tvl-depot/tvix/eval/src/compiler/mod.rs

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//! 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 fulfilled. In cases where the invariant is guaranteed
//! by the code in this module, `debug_assert!` has been used to catch
//! mistakes early during development.
mod scope;
use path_clean::PathClean;
use rnix::ast::{self, AstToken, HasEntry};
use rowan::ast::AstNode;
use smol_str::SmolStr;
use std::collections::HashMap;
use std::path::{Path, PathBuf};
use std::rc::Rc;
use crate::chunk::Chunk;
use crate::errors::{Error, ErrorKind, EvalResult};
use crate::opcode::{CodeIdx, Count, JumpOffset, OpCode, UpvalueIdx};
use crate::value::{Closure, Lambda, Thunk, Value};
use crate::warnings::{EvalWarning, WarningKind};
use self::scope::{Local, LocalIdx, LocalPosition, Scope, Upvalue};
/// Represents the result of compiling a piece of Nix code. If
/// compilation was successful, the resulting bytecode can be passed
/// to the VM.
pub struct CompilationOutput {
pub lambda: Lambda,
pub warnings: Vec<EvalWarning>,
pub errors: Vec<Error>,
}
/// Represents the lambda currently being compiled.
struct LambdaCtx {
lambda: Lambda,
scope: Scope,
}
impl LambdaCtx {
fn new() -> Self {
LambdaCtx {
lambda: Lambda::new_anonymous(),
scope: Default::default(),
}
}
}
/// Alias for the map of globally available functions that should
/// implicitly be resolvable in the global scope.
type GlobalsMap = HashMap<&'static str, Rc<dyn Fn(&mut Compiler)>>;
struct Compiler<'code> {
contexts: Vec<LambdaCtx>,
warnings: Vec<EvalWarning>,
errors: Vec<Error>,
root_dir: PathBuf,
/// Carries all known global tokens; the full set of which is
/// created when the compiler is invoked.
///
/// Each global has an associated token, which when encountered as
/// an identifier is resolved against the scope poisoning logic,
/// and a function that should emit code for the token.
globals: GlobalsMap,
/// File reference in the codemap contains all known source code
/// and is used to track the spans from which instructions where
/// derived.
file: &'code codemap::File,
}
// Helper functions for emitting code and metadata to the internal
// structures of the compiler.
impl Compiler<'_> {
fn context(&self) -> &LambdaCtx {
&self.contexts[self.contexts.len() - 1]
}
fn context_mut(&mut self) -> &mut LambdaCtx {
let idx = self.contexts.len() - 1;
&mut self.contexts[idx]
}
fn chunk(&mut self) -> &mut Chunk {
&mut self.context_mut().lambda.chunk
}
fn scope(&self) -> &Scope {
&self.context().scope
}
fn scope_mut(&mut self) -> &mut Scope {
&mut self.context_mut().scope
}
/// Push a single instruction to the current bytecode chunk.
fn push_op_old(&mut self, data: OpCode) -> CodeIdx {
self.chunk().push_op_old(data)
}
/// Push a single instruction to the current bytecode chunk and
/// track the source span from which it was compiled.
fn push_op<T: AstNode>(&mut self, data: OpCode, node: &T) -> CodeIdx {
let span: codemap::Span = {
let rowan_span = node.syntax().text_range();
self.file.span.subspan(
u32::from(rowan_span.start()) as u64,
u32::from(rowan_span.end()) as u64,
)
};
self.chunk().push_op(data, span)
}
/// Emit a single constant to the current bytecode chunk.
fn emit_constant_old(&mut self, value: Value) {
let idx = self.chunk().push_constant(value);
self.push_op_old(OpCode::OpConstant(idx));
}
/// Emit a single constant to the current bytecode chunk and track
/// the source span from which it was compiled.
fn emit_constant<T: AstNode>(&mut self, value: Value, node: &T) {
let idx = self.chunk().push_constant(value);
self.push_op(OpCode::OpConstant(idx), node);
}
}
// Actual code-emitting AST traversal methods.
impl Compiler<'_> {
fn compile(&mut self, slot: Option<LocalIdx>, expr: ast::Expr) {
match expr {
ast::Expr::Literal(literal) => self.compile_literal(literal),
ast::Expr::Path(path) => self.compile_path(path),
ast::Expr::Str(s) => self.compile_str(slot, s),
ast::Expr::UnaryOp(op) => self.compile_unary_op(slot, op),
ast::Expr::BinOp(op) => self.compile_binop(slot, op),
ast::Expr::HasAttr(has_attr) => self.compile_has_attr(slot, has_attr),
ast::Expr::List(list) => self.compile_list(slot, list),
ast::Expr::AttrSet(attrs) => self.thunk(slot, move |c, s| c.compile_attr_set(s, attrs)),
ast::Expr::Select(select) => self.compile_select(slot, select),
ast::Expr::Assert(assert) => self.compile_assert(slot, assert),
ast::Expr::IfElse(if_else) => self.compile_if_else(slot, if_else),
ast::Expr::LetIn(let_in) => self.compile_let_in(slot, let_in),
ast::Expr::Ident(ident) => self.compile_ident(slot, ident),
ast::Expr::With(with) => self.compile_with(slot, with),
ast::Expr::Lambda(lambda) => self.compile_lambda(slot, lambda),
ast::Expr::Apply(apply) => self.compile_apply(slot, apply),
// Parenthesized expressions are simply unwrapped, leaving
// their value on the stack.
