//! This module implements a compiler for compiling the rnix AST
//! representation to Tvix bytecode.
//!
//! A note on `unwrap()`: This module contains a lot of calls to
//! `unwrap()` or `expect(...)` on data structures returned by `rnix`.
//! The reason for this is that rnix uses the same data structures to
//! represent broken and correct ASTs, so all typed AST variants have
//! the ability to represent an incorrect node.
//!
//! However, at the time that the AST is passed to the compiler we
//! have verified that `rnix` considers the code to be correct, so all
//! variants are filed. In cases where the invariant is guaranteed by
//! the code in this module, `debug_assert!` has been used to catch
//! mistakes early during development.
use crate::chunk::Chunk;
use crate::errors::EvalResult;
use crate::opcode::{CodeIdx, OpCode};
use crate::value::Value;
use rnix;
use rnix::types::{BinOpKind, EntryHolder, TokenWrapper, TypedNode, Wrapper};
struct Compiler {
chunk: Chunk,
}
impl Compiler {
fn compile(&mut self, node: rnix::SyntaxNode) -> EvalResult<()> {
match node.kind() {
// Root of a file contains no content, it's just a marker
// type.
rnix::SyntaxKind::NODE_ROOT => self.compile(node.first_child().expect("TODO")),
// Literals contain a single token comprising of the
// literal itself.
rnix::SyntaxKind::NODE_LITERAL => {
let value = rnix::types::Value::cast(node).unwrap();
self.compile_literal(value.to_value().expect("TODO"))
}
rnix::SyntaxKind::NODE_STRING => {
let op = rnix::types::Str::cast(node).unwrap();
self.compile_string(op)
}
// The interpolation node is just a wrapper around the
// inner value of a fragment, it only requires unwrapping.
rnix::SyntaxKind::NODE_STRING_INTERPOL => {
self.compile(node.first_child().expect("TODO (should not be possible)"))
}
rnix::SyntaxKind::NODE_BIN_OP => {
let op = rnix::types::BinOp::cast(node).expect("TODO (should not be possible)");
self.compile_binop(op)
}
rnix::SyntaxKind::NODE_UNARY_OP => {
let op = rnix::types::UnaryOp::cast(node).expect("TODO: (should not be possible)");
self.compile_unary_op(op)
}
rnix::SyntaxKind::NODE_PAREN => {
let node = rnix::types::Paren::cast(node).unwrap();
self.compile(node.inner().unwrap())
}
rnix::SyntaxKind::NODE_IDENT => {
let node = rnix::types::Ident::cast(node).unwrap();
self.compile_ident(node)
}
rnix::SyntaxKind::NODE_ATTR_SET => {
let node = rnix::types::AttrSet::cast(node).unwrap();
self.compile_attr_set(node)
}
rnix::SyntaxKind::NODE_LIST => {
let node = rnix::types::List::cast(node).unwrap();
self.compile_list(node)
}
rnix::SyntaxKind::NODE_IF_ELSE => {
let node = rnix::types::IfElse::cast(node).unwrap();
self.compile_if_else(node)
}
kind => {
println!("visiting unsupported node: {:?}", kind);
Ok(())
}
}
}
fn compile_literal(&mut self, value: rnix::value::Value) -> EvalResult<()> {
match value {
rnix::NixValue::Float(f) => {
let idx = self.chunk.add_constant(Value::Float(f));
self.chunk.add_op(OpCode::OpConstant(idx));
Ok(())
}
rnix::NixValue::Integer(i) => {
let idx = self.chunk.add_constant(Value::Integer(i));
self.chunk.add_op(OpCode::OpConstant(idx));
Ok(())
}
rnix::NixValue::String(_) => todo!(),
rnix::NixValue::Path(_, _) => todo!(),
}
}
fn compile_string(&mut self, string: rnix::types::Str) -> EvalResult<()> {
let mut count = 0;
// The string parts are produced in literal order, however
// they need to be reversed on the stack in order to
// efficiently create the real string in case of
// interpolation.
for part in string.parts().into_iter().rev() {
count += 1;
match part {
// Interpolated expressions are compiled as normal and
// dealt with by the VM before being assembled into
// the final string.
