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-rw-r--r--dhall/src/semantics/nze/env.rs42
-rw-r--r--dhall/src/semantics/nze/nir.rs201
-rw-r--r--dhall/src/semantics/nze/normalize.rs53
-rw-r--r--dhall/src/semantics/resolve/cache.rs35
-rw-r--r--dhall/src/semantics/resolve/env.rs59
-rw-r--r--dhall/src/semantics/resolve/hir.rs87
-rw-r--r--dhall/src/semantics/resolve/resolve.rs332
-rw-r--r--dhall/src/semantics/tck/env.rs30
-rw-r--r--dhall/src/semantics/tck/tir.rs60
-rw-r--r--dhall/src/semantics/tck/typecheck.rs85
10 files changed, 609 insertions, 375 deletions
diff --git a/dhall/src/semantics/nze/env.rs b/dhall/src/semantics/nze/env.rs
index ec99dbe..30fa8af 100644
--- a/dhall/src/semantics/nze/env.rs
+++ b/dhall/src/semantics/nze/env.rs
@@ -1,4 +1,5 @@
use crate::semantics::{AlphaVar, Nir, NirKind};
+use crate::Ctxt;
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub enum NzVar {
@@ -9,19 +10,20 @@ pub enum NzVar {
}
#[derive(Debug, Clone)]
-enum EnvItem<Type> {
+enum EnvItem<'cx, T> {
// Variable is bound with given type
- Kept(Type),
+ Kept(T),
// Variable has been replaced by corresponding value
- Replaced(Nir, Type),
+ Replaced(Nir<'cx>, T),
}
#[derive(Debug, Clone)]
-pub struct ValEnv<Type> {
- items: Vec<EnvItem<Type>>,
+pub struct ValEnv<'cx, T> {
+ cx: Ctxt<'cx>,
+ items: Vec<EnvItem<'cx, T>>,
}
-pub type NzEnv = ValEnv<()>;
+pub type NzEnv<'cx> = ValEnv<'cx, ()>;
impl NzVar {
pub fn new(idx: usize) -> Self {
@@ -46,11 +48,17 @@ impl NzVar {
}
}
-impl<Type: Clone> ValEnv<Type> {
- pub fn new() -> Self {
- ValEnv { items: Vec::new() }
+impl<'cx, T: Clone> ValEnv<'cx, T> {
+ pub fn new(cx: Ctxt<'cx>) -> Self {
+ ValEnv {
+ cx,
+ items: Vec::new(),
+ }
+ }
+ pub fn cx(&self) -> Ctxt<'cx> {
+ self.cx
}
- pub fn discard_types(&self) -> ValEnv<()> {
+ pub fn discard_types(&self) -> ValEnv<'cx, ()> {
let items = self
.items
.iter()
@@ -59,27 +67,27 @@ impl<Type: Clone> ValEnv<Type> {
EnvItem::Replaced(val, _) => EnvItem::Replaced(val.clone(), ()),
})
.collect();
- ValEnv { items }
+ ValEnv { cx: self.cx, items }
}
- pub fn insert_type(&self, ty: Type) -> Self {
+ pub fn insert_type(&self, ty: T) -> Self {
let mut env = self.clone();
env.items.push(EnvItem::Kept(ty));
env
}
- pub fn insert_value(&self, e: Nir, ty: Type) -> Self {
+ pub fn insert_value(&self, e: Nir<'cx>, ty: T) -> Self {
let mut env = self.clone();
env.items.push(EnvItem::Replaced(e, ty));
env
}
- pub fn lookup_val(&self, var: AlphaVar) -> NirKind {
+ pub fn lookup_val(&self, var: AlphaVar) -> NirKind<'cx> {
let idx = self.items.len() - 1 - var.idx();
match &self.items[idx] {
EnvItem::Kept(_) => NirKind::Var(NzVar::new(idx)),
EnvItem::Replaced(x, _) => x.kind().clone(),
}
}
- pub fn lookup_ty(&self, var: AlphaVar) -> Type {
+ pub fn lookup_ty(&self, var: AlphaVar) -> T {
let idx = self.items.len() - 1 - var.idx();
match &self.items[idx] {
EnvItem::Kept(ty) | EnvItem::Replaced(_, ty) => ty.clone(),
@@ -87,8 +95,8 @@ impl<Type: Clone> ValEnv<Type> {
}
}
-impl<'a> From<&'a NzEnv> for NzEnv {
- fn from(x: &'a NzEnv) -> Self {
+impl<'cx, 'a> From<&'a NzEnv<'cx>> for NzEnv<'cx> {
+ fn from(x: &'a NzEnv<'cx>) -> Self {
x.clone()
}
}
diff --git a/dhall/src/semantics/nze/nir.rs b/dhall/src/semantics/nze/nir.rs
index 7bda836..8cf06c5 100644
--- a/dhall/src/semantics/nze/nir.rs
+++ b/dhall/src/semantics/nze/nir.rs
@@ -11,7 +11,7 @@ use crate::semantics::{
use crate::syntax::{
Const, Expr, ExprKind, InterpolatedTextContents, Label, NumKind, Span,
};
-use crate::ToExprOptions;
+use crate::{Ctxt, ToExprOptions};
/// Stores a possibly unevaluated value. Gets (partially) normalized on-demand, sharing computation
/// automatically. Uses a Rc<OnceCell> to share computation.