ast::Expr::Paren(paren) => self.compile(slot, paren.expr().unwrap()),
ast::Expr::LegacyLet(_) => todo!("legacy let"),
ast::Expr::Root(_) => unreachable!("there cannot be more than one root"),
ast::Expr::Error(_) => unreachable!("compile is only called on validated trees"),
}
}
fn compile_literal(&mut self, node: ast::Literal) {
match node.kind() {
ast::LiteralKind::Float(f) => {
self.emit_constant(Value::Float(f.value().unwrap()), &node);
}
ast::LiteralKind::Integer(i) => {
self.emit_constant(Value::Integer(i.value().unwrap()), &node);
}
ast::LiteralKind::Uri(u) => {
self.emit_warning(node.syntax().clone(), WarningKind::DeprecatedLiteralURL);
self.emit_constant(Value::String(u.syntax().text().into()), &node);
}
}
}
fn compile_path(&mut self, node: ast::Path) {
// TODO(tazjin): placeholder implementation while waiting for
// https://github.com/nix-community/rnix-parser/pull/96
let raw_path = node.to_string();
let path = if raw_path.starts_with('/') {
Path::new(&raw_path).to_owned()
} else if raw_path.starts_with('~') {
let mut buf = match dirs::home_dir() {
Some(buf) => buf,
None => {
self.emit_error(
node.syntax().clone(),
ErrorKind::PathResolution("failed to determine home directory".into()),
);
return;
}
};
buf.push(&raw_path);
buf
} else if raw_path.starts_with('.') {
let mut buf = self.root_dir.clone();
buf.push(&raw_path);
buf
} else {
// TODO: decide what to do with findFile
todo!("other path types (e.g. <...> lookups) not yet implemented")
};
// TODO: Use https://github.com/rust-lang/rfcs/issues/2208
// once it is available
let value = Value::Path(path.clean());
self.emit_constant(value, &node);
}
fn compile_str(&mut self, slot: Option<LocalIdx>, node: ast::Str) {
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 node.normalized_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.
ast::InterpolPart::Interpolation(node) => self.compile(slot, node.expr().unwrap()),
ast::InterpolPart::Literal(lit) => {
self.emit_constant(Value::String(lit.into()), &node);
}
}
}
if count != 1 {
self.push_op(OpCode::OpInterpolate(Count(count)), &node);
}
}
fn compile_unary_op(&mut self, slot: Option<LocalIdx>, op: ast::UnaryOp) {
self.compile(slot, op.expr().unwrap());
self.emit_force();
let opcode = match op.operator().unwrap() {
ast::UnaryOpKind::Invert => OpCode::OpInvert,
ast::UnaryOpKind::Negate => OpCode::OpNegate,
};
self.push_op_old(opcode);
}
fn compile_binop(&mut self, slot: Option<LocalIdx>, op: ast::BinOp) {
use ast::BinOpKind;
// Short-circuiting and other strange 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(slot, op),
BinOpKind::Or => return self.compile_or(slot, op),
BinOpKind::Implication => return self.compile_implication(slot, op),
_ => {}
};
// For all other operators, the two values need to be left on
// the stack in the correct order before pushing the
// instruction for the operation itself.
self.compile(slot, op.lhs().unwrap());
self.emit_force();
self.compile(slot, op.rhs().unwrap());
self.emit_force();
match op.operator().unwrap() {
BinOpKind::Add => self.push_op_old(OpCode::OpAdd),
BinOpKind::Sub => self.push_op_old(OpCode::OpSub),
BinOpKind::Mul => self.push_op_old(OpCode::OpMul),
BinOpKind::Div => self.push_op_old(OpCode::OpDiv),
BinOpKind::Update => self.push_op_old(OpCode::OpAttrsUpdate),
BinOpKind::Equal => self.push_op_old(OpCode::OpEqual),
BinOpKind::Less => self.push_op_old(OpCode::OpLess),
BinOpKind::LessOrEq => self.push_op_old(OpCode::OpLessOrEq),
BinOpKind::More => self.push_op_old(OpCode::OpMore),
BinOpKind::MoreOrEq => self.push_op_old(OpCode::OpMoreOrEq),
BinOpKind::Concat => self.push_op_old(OpCode::OpConcat),
BinOpKind::NotEqual => {
self.push_op_old(OpCode::OpEqual);
self.push_op_old(OpCode::OpInvert)
}
// Handled by separate branch above.
