schala/schala-lang/src/eval.rs

371 lines
12 KiB
Rust

use std::cell::RefCell;
use std::rc::Rc;
use std::fmt::Write;
use std::io;
use itertools::Itertools;
use util::StateStack;
use reduced_ast::{ReducedAST, Stmt, Expr, Lit, Func};
use symbol_table::{SymbolSpec, Symbol, SymbolTable};
pub struct State<'a> {
values: StateStack<'a, Rc<String>, ValueEntry>,
symbol_table_handle: Rc<RefCell<SymbolTable>>,
}
macro_rules! builtin_binding {
($name:expr, $values:expr) => {
$values.insert(Rc::new(format!($name)), ValueEntry::Binding { constant: true, val: Expr::Func(Func::BuiltIn(Rc::new(format!($name)))) });
}
}
impl<'a> State<'a> {
pub fn new(symbol_table_handle: Rc<RefCell<SymbolTable>>) -> State<'a> {
let mut values = StateStack::new(Some(format!("global")));
builtin_binding!("print", values);
builtin_binding!("println", values);
builtin_binding!("getline", values);
State { values, symbol_table_handle }
}
pub fn debug_print(&self) -> String {
format!("Values: {:?}", self.values)
}
}
#[derive(Debug)]
enum ValueEntry {
Binding {
constant: bool,
val: /*FullyEvaluatedExpr*/ Expr,
}
}
type EvalResult<T> = Result<T, String>;
impl Expr {
fn to_repl(&self) -> String {
use self::Lit::*;
use self::Func::*;
fn paren_wrapped_vec(exprs: &Vec<Expr>) -> String {
let mut buf = String::new();
write!(buf, "(").unwrap();
for term in exprs.iter().map(|e| Some(e)).intersperse(None) {
match term {
Some(e) => write!(buf, "{}", e.to_repl()).unwrap(),
None => write!(buf, ", ").unwrap(),
};
}
write!(buf, ")").unwrap();
buf
}
match self {
Expr::Lit(ref l) => match l {
Nat(n) => format!("{}", n),
Int(i) => format!("{}", i),
Float(f) => format!("{}", f),
Bool(b) => format!("{}", b),
StringLit(s) => format!("\"{}\"", s),
Custom(name, args) if args.len() == 0 => format!("{}", name),
Custom(name, args) => format!("{}{}", name, paren_wrapped_vec(args)),
},
Expr::Func(f) => match f {
BuiltIn(name) => format!("<built-in function {}>", name),
UserDefined { name: None, .. } => format!("<function>"),
UserDefined { name: Some(name), .. } => format!("<function {}>", name),
},
Expr::Tuple(exprs) => paren_wrapped_vec(exprs),
_ => format!("{:?}", self),
}
}
}
impl<'a> State<'a> {
pub fn evaluate(&mut self, ast: ReducedAST, repl: bool) -> Vec<Result<String, String>> {
let mut acc = vec![];
// handle prebindings
for statement in ast.0.iter() {
self.prebinding(statement);
}
for statement in ast.0 {
match self.statement(statement) {
Ok(Some(ref output)) if repl => acc.push(Ok(output.to_repl())),
Ok(_) => (),
Err(error) => {
acc.push(Err(format!("Runtime error: {}", error)));
return acc;
},
}
}
acc
}
fn prebinding(&mut self, stmt: &Stmt) {
match stmt {
Stmt::PreBinding { name, func } => {
let v_entry = ValueEntry::Binding { constant: true, val: Expr::Func(func.clone()) };
self.values.insert(name.clone(), v_entry);
},
Stmt::Expr(_expr) => {
//TODO have this support things like nested function defs
},
_ => ()
}
}
fn statement(&mut self, stmt: Stmt) -> EvalResult<Option<Expr>> {
match stmt {
Stmt::Binding { name, constant, expr } => {
let val = self.expression(expr)?;
self.values.insert(name.clone(), ValueEntry::Binding { constant, val });
Ok(None)
},
Stmt::Expr(expr) => Ok(Some(self.expression(expr)?)),
Stmt::PreBinding {..} | Stmt::Noop => Ok(None),
}
}
fn block(&mut self, stmts: Vec<Stmt>) -> EvalResult<Expr> {
let mut ret = None;
for stmt in stmts {
ret = self.statement(stmt)?;
}
Ok(ret.unwrap_or(Expr::Unit))
}
fn expression(&mut self, expr: Expr) -> EvalResult<Expr> {
use self::Expr::*;
match expr {
literal @ Lit(_) => Ok(literal),
