contrib/analyze_brprob.py - gcc - Git at Google

 #!/usr/bin/env python3
 #
 # Script to analyze results of our branch prediction heuristics
 #
 # This file is part of GCC.
 #
 # GCC is free software; you can redistribute it and/or modify it under
 # the terms of the GNU General Public License as published by the Free
 # Software Foundation; either version 3, or (at your option) any later
 # version.
 #
 # GCC is distributed in the hope that it will be useful, but WITHOUT ANY
 # WARRANTY; without even the implied warranty of MERCHANTABILITY or
 # FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 # for more details.
 #
 # You should have received a copy of the GNU General Public License
 # along with GCC; see the file COPYING3.  If not see
 # <http://www.gnu.org/licenses/>.  */
 #
 #
 #
 # This script is used to calculate two basic properties of the branch prediction
 # heuristics - coverage and hitrate.  Coverage is number of executions
 # of a given branch matched by the heuristics and hitrate is probability
 # that once branch is predicted as taken it is really taken.
 #
 # These values are useful to determine the quality of given heuristics.
 # Hitrate may be directly used in predict.def.
 #
 # Usage:
 #  Step 1: Compile and profile your program.  You need to use -fprofile-generate
 #    flag to get the profiles.
 #  Step 2: Make a reference run of the intrumented application.
 #  Step 3: Compile the program with collected profile and dump IPA profiles
 #          (-fprofile-use -fdump-ipa-profile-details)
 #  Step 4: Collect all generated dump files:
 #          find . -name '*.profile' | xargs cat > dump_file
 #  Step 5: Run the script:
 #          ./analyze_brprob.py dump_file
 #          and read results.  Basically the following table is printed:
 #
 # HEURISTICS                           BRANCHES  (REL)  HITRATE                COVERAGE  (REL)
 # early return (on trees)                     3   0.2%  35.83% /  93.64%          66360   0.0%
 # guess loop iv compare                       8   0.6%  53.35% /  53.73%       11183344   0.0%
 # call                                       18   1.4%  31.95% /  69.95%       51880179   0.2%
 # loop guard                                 23   1.8%  84.13% /  84.85%    13749065956  42.2%
 # opcode values positive (on trees)          42   3.3%  15.71% /  84.81%     6771097902  20.8%
 # opcode values nonequal (on trees)         226  17.6%  72.48% /  72.84%      844753864   2.6%
 # loop exit                                 231  18.0%  86.97% /  86.98%     8952666897  27.5%
 # loop iterations                           239  18.6%  91.10% /  91.10%     3062707264   9.4%
 # DS theory                                 281  21.9%  82.08% /  83.39%     7787264075  23.9%
 # no prediction                             293  22.9%  46.92% /  70.70%     2293267840   7.0%
 # guessed loop iterations                   313  24.4%  76.41% /  76.41%    10782750177  33.1%
 # first match                               708  55.2%  82.30% /  82.31%    22489588691  69.0%
 # combined                                 1282 100.0%  79.76% /  81.75%    32570120606 100.0%
 #
 #
 #  The heuristics called "first match" is a heuristics used by GCC branch
 #  prediction pass and it predicts 55.2% branches correctly. As you can,
 #  the heuristics has very good covertage (69.05%).  On the other hand,
 #  "opcode values nonequal (on trees)" heuristics has good hirate, but poor
 #  coverage.

 import sys
 import os
 import re
 import argparse

 from math import *

 counter_aggregates = set(['combined', 'first match', 'DS theory',
     'no prediction'])
 hot_threshold = 10

 def percentage(a, b):
     return 100.0 * a / b

 def average(values):
     return 1.0 * sum(values) / len(values)

 def average_cutoff(values, cut):
     l = len(values)
     skip = floor(l * cut / 2)
     if skip > 0:
         values.sort()
         values = values[skip:-skip]
     return average(values)

 def median(values):
     values.sort()
     return values[int(len(values) / 2)]

 class PredictDefFile:
     def __init__(self, path):
         self.path = path
         self.predictors = {}