BinOpKind::And | BinOpKind::Implication | BinOpKind::Or => {
unreachable!()
}
};
}
fn compile_and(&mut self, slot: Option<LocalIdx>, node: ast::BinOp) {
debug_assert!(
matches!(node.operator(), Some(ast::BinOpKind::And)),
"compile_and called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack.
self.compile(slot, node.lhs().unwrap());
self.emit_force();
// If this value is false, jump over the right-hand side - the
// whole expression is false.
let end_idx = self.push_op_old(OpCode::OpJumpIfFalse(JumpOffset(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.push_op_old(OpCode::OpPop);
self.compile(slot, node.rhs().unwrap());
self.emit_force();
self.patch_jump(end_idx);
self.push_op_old(OpCode::OpAssertBool);
}
fn compile_or(&mut self, slot: Option<LocalIdx>, node: ast::BinOp) {
debug_assert!(
matches!(node.operator(), Some(ast::BinOpKind::Or)),
"compile_or called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack
self.compile(slot, node.lhs().unwrap());
self.emit_force();
// Opposite of above: If this value is **true**, we can
// short-circuit the right-hand side.
let end_idx = self.push_op_old(OpCode::OpJumpIfTrue(JumpOffset(0)));
self.push_op_old(OpCode::OpPop);
self.compile(slot, node.rhs().unwrap());
self.emit_force();
self.patch_jump(end_idx);
self.push_op_old(OpCode::OpAssertBool);
}
fn compile_implication(&mut self, slot: Option<LocalIdx>, node: ast::BinOp) {
debug_assert!(
matches!(node.operator(), Some(ast::BinOpKind::Implication)),
"compile_implication called with wrong operator kind: {:?}",
node.operator(),
);
// Leave left-hand side value on the stack and invert it.
self.compile(slot, node.lhs().unwrap());
self.emit_force();
self.push_op_old(OpCode::OpInvert);
// Exactly as `||` (because `a -> b` = `!a || b`).
let end_idx = self.push_op_old(OpCode::OpJumpIfTrue(JumpOffset(0)));
self.push_op_old(OpCode::OpPop);
self.compile(slot, node.rhs().unwrap());
self.emit_force();
self.patch_jump(end_idx);
self.push_op_old(OpCode::OpAssertBool);
}
fn compile_has_attr(&mut self, slot: Option<LocalIdx>, node: ast::HasAttr) {
// Put the attribute set on the stack.
self.compile(slot, node.expr().unwrap());
// Push all path fragments with an operation for fetching the
// next nested element, for all fragments except the last one.
for (count, fragment) in node.attrpath().unwrap().attrs().enumerate() {
if count > 0 {
self.push_op_old(OpCode::OpAttrsTrySelect);
}
self.compile_attr(slot, fragment);
}
// After the last fragment, emit the actual instruction that
// leaves a boolean on the stack.
self.push_op_old(OpCode::OpAttrsIsSet);
}
fn compile_attr(&mut self, slot: Option<LocalIdx>, node: ast::Attr) {
match node {
ast::Attr::Dynamic(dynamic) => {
self.compile(slot, dynamic.expr().unwrap());
self.emit_force();
}
ast::Attr::Str(s) => {
self.compile_str(slot, s);
self.emit_force();
}
ast::Attr::Ident(ident) => self.emit_literal_ident(&ident),
}
}
// Compile list literals into equivalent bytecode. List
// construction is fairly simple, consisting 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, slot: Option<LocalIdx>, node: ast::List) {
let mut count = 0;
for item in node.items() {
count += 1;
self.compile(slot, item);
}
self.push_op_old(OpCode::OpList(Count(count)));
}
// 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, slot: Option<LocalIdx>, node: ast::AttrSet) {
if node.rec_token().is_some() {
todo!("recursive attribute sets are not yet implemented")
}
let mut count = 0;
// Inherits have to be evaluated before entering the scope of
// a potentially recursive attribute sets (i.e. we always
// inherit "from the outside").
for inherit in node.inherits() {
match inherit.from() {
Some(from) => {
for ident in inherit.idents() {
count += 1;
// First emit the identifier itself (this
// becomes the new key).
self.emit_literal_ident(&ident);
// Then emit the node that we're inheriting
// from.
//
// TODO: Likely significant optimisation
// potential in having a multi-select
// instruction followed by a merge, rather
// than pushing/popping the same attrs
// potentially a lot of times.
self.compile(slot, from.expr().unwrap());
self.emit_force();
self.emit_literal_ident(&ident);
self.push_op_old(OpCode::OpAttrsSelect);
}
}
None => {
for ident in inherit.idents() {
count += 1;
// Emit the key to use for OpAttrs
self.emit_literal_ident(&ident);
// Emit the value.
self.compile_ident(slot, ident);
}
}
}
}
for kv in node.attrpath_values() {
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.attrpath().unwrap().attrs() {
key_count += 1;
self.compile_attr(slot, 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.push_op_old(OpCode::OpAttrPath(Count(key_count)));
}
// 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(slot, kv.value().unwrap());
}
self.push_op_old(OpCode::OpAttrs(Count(count)));
}
fn compile_select(&mut self, slot: Option<LocalIdx>, node: ast::Select) {
let set = node.expr().unwrap();
let path = node.attrpath().unwrap();
if node.or_token().is_some() {
self.compile_select_or(slot, set, path, node.default_expr().unwrap());
return;
}
// Push the set onto the stack
self.compile(slot, set);
self.emit_force();
// Compile each key fragment and emit access instructions.
