client/site_tests/kernel_Ktime/kernel_Ktime.py - mirrors/cros/chromiumos/third_party/autotest - Git at Google

 # Copyright (c) 2014 The Chromium Authors. All rights reserved.
 # Use of this source code is governed by a BSD-style license that can be
 # found in the LICENSE file.

 import logging
 import os
 import re
 from time import sleep

 from autotest_lib.client.bin import test, utils
 from autotest_lib.client.common_lib import error

 class kernel_Ktime(test.test):
     """
     Test to ensure that ktime and the RTC clock are consistent.

     """
     version = 1

     MIN_KERNEL_VER = '3.8'
     KERNEL_VER = '3.18'
     MODULE_NAME = 'udelay_test'
     MODULE_NAME_NEW = 'test_udelay'
     UDELAY_PATH = '/sys/kernel/debug/udelay_test'
     RTC_PATH = '/sys/class/rtc/rtc0/since_epoch'

     # How many iterations to run the test for, each iteration is usally
     # a second, but might be more if the skew is too large when retrieving
     # the RTC and ktime.
     TEST_DURATION = 250

     # Allowable drift (as a function of elapsed RTC time): 0.01%
     ALLOWABLE_DRIFT = 0.0001

     # Maximum skew between ktime readings when aligning RTC and ktime
     MAX_SKEW = 0.050

     # Diffs to average for the rolling display
     DIFFS_TO_AVERAGE = 30

     def _set_file(self, contents, filename):
         """
         Write a string to a file.

         @param contents: the contents to write to the file
         @param filename: the filename to use

         """
         logging.debug('setting %s to %s', filename, contents)
         with open(filename, 'w') as f:
             f.write(contents)


     def _get_file(self, filename):
         """
         Read a string from a file.

         @returns: the contents of the file (string)

         """
         with open(filename, 'r') as f:
             return f.read()


     def _get_rtc(self):
         """
         Get the current RTC time.

         @returns: the current RTC time since epoch (int)

         """
         return int(self._get_file(self.RTC_PATH))


     def _get_ktime(self):
         """
         Get the current ktime.

         @returns: the current ktime (float)

         """
         # Writing a delay of 0 will return info including the current ktime.
         self._set_file('0', self.UDELAY_PATH)
         with open(self.UDELAY_PATH, 'r') as f:
             for line in f:
                 line = line.rstrip()
                 logging.debug('result: %s', line)
                 m = re.search(r'kt=(\d+.\d+)', line)
                 if m:
                     return float(m.group(1))
         return 0.0


     def _get_times(self):
         """
         Get the rtc and estimated ktime and max potential error.

         Returns the RTC and a best guess of the ktime when the RTC actually
         ticked over to the current value.  Also returns the maximum potential
         error of how far they are off by.

         RTC ticked in the range of [ktime - max_error, ktime + max_error]

         @returns: list of the current rtc, estimated ktime, max error

         """
         # Times are read k1, r1, k2, r2, k3.  RTC ticks over somewhere between
         # r1 and r2, but since we don't know exactly when that is, the best
         # guess we have is between k1 and k3.
         rtc_older = self._get_rtc()
         ktime_older = self._get_ktime()
         rtc_old = self._get_rtc()
         ktime_old = self._get_ktime()

         # Ensure that this function returns in a reasonable number of
         # iterations.  If excessive skew occurs repeatedly (eg RTC is too
         # slow), abort.
         bad_skew = 0
         while bad_skew < 10:
             rtc = self._get_rtc()
             ktime = self._get_ktime()
             skew = ktime - ktime_older
             if skew > self.MAX_SKEW:
                 # Time between successive calls to ktime was too slow to
                 # bound the error to a reasonable value.  A few occurrences
                 # isn't anything to be concerned about, but if it's happening
                 # every second, it's worth investigating and could indicate
                 # that the RTC is very slow and MAX_SKEW needs to be increased.
                 logging.info((
                     'retrying excessive skew: '
                     'rtc [%d %d %d] ktime [%f %f %f] skew %f'),
                     rtc_older, rtc_old, rtc, ktime_older, ktime_old, ktime,
                     skew)
                 bad_skew += 1
             elif rtc != rtc_old:
                 if rtc_older != rtc_old or rtc != rtc_old + 1:
                     # This could happen if we took more than one second per
                     # loop and could be changed to a warning if legitimate.
                     raise error.TestFail('rtc progressed from %u to %u to %u' %
                             (rtc_older, rtc_old, rtc))
                 return rtc, ktime_older + skew / 2, skew / 2
             rtc_older = rtc_old
             ktime_older = ktime_old
             rtc_old = rtc
             ktime_old = ktime
         raise error.TestFail('could not reach skew %f after %d attempts' % (
                 self.MAX_SKEW, bad_skew))


