ref: 1132d1b9df4c9ea2b857fa9778fe6762cd81ded8
dir: /sys/src/cmd/python/Tools/pybench/pybench.py/
#!/usr/local/bin/python -O """ A Python Benchmark Suite """ # # Note: Please keep this module compatible to Python 1.5.2. # # Tests may include features in later Python versions, but these # should then be embedded in try-except clauses in the configuration # module Setup.py. # # pybench Copyright __copyright__ = """\ Copyright (c), 1997-2006, Marc-Andre Lemburg (mal@lemburg.com) Copyright (c), 2000-2006, eGenix.com Software GmbH (info@egenix.com) All Rights Reserved. Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee or royalty is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation or portions thereof, including modifications, that you make. THE AUTHOR MARC-ANDRE LEMBURG DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE ! """ import sys, time, operator, string from CommandLine import * try: import cPickle pickle = cPickle except ImportError: import pickle # Version number; version history: see README file ! __version__ = '2.0' ### Constants # Second fractions MILLI_SECONDS = 1e3 MICRO_SECONDS = 1e6 # Percent unit PERCENT = 100 # Horizontal line length LINE = 79 # Minimum test run-time MIN_TEST_RUNTIME = 1e-3 # Number of calibration runs to use for calibrating the tests CALIBRATION_RUNS = 20 # Number of calibration loops to run for each calibration run CALIBRATION_LOOPS = 20 # Allow skipping calibration ? ALLOW_SKIPPING_CALIBRATION = 1 # Timer types TIMER_TIME_TIME = 'time.time' TIMER_TIME_CLOCK = 'time.clock' TIMER_SYSTIMES_PROCESSTIME = 'systimes.processtime' # Choose platform default timer if sys.platform[:3] == 'win': # On WinXP this has 2.5ms resolution TIMER_PLATFORM_DEFAULT = TIMER_TIME_CLOCK else: # On Linux this has 1ms resolution TIMER_PLATFORM_DEFAULT = TIMER_TIME_TIME # Print debug information ? _debug = 0 ### Helpers def get_timer(timertype): if timertype == TIMER_TIME_TIME: return time.time elif timertype == TIMER_TIME_CLOCK: return time.clock elif timertype == TIMER_SYSTIMES_PROCESSTIME: import systimes return systimes.processtime else: raise TypeError('unknown timer type: %s' % timertype) def get_machine_details(): import platform if _debug: print 'Getting machine details...' buildno, builddate = platform.python_build() python = platform.python_version() if python > '2.0': try: unichr(100000) except ValueError: # UCS2 build (standard) unicode = 'UCS2' else: # UCS4 build (most recent Linux distros) unicode = 'UCS4' else: unicode = None bits, linkage = platform.architecture() return { 'platform': platform.platform(), 'processor': platform.processor(), 'executable': sys.executable, 'python': platform.python_version(), 'compiler': platform.python_compiler(), 'buildno': buildno, 'builddate': builddate, 'unicode': unicode, 'bits': bits, } def print_machine_details(d, indent=''): l = ['Machine Details:', ' Platform ID: %s' % d.get('platform', 'n/a'), ' Processor: %s' % d.get('processor', 'n/a'), '', 'Python:', ' Executable: %s' % d.get('executable', 'n/a'), ' Version: %s' % d.get('python', 'n/a'), ' Compiler: %s' % d.get('compiler', 'n/a'), ' Bits: %s' % d.get('bits', 'n/a'), ' Build: %s (#%s)' % (d.get('builddate', 'n/a'), d.get('buildno', 'n/a')), ' Unicode: %s' % d.get('unicode', 'n/a'), ] print indent + string.join(l, '\n' + indent) + '\n' ### Test baseclass class Test: """ All test must have this class as baseclass. It provides the necessary interface to the benchmark machinery. The tests must set .rounds to a value high enough to let the test run between 20-50 seconds. This is needed because clock()-timing only gives rather inaccurate values (on Linux, for example, it is accurate to a few hundreths of a second). If you don't want to wait that long, use a warp factor larger than 1. It is also important to set the .operations variable to a value representing the number of "virtual operations" done per call of .run(). If you change a test in some way, don't forget to increase it's version number. """ ### Instance variables that each test should override # Version number of the test as float (x.yy); this is important # for comparisons of benchmark runs - tests with unequal version # number will not get compared. version = 2.0 # The number of abstract operations done in each round of the # test. An