//
// TODO: multi-select instruction to avoid re-pushing attrs on
// nested selects.
for fragment in path.attrs() {
self.compile_attr(slot, fragment);
self.push_op_old(OpCode::OpAttrsSelect);
}
}
/// Compile an `or` expression into a chunk of conditional jumps.
///
/// If at any point during attribute set traversal a key is
/// missing, the `OpAttrOrNotFound` instruction will leave a
/// special sentinel value on the stack.
///
/// After each access, a conditional jump evaluates the top of the
/// stack and short-circuits to the default value if it sees the
/// sentinel.
///
/// Code like `{ a.b = 1; }.a.c or 42` yields this bytecode and
/// runtime stack:
///
/// ```notrust
/// Bytecode Runtime stack
/// ┌────────────────────────────┐ ┌─────────────────────────┐
/// │ ... │ │ ... │
/// │ 5 OP_ATTRS(1) │ → │ 5 [ { a.b = 1; } ] │
/// │ 6 OP_CONSTANT("a") │ → │ 6 [ { a.b = 1; } "a" ] │
/// │ 7 OP_ATTR_OR_NOT_FOUND │ → │ 7 [ { b = 1; } ] │
/// │ 8 JUMP_IF_NOT_FOUND(13) │ → │ 8 [ { b = 1; } ] │
/// │ 9 OP_CONSTANT("C") │ → │ 9 [ { b = 1; } "c" ] │
/// │ 10 OP_ATTR_OR_NOT_FOUND │ → │ 10 [ NOT_FOUND ] │
/// │ 11 JUMP_IF_NOT_FOUND(13) │ → │ 11 [ ] │
/// │ 12 JUMP(14) │ │ .. jumped over │
/// │ 13 CONSTANT(42) │ → │ 12 [ 42 ] │
/// │ 14 ... │ │ .. .... │
/// └────────────────────────────┘ └─────────────────────────┘
/// ```
fn compile_select_or(
&mut self,
slot: Option<LocalIdx>,
set: ast::Expr,
path: ast::Attrpath,
default: ast::Expr,
) {
self.compile(slot, set);
self.emit_force();
let mut jumps = vec![];
for fragment in path.attrs() {
self.compile_attr(slot, fragment);
self.push_op_old(OpCode::OpAttrsTrySelect);
jumps.push(
self.chunk()
.push_op_old(OpCode::OpJumpIfNotFound(JumpOffset(0))),
);
}
let final_jump = self.push_op_old(OpCode::OpJump(JumpOffset(0)));
for jump in jumps {
self.patch_jump(jump);
}
// Compile the default value expression and patch the final
// jump to point *beyond* it.
self.compile(slot, default);
self.patch_jump(final_jump);
}
fn compile_assert(&mut self, slot: Option<LocalIdx>, node: ast::Assert) {
// Compile the assertion condition to leave its value on the stack.
self.compile(slot, node.condition().unwrap());
self.push_op_old(OpCode::OpAssert);
// The runtime will abort evaluation at this point if the
// assertion failed, if not the body simply continues on like
// normal.
self.compile(slot, node.body().unwrap());
}
// 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, slot: Option<LocalIdx>, node: ast::IfElse) {
self.compile(slot, node.condition().unwrap());
let then_idx = self.push_op_old(OpCode::OpJumpIfFalse(JumpOffset(0)));
self.push_op_old(OpCode::OpPop); // discard condition value
self.compile(slot, node.body().unwrap());
let else_idx = self.push_op_old(OpCode::OpJump(JumpOffset(0)));
self.patch_jump(then_idx); // patch jump *to* else_body
self.push_op_old(OpCode::OpPop); // discard condition value
self.compile(slot, node.else_body().unwrap());
self.patch_jump(else_idx); // patch jump *over* else body
}
// Compile an `inherit` node of a `let`-expression.
fn compile_let_inherit<I: Iterator<Item = ast::Inherit>>(
&mut self,
slot: Option<LocalIdx>,
inherits: I,
) {
for inherit in inherits {
match inherit.from() {
// Within a `let` binding, inheriting from the outer
// scope is a no-op *if* the identifier can be
// statically resolved.
None if !self.scope().has_with() => {
self.emit_warning(inherit.syntax().clone(), WarningKind::UselessInherit);
continue;
}
None => {
for ident in inherit.idents() {
// If the identifier resolves statically, it
// has precedence over dynamic bindings, and
// the inherit is useless.
if matches!(
self.scope_mut()
.resolve_local(ident.ident_token().unwrap().text()),
LocalPosition::Known(_)
) {
self.emit_warning(ident.syntax().clone(), WarningKind::UselessInherit);
continue;
}
self.compile_ident(slot, ident.clone());
let idx = self.declare_local(
ident.syntax().clone(),
ident.ident_token().unwrap().text(),
);
self.scope_mut().mark_initialised(idx);
}
}
Some(from) => {
for ident in inherit.idents() {
self.compile(slot, from.expr().unwrap());
self.emit_force();
self.emit_literal_ident(&ident);
self.push_op_old(OpCode::OpAttrsSelect);
let idx = self.declare_local(
ident.syntax().clone(),
ident.ident_token().unwrap().text(),
);
self.scope_mut().mark_initialised(idx);
}
}
}
}
}
// Compile a standard `let ...; in ...` statement.
