bench/bench_util.py - platform/external/skqp - Gitiles

 '''
 Created on May 19, 2011

 @author: bungeman
 '''

 import re
 import math

 # bench representation algorithm constant names
 ALGORITHM_AVERAGE = 'avg'
 ALGORITHM_MEDIAN = 'med'
 ALGORITHM_MINIMUM = 'min'
 ALGORITHM_25TH_PERCENTILE = '25th'

 # Regular expressions used throughout
 PER_SETTING_RE = '([^\s=]+)(?:=(\S+))?'
 SETTINGS_RE = 'skia bench:((?:\s+' + PER_SETTING_RE + ')*)'
 BENCH_RE = 'running bench (?:\[\d+ \d+\] )?\s*(\S+)'
 TIME_RE = '(?:(\w*)msecs = )?\s*((?:\d+\.\d+)(?:,\d+\.\d+)*)'
 # non-per-tile benches have configs that don't end with ']' or '>'
 CONFIG_RE = '(\S+[^\]>]): ((?:' + TIME_RE + '\s+)+)'
 # per-tile bench lines are in the following format. Note that there are
 # non-averaged bench numbers in separate lines, which we ignore now due to
 # their inaccuracy.
 TILE_RE = ('  tile_(\S+): tile \[\d+,\d+\] out of \[\d+,\d+\] <averaged>:'
            ' ((?:' + TIME_RE + '\s+)+)')
 # for extracting tile layout
 TILE_LAYOUT_RE = ' out of \[(\d+),(\d+)\] <averaged>: '

 PER_SETTING_RE_COMPILED = re.compile(PER_SETTING_RE)
 SETTINGS_RE_COMPILED = re.compile(SETTINGS_RE)
 BENCH_RE_COMPILED = re.compile(BENCH_RE)
 TIME_RE_COMPILED = re.compile(TIME_RE)
 CONFIG_RE_COMPILED = re.compile(CONFIG_RE)
 TILE_RE_COMPILED = re.compile(TILE_RE)
 TILE_LAYOUT_RE_COMPILED = re.compile(TILE_LAYOUT_RE)

 class BenchDataPoint:
     """A single data point produced by bench.

     (str, str, str, float, {str:str}, str, [floats])"""
     def __init__(self, bench, config, time_type, time, settings,
                  tile_layout='', per_tile_values=[]):
         self.bench = bench
         self.config = config
         self.time_type = time_type
         self.time = time
         self.settings = settings
         # how tiles cover the whole picture. '5x3' means 5 columns and 3 rows.
         self.tile_layout = tile_layout
         # list of per_tile bench values, if applicable
         self.per_tile_values = per_tile_values

     def __repr__(self):
         return "BenchDataPoint(%s, %s, %s, %s, %s)" % (
                    str(self.bench),
                    str(self.config),
                    str(self.time_type),
                    str(self.time),
                    str(self.settings),
                )

 class _ExtremeType(object):
     """Instances of this class compare greater or less than other objects."""
     def __init__(self, cmpr, rep):
         object.__init__(self)
         self._cmpr = cmpr
         self._rep = rep

     def __cmp__(self, other):
         if isinstance(other, self.__class__) and other._cmpr == self._cmpr:
             return 0
         return self._cmpr

     def __repr__(self):
         return self._rep

 Max = _ExtremeType(1, "Max")
 Min = _ExtremeType(-1, "Min")

 class _ListAlgorithm(object):
     """Algorithm for selecting the representation value from a given list.
     representation is one of the ALGORITHM_XXX representation types."""
     def __init__(self, data, representation=None):
         if not representation:
             representation = ALGORITHM_AVERAGE  # default algorithm
         self._data = data
         self._len = len(data)
         if representation == ALGORITHM_AVERAGE:
             self._rep = sum(self._data) / self._len
         else:
             self._data.sort()
             if representation == ALGORITHM_MINIMUM:
                 self._rep = self._data[0]
             else:
                 # for percentiles, we use the value below which x% of values are
                 # found, which allows for better detection of quantum behaviors.
                 if representation == ALGORITHM_MEDIAN:
                     x = int(round(0.5 * self._len + 0.5))
                 elif representation == ALGORITHM_25TH_PERCENTILE:
                     x = int(round(0.25 * self._len + 0.5))
                 else:
                     raise Exception("invalid representation algorithm %s!" %
                                     representation)
                 self._rep = self._data[x - 1]

     def compute(self):
         return self._rep

 def _ParseAndStoreTimes(config_re_compiled, is_per_tile, line, bench,
                         value_dic, layout_dic, representation=None):
     """Parses given bench time line with regex and adds data to value_dic.

