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Only the Java Core part of Javolution library, with slight modifications for use in MSFTBX.

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/*
 * Javolution - Java(TM) Solution for Real-Time and Embedded Systems
 * Copyright (C) 2012 - Javolution (http://javolution.org/)
 * All rights reserved.
 * 
 * Permission to use, copy, modify, and distribute this software is
 * freely granted, provided that this notice is preserved.
 */
package javolution.tools;

import javolution.context.LogContext;
import javolution.lang.Configurable;
import javolution.lang.MathLib;
import javolution.text.TextBuilder;
import javolution.util.FastTable;

/**
 * 

Utility class to measure the worst case execution time and average * execution time with high precision. Here an example measuring the * worst case execution time of {@link java.util.List#add(int, Object)} * for diverse list implementations.

* [code] * Perfometer> insertPerf = new Perfometer<>("java.util.List#add(int, Object)") { * List list; * Random random; * protected void initialize() throws Exception { * list = getInput().newInstance(); * random = new Random(-1); // Use seed to ensure same execution path. * } * protected void run(boolean measure) { * Object obj = new Object(); * int i = random.nextInt(list.size() + 1); * if (measure) list.add(i, obj); * } * protected void validate() { // Optional. * assert list.size() == getNbrOfIterations(); * } * } * ... * public void testExecutionTime() { * insertPerf.measure(java.util.ArrayList.class, 10000).print(); * insertPerf.measure(java.util.LinkedList.class, 10000).print(); * insertPerf.measure(javolution.util.FastTable.class, 10000).print(); * } * ... * > [INFO] java.util.List#add(int, Object) (10000) for java.util.ArrayList: 590.21450 ns (avg), 8443.0000 ns (wcet#9369) * > [INFO] java.util.List#add(int, Object) (10000) for java.util.LinkedList: 4849.8313 ns (avg), 26536.000 ns (wcet#9863) * > [INFO] java.util.List#add(int, Object) (10000) for javolution.util.FastTable: 217.26300 ns (avg), 534.00000 ns (wcet#8864) * [/code] * * @param the perfometer input type. */ public abstract class Perfometer { /** * Hold the measurement duration in milliseconds (default 1000 ms). */ public static final Configurable DURATION_MS = new Configurable() { @Override public String getName() { // Requires since there are multiple configurable fields. return this.getClass().getEnclosingClass().getName() + "#DURATION_MS"; } @Override protected Integer getDefault() { return 1000; } }; /** * Indicates if perfometer measurements should be skipped ( * e.g. {@code -Djavolution.test.Perfometer#SKIP=true} to skip * performance measurements). * When skipped, {@link #measure} and {@link #print} don't do anything. */ public static final Configurable SKIP = new Configurable() { @Override public String getName() { // Requires since there are multiple configurable fields. return this.getClass().getEnclosingClass().getName() + "#SKIP"; } @Override protected Boolean getDefault() { return false; } }; private final String description; private T input; private long[] times; // Nano-Seconds. /** * Creates a perfometer having the specified description. * * @param description the description of the code being measured. */ public Perfometer(String description) { this.description = description; } /** * Returns the average execution time in seconds. */ public double getAvgTimeInSeconds() { if (times == null) return Double.NaN; long sum = 0; for (long time : times) { sum += time; } return sum / 1e9 / times.length; } /** * Returns this perfometer description. */ public String getDescription() { return description; } /** * Returns this perfometer current inputs. */ public T getInput() { return input; } /** * Returns this perfometer current number of iterations performed. */ public int getNbrOfIterations() { return (times != null) ? times.length : 0; } /** * Returns the execution times in seconds. */ public double[] getTimesInSeconds() { if (times == null) return new double[0]; double[] timesSec = new double[times.length]; for (int i=0; i < times.length; i++) { timesSec[i] = times[i] / 1e9; } return timesSec; } /** * Measures the execution time with high precision (single iteration). * * @param input the test input. */ public Perfometer measure(T input) { return measure(input, 1); } /** * Measures the worst case execution time and average execution time. * * @param input the test input. * @param nbrOfIterations the number of iterations performed on which * the average will be calculated. */ public Perfometer measure(T input, int nbrOfIterations) { if (SKIP.get()) return this; // Skip. this.input = input; this.times = new long[nbrOfIterations]; long[] calibrations = longArray(nbrOfIterations, Long.MAX_VALUE); long[] measures = longArray(nbrOfIterations, Long.MAX_VALUE); try { long exitTime = System.currentTimeMillis() + DURATION_MS.get(); do { // Calibration. initialize(); for (int i = 0; i < nbrOfIterations; i++) { long start = System.nanoTime(); run(false); long time = System.nanoTime() - start; calibrations[i] = MathLib.min(calibrations[i], time); } // Measurement. initialize(); for (int i = 0; i < nbrOfIterations; i++) { long start = System.nanoTime(); run(true); long time = System.nanoTime() - start; measures[i] = MathLib.min(measures[i], time); } } while (System.currentTimeMillis() < exitTime); for (int i = 0; i < nbrOfIterations; i++) { times[i] = measures[i] - calibrations[i]; } return this; } catch (Exception error) { throw new RuntimeException("Perfometer Exception", error); } } /** * Outputs the result. */ public void print() { if (Perfometer.SKIP.get()) return; TextBuilder txt = new TextBuilder(); txt.append(description).append(" (").append(getNbrOfIterations()) .append(") for ").append(input).append(": "); while (txt.length() < 80) txt.append(' '); txt.append(getAvgTimeInSeconds() * 1E9, 8, false, true); // Nano-Seconds. txt.append(" ns (avg), "); txt.append(getWCETinSeconds() * 1E9, 8, false, true); // Nano-Seconds. txt.append(" ns (wcet#").append(getWorstCaseNumber()).append(")"); LogContext.info(txt); } /** * Outputs the measurements in nanoseconds. */ public void printDetails() { if (Perfometer.SKIP.get()) return; FastTable measurements = new FastTable(); for (long time : times) measurements.add(time); LogContext.debug(measurements); } /** * Returns the worst case execution time in seconds. */ public double getWCETinSeconds() { if (times == null) return Double.NaN; long wcet = 0; for (long time : times) { if (time > wcet) wcet = time; } return wcet / 1e9; } /** * Returns the iteration number having the slowest execution time. */ public int getWorstCaseNumber() { if (times == null) return -1; long wcet = 0; int j = -1; for (int i=0; i < times.length; i++) { if (times[i] > wcet) { wcet = times[i]; j = i; } } return j; } /** * Performs the initialization. */ protected abstract void initialize() throws Exception; /** * Runs the code being benchmarked. * * @param measure {@code false} when calibration is performed; * {@code true} otherwise. */ protected abstract void run(boolean measure) throws Exception; /** * Validates the final result (after all iterations are completed). */ protected void validate() {} private long[] longArray(int length, long initialValue) { long[] array = new long[length]; for (int i = 0; i < length; i++) array[i] = initialValue; return array; } }