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interpreter: Prototype interpreter

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TODO: Type-checking, floats, variables & scope
TODO Later: A bytecode interpreter
This commit is contained in:
John 2023-10-26 14:48:44 -05:00
parent 9ab9583a5b
commit 15a3d265df
4 changed files with 584 additions and 5 deletions
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77
libconlang/examples/interpret.rs Normal file
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//! This example grabs input from stdin or a file, lexes it, parses it, and interprets it
use conlang::{interpreter::Interpreter, lexer::Lexer, parser::Parser};
use std::{
error::Error,
io::{stdin, stdout, IsTerminal, Write},
path::{Path, PathBuf},
};
fn main() -> Result<(), Box<dyn Error>> {
let conf = Config::new();
if conf.paths.is_empty() {
take_stdin()?;
} else {
for path in conf.paths.iter().map(PathBuf::as_path) {
parse(&std::fs::read_to_string(path)?, Some(path))?;
}
}
Ok(())
}
struct Config {
paths: Vec<PathBuf>,
}
impl Config {
fn new() -> Self {
Config { paths: std::env::args().skip(1).map(PathBuf::from).collect() }
}
}
fn take_stdin() -> Result<(), Box<dyn Error>> {
const PROMPT: &str = "> ";
if stdin().is_terminal() {
print!("{PROMPT}");
stdout().flush()?;
for line in stdin().lines() {
let line = line?;
if !line.is_empty() {
let _ = run(&line).map_err(|e| eprintln!("{e}"));
println!();
}
print!("{PROMPT}");
stdout().flush()?;
}
} else {
parse(&std::io::read_to_string(stdin())?, None)?
}
Ok(())
}
fn parse(file: &str, path: Option<&Path>) -> Result<(), Box<dyn Error>> {
match Parser::from(Lexer::new(file)).parse() {
Ok(ast) => Interpreter::new().interpret(&ast)?,
Err(e) if e.start().is_some() => print!("{:?}:{}", path.unwrap_or(Path::new("-")), e),
Err(e) => print!("{e}"),
}
println!();
Ok(())
}
fn run(file: &str) -> Result<(), Box<dyn Error>> {
let mut interpreter = Interpreter::new();
// If it parses successfully as a program, run the program
match Parser::from(Lexer::new(file)).parse() {
Ok(ast) => interpreter.interpret(&ast)?,
Err(e) => {
// If not, re-parse as an expression, and print the stack
let Ok(expr) = Parser::from(Lexer::new(file)).parse_expr() else {
Err(e)?
};
for value in interpreter.eval(&expr)? {
println!("{value}");
}
}
}
Ok(())
}

504
libconlang/src/interpreter.rs Normal file
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//! Interprets an AST as a program
use crate::ast::preamble::*;
use error::{Error, IResult, Reason};
use temp_type_impl::ConValue;
pub mod temp_type_impl {
//! Temporary implementations of Conlang values until I'm able to
use super::error::{Error, IResult, Reason};
use std::ops::*;
/// A Conlang value
///
/// This is a hack to work around the fact that Conlang doesn't have a functioning type system
/// yet :(
#[derive(Clone, Debug)]
pub enum ConValue {
/// The empty/unit `()` type
Empty,
/// An integer
Int(i128),
/// A boolean
Bool(bool),
/// A unicode character
Char(char),
/// A string
String(String),
}
impl ConValue {
/// Gets whether the current value is true or false
pub fn truthy(&self) -> IResult<bool> {
match self {
ConValue::Bool(v) => Ok(*v),
_ => Err(Error::with_reason(Reason::TypeError))?,
}
}
cmp! {
lt: false, <;
lt_eq: true, <=;
eq: true, ==;
neq: false, !=;
gt_eq: true, >=;
gt: false, >;
}
}
/// Templates comparison functions for [ConValue]
macro cmp ($($fn:ident: $empty:literal, $op:tt);*$(;)?) {$(
/// TODO: Remove when functions are implemented:
/// Desugar into function calls
pub fn $fn(&self, other: &Self) -> IResult<Self> {
match (self, other) {
(Self::Empty, Self::Empty) => Ok(Self::Bool($empty)),
(Self::Int(a), Self::Int(b)) => Ok(Self::Bool(a $op b)),
(Self::Bool(a), Self::Bool(b)) => Ok(Self::Bool(a $op b)),
(Self::Char(a), Self::Char(b)) => Ok(Self::Bool(a $op b)),
(Self::String(a), Self::String(b)) => Ok(Self::Bool(a $op b)),
_ => Err(Error::with_reason(Reason::TypeError))
}
}
)*}
/// Implements [From] for an enum with 1-tuple variants