     config_re_compiled: precompiled regular expression for parsing the config
         line.
     is_per_tile: boolean indicating whether this is a per-tile bench.
         If so, we add tile layout into layout_dic as well.
     line: input string line to parse.
     bench: name of bench for the time values.
     value_dic: dictionary to store bench values. See bench_dic in parse() below.
     layout_dic: dictionary to store tile layouts. See parse() for descriptions.
     representation: should match one of the ALGORITHM_XXX types."""

     for config in config_re_compiled.finditer(line):
         current_config = config.group(1)
         tile_layout = ''
         if is_per_tile:  # per-tile bench, add name prefix
             current_config = 'tile_' + current_config
             layouts = TILE_LAYOUT_RE_COMPILED.search(line)
             if layouts and len(layouts.groups()) == 2:
               tile_layout = '%sx%s' % layouts.groups()
         times = config.group(2)
         for new_time in TIME_RE_COMPILED.finditer(times):
             current_time_type = new_time.group(1)
             iters = [float(i) for i in
                      new_time.group(2).strip().split(',')]
             value_dic.setdefault(bench, {}).setdefault(
                 current_config, {}).setdefault(current_time_type, []).append(
                     _ListAlgorithm(iters, representation).compute())
             layout_dic.setdefault(bench, {}).setdefault(
                 current_config, {}).setdefault(current_time_type, tile_layout)

 def parse(settings, lines, representation=None):
     """Parses bench output into a useful data structure.

     ({str:str}, __iter__ -> str) -> [BenchDataPoint]
     representation is one of the ALGORITHM_XXX types."""

     benches = []
     current_bench = None
     bench_dic = {}  # [bench][config][time_type] -> [list of bench values]
     # [bench][config][time_type] -> tile_layout
     layout_dic = {}

     for line in lines:

         # see if this line is a settings line
         settingsMatch = SETTINGS_RE_COMPILED.search(line)
         if (settingsMatch):
             settings = dict(settings)
             for settingMatch in PER_SETTING_RE_COMPILED.finditer(settingsMatch.group(1)):
                 if (settingMatch.group(2)):
                     settings[settingMatch.group(1)] = settingMatch.group(2)
                 else:
                     settings[settingMatch.group(1)] = True

         # see if this line starts a new bench
         new_bench = BENCH_RE_COMPILED.search(line)
         if new_bench:
             current_bench = new_bench.group(1)

         # add configs on this line to the bench_dic
         if current_bench:
             if line.startswith('  tile_') :
                 _ParseAndStoreTimes(TILE_RE_COMPILED, True, line, current_bench,
                                     bench_dic, layout_dic, representation)
             else:
                 _ParseAndStoreTimes(CONFIG_RE_COMPILED, False, line,
                                     current_bench,
                                     bench_dic, layout_dic, representation)

     # append benches to list, use the total time as final bench value.
     for bench in bench_dic:
         for config in bench_dic[bench]:
             for time_type in bench_dic[bench][config]:
                 tile_layout = ''
                 per_tile_values = []
                 if len(bench_dic[bench][config][time_type]) > 1:
                     # per-tile values, extract tile_layout
                     per_tile_values = bench_dic[bench][config][time_type]
                     tile_layout = layout_dic[bench][config][time_type]
                 benches.append(BenchDataPoint(
                     bench,
                     config,
                     time_type,
                     sum(bench_dic[bench][config][time_type]),
                     settings,
                     tile_layout,
                     per_tile_values))

     return benches

 class LinearRegression:
     """Linear regression data based on a set of data points.