operation is the basic unit of what you want to # measure. The benchmark will output the amount of run-time per # operation. Note that in order to raise the measured timings # significantly above noise level, it is often required to repeat # sets of operations more than once per test round. The measured # overhead per test round should be less than 1 second. operations = 1 # Number of rounds to execute per test run. This should be # adjusted to a figure that results in a test run-time of between # 1-2 seconds. rounds = 100000 ### Internal variables # Mark this class as implementing a test is_a_test = 1 # Last timing: (real, run, overhead) last_timing = (0.0, 0.0, 0.0) # Warp factor to use for this test warp = 1 # Number of calibration runs to use calibration_runs = CALIBRATION_RUNS # List of calibration timings overhead_times = None # List of test run timings times = [] # Timer used for the benchmark timer = TIMER_PLATFORM_DEFAULT def __init__(self, warp=None, calibration_runs=None, timer=None): # Set parameters if warp is not None: self.rounds = int(self.rounds / warp) if self.rounds == 0: raise ValueError('warp factor set too high') self.warp = warp if calibration_runs is not None: if (not ALLOW_SKIPPING_CALIBRATION and calibration_runs < 1): raise ValueError('at least one calibration run is required') self.calibration_runs = calibration_runs if timer is not None: timer = timer # Init variables self.times = [] self.overhead_times = [] # We want these to be in the instance dict, so that pickle # saves them self.version = self.version self.operations = self.operations self.rounds = self.rounds def get_timer(self): """ Return the timer function to use for the test. """ return get_timer(self.timer) def compatible(self, other): """ Return 1/0 depending on whether the test is compatible with the other Test instance or not. """ if self.version != other.version: return 0 if self.rounds != other.rounds: return 0 return 1 def calibrate_test(self): if self.calibration_runs == 0: self.overhead_times = [0.0] return calibrate = self.calibrate timer = self.get_timer() calibration_loops = range(CALIBRATION_LOOPS) # Time the calibration loop overhead prep_times = [] for i in range(self.calibration_runs): t = timer() for i in calibration_loops: pass t = timer() - t prep_times.append(t) min_prep_time = min(prep_times) if _debug: print print 'Calib. prep time = %.6fms' % ( min_prep_time * MILLI_SECONDS) # Time the calibration runs (doing CALIBRATION_LOOPS loops of # .calibrate() method calls each) for i in range(self.calibration_runs): t = timer() for i in calibration_loops: calibrate() t = timer() - t self.overhead_times.append(t / CALIBRATION_LOOPS - min_prep_time) # Check the measured times min_overhead = min(self.overhead_times) max_overhead = max(self.overhead_times) if _debug: print 'Calib. overhead time = %.6fms' % ( min_overhead * MILLI_SECONDS) if min_overhead < 0.0: raise ValueError('calibration setup did not work') if max_overhead - min_overhead > 0.1: raise ValueError( 'overhead calibration timing range too inaccurate: ' '%r - %r' % (min_overhead, max_overhead)) def run(self): """ Run the test in two phases: first calibrate, then do the actual test. Be careful to keep the calibration timing low w/r to the test timing. """ test = self.test timer = self.get_timer() # Get calibration min_overhead = min(self.overhead_times) # Test run t = timer() test() t = timer() - t if t < MIN_TEST_RUNTIME: raise ValueError('warp factor too high: ' 'test times are < 10ms') eff_time = t - min_overhead if eff_time < 0: raise ValueError('wrong calibration') self.last_timing = (eff_time, t, min_overhead) self.times.append(eff_time) def calibrate(self): """ Calibrate the test. This method should execute everything that is needed to setup and run the test - except for the actual operations that you intend to measure. pybench uses this method to measure the test implementation overhead. """ return def test(self): """ Run the test. The test needs to run self.rounds executing self.operations number of operations each. """ return def stat(self): """ Return test run statistics as tuple: (minimum run time, average run time, total run time, average time per operation, minimum overhead time) """ runs = len(self.times) if runs == 0: return 0.0, 0.0, 