//
// Unless in a non-standard scope, the encountered values are
// simply pushed on the stack and their indices noted in the
// entries vector.
fn compile_let_in(&mut self, slot: Option<LocalIdx>, node: ast::LetIn) {
self.begin_scope();
self.compile_let_inherit(slot, node.inherits());
// First pass to ensure that all identifiers are known;
// required for resolving recursion.
let mut entries: Vec<(LocalIdx, ast::Expr)> = vec![];
for entry in node.attrpath_values() {
let mut path = match normalise_ident_path(entry.attrpath().unwrap().attrs()) {
Ok(p) => p,
Err(err) => {
self.errors.push(err);
continue;
}
};
if path.len() != 1 {
todo!("nested bindings in let expressions :(")
}
let idx = self.declare_local(
entry.attrpath().unwrap().syntax().clone(),
path.pop().unwrap(),
);
entries.push((idx, entry.value().unwrap()));
}
// Second pass to place the values in the correct stack slots.
let indices: Vec<LocalIdx> = entries.iter().map(|(idx, _)| *idx).collect();
for (idx, value) in entries.into_iter() {
self.compile(Some(idx), value);
// Any code after this point will observe the value in the
// right stack slot, so mark it as initialised.
self.scope_mut().mark_initialised(idx);
}
// Third pass to emit finaliser instructions if necessary.
for idx in indices {
if self.scope()[idx].needs_finaliser {
let stack_idx = self.scope().stack_index(idx);
self.push_op_old(OpCode::OpFinalise(stack_idx));
}
}
// Deal with the body, then clean up the locals afterwards.
self.compile(slot, node.body().unwrap());
self.end_scope();
}
fn compile_ident(&mut self, slot: Option<LocalIdx>, node: ast::Ident) {
let ident = node.ident_token().unwrap();
// If the identifier is a global, and it is not poisoned, emit
// the global directly.
if let Some(global) = self.globals.get(ident.text()) {
if !self.scope().is_poisoned(ident.text()) {
global.clone()(self);
return;
}
}
match self.scope_mut().resolve_local(ident.text()) {
LocalPosition::Unknown => {
// Are we possibly dealing with an upvalue?
if let Some(idx) = self.resolve_upvalue(self.contexts.len() - 1, ident.text()) {
self.push_op_old(OpCode::OpGetUpvalue(idx));
return;
}
// Even worse - are we dealing with a dynamic upvalue?
if let Some(idx) =
self.resolve_dynamic_upvalue(self.contexts.len() - 1, ident.text())
{
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
// Edge case: Current scope *also* has a non-empty
// `with`-stack. This means we need to resolve
// both in this scope, and in the upvalues.
if self.scope().has_with() {
self.emit_constant_old(Value::String(ident.text().into()));
self.push_op_old(OpCode::OpResolveWithOrUpvalue(idx));
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
return;
}
self.push_op_old(OpCode::OpGetUpvalue(idx));
return;
}
if !self.scope().has_with() {
self.emit_error(node.syntax().clone(), ErrorKind::UnknownStaticVariable);
return;
}
// Variable needs to be dynamically resolved at
// runtime.
self.emit_constant_old(Value::String(ident.text().into()));
self.push_op_old(OpCode::OpResolveWith);
}
LocalPosition::Known(idx) => {
let stack_idx = self.scope().stack_index(idx);
self.push_op_old(OpCode::OpGetLocal(stack_idx));
}
// This identifier is referring to a value from the same
// scope which is not yet defined. This identifier access
// must be thunked.
LocalPosition::Recursive(idx) => self.thunk(slot, move |compiler, _| {
let upvalue_idx =
compiler.add_upvalue(compiler.contexts.len() - 1, Upvalue::Local(idx));
compiler
.chunk()
.push_op_old(OpCode::OpGetUpvalue(upvalue_idx));
}),
};
}
// Compile `with` expressions by emitting instructions that
// pop/remove the indices of attribute sets that are implicitly in
// scope through `with` on the "with-stack".
fn compile_with(&mut self, slot: Option<LocalIdx>, node: ast::With) {
self.begin_scope();
// TODO: Detect if the namespace is just an identifier, and
// resolve that directly (thus avoiding duplication on the
// stack).
self.compile(slot, node.namespace().unwrap());
self.emit_force();
let local_idx = self.scope_mut().declare_phantom();
let with_idx = self.scope().stack_index(local_idx);
self.scope_mut().push_with();
self.push_op_old(OpCode::OpPushWith(with_idx));
self.compile(slot, node.body().unwrap());
self.push_op_old(OpCode::OpPopWith);
self.scope_mut().pop_with();
self.end_scope();
}
fn compile_lambda(&mut self, slot: Option<LocalIdx>, node: ast::Lambda) {
// Open new lambda context in compiler, which has its own
// scope etc.