     ([(Number,Number)])
     There must be at least two points for this to make sense."""
     def __init__(self, points):
         n = len(points)
         max_x = Min
         min_x = Max

         Sx = 0.0
         Sy = 0.0
         Sxx = 0.0
         Sxy = 0.0
         Syy = 0.0
         for point in points:
             x = point[0]
             y = point[1]
             max_x = max(max_x, x)
             min_x = min(min_x, x)

             Sx += x
             Sy += y
             Sxx += x*x
             Sxy += x*y
             Syy += y*y

         denom = n*Sxx - Sx*Sx
         if (denom != 0.0):
             B = (n*Sxy - Sx*Sy) / denom
         else:
             B = 0.0
         a = (1.0/n)*(Sy - B*Sx)

         se2 = 0
         sB2 = 0
         sa2 = 0
         if (n >= 3 and denom != 0.0):
             se2 = (1.0/(n*(n-2)) * (n*Syy - Sy*Sy - B*B*denom))
             sB2 = (n*se2) / denom
             sa2 = sB2 * (1.0/n) * Sxx


         self.slope = B
         self.intercept = a
         self.serror = math.sqrt(max(0, se2))
         self.serror_slope = math.sqrt(max(0, sB2))
         self.serror_intercept = math.sqrt(max(0, sa2))
         self.max_x = max_x
         self.min_x = min_x

     def __repr__(self):
         return "LinearRegression(%s, %s, %s, %s, %s)" % (
                    str(self.slope),
                    str(self.intercept),
                    str(self.serror),
                    str(self.serror_slope),
                    str(self.serror_intercept),
                )

     def find_min_slope(self):
         """Finds the minimal slope given one standard deviation."""
         slope = self.slope
         intercept = self.intercept
         error = self.serror
         regr_start = self.min_x
         regr_end = self.max_x
         regr_width = regr_end - regr_start

         if slope < 0:
             lower_left_y = slope*regr_start + intercept - error
             upper_right_y = slope*regr_end + intercept + error
             return min(0, (upper_right_y - lower_left_y) / regr_width)

         elif slope > 0:
             upper_left_y = slope*regr_start + intercept + error
             lower_right_y = slope*regr_end + intercept - error
             return max(0, (lower_right_y - upper_left_y) / regr_width)

         return 0

 def CreateRevisionLink(revision_number):
     """Returns HTML displaying the given revision number and linking to
     that revision's change page at code.google.com, e.g.
     http://code.google.com/p/skia/source/detail?r=2056
     """
     return '<a href="http://code.google.com/p/skia/source/detail?r=%s">%s</a>'%(
         revision_number, revision_number)

 def main():
     foo = [[0.0, 0.0], [0.0, 1.0], [0.0, 2.0], [0.0, 3.0]]
     LinearRegression(foo)

 if __name__ == "__main__":
     main()
	'''
	Created on May 19, 2011

	@author: bungeman
	'''

	import re
	import math

	# bench representation algorithm constant names
	ALGORITHM_AVERAGE = 'avg'
	ALGORITHM_MEDIAN = 'med'
	ALGORITHM_MINIMUM = 'min'
	ALGORITHM_25TH_PERCENTILE = '25th'

	# Regular expressions used throughout
	PER_SETTING_RE = '([^\s=]+)(?:=(\S+))?'
	SETTINGS_RE = 'skia bench:((?:\s+' + PER_SETTING_RE + ')*)'
	BENCH_RE = 'running bench (?:\[\d+ \d+\] )?\s*(\S+)'
	TIME_RE = '(?:(\w)msecs = )?\s((?:\d+\.\d+)(?:,\d+\.\d+)*)'
	# non-per-tile benches have configs that don't end with ']' or '>'
	CONFIG_RE = '(\S+[^\]>]): ((?:' + TIME_RE + '\s+)+)'
	# per-tile bench lines are in the following format. Note that there are
	# non-averaged bench numbers in separate lines, which we ignore now due to
	# their inaccuracy.
	TILE_RE = (' tile_(\S+): tile \[\d+,\d+\] out of \[\d+,\d+\] <averaged>:'
	' ((?:' + TIME_RE + '\s+)+)')
	# for extracting tile layout
	TILE_LAYOUT_RE = ' out of \[(\d+),(\d+)\] <averaged>: '

	PER_SETTING_RE_COMPILED = re.compile(PER_SETTING_RE)
	SETTINGS_RE_COMPILED = re.compile(SETTINGS_RE)
	BENCH_RE_COMPILED = re.compile(BENCH_RE)
	TIME_RE_COMPILED = re.compile(TIME_RE)
	CONFIG_RE_COMPILED = re.compile(CONFIG_RE)
	TILE_RE_COMPILED = re.compile(TILE_RE)
	TILE_LAYOUT_RE_COMPILED = re.compile(TILE_LAYOUT_RE)

	class BenchDataPoint:
	"""A single data point produced by bench.