rnix::StrPart::Ast(node) => self.compile(node)?,
rnix::StrPart::Literal(lit) => {
let idx = self.chunk.add_constant(Value::String(lit.into()));
self.chunk.add_op(OpCode::OpConstant(idx));
}
}
}
if count != 1 {
self.chunk.add_op(OpCode::OpInterpolate(count));
}
Ok(())
}
fn compile_binop(&mut self, op: rnix::types::BinOp) -> EvalResult<()> {
// Short-circuiting logical operators, which are under the
// same node type as NODE_BIN_OP, but need to be handled
// separately (i.e. before compiling the expressions used for
// standard binary operators).
match op.operator().unwrap() {
BinOpKind::And => return self.compile_and(op),
BinOpKind::Or => return self.compile_or(op),
BinOpKind::Implication => return self.compile_implication(op),
_ => {}
};
self.compile(op.lhs().unwrap())?;
self.compile(op.rhs().unwrap())?;
match op.operator().unwrap() {
BinOpKind::Add => self.chunk.add_op(OpCode::OpAdd),
BinOpKind::Sub => self.chunk.add_op(OpCode::OpSub),
BinOpKind::Mul => self.chunk.add_op(OpCode::OpMul),
BinOpKind::Div => self.chunk.add_op(OpCode::OpDiv),
BinOpKind::Update => self.chunk.add_op(OpCode::OpAttrsUpdate),
BinOpKind::Equal => self.chunk.add_op(OpCode::OpEqual),
BinOpKind::Less => self.chunk.add_op(OpCode::OpLess),
BinOpKind::LessOrEq => self.chunk.add_op(OpCode::OpLessOrEq),
BinOpKind::More => self.chunk.add_op(OpCode::OpMore),
BinOpKind::MoreOrEq => self.chunk.add_op(OpCode::OpMoreOrEq),
BinOpKind::Concat => self.chunk.add_op(OpCode::OpConcat),
BinOpKind::NotEqual => {
self.chunk.add_op(OpCode::OpEqual);
self.chunk.add_op(OpCode::OpInvert)
}
BinOpKind::IsSet => todo!("? operator"),
// Handled by separate branch above.
BinOpKind::And | BinOpKind::Implication | BinOpKind::Or => unreachable!(),
};
Ok(())
}
fn compile_unary_op(&mut self, op: rnix::types::UnaryOp) -> EvalResult<()> {
self.compile(op.value().unwrap())?;
use rnix::types::UnaryOpKind;
let opcode = match op.operator() {
UnaryOpKind::Invert => OpCode::OpInvert,
UnaryOpKind::Negate => OpCode::OpNegate,
};
self.chunk.add_op(opcode);
Ok(())
}
fn compile_ident(&mut self, node: rnix::types::Ident) -> EvalResult<()> {
match node.as_str() {
// TODO(tazjin): Nix technically allows code like
//
// let null = 1; in null
// => 1
//
// which we do *not* want to check at runtime. Once
// scoping is introduced, the compiler should carry some
// optimised information about any "weird" stuff that's
// happened to the scope (such as overrides of these
// literals, or builtins).
"true" => self.chunk.add_op(OpCode::OpTrue),
"false" => self.chunk.add_op(OpCode::OpFalse),
"null" => self.chunk.add_op(OpCode::OpNull),
_ => todo!("identifier access"),
};
Ok(())
}
// Compile attribute set literals into equivalent bytecode.
//
// This is complicated by a number of features specific to Nix
// attribute sets, most importantly:
//
// 1. Keys can be dynamically constructed through interpolation.
// 2. Keys can refer to nested attribute sets.
// 3. Attribute sets can (optionally) be recursive.
fn compile_attr_set(&mut self, node: rnix::types::AttrSet) -> EvalResult<()> {
if node.recursive() {
todo!("recursive attribute sets are not yet implemented")
}
let mut count = 0;
for kv in node.entries() {
count += 1;
// Because attribute set literals can contain nested keys,
// there is potentially more than one key fragment. If
// this is the case, a special operation to construct a
// runtime value representing the attribute path is
// emitted.
let mut key_count = 0;
for fragment in kv.key().unwrap().path() {
key_count += 1;
match fragment.kind() {
rnix::SyntaxKind::NODE_IDENT => {
let ident = rnix::types::Ident::cast(fragment).unwrap();
// TODO(tazjin): intern!
let idx = self
.chunk
.add_constant(Value::String(ident.as_str().to_string().into()));
self.chunk.add_op(OpCode::OpConstant(idx));
}
// For all other expression types, we simply
// compile them as normal. The operation should
// result in a string value, which is checked at
// runtime on construction.