macro from ($($T:ty => $v:expr),*$(,)?) {
$(impl From<$T> for ConValue {
fn from(value: $T) -> Self { $v(value.into()) }
})*
}
from! {
i128 => ConValue::Int,
bool => ConValue::Bool,
char => ConValue::Char,
&str => ConValue::String,
String => ConValue::String,
}
impl From<()> for ConValue {
fn from(_: ()) -> Self {
Self::Empty
}
}
/// Implements binary [std::ops] traits for [ConValue]
///
/// TODO: Desugar operators into function calls
macro ops($($trait:ty: $fn:ident = [$($match:tt)*])*) {
$(impl $trait for ConValue {
type Output = IResult<Self>;
/// TODO: Desugar operators into function calls
fn $fn(self, rhs: Self) -> Self::Output {Ok(match (self, rhs) {$($match)*})}
})*
}
ops! {
Add: add = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a + b),
(ConValue::String(a), ConValue::String(b)) => ConValue::String(a + &b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
BitAnd: bitand = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a & b),
(ConValue::Bool(a), ConValue::Bool(b)) => ConValue::Bool(a & b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
BitOr: bitor = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a | b),
(ConValue::Bool(a), ConValue::Bool(b)) => ConValue::Bool(a | b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
BitXor: bitxor = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a ^ b),
(ConValue::Bool(a), ConValue::Bool(b)) => ConValue::Bool(a ^ b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Div: div = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a / b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Mul: mul = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a * b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Rem: rem = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a % b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Shl: shl = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a << b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Shr: shr = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a >> b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
Sub: sub = [
(ConValue::Empty, ConValue::Empty) => ConValue::Empty,
(ConValue::Int(a), ConValue::Int(b)) => ConValue::Int(a - b),
_ => Err(Error::with_reason(Reason::TypeError))?
]
}
impl Neg for ConValue {
type Output = IResult<Self>;
fn neg(self) -> Self::Output {
Ok(match self {
ConValue::Empty => ConValue::Empty,
ConValue::Int(v) => ConValue::Int(-v),
_ => Err(Error::with_reason(Reason::TypeError))?,
})
}
}
impl Not for ConValue {
type Output = IResult<Self>;
fn not(self) -> Self::Output {
Ok(match self {
ConValue::Empty => ConValue::Empty,
ConValue::Int(v) => ConValue::Int(!v),
ConValue::Bool(v) => ConValue::Bool(!v),
_ => Err(Error::with_reason(Reason::TypeError))?,
})
}
}
impl std::fmt::Display for ConValue {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
ConValue::Empty => "Empty".fmt(f),
ConValue::Int(v) => v.fmt(f),
ConValue::Bool(v) => v.fmt(f),
ConValue::Char(v) => write!(f, "'{v}'"),
ConValue::String(v) => write!(f, "\"{v}\""),
}
}
}
}
/// A work-in-progress tree walk interpreter for Conlang
#[derive(Clone, Debug, Default)]
pub struct Interpreter {
stack: Vec<ConValue>,
}
impl Interpreter {
/// Creates a new [Interpreter]
pub fn new() -> Self {
Default::default()
}
/// Interprets the [Start] of a syntax tree
pub fn interpret(&mut self, start: &Start) -> IResult<()> {
self.visit(start)
}
/// Evaluates a single [Expression](expression::Expr)
pub fn eval(mut self, expr: &expression::Expr) -> IResult<Vec<ConValue>> {
self.visit_expr(expr)?;
Ok(self.stack)
}
fn push(&mut self, value: impl Into<ConValue>) {
self.stack.push(value.into())
}
fn peek(&mut self) -> IResult<&ConValue> {
self.stack
.last()
.ok_or(Error::with_reason(Reason::StackUnderflow))
}
fn pop(&mut self) -> IResult<ConValue> {
self.stack
.pop()
.ok_or(Error::with_reason(Reason::StackUnderflow))
}
fn pop_two(&mut self) -> IResult<(ConValue, ConValue)> {
Ok((self.pop()?, self.pop()?))
