1)
data += '\nctrl_interface=/var/run/hostapd\n'
f.write(data)
def __getitem__(self, config):
if not config:
return self.instances[0]
for hapd in self.instances:
if hapd.config == config:
return hapd
return None
def __del__(self):
print("Removing Hostapd")
try:
os.remove(self.global_ctrl_iface)
except:
dbg("Failed to remove %s" % self.global_ctrl_iface)
self.instances = None
# Hostapd may have already been stopped
if self.process:
self.ctx.stop_process(self.process)
self.ctx = None
# Hostapd creates simdb sockets for EAP-SIM/AKA tests but does not
# clean them up.
for f in glob("/tmp/eap_sim_db*"):
os.remove(f)
dbus_count = 0
class Namespace:
def __init__(self, args, name, radios):
self.dbus_address = None
self.processes = []
self.name = name
self.radios = radios
self.args = args
Process(['ip', 'netns', 'add', name], wait=True)
for r in radios:
Process(['iw', 'phy', r.name, 'set', 'netns', 'name', name], wait=True)
self.start_dbus()
def reset(self):
self._bus = None
for r in self.radios:
r._radio = None
self.radios = []
if self.name == "root":
self._bus = dbus.bus.BusConnection(address_or_type=self.dbus_address)
for p in self.processes:
print("Killing process %s" % p.name)
p.kill()
self.processes = []
def __del__(self):
print("Removing namespace %s" % self.name)
Process(['ip', 'netns', 'del', self.name], wait=True)
def get_bus(self):
return self._bus
def start_process(self, args, env=None, **kwargs):
# Special case for 'root' namespace (aka TestContext)
if self.name == "root":
ns = None
else:
ns = self.name
if not env:
env = os.environ.copy()
# In case this process needs DBus...
env['DBUS_SYSTEM_BUS_ADDRESS'] = self.dbus_address
p = Process(args, ctx=self, namespace=ns, env=env, **kwargs)
if not kwargs.get('wait', False):
self.processes.append(p)
return p
def stop_process(self, p, force=False):
p.kill(force)
def is_process_running(self, process):
for p in self.processes:
if p.name == process:
return True
return False
def _cleanup_dbus(self):
try:
os.remove(self.dbus_address.split('=')[1])
except:
pass
os.remove(self.dbus_cfg)
def start_dbus(self):
global dbus_count
self.dbus_address = 'unix:path=/tmp/dbus%d' % dbus_count
self.dbus_cfg = '/tmp/dbus%d.conf' % dbus_count
dbus_count += 1
with open(self.dbus_cfg, 'w+') as f:
f.write(dbus_config)
f.write('<listen>%s</listen>\n' % self.dbus_address)
f.write('</busconfig>\n')
p = self.start_process(['dbus-daemon', '--config-file=%s' % self.dbus_cfg],
wait=False, cleanup=self._cleanup_dbus)
p.wait_for_socket(self.dbus_address.split('=')[1], wait=5)
self._bus = dbus.bus.BusConnection(address_or_type=self.dbus_address)
def start_iwd(self, config_dir = '/tmp', storage_dir = '/tmp/iwd'):
args = []
iwd_radios = ','.join([r.name for r in self.radios if r.use == 'iwd'])
if self.args.valgrind:
args.extend(['valgrind', '--leak-check=full', '--track-origins=yes',
'--log-file=/tmp/valgrind.log'])
args.extend(['iwd', '-p', iwd_radios])
if self.is_verbose(args[0]):
args.append('-d')
env = os.environ.copy()
env['CONFIGURATION_DIRECTORY'] = config_dir
env['STATE_DIRECTORY'] = storage_dir
if self.is_verbose('iwd-dhcp'):
env['IWD_DHCP_DEBUG'] = '1'
if self.is_verbose('iwd-tls'):
env['IWD_TLS_DEBUG'] = '1'
if self.is_verbose('iwd-genl'):