     def parse_and_modify(self, heuristics, write_def_file):
         lines = [x.rstrip() for x in open(self.path).readlines()]

         p = None
         modified_lines = []
         for l in lines:
             if l.startswith('DEF_PREDICTOR'):
                 m = re.match('.*"(.*)".*', l)
                 p = m.group(1)
             elif l == '':
                 p = None

             if p != None:
                 heuristic = [x for x in heuristics if x.name == p]
                 heuristic = heuristic[0] if len(heuristic) == 1 else None

                 m = re.match('.*HITRATE \(([^)]*)\).*', l)
                 if (m != None):
                     self.predictors[p] = int(m.group(1))

                     # modify the line
                     if heuristic != None:
                         new_line = (l[:m.start(1)]
                             + str(round(heuristic.get_hitrate()))
                             + l[m.end(1):])
                         l = new_line
                     p = None
                 elif 'PROB_VERY_LIKELY' in l:
                     self.predictors[p] = 100
             modified_lines.append(l)

         # save the file
         if write_def_file:
             with open(self.path, 'w+') as f:
                 for l in modified_lines:
                     f.write(l + '\n')
 class Heuristics:
     def __init__(self, count, hits, fits):
         self.count = count
         self.hits = hits
         self.fits = fits

 class Summary:
     def __init__(self, name):
         self.name = name
         self.edges= []

     def branches(self):
         return len(self.edges)

     def hits(self):
         return sum([x.hits for x in self.edges])

     def fits(self):
         return sum([x.fits for x in self.edges])

     def count(self):
         return sum([x.count for x in self.edges])

     def successfull_branches(self):
         return len([x for x in self.edges if 2 * x.hits >= x.count])

     def get_hitrate(self):
         return 100.0 * self.hits() / self.count()

     def get_branch_hitrate(self):
         return 100.0 * self.successfull_branches() / self.branches()

     def count_formatted(self):
         v = self.count()
         for unit in ['', 'k', 'M', 'G', 'T', 'P', 'E', 'Z', 'Y']:
             if v < 1000:
                 return "%3.2f%s" % (v, unit)
             v /= 1000.0
         return "%.1f%s" % (v, 'Y')

     def count(self):
         return sum([x.count for x in self.edges])

     def print(self, branches_max, count_max, predict_def):
         # filter out most hot edges (if requested)
         self.edges = sorted(self.edges, reverse = True, key = lambda x: x.count)
         if args.coverage_threshold != None:
             threshold = args.coverage_threshold * self.count() / 100
             edges = [x for x in self.edges if x.count < threshold]
             if len(edges) != 0:
                 self.edges = edges

         predicted_as = None
         if predict_def != None and self.name in predict_def.predictors:
             predicted_as = predict_def.predictors[self.name]

         print('%-40s %8i %5.1f%% %11.2f%% %7.2f%% / %6.2f%% %14i %8s %5.1f%%' %
             (self.name, self.branches(),
                 percentage(self.branches(), branches_max),
                 self.get_branch_hitrate(),
                 self.get_hitrate(),
                 percentage(self.fits(), self.count()),
                 self.count(), self.count_formatted(),
                 percentage(self.count(), count_max)), end = '')

         if predicted_as != None:
             print('%12i%% %5.1f%%' % (predicted_as,
                 self.get_hitrate() - predicted_as), end = '')
         else:
             print(' ' * 20, end = '')

