Problem of Apollonius
This program is written mostly in the "sigilless" style for several reasons. First, sigils tend to imply variables, and these sigilless symbols are not variables, but readonly bindings to values that are calculated only once, so leaving off the sigil emphasizes the fact that they are not variables, but merely named intermediate results.
Second, it looks more like the original mathematical formulas to do it this way (which is also why we define a postfix:<²> for squaring values).
Third, together with the use of Unicode, we are emphasizing the social contract between the writer and the reader, which has a clause in it that indicates code is read much more often than it is written, therefore the writer is obligated to undergo vicarious suffering on behalf of the reader to make things clear. If the reader doesn't understand, it's the writer's fault, in other words. Or in other other words, figure out how to type those Unicode characters, even if it's hard. And you should type them whenever it makes things clearer to the reader.
Finally, writing in an SSA style tends to help the optimizer.
class Circle {
has $.x;
has $.y;
has $.r;
method gist { "circle($!x, $!y, $!r)" }
}
sub circle($x,$y,$r) { Circle.new: :$x, :$y, :$r }
sub postfix:<²>($x) { $x * $x }
sub solve-Apollonius([\c1, \c2, \c3], [\s1, \s2, \s3]) {
my \𝑣11 = 2 * c2.x - 2 * c1.x;
my \𝑣12 = 2 * c2.y - 2 * c1.y;
my \𝑣13 = c1.x² - c2.x² + c1.y² - c2.y² - c1.r² + c2.r²;
my \𝑣14 = 2 * s2 * c2.r - 2 * s1 * c1.r;
my \𝑣21 = 2 * c3.x - 2 * c2.x;
my \𝑣22 = 2 * c3.y - 2 * c2.y;
my \𝑣23 = c2.x² - c3.x² + c2.y² - c3.y² - c2.r² + c3.r²;
my \𝑣24 = 2 * s3 * c3.r - 2 * s2 * c2.r;
my \𝑤12 = 𝑣12 / 𝑣11;
my \𝑤13 = 𝑣13 / 𝑣11;
my \𝑤14 = 𝑣14 / 𝑣11;
my \𝑤22 = 𝑣22 / 𝑣21 - 𝑤12;
my \𝑤23 = 𝑣23 / 𝑣21 - 𝑤13;
my \𝑤24 = 𝑣24 / 𝑣21 - 𝑤14;
my \𝑃 = -𝑤23 / 𝑤22;
my \𝑄 = 𝑤24 / 𝑤22;
my \𝑀 = -𝑤12 * 𝑃 - 𝑤13;
my \𝑁 = 𝑤14 - 𝑤12 * 𝑄;
my \𝑎 = 𝑁² + 𝑄² - 1;
my \𝑏 = 2 * 𝑀 * 𝑁 - 2 * 𝑁 * c1.x + 2 * 𝑃 * 𝑄 - 2 * 𝑄 * c1.y + 2 * s1 * c1.r;
my \𝑐 = c1.x² + 𝑀² - 2 * 𝑀 * c1.x + 𝑃² + c1.y² - 2 * 𝑃 * c1.y - c1.r²;
my \𝐷 = 𝑏² - 4 * 𝑎 * 𝑐;
my \rs = (-𝑏 - sqrt 𝐷) / (2 * 𝑎);
my \xs = 𝑀 + 𝑁 * rs;
my \ys = 𝑃 + 𝑄 * rs;
circle(xs, ys, rs);
}
sub MAIN {
my @c = circle(0, 0, 1), circle(4, 0, 1), circle(2, 4, 2);
say solve-Apollonius @c, <1 1 1>;
say solve-Apollonius @c, <-1 -1 -1>;
}
Output:
circle(2, 2.1, 3.9)
circle(2, 0.833333333333333, 1.16666666666667)