env['IWD_GENL_DEBUG'] = '1'
if self.is_verbose('iwd-acd'):
env['IWD_ACD_DEBUG'] = '1'
pid = self.start_process(args, env=env)
return pid
def is_verbose(self, process):
process = os.path.basename(process)
if self.args is None:
return False
# every process is verbose when logging is enabled
if self.args.log:
return True
if process in self.args.verbose:
return True
# Special case here to enable verbose output with valgrind running
if process == 'valgrind' and 'iwd' in self.args.verbose:
return True
# Handle any glob matches
for item in self.args.verbose:
if process in glob(item):
return True
return False
def wait_for_dbus_service(self, service):
tries = 0
while not self._bus.name_has_owner(service):
if tries > 200:
raise TimeoutError('DBus service %s did not appear', service)
tries += 1
sleep(0.1)
def __str__(self):
ret = 'Namespace: %s\n' % self.name
ret += 'Processes:\n'
for p in self.processes:
ret += '\t%s' % str(p)
ret += 'Radios:\n'
if len(self.radios) > 0:
for r in self.radios:
ret += '\t%s\n' % str(r)
else:
ret += '\tNo Radios\n'
ret += 'DBus Address: %s\n' % self.dbus_address
ret += '===================================================\n\n'
return ret
class TestContext(Namespace):
'''
Contains all information for a given set of tests being run
such as processes, radios, interfaces and test results.
'''
def __init__(self, args):
self.name = "root"
self.processes = []
self.args = args
self.hw_config = None
self.hostapd = None
self.wpas_interfaces = None
self.cur_radio_id = 0
self.cur_iface_id = 0
self.radios = []
self.loopback_started = False
self.results = {}
self.mainloop = GLib.MainLoop()
self.namespaces = []
def start_dbus_monitor(self):
if not self.is_verbose('dbus-monitor'):
return
self.start_process(['dbus-monitor', '--address', self.dbus_address])
def start_haveged(self):
self.start_process(['haveged', '-F'])
def create_radios(self):
setup = self.hw_config['SETUP']
nradios = int(setup['num_radios'])
args = ['hwsim']
if not self.hw_config['SETUP'].get('hwsim_medium', 'yes') in ['yes', '1', 'true']:
# register hwsim as medium
args.extend(['--no-register'])
self.start_process(args)
self.wait_for_dbus_service('net.connman.hwsim')
for i in range(nradios):
name = 'rad%u' % i
# Get any [radX] sections. These are for configuring
# any special radios. This no longer requires a
# radio_conf list, we just assume radios start rad0
# and increment.
rad_config = None
if self.hw_config.has_section(name):
rad_config = self.hw_config[name]
self.radios.append(VirtualRadio(name, rad_config))
self.cur_radio_id += 1
def discover_radios(self):
phys = []
iw = pyroute2.iwutil.IW()
attrs = [phy['attrs'] for phy in iw.list_wiphy()]
for attr in attrs:
for key, value in attr:
if key == 'NL80211_ATTR_WIPHY_NAME':
if value not in phys:
phys.append(value)
break
print('Discovered radios: %s' % str(phys))
self.radios = [Radio(name) for name in phys]
def start_radios(self):
reg_domain = self.hw_config['SETUP'].get('reg_domain', None)
if reg_domain:
Process(['iw', 'reg', 'set', reg_domain], True)
if self.args.hw:
self.discover_radios()
else:
self.create_radios()
def start_hostapd(self):
if not 'HOSTAPD' in self.hw_config:
return
settings = self.hw_config['HOSTAPD']
if self.args.hw:
# Just grab the first N radios. It gets rather
# complicated trying to map radX radios specified in
# hw.conf so any passed through physical adapters are
# just given to hostapd/IWD as they appear during
# discovery.
#
# TODO: It may be desireable to map PCI/USB adapters to
# specific radX radios specified in the config but
# there are really 2 separate use cases here.
# 1. You want to test a *specific* radio with IWD
# or hostapd. For this you would want radX
# to map to a specific radio
# 2. You have many adapters in use to run multiple
# tests. In this case you would not care what
# was using each radio, just that there was
# enough to run all tests.
nradios = 0
for k, _ in settings.items():
if k == 'radius_server':
continue
nradios += 1
hapd_radios = self.radios[:nradios]
else:
hapd_radios = [rad for rad in self.radios if rad.name in settings]
hapd_configs = [conf for rad, conf in settings.items() if rad != 'radius_server']
radius_config = settings.get('radius_server', None)
self.hostapd = Hostapd(self, hapd_radios, hapd_configs, radius_config)
def start_wpas_interfaces(self):
if 'WPA_SUPPLICANT' not in self.hw_config:
return
settings = self.hw_config['WPA_SUPPLICANT']
wpas_radios = [rad for rad in self.radios if rad.name in settings]
self.wpas_interfaces = [rad.create_interface(settings[rad.name], 'wpas') for rad in wpas_radios]
def start_ofono(self):
sim_keys = self.hw_config['SETUP'].get('sim_keys', None)
if not sim_keys:
print("Ofono not requred")
return
elif sim_keys != 'ofono':
os.environ['IWD_SIM_KEYS'] = sim_keys
return
if not find_binary(['ofonod']) or not find_binary(['phonesim']):
print("Ofono or Phonesim not found, skipping test")
return
Process(['ifconfig', 'lo', 'up'], wait=True)
os.environ['OFONO_PHONESIM_CONFIG'] = '/tmp/phonesim.conf'
phonesim_args = ['phonesim', '-p', '12345', '/usr/share/phonesim/default.xml']
self.start_process(phonesim_args)
#
# TODO:
# Is there something to wait for? Without this phonesim rejects
# connections on all but the fist test.
#
time.sleep(3)
ofono_args = ['ofonod', '-n', '--plugin=atmodem,phonesim']
if self.is_verbose('ofonod'):
ofono_args.append('-d')
self.start_process(ofono_args)
print("Ofono started")
def create_namespaces(self):
if not self.hw_config.has_section('NameSpaces'):
return
for key, value in self.hw_config.items('NameSpaces'):
radio_names = value.split(',')
# Gather up radio objects for this namespace
radios = [rad for rad in self.radios if rad.name in radio_names]
# Remove radios from 'root' namespace
self.radios = list(set(self.radios) - set(radios))
self.namespaces.append(Namespace(self.args, key, radios))
def get_namespace(self, ns):
for n in self.namespaces:
if n.name == ns:
return n
return None
def stop_test_processes(self):
for n in self.namespaces:
n.reset()
self.namespaces = []
self.hostapd = None
self.wpas_interfaces = None
self.reset()
def __str__(self):
ret = 'Arguments:\n'
for arg in vars(self.args):
ret += '\t --%s %s\n' % (arg, str(getattr(self.args, arg)))
ret += 'Hostapd:\n'
if self.hostapd:
for h in self.hostapd.instances:
ret += '\t%s\n' % str(h)
else:
ret += '\tNo Hostapd instances\n'
ret += super().__str__()
for n in self.namespaces:
ret += n.__str__()
return ret
def prepare_sandbox():
print('Preparing sandbox')
for entry in mount_table:
try:
os.lstat(entry.target)
except:
os.mkdir(entry.target, 755)
mount(entry.fstype, entry.target, entry.fstype, entry.flags,
entry.options)
for entry in dev_table:
os.symlink(entry.target, entry.linkpath)
os.mkdir('/tmp/iwd')
os.setsid()
fcntl.ioctl(STDIN_FILENO, TIOCSTTY, 1)
def build_unit_list(args):
'''
Build list of unit tests based on passed arguments. This first
checks for literal names provided in the arguments, then if
no matches were found, checks for a glob match.