@@ -20,31 +20,31 @@ use crate::ToExprOptions;
/// normalize as needed.
/// Stands for "Normalized Intermediate Representation"
#[derive(Clone)]
-pub struct Nir(Rc<lazy::Lazy<Thunk, NirKind>>);
+pub struct Nir<'cx>(Rc<lazy::Lazy<Thunk<'cx>, NirKind<'cx>>>);
/// An unevaluated subexpression
#[derive(Debug, Clone)]
-pub enum Thunk {
+pub enum Thunk<'cx> {
/// A completely unnormalized expression.
- Thunk { env: NzEnv, body: Hir },
+ Thunk { env: NzEnv<'cx>, body: Hir<'cx> },
/// A partially normalized expression that may need to go through `normalize_one_layer`.
- PartialExpr { env: NzEnv, expr: ExprKind<Nir> },
+ PartialExpr { expr: ExprKind<Nir<'cx>> },
}
/// An unevaluated subexpression that takes an argument.
#[derive(Debug, Clone)]
-pub enum Closure {
+pub enum Closure<'cx> {
/// Normal closure
- Closure { env: NzEnv, body: Hir },
+ Closure { env: NzEnv<'cx>, body: Hir<'cx> },
/// Closure that ignores the argument passed
- ConstantClosure { body: Nir },
+ ConstantClosure { body: Nir<'cx> },
}
/// A text literal with interpolations.
// Invariant: this must not contain interpolations that are themselves TextLits, and contiguous
// text values must be merged.
#[derive(Debug, Clone, PartialEq, Eq)]
-pub struct TextLit(Vec<InterpolatedTextContents<Nir>>);
+pub struct TextLit<'cx>(Vec<InterpolatedTextContents<Nir<'cx>>>);
/// This represents a value in Weak Head Normal Form (WHNF). This means that the value is
/// normalized up to the first constructor, but subexpressions may not be fully normalized.
@@ -54,67 +54,65 @@ pub struct TextLit(Vec<InterpolatedTextContents<Nir>>);
/// In particular, this means that once we get a `NirKind`, it can be considered immutable, and
/// we only need to recursively normalize its sub-`Nir`s to get to the NF.
#[derive(Debug, Clone, PartialEq, Eq)]
-pub enum NirKind {
+pub enum NirKind<'cx> {
/// Closures
LamClosure {
binder: Binder,
- annot: Nir,
- closure: Closure,
+ annot: Nir<'cx>,
+ closure: Closure<'cx>,
},
PiClosure {
binder: Binder,
- annot: Nir,
- closure: Closure,
+ annot: Nir<'cx>,
+ closure: Closure<'cx>,
},
- AppliedBuiltin(BuiltinClosure),
+ AppliedBuiltin(BuiltinClosure<'cx>),
Var(NzVar),
Const(Const),
Num(NumKind),
// Must be a number type, Bool or Text
BuiltinType(Builtin),
- TextLit(TextLit),
- EmptyOptionalLit(Nir),
- NEOptionalLit(Nir),
- OptionalType(Nir),
+ TextLit(TextLit<'cx>),
+ EmptyOptionalLit(Nir<'cx>),
+ NEOptionalLit(Nir<'cx>),
+ OptionalType(Nir<'cx>),
// EmptyListLit(t) means `[] : List t`, not `[] : t`
- EmptyListLit(Nir),
- NEListLit(Vec<Nir>),
- ListType(Nir),
- RecordLit(HashMap<Label, Nir>),
- RecordType(HashMap<Label, Nir>),
- UnionConstructor(Label, HashMap<Label, Option<Nir>>),
- UnionLit(Label, Nir, HashMap<Label, Option<Nir>>),
- UnionType(HashMap<Label, Option<Nir>>),
- Equivalence(Nir, Nir),
- Assert(Nir),
+ EmptyListLit(Nir<'cx>),
+ NEListLit(Vec<Nir<'cx>>),
+ ListType(Nir<'cx>),
+ RecordLit(HashMap<Label, Nir<'cx>>),
+ RecordType(HashMap<Label, Nir<'cx>>),
+ UnionConstructor(Label, HashMap<Label, Option<Nir<'cx>>>),
+ UnionLit(Label, Nir<'cx>, HashMap<Label, Option<Nir<'cx>>>),
+ UnionType(HashMap<Label, Option<Nir<'cx>>>),
+ Equivalence(Nir<'cx>, Nir<'cx>),
+ Assert(Nir<'cx>),
/// Invariant: evaluation must not be able to progress with `normalize_operation`.