self.contexts.push(LambdaCtx::new());
self.begin_scope();
// Compile the function itself
match node.param().unwrap() {
ast::Param::Pattern(_) => todo!("formals function definitions"),
ast::Param::IdentParam(param) => {
let name = param
.ident()
.unwrap()
.ident_token()
.unwrap()
.text()
.to_string();
let idx = self.declare_local(param.syntax().clone(), &name);
self.scope_mut().mark_initialised(idx);
}
}
self.compile(slot, node.body().unwrap());
self.end_scope();
// TODO: determine and insert enclosing name, if available.
// Pop the lambda context back off, and emit the finished
// lambda as a constant.
let compiled = self.contexts.pop().unwrap();
#[cfg(feature = "disassembler")]
{
crate::disassembler::disassemble_chunk(&compiled.lambda.chunk);
}
// If the function is not a closure, just emit it directly and
// move on.
if compiled.lambda.upvalue_count == 0 {
self.emit_constant_old(Value::Closure(Closure::new(Rc::new(compiled.lambda))));
return;
}
// If the function is a closure, we need to emit the variable
// number of operands that allow the runtime to close over the
// upvalues and leave a blueprint in the constant index from
// which the runtime closure can be constructed.
let blueprint_idx = self
.chunk()
.push_constant(Value::Blueprint(Rc::new(compiled.lambda)));
self.push_op_old(OpCode::OpClosure(blueprint_idx));
self.emit_upvalue_data(slot, compiled.scope.upvalues);
}
fn compile_apply(&mut self, slot: Option<LocalIdx>, node: ast::Apply) {
// To call a function, we leave its arguments on the stack,
// followed by the function expression itself, and then emit a
// call instruction. This way, the stack is perfectly laid out
// to enter the function call straight away.
self.compile(slot, node.argument().unwrap());
self.compile(slot, node.lambda().unwrap());
self.push_op_old(OpCode::OpCall);
}
/// Compile an expression into a runtime thunk which should be
/// lazily evaluated when accessed.
// TODO: almost the same as Compiler::compile_lambda; unify?
fn thunk<F>(&mut self, slot: Option<LocalIdx>, content: F)
where
F: FnOnce(&mut Compiler, Option<LocalIdx>),
{
self.contexts.push(LambdaCtx::new());
self.begin_scope();
content(self, slot);
self.end_scope();
let thunk = self.contexts.pop().unwrap();
#[cfg(feature = "disassembler")]
{
crate::disassembler::disassemble_chunk(&thunk.lambda.chunk);
}
// Emit the thunk directly if it does not close over the
// environment.
if thunk.lambda.upvalue_count == 0 {
self.emit_constant_old(Value::Thunk(Thunk::new(Rc::new(thunk.lambda))));
return;
}
// Otherwise prepare for runtime construction of the thunk.
let blueprint_idx = self
.chunk()
.push_constant(Value::Blueprint(Rc::new(thunk.lambda)));
self.push_op_old(OpCode::OpThunk(blueprint_idx));
self.emit_upvalue_data(slot, thunk.scope.upvalues);
}
/// Emit the data instructions that the runtime needs to correctly
/// assemble the provided upvalues array.
fn emit_upvalue_data(&mut self, slot: Option<LocalIdx>, upvalues: Vec<Upvalue>) {
for upvalue in upvalues {
match upvalue {
Upvalue::Local(idx) if slot.is_none() => {
let stack_idx = self.scope().stack_index(idx);
self.push_op_old(OpCode::DataLocalIdx(stack_idx));
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
}
Upvalue::Local(idx) => {
let stack_idx = self.scope().stack_index(idx);
// If the upvalue slot is located *after* the
// closure, the upvalue resolution must be
// deferred until the scope is fully initialised
// and can be finalised.
if slot.unwrap() < idx {
self.push_op_old(OpCode::DataDeferredLocal(stack_idx));
self.scope_mut().mark_needs_finaliser(slot.unwrap());
} else {
self.push_op_old(OpCode::DataLocalIdx(stack_idx));
}
}
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
Upvalue::Upvalue(idx) => {
self.push_op_old(OpCode::DataUpvalueIdx(idx));
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
}
Upvalue::Dynamic { name, up } => {
let idx = self.chunk().push_constant(Value::String(name.into()));
self.push_op_old(OpCode::DataDynamicIdx(idx));
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
if let Some(up) = up {
self.push_op_old(OpCode::DataDynamicAncestor(up));
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
}
}
};
}
}
/// Emit the literal string value of an identifier. Required for
/// several operations related to attribute sets, where
/// identifiers are used as string keys.
fn emit_literal_ident(&mut self, ident: &ast::Ident) {
self.emit_constant_old(Value::String(ident.ident_token().unwrap().text().into()));
}
/// Patch the jump instruction at the given index, setting its
/// jump offset from the placeholder to the current code position.
