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day24.rs
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day24.rs
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//! # Never Tell Me The Odds
//!
//! ## Part One
//!
//! We find the intersection for each pair of hailstones by solving a pair of linear simultaneous
//! equations in 2 unknowns:
//!
//! * `a` and `g` are the x positions of the pair of hailstones.
//! * `b` and `h` are the y positions.
//! * `d` and `j` are the x velocities.
//! * `e` and `k` are the x velocities.
//! * Let `t` and `u` be the times that the first and second hailstone respectively are at the
//! intersection point.
//!
//! Then we can write:
//!
//! * `a + dt = g + ju` => `dt - ju = g - a`
//! * `b + et = h + ku` => `et - ku = h - b`
//!
//! In matrix form:
//!
//! ```none
//! | d -j ||u| = | g - a |
//! | e -k ||t| | h - b |
//! ```
//!
//! Solve by finding the inverse of the 2x2 matrix and premultiplying both sides. The inverse is:
//!
//! ```none
//! ______1______ | -k j |
//! d(-k) - (-j)e | -e d |
//! ```
//!
//! Then we check that both times are non-negative and that the intersection point is inside the
//! target area.
//!
//! ## Part Two
//!
//! First we choose 3 arbitrary hailstones. Then we subtract the position and velocity of the
//! the first to make the other two relative.
//!
//! The two hailstones will intercept a line leaving the origin. We can determine this line
//! by intersection the two planes that the hailstone's velocity lie in. These planes are
//! defined by a normal vector orthogonal to the plane.
//!
//! This normal vector is the [cross product](https://en.wikipedia.org/wiki/Cross_product) of
//! any two vector that lie in the plane, in this case the velocity and also the vector from the
//! origin to the starting location of the hailstone.
//!
//! The direction but not necessarily the magnitude of the velocity is then given by the cross
//! product of the two normals.
//!
//! Given the rock direction we can calculate the times that the two hailstones are intercepted
//! then use this to determine the original position of the rock, as long as the two times
//! are different.
use crate::util::iter::*;
use crate::util::math::*;
use crate::util::parse::*;
use std::ops::RangeInclusive;
const RANGE: RangeInclusive<i64> = 200_000_000_000_000..=400_000_000_000_000;
#[derive(Clone, Copy)]
struct Vector {
x: i128,
y: i128,
z: i128,
}
/// 3D vector implementation.
impl Vector {
fn add(self, other: Self) -> Self {
let x = self.x + other.x;
let y = self.y + other.y;
let z = self.z + other.z;
Vector { x, y, z }
}
fn sub(self, other: Self) -> Self {
let x = self.x - other.x;
let y = self.y - other.y;
let z = self.z - other.z;
Vector { x, y, z }
}
fn cross(self, other: Self) -> Self {
let x = self.y * other.z - self.z * other.y;
let y = self.z * other.x - self.x * other.z;
let z = self.x * other.y - self.y * other.x;
Vector { x, y, z }
}
// Changes the magnitude (but not direction) of the vector.
// Prevents numeric overflow.
fn gcd(self) -> Self {
let gcd = self.x.gcd(self.y).gcd(self.z);
let x = self.x / gcd;
let y = self.y / gcd;
let z = self.z / gcd;
Vector { x, y, z }
}
fn sum(self) -> i128 {
self.x + self.y + self.z
}
}
pub fn parse(input: &str) -> Vec<[i64; 6]> {
input.iter_signed().chunk::<6>().collect()
}
pub fn part1(input: &[[i64; 6]]) -> u32 {
let mut result = 0;
for (index, &[a, b, _, c, d, _]) in input[1..].iter().enumerate() {
for &[e, f, _, g, h, _] in &input[..index + 1] {
// If the determinant is zero there is no solution possible
// which implies the trajectories are parallel.
let determinant = d * g - c * h;
if determinant == 0 {
continue;
}
// Invert the 2x2 matrix then multiply by the respective columns to find the times.
let t = (g * (f - b) - h * (e - a)) / determinant;
let u = (c * (f - b) - d * (e - a)) / determinant;
// We can pick either the first or second hailstone to find the intersection position.
let x = a + t * c;
let y = b + t * d;
// Both times must be in the future and the position within the specified area.
if t >= 0 && u >= 0 && RANGE.contains(&x) && RANGE.contains(&y) {
result += 1;
}
}
}
result
}
pub fn part2(input: &[[i64; 6]]) -> i128 {
// Calculations need the range of `i128`.
let widen = |i: usize| {
let [px, py, pz, vx, vy, vz] = input[i].map(|n| n as i128);
let p = Vector { x: px, y: py, z: pz };
let v = Vector { x: vx, y: vy, z: vz };
(p, v)
};
// Take 3 arbitrary hailstones.
let (p0, v0) = widen(0);
let (p1, v1) = widen(1);
let (p2, v2) = widen(2);
// Subtract the positions and velocities to make them relative.
// The first hailstone is stationary at the origin.
let p3 = p1.sub(p0);
let p4 = p2.sub(p0);
let v3 = v1.sub(v0);
let v4 = v2.sub(v0);
// Find the normal to the plane that the second and third hailstones velocity lies in.
// This is the cross product of their respective position and velocity.
// The cross product `s` of these two vectors is the same direction but not necessarily the
// same magnitude of the desired velocity of the rock.
// Only the direction is relevant (not the magnitude) so we can normalize the vector by the
// GCD of its components in order to prevent numeric overflow.
let q = v3.cross(p3).gcd();
let r = v4.cross(p4).gcd();
let s = q.cross(r).gcd();
// Find the times when the second and third hailstone intercept this vector.
// If the times are different then we can extrapolate the original position of the rock.
let t = (p3.y * s.x - p3.x * s.y) / (v3.x * s.y - v3.y * s.x);
let u = (p4.y * s.x - p4.x * s.y) / (v4.x * s.y - v4.y * s.x);
assert!(t != u);
// Calculate the original position of the rock, remembering to add the first hailstone's
// position to convert back to absolute coordinates.
let a = p0.add(p3).sum();
let b = p0.add(p4).sum();
let c = v3.sub(v4).sum();
(u * a - t * b + u * t * c) / (u - t)
}