extern crate take_mut; use std::collections::HashMap; use parser::{AST, ASTNode, Expression, Function}; type Reduction = (T, Option); #[derive(Debug)] enum SideEffect { Print(String), AddBinding(String, Expression), } struct EnvFrame { functions: HashMap, variables: HashMap, } impl EnvFrame { fn new() -> EnvFrame { EnvFrame { functions: HashMap::new(), variables: HashMap::new(), } } } pub struct Evaluator { frames: Vec, } impl Evaluator { pub fn new() -> Evaluator { Evaluator { frames: vec!(EnvFrame::new()), } } pub fn run(&mut self, ast: AST) -> Vec { ast.into_iter() .map(|astnode| self.reduce(astnode)) .collect() } fn add_binding(&mut self, var: String, value: Expression) { match self.frames.last_mut() { Some(frame) => frame.variables.insert(var, value), None => panic!("Evaluator should ensure that frames always has at least one element"), }; } fn lookup_binding(&self, var: String) -> Option { for frame in self.frames.iter().rev() { match frame.variables.get(&var) { None => (), Some(expr) => return Some(expr.clone()), } } None } fn add_function(&mut self, name: String, function: Function) { match self.frames.last_mut() { Some(frame) => frame.functions.insert(name, function), None => panic!("Evaluator should ensure that frames always has at least one element"), }; } fn lookup_function(&self, name: String) -> Option { for frame in self.frames.iter().rev() { match frame.functions.get(&name) { None => (), Some(function) => return Some(function.clone()), } } None } } trait Evaluable { fn is_reducible(&self) -> bool; } impl Evaluable for ASTNode { fn is_reducible(&self) -> bool { use parser::ASTNode::*; match self { &ExprNode(ref expr) => expr.is_reducible(), &FuncNode(_) => true, } } } impl Evaluable for Expression { fn is_reducible(&self) -> bool { use parser::Expression::*; match *self { Null => false, StringLiteral(_) => false, Number(_) => false, _ => true, } } } impl Evaluator { fn reduce(&mut self, mut node: ASTNode) -> String { loop { node = self.step(node); if !node.is_reducible() { break; } } format!("{}", node) } fn step(&mut self, node: ASTNode) -> ASTNode { let (new_node, side_effect) = self.reduce_astnode(node); if let Some(s) = side_effect { self.perform_side_effect(s); } new_node } fn perform_side_effect(&mut self, side_effect: SideEffect) { use self::SideEffect::*; match side_effect { Print(s) => println!("{}", s), AddBinding(var, value) => { self.add_binding(var, value); } } } fn reduce_astnode(&mut self, node: ASTNode) -> Reduction { use parser::ASTNode::*; match node { ExprNode(expr) => { if expr.is_reducible() { let (new_expr, side_effect) = self.reduce_expr(expr); (ExprNode(new_expr), side_effect) } else { (ExprNode(expr), None) } } FuncNode(func) => { let fn_name = func.prototype.name.clone(); self.add_function(fn_name, func); (ExprNode(Expression::Null), None) } } } fn reduce_expr(&mut self, expression: Expression) -> Reduction { use parser::Expression::*; match expression { Null => (Null, None), e @ StringLiteral(_) => (e, None), e @ Number(_) => (e, None), Variable(var) => { match self.lookup_binding(var) { None => (Null, None), Some(expr) => (expr, None), } } BinExp(op, box left, box right) => { if right.is_reducible() { let new = self.reduce_expr(right); return (BinExp(op, Box::new(left), Box::new(new.0)), new.1); } // special case for variable assignment if op == "=" { match left { Variable(var) => { let binding = SideEffect::AddBinding(var, right); return (Null, Some(binding)); } _ => return (Null, None) } } if left.is_reducible() { let new = self.reduce_expr(left); (BinExp(op, Box::new(new.0), Box::new(right)), new.1) } else { (self.reduce_binop(op, left, right), None) //can assume both arguments are maximally reduced } } Call(name, mut args) => { let mut f = true; for arg in args.iter_mut() { if arg.is_reducible() { take_mut::take(arg, |arg| self.reduce_expr(arg).0); f = false; break; } } if f { self.reduce_call(name, args) } else { (Call(name, args), None) } } Conditional(box test, then_block, else_block) => { if test.is_reducible() { let (new_test, new_effect) = self.reduce_expr(test); (Conditional(Box::new(new_test), then_block, else_block), new_effect) } else { if let Number(0.0) = test { unimplemented!() } else { unimplemented!() } } } } } fn reduce_binop(&mut self, op: String, left: Expression, right: Expression) -> Expression { use parser::Expression::*; match &op[..] { "+" => { match (left, right) { (Number(l), Number(r)) => Number(l + r), (StringLiteral(s1), StringLiteral(s2)) => { StringLiteral(format!("{}{}", s1, s2)) } _ => Null, } } "-" => { match (left, right) { (Number(l), Number(r)) => Number(l - r), _ => Null, } } "*" => { match (left, right) { (Number(l), Number(r)) => Number(l * r), _ => Null, } } "/" => { match (left, right) { (Number(l), Number(r)) if r != 0.0 => Number(l / r), _ => Null, } } "%" => { match (left, right) { (Number(l), Number(r)) => Number(l % r), _ => Null, } } _ => Null, } } fn reduce_call(&mut self, name: String, arguments: Vec) -> Reduction { use parser::Expression::*; // ugly hack for now if name == "print" { let mut s = String::new(); for arg in arguments { s.push_str(&format!("{}\n", arg)); } return (Null, Some(SideEffect::Print(s))); } let function = match self.lookup_function(name) { Some(func) => func, None => return (Null, None), }; if function.prototype.parameters.len() != arguments.len() { return (Null, None); } let mut frame = EnvFrame::new(); for (binding, expr) in function.prototype.parameters.iter().zip(arguments.iter()) { frame.variables.insert(binding.clone(), expr.clone()); } self.frames.push(frame); let mut retval = Null; for expr in function.body.iter() { retval = expr.clone(); while retval.is_reducible() { let r = self.reduce_expr(retval); retval = r.0; if let Some(s) = r.1 { self.perform_side_effect(s); } } } self.frames.pop(); (retval, None) } }