	(str, str, str, float, {str:str}, str, [floats])"""
	def __init__(self, bench, config, time_type, time, settings,
	tile_layout='', per_tile_values=[]):
	self.bench = bench
	self.config = config
	self.time_type = time_type
	self.time = time
	self.settings = settings
	# how tiles cover the whole picture. '5x3' means 5 columns and 3 rows.
	self.tile_layout = tile_layout
	# list of per_tile bench values, if applicable
	self.per_tile_values = per_tile_values

	def __repr__(self):
	return "BenchDataPoint(%s, %s, %s, %s, %s)" % (
	str(self.bench),
	str(self.config),
	str(self.time_type),
	str(self.time),
	str(self.settings),
	)

	class _ExtremeType(object):
	"""Instances of this class compare greater or less than other objects."""
	def __init__(self, cmpr, rep):
	object.__init__(self)
	self._cmpr = cmpr
	self._rep = rep

	def __cmp__(self, other):
	if isinstance(other, self.__class__) and other._cmpr == self._cmpr:
	return 0
	return self._cmpr

	def __repr__(self):
	return self._rep

	Max = _ExtremeType(1, "Max")
	Min = _ExtremeType(-1, "Min")

	class _ListAlgorithm(object):
	"""Algorithm for selecting the representation value from a given list.
	representation is one of the ALGORITHM_XXX representation types."""
	def __init__(self, data, representation=None):
	if not representation:
	representation = ALGORITHM_AVERAGE # default algorithm
	self._data = data
	self._len = len(data)
	if representation == ALGORITHM_AVERAGE:
	self._rep = sum(self._data) / self._len
	else:
	self._data.sort()
	if representation == ALGORITHM_MINIMUM:
	self._rep = self._data[0]
	else:
	# for percentiles, we use the value below which x% of values are
	# found, which allows for better detection of quantum behaviors.
	if representation == ALGORITHM_MEDIAN:
	x = int(round(0.5 * self._len + 0.5))
	elif representation == ALGORITHM_25TH_PERCENTILE:
	x = int(round(0.25 * self._len + 0.5))
	else:
	raise Exception("invalid representation algorithm %s!" %
	representation)
	self._rep = self._data[x - 1]

	def compute(self):
	return self._rep

	def _ParseAndStoreTimes(config_re_compiled, is_per_tile, line, bench,
	value_dic, layout_dic, representation=None):
	"""Parses given bench time line with regex and adds data to value_dic.

	config_re_compiled: precompiled regular expression for parsing the config
	line.
	is_per_tile: boolean indicating whether this is a per-tile bench.
	If so, we add tile layout into layout_dic as well.
	line: input string line to parse.
	bench: name of bench for the time values.
	value_dic: dictionary to store bench values. See bench_dic in parse() below.
	layout_dic: dictionary to store tile layouts. See parse() for descriptions.
	representation: should match one of the ALGORITHM_XXX types."""

	for config in config_re_compiled.finditer(line):
	current_config = config.group(1)
	tile_layout = ''
	if is_per_tile: # per-tile bench, add name prefix
	current_config = 'tile_' + current_config
	layouts = TILE_LAYOUT_RE_COMPILED.search(line)
	if layouts and len(layouts.groups()) == 2:
	tile_layout = '%sx%s' % layouts.groups()
	times = config.group(2)
	for new_time in TIME_RE_COMPILED.finditer(times):
	current_time_type = new_time.group(1)
	iters = [float(i) for i in
	new_time.group(2).strip().split(',')]
	value_dic.setdefault(bench, {}).setdefault(
	current_config, {}).setdefault(current_time_type, []).append(
	_ListAlgorithm(iters, representation).compute())
	layout_dic.setdefault(bench, {}).setdefault(
	current_config, {}).setdefault(current_time_type, tile_layout)

	def parse(settings, lines, representation=None):
	"""Parses bench output into a useful data structure.