     def run_once(self):
         kernel_ver = os.uname()[2]
         if utils.compare_versions(kernel_ver, self.MIN_KERNEL_VER) < 0:
             logging.info(
                     'skipping test: old kernel %s (min %s) missing module %s',
                     kernel_ver, self.MIN_KERNEL_VER, self.MODULE_NAME)
             return
         elif utils.compare_versions(kernel_ver, self.KERNEL_VER) < 0:
             utils.load_module(self.MODULE_NAME)
         elif utils.compare_versions(kernel_ver, self.KERNEL_VER) > 0:
             utils.load_module(self.MODULE_NAME_NEW)

         start_rtc, start_ktime, start_error = self._get_times()
         logging.info(
                 'start rtc %d ktime %f error %f',
                 start_rtc, start_ktime, start_error)

         recent_diffs = []
         max_diff = 0
         sum_rtc = 0
         sum_diff = 0
         sum_rtc_rtc = 0
         sum_rtc_diff = 0
         sum_diff_diff = 0
         for i in xrange(self.TEST_DURATION):
             # Sleep some amount of time to avoid busy waiting the entire time
             sleep((i % 10) * 0.1)

             current_rtc, current_ktime, current_error = self._get_times()
             elapsed_rtc = current_rtc - start_rtc
             elapsed_ktime = current_ktime - start_ktime
             elapsed_diff = float(elapsed_rtc) - elapsed_ktime

             # Allow for inaccurate ktime off ALLOWABLE_DRIFT from elapsed RTC,
             # and take into account start and current error in times gathering
             max_error = start_error + current_error
             drift_threshold = elapsed_rtc * self.ALLOWABLE_DRIFT + max_error

             # Track rolling average and maximum diff
             recent_diffs.append(elapsed_diff)
             if len(recent_diffs) > self.DIFFS_TO_AVERAGE:
                 recent_diffs.pop(0)
             rolling_diff = sum(recent_diffs) / len(recent_diffs)
             if abs(elapsed_diff) > abs(max_diff):
                 max_diff = elapsed_diff

             # Track linear regression
             sum_rtc += elapsed_rtc
             sum_diff += elapsed_diff
             sum_rtc_rtc += elapsed_rtc * elapsed_rtc
             sum_rtc_diff += elapsed_rtc * elapsed_diff
             sum_diff_diff += elapsed_diff * elapsed_diff

             logging.info((
                     'current rtc %d ktime %f error %f; elapsed rtc %d '
                     'ktime %f: threshold %f diff %+f rolling %+f'),
                     current_rtc, current_ktime, current_error, elapsed_rtc,
                     elapsed_ktime, drift_threshold, elapsed_diff, rolling_diff)

             if abs(elapsed_diff) > drift_threshold:
                 raise error.TestFail((
                         'elapsed rtc %d and ktime %f diff %f '
                         'is greater than threshold %f') %
                         (elapsed_rtc, elapsed_ktime, elapsed_diff,
                         drift_threshold))

         # Dump final statistics
         logging.info('max_diff %f', max_diff)
         mean_rtc = sum_rtc / self.TEST_DURATION
         mean_diff = sum_diff / self.TEST_DURATION
         slope = ((sum_rtc_diff - sum_rtc * mean_diff) /
                 (sum_rtc_rtc - sum_rtc * mean_rtc))
         logging.info('drift %.9f', slope)

         utils.unload_module(self.MODULE_NAME)
	# Copyright (c) 2014 The Chromium Authors. All rights reserved.
	# Use of this source code is governed by a BSD-style license that can be
	# found in the LICENSE file.

	import logging
	import os
	import re
	from time import sleep

	from autotest_lib.client.bin import test, utils
	from autotest_lib.client.common_lib import error

	class kernel_Ktime(test.test):
	"""
	Test to ensure that ktime and the RTC clock are consistent.