         # print details about the most important edges
         if args.coverage_threshold == None:
             edges = [x for x in self.edges[:100] if x.count * hot_threshold > self.count()]
             if args.verbose:
                 for c in edges:
                     r = 100.0 * c.count / self.count()
                     print(' %.0f%%:%d' % (r, c.count), end = '')
             elif len(edges) > 0:
                 print(' %0.0f%%:%d' % (100.0 * sum([x.count for x in edges]) / self.count(), len(edges)), end = '')

         print()

 class Profile:
     def __init__(self, filename):
         self.filename = filename
         self.heuristics = {}
         self.niter_vector = []

     def add(self, name, prediction, count, hits):
         if not name in self.heuristics:
             self.heuristics[name] = Summary(name)

         s = self.heuristics[name]

         if prediction < 50:
             hits = count - hits
         remaining = count - hits
         fits = max(hits, remaining)

         s.edges.append(Heuristics(count, hits, fits))

     def add_loop_niter(self, niter):
         if niter > 0:
             self.niter_vector.append(niter)

     def branches_max(self):
         return max([v.branches() for k, v in self.heuristics.items()])

     def count_max(self):
         return max([v.count() for k, v in self.heuristics.items()])

     def print_group(self, sorting, group_name, heuristics, predict_def):
         count_max = self.count_max()
         branches_max = self.branches_max()

         sorter = lambda x: x.branches()
         if sorting == 'branch-hitrate':
             sorter = lambda x: x.get_branch_hitrate()
         elif sorting == 'hitrate':
             sorter = lambda x: x.get_hitrate()
         elif sorting == 'coverage':
             sorter = lambda x: x.count
         elif sorting == 'name':
             sorter = lambda x: x.name.lower()

         print('%-40s %8s %6s %12s %18s %14s %8s %6s %12s %6s %s' %
             ('HEURISTICS', 'BRANCHES', '(REL)',
             'BR. HITRATE', 'HITRATE', 'COVERAGE', 'COVERAGE', '(REL)',
             'predict.def', '(REL)', 'HOT branches (>%d%%)' % hot_threshold))
         for h in sorted(heuristics, key = sorter):
             h.print(branches_max, count_max, predict_def)

     def dump(self, sorting):
         heuristics = self.heuristics.values()
         if len(heuristics) == 0:
             print('No heuristics available')
             return

         predict_def = None
         if args.def_file != None:
             predict_def = PredictDefFile(args.def_file)
             predict_def.parse_and_modify(heuristics, args.write_def_file)

         special = list(filter(lambda x: x.name in counter_aggregates,
             heuristics))
         normal = list(filter(lambda x: x.name not in counter_aggregates,
             heuristics))

         self.print_group(sorting, 'HEURISTICS', normal, predict_def)
         print()
         self.print_group(sorting, 'HEURISTIC AGGREGATES', special, predict_def)

         if len(self.niter_vector) > 0:
             print ('\nLoop count: %d' % len(self.niter_vector)),
             print('  avg. # of iter: %.2f' % average(self.niter_vector))
             print('  median # of iter: %.2f' % median(self.niter_vector))
             for v in [1, 5, 10, 20, 30]:
                 cut = 0.01 * v
                 print('  avg. (%d%% cutoff) # of iter: %.2f'
                     % (v, average_cutoff(self.niter_vector, cut)))

 parser = argparse.ArgumentParser()
 parser.add_argument('dump_file', metavar = 'dump_file',
     help = 'IPA profile dump file')
 parser.add_argument('-s', '--sorting', dest = 'sorting',
     choices = ['branches', 'branch-hitrate', 'hitrate', 'coverage', 'name'],
     default = 'branches')
 parser.add_argument('-d', '--def-file', help = 'path to predict.def')
 parser.add_argument('-w', '--write-def-file', action = 'store_true',
     help = 'Modify predict.def file in order to set new numbers')
 parser.add_argument('-c', '--coverage-threshold', type = int,
     help = 'Ignore edges that have percentage coverage >= coverage-threshold')
 parser.add_argument('-v', '--verbose', action = 'store_true', help = 'Print verbose informations')

 args = parser.parse_args()

 profile = Profile(args.dump_file)
 loop_niter_str = ';;  profile-based iteration count: '

 for l in open(args.dump_file):
     if l.startswith(';;heuristics;'):
         parts = l.strip().split(';')
         assert len(parts) == 8
         name = parts[3]
         prediction = float(parts[6])
         count = int(parts[4])
         hits = int(parts[5])

