I'm using bits of Perry Cook's Synthesis Toolkit (STK) to generate saw and square waves. STK includes this BLIT-based sawtooth oscillator:

```
inline STKFloat BlitSaw::tick( void ) {
StkFloat tmp, denominator = sin( phase_ );
if ( fabs(denominator) <= std::numeric_limits<StkFloat>::epsilon() )
tmp = a_;
else {
tmp = sin( m_ * phase_ );
tmp /= p_ * denominator;
}
tmp += state_ - C2_;
state_ = tmp * 0.995;
phase_ += rate_;
if ( phase_ >= PI )
phase_ -= PI;
lastFrame_[0] = tmp;
return lastFrame_[0];
}
```

The square wave oscillator is broadly similar. At the top, there's this comment:

```
// A fully optimized version of this code would replace the two sin
// calls with a pair of fast sin oscillators, for which stable fast
// two-multiply algorithms are well known.
```

I don't know where to start looking for these "fast two-multiply algorithms" and I'd appreciate some pointers. I could use a lookup table instead, but I'm keen to learn what these 'fast sin oscillators' are. I could also use an abbreviated Taylor series, but thats way more than two multiplies. Searching hasn't turned up anything much, although I did find this approximation:

```
#define AD_SIN(n) (n*(2.f- fabs(n)))
```

Plotting it out shows that it's not really a close approximation outside the range of -1 to 1, so I don't think I can use it when `phase_`

is in the range -pi to pi:

Here, Sine is the blue line and the purple line is the approximation.

Profiling my code reveals that the calls to `sin()`

are far and away the most time-consuming calls, so I really would like to optimise this piece.

Thanks

**EDIT** Thanks for the detailed and varied answers. I will explore these and accept one at the weekend.

**EDIT 2** Would the anonymous close voter please kindly explain their vote in the comments? Thank you.