Call { box f, args } => {
if let Val(name) = f {
self.apply_data_constructor(name, args)
} else {
match self.expression(f)? {
Func(f) => self.apply_function(f, args),
other => return Err(format!("Tried to call {:?} which is not a function or data constructor", other)),
}
}
},
Val(v) => self.value(v),
func @ Func(_) => Ok(func),
Tuple(exprs) => Ok(Tuple(exprs.into_iter().map(|expr| self.expression(expr)).collect::<Result<Vec<Expr>,_>>()?)),
Conditional { box cond, then_clause, else_clause } => self.conditional(cond, then_clause, else_clause),
Assign { box val, box expr } => {
let name = match val {
Expr::Val(name) => name,
_ => return Err(format!("Trying to assign to a non-value")),
};
let constant = match self.values.lookup(&name) {
None => return Err(format!("{} is undefined", name)),
Some(ValueEntry::Binding { constant, .. }) => constant.clone(),
};
if constant {
return Err(format!("trying to update {}, a non-mutable binding", name));
}
let val = self.expression(expr)?;
self.values.insert(name.clone(), ValueEntry::Binding { constant: false, val });
Ok(Expr::Unit)
},
e => Err(format!("Expr {:?} eval not implemented", e))
}
}
fn apply_data_constructor(&mut self, name: Rc<String>, args: Vec<Expr>) -> EvalResult<Expr> {
let symbol_table = self.symbol_table_handle.borrow();
match symbol_table.values.get(&name) {
Some(Symbol { spec: SymbolSpec::DataConstructor { type_name, type_args }, name }) => {
if args.len() != type_args.len() {
return Err(format!("Data constructor {} requires {} args", name, type_args.len()));
}
Ok(Expr::Lit(self::Lit::Custom(name.clone(), vec![])))
},
_ => return Err(format!("Bad symbol {}", name))
}
}
fn apply_function(&mut self, f: Func, args: Vec<Expr>) -> EvalResult<Expr> {
match f {
Func::BuiltIn(sigil) => self.apply_builtin(sigil, args),
Func::UserDefined { params, body, name } => {
if params.len() != args.len() {
return Err(format!("calling a {}-argument function with {} args", params.len(), args.len()))
}
let mut func_state = State {
values: self.values.new_frame(name.map(|n| format!("{}", n))),
symbol_table_handle: self.symbol_table_handle.clone(),
};
for (param, val) in params.into_iter().zip(args.into_iter()) {
let val = func_state.expression(val)?;
func_state.values.insert(param, ValueEntry::Binding { constant: true, val });
}
// TODO figure out function return semantics
func_state.block(body)
}
}
}
fn apply_builtin(&mut self, name: Rc<String>, args: Vec<Expr>) -> EvalResult<Expr> {
use self::Expr::*;
use self::Lit::*;
let evaled_args: Result<Vec<Expr>, String> = args.into_iter().map(|arg| self.expression(arg)).collect();
let evaled_args = evaled_args?;
Ok(match (name.as_str(), evaled_args.as_slice()) {
/* binops */
("+", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l + r)),
("++", &[Lit(StringLit(ref s1)), Lit(StringLit(ref s2))]) => Lit(StringLit(Rc::new(format!("{}{}", s1, s2)))),
("-", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l - r)),
("*", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l * r)),
("/", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Float((l as f64)/ (r as f64))),
("//", &[Lit(Nat(l)), Lit(Nat(r))]) => if r == 0 {
return Err(format!("divide by zero"));
} else {
Lit(Nat(l / r))
},
("%", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l % r)),
("^", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l ^ r)),
("&", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l & r)),
("|", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Nat(l | r)),
("==", &[Lit(Nat(l)), Lit(Nat(r))]) => Lit(Bool(l == r)),