///
/// This is required because the actual target offset of jumps is
/// not known at the time when the jump operation itself is
/// emitted.
fn patch_jump(&mut self, idx: CodeIdx) {
let offset = JumpOffset(self.chunk().code.len() - 1 - idx.0);
match &mut self.chunk().code[idx.0] {
OpCode::OpJump(n)
| OpCode::OpJumpIfFalse(n)
| OpCode::OpJumpIfTrue(n)
| OpCode::OpJumpIfNotFound(n) => {
*n = offset;
}
op => panic!("attempted to patch unsupported op: {:?}", op),
}
}
fn begin_scope(&mut self) {
self.scope_mut().scope_depth += 1;
}
fn end_scope(&mut self) {
debug_assert!(self.scope().scope_depth != 0, "can not end top scope");
// If this scope poisoned any builtins or special identifiers,
// they need to be reset.
let depth = self.scope().scope_depth;
self.scope_mut().unpoison(depth);
self.scope_mut().scope_depth -= 1;
// When ending a scope, all corresponding locals need to be
// removed, but the value of the body needs to remain on the
// stack. This is implemented by a separate instruction.
let mut pops = 0;
// TL;DR - iterate from the back while things belonging to the
// ended scope still exist.
while !self.scope().locals.is_empty()
&& self.scope().locals[self.scope().locals.len() - 1].above(self.scope().scope_depth)
{
pops += 1;
// While removing the local, analyse whether it has been
// accessed while it existed and emit a warning to the
// user otherwise.
if let Some(Local {
node: Some(node),
used,
name,
..
}) = self.scope_mut().locals.pop()
{
if !used && !name.starts_with('_') {
self.emit_warning(node, WarningKind::UnusedBinding);
}
}
}
if pops > 0 {
self.push_op_old(OpCode::OpCloseScope(Count(pops)));
}
}
/// Declare a local variable known in the scope that is being
/// compiled by pushing it to the locals. This is used to
/// determine the stack offset of variables.
fn declare_local<S: Into<String>>(&mut self, node: rnix::SyntaxNode, name: S) -> LocalIdx {
let name = name.into();
let depth = self.scope().scope_depth;
// Do this little dance to get ahold of the *static* key and
// use it for poisoning if required.
let key: Option<&'static str> = match self.globals.get_key_value(name.as_str()) {
Some((key, _)) => Some(*key),
None => None,
};
if let Some(global_ident) = key {
self.emit_warning(node.clone(), WarningKind::ShadowedGlobal(global_ident));
self.scope_mut().poison(global_ident, depth);
}
let mut shadowed = false;
for other in self.scope().locals.iter().rev() {
if other.name == name && other.depth == depth {
shadowed = true;
break;
}
}
if shadowed {
self.emit_error(
node.clone(),
ErrorKind::VariableAlreadyDefined(name.clone()),
);
}
self.scope_mut().declare_local(name, node)
}
fn resolve_upvalue(&mut self, ctx_idx: usize, name: &str) -> Option<UpvalueIdx> {
if ctx_idx == 0 {
// There can not be any upvalue at the outermost context.
return None;
}
// Determine whether the upvalue is a local in the enclosing context.
match self.contexts[ctx_idx - 1].scope.resolve_local(name) {
// recursive upvalues are dealt with the same way as
// standard known ones, as thunks and closures are
// guaranteed to be placed on the stack (i.e. in the right
// position) *during* their runtime construction
LocalPosition::Known(idx) | LocalPosition::Recursive(idx) => {
return Some(self.add_upvalue(ctx_idx, Upvalue::Local(idx)))
}
LocalPosition::Unknown => { /* continue below */ }
};
// If the upvalue comes from even further up, we need to
// recurse to make sure that the upvalues are created at each
// level.
if let Some(idx) = self.resolve_upvalue(ctx_idx - 1, name) {
return Some(self.add_upvalue(ctx_idx, Upvalue::Upvalue(idx)));
}
None
}
/// If no static resolution for a potential upvalue was found,
/// finds the lowest lambda context that has a `with`-stack and
/// thread dynamic upvalues all the way through.
///
/// At runtime, as closures are being constructed they either
/// capture a dynamically available upvalue, take an upvalue from
/// their "ancestor" or leave a sentinel value on the stack.
///
/// As such an upvalue is actually accessed, an error is produced
/// when the sentinel is found. See the runtime's handling of
/// dynamic upvalues for details.
fn resolve_dynamic_upvalue(&mut self, at: usize, name: &str) -> Option<UpvalueIdx> {
if at == 0 {
// There can not be any upvalue at the outermost context.
return None;
}
if let Some((lowest_idx, _)) = self
.contexts
.iter()
.enumerate()
.find(|(_, c)| c.scope.has_with())
{
// An enclosing lambda context has dynamic values. Each
// context in the chain from that point on now needs to
// capture dynamic upvalues because we can not statically
// know at which level the correct one is located.
