I am working on a live wallpaper (my first actually :)), and I seem to have a reached an impasse:

If you haven't guessed it by the variable names and the code, the live wallpaper in question is a clock. Its components must follow a very strict degrees/time ratio (in total there will be over a dozen bitmaps rotating at different rates, in different directions (some following the same ratios/rules)).

Anyways... As it stands, every additional bitmap that is added pretty much doubles the length of execution of drawFrame(). If I was going to stop at 3 moving parts, it wouldn't be so bad, it looks OK as is; but increase the amount of bitmaps by 9 (or even 2 or 3 more) and the frame rate becomes unacceptable.

I am not re-decoding bitmaps every turn as is recommended...

What should I do to remedy this situation?

I was thinking of looking into openGL surface/engine, but i saw an exchange on SO where a user was handling over 100 bitmaps at once without problem (Android drawBitmap Performance For Lots of Bitmaps?), which got me hoping I could do the same.

I also included an appropriate version of each image in the respective drawable -_dpi folders. The images are not particularly large, file size is fairly small as there are very colors and lots of transparent portions (largest is = screen size, smallest = 90%widthscreen/50% height of screen -- so for xhdpi 720 1280 biggest and 565*562 smallest)

So basically, according to my research, my code should be snappy... but it's not. Clearly I am wrong :), please help me get it right!

Thank you very much.

```
void drawFrame()
{
timeSinceLastRun = AnimationUtils.currentAnimationTimeMillis() - timeAtLastRun;
timeAtLastRun = AnimationUtils.currentAnimationTimeMillis();
final SurfaceHolder holder = getSurfaceHolder();
Canvas c = null;
try
{
c = holder.lockCanvas();
if (c != null)
{
c.save();
c.drawColor(0xff000000);
drawTouchPoint(c);
if(isItPhase1)
{
skipToPosition(c,0,0,false,1);
skipToPosition(c,1,1,false,2);
skipToPosition(c,2,2,true,3);
}
else
{
animateGears(c,0,0,0,0);
animateGears(c,1,1,1,1);
animateGears(c,2,2,2,2);
}
c.restore();
}
}
finally
{
if (c != null)
holder.unlockCanvasAndPost(c);
}
mHandler.removeCallbacks(mDrawPattern);
if (mVisible)
{
mHandler.postDelayed(mDrawPattern, 1000/25);
}
}
private void skipToPosition(Canvas c, int xP, int yP, boolean lastTest, int timeBasis)
{
if(isItFirstRun)
{
gears[0] = BitmapFactory.decodeResource(getResources(),
l.werner.mechanicalclocklivewallpaperversion0001.R.drawable.seconds_gear);
gears[1] = BitmapFactory.decodeResource(getResources(),
l.werner.mechanicalclocklivewallpaperversion0001.R.drawable.minutes_gear);
gears[2] = BitmapFactory.decodeResource(getResources(),
l.werner.mechanicalclocklivewallpaperversion0001.R.drawable.hours_gear);
m[0] = new Matrix();
m[1] = new Matrix();
m[2] = new Matrix();
m2[0] = new Matrix();
m2[1] = new Matrix();
m2[2] = new Matrix();
x[0] = 0;
x[1] = 0;
x[2] = 0;
y[0] = 0.006f;
y[1] = 0.0001f;
y[2] = (0.000001666666666666666666666666666666667f);
timeSinceLastRun = 0;
movementPerTurn = 0;
isItFirstRun = !isItFirstRun;
}
Calendar cal = Calendar.getInstance();
float second = cal.get(Calendar.SECOND);
float minute = cal.get(Calendar.MINUTE);
float hour = cal.get(Calendar.HOUR);
if(timeBasis == 1)
x[xP] = x[xP] + (360f*(second/60f));
else if(timeBasis == 2)
x[xP] = x[xP] + (360f*(minute/60f));
else if(timeBasis == 3)
x[xP] = x[xP] + (360f*(hour/12f));
if(lastTest)
{
isItPhase1 = !isItPhase1;
}
}
void animateGears(Canvas c, int xP, int yP, int g, int mP)
{
movementPerTurn = y[yP] * timeSinceLastRun;
x[xP] = x[xP] + movementPerTurn;
m[mP].setRotate(((float)x[xP]*1f), 0.5f*gears[g].getWidth(),0.5f*gears[g].getHeight());
m2[mP].setTranslate(c.getWidth()/2f - 0.5f*gears[g].getWidth(),
c.getHeight()/2f - 0.5f*gears[g].getHeight());
m[mP].setConcat(m2[mP], m[mP]);
c.drawBitmap(gears[g], m[mP] , null);
}
```