_ => self.compile(fragment)?,
}
}
// We're done with the key if there was only one fragment,
// otherwise we need to emit an instruction to construct
// the attribute path.
if key_count > 1 {
self.chunk.add_op(OpCode::OpAttrPath(2));
}
// The value is just compiled as normal so that its
// resulting value is on the stack when the attribute set
// is constructed at runtime.
self.compile(kv.value().unwrap())?;
}
self.chunk.add_op(OpCode::OpAttrs(count));
Ok(())
}
// Compile list literals into equivalent bytecode. List
// construction is fairly simple, composing of pushing code for
// each literal element and an instruction with the element count.
//
// The VM, after evaluating the code for each element, simply
// constructs the list from the given number of elements.
fn compile_list(&mut self, node: rnix::types::List) -> EvalResult<()> {
let mut count = 0;
for item in node.items() {
count += 1;
self.compile(item)?;
}
self.chunk.add_op(OpCode::OpList(count));
Ok(())
}
// Compile conditional expressions using jumping instructions in the VM.
//
// ┌────────────────────┐
// │ 0 [ conditional ] │
// │ 1 JUMP_IF_FALSE →┼─┐
// │ 2 [ main body ] │ │ Jump to else body if
// ┌┼─3─← JUMP │ │ condition is false.
// Jump over else body ││ 4 [ else body ]←┼─┘
// if condition is true.└┼─5─→ ... │
// └────────────────────┘
fn compile_if_else(&mut self, node: rnix::types::IfElse) -> EvalResult<()> {
self.compile(node.condition().unwrap())?;
let then_idx = self.chunk.add_op(OpCode::OpJumpIfFalse(0));
self.chunk.add_op(OpCode::OpPop); // discard condition value
self.compile(node.body().unwrap())?;
let else_idx = self.chunk.add_op(OpCode::OpJump(0));
self.patch_jump(then_idx); // patch jump *to* else_body
self.chunk.add_op(OpCode::OpPop); // discard condition value
self.compile(node.else_body().unwrap())?;
self.patch_jump(else_idx); // patch jump *over* else body
Ok(())
}
fn compile_and(&mut self, node: rnix::types::BinOp) -> EvalResult<()> {
debug_assert!(
matches!(node.operator(), Some(BinOpKind::And)),
"compile_and called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack.
self.compile(node.lhs().unwrap())?;
// If this value is false, jump over the right-hand side - the
// whole expression is false.
let end_idx = self.chunk.add_op(OpCode::OpJumpIfFalse(0));
// Otherwise, remove the previous value and leave the
// right-hand side on the stack. Its result is now the value
// of the whole expression.
self.chunk.add_op(OpCode::OpPop);
self.compile(node.rhs().unwrap())?;
self.patch_jump(end_idx);
Ok(())
}
fn compile_or(&mut self, node: rnix::types::BinOp) -> EvalResult<()> {
debug_assert!(
matches!(node.operator(), Some(BinOpKind::Or)),
"compile_or called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack
self.compile(node.lhs().unwrap())?;
// Opposite of above: If this value is **true**, we can
// short-circuit the right-hand side.
let end_idx = self.chunk.add_op(OpCode::OpJumpIfTrue(0));
self.chunk.add_op(OpCode::OpPop);
self.compile(node.rhs().unwrap())?;
self.patch_jump(end_idx);
Ok(())
}
fn compile_implication(&mut self, node: rnix::types::BinOp) -> EvalResult<()> {
debug_assert!(
matches!(node.operator(), Some(BinOpKind::Implication)),
"compile_implication called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack and invert it.
self.compile(node.lhs().unwrap())?;
self.chunk.add_op(OpCode::OpInvert);
// Exactly as `||` (because `a -> b` = `!a || b`).
let end_idx = self.chunk.add_op(OpCode::OpJumpIfTrue(0));
self.chunk.add_op(OpCode::OpPop);
self.compile(node.rhs().unwrap())?;
self.patch_jump(end_idx);
Ok(())
}
fn patch_jump(&mut self, idx: CodeIdx) {
let offset = self.chunk.code.len() - 1 - idx.0;
match &mut self.chunk.code[idx.0] {
OpCode::OpJump(n) | OpCode::OpJumpIfFalse(n) | OpCode::OpJumpIfTrue(n) => {
*n = offset;
}
op => panic!("attempted to patch unsupported op: {:?}", op),
}
}
}
pub fn compile(ast: rnix::AST) -> EvalResult<Chunk> {
let mut c = Compiler {
chunk: Chunk::default(),
};
c.compile(ast.node())?;
Ok(c.chunk)
}