/// This is used when an operation couldn't proceed further, for example because of variables.
- Op(OpKind<Nir>),
+ Op(OpKind<Nir<'cx>>),
}
-impl Nir {
+impl<'cx> Nir<'cx> {
/// Construct a Nir from a completely unnormalized expression.
- pub fn new_thunk(env: NzEnv, hir: Hir) -> Nir {
+ pub fn new_thunk(env: NzEnv<'cx>, hir: Hir<'cx>) -> Self {
Nir(Rc::new(lazy::Lazy::new(Thunk::new(env, hir))))
}
/// Construct a Nir from a partially normalized expression that's not in WHNF.
- pub fn from_partial_expr(e: ExprKind<Nir>) -> Nir {
- // TODO: env
- let env = NzEnv::new();
- Nir(Rc::new(lazy::Lazy::new(Thunk::from_partial_expr(env, e))))
+ pub fn from_partial_expr(e: ExprKind<Self>) -> Self {
+ Nir(Rc::new(lazy::Lazy::new(Thunk::from_partial_expr(e))))
}
/// Make a Nir from a NirKind
- pub fn from_kind(v: NirKind) -> Nir {
+ pub fn from_kind(v: NirKind<'cx>) -> Self {
Nir(Rc::new(lazy::Lazy::new_completed(v)))
}
pub fn from_const(c: Const) -> Self {
Self::from_kind(NirKind::Const(c))
}
- pub fn from_builtin(b: Builtin) -> Self {
- Self::from_builtin_env(b, &NzEnv::new())
+ pub fn from_builtin(cx: Ctxt<'cx>, b: Builtin) -> Self {
+ Self::from_builtin_env(b, &NzEnv::new(cx))
}
- pub fn from_builtin_env(b: Builtin, env: &NzEnv) -> Self {
+ pub fn from_builtin_env(b: Builtin, env: &NzEnv<'cx>) -> Self {
Nir::from_kind(NirKind::from_builtin_env(b, env.clone()))
}
pub fn from_text(txt: impl ToString) -> Self {
@@ -129,51 +127,54 @@ impl Nir {
}
/// This is what you want if you want to pattern-match on the value.
- pub fn kind(&self) -> &NirKind {
+ pub fn kind(&self) -> &NirKind<'cx> {
&*self.0
}
/// The contents of a `Nir` are immutable and shared. If however we happen to be the sole
/// owners, we can mutate it directly. Otherwise, this clones the internal value first.
- pub fn kind_mut(&mut self) -> &mut NirKind {
+ pub fn kind_mut(&mut self) -> &mut NirKind<'cx> {
Rc::make_mut(&mut self.0).get_mut()
}
/// If we are the sole owner of this Nir, we can avoid a clone.
- pub fn into_kind(self) -> NirKind {
+ pub fn into_kind(self) -> NirKind<'cx> {
match Rc::try_unwrap(self.0) {
Ok(lazy) => lazy.into_inner(),
Err(rc) => (**rc).clone(),
}
}
- pub fn to_type(&self, u: impl Into<Universe>) -> Type {
+ pub fn to_type(&self, u: impl Into<Universe>) -> Type<'cx> {
Type::new(self.clone(), u.into())
}
/// Converts a value back to the corresponding AST expression.
