Day 04: Making sense of the tree
Part of the Advent of Grok {Shan, Shui}*. See blog post for intro and table of contents.
Continuing right from the place where we stopped, I find myself uneasy about the names of things. I still remember loving short names like ang in my C++ days, and I still resent prevalent in some codebases multiword over-explanatory names like angle_for_current_leaf, but I mostly prefer 1-2 full words for a variable name. It is much easier to read aloud, if nothing else!
So, what about this?
this.tree01 = function(x, y, {height = 50, width = 3, color = rgba(100,100,100,0.5), noise = 0.5 }) {
color = rgba(255, 0, 0, 0.5);
resolution = 10;
var noises = range(resolution).map(i => [Noise.noise(i * 0.5), Noise.noise(i * 0.5, 0.5)]);
var points = range(resolution).map(i => ({x, y: y - (i * height) / resolution}))
var line1 = points.zip(noises).map(
([point, [noise1, _]]) => [point.x + (noise1 - 0.5) * width - width / 2, point.y]
);
var line2 = points.zip(noises).map(
([point, [_, noise2]]) => [point.x + (noise2 - 0.5) * width + width / 2, point.y]
);
var canvas =
range(resolution).zip(points).slice(resolution / 4 + 1).flatMap(
([i, point]) => {
to_top = resolution - i
return range(to_top / 5).map(() => blob_(
point.x + rand(-0.5, 0.5) * width * 1.2 * to_top,
point.y + rand(-0.5, 0.5) * width,
{
length: rand(20) * to_top * 0.2 + 10,
width: rand(6) + 3,
angle: rand(-0.5, 0.5) * Math.PI / 6,
color: color.merge({a: rand(0.2) + color.a}),
},
))
}
).join()
canvas +=
poly_(line1, { fill: "none", stroke: color, width: 1.5 }) +
poly_(line2, { fill: "none", stroke: color, width: 1.5 });
return canvas;
};
I needed to fix argument names in one place that calls tree01, and also the signatures of blob and poly. As the latter functions are called from everywhere, I just rewrote them into blob_ and poly_ with new API (and new code, because why not). poly_ is self-evident (just generates an SVG polygon):
function poly_(points, {x_offset = 0, y_offset = 0, fill = rgba(0, 0, 0, 0), stroke, width = 0}) {
stroke ||= fill
return "<polyline points='" +
points.map( ([x, y]) => `${(x + x_offset).toFixed(1)},${(y + y_offset).toFixed(1)}` ).join(' ') +
`' style='fill: ${fill};stroke: ${stroke};stroke-width: ${width}'/>`
}
blob_ is more convoluted, and we’ll probably get back to it after handling some of the more high-level stuff:
function blob_(x, y, {
length = 20,
width = 5,
angle = 0,
color = rgba(200, 200, 200, 0.9),
noise = 0.5,
render = true,
fun}) {
fun ||= (x) => x <= 1 ? Math.pow(Math.sin(x * Math.PI), 0.5) : -Math.pow(Math.sin((x + 1) * Math.PI), 0.5)
var resolution = 20.0;
var las = range(resolution + 1).map( i => {
var p = (i / resolution) * 2;
var xo = length / 2 - Math.abs(p - 1) * length;
var yo = (fun(p) * width) / 2;
var a = Math.atan2(yo, xo);
var l = Math.sqrt(xo * xo + yo * yo);
return [l, a];
})
var n0 = Math.random() * 10;
var noises = range(resolution + 1).
map( i => Noise.noise(i * 0.05, n0)).
map( n => n * noise + (1 - noise))
loopNoise(noises);
var points = las.zip(noises).map(
([[l, a], n]) => [x + Math.cos(a + angle) * l * n, y + Math.sin(a + angle) * l * n]
)
if (render) {
return poly_(points, { fill: color, stroke: color, width: 0 });
} else {
return points;
}
}
…but basically it generates some random-ish blob of the specified size.
Now, we might notice that in noises array, first values only needed for line1, second ones for line2; can we just embed it? With not much understanding (yet) of the nature of this Noise.noise, I was afraid the different order of calls might change values, but the quick experiment shows that with fixed SEED, Noise.noise(n) always produces the same value for the same n, so… here is the final form of the function:
this.tree01 = function(x, y, {height = 50, width = 3, color = rgba(100,100,100,0.5), noise = 0.5 }) {
color = rgba(255, 0, 0, 0.5);
resolution = 10;
var points = range(resolution).map(i => ({x, y: y - (i * height) / resolution}))
var trunk1 = points.map(
(point, i) => [point.x - width / 2 + width * (Noise.noise(i * 0.5) - 0.5), point.y]
);
var trunk2 = points.map(
(point, i) => [point.x + width / 2 + width * (Noise.noise(i * 0.5, 0.5) - 0.5), point.y]
);
var crowns =
range(resolution).zip(points).slice(resolution / 4 + 1).flatMap(
([i, point]) => {
to_top = resolution - i
return range(to_top / 5).map(() => [
point.x + rand(-0.5, 0.5) * width * 1.2 * to_top,
point.y + rand(-0.5, 0.5) * width,
{
length: rand(20) * to_top * 0.2 + 10,
width: rand(6) + 3,
angle: rand(-0.5, 0.5) * Math.PI / 6,
color: color.merge({a: rand(0.2) + color.a}),
},
])
}
)
return crowns.map( ([x, y, args]) => blob_(x, y, args)).join() +
poly_(trunk1, { fill: "none", stroke: color, width: 1.5 }) +
poly_(trunk2, { fill: "none", stroke: color, width: 1.5 });
};
Here is what’s going on here, now more or less obvious:
- generate
resolutionnumber of points with the samex, andys spread through all theheight; - generate two trunk lines, with each point being shifted by
xbywidth / 2(left and right), and then “jerked” a bit randomly with noise - starting from 4th point up, generate crown “blobs” (at lower points, there would be several blobs on top of each other, at higher ones, less and less of them, because we generate
to_top / 5blobs at each point) - draw it!
At this point (when I decoupled crown blobs data generation from blob_ calls), picture changed somewhat:
That’s because again of Math.random() calls value order (blob uses it, too, so “generate random data for one blob → call blob_” vs “generate data for all blobs → for every data, call blob_” invokes different random numbers). But at this point of the investigation, it seems OK!
And that’s the end of Day Four investigation.
Next, with the developed understanding and tools, we’ll switch to several other trees, and then to objects with completely different logic!