         profile.add(name, prediction, count, hits)
     elif l.startswith(loop_niter_str):
         v = int(l[len(loop_niter_str):])
         profile.add_loop_niter(v)

 profile.dump(args.sorting)
	#!/usr/bin/env python3
	#
	# Script to analyze results of our branch prediction heuristics
	#
	# This file is part of GCC.
	#
	# GCC is free software; you can redistribute it and/or modify it under
	# the terms of the GNU General Public License as published by the Free
	# Software Foundation; either version 3, or (at your option) any later
	# version.
	#
	# GCC is distributed in the hope that it will be useful, but WITHOUT ANY
	# WARRANTY; without even the implied warranty of MERCHANTABILITY or
	# FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	# for more details.
	#
	# You should have received a copy of the GNU General Public License
	# along with GCC; see the file COPYING3. If not see
	# <http://www.gnu.org/licenses/>. */
	#
	#
	#
	# This script is used to calculate two basic properties of the branch prediction
	# heuristics - coverage and hitrate. Coverage is number of executions
	# of a given branch matched by the heuristics and hitrate is probability
	# that once branch is predicted as taken it is really taken.
	#
	# These values are useful to determine the quality of given heuristics.
	# Hitrate may be directly used in predict.def.
	#
	# Usage:
	# Step 1: Compile and profile your program. You need to use -fprofile-generate
	# flag to get the profiles.
	# Step 2: Make a reference run of the intrumented application.
	# Step 3: Compile the program with collected profile and dump IPA profiles
	# (-fprofile-use -fdump-ipa-profile-details)
	# Step 4: Collect all generated dump files:
	# find . -name '*.profile' \| xargs cat > dump_file
	# Step 5: Run the script:
	# ./analyze_brprob.py dump_file
	# and read results. Basically the following table is printed:
	#
	# HEURISTICS BRANCHES (REL) HITRATE COVERAGE (REL)
	# early return (on trees) 3 0.2% 35.83% / 93.64% 66360 0.0%
	# guess loop iv compare 8 0.6% 53.35% / 53.73% 11183344 0.0%
	# call 18 1.4% 31.95% / 69.95% 51880179 0.2%
	# loop guard 23 1.8% 84.13% / 84.85% 13749065956 42.2%
	# opcode values positive (on trees) 42 3.3% 15.71% / 84.81% 6771097902 20.8%
	# opcode values nonequal (on trees) 226 17.6% 72.48% / 72.84% 844753864 2.6%
	# loop exit 231 18.0% 86.97% / 86.98% 8952666897 27.5%
	# loop iterations 239 18.6% 91.10% / 91.10% 3062707264 9.4%
	# DS theory 281 21.9% 82.08% / 83.39% 7787264075 23.9%
	# no prediction 293 22.9% 46.92% / 70.70% 2293267840 7.0%
	# guessed loop iterations 313 24.4% 76.41% / 76.41% 10782750177 33.1%
	# first match 708 55.2% 82.30% / 82.31% 22489588691 69.0%
	# combined 1282 100.0% 79.76% / 81.75% 32570120606 100.0%
	#
	#
	# The heuristics called "first match" is a heuristics used by GCC branch
	# prediction pass and it predicts 55.2% branches correctly. As you can,
	# the heuristics has very good covertage (69.05%). On the other hand,
	# "opcode values nonequal (on trees)" heuristics has good hirate, but poor
	# coverage.

	import sys
	import os
	import re
	import argparse

	from math import *

	counter_aggregates = set(['combined', 'first match', 'DS theory',
	'no prediction'])
	hot_threshold = 10

	def percentage(a, b):
	return 100.0 * a / b

	def average(values):
	return 1.0 * sum(values) / len(values)

	def average_cutoff(values, cut):
	l = len(values)
	skip = floor(l * cut / 2)
	if skip > 0:
	values.sort()
	values = values[skip:-skip]
	return average(values)

	def median(values):
	values.sort()
	return values[int(len(values) / 2)]

	class PredictDefFile:
	def __init__(self, path):
	self.path = path
	self.predictors = {}