'''
tests = []
test_root = args.testhome + '/unit'
for unit in args.unit_tests.split(','):
path = '%s/%s' % (test_root, unit)
if os.access(unit, os.X_OK):
tests.append(unit)
elif os.access(path, os.X_OK):
tests.append(path)
else:
# Full list or glob, first build up valid list of tests
matches = glob(path)
if matches == []:
raise Exception("Could not find test %s" % unit)
matches = [exe for exe in matches if os.access(exe, os.X_OK)]
tests.extend(matches)
return sorted(tests)
def build_test_list(args):
'''
Build list of auto test directories based on passed arguments.
First check for absolute paths, then look in <iwd>/autotests,
then glob match.
'''
tests = []
test_root = args.testhome + '/autotests'
full_list = sorted(os.listdir(test_root))
# Run all tests
if not args.auto_tests:
# --shell with no tests implies 'shell' test
if args.shell:
return [test_root + '/shell']
# Pair down any non-tests and append full path
tests = [test_root + '/' + t for t in full_list if t.startswith('test')]
else:
print("Generating partial test list")
for t in args.auto_tests.split(','):
path = '%s/%s' % (test_root, t)
if t.endswith('+'):
t = t.split('+')[0]
i = full_list.index(t)
tests = [test_root + '/' + x for x in full_list[i:] \
if x.startswith('test')]
elif os.path.exists(t):
tests.append(t)
elif os.path.exists(path):
tests.append(path)
else:
matches = glob(path)
if matches == []:
raise Exception("Could not find test %s" % t)
tests.extend(matches)
return sorted(tests)
SimpleResult = namedtuple('SimpleResult', 'run failures errors skipped time')
def start_test(ctx, subtests, rqueue):
'''
Run an individual test. 'subtests' are parsed prior to calling
but these effectively make up a single test. 'rqueue' is the
results queue which is required since this is using
multiprocessing.
'''
suite = unittest.TestSuite()
#
# Iterate through each individual python test.
#
for s in subtests:
loader = unittest.TestLoader()
subtest = importlib.import_module(os.path.splitext(s)[0])
suite.addTests(loader.loadTestsFromModule(subtest))
# Prevents future test modules with the same name (e.g.
# connection_test.py) from being loaded from the cache
sys.modules.pop(subtest.__name__)
start = time.time()
runner = unittest.TextTestRunner()
result = runner.run(suite)
#
# The multiprocessing queue is picky with what objects it will serialize
# and send between processes. Because of this we put the important bits
# of the result into our own 'SimpleResult' tuple.
#
sresult = SimpleResult(run=result.testsRun, failures=len(result.failures),
errors=len(result.errors), skipped=len(result.skipped),
time=time.time() - start)
rqueue.put(sresult)
# This may not be required since we are manually popping sys.modules
importlib.invalidate_caches()
def pre_test(ctx, test, copied):
'''
Copy test files, start processes, and any other pre test work.
'''
os.chdir(test)
dbg("Starting test %s" % test)
if not os.path.exists(test + '/hw.conf'):
print("No hw.conf found for %s" % test)
exit()
ctx.hw_config = ConfigParser()
ctx.hw_config.read(test + '/hw.conf')