	({str:str}, __iter__ -> str) -> [BenchDataPoint]
	representation is one of the ALGORITHM_XXX types."""

	benches = []
	current_bench = None
	bench_dic = {} # [bench][config][time_type] -> [list of bench values]
	# [bench][config][time_type] -> tile_layout
	layout_dic = {}

	for line in lines:

	# see if this line is a settings line
	settingsMatch = SETTINGS_RE_COMPILED.search(line)
	if (settingsMatch):
	settings = dict(settings)
	for settingMatch in PER_SETTING_RE_COMPILED.finditer(settingsMatch.group(1)):
	if (settingMatch.group(2)):
	settings[settingMatch.group(1)] = settingMatch.group(2)
	else:
	settings[settingMatch.group(1)] = True

	# see if this line starts a new bench
	new_bench = BENCH_RE_COMPILED.search(line)
	if new_bench:
	current_bench = new_bench.group(1)

	# add configs on this line to the bench_dic
	if current_bench:
	if line.startswith(' tile_') :
	_ParseAndStoreTimes(TILE_RE_COMPILED, True, line, current_bench,
	bench_dic, layout_dic, representation)
	else:
	_ParseAndStoreTimes(CONFIG_RE_COMPILED, False, line,
	current_bench,
	bench_dic, layout_dic, representation)

	# append benches to list, use the total time as final bench value.
	for bench in bench_dic:
	for config in bench_dic[bench]:
	for time_type in bench_dic[bench][config]:
	tile_layout = ''
	per_tile_values = []
	if len(bench_dic[bench][config][time_type]) > 1:
	# per-tile values, extract tile_layout
	per_tile_values = bench_dic[bench][config][time_type]
	tile_layout = layout_dic[bench][config][time_type]
	benches.append(BenchDataPoint(
	bench,
	config,
	time_type,
	sum(bench_dic[bench][config][time_type]),
	settings,
	tile_layout,
	per_tile_values))

	return benches

	class LinearRegression:
	"""Linear regression data based on a set of data points.

	([(Number,Number)])
	There must be at least two points for this to make sense."""
	def __init__(self, points):
	n = len(points)
	max_x = Min
	min_x = Max

	Sx = 0.0
	Sy = 0.0
	Sxx = 0.0
	Sxy = 0.0
	Syy = 0.0
	for point in points:
	x = point[0]
	y = point[1]
	max_x = max(max_x, x)
	min_x = min(min_x, x)

	Sx += x
	Sy += y
	Sxx += x*x
	Sxy += x*y
	Syy += y*y

	denom = nSxx - SxSx
	if (denom != 0.0):
	B = (nSxy - SxSy) / denom
	else:
	B = 0.0
	a = (1.0/n)(Sy - BSx)

	se2 = 0
	sB2 = 0
	sa2 = 0
	if (n >= 3 and denom != 0.0):
	se2 = (1.0/(n(n-2)) (nSyy - SySy - BBdenom))
	sB2 = (n*se2) / denom
	sa2 = sB2 * (1.0/n) * Sxx


	self.slope = B
	self.intercept = a
	self.serror = math.sqrt(max(0, se2))
	self.serror_slope = math.sqrt(max(0, sB2))
	self.serror_intercept = math.sqrt(max(0, sa2))
	self.max_x = max_x
	self.min_x = min_x

	def __repr__(self):
	return "LinearRegression(%s, %s, %s, %s, %s)" % (
	str(self.slope),
	str(self.intercept),
	str(self.serror),
	str(self.serror_slope),
	str(self.serror_intercept),
	)

	def find_min_slope(self):
	"""Finds the minimal slope given one standard deviation."""
	slope = self.slope
	intercept = self.intercept
	error = self.serror
	regr_start = self.min_x
	regr_end = self.max_x
	regr_width = regr_end - regr_start

	if slope < 0:
	lower_left_y = slope*regr_start + intercept - error
	upper_right_y = slope*regr_end + intercept + error
	return min(0, (upper_right_y - lower_left_y) / regr_width)

	elif slope > 0:
	upper_left_y = slope*regr_start + intercept + error
	lower_right_y = slope*regr_end + intercept - error
	return max(0, (lower_right_y - upper_left_y) / regr_width)

	return 0

	def CreateRevisionLink(revision_number):
	"""Returns HTML displaying the given revision number and linking to
	that revision's change page at code.google.com, e.g.
	http://code.google.com/p/skia/source/detail?r=2056
	"""
	return '<a href="http://code.google.com/p/skia/source/detail?r=%s">%s</a>'%(
	revision_number, revision_number)

	def main():
	foo = [[0.0, 0.0], [0.0, 1.0], [0.0, 2.0], [0.0, 3.0]]
	LinearRegression(foo)

	if __name__ == "__main__":
	main()