advent-of-code/2016/rust/src/day_12.rs

use std::collections::HashMap;

use errors::*;

pub fn solve(input: &str) -> Result<String> {
    Ok("".into())
}

// The assembunny code you've extracted operates on four registers (a, b, c, and d) that start at 0
// and can hold any integer. However, it seems to make use of only a few instructions:
#[derive(Clone, Debug, Hash, Eq, PartialEq)]
enum Register {
    A,
    B,
    C,
    D,
}

enum Variable {
    Register(Register),
    Value(usize),
}

#[derive(Debug, PartialEq)]
struct State {
    pc: usize,
    registers: HashMap<Register, isize>,
}

impl State {
    fn value(&self, v: &Variable) -> isize {
        match v {
            &Variable::Register(ref r) => {
                self.registers.get(r).cloned().unwrap_or(0 as isize)
            }
            &Variable::Value(value) => value as isize,
        }
    }
}

// cpy x y copies x (either an integer or the value of a register) into register y.
struct Copy {
    variable: Variable,
    register: Register,
}

impl Copy {
    fn run(&self, state: &State) -> State {
        let pc = state.pc + 1;
        let value = state.value(&self.variable);
        let mut registers = state.registers.clone();
        registers.insert(self.register.clone(), value);
        State {
            pc: pc,
            registers: registers,
        }
    }
}

// inc x increases the value of register x by one.
// dec x decreases the value of register x by one.
// jnz x y jumps to an instruction y away (positive means forward; negative means backward), but only if x is not zero.

#[cfg(test)]
mod tests {
    use super::{Variable, Register, State, Copy};

    #[test]
    fn test_state_value() {
        let state = State {
            pc: 0,
            registers: vec![(Register::A, 41)].into_iter().collect(),
        };
        assert_eq!(state.value(&Variable::Register(Register::A)), 41);
        assert_eq!(state.value(&Variable::Register(Register::B)), 0);
        assert_eq!(state.value(&Variable::Value(23)), 23);
    }

    #[test]
    fn test_copy() {
        let variable = Variable::Value(41);
        let register = Register::A;
        let copy = Copy {
            variable: variable,
            register: register,
        };
        let state = State {
            pc: 0,
            registers: vec![].into_iter().collect(),
        };
        let expected = State {
            pc: 1,
            registers: vec![(Register::A, 41)].into_iter().collect(),
        };

        assert_eq!(copy.run(&state), expected);
    }
}
[2016][rust][12.0] Copy 8 years ago			`use std::collections::HashMap;`

			`use errors::*;`

			`pub fn solve(input: &str) -> Result<String> {`
			`Ok("".into())`
			`}`

			`// The assembunny code you've extracted operates on four registers (a, b, c, and d) that start at 0`
			`// and can hold any integer. However, it seems to make use of only a few instructions:`
			`#[derive(Clone, Debug, Hash, Eq, PartialEq)]`
			`enum Register {`
			`A,`
			`B,`
			`C,`
			`D,`
			`}`

			`enum Variable {`
			`Register(Register),`
			`Value(usize),`
			`}`

			`#[derive(Debug, PartialEq)]`
			`struct State {`
			`pc: usize,`
			`registers: HashMap<Register, isize>,`
			`}`

			`impl State {`
			`fn value(&self, v: &Variable) -> isize {`
			`match v {`
			`&Variable::Register(ref r) => {`
			`self.registers.get(r).cloned().unwrap_or(0 as isize)`
			`}`
			`&Variable::Value(value) => value as isize,`
			`}`
			`}`
			`}`

			`// cpy x y copies x (either an integer or the value of a register) into register y.`
			`struct Copy {`
			`variable: Variable,`
			`register: Register,`
			`}`

			`impl Copy {`
			`fn run(&self, state: &State) -> State {`
			`let pc = state.pc + 1;`
			`let value = state.value(&self.variable);`
			`let mut registers = state.registers.clone();`
			`registers.insert(self.register.clone(), value);`
			`State {`
			`pc: pc,`
			`registers: registers,`
			`}`
			`}`
			`}`

			`// inc x increases the value of register x by one.`
			`// dec x decreases the value of register x by one.`
			`// jnz x y jumps to an instruction y away (positive means forward; negative means backward), but only if x is not zero.`

			`#[cfg(test)]`
			`mod tests {`
			`use super::{Variable, Register, State, Copy};`

			`#[test]`
			`fn test_state_value() {`
			`let state = State {`
			`pc: 0,`
			`registers: vec![(Register::A, 41)].into_iter().collect(),`
			`};`
			`assert_eq!(state.value(&Variable::Register(Register::A)), 41);`
			`assert_eq!(state.value(&Variable::Register(Register::B)), 0);`
			`assert_eq!(state.value(&Variable::Value(23)), 23);`
			`}`

			`#[test]`
			`fn test_copy() {`
			`let variable = Variable::Value(41);`
			`let register = Register::A;`
			`let copy = Copy {`
			`variable: variable,`
			`register: register,`
			`};`
			`let state = State {`
			`pc: 0,`
			`registers: vec![].into_iter().collect(),`
			`};`
			`let expected = State {`
			`pc: 1,`
			`registers: vec![(Register::A, 41)].into_iter().collect(),`
			`};`

			`assert_eq!(copy.run(&state), expected);`
			`}`
			`}`