0.0, 0.0 min_time = min(self.times) total_time = reduce(operator.add, self.times, 0.0) avg_time = total_time / float(runs) operation_avg = total_time / float(runs * self.rounds * self.operations) if self.overhead_times: min_overhead = min(self.overhead_times) else: min_overhead = self.last_timing[2] return min_time, avg_time, total_time, operation_avg, min_overhead ### Load Setup # This has to be done after the definition of the Test class, since # the Setup module will import subclasses using this class. import Setup ### Benchmark base class class Benchmark: # Name of the benchmark name = '' # Number of benchmark rounds to run rounds = 1 # Warp factor use to run the tests warp = 1 # Warp factor # Average benchmark round time roundtime = 0 # Benchmark version number as float x.yy version = 2.0 # Produce verbose output ? verbose = 0 # Dictionary with the machine details machine_details = None # Timer used for the benchmark timer = TIMER_PLATFORM_DEFAULT def __init__(self, name, verbose=None, timer=None, warp=None, calibration_runs=None): if name: self.name = name else: self.name = '%04i-%02i-%02i %02i:%02i:%02i' % \ (time.localtime(time.time())[:6]) if verbose is not None: self.verbose = verbose if timer is not None: self.timer = timer if warp is not None: self.warp = warp if calibration_runs is not None: self.calibration_runs = calibration_runs # Init vars self.tests = {} if _debug: print 'Getting machine details...' self.machine_details = get_machine_details() # Make .version an instance attribute to have it saved in the # Benchmark pickle self.version = self.version def get_timer(self): """ Return the timer function to use for the test. """ return get_timer(self.timer) def compatible(self, other): """ Return 1/0 depending on whether the benchmark is compatible with the other Benchmark instance or not. """ if self.version != other.version: return 0 if (self.machine_details == other.machine_details and self.timer != other.timer): return 0 if (self.calibration_runs == 0 and other.calibration_runs != 0): return 0 if (self.calibration_runs != 0 and other.calibration_runs == 0): return 0 return 1 def load_tests(self, setupmod, limitnames=None): # Add tests if self.verbose: print 'Searching for tests ...' print '--------------------------------------' for testclass in setupmod.__dict__.values(): if not hasattr(testclass, 'is_a_test'): continue name = testclass.__name__ if name == 'Test': continue if (limitnames is not None and limitnames.search(name) is None): continue self.tests[name] = testclass( warp=self.warp, calibration_runs=self.calibration_runs, timer=self.timer) l = self.tests.keys() l.sort() if self.verbose: for name in l: print ' %s' % name print '--------------------------------------' print ' %i tests found' % len(l) print def calibrate(self): print 'Calibrating tests. Please wait...' if self.verbose: print print 'Test min max' print '-' * LINE tests = self.tests.items() tests.sort() for i in range(len(tests)): name, test = tests[i] test.calibrate_test() if self.verbose: print '%30s: %6.3fms %6.3fms' % \ (name, min(test.overhead_times) * MILLI_SECONDS, max(test.overhead_times) * MILLI_SECONDS) print def run(self): tests = self.tests.items() tests.sort() timer = self.get_timer() print 'Running %i round(s) of the suite at warp factor %i:' % \ (self.rounds, self.warp) print self.roundtimes = [] for i in range(self.rounds): if self.verbose: print ' Round %-25i effective absolute overhead' % (i+1) total_eff_time = 0.0 for j in range(len(tests)): name, test = tests[j] if self.verbose: print '%30s:' % name, test.run() (eff_time, abs_time, min_overhead) = test.last_timing total_eff_time = total_eff_time + eff_time if self.verbose: print ' %5.0fms %5.0fms %7.3fms' % \ (eff_time * MILLI_SECONDS, abs_time * MILLI_SECONDS, min_overhead * MILLI_SECONDS) self.roundtimes.append(total_eff_time) if self.verbose: print (' ' ' ------------------------------') print (' ' ' Totals: %6.0fms' % (total_eff_time * MILLI_SECONDS)) print else: print '* Round %i done in %.3f seconds.' % (i+1, total_eff_time) print def stat(self): """ Return benchmark run statistics as tuple: (minimum round time, average round time, maximum round time) XXX Currently not used, since the benchmark does test statistics across all rounds. """ runs = len(self.roundtimes) if runs == 0: return 0.0, 0.0 min_time = min(self.roundtimes) total_time = reduce(operator.add, self.roundtimes, 0.0) avg_time = total_time / float(runs) max_time = max(self.roundtimes) return (min_time, avg_time, max_time) def print_header(self, title='Benchmark'): print '-' * LINE print '%s: %s' % (title, self.name) print '-' * LINE print print ' Rounds: %s' % self.rounds print ' Warp: %s' % self.warp print ' Timer: %s' % self.timer print if self.machine_details: print_machine_details(self.machine_details, indent=' ') print def print_benchmark(self, hidenoise=0, limitnames=None): print ('Test ' ' minimum average operation overhead') print '-' * LINE tests = self.tests.items() tests.sort() total_min_time = 0.0 total_avg_time = 0.0 for name, test in tests: if (limitnames is not None and limitnames.search(name) is None): continue (min_time, avg_time, total_time, op_avg, min_overhead) = test.stat() total_min_time = total_min_time + min_time total_avg_time = total_avg_time + avg_time print '%30s: %5.0fms %5.0fms %6.2fus %7.3fms' % \ (name, min_time * MILLI_SECONDS, avg_time * MILLI_SECONDS, op_avg * MICRO_SECONDS, min_overhead *MILLI_SECONDS) print '-' * LINE print ('Totals: ' ' %6.0fms %6.0fms' % (total_min_time * MILLI_SECONDS, total_avg_time * MILLI_SECONDS, )) print def print_comparison(self, compare_to, hidenoise=0, limitnames=None): # Check benchmark versions if compare_to.version != self.version: print ('* Benchmark versions differ: ' 'cannot compare this benchmark to "%s" !' % compare_to.name) print self.print_benchmark(hidenoise=hidenoise, limitnames=limitnames) return # Print header compare_to.print_header('Comparing with') print ('Test ' ' minimum run-time average run-time') print (' ' ' this other diff this other diff') print '-' * LINE # Print test comparisons tests = self.tests.items() tests.sort() total_min_time = other_total_min_time = 0.0 total_avg_time = other_total_avg_time = 0.0 benchmarks_compatible = self.compatible(compare_to) tests_compatible = 1 for name, test in tests: if (limitnames is not None and limitnames.search(name) is None): continue (min_time, avg_time, total_time, op_avg, min_overhead) = test.stat() total_min_time = total_min_time + min_time total_avg_time = total_avg_time + avg_time try: other = compare_to.tests[name] except KeyError: other = None if other is None: # Other benchmark doesn't include the given test min_diff, avg_diff = 'n/a', 'n/a' other_min_time = 0.0 other_avg_time = 0.0 tests_compatible = 0 else: (other_min_time, other_avg_time, other_total_time, other_op_avg, other_min_overhead) = other.stat() other_total_min_time = other_total_min_time + other_min_time other_total_avg_time = other_total_avg_time + other_avg_time if (benchmarks_compatible and test.compatible(other)): # Both benchmark and tests are comparible min_diff = ((min_time * self.warp) / (other_min_time * other.warp) - 1.0) avg_diff = ((avg_time * self.warp) / (other_avg_time * other.warp) - 1.0) if hidenoise and abs(min_diff) < 10.0: min_diff = '' else: min_diff = '%+5.1f%%' % (min_diff * PERCENT) if hidenoise and abs(avg_diff) < 10.0: avg_diff = '' else: avg_diff = '%+5.1f%%' % (avg_diff * PERCENT) else: # Benchmark or tests are not comparible min_diff, avg_diff = 'n/a', 'n/a' tests_compatible = 0 print '%30s: %5.0fms %5.0fms %7s %5.0fms %5.0fms %7s' % \ (name, min_time * MILLI_SECONDS, other_min_time * MILLI_SECONDS * compare_to.warp / self.warp, min_diff, avg_time * MILLI_SECONDS, other_avg_time * MILLI_SECONDS * compare_to.warp / self.warp, avg_diff) print '-' * LINE # Summarise test results if not benchmarks_compatible or not tests_compatible: min_diff, avg_diff = 'n/a', 'n/a' else: if other_total_min_time != 0.0: min_diff = '%+5.1f%%' % ( ((total_min_time * self.warp) / (other_total_min_time * compare_to.warp) - 1.0) * PERCENT) else: min_diff = 'n/a' if other_total_avg_time != 0.0: avg_diff = '%+5.1f%%' % ( ((total_avg_time * self.warp) / (other_total_avg_time * compare_to.warp) - 1.0) * PERCENT) else: avg_diff = 'n/a' print ('Totals: ' ' %5.0fms %5.0fms %7s %5.0fms %5.0fms %7s' % (total_min_time * MILLI_SECONDS, (other_total_min_time * compare_to.warp/self.warp * MILLI_SECONDS), min_diff, total_avg_time * MILLI_SECONDS, (other_total_avg_time * compare_to.warp/self.warp * MILLI_SECONDS), avg_diff )) print print '(this=%s, other=%s)' % (self.name, compare_to.name) print class PyBenchCmdline(Application): header = ("PYBENCH - a benchmark test suite for Python " "interpreters/compilers.") version = __version__ debug = _debug options = [ArgumentOption('-n', 'number of rounds', Setup.Number_of_rounds), ArgumentOption('-f', 'save benchmark to file arg', ''), ArgumentOption('-c', 'compare benchmark with the one in file arg', ''), ArgumentOption('-s', 'show benchmark in file arg, then exit', ''), ArgumentOption('-w', 'set warp factor to arg', Setup.Warp_factor), ArgumentOption('-t', 'run only tests with names matching arg', ''), ArgumentOption('-C', 'set the number of calibration runs to arg', CALIBRATION_RUNS), SwitchOption('-d', 'hide noise in comparisons', 0), SwitchOption('-v', 'verbose output (not recommended)', 0), SwitchOption('--with-gc', 'enable garbage collection', 0), SwitchOption('--with-syscheck', 'use default sys check interval', 0), ArgumentOption('--timer', 'use given timer', TIMER_PLATFORM_DEFAULT), ] about = """\ The normal operation is to run the suite and display the results. Use -f to save them for later reuse or comparisons. Available timers: time.time time.clock systimes.processtime Examples: python2.1 pybench.py -f p21.pybench python2.5 pybench.py -f p25.pybench python pybench.py -s p25.pybench -c p21.pybench """ copyright = __copyright__ def main(self): rounds = self.values['-n'] reportfile = self.values['-f'] show_bench = self.values['-s'] compare_to = self.values['-c'] hidenoise = self.values['-d'] warp = int(self.values['-w']) withgc = self.values['--with-gc'] limitnames = self.values['-t'] if limitnames: if _debug: print '* limiting test names to one with substring "%s"' % \ limitnames limitnames = re.compile(limitnames, re.I) else: limitnames = None verbose = self.verbose withsyscheck = self.values['--with-syscheck'] calibration_runs = self.values['-C'] timer = self.values['--timer'] print '-' * LINE print 'PYBENCH %s' % __version__ print '-' * LINE print '* using Python %s' % (string.split(sys.version)[0]) # Switch off garbage collection if not withgc: try: import gc except ImportError: print '* Python version doesn\'t support garbage collection' else: gc.disable() print '* disabled garbage collection' # "Disable" sys check interval if not withsyscheck: # Too bad the check interval uses an int instead of a long... value = 2147483647 sys.setcheckinterval(value) print '* system check interval set to maximum: %s' % value if timer == TIMER_SYSTIMES_PROCESSTIME: import systimes print '* using timer: systimes.processtime (%s)' % \ systimes.SYSTIMES_IMPLEMENTATION else: print '* using timer: %s' % timer print if compare_to: try: f = open(compare_to,'rb') bench = pickle.load(f) bench.name = compare_to f.close() compare_to = bench except IOError, reason: print '* Error opening/reading file %s: %s' % ( repr(compare_to), reason) compare_to = None if show_bench: try: f = open(show_bench,'rb') bench = pickle.load(f) bench.name = show_bench f.close() bench.print_header() if compare_to: bench.print_comparison(compare_to, hidenoise=hidenoise, limitnames=limitnames) else: bench.print_benchmark(hidenoise=hidenoise, limitnames=limitnames) except IOError, reason: print '* Error opening/reading file %s: %s' % ( repr(show_bench), reason) print return if reportfile: print 'Creating benchmark: %s (rounds=%i, warp=%i)' % \ (reportfile, rounds, warp) print # Create benchmark object bench = Benchmark(reportfile, verbose=verbose, timer=timer, warp=warp, calibration_runs=calibration_runs) bench.rounds = rounds bench.load_tests(Setup, limitnames=limitnames) try: bench.calibrate() bench.run() except KeyboardInterrupt: print print '*** KeyboardInterrupt -- Aborting' print return bench.print_header() if compare_to: bench.print_comparison(compare_to, hidenoise=hidenoise, limitnames=limitnames) else: bench.print_benchmark(hidenoise=hidenoise, limitnames=limitnames) # Ring bell sys.stderr.write('\007') if reportfile: try: f = open(reportfile,'wb') bench.name = reportfile pickle.dump(bench,f) f.close() except IOError, reason: print '* Error opening/writing reportfile' except IOError, reason: print '* Error opening/writing reportfile %s: %s' % ( reportfile, reason) print if __name__ == '__main__': PyBenchCmdline()