- pub fn to_expr(&self, opts: ToExprOptions) -> Expr {
- self.to_hir_noenv().to_expr(opts)
+ pub fn to_expr(&self, cx: Ctxt<'cx>, opts: ToExprOptions) -> Expr {
+ self.to_hir_noenv().to_expr(cx, opts)
}
- pub fn to_expr_tyenv(&self, tyenv: &TyEnv) -> Expr {
+ pub fn to_expr_tyenv(&self, tyenv: &TyEnv<'cx>) -> Expr {
self.to_hir(tyenv.as_varenv()).to_expr_tyenv(tyenv)
}
- pub fn app(&self, v: Nir) -> Nir {
+ pub fn app(&self, v: Self) -> Self {
Nir::from_kind(self.app_to_kind(v))
}
- pub fn app_to_kind(&self, v: Nir) -> NirKind {
+ pub fn app_to_kind(&self, v: Self) -> NirKind<'cx> {
apply_any(self, v)
}
- pub fn to_hir(&self, venv: VarEnv) -> Hir {
- let map_uniontype = |kts: &HashMap<Label, Option<Nir>>| {
- ExprKind::UnionType(
- kts.iter()
- .map(|(k, v)| {
- (k.clone(), v.as_ref().map(|v| v.to_hir(venv)))
- })
- .collect(),
- )
- };
+ pub fn to_hir(&self, venv: VarEnv) -> Hir<'cx> {
+ let map_uniontype =
+ |kts: &HashMap<Label, Option<Nir<'cx>>>| -> ExprKind<Hir<'cx>> {
+ ExprKind::UnionType(
+ kts.iter()
+ .map(|(k, v)| {
+ (k.clone(), v.as_ref().map(|v| v.to_hir(venv)))
+ })
+ .collect(),
+ )
+ };
+ let builtin =
+ |b| Hir::new(HirKind::Expr(ExprKind::Builtin(b)), Span::Artificial);
let hir = match self.kind() {
NirKind::Var(v) => HirKind::Var(venv.lookup(*v)),
@@ -204,21 +205,21 @@ impl Nir {
NirKind::BuiltinType(b) => ExprKind::Builtin(*b),
NirKind::Num(l) => ExprKind::Num(l.clone()),
NirKind::OptionalType(t) => ExprKind::Op(OpKind::App(
- Nir::from_builtin(Builtin::Optional).to_hir(venv),
+ builtin(Builtin::Optional),
t.to_hir(venv),
)),
NirKind::EmptyOptionalLit(n) => ExprKind::Op(OpKind::App(
- Nir::from_builtin(Builtin::OptionalNone).to_hir(venv),
+ builtin(Builtin::OptionalNone),
n.to_hir(venv),
)),
NirKind::NEOptionalLit(n) => ExprKind::SomeLit(n.to_hir(venv)),
NirKind::ListType(t) => ExprKind::Op(OpKind::App(
- Nir::from_builtin(Builtin::List).to_hir(venv),
+ builtin(Builtin::List),
t.to_hir(venv),
)),
NirKind::EmptyListLit(n) => ExprKind::EmptyListLit(Hir::new(
HirKind::Expr(ExprKind::Op(OpKind::App(
- Nir::from_builtin(Builtin::List).to_hir(venv),
+ builtin(Builtin::List),
n.to_hir(venv),
))),
Span::Artificial,
@@ -276,52 +277,52 @@ impl Nir {
Hir::new(hir, Span::Artificial)
}
- pub fn to_hir_noenv(&self) -> Hir {
+ pub fn to_hir_noenv(&self) -> Hir<'cx> {
self.to_hir(VarEnv::new())
}
}
-impl NirKind {
- pub fn into_nir(self) -> Nir {
+impl<'cx> NirKind<'cx> {
+ pub fn into_nir(self) -> Nir<'cx> {
Nir::from_kind(self)
}
- pub fn from_builtin(b: Builtin) -> NirKind {
- NirKind::from_builtin_env(b, NzEnv::new())
+ pub fn from_builtin(cx: Ctxt<'cx>, b: Builtin) -> Self {
+ NirKind::from_builtin_env(b, NzEnv::new(cx))
}
- pub fn from_builtin_env(b: Builtin, env: NzEnv) -> NirKind {
+ pub fn from_builtin_env(b: Builtin, env: NzEnv<'cx>) -> Self {
BuiltinClosure::new(b, env)
}
}
-impl Thunk {
- fn new