	"""
	version = 1

	MIN_KERNEL_VER = '3.8'
	KERNEL_VER = '3.18'
	MODULE_NAME = 'udelay_test'
	MODULE_NAME_NEW = 'test_udelay'
	UDELAY_PATH = '/sys/kernel/debug/udelay_test'
	RTC_PATH = '/sys/class/rtc/rtc0/since_epoch'

	# How many iterations to run the test for, each iteration is usally
	# a second, but might be more if the skew is too large when retrieving
	# the RTC and ktime.
	TEST_DURATION = 250

	# Allowable drift (as a function of elapsed RTC time): 0.01%
	ALLOWABLE_DRIFT = 0.0001

	# Maximum skew between ktime readings when aligning RTC and ktime
	MAX_SKEW = 0.050

	# Diffs to average for the rolling display
	DIFFS_TO_AVERAGE = 30

	def _set_file(self, contents, filename):
	"""
	Write a string to a file.

	@param contents: the contents to write to the file
	@param filename: the filename to use

	"""
	logging.debug('setting %s to %s', filename, contents)
	with open(filename, 'w') as f:
	f.write(contents)


	def _get_file(self, filename):
	"""
	Read a string from a file.

	@returns: the contents of the file (string)

	"""
	with open(filename, 'r') as f:
	return f.read()


	def _get_rtc(self):
	"""
	Get the current RTC time.

	@returns: the current RTC time since epoch (int)

	"""
	return int(self._get_file(self.RTC_PATH))


	def _get_ktime(self):
	"""
	Get the current ktime.

	@returns: the current ktime (float)

	"""
	# Writing a delay of 0 will return info including the current ktime.
	self._set_file('0', self.UDELAY_PATH)
	with open(self.UDELAY_PATH, 'r') as f:
	for line in f:
	line = line.rstrip()
	logging.debug('result: %s', line)
	m = re.search(r'kt=(\d+.\d+)', line)
	if m:
	return float(m.group(1))
	return 0.0


	def _get_times(self):
	"""
	Get the rtc and estimated ktime and max potential error.

	Returns the RTC and a best guess of the ktime when the RTC actually
	ticked over to the current value. Also returns the maximum potential
	error of how far they are off by.

	RTC ticked in the range of [ktime - max_error, ktime + max_error]

	@returns: list of the current rtc, estimated ktime, max error

	"""
	# Times are read k1, r1, k2, r2, k3. RTC ticks over somewhere between
	# r1 and r2, but since we don't know exactly when that is, the best
	# guess we have is between k1 and k3.
	rtc_older = self._get_rtc()
	ktime_older = self._get_ktime()
	rtc_old = self._get_rtc()
	ktime_old = self._get_ktime()

	# Ensure that this function returns in a reasonable number of
	# iterations. If excessive skew occurs repeatedly (eg RTC is too
	# slow), abort.
	bad_skew = 0
	while bad_skew < 10:
	rtc = self._get_rtc()
	ktime = self._get_ktime()
	skew = ktime - ktime_older
	if skew > self.MAX_SKEW:
	# Time between successive calls to ktime was too slow to
	# bound the error to a reasonable value. A few occurrences
	# isn't anything to be concerned about, but if it's happening
	# every second, it's worth investigating and could indicate
	# that the RTC is very slow and MAX_SKEW needs to be increased.
	logging.info((
	'retrying excessive skew: '
	'rtc [%d %d %d] ktime [%f %f %f] skew %f'),
	rtc_older, rtc_old, rtc, ktime_older, ktime_old, ktime,
	skew)
	bad_skew += 1
	elif rtc != rtc_old:
	if rtc_older != rtc_old or rtc != rtc_old + 1:
	# This could happen if we took more than one second per
	# loop and could be changed to a warning if legitimate.
	raise error.TestFail('rtc progressed from %u to %u to %u' %
	(rtc_older, rtc_old, rtc))
	return rtc, ktime_older + skew / 2, skew / 2
	rtc_older = rtc_old
	ktime_older = ktime_old
	rtc_old = rtc
	ktime_old = ktime
	raise error.TestFail('could not reach skew %f after %d attempts' % (
	self.MAX_SKEW, bad_skew))