#
# We have two types of test files: tests and everything else. Rather
# than require each test to specify the files needing to be copied to
# /tmp (previously 'tmpfs_extra_stuff'), we just copy everything which
# isn't a test. There is really no reason not to do this as any file
# present in a test directory should be needed by the test.
#
# All files
files = os.listdir(test)
# Tests (starts or ends with 'test')
subtests = [f for f in files if f.startswith('test') or \
os.path.splitext(f)[0].endswith('test')]
# Everything else (except .py files)
to_copy = [f for f in list(set(files) - set(subtests)) if not f.endswith('.py')]
for f in to_copy:
if os.path.isdir(f):
shutil.copytree(f, '/tmp/' + f)
else:
shutil.copy(f, '/tmp')
copied.append(f)
# Prune down any subtests if needed
if ctx.args.sub_tests:
ctx.args.sub_tests = ctx.args.sub_tests.split(',')
pruned = []
for s in subtests:
# Allow test name both with and without the extension
if s in ctx.args.sub_tests or os.path.splitext(s)[0] in ctx.args.sub_tests:
pruned.append(s)
subtests = pruned
ctx.start_dbus()
ctx.start_haveged()
ctx.start_dbus_monitor()
ctx.start_radios()
ctx.create_namespaces()
ctx.start_hostapd()
ctx.start_wpas_interfaces()
ctx.start_ofono()
if ctx.args.log:
ctx.start_process(['iwmon'])
elif ctx.args.monitor:
ctx.start_process(['iwmon'], outfile=ctx.args.monitor)
if ctx.hw_config.has_option('SETUP', 'start_iwd'):
start = ctx.hw_config.getboolean('SETUP', 'start_iwd')
else:
start = True
if start:
ctx.start_iwd()
else:
print("Not starting IWD from test-runner")
print(ctx)
sys.path.insert(1, test)
return sorted(subtests)
def post_test(ctx, to_copy):
'''
Remove copied files, and stop test processes.
'''
try:
for f in to_copy:
if os.path.isdir('/tmp/' + f):
shutil.rmtree('/tmp/' + f)
else:
os.remove('/tmp/' + f)
Process(['ifconfig', 'lo', 'down'], wait=True)
except Exception as e:
print("Exception thrown in post_test")
finally:
ctx.stop_test_processes()
if ctx.args.valgrind:
with open('/tmp/valgrind.log', 'r') as f:
dbg(f.read())
dbg("\n")
def print_results(results):
table = PrettyTable(['Test', colored('Passed', 'green'), colored('Failed', 'red'), \
colored('Skipped', 'cyan'), colored('Time', 'yellow')])
total_pass = 0
total_fail = 0
total_skip = 0
total_time = 0
for test, result in results.items():
if result.time == TEST_MAX_TIMEOUT:
failed = "Timed out"
passed = "Timed out"
elif result.time == 0:
failed = "Exception"
passed = "Exception"
else:
failed = result.failures + result.errors
passed = result.run - failed
total_pass += passed
total_fail += failed
total_skip += result.skipped
total_time += result.time
time = '%.2f' % result.time
table.add_row([test, colored(passed, 'green'), colored(failed, 'red'), \
colored(result.skipped, 'cyan'), colored(time, 'yellow')])
total_time = '%.2f' % total_time
table.add_row(['Total', colored(total_pass, 'green'), colored(total_fail, 'red'), \
colored(total_skip, 'cyan'), colored(total_time, 'yellow')])
dbg(table)
def run_auto_tests(ctx, args):
tests = build_test_list(args)
# Copy autotests/misc/{certs,secrets,phonesim} so any test can refer to them
shutil.copytree(args.testhome + '/autotests/misc/certs', '/tmp/certs')
shutil.copytree(args.testhome + '/autotests/misc/secrets', '/tmp/secrets')
shutil.copy(args.testhome + '/autotests/misc/phonesim/phonesim.conf', '/tmp')
for test in tests:
copied = []
try:
subtests = pre_test(ctx, test, copied)
if args.shell:
#
# Shell really isn't meant to be used with multiple tests. If
# a set of tests was passed in just start out in the first.
#
os.chdir(tests[0])
os.system('/bin/bash')
exit()
if len(subtests) < 1:
dbg("No tests to run")
exit()
rqueue = multiprocessing.Queue()
p = multiprocessing.Process(target=start_test, args=(ctx, subtests, rqueue))
p.start()
