use std::collections::HashMap; use errors::*; pub fn solve(input: &str) -> Result { 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, } 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); } }