	def run_once(self):
	kernel_ver = os.uname()[2]
	if utils.compare_versions(kernel_ver, self.MIN_KERNEL_VER) < 0:
	logging.info(
	'skipping test: old kernel %s (min %s) missing module %s',
	kernel_ver, self.MIN_KERNEL_VER, self.MODULE_NAME)
	return
	elif utils.compare_versions(kernel_ver, self.KERNEL_VER) < 0:
	utils.load_module(self.MODULE_NAME)
	elif utils.compare_versions(kernel_ver, self.KERNEL_VER) > 0:
	utils.load_module(self.MODULE_NAME_NEW)

	start_rtc, start_ktime, start_error = self._get_times()
	logging.info(
	'start rtc %d ktime %f error %f',
	start_rtc, start_ktime, start_error)

	recent_diffs = []
	max_diff = 0
	sum_rtc = 0
	sum_diff = 0
	sum_rtc_rtc = 0
	sum_rtc_diff = 0
	sum_diff_diff = 0
	for i in xrange(self.TEST_DURATION):
	# Sleep some amount of time to avoid busy waiting the entire time
	sleep((i % 10) * 0.1)

	current_rtc, current_ktime, current_error = self._get_times()
	elapsed_rtc = current_rtc - start_rtc
	elapsed_ktime = current_ktime - start_ktime
	elapsed_diff = float(elapsed_rtc) - elapsed_ktime

	# Allow for inaccurate ktime off ALLOWABLE_DRIFT from elapsed RTC,
	# and take into account start and current error in times gathering
	max_error = start_error + current_error
	drift_threshold = elapsed_rtc * self.ALLOWABLE_DRIFT + max_error

	# Track rolling average and maximum diff
	recent_diffs.append(elapsed_diff)
	if len(recent_diffs) > self.DIFFS_TO_AVERAGE:
	recent_diffs.pop(0)
	rolling_diff = sum(recent_diffs) / len(recent_diffs)
	if abs(elapsed_diff) > abs(max_diff):
	max_diff = elapsed_diff

	# Track linear regression
	sum_rtc += elapsed_rtc
	sum_diff += elapsed_diff
	sum_rtc_rtc += elapsed_rtc * elapsed_rtc
	sum_rtc_diff += elapsed_rtc * elapsed_diff
	sum_diff_diff += elapsed_diff * elapsed_diff

	logging.info((
	'current rtc %d ktime %f error %f; elapsed rtc %d '
	'ktime %f: threshold %f diff %+f rolling %+f'),
	current_rtc, current_ktime, current_error, elapsed_rtc,
	elapsed_ktime, drift_threshold, elapsed_diff, rolling_diff)

	if abs(elapsed_diff) > drift_threshold:
	raise error.TestFail((
	'elapsed rtc %d and ktime %f diff %f '
	'is greater than threshold %f') %
	(elapsed_rtc, elapsed_ktime, elapsed_diff,
	drift_threshold))

	# Dump final statistics
	logging.info('max_diff %f', max_diff)
	mean_rtc = sum_rtc / self.TEST_DURATION
	mean_diff = sum_diff / self.TEST_DURATION
	slope = ((sum_rtc_diff - sum_rtc * mean_diff) /
	(sum_rtc_rtc - sum_rtc * mean_rtc))
	logging.info('drift %.9f', slope)

	utils.unload_module(self.MODULE_NAME)