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day18: improve brute for for binary search for big gainz
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test / AoC 2024 (push) Successful in 1m48s
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also avoid unnecessary path tracking work
This commit is contained in:
Keenan Tims 2024-12-18 11:33:26 -08:00
parent 1c254fff93
commit 2a11e17d92
Signed by: ktims
GPG Key ID: 11230674D69038D4
1 changed files with 70 additions and 33 deletions
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103
src/day18.rs
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@ -10,6 +10,7 @@ struct MemoryMap {
}
trait PathTrack {
const DOES_WORK: bool = true;
fn new() -> Self;
fn push(&mut self, pos: (i64, i64));
fn finalize(&mut self) {}
@ -37,6 +38,15 @@ impl PathTrack for Vec<(i64, i64)> {
}
}
struct NoopTrack {}
impl PathTrack for NoopTrack {
const DOES_WORK: bool = false;
fn new() -> Self {
Self {}
}
fn push(&mut self, _: (i64, i64)) {}
}
impl MemoryMap {
fn from_str(input: &str, width: usize, height: usize) -> Self {
let map = Grid::with_shape(width, height, true);
@ -51,17 +61,14 @@ impl MemoryMap {
Self { map, byte_stream }
}
// Return if the byte caused a new blockage or not
fn place_byte(&mut self, i: usize) -> bool {
fn place_byte(&mut self, i: usize) {
let pos = self.byte_stream[i];
match self.map.set(&pos, false) {
None => panic!("corruption outside memory bounds"),
Some(x) => x,
}
self.map.set(&pos, false);
}
fn place_bytes(&mut self, n: usize) {
assert!(n < self.byte_stream.len());
for i in 0..n {
fn place_bytes(&mut self, start: usize, end: usize) {
for i in start..=end {
self.place_byte(i);
}
}
@ -85,16 +92,20 @@ impl MemoryMap {
while let Some((cost, pos)) = queue.pop() {
if pos == goal {
let mut visited_pos = goal;
let mut path = T::new();
path.push(pos);
while let Some(next) = prev.get(&visited_pos) {
visited_pos = *next;
path.push(*next);
if *next == start {
path.finalize();
return Some(path);
if T::DOES_WORK {
let mut visited_pos = goal;
let mut path = T::new();
path.push(pos);
while let Some(next) = prev.get(&visited_pos) {
visited_pos = *next;
path.push(*next);
if *next == start {
path.finalize();
return Some(path);
}
}
} else {
return Some(T::new());
}
}
@ -106,7 +117,9 @@ impl MemoryMap {
for new_pos in moves {
if costs.get(&new_pos).is_none_or(|best_cost| cost.0 + 1 < *best_cost) {
costs.set(&new_pos, cost.0 + 1);
prev.set(&new_pos, pos);
if T::DOES_WORK {
prev.set(&new_pos, pos);
}
queue.push((Reverse(cost.0 + 1), new_pos));
}
}
@ -115,37 +128,56 @@ impl MemoryMap {
}
}
pub fn part1_impl(input: &str, width: usize, height: usize, n: usize) -> usize {
pub fn part1_impl(input: &str, width: usize, height: usize, initial_safe_byte_count: usize) -> usize {
let mut map = MemoryMap::from_str(input, width, height);
map.place_bytes(n);
map.place_bytes(0, initial_safe_byte_count - 1);
let path = map.dijkstra::<LengthPath>((0, 0)).expect("no path found");
path.0 - 1 // count edges, not visited nodes (start doesn't count)
}
pub fn part2_impl(input: &str, width: usize, height: usize, n: usize) -> (i64, i64) {
// My original devised solution
pub fn part2_impl_brute(input: &str, width: usize, height: usize, initial_safe_byte_count: usize) -> (i64, i64) {
let mut input_map = MemoryMap::from_str(input, width, height);
input_map.place_bytes(0, initial_safe_byte_count - 1);
input_map.place_bytes(n);
let mut path = input_map.dijkstra::<Vec<(i64, i64)>>((0, 0)).expect("no path found");
for byte in n..input_map.byte_stream.len() {
if input_map.place_byte(byte) {
// If it's a new blockage, and it obstructs our best path, we need to do a new path search
if let Some((obs_at, _)) = path.iter().find_position(|v| *v == &input_map.byte_stream[byte]) {
let (before, _) = path.split_at(obs_at);
for byte in initial_safe_byte_count..input_map.byte_stream.len() {
input_map.place_byte(byte);
// If it obstructs our best path, we need to do a new path search
if let Some((obs_at, _)) = path.iter().find_position(|v| *v == &input_map.byte_stream[byte]) {
let (before, _) = path.split_at(obs_at);
if let Some(new_path) = input_map.dijkstra::<Vec<(i64, i64)>>(path[obs_at - 1]) {
path = [before, &new_path].concat();
} else {
return input_map.byte_stream[byte];
}
if let Some(new_path) = input_map.dijkstra::<Vec<(i64, i64)>>(path[obs_at - 1]) {
path = [before, &new_path].concat();
} else {
return input_map.byte_stream[byte];
}
}
}
panic!("no bytes block route");
}
// Optimized based on others' ideas
pub fn part2_impl(input: &str, width: usize, height: usize, initial_safe_byte_count: usize) -> (i64, i64) {
let mut input_map = MemoryMap::from_str(input, width, height);
input_map.place_bytes(0, initial_safe_byte_count - 1);
// for the unplaced bytes, binary search for the partition point, given the predicate that a path is reachable
// when all bytes up to that n have been placed
let possible_problems = (initial_safe_byte_count..input_map.byte_stream.len()).collect_vec();
let solution = possible_problems.partition_point(|byte| {
// avoiding this clone by rolling back the byte placements instead is slower
let mut local_map = input_map.clone();
local_map.place_bytes(initial_safe_byte_count, *byte);
local_map.dijkstra::<NoopTrack>((0, 0)).is_some()
}) + initial_safe_byte_count;
return input_map.byte_stream[solution];
}
#[aoc(day18, part1)]
pub fn part1(input: &str) -> usize {
part1_impl(input, 71, 71, 1024)
@ -195,4 +227,9 @@ mod tests {
fn part2_example() {
assert_eq!(part2_impl(EXAMPLE, 7, 7, 12), (6, 1));
}
#[test]
fn part2_example_brute() {
assert_eq!(part2_impl_brute(EXAMPLE, 7, 7, 12,), (6, 1));
}
}