# Drawing the WaveForm effect of Siri

I have been trying to understand how to draw Siri's wave effect in iOS and came across this great repository. The final result looks like this : However I am having difficulty understanding what is going on with the code that generates the waves.I can generate a single static sine wave but this, I don't quite seem to understand.

Particularly when we calculate the value of y , why does it have to be :

```let y = scaling * maxAmplitude * normedAmplitude * sin(CGFloat(2 * M_PI) * self.frequency * (x / self.bounds.width) + self.phase) + self.bounds.height/2.0```

Source Code:

`````` //MARK : Properties

let density : CGFloat =        1
let frequency : CGFloat =      1.5
var phase :CGFloat =           0
var phaseShift:CGFloat =      -0.15
var numberOfWaves:Int =        6
var primaryLineWidth:CGFloat = 1.5
var idleAmplitude:CGFloat =    0.01
var waveColor:UIColor =        UIColor.white
var amplitude:CGFloat =        1.0 {
didSet {
amplitude = max(amplitude, self.idleAmplitude)
self.setNeedsDisplay()
}
}
``````

Method

``````  override open func draw(_ rect: CGRect) {
// Convenience function to draw the wave
func drawWave(_ index:Int, maxAmplitude:CGFloat, normedAmplitude:CGFloat) {
let path = UIBezierPath()
let mid = self.bounds.width/2.0

path.lineWidth = index == 0 ? self.primaryLineWidth : self.secondaryLineWidth

for x in Swift.stride(from:0, to:self.bounds.width + self.density, by:self.density) {
// Parabolic scaling
let scaling = -pow(1 / mid * (x - mid), 2) + 1

// The confusing part /////////////////////////////////////////
let y = scaling * maxAmplitude * normedAmplitude *
sin(CGFloat(2 * M_PI) * self.frequency * (x / self.bounds.width) + self.phase)
+ self.bounds.height/2.0

//////////////////////////////////////////////////////////////////
if x == 0 {
path.move(to: CGPoint(x:x, y:y))
} else {
}
}

path.stroke()
}

let context = UIGraphicsGetCurrentContext()
context?.setAllowsAntialiasing(true)

self.backgroundColor?.set()
context?.fill(rect)

let halfHeight = self.bounds.height / 2.0
let maxAmplitude = halfHeight - self.primaryLineWidth

for i in 0 ..< self.numberOfWaves {
let progress = 1.0 - CGFloat(i) / CGFloat(self.numberOfWaves)
let normedAmplitude = (1.5 * progress - 0.8) * self.amplitude
let multiplier = min(1.0, (progress/3.0*2.0) + (1.0/3.0))
self.waveColor.withAlphaComponent(multiplier * self.waveColor.cgColor.alpha).set()
drawWave(i, maxAmplitude: maxAmplitude, normedAmplitude: normedAmplitude)
}
self.phase += self.phaseShift
}
``````

Both the for loops seem very mathematical , I have no clue what's going on in there. Thanks in advance.

• I'm not sure what the question is here... – Abizern Feb 17 '17 at 13:20
• I wanted a brief explanation of the code inside the `draw(rect)` method but the question is vague. So I ask this .. why is `let y = scaling * maxAmplitude * normedAmplitude * sin(CGFloat(2 * M_PI) * self.frequency * (x / self.bounds.width) + self.phase) + self.bounds.height/2.0` – user7404038 Feb 18 '17 at 9:03

Here's a breakdown of the inner-most loop, which loops through `x` to draw the waveform. I'm going to get a little detailed in my explanation in the hopes that some bit of the additional info might be useful to others.

``````        for x in Swift.stride(from:0, to:self.bounds.width + self.density, by:self.density)
{
``````

The loop iterates through the width of the UIView by a `density` increment. This allows control over two properties: (1) the 'resolution' of the waveform and (2) how long it spends generating the `UIBezierPath` that gets drawn. Simply setting `density` to `2` (in `ViewController.swift`) will cut the number of calculations in half as well as produce a path with half as many elements to draw. Increasing `density` by a full order of magnitude (`10`) may seem like too much, but you would be hard-pressed to notice a visual difference. Try setting the value to `100` if you want to see a triangle-wave.

Side note: due to the use of `stride(from:to:by:)` if the view's width isn't evenly divisible by `density`, the waveform may stop short of the right side of the view, so `+ self.density` was added.