	def parse_and_modify(self, heuristics, write_def_file):
	lines = [x.rstrip() for x in open(self.path).readlines()]

	p = None
	modified_lines = []
	for l in lines:
	if l.startswith('DEF_PREDICTOR'):
	m = re.match('."(.)".*', l)
	p = m.group(1)
	elif l == '':
	p = None

	if p != None:
	heuristic = [x for x in heuristics if x.name == p]
	heuristic = heuristic[0] if len(heuristic) == 1 else None

	m = re.match('.HITRATE \(([^)])\).*', l)
	if (m != None):
	self.predictors[p] = int(m.group(1))

	# modify the line
	if heuristic != None:
	new_line = (l[:m.start(1)]
	+ str(round(heuristic.get_hitrate()))
	+ l[m.end(1):])
	l = new_line
	p = None
	elif 'PROB_VERY_LIKELY' in l:
	self.predictors[p] = 100
	modified_lines.append(l)

	# save the file
	if write_def_file:
	with open(self.path, 'w+') as f:
	for l in modified_lines:
	f.write(l + '\n')
	class Heuristics:
	def __init__(self, count, hits, fits):
	self.count = count
	self.hits = hits
	self.fits = fits

	class Summary:
	def __init__(self, name):
	self.name = name
	self.edges= []

	def branches(self):
	return len(self.edges)

	def hits(self):
	return sum([x.hits for x in self.edges])

	def fits(self):
	return sum([x.fits for x in self.edges])

	def count(self):
	return sum([x.count for x in self.edges])

	def successfull_branches(self):
	return len([x for x in self.edges if 2 * x.hits >= x.count])

	def get_hitrate(self):
	return 100.0 * self.hits() / self.count()

	def get_branch_hitrate(self):
	return 100.0 * self.successfull_branches() / self.branches()

	def count_formatted(self):
	v = self.count()
	for unit in ['', 'k', 'M', 'G', 'T', 'P', 'E', 'Z', 'Y']:
	if v < 1000:
	return "%3.2f%s" % (v, unit)
	v /= 1000.0
	return "%.1f%s" % (v, 'Y')

	def count(self):
	return sum([x.count for x in self.edges])

	def print(self, branches_max, count_max, predict_def):
	# filter out most hot edges (if requested)
	self.edges = sorted(self.edges, reverse = True, key = lambda x: x.count)
	if args.coverage_threshold != None:
	threshold = args.coverage_threshold * self.count() / 100
	edges = [x for x in self.edges if x.count < threshold]
	if len(edges) != 0:
	self.edges = edges

	predicted_as = None
	if predict_def != None and self.name in predict_def.predictors:
	predicted_as = predict_def.predictors[self.name]

	print('%-40s %8i %5.1f%% %11.2f%% %7.2f%% / %6.2f%% %14i %8s %5.1f%%' %
	(self.name, self.branches(),
	percentage(self.branches(), branches_max),
	self.get_branch_hitrate(),
	self.get_hitrate(),
	percentage(self.fits(), self.count()),
	self.count(), self.count_formatted(),
	percentage(self.count(), count_max)), end = '')

	if predicted_as != None:
	print('%12i%% %5.1f%%' % (predicted_as,
	self.get_hitrate() - predicted_as), end = '')
	else:
	print(' ' * 20, end = '')

	# print details about the most important edges
	if args.coverage_threshold == None:
	edges = [x for x in self.edges[:100] if x.count * hot_threshold > self.count()]
	if args.verbose:
	for c in edges:
	r = 100.0 * c.count / self.count()
	print(' %.0f%%:%d' % (r, c.count), end = '')
	elif len(edges) > 0:
	print(' %0.0f%%:%d' % (100.0 * sum([x.count for x in edges]) / self.count(), len(edges)), end = '')

	print()

	class Profile:
	def __init__(self, filename):
	self.filename = filename
	self.heuristics = {}
	self.niter_vector = []

	def add(self, name, prediction, count, hits):
	if not name in self.heuristics:
	self.heuristics[name] = Summary(name)

