Conlang/cl-interpret/src/interpret.rs

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//! A work-in-progress tree walk interpreter for Conlang
//!
//! Currently, major parts of the interpreter are not yet implemented, and major parts will never be
//! implemented in its current form. Namely, since no [ConValue] has a stable location, it's
//! meaningless to get a pointer to one, and would be undefined behavior to dereference a pointer to
//! one in any situation.
use super::*;
use cl_ast::*;
/// A work-in-progress tree walk interpreter for Conlang
pub trait Interpret {
/// Interprets this thing in the given [`Environment`].
///
/// Everything returns a value!™
fn interpret(&self, env: &mut Environment) -> IResult<ConValue>;
}
impl Interpret for File {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
for item in &self.items {
item.interpret(env)?;
}
Ok(ConValue::Empty)
}
}
impl Interpret for Item {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
match &self.kind {
ItemKind::Alias(item) => item.interpret(env),
ItemKind::Const(item) => item.interpret(env),
ItemKind::Static(item) => item.interpret(env),
ItemKind::Module(item) => item.interpret(env),
ItemKind::Function(item) => item.interpret(env),
ItemKind::Struct(item) => item.interpret(env),
ItemKind::Enum(item) => item.interpret(env),
ItemKind::Impl(item) => item.interpret(env),
}
}
}
impl Interpret for Alias {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("Interpret type alias in {env}")
}
}
impl Interpret for Const {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("interpret const in {env}")
}
}
impl Interpret for Static {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("interpret static in {env}")
}
}
impl Interpret for Module {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
// TODO: Enter this module's namespace
match &self.kind {
ModuleKind::Inline(file) => file.interpret(env),
ModuleKind::Outline => todo!("Load and parse external files"),
}
}
}
impl Interpret for Function {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
// register the function in the current environment
env.insert_fn(self);
Ok(ConValue::Empty)
}
}
impl Interpret for Struct {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("Interpret structs in {env}")
}
}
impl Interpret for Enum {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("Interpret enums in {env}")
}
}
impl Interpret for Impl {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("Enter a struct's namespace and insert function definitions into it in {env}");
}
}
impl Interpret for Stmt {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { extents: _, kind, semi } = self;
let out = match kind {
StmtKind::Empty => ConValue::Empty,
StmtKind::Local(stmt) => stmt.interpret(env)?,
StmtKind::Item(stmt) => stmt.interpret(env)?,
StmtKind::Expr(stmt) => stmt.interpret(env)?,
};
Ok(match semi {
Semi::Terminated => ConValue::Empty,
Semi::Unterminated => out,
})
}
}
impl Interpret for Let {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Let { mutable: _, name: Identifier(name), ty: _, init } = self;
let init = init.as_ref().map(|i| i.interpret(env)).transpose()?;
env.insert(name, init);
Ok(ConValue::Empty)
}
}
impl Interpret for Expr {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { extents: _, kind } = self;
match kind {
ExprKind::Assign(v) => v.interpret(env),
ExprKind::Binary(v) => v.interpret(env),
ExprKind::Unary(v) => v.interpret(env),
ExprKind::Member(v) => v.interpret(env),
ExprKind::Call(v) => v.interpret(env),
ExprKind::Index(v) => v.interpret(env),
ExprKind::Path(v) => v.interpret(env),
ExprKind::Literal(v) => v.interpret(env),
ExprKind::Array(v) => v.interpret(env),
ExprKind::ArrayRep(v) => v.interpret(env),
ExprKind::AddrOf(v) => v.interpret(env),
ExprKind::Block(v) => v.interpret(env),
ExprKind::Empty => Ok(ConValue::Empty),
ExprKind::Group(v) => v.interpret(env),
ExprKind::Tuple(v) => v.interpret(env),
ExprKind::While(v) => v.interpret(env),
ExprKind::If(v) => v.interpret(env),
ExprKind::For(v) => v.interpret(env),
ExprKind::Break(v) => v.interpret(env),
ExprKind::Return(v) => v.interpret(env),
ExprKind::Continue(v) => v.interpret(env),
}
}
}
impl Interpret for Assign {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Assign { head, op, tail } = self;
// Resolve the head pattern
let head = match &head.kind {
ExprKind::Path(Path { parts, .. }) if parts.len() == 1 => {
match parts.last().expect("parts should not be empty") {
PathPart::SuperKw => Err(Error::NotAssignable(head.extents.head))?,
PathPart::SelfKw => todo!("Assignment to `self`"),
PathPart::Ident(Identifier(s)) => s,
}
}
ExprKind::Member(_) => todo!("Member access assignment"),
ExprKind::Call(_) => todo!("Assignment to the result of a function call?"),
ExprKind::Index(_) => todo!("Assignment to an index operation"),
ExprKind::Path(_) => todo!("Path expression resolution (IMPORTANT)"),
ExprKind::Empty | ExprKind::Group(_) | ExprKind::Tuple(_) => {
todo!("Pattern Destructuring?")
