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|
use nom::{
branch::alt,
bytes::complete::tag,
character::complete::{alpha1, i64, line_ending},
combinator::map,
multi::separated_list1,
sequence::tuple,
IResult,
};
use std::{
collections::{BTreeMap, BTreeSet},
fs,
};
fn main() -> Result<(), Box<dyn std::error::Error>> {
let input = fs::read_to_string("inputs/day_21.txt")?;
let mut monkeys = Monkeys::parser(&input).unwrap().1;
dbg!(monkeys.eval("root"));
let (original_root_left, original_root_right) =
monkeys.0.get("root").expect("No root monkey!").values();
monkeys.0.insert(
"root".into(),
Expression::Eql(original_root_left, original_root_right.expect("foo")),
);
monkeys
.0
.insert("humn".into(), Expression::Value(Value::Input));
while monkeys.0.len() > 1 {
monkeys.simplify();
}
println!("{}", monkeys.print_expression("root"));
Ok(())
}
#[derive(Debug, Clone)]
struct Monkeys(BTreeMap<String, Expression>);
#[derive(Debug, Clone)]
enum Expression {
Value(Value),
Add(Value, Value),
Sub(Value, Value),
Mul(Value, Value),
Div(Value, Value),
Eql(Value, Value),
}
#[derive(Debug, Clone)]
enum Value {
Ref(String),
Literal(i64),
Input,
}
impl Monkeys {
fn parser(input: &str) -> IResult<&str, Self> {
map(
separated_list1(line_ending, tuple((alpha1, tag(": "), Expression::parser))),
|lines| {
Monkeys(
lines
.into_iter()
.map(|(id, _, expression): (&str, _, Expression)| {
(id.to_owned(), expression)
})
.collect(),
)
},
)(input)
}
fn simplify(&mut self) {
let ids: Vec<String> = self.0.keys().cloned().collect();
// simplify to literals where possible
for id in &ids {
if let Some(val) = self.eval(id) {
self.0
.insert(id.clone(), Expression::Value(Value::Literal(val)));
}
}
// simplify single sides of expressions where possible (especially unwrap refs)
for id in &ids {
let monkey = self.0.get(id).expect("Unknown monkey!");
let simplified = match monkey {
Expression::Value(v) => Expression::Value(self.simplify_value(v)),
Expression::Add(a, b) => {
Expression::Add(self.simplify_value(a), self.simplify_value(b))
}
Expression::Sub(a, b) => {
Expression::Sub(self.simplify_value(a), self.simplify_value(b))
}
Expression::Mul(a, b) => {
Expression::Mul(self.simplify_value(a), self.simplify_value(b))
}
Expression::Div(a, b) => {
Expression::Div(self.simplify_value(a), self.simplify_value(b))
}
Expression::Eql(a, b) => {
Expression::Eql(self.simplify_value(a), self.simplify_value(b))
}
};
self.0.insert(id.clone(), simplified);
if let Some(val) = self.eval(id) {
self.0
.insert(id.clone(), Expression::Value(Value::Literal(val)));
}
}
// simplify across the equals
for id in &ids {
let monkey = self.0.get(id).expect("Unknown monkey!").clone();
match monkey {
Expression::Eql(Value::Ref(r), Value::Literal(v))
| Expression::Eql(Value::Literal(v), Value::Ref(r)) => {
let referenced_monkey = self.0.get(&r).expect("Unknown monkey!").clone();
let new_eql = match referenced_monkey {
Expression::Add(new_lhs, Value::Literal(added))
| Expression::Add(Value::Literal(added), new_lhs) => {
Some((new_lhs.clone(), v - added))
}
Expression::Sub(new_lhs, Value::Literal(subtracted)) => {
Some((new_lhs.clone(), v + subtracted))
}
Expression::Sub(Value::Literal(subtracted_from), new_lhs) => {
Some((new_lhs.clone(), subtracted_from - v))
}
Expression::Mul(new_lhs, Value::Literal(mult))
| Expression::Mul(Value::Literal(mult), new_lhs) => {
Some((new_lhs.clone(), v / mult))
}
Expression::Div(new_lhs, Value::Literal(denom)) => {
Some((new_lhs.clone(), v * denom))
}
_ => None,
};
if let Some((new_lhs, new_v)) = new_eql {
self.0
