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/*
* $RCSfile$
*
* Copyright (c) 2005 Sun Microsystems, Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* - Redistribution of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* - Redistribution in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
*
* Neither the name of Sun Microsystems, Inc. or the names of
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* This software is provided "AS IS," without a warranty of any
* kind. ALL EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND
* WARRANTIES, INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY
* EXCLUDED. SUN MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL
* NOT BE LIABLE FOR ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF
* USING, MODIFYING OR DISTRIBUTING THIS SOFTWARE OR ITS
* DERIVATIVES. IN NO EVENT WILL SUN OR ITS LICENSORS BE LIABLE FOR
* ANY LOST REVENUE, PROFIT OR DATA, OR FOR DIRECT, INDIRECT, SPECIAL,
* CONSEQUENTIAL, INCIDENTAL OR PUNITIVE DAMAGES, HOWEVER CAUSED AND
* REGARDLESS OF THE THEORY OF LIABILITY, ARISING OUT OF THE USE OF OR
* INABILITY TO USE THIS SOFTWARE, EVEN IF SUN HAS BEEN ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGES.
*
* You acknowledge that this software is not designed, licensed or
* intended for use in the design, construction, operation or
* maintenance of any nuclear facility.
*
* $Revision$
* $Date$
* $State$
*/
import javax.media.j3d.*;
import javax.vecmath.*;
import java.text.*;
/** This behavior calculates the frame rate and average frame rate of a
* Java3D application.
* The behavior sets itself up to wakeup every time a new frame is rendered.
*
* <p> The HotSpot(tm) compiler performs some initial optimizations before
* running at optimal speed. Frame rates measured during this warmup period
* will be inaccurate and not indicative of the true performance of the the
* application. Therefore, before beginning the frame rate computation,
* the frame counter waits for a fixed time period to allow the HotSpot(tm)
* compiler to stablilize.
*
* <p> To avoid computing the frame rate too frequently (which would also
* hamper rendering performance), the frame counter only computes the frame
* rate at fixed time intervals. The default sampling duration is 10 seconds.
* After waiting for the warmup period, the frame counter needs to calibrate
* itself. It computes the number of frames rendered during the sampling
* period. After doing this calibration, the frame counter reports the frame
* rate after these many frames are rendered. It also reports the average
* frame rate after a fixed number of sampling intervals (the default is 5).
*
* <p>The frame counter can be set up to run for a fixed number of sampling
* intervals or to run indefinitely. The defaultis to run indefinitely.
*/
public class FPSCounter extends Behavior {
// Wakeup condition - framecount = 0 -> wakeup on every frame
WakeupOnElapsedFrames FPSwakeup = new WakeupOnElapsedFrames(0);
// Do calibration for these many millisec
private static final long testduration = 1000;
// Report frame rate after every sampleduration milliseconds
private static final long sampleduration = 10000;
// Flag to indicate that it is time to (re)calibrate
private boolean doCalibration = true;
// Flag to indicate the counter has started
private boolean startup = true;
// Wait for HotSpot compiler to perform optimizations
private boolean warmup = true;
// Time to wait for HotSpot compiler to stabilize (in milliseconds)
private long warmupTime = 20000;
// Counter for number of frames rendered
private int numframes = 0;
// Report frame rate after maxframe number of frames have been rendered
private int maxframes = 1;
// Variables to keep track of elapsed time
private long startuptime = 0;
private long currtime = 0;
private long lasttime = 0;
private long deltatime;
// Run indefinitely or for a fixed duration
private boolean finiteLoop = false;
// No. of sampling intervals to run for if not running indefinitely
private long maxLoops;
// No. of sampling intervals run for so far
private long numLoops = 0;
// Total number of frames rendered so far
private int sumFrames = 0;
// Total time since last reporting of average frame rate
private long sumTimes = 0;
// Counts no. of sampling intervals
private int loop = 0;
// Average frame rate is reported after loopCount number of
// sampling intervals
private int loopCount = 5;
private double sumFps = 0.0;
private String symbol[] = {"\\", "|", "|", "/", "-", "|", "-"};
int index = 0;
private NumberFormat nf = null;
public FPSCounter() {
setEnable(true);
nf = NumberFormat.getNumberInstance();
}
/**
* Called to init the behavior
*/
public void initialize() {
// Set the trigger for the behavior to wakeup on every frame rendered
wakeupOn(FPSwakeup);
}
/**
* Called every time the behavior is activated
*/
public void processStimulus(java.util.Enumeration critera) {
// Apply calibration algorithm to determine number of frames to
// wait before computing frames per second.