}
_ => Err(Error::NotAssignable(head.extents.head))?,
};
// Get the initializer and the tail
let init = tail.interpret(env)?;
let target = env.get_mut(head)?;
if let AssignKind::Plain = op {
use std::mem::discriminant as variant;
// runtime typecheck
match target {
Some(value) if variant(value) == variant(&init) => {
*value = init;
}
value @ None => *value = Some(init),
_ => Err(Error::TypeError)?,
}
return Ok(ConValue::Empty);
}
let Some(target) = target else {
return Err(Error::NotInitialized(head.into()));
};
match op {
AssignKind::Add => target.add_assign(init)?,
AssignKind::Sub => target.sub_assign(init)?,
AssignKind::Mul => target.mul_assign(init)?,
AssignKind::Div => target.div_assign(init)?,
AssignKind::Rem => target.rem_assign(init)?,
AssignKind::And => target.bitand_assign(init)?,
AssignKind::Or => target.bitor_assign(init)?,
AssignKind::Xor => target.bitxor_assign(init)?,
AssignKind::Shl => target.shl_assign(init)?,
AssignKind::Shr => target.shr_assign(init)?,
_ => (),
}
Ok(ConValue::Empty)
}
}
impl Interpret for Binary {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Binary { head, tail } = self;
let mut head = head.interpret(env)?;
// Short-circuiting ops
for (op, tail) in tail {
match op {
BinaryKind::LogAnd => {
if head.truthy()? {
head = tail.interpret(env)?;
continue;
}
return Ok(head); // Short circuiting
}
BinaryKind::LogOr => {
if !head.truthy()? {
head = tail.interpret(env)?;
continue;
}
return Ok(head); // Short circuiting
}
BinaryKind::LogXor => {
head = ConValue::Bool(head.truthy()? ^ tail.interpret(env)?.truthy()?);
continue;
}
_ => {}
}
let tail = tail.interpret(env)?;
head = match op {
BinaryKind::Mul => env.call("mul", &[head, tail]),
BinaryKind::Div => env.call("div", &[head, tail]),
BinaryKind::Rem => env.call("rem", &[head, tail]),
BinaryKind::Add => env.call("add", &[head, tail]),
BinaryKind::Sub => env.call("sub", &[head, tail]),
BinaryKind::Shl => env.call("shl", &[head, tail]),
BinaryKind::Shr => env.call("shr", &[head, tail]),
BinaryKind::BitAnd => env.call("and", &[head, tail]),
BinaryKind::BitOr => env.call("or", &[head, tail]),
BinaryKind::BitXor => env.call("xor", &[head, tail]),
BinaryKind::RangeExc => env.call("range_exc", &[head, tail]),
BinaryKind::RangeInc => env.call("range_inc", &[head, tail]),
BinaryKind::Lt => env.call("lt", &[head, tail]),
BinaryKind::LtEq => env.call("lt_eq", &[head, tail]),
BinaryKind::Equal => env.call("eq", &[head, tail]),
BinaryKind::NotEq => env.call("neq", &[head, tail]),
BinaryKind::GtEq => env.call("gt_eq", &[head, tail]),
BinaryKind::Gt => env.call("gt", &[head, tail]),
BinaryKind::Dot => todo!("search within a type's namespace!"),
_ => Ok(head),
}?;
}
Ok(head)
}
}
impl Interpret for Unary {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Unary { tail, ops } = self;
let mut operand = tail.interpret(env)?;
for op in ops.iter().rev() {
operand = match op {
UnaryKind::Deref => env.call("deref", &[operand])?,
UnaryKind::Neg => env.call("neg", &[operand])?,
UnaryKind::Not => env.call("not", &[operand])?,
UnaryKind::At => {
println!("{operand}");
operand
}
UnaryKind::Tilde => unimplemented!("Tilde operator"),
};
}
Ok(operand)
}
}
impl Interpret for Member {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
todo!("Interpret member accesses in {env}")
}
}
impl Interpret for Call {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { callee, args } = self;
// evaluate the callee
let mut callee = callee.interpret(env)?;
for args in args {
let ConValue::Tuple(args) = args.interpret(env)? else {
Err(Error::TypeError)?