.insert(id.clone(), Expression::Eql(new_lhs, Value::Literal(new_v)));
}
}
_ => {}
}
}
// clearing out unreferenced monkeys
let monkey_references: BTreeSet<String> = self
.0
.values()
.flat_map(|expression| match expression.values() {
(Value::Ref(v1), Some(Value::Ref(v2))) => vec![v1, v2],
(Value::Ref(v), _) | (_, Some(Value::Ref(v))) => vec![v],
_ => vec![],
})
.collect();
for id in &ids {
if id != "root" && !monkey_references.contains(id) {
self.0.remove(id);
}
}
}
fn simplify_value(&self, val: &Value) -> Value {
match val {
Value::Ref(r) => {
let referenced = self.0.get(r).expect("Unknown monkey!");
match referenced {
Expression::Value(v) => v.clone(),
_ => val.clone(),
}
}
v => v.clone(),
}
}
fn eval(&self, id: &str) -> Option<i64> {
let monkey = self.0.get(id).expect("Unknown monkey!");
match monkey {
Expression::Value(v) => self.resolve_value(v),
Expression::Add(a, b) => self
.resolve_value(a)
.zip(self.resolve_value(b))
.map(|(a, b)| a + b),
Expression::Sub(a, b) => self
.resolve_value(a)
.zip(self.resolve_value(b))
.map(|(a, b)| a - b),
Expression::Mul(a, b) => self
.resolve_value(a)
.zip(self.resolve_value(b))
.map(|(a, b)| a * b),
Expression::Div(a, b) => self
.resolve_value(a)
.zip(self.resolve_value(b))
.map(|(a, b)| a / b),
Expression::Eql(a, b) => self
.resolve_value(a)
.zip(self.resolve_value(b))
.map(|(a, b)| if a == b { 1 } else { 0 }),
}
}
fn resolve_value(&self, value: &Value) -> Option<i64> {
match value {
Value::Ref(id) => self.eval(id),
Value::Literal(num) => Some(*num),
Value::Input => None,
}
}
fn print_expression(&self, id: &str) -> String {
let monkey = self.0.get(id).expect("Unknown monkey!");
// The crazy newlines here make it easier to see the
// brackets. Drop it in emacs and autoindent, and it's easy to
// see the next expression which isn't being collapsed.
match monkey {
Expression::Value(v) => format!("(\n{}\n)", self.print_value(v)),
Expression::Add(a, b) => {
format!("(\n{}\n+\n{}\n)", self.print_value(a), self.print_value(b))
}
Expression::Sub(a, b) => {
format!("(\n{}\n-\n{}\n)", self.print_value(a), self.print_value(b))
}
Expression::Mul(a, b) => {
format!("(\n{}\n*\n{}\n)", self.print_value(a), self.print_value(b))
}
Expression::Div(a, b) => {
format!("(\n{}\n/\n{}\n)", self.print_value(a), self.print_value(b))
}
Expression::Eql(a, b) => {
format!("(\n{}\n=\n{}\n)", self.print_value(a), self.print_value(b))
}
}
}
fn print_value(&self, value: &Value) -> String {
match value {
Value::Ref(id) => self.print_expression(id),
Value::Literal(num) => format!("{}", num),
Value::Input => "input".into(),
}
}
}
impl Expression {
fn parser(input: &str) -> IResult<&str, Self> {
alt((
map(
tuple((Value::parser, tag(" + "), Value::parser)),
|(a, _, b)| Expression::Add(a, b),
),
map(
tuple((Value::parser, tag(" - "), Value::parser)),
|(a, _, b)| Expression::Sub(a, b),
),
map(
tuple((Value::parser, tag(" * "), Value::parser)),
|(a, _, b)| Expression::Mul(a, b),
),
map(
tuple((Value::parser, tag(" / "), Value::parser)),
|(a, _, b)| Expression::Div(a, b),
),
map(Value::parser, Expression::Value),
))(input)
}
fn values(&self) -> (Value, Option<Value>) {
match self.clone() {
Expression::Value(v) => (v, None),
Expression::Add(a, b) => (a, Some(b)),
Expression::Sub(a, b) => (a, Some(b)),
Expression::Mul(a, b) => (a, Some(b)),
Expression::Div(a, b) => (a, Some(b)),
Expression::Eql(a, b) => (a, Some(b)),
}
}
}
impl Value {
fn parser(input: &str) -> IResult<&str, Self> {
alt((
map(i64, Value::Literal),
map(alpha1, |s: &str| Value::Ref(s.to_owned())),
))(input)
}
}
|