``````            // Parabolic scaling
let scaling = -pow(1 / mid * (x - mid), 2) + 1
``````

Have you noticed how the waveform seems to be attached to an anchor point on both sides of the screen? That's what this parabolic scaling is doing. To see it more clearly, you can plug this formula into Google's graphing functionality to get this: Within that range, `y` follows a curve, yes, but notice how `y` starts at 0, rises to exactly 1.0 in the center, then falls back down to 0. More specifically, it does this within the range of `x` from 0 to 1. That's key because we'll be mapping this curve to the width of the view, where the left edge of the screen maps to `x=0` and the right edge of the screen maps to `x=1`.

If we map this curve to our on-screen waveform and use it to scale the amplitude (amplitude: the size of the waveform relative to its center-line) you'll see that the left and right endpoints of the waveform would have an amplitude of 0 (our anchor points) with the size of the waveform gradually increasing to full-size (1.0) in the center.

To see the full effect of this scaling, try changing that line to `let scaling = CGFloat(1.0)`.

At this point, we're ready to chart the waveform. Here's the original line of code that the OP was asking about:

`````` let y = scaling * maxAmplitude * normedAmplitude *
sin(CGFloat(2 * M_PI) * self.frequency * (x / self.bounds.width) + self.phase)
+ self.bounds.height/2.0
``````

That's a lot to take in all at once. This code does the same exact thing, but I've broken it apart into temporary variables with appropriate names to aid in understanding what's going on:

``````let unitWidth = x / self.bounds.width

var wave = CGFloat(2 * M_PI)
wave *= unitWidth
wave *= self.frequency

let wavePosition = wave + self.phase

let waveUnitValue = sin(wavePosition)

var amplitude = waveUnitValue * maxAmplitude
amplitude *= scaling
amplitude *= normedAmplitude

let y = amplitude + self.bounds.height/2.0
``````

Okay, let's tackle this one bit at a time. We'll start with `unitWidth`. Remember when I mentioned that we were going to map the curve to the width of our screen? That's what this `unitWidth` calculation is doing: as `x` ranges from 0 to `self.bounds.width`, `unitWidth` will range from 0 to 1.

Next up is `wave`. It is important to note that this value is intended for the purpose of calculating a sine wave. Note that the `sin` function works in Radians which means that the full period of a sine wave will range from 0 to 2π, so we'll start there (`CGFloat(2 * M_PI)`).

We then apply our `unitWidth` to `wave` which determines where, within the sine wave we want to be for a given `x` position in the view. Think about it like this: Along the left side of the view, `unitWidth` is 0, so this multiplication results in 0 (the start of a sine wave.) Along the right-side of the view, `unitWidth` is 1.0 (giving us the full value 2π - the end of the sine wave.) If we're in the middle of the view, `unitWidth` will be 0.5, which would give us half-way through the full sine-wave period. And everything in-between. This is called interpolation. It is important to understand that we're not moving the sine wave, we're stepping through it.

Next up, we apply `self.frequency` to `wave`. This scales the sine wave such that higher values have more hills and valleys. A frequency is 1 would not do anything and we'll follow the natural sine wave. But that's boring, so the frequency is increased a bit (1.5) in order to give a better visual appearance. Like salt, adjust to taste. Here it is at 3x the frequency: So far, we've defined how our sine wave will look relative to the view that we're drawing it to. Our next task is to give it motion. To that end, we'll add `self.phase` to `wave`. This is called 'phase' because a phase is a distinct period within the waveform. By continuously changing `self.phase` for each frame of the animation, the drawing will start at a different position within the waveform, making it appear to move past the screen.

Finally, we use `wavePosition` to calculate the actual sine wave value (`let waveUnitValue = sin(wavePosition)`). I've called this `waveUnitValue` because the result of sin() is a value that ranges from -1 to +1. If we drew it as-is, our wave would be pretty boring, resembling nearly a flat line: "I've got a need... a need for amplitude"

-- Nobody

Our `amplitude` starts by applying a `maxAmplitude` to `waveUnitValue`, stretching it vertically. Why start with the maximum? If we go back to that calculation of the `scaling` variable, we'd be reminded that this is a unit value - a value that range from 0 to 1 - which means that it can only reduce the amplitude (or leave it unchanged) but not increase it.

And that's exactly what we'll do next, apply our `scaling` value. This causes our waveform to have an amplitude of 0 at the ends, gradually increasing to full amplitude in the center. Without this, we would have something that looks like this: Finally, we have `normedAmplitude`. If you follow the code, you'll see that the `drawWave` function is called within a loop in order to draw multiple waves into the view (this is where those secondary or 'shadow' waveforms come in.) The `normedAmplitude` is used to select a different amplitude for each of the waveforms drawn as part of the overall effect.

It is interesting to note that the normedAmplitude can go negative, which allows for the shadow waveforms to be flipped vertically, filling in the waveform's empty spaces. Try changing the use of `normedAmplitude` in the original code to `abs(normedAmplitude)` and you'll see something like this (combined with the 3x frequency example to highlight the difference): The last step is to center the waveform in the view (`amplitude + self.bounds.height/2.0`), which becomes the final `y` value we'll use to draw the waveform.

So, um. That's it.

• Thanks for the amazing answer. – user7404038 Mar 23 '17 at 17:50