};
callee = callee.call(env, &args)?;
}
Ok(callee)
}
}
impl Interpret for Index {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { head, indices } = self;
let mut head = head.interpret(env)?;
for indices in indices {
let Indices { exprs } = indices;
for index in exprs {
head = head.index(&index.interpret(env)?)?;
}
}
Ok(head)
}
}
impl Interpret for Path {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { absolute: _, parts } = self;
if parts.len() == 1 {
match parts.last().expect("parts should not be empty") {
PathPart::SuperKw | PathPart::SelfKw => todo!("Path navigation"),
PathPart::Ident(Identifier(s)) => env.get(s).cloned(),
}
} else {
todo!("Path navigation!")
}
}
}
impl Interpret for Literal {
fn interpret(&self, _env: &mut Environment) -> IResult<ConValue> {
Ok(match self {
Literal::String(value) => ConValue::from(value.as_str()),
Literal::Char(value) => ConValue::Char(*value),
Literal::Bool(value) => ConValue::Bool(*value),
// Literal::Float(value) => todo!("Float values in interpreter: {value:?}"),
Literal::Int(value) => ConValue::Int(*value as _),
})
}
}
impl Interpret for Array {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { values } = self;
let mut out = vec![];
for expr in values {
out.push(expr.interpret(env)?)
}
Ok(ConValue::Array(out))
}
}
impl Interpret for ArrayRep {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { value, repeat } = self;
let repeat = match repeat.interpret(env)? {
ConValue::Int(v) => v,
_ => Err(Error::TypeError)?,
};
let value = value.interpret(env)?;
Ok(ConValue::Array(vec![value; repeat as usize]))
}
}
impl Interpret for AddrOf {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { count: _, mutable: _, expr } = self;
// this is stupid
todo!("Create reference\nfrom expr: {expr}\nin env:\n{env}\n")
}
}
impl Interpret for Block {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { stmts } = self;
let mut env = env.frame("block");
let mut out = ConValue::Empty;
for stmt in stmts {
out = stmt.interpret(&mut env)?;
}
Ok(out)
}
}
impl Interpret for Group {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { expr } = self;
expr.interpret(env)
}
}
impl Interpret for Tuple {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { exprs } = self;
Ok(ConValue::Tuple(exprs.iter().try_fold(
vec![],
|mut out, element| {
out.push(element.interpret(env)?);
Ok(out)
},
)?))
}
}
impl Interpret for While {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { cond, pass, fail } = self;
while cond.interpret(env)?.truthy()? {
match pass.interpret(env) {
Err(Error::Break(value)) => return Ok(value),
Err(Error::Continue) => continue,
e => e?,
};
}
fail.interpret(env)
}
}
impl Interpret for If {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { cond, pass, fail } = self;
if cond.interpret(env)?.truthy()? {
pass.interpret(env)
} else {
fail.interpret(env)
}
}
}
impl Interpret for For {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { bind: Identifier(name), cond, pass, fail } = self;
// TODO: A better iterator model
let bounds = match cond.interpret(env)? {
ConValue::RangeExc(a, b) => a..=b,
ConValue::RangeInc(a, b) => a..=b,
_ => Err(Error::TypeError)?,
};
{
let mut env = env.frame("loop variable");
for loop_var in bounds {
env.insert(name, Some(loop_var.into()));
match pass.interpret(&mut env) {
Err(Error::Break(value)) => return Ok(value),
Err(Error::Continue) => continue,
result => result?,
};
}
}
fail.interpret(env)
}
}
impl Interpret for Else {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { body } = self;
match body {
Some(body) => body.interpret(env),
None => Ok(ConValue::Empty),
}
}
}
impl Interpret for Continue {
fn interpret(&self, _env: &mut Environment) -> IResult<ConValue> {
Err(Error::Continue)
}
}
impl Interpret for Return {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { body } = self;
Err(Error::Return(
body.as_ref()
.map(|body| body.interpret(env))
.unwrap_or(Ok(ConValue::Empty))?,
))
}
}
impl Interpret for Break {
fn interpret(&self, env: &mut Environment) -> IResult<ConValue> {
let Self { body } = self;
Err(Error::Break(
body.as_ref()
.map(|body| body.interpret(env))
.unwrap_or(Ok(ConValue::Empty))?,
))
}
}