# Rather than time each subtest we just time the total but
# mutiply the default time by the number of tests being run.
p.join(TEST_MAX_TIMEOUT * len(subtests))
if p.is_alive():
# Timeout
p.terminate()
ctx.results[os.path.basename(test)] = SimpleResult(run=0,
failures=0, errors=0,
skipped=0, time=TEST_MAX_TIMEOUT)
else:
ctx.results[os.path.basename(test)] = rqueue.get()
except Exception as ex:
print(ex)
print("Uncaught exception thrown for %s" % test)
ctx.results[os.path.basename(test)] = SimpleResult(run=0, failures=0,
errors=0, skipped=0, time=0)
finally:
post_test(ctx, copied)
shutil.rmtree('/tmp/certs')
shutil.rmtree('/tmp/secrets')
os.remove('/tmp/phonesim.conf')
# Write out kernel log
if ctx.args.log:
ctx.start_process(["dmesg"], wait=True)
def run_unit_tests(ctx, args):
os.chdir(args.testhome + '/unit')
units = build_unit_list(args)
for u in units:
if ctx.start_process([u], wait=True).ret != 0:
dbg("Unit test %s failed" % os.path.basename(u))
else:
dbg("Unit test %s passed" % os.path.basename(u))
def run_tests():
global config
with open('/proc/cmdline', 'r') as f:
cmdline = f.read()
start = cmdline.find('--testhome')
options = shlex.split(cmdline[start:])
parser = argparse.ArgumentParser()
parser.add_argument('--testhome')
parser.add_argument('--auto_tests')
parser.add_argument('--unit_tests')
parser.add_argument('--verbose', default=[])
parser.add_argument('--debug')
parser.add_argument('--path')
parser.add_argument('--valgrind')
parser.add_argument('--gdb')
parser.add_argument('--shell')
parser.add_argument('--log')
parser.add_argument('--log-gid')
parser.add_argument('--log-uid')
parser.add_argument('--hw')
parser.add_argument('--monitor')
parser.add_argument('--sub_tests')
args = parser.parse_args(options)
#
# This prevents any print() calls in this script from printing unless
# --debug is passed. For an 'always print' option use dbg()
#
if not args.debug:
sys.stdout = open(os.devnull, 'w')
if args.verbose != []:
args.verbose = args.verbose.split(',')
os.environ['PATH'] = '%s/src' % args.testhome
os.environ['PATH'] += ':%s/tools' % args.testhome
os.environ['PATH'] += ':%s/client' % args.testhome
os.environ['PATH'] += ':%s/monitor' % args.testhome
os.environ['PATH'] += ':%s/wired' % args.testhome
os.environ['PATH'] += ':' + args.path
sys.path.append(args.testhome + '/autotests/util')
#
# This allows all autotest utils (iwd/hostapd/etc) to access the
# TestContext. Any other module or script (in the same interpreter) can
# simply import config.ctx and access all live test information,
# start/stop processes, see active radios etc.
#
config = importlib.import_module('config')
config.ctx = TestContext(args)
if args.log:
mount('logdir', args.log, '9p', 0, 'trans=virtio,version=9p2000.L')
# Clear out any log files from other test runs
for f in glob('%s/*' % args.log):
print("removing %s" % f)
if os.path.isdir(f):
shutil.rmtree(f)
else:
os.remove(f)
elif args.monitor:
parent = os.path.abspath(os.path.join(args.monitor, os.pardir))
mount('mondir', parent, '9p', 0, 'trans=virtio,version=9p2000.L')
if config.ctx.args.unit_tests is None:
run_auto_tests(config.ctx, args)
else:
run_unit_tests(config.ctx, args)
class Main:
def __init__(self):
self.parser = argparse.ArgumentParser(
description='IWD Test Runner')
self.parser.add_argument('--qemu', '-q',
metavar='<QEMU binary>', type=str,