}
}
impl Visitor<IResult<()>> for Interpreter {
fn visit_program(&mut self, prog: &Program) -> IResult<()> {
for stmt in &prog.0 {
self.visit_statement(stmt)?;
}
Ok(())
}
fn visit_statement(&mut self, stmt: &Stmt) -> IResult<()> {
match stmt {
Stmt::Let { name, mutable, ty, init } => todo!(
"let{} {name:?}: {ty:?} = {init:?}",
if *mutable { " mut" } else { "" }
),
Stmt::Expr(e) => {
self.visit_expr(e)?;
self.pop().map(drop)
}
}
}
fn visit_operation(&mut self, expr: &math::Operation) -> IResult<()> {
use math::Operation;
// TODO: the indentation depth here is driving me insane.
// maybe refactor the ast to break binary and unary
// operations into their own nodes, and use
// Operation to unify them?
match expr {
Operation::Binary { first, other } => {
self.visit_operation(first)?;
for (op, other) in other {
match op {
operator::Binary::LogAnd => {
if self.peek()?.truthy()? {
self.pop()?;
self.visit_operation(other)?;
}
}
operator::Binary::LogOr => {
if !self.peek()?.truthy()? {
self.pop()?;
self.visit_operation(other)?;
}
}
operator::Binary::LogXor => {
let first = self.pop()?.truthy()?;
self.visit_operation(other)?;
let second = self.pop()?.truthy()?;
self.push(first ^ second);
}
_ => {
self.visit_operation(other)?;
self.visit_binary_op(op)?;
}
}
}
Ok(())
}
Operation::Unary { operators, operand } => {
self.visit_primary(operand)?;
for op in operators.iter().rev() {
self.visit_unary_op(op)?;
}
Ok(())
}
}
}
fn visit_binary_op(&mut self, op: &operator::Binary) -> IResult<()> {
use operator::Binary;
let (second, first) = self.pop_two()?;
self.push(match op {
Binary::Mul => first * second,
Binary::Div => first / second,
Binary::Rem => first % second,
Binary::Add => first + second,
Binary::Sub => first - second,
Binary::Lsh => first << second,
Binary::Rsh => first >> second,
Binary::BitAnd => first & second,
Binary::BitOr => first | second,
Binary::BitXor => first ^ second,
Binary::LogAnd | Binary::LogOr | Binary::LogXor => {
unimplemented!("Implemented in visit_operation")
}
Binary::RangeExc => todo!("Range expressions"),
Binary::RangeInc => todo!("Range expressions"),
Binary::Less => first.lt(&second),
Binary::LessEq => first.lt_eq(&second),
Binary::Equal => first.eq(&second),
Binary::NotEq => first.neq(&second),
Binary::GreaterEq => first.gt_eq(&second),
Binary::Greater => first.gt(&second),
Binary::Assign => todo!("Assignment"),
Binary::AddAssign => todo!("Assignment"),
Binary::SubAssign => todo!("Assignment"),
Binary::MulAssign => todo!("Assignment"),
Binary::DivAssign => todo!("Assignment"),
Binary::RemAssign => todo!("Assignment"),
Binary::BitAndAssign => todo!("Assignment"),
Binary::BitOrAssign => todo!("Assignment"),
Binary::BitXorAssign => todo!("Assignment"),
Binary::ShlAssign => todo!("Assignment"),
Binary::ShrAssign => todo!("Assignment"),
}?);
Ok(())
}
fn visit_unary_op(&mut self, op: &operator::Unary) -> IResult<()> {
let operand = self.pop()?;
self.push(match op {
operator::Unary::RefRef => todo!(),
operator::Unary::Ref => todo!(),
operator::Unary::Deref => todo!(),
operator::Unary::Neg => (-operand)?,
operator::Unary::Not => (!operand)?,
operator::Unary::At => todo!(),
operator::Unary::Hash => {
println!("{operand}");
operand
}
operator::Unary::Tilde => todo!(),
});
Ok(())
}
fn visit_if(&mut self, expr: &control::If) -> IResult<()> {
self.visit_expr(&expr.cond)?;
if self.pop()?.truthy()? {
self.visit_block(&expr.body)?;
} else if let Some(block) = &expr.else_ {
self.visit_else(block)?;
}
Ok(())
}
fn visit_while(&mut self, expr: &control::While) -> IResult<()> {
let mut broke = false;
while {
self.visit_expr(&expr.cond)?;
self.pop()?.truthy()?
