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396 lines
14 KiB
Python
Executable File
396 lines
14 KiB
Python
Executable File
#!/usr/bin/python3
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# Plot GNU C Library string microbenchmark output.
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# Copyright (C) 2019-2020 Free Software Foundation, Inc.
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# This file is part of the GNU C Library.
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#
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# The GNU C Library is free software; you can redistribute it and/or
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# modify it under the terms of the GNU Lesser General Public
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# License as published by the Free Software Foundation; either
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# version 2.1 of the License, or (at your option) any later version.
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#
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# The GNU C Library is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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# Lesser General Public License for more details.
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#
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# You should have received a copy of the GNU Lesser General Public
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# License along with the GNU C Library; if not, see
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# <https://www.gnu.org/licenses/>.
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"""Plot string microbenchmark results.
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Given a benchmark results file in JSON format and a benchmark schema file,
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plot the benchmark timings in one of the available representations.
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Separate figure is generated and saved to a file for each 'results' array
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found in the benchmark results file. Output filenames and plot titles
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are derived from the metadata found in the benchmark results file.
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"""
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import argparse
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from collections import defaultdict
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import json
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import matplotlib as mpl
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import numpy as np
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import os
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try:
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import jsonschema as validator
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except ImportError:
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print("Could not find jsonschema module.")
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raise
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# Use pre-selected markers for plotting lines to improve readability
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markers = [".", "x", "^", "+", "*", "v", "1", ">", "s"]
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# Benchmark variants for which the x-axis scale should be logarithmic
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log_variants = {"powers of 2"}
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def gmean(numbers):
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"""Compute geometric mean.
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Args:
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numbers: 2-D list of numbers
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Return:
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numpy array with geometric means of numbers along each column
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"""
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a = np.array(numbers, dtype=np.complex)
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means = a.prod(0) ** (1.0 / len(a))
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return np.real(means)
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def relativeDifference(x, x_reference):
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"""Compute per-element relative difference between each row of
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a matrix and an array of reference values.
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Args:
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x: numpy matrix of shape (n, m)
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x_reference: numpy array of size m
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Return:
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relative difference between rows of x and x_reference (in %)
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"""
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abs_diff = np.subtract(x, x_reference)
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return np.divide(np.multiply(abs_diff, 100.0), x_reference)
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def plotTime(timings, routine, bench_variant, title, outpath):
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"""Plot absolute timing values.
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Args:
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timings: timings to plot
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routine: benchmarked string routine name
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bench_variant: top-level benchmark variant name
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title: figure title (generated so far)
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outpath: output file path (generated so far)
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Return:
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y: y-axis values to plot
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title_final: final figure title
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outpath_final: file output file path
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"""
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y = timings
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plt.figure()
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if not args.values:
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plt.axes().yaxis.set_major_formatter(plt.NullFormatter())
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plt.ylabel("timing")
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title_final = "%s %s benchmark timings\n%s" % \
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(routine, bench_variant, title)
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outpath_final = os.path.join(args.outdir, "%s_%s_%s%s" % \
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(routine, args.plot, bench_variant, outpath))
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return y, title_final, outpath_final
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def plotRelative(timings, all_timings, routine, ifuncs, bench_variant,
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title, outpath):
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"""Plot timing values relative to a chosen ifunc
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Args:
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timings: timings to plot
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all_timings: all collected timings
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routine: benchmarked string routine name
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ifuncs: names of ifuncs tested
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bench_variant: top-level benchmark variant name
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title: figure title (generated so far)
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outpath: output file path (generated so far)
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Return:
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y: y-axis values to plot
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title_final: final figure title
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outpath_final: file output file path
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"""
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# Choose the baseline ifunc
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if args.baseline:
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baseline = args.baseline.replace("__", "")
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else:
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baseline = ifuncs[0]
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baseline_index = ifuncs.index(baseline)
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# Compare timings against the baseline
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y = relativeDifference(timings, all_timings[baseline_index])
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plt.figure()
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plt.axhspan(-args.threshold, args.threshold, color="lightgray", alpha=0.3)
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plt.axhline(0, color="k", linestyle="--", linewidth=0.4)
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plt.ylabel("relative timing (in %)")
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title_final = "Timing comparison against %s\nfor %s benchmark, %s" % \
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(baseline, bench_variant, title)
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outpath_final = os.path.join(args.outdir, "%s_%s_%s%s" % \
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(baseline, args.plot, bench_variant, outpath))
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return y, title_final, outpath_final
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def plotMax(timings, routine, bench_variant, title, outpath):
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"""Plot results as percentage of the maximum ifunc performance.