// sampleduration = 10000 -> to run test, pass for 10 seconds.
if (doCalibration) { // start calibration
if (startup) {
// Record time at which the behavior was first invoked
startuptime = System.currentTimeMillis();
startup = false;
}
else if(warmup) { // Wait for the system to stabilize.
System.out.print("\rFPSCounter warming up..." +
symbol[(index++)%symbol.length]);
currtime = System.currentTimeMillis();
deltatime = currtime - startuptime;
if(deltatime > warmupTime) {
// Done waiting for warmup
warmup = false;
lasttime = System.currentTimeMillis();
System.out.println("\rFPSCounter warming up...Done");
}
}
else {
numframes += 1;
// Wait till at least maxframe no. of frames have been rendered
if (numframes >= maxframes) {
currtime = System.currentTimeMillis();
deltatime = currtime - lasttime;
// Do the calibration for testduration no. of millisecs
if (deltatime > testduration) {
// Compute total no. of frames rendered so far in the
// current sampling duration
maxframes = (int)Math.ceil((double)numframes *
((double)sampleduration /
(double)deltatime));
// Done with calibration
doCalibration = false;
// reset the value for the measurement
numframes = 0;
lasttime = System.currentTimeMillis();
}
else {
// Need to run the calibration routine for some more
// time. Increase the no. of frames to be rendered
maxframes *= 2;
}
}
}
}
else { // do the measurement
numframes += 1;
if (numframes >= maxframes) {
currtime = System.currentTimeMillis();
deltatime = currtime - lasttime;
// time is in millisec, so multiply by 1000 to get frames/sec
double fps = (double)numframes / ((double)deltatime / 1000.0);
System.out.println("Frame Rate : \n\tNo. of frames : " +
numframes + "\n\tTime : " +
((double)deltatime / 1000.0) +
" sec." + "\n\tFrames/sec : " + nf.format(fps));
// Calculate average frame rate
sumFrames += numframes;
sumTimes += deltatime;
sumFps += fps;
loop++;
if (loop >= loopCount) {
double avgFps = (double)sumFrames*1000.0/(double)sumTimes;
double ravgFps = sumFps/(double)loopCount;
System.out.println("Aggregate frame rate " +
nf.format(avgFps) + " frames/sec");
System.out.println("Average frame rate " +
nf.format(ravgFps) + " frames/sec");
numLoops++;
if (finiteLoop && numLoops >= maxLoops) {
System.out.println("************** The End **************\n");
setEnable(false);
}
loop = 0;
sumFps = 0;
}
numframes = 0;
lasttime = System.currentTimeMillis();;
}
}
// Set the trigger for the behavior
wakeupOn(FPSwakeup);
}
/**
* The frame counter waits for some time before computing the
* frame rate. This allows the HotSpot compiler to perform
* initial optimizations. The amount of time to wait for is set
* by this method. The default is 20000 (20 sec)
*
* @param amount of time to wait for before computing frame rate
* (specified in milliseconds)
*/
public void setWarmupTime(long wt) {
warmupTime = wt;
}
/**
* Sets the number of sampling intervals to wait for before computing
* the average frame rate.
* The default is 5.
*
* @param number of sampling intervals over which to compute frame rate.
* A value of 0 implies the average frame rate is computed over one
* sampling interval
*/
public void setLoopCount(int lc) {
loopCount = lc;
}
/**
* This method sets the number of sampling intervals for which
* the frame counter should run.
*
* @param number of sampling intervals to run for
*/
public void setMaxLoops(int ml) {
maxLoops = ml;
finiteLoop = true;
}
}
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