} {
let Err(out) = self.visit_block(&expr.body) else {
continue;
};
match out.reason() {
Reason::Continue => continue,
Reason::Break(value) => {
self.push(value);
broke = true;
break;
}
r => Err(Error::with_reason(r))?,
}
}
if let (Some(r#else), false) = (&expr.else_, broke) {
self.visit_else(r#else)?;
}
Ok(())
}
fn visit_for(&mut self, expr: &control::For) -> IResult<()> {
todo!("Visit for: {expr:?}")
}
fn visit_else(&mut self, else_: &control::Else) -> IResult<()> {
self.visit_block(&else_.block)
}
fn visit_continue(&mut self, _: &control::Continue) -> IResult<()> {
Err(Error::cnt())
}
fn visit_break(&mut self, brk: &control::Break) -> IResult<()> {
Err(Error::brk({
self.visit_expr(&brk.expr)?;
self.pop()?
}))
}
fn visit_return(&mut self, ret: &control::Return) -> IResult<()> {
Err(Error::ret({
self.visit_expr(&ret.expr)?;
self.pop()?
}))
}
fn visit_identifier(&mut self, ident: &Identifier) -> IResult<()> {
todo!("Identifier lookup and scoping rules: {ident:?}")
}
fn visit_string_literal(&mut self, string: &str) -> IResult<()> {
self.push(string);
Ok(())
}
fn visit_char_literal(&mut self, char: &char) -> IResult<()> {
self.push(*char);
Ok(())
}
fn visit_bool_literal(&mut self, bool: &bool) -> IResult<()> {
self.push(*bool);
Ok(())
}
fn visit_float_literal(&mut self, float: &literal::Float) -> IResult<()> {
todo!("visit floats in interpreter: {float:?}")
}
fn visit_int_literal(&mut self, int: &u128) -> IResult<()> {
self.push((*int) as i128);
Ok(())
}
fn visit_empty(&mut self) -> IResult<()> {
self.push(());
Ok(())
}
}
pub mod error {
//! The [Error] type represents any error thrown by the [Interpreter](super::Interpreter)
use super::temp_type_impl::ConValue;
pub type IResult<T> = Result<T, Error>;
/// Represents any error thrown by the [Interpreter](super::Interpreter)
#[derive(Clone, Debug)]
pub struct Error {
reason: Reason,
}
impl Error {
/// Returns the [Reason] for this error
pub fn reason(self) -> Reason {
self.reason
}
/// Creates an error with a given [Reason]
pub(crate) fn with_reason(reason: Reason) -> Self {
Self { reason }
}
/// Creates a [Return](Reason::Return) error, with the given [value](ConValue)
pub fn ret(value: ConValue) -> Self {
Self { reason: Reason::Return(value) }
}
/// Creates a [Break](Reason::Break) error, with the given [value](ConValue)
pub fn brk(value: ConValue) -> Self {
Self { reason: Reason::Break(value) }
}
/// Creates a [Continue](Reason::Continue) error
pub fn cnt() -> Self {
Self { reason: Reason::Continue }
}
}
/// The reason for the [Error]
#[derive(Clone, Debug)]
pub enum Reason {
/// Propagate a Return value
Return(ConValue),
/// Propagate a Break value
Break(ConValue),
/// Continue to the next iteration of a loop
Continue,
/// Underflowed the stack
StackUnderflow,
/// Type incompatibility
// TODO: store the type information in this error
TypeError,
}
impl std::error::Error for Error {}
impl std::fmt::Display for Error {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
self.reason.fmt(f)
}
}
impl std::fmt::Display for Reason {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
Reason::Return(value) => write!(f, "return {value:?}"),
Reason::Break(value) => write!(f, "break {value:?}"),
Reason::Continue => "continue".fmt(f),
Reason::StackUnderflow => "Stack underflow".fmt(f),
Reason::TypeError => "Type error".fmt(f),
}
}
}
}

6
libconlang/src/lib.rs
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@ -1,4 +1,4 @@
//! Conlang is an expression-based programming language with similarities to Rust //! Conlang is an expression-based programming language with similarities to Rust and Python
#![warn(clippy::all)] #![warn(clippy::all)]
#![feature(decl_macro)] #![feature(decl_macro)]
@ -12,9 +12,7 @@ pub mod parser;
pub mod pretty_printer; pub mod pretty_printer;
pub mod interpreter { pub mod interpreter;
//! Interprets an AST as a program
}
#[cfg(test)] #[cfg(test)]
mod tests; mod tests;

2
libconlang/src/parser.rs
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@ -69,7 +69,7 @@ pub mod error {
reason: Reason, reason: Reason,
start: Option<Token>, start: Option<Token>,
} }
impl std::error::Error for Error {}
impl Display for Error { impl Display for Error {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
if let Some(token) = &self.start { if let Some(token) = &self.start {