help='QEMU binary to use',
dest='qemu',
default=None)
self.parser.add_argument('--kernel', '-k', metavar='<kernel>',
type=str,
help='Path to kernel image',
dest='kernel',
default=None)
self.parser.add_argument('--verbose', '-v', metavar='<list>',
type=str,
help='Comma separated list of applications',
dest='verbose',
default=[])
self.parser.add_argument('--debug', '-d',
action='store_true',
help='Enable test-runner debugging',
dest='debug')
self.parser.add_argument('--shell', '-s', action='store_true',
help='Boot into shell', dest='shell')
self.parser.add_argument('--log', '-l', type=str,
help='Directory for log files')
self.parser.add_argument('--hw', '-w', type=str, nargs=1,
help='Use physical adapters for tests (passthrough)')
self.parser.add_argument('--monitor', '-m', type=str,
help='Enables iwmon output to file')
self.parser.add_argument('--sub-tests', '-S', metavar='<subtests>',
type=str, nargs=1, help='List of subtests to run',
default=None, dest='sub_tests')
# Prevent --autotest/--unittest from being used together
auto_unit_group = self.parser.add_mutually_exclusive_group()
auto_unit_group.add_argument('--auto-tests', '-A',
metavar='<tests>', type=str, nargs=1,
help='List of tests to run',
default=None,
dest='auto_tests')
auto_unit_group.add_argument('--unit-tests', '-U',
metavar='<tests>', type=str, nargs='?',
const='*',
help='List of unit tests to run',
dest='unit_tests')
# Prevent --valgrind/--gdb from being used together
valgrind_gdb_group = self.parser.add_mutually_exclusive_group()
valgrind_gdb_group.add_argument('--gdb', '-g', metavar='<exec>',
type=str, nargs=1,
help='Run gdb on specified executable',
dest='gdb')
valgrind_gdb_group.add_argument('--valgrind', '-V', action='store_true',
help='Run valgrind on IWD', dest='valgrind')
self.args = self.parser.parse_args()
if self.args.auto_tests:
self.args.auto_tests = self.args.auto_tests[0].split(',')
if self.args.sub_tests:
self.args.sub_tests = self.args.sub_tests[0].split(',')
if self.args.log and self.args.unit_tests:
dbg("Cannot use --log with --unit-tests")
quit()
if self.args.sub_tests:
if not self.args.auto_tests:
dbg("--sub-tests must be used with --auto-tests")
quit()
if len(self.args.auto_tests) > 1:
dbg("--sub-tests must be used with a single auto test")
quit()
def start(self):
usb_adapters = None
qemu_table = [
'qemu-system-x86_64',
'/usr/bin/qemu-system-x86_64'
]
kernel_table = [
'bzImage',
'arch/x86/boot/bzImage',
'vmlinux',
'arch/x86/boot/vmlinux'
]
if self.args.qemu is None:
qemu_binary = find_binary(qemu_table)
if not qemu_binary:
print("Could not find qemu binary")
quit()
else:
if path_exists(self.args.qemu):
qemu_binary = self.args.qemu
else:
print("QEMU binary %s does not exist" % \
self.args.qemu)
quit()
if self.args.kernel is None:
kernel_binary = find_binary(kernel_table)
if not kernel_binary:
print("Could not find kernel image")
quit()
else:
if path_exists(self.args.kernel):
kernel_binary = self.args.kernel
else:
print("Kernel image %s does not exist" % \
self.args.kernel)
quit()
if self.args.hw:
hw_conf = ConfigParser()
hw_conf.read(self.args.hw)
# TODO: Parse PCI adapters
if hw_conf.has_section('USBAdapters'):
# The actual key name of the adapter
# doesn't matter since all we need is the
# bus/address. This gets named by the kernel
# anyways once in the VM.
usb_adapters = [v for v in hw_conf['USBAdapters'].values()]