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The optimal ifunc is computed on a per-parameter-value basis.
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Performance is computed as 1/timing.
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Args:
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timings: timings to plot
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routine: benchmarked string routine name
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bench_variant: top-level benchmark variant name
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title: figure title (generated so far)
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outpath: output file path (generated so far)
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Return:
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y: y-axis values to plot
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title_final: final figure title
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outpath_final: file output file path
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"""
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perf = np.reciprocal(timings)
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max_perf = np.max(perf, axis=0)
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y = np.add(100.0, relativeDifference(perf, max_perf))
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plt.figure()
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plt.axhline(100.0, color="k", linestyle="--", linewidth=0.4)
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plt.ylabel("1/timing relative to max (in %)")
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title_final = "Performance comparison against max for %s\n%s " \
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"benchmark, %s" % (routine, bench_variant, title)
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outpath_final = os.path.join(args.outdir, "%s_%s_%s%s" % \
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(routine, args.plot, bench_variant, outpath))
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return y, title_final, outpath_final
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def plotThroughput(timings, params, routine, bench_variant, title, outpath):
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"""Plot throughput.
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Throughput is computed as the varied parameter value over timing.
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Args:
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timings: timings to plot
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params: varied parameter values
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routine: benchmarked string routine name
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bench_variant: top-level benchmark variant name
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title: figure title (generated so far)
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outpath: output file path (generated so far)
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Return:
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y: y-axis values to plot
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title_final: final figure title
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outpath_final: file output file path
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"""
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y = np.divide(params, timings)
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plt.figure()
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if not args.values:
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plt.axes().yaxis.set_major_formatter(plt.NullFormatter())
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plt.ylabel("%s / timing" % args.key)
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title_final = "%s %s benchmark throughput results\n%s" % \
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(routine, bench_variant, title)
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outpath_final = os.path.join(args.outdir, "%s_%s_%s%s" % \
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(routine, args.plot, bench_variant, outpath))
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return y, title_final, outpath_final
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def finishPlot(x, y, title, outpath, x_scale, plotted_ifuncs):
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"""Finish generating current Figure.
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Args:
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x: x-axis values
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y: y-axis values
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title: figure title
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outpath: output file path
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x_scale: x-axis scale
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plotted_ifuncs: names of ifuncs to plot
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"""
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plt.xlabel(args.key)
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plt.xscale(x_scale)
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plt.title(title)
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plt.grid(color="k", linestyle=args.grid, linewidth=0.5, alpha=0.5)
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for i in range(len(plotted_ifuncs)):
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plt.plot(x, y[i], marker=markers[i % len(markers)],
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label=plotted_ifuncs[i])
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plt.legend(loc="best", fontsize="small")
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plt.savefig("%s_%s.%s" % (outpath, x_scale, args.extension),
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format=args.extension, dpi=args.resolution)
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if args.display:
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plt.show()
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plt.close()
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def plotRecursive(json_iter, routine, ifuncs, bench_variant, title, outpath,
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x_scale):
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"""Plot benchmark timings.
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Args:
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json_iter: reference to json object
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routine: benchmarked string routine name
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ifuncs: names of ifuncs tested
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bench_variant: top-level benchmark variant name
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title: figure's title (generated so far)
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outpath: output file path (generated so far)
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x_scale: x-axis scale
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"""
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# RECURSIVE CASE: 'variants' array found
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if "variants" in json_iter:
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# Continue recursive search for 'results' array. Record the
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# benchmark variant (configuration) in order to customize
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# the title, filename and X-axis scale for the generated figure.
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for variant in json_iter["variants"]:
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new_title = "%s%s, " % (title, variant["name"])
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new_outpath = "%s_%s" % (outpath, variant["name"].replace(" ", "_"))
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new_x_scale = "log" if variant["name"] in log_variants else x_scale
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plotRecursive(variant, routine, ifuncs, bench_variant, new_title,
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new_outpath, new_x_scale)
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return
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# BASE CASE: 'results' array found
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domain = []
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timings = defaultdict(list)
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# Collect timings
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for result in json_iter["results"]:
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domain.append(result[args.key])
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timings[result[args.key]].append(result["timings"])
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domain = np.unique(np.array(domain))
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averages = []
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# Compute geometric mean if there are multple timings for each
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# parameter value.