let name = SmolStr::new(name);
let mut upvalue_idx = None;
for idx in lowest_idx..=at {
upvalue_idx = Some(self.add_upvalue(
idx,
Upvalue::Dynamic {
name: name.clone(),
up: upvalue_idx,
},
));
}
// Return the outermost upvalue index (i.e. the one of the
// current context).
return upvalue_idx;
}
None
}
fn add_upvalue(&mut self, ctx_idx: usize, upvalue: Upvalue) -> UpvalueIdx {
// If there is already an upvalue closing over the specified
// index, retrieve that instead.
for (idx, existing) in self.contexts[ctx_idx].scope.upvalues.iter().enumerate() {
if *existing == upvalue {
return UpvalueIdx(idx);
}
}
self.contexts[ctx_idx].scope.upvalues.push(upvalue);
let idx = UpvalueIdx(self.contexts[ctx_idx].lambda.upvalue_count);
self.contexts[ctx_idx].lambda.upvalue_count += 1;
idx
}
fn emit_force(&mut self) {
self.push_op_old(OpCode::OpForce);
}
fn emit_warning(&mut self, node: rnix::SyntaxNode, kind: WarningKind) {
self.warnings.push(EvalWarning { node, kind })
}
fn emit_error(&mut self, node: rnix::SyntaxNode, kind: ErrorKind) {
self.errors.push(Error {
node: Some(node),
kind,
})
}
}
/// Convert a non-dynamic string expression to a string if possible,
/// or raise an error.
fn expr_str_to_string(expr: ast::Str) -> EvalResult<String> {
if expr.normalized_parts().len() == 1 {
if let ast::InterpolPart::Literal(s) = expr.normalized_parts().pop().unwrap() {
return Ok(s);
}
}
return Err(Error {
node: Some(expr.syntax().clone()),
kind: ErrorKind::DynamicKeyInLet(expr.syntax().clone()),
});
}
/// Convert a single identifier path fragment to a string if possible,
/// or raise an error about the node being dynamic.
fn attr_to_string(node: ast::Attr) -> EvalResult<String> {
match node {
ast::Attr::Ident(ident) => Ok(ident.ident_token().unwrap().text().into()),
ast::Attr::Str(s) => expr_str_to_string(s),
// The dynamic node type is just a wrapper. C++ Nix does not
// care about the dynamic wrapper when determining whether the
// node itself is dynamic, it depends solely on the expression
// inside (i.e. `let ${"a"} = 1; in a` is valid).
ast::Attr::Dynamic(ref dynamic) => match dynamic.expr().unwrap() {
ast::Expr::Str(s) => expr_str_to_string(s),
_ => Err(ErrorKind::DynamicKeyInLet(node.syntax().clone()).into()),
},
}
}
// Normalises identifier fragments into a single string vector for
// `let`-expressions; fails if fragments requiring dynamic computation
// are encountered.
fn normalise_ident_path<I: Iterator<Item = ast::Attr>>(path: I) -> EvalResult<Vec<String>> {
path.map(attr_to_string).collect()
}
/// Prepare the full set of globals from additional globals supplied
/// by the caller of the compiler, as well as the built-in globals
/// that are always part of the language.
///
/// Note that all builtin functions are *not* considered part of the
/// language in this sense and MUST be supplied as additional global
/// values, including the `builtins` set itself.
fn prepare_globals(additional: HashMap<&'static str, Value>) -> GlobalsMap {
let mut globals: GlobalsMap = HashMap::new();
globals.insert(
"true",
Rc::new(|compiler| {
compiler.chunk().push_op_old(OpCode::OpTrue);
}),
);
globals.insert(
"false",
Rc::new(|compiler| {
compiler.chunk().push_op_old(OpCode::OpFalse);
}),
);
globals.insert(
"null",
Rc::new(|compiler| {
compiler.chunk().push_op_old(OpCode::OpNull);
}),
);
for (ident, value) in additional.into_iter() {
globals.insert(
ident,
Rc::new(move |compiler| compiler.emit_constant_old(value.clone())),
);
}
globals
}
pub fn compile<'code>(
expr: ast::Expr,
location: Option<PathBuf>,
file: &'code codemap::File,
globals: HashMap<&'static str, Value>,
) -> EvalResult<CompilationOutput> {
let mut root_dir = match location {
Some(dir) => Ok(dir),
None => std::env::current_dir().map_err(|e| {
ErrorKind::PathResolution(format!("could not determine current directory: {}", e))
}),
}?;
// If the path passed from the caller points to a file, the
// filename itself needs to be truncated as this must point to a
// directory.
if root_dir.is_file() {
root_dir.pop();
}
let mut c = Compiler {
root_dir,
file,
globals: prepare_globals(globals),
contexts: vec![LambdaCtx::new()],
warnings: vec![],
errors: vec![],
};
c.compile(None, expr);
// The final operation of any top-level Nix program must always be
// `OpForce`. A thunk should not be returned to the user in an
// unevaluated state (though in practice, a value *containing* a
// thunk might be returned).
c.emit_force();
Ok(CompilationOutput {
lambda: c.contexts.pop().unwrap().lambda,
warnings: c.warnings,
errors: c.errors,
})
}