	s = self.heuristics[name]

	if prediction < 50:
	hits = count - hits
	remaining = count - hits
	fits = max(hits, remaining)

	s.edges.append(Heuristics(count, hits, fits))

	def add_loop_niter(self, niter):
	if niter > 0:
	self.niter_vector.append(niter)

	def branches_max(self):
	return max([v.branches() for k, v in self.heuristics.items()])

	def count_max(self):
	return max([v.count() for k, v in self.heuristics.items()])

	def print_group(self, sorting, group_name, heuristics, predict_def):
	count_max = self.count_max()
	branches_max = self.branches_max()

	sorter = lambda x: x.branches()
	if sorting == 'branch-hitrate':
	sorter = lambda x: x.get_branch_hitrate()
	elif sorting == 'hitrate':
	sorter = lambda x: x.get_hitrate()
	elif sorting == 'coverage':
	sorter = lambda x: x.count
	elif sorting == 'name':
	sorter = lambda x: x.name.lower()

	print('%-40s %8s %6s %12s %18s %14s %8s %6s %12s %6s %s' %
	('HEURISTICS', 'BRANCHES', '(REL)',
	'BR. HITRATE', 'HITRATE', 'COVERAGE', 'COVERAGE', '(REL)',
	'predict.def', '(REL)', 'HOT branches (>%d%%)' % hot_threshold))
	for h in sorted(heuristics, key = sorter):
	h.print(branches_max, count_max, predict_def)

	def dump(self, sorting):
	heuristics = self.heuristics.values()
	if len(heuristics) == 0:
	print('No heuristics available')
	return

	predict_def = None
	if args.def_file != None:
	predict_def = PredictDefFile(args.def_file)
	predict_def.parse_and_modify(heuristics, args.write_def_file)

	special = list(filter(lambda x: x.name in counter_aggregates,
	heuristics))
	normal = list(filter(lambda x: x.name not in counter_aggregates,
	heuristics))

	self.print_group(sorting, 'HEURISTICS', normal, predict_def)
	print()
	self.print_group(sorting, 'HEURISTIC AGGREGATES', special, predict_def)

	if len(self.niter_vector) > 0:
	print ('\nLoop count: %d' % len(self.niter_vector)),
	print(' avg. # of iter: %.2f' % average(self.niter_vector))
	print(' median # of iter: %.2f' % median(self.niter_vector))
	for v in [1, 5, 10, 20, 30]:
	cut = 0.01 * v
	print(' avg. (%d%% cutoff) # of iter: %.2f'
	% (v, average_cutoff(self.niter_vector, cut)))

	parser = argparse.ArgumentParser()
	parser.add_argument('dump_file', metavar = 'dump_file',
	help = 'IPA profile dump file')
	parser.add_argument('-s', '--sorting', dest = 'sorting',
	choices = ['branches', 'branch-hitrate', 'hitrate', 'coverage', 'name'],
	default = 'branches')
	parser.add_argument('-d', '--def-file', help = 'path to predict.def')
	parser.add_argument('-w', '--write-def-file', action = 'store_true',
	help = 'Modify predict.def file in order to set new numbers')
	parser.add_argument('-c', '--coverage-threshold', type = int,
	help = 'Ignore edges that have percentage coverage >= coverage-threshold')
	parser.add_argument('-v', '--verbose', action = 'store_true', help = 'Print verbose informations')

	args = parser.parse_args()

	profile = Profile(args.dump_file)
	loop_niter_str = ';; profile-based iteration count: '

	for l in open(args.dump_file):
	if l.startswith(';;heuristics;'):
	parts = l.strip().split(';')
	assert len(parts) == 8
	name = parts[3]
	prediction = float(parts[6])
	count = int(parts[4])
	hits = int(parts[5])

	profile.add(name, prediction, count, hits)
	elif l.startswith(loop_niter_str):
	v = int(l[len(loop_niter_str):])
	profile.add_loop_niter(v)

	profile.dump(args.sorting)