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for parameter in domain:
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averages.append(gmean(timings[parameter]))
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averages = np.array(averages).transpose()
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# Choose ifuncs to plot
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if isinstance(args.ifuncs, str):
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plotted_ifuncs = ifuncs
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else:
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plotted_ifuncs = [x.replace("__", "") for x in args.ifuncs]
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plotted_indices = [ifuncs.index(x) for x in plotted_ifuncs]
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plotted_vals = averages[plotted_indices,:]
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# Plotting logic specific to each plot type
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if args.plot == "time":
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codomain, title, outpath = plotTime(plotted_vals, routine,
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bench_variant, title, outpath)
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elif args.plot == "rel":
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codomain, title, outpath = plotRelative(plotted_vals, averages, routine,
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ifuncs, bench_variant, title, outpath)
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elif args.plot == "max":
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codomain, title, outpath = plotMax(plotted_vals, routine,
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bench_variant, title, outpath)
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elif args.plot == "thru":
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codomain, title, outpath = plotThroughput(plotted_vals, domain, routine,
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bench_variant, title, outpath)
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# Plotting logic shared between plot types
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finishPlot(domain, codomain, title, outpath, x_scale, plotted_ifuncs)
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def main(args):
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"""Program Entry Point.
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Args:
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args: command line arguments (excluding program name)
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"""
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# Select non-GUI matplotlib backend if interactive display is disabled
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if not args.display:
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mpl.use("Agg")
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global plt
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import matplotlib.pyplot as plt
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schema = None
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with open(args.schema, "r") as f:
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schema = json.load(f)
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for filename in args.bench:
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bench = None
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with open(filename, "r") as f:
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bench = json.load(f)
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validator.validate(bench, schema)
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for function in bench["functions"]:
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bench_variant = bench["functions"][function]["bench-variant"]
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ifuncs = bench["functions"][function]["ifuncs"]
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ifuncs = [x.replace("__", "") for x in ifuncs]
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plotRecursive(bench["functions"][function], function, ifuncs,
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bench_variant, "", "", args.logarithmic)
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""" main() """
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if __name__ == "__main__":
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parser = argparse.ArgumentParser(description=
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"Plot string microbenchmark results",
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formatter_class=argparse.ArgumentDefaultsHelpFormatter)
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# Required parameter
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parser.add_argument("bench", nargs="+",
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help="benchmark results file(s) in json format")
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# Optional parameters
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parser.add_argument("-b", "--baseline", type=str,
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help="baseline ifunc for 'rel' plot")
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parser.add_argument("-d", "--display", action="store_true",
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help="display figures")
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parser.add_argument("-e", "--extension", type=str, default="png",
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choices=["png", "pdf", "svg"],
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help="output file(s) extension")
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parser.add_argument("-g", "--grid", action="store_const", default="",
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const="-", help="show grid lines")
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parser.add_argument("-i", "--ifuncs", nargs="+", default="all",
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help="ifuncs to plot")
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parser.add_argument("-k", "--key", type=str, default="length",
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help="key to access the varied parameter")
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parser.add_argument("-l", "--logarithmic", action="store_const",
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default="linear", const="log",
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help="use logarithmic x-axis scale")
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parser.add_argument("-o", "--outdir", type=str, default=os.getcwd(),
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help="output directory")
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parser.add_argument("-p", "--plot", type=str, default="time",
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choices=["time", "rel", "max", "thru"],
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help="plot absolute timings, relative timings, " \
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"performance relative to max, or throughput")
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parser.add_argument("-r", "--resolution", type=int, default=100,
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help="dpi resolution for the generated figures")
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parser.add_argument("-s", "--schema", type=str,
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default=os.path.join(os.path.dirname(
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os.path.realpath(__file__)),
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"benchout_strings.schema.json"),
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help="schema file to validate the results file.")
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parser.add_argument("-t", "--threshold", type=int, default=5,
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help="threshold to mark in 'rel' graph (in %%)")
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parser.add_argument("-v", "--values", action="store_true",
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help="show actual values")
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args = parser.parse_args()
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main(args)
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