mod error; mod value; pub use self::error::{Error, Result}; pub use self::value::{Function, Value}; use crate::ast::hir::{Binding, Expr}; use crate::ast::{BinaryOperator, FunctionType, Ident, Literal, Type, UnaryOperator}; use crate::common::env::Env; #[derive(Debug, Default)] pub struct Interpreter<'a> { env: Env<&'a Ident<'a>, Value<'a>>, } impl<'a> Interpreter<'a> { pub fn new() -> Self { Self::default() } fn resolve(&self, var: &'a Ident<'a>) -> Result<Value<'a>> { self.env .resolve(var) .cloned() .ok_or_else(|| Error::UndefinedVariable(var.to_owned())) } pub fn eval(&mut self, expr: &'a Expr<'a, Type>) -> Result<Value<'a>> { let res = match expr { Expr::Ident(id, _) => self.resolve(id), Expr::Literal(Literal::Int(i), _) => Ok((*i).into()), Expr::Literal(Literal::Bool(b), _) => Ok((*b).into()), Expr::Literal(Literal::String(s), _) => Ok(s.clone().into()), Expr::Literal(Literal::Unit, _) => unreachable!(), Expr::UnaryOp { op, rhs, .. } => { let rhs = self.eval(rhs)?; match op { UnaryOperator::Neg => -rhs, _ => unimplemented!(), } } Expr::BinaryOp { lhs, op, rhs, .. } => { let lhs = self.eval(lhs)?; let rhs = self.eval(rhs)?; match op { BinaryOperator::Add => lhs + rhs, BinaryOperator::Sub => lhs - rhs, BinaryOperator::Mul => lhs * rhs, BinaryOperator::Div => lhs / rhs, BinaryOperator::Pow => todo!(), BinaryOperator::Equ => Ok(lhs.eq(&rhs).into()), BinaryOperator::Neq => todo!(), } } Expr::Let { bindings, body, .. } => { self.env.push(); for Binding { ident, body, .. } in bindings { let val = self.eval(body)?; self.env.set(ident, val); } let res = self.eval(body)?; self.env.pop(); Ok(res) } Expr::If { condition, then, else_, .. } => { let condition = self.eval(condition)?; if *(condition.as_type::<bool>()?) { self.eval(then) } else { self.eval(else_) } } Expr::Call { ref fun, args, .. } => { let fun = self.eval(fun)?; let expected_type = FunctionType { args: args.iter().map(|_| Type::Int).collect(), ret: Box::new(Type::Int), }; let Function { args: function_args, body, .. } = fun.as_function(expected_type)?; let arg_values = function_args.iter().zip( args.iter() .map(|v| self.eval(v)) .collect::<Result<Vec<_>>>()?, ); let mut interpreter = Interpreter::new(); for (arg_name, arg_value) in arg_values { interpreter.env.set(arg_name, arg_value); } Ok(Value::from(*interpreter.eval(body)?.as_type::<i64>()?)) } Expr::Fun { type_args: _, args, body, type_, } => { let type_ = match type_ { Type::Function(ft) => ft.clone(), _ => unreachable!("Function expression without function type"), }; Ok(Value::from(value::Function { // TODO type_, args: args.iter().map(|(arg, _)| arg.to_owned()).collect(), body: (**body).to_owned(), })) } }?; debug_assert_eq!(&res.type_(), expr.type_()); Ok(res) } } pub fn eval<'a>(expr: &'a Expr<'a, Type>) -> Result<Value<'a>> { let mut interpreter = Interpreter::new(); interpreter.eval(expr) } #[cfg(test)] mod tests { use std::convert::TryFrom; use super::value::{TypeOf, Val}; use super::*; use BinaryOperator::*; fn int_lit(i: u64) -> Box<Expr<'static, Type<'static>>> { Box::new(Expr::Literal(Literal::Int(i), Type::Int)) } fn do_eval<T>(src: &str) -> T where for<'a> &'a T: TryFrom<&'a Val<'a>>, T: Clone + TypeOf, { let expr = crate::parser::expr(src).unwrap().1; let hir = crate::tc::typecheck_expr(expr).unwrap(); let res = eval(&hir).unwrap(); res.as_type::<T>().unwrap().clone() } #[test] fn simple_addition() { let expr = Expr::BinaryOp { lhs: int_lit(1), op: Mul, rhs: int_lit(2), type_: Type::Int, }; let res = eval(&expr).unwrap(); assert_eq!(*res.as_type::<i64>().unwrap(), 2); } #[test] fn variable_shadowing() { let res = do_eval::<i64>("let x = 1 in (let x = 2 in x) + x"); assert_eq!(res, 3); } #[test] fn conditional_with_equals() { let res = do_eval::<i64>("let x = 1 in if x == 1 then 2 else 4"); assert_eq!(res, 2); } #[test] #[ignore] fn function_call() { let res = do_eval::<i64>("let id = fn x = x in id 1"); assert_eq!(res, 1); } }