("==", &[Lit(Int(l)), Lit(Int(r))]) => Lit(Bool(l == r)),
("==", &[Lit(Float(l)), Lit(Float(r))]) => Lit(Bool(l == r)),
("==", &[Lit(Bool(l)), Lit(Bool(r))]) => Lit(Bool(l == r)),
("==", &[Lit(StringLit(ref l)), Lit(StringLit(ref r))]) => Lit(Bool(l == r)),
/* prefix ops */
("!", &[Lit(Bool(true))]) => Lit(Bool(false)),
("!", &[Lit(Bool(false))]) => Lit(Bool(true)),
("-", &[Lit(Nat(n))]) => Lit(Int(-1*(n as i64))),
("-", &[Lit(Int(n))]) => Lit(Int(-1*(n as i64))),
("+", &[Lit(Int(n))]) => Lit(Int(n)),
("+", &[Lit(Nat(n))]) => Lit(Nat(n)),
/* builtin functions */
("print", &[ref anything]) => {
print!("{}", anything.to_repl());
Expr::Unit
},
("println", &[ref anything]) => {
println!("{}", anything.to_repl());
Expr::Unit
},
("getline", &[]) => {
let mut buf = String::new();
io::stdin().read_line(&mut buf).expect("Error readling line in 'getline'");
Lit(StringLit(Rc::new(buf.trim().to_string())))
},
(x, args) => return Err(format!("bad or unimplemented builtin {:?} | {:?}", x, args)),
})
}
fn conditional(&mut self, cond: Expr, then_clause: Vec<Stmt>, else_clause: Vec<Stmt>) -> EvalResult<Expr> {
let cond = self.expression(cond)?;
Ok(match cond {
Expr::Lit(Lit::Bool(true)) => self.block(then_clause)?,
Expr::Lit(Lit::Bool(false)) => self.block(else_clause)?,
_ => return Err(format!("Conditional with non-boolean condition"))
})
}
fn value(&mut self, name: Rc<String>) -> EvalResult<Expr> {
use self::ValueEntry::*;
use self::Func::*;
//TODO add a layer of indirection here to talk to the symbol table first, and only then look up
//in the values table
let symbol_table = self.symbol_table_handle.borrow();
Ok(match symbol_table.values.get(&name) {
Some(Symbol { name, spec }) => match spec {
SymbolSpec::DataConstructor { type_name, type_args } => {
if type_args.len() == 0 {
Expr::Lit(Lit::Custom(name.clone(), vec![]))
} else {
return Err(format!("This data constructor thing not done"))
}
},
SymbolSpec::Func(_) => match self.values.lookup(&name) {
Some(Binding { val: Expr::Func(UserDefined { name, params, body }), .. }) => {
Expr::Func(UserDefined { name: name.clone(), params: params.clone(), body: body.clone() })
},
_ => unreachable!(),
},
},
/* see if it's an ordinary variable TODO make variables go in symbol table */
None => match self.values.lookup(&name) {
Some(Binding { val, .. }) => val.clone(),
None => return Err(format!("Couldn't find value {}", name)),
}
})
}
}
#[cfg(test)]
mod eval_tests {
use std::cell::RefCell;
use std::rc::Rc;
use symbol_table::SymbolTable;
use tokenizing::tokenize;
use parsing::parse;
use eval::State;
macro_rules! fresh_env {
($string:expr, $correct:expr) => {
let symbol_table = Rc::new(RefCell::new(SymbolTable::new()));
let mut state = State::new(symbol_table);
let ast = parse(tokenize($string)).0.unwrap();
state.symbol_table_handle.borrow_mut().add_top_level_symbols(&ast);
let reduced = ast.reduce(&state.symbol_table_handle.borrow());
let all_output = state.evaluate(reduced, true);
let ref output = all_output.last().unwrap();
assert_eq!(**output, Ok($correct.to_string()));
}
}
#[test]
fn test_basic_eval() {
fresh_env!("1 + 2", "3");
fresh_env!("var a = 1; a = 2", "Unit");
fresh_env!("var a = 1; a = 2; a", "2");
fresh_env!(r#"("a", 1 + 2)"#, r#"("a", 3)"#);
}
#[test]
fn function_eval() {
fresh_env!("fn oi(x) { x + 1 }; oi(4)", "5");
fresh_env!("fn oi(x) { x + 1 }; oi(1+2)", "4");
}
#[test]
fn scopes() {
let scope_ok = r#"
const a = 20
fn haha() {
const a = 10
a
}
haha()
"#;
fresh_env!(scope_ok, "10");
let scope_ok = r#"
const a = 20
fn haha() {
const a = 10
a
}
a
"#;
fresh_env!(scope_ok, "20");
}
}