#!/usr/bin/python2
#
# Copyright 2015 The ANGLE Project Authors. All rights reserved.
# Use of this source code is governed by a BSD-style license that can be
# found in the LICENSE file.
#
# perf_test_runner.py:
#   Helper script for running and analyzing perftest results. Runs the
#   tests in an infinite batch, printing out the mean and coefficient of
#   variation of the population continuously.
#

import argparse
import glob
import logging
import os
import re
import subprocess
import sys

base_path = os.path.abspath(os.path.join(os.path.dirname(os.path.abspath(__file__)), '..'))

# Look for a [Rr]elease build.
TEST_SUITE_SEARCH_PATH = glob.glob('out/*elease*')
DEFAULT_METRIC = 'wall_time'
DEFAULT_EXPERIMENTS = 10

DEFAULT_TEST_SUITE = 'angle_perftests'

if sys.platform == 'win32':
    DEFAULT_TEST_NAME = 'DrawCallPerfBenchmark.Run/d3d11_null'
else:
    DEFAULT_TEST_NAME = 'DrawCallPerfBenchmark.Run/gl'

EXIT_SUCCESS = 0
EXIT_FAILURE = 1

scores = []


# Danke to http://stackoverflow.com/a/27758326
def mean(data):
    """Return the sample arithmetic mean of data."""
    n = len(data)
    if n < 1:
        raise ValueError('mean requires at least one data point')
    return float(sum(data)) / float(n)  # in Python 2 use sum(data)/float(n)


def sum_of_square_deviations(data, c):
    """Return sum of square deviations of sequence data."""
    ss = sum((float(x) - c)**2 for x in data)
    return ss


def coefficient_of_variation(data):
    """Calculates the population coefficient of variation."""
    n = len(data)
    if n < 2:
        raise ValueError('variance requires at least two data points')
    c = mean(data)
    ss = sum_of_square_deviations(data, c)
    pvar = ss / n  # the population variance
    stddev = (pvar**0.5)  # population standard deviation
    return stddev / c


def truncated_list(data, n):
    """Compute a truncated list, n is truncation size"""
    if len(data) < n * 2:
        raise ValueError('list not large enough to truncate')
    return sorted(data)[n:-n]


def truncated_mean(data, n):
    """Compute a truncated mean, n is truncation size"""
    return mean(truncated_list(data, n))


def truncated_cov(data, n):
    """Compute a truncated coefficient of variation, n is truncation size"""
    return coefficient_of_variation(truncated_list(data, n))


def main(raw_args):
    parser = argparse.ArgumentParser()
    parser.add_argument(
        '--suite',
        help='Test suite binary. Default is "%s".' % DEFAULT_TEST_SUITE,
        default=DEFAULT_TEST_SUITE)
    parser.add_argument(
        '-m',
        '--metric',
        help='Test metric. Default is "%s".' % DEFAULT_METRIC,
        default=DEFAULT_METRIC)
    parser.add_argument(
        '--experiments',
        help='Number of experiments to run. Default is %d.' % DEFAULT_EXPERIMENTS,
        default=DEFAULT_EXPERIMENTS,
        type=int)
    parser.add_argument('-v', '--verbose', help='Extra verbose logging.', action='store_true')
    parser.add_argument('test_name', help='Test to run', default=DEFAULT_TEST_NAME)
    args, extra_args = parser.parse_known_args(raw_args)

    if args.verbose:
        logging.basicConfig(level='DEBUG')

    if sys.platform == 'win32':
        args.suite += '.exe'

    # Find most recent binary
    newest_binary = None
    newest_mtime = None

    for path in TEST_SUITE_SEARCH_PATH:
        binary_path = os.path.join(base_path, path, args.suite)
        if os.path.exists(binary_path):
            binary_mtime = os.path.getmtime(binary_path)
            if (newest_binary is None) or (binary_mtime > newest_mtime):
                newest_binary = binary_path
                newest_mtime = binary_mtime

    perftests_path = newest_binary

    if perftests_path == None or not os.path.exists(perftests_path):
        print('Cannot find Release %s!' % args.test_suite)
        return EXIT_FAILURE

    print('Using test executable: %s' % perftests_path)
    print('Test name: %s' % args.test_name)

    def get_results(metric, extra_args=[]):
        run = [perftests_path, '--gtest_filter=%s' % args.test_name] + extra_args
        logging.info('running %s' % str(run))
        process = subprocess.Popen(run, stdout=subprocess.PIPE, stderr=subprocess.PIPE)
        output, err = process.communicate()

        m = re.search(r'Running (\d+) tests', output)
        if m and int(m.group(1)) > 1:
            print(output)
            raise Exception('Found more than one test result in output')

        # Results are reported in the format:
        # name_backend.metric: story= value units.
        pattern = r'\.' + metric + r':.*= ([0-9.]+)'
        logging.debug('searching for %s in output' % pattern)
        m = re.findall(pattern, output)
        if not m:
            print(output)
            raise Exception('Did not find the metric "%s" in the test output' % metric)

        return [float(value) for value in m]

    # Calibrate the number of steps
    steps = get_results("steps_to_run", ["--calibration"] + extra_args)[0]
    print("running with %d steps." % steps)

    # Loop 'args.experiments' times, running the tests.
    for experiment in range(args.experiments):
        experiment_scores = get_results(args.metric,
                                        ["--steps-per-trial", str(steps)] + extra_args)

        for score in experiment_scores:
            sys.stdout.write("%s: %.2f" % (args.metric, score))
            scores.append(score)

            if (len(scores) > 1):
                sys.stdout.write(", mean: %.2f" % mean(scores))
                sys.stdout.write(", variation: %.2f%%" %
                                 (coefficient_of_variation(scores) * 100.0))

            if (len(scores) > 7):
                truncation_n = len(scores) >> 3
                sys.stdout.write(", truncated mean: %.2f" % truncated_mean(scores, truncation_n))
                sys.stdout.write(", variation: %.2f%%" %
                                 (truncated_cov(scores, truncation_n) * 100.0))

            print("")

    return EXIT_SUCCESS


if __name__ == "__main__":
    sys.exit(main(sys.argv[1:]))