#
# Additional arguments not provided to test-runner which are
# needed once booted into the kernel.
#
options = 'init=%s' % os.path.realpath(sys.argv[0])
# Support running from top level as well as tools
if os.getcwd().endswith('tools'):
options += ' --testhome %s/../' % os.getcwd()
else:
options += ' --testhome %s' % os.getcwd()
options += ' --path "%s"' % os.environ['PATH']
if self.args.auto_tests:
options += ' --auto_tests %s' % ','.join(self.args.auto_tests)
if self.args.sub_tests:
options += ' --sub_tests %s' % ','.join(self.args.sub_tests)
if self.args.log:
if os.environ.get('SUDO_GID', None) is None:
print("--log can only be used as root user")
quit()
self.args.log = os.path.abspath(self.args.log)
uid = int(os.environ['SUDO_UID'])
gid = int(os.environ['SUDO_GID'])
if not path_exists(self.args.log):
os.mkdir(self.args.log)
os.chown(self.args.log, uid, gid)
options += ' --log-gid %u' % gid
options += ' --log-uid %u' % uid
if self.args.monitor:
if os.environ.get('SUDO_GID', None) is None:
print("--monitor can only be used as root user")
quit()
self.args.monitor = os.path.abspath(self.args.monitor)
mon_parent_dir = os.path.abspath(os.path.join(self.args.monitor, os.pardir))
denylist = [
'auto_tests',
'sub_tests',
'qemu',
'kernel'
]
nproc = multiprocessing.cpu_count()
#
# Specially handle CPU systems with minimal cores, otherwise
# use half the host cores.
#
if nproc < 2:
smp = 1
else:
smp = int(nproc / 2)
print("Using %d cores for VM" % smp)
#
# This passes through most of the command line options to
# the kernel command line. Some are not relevant (e.g. qemu)
# so similar options are added in the denylist above. This excludes
# any unset options which are assumed to be None or False. This
# is done so default arguments can be filled once in the VM. If
# we pass and basic types (None, False etc.) they are turned into
# a string representation ('None', 'False', etc.) which is not
# desirable.
#
for arg in vars(self.args):
if arg in denylist or getattr(self.args, arg) in [None, False, []]:
continue
options += ' --%s %s' % (arg, str(getattr(self.args, arg)))
kern_log = "ignore_loglevel" if "kernel" in self.args.verbose else "quiet"
qemu_cmdline = [
qemu_binary,
'-machine', 'type=q35,accel=kvm:tcg',
'-nodefaults', '-no-user-config', '-monitor', 'none',
'-display', 'none', '-m', '256M', '-nographic', '-vga',
'none', '-no-acpi', '-no-hpet',
'-no-reboot', '-fsdev',
'local,id=fsdev-root,path=/,readonly,security_model=none,multidevs=remap',
'-device',
'virtio-9p-pci,fsdev=fsdev-root,mount_tag=/dev/root',
'-chardev', 'stdio,id=chardev-serial0,signal=off',
'-device', 'pci-serial,chardev=chardev-serial0',
'-device', 'virtio-rng-pci',
'-kernel',
kernel_binary,
'-append',
'console=ttyS0,115200n8 earlyprintk=serial \
rootfstype=9p root=/dev/root \
rootflags=trans=virtio,version=9p2000.u \
acpi=off pci=noacpi %s ro \
mac80211_hwsim.radios=0 %s' % (kern_log, options),
'-cpu', 'host', '-smp', str(smp)
]
# Add two ethernet devices for testing EAD
qemu_cmdline.extend([
'-net', 'nic,model=virtio',
'-net', 'nic,model=virtio',
'-net', 'user'
])
if usb_adapters:
for bus, addr in [s.split(',') for s in usb_adapters]:
qemu_cmdline.extend(['-usb',
'-device',
'usb-host,hostbus=%s,hostaddr=%s' % \
(bus, addr)])
if self.args.log:
#
# Creates a virtfs device that can be mounted. This mount
# will point back to the provided log directory and is
# writable unlike the rest of the mounted file system.
#
qemu_cmdline.extend([
'-virtfs',
'local,path=%s,mount_tag=logdir,security_model=passthrough,id=logdir' \
% self.args.log
])
if self.args.monitor:
qemu_cmdline.extend([
'-virtfs',
'local,path=%s,mount_tag=mondir,security_model=passthrough,id=mondir' \
% mon_parent_dir
])
os.execlp(qemu_cmdline[0], *qemu_cmdline)
if __name__ == '__main__':
if os.getpid() == 1 and os.getppid() == 0:
atexit.register(exit_vm)
prepare_sandbox()
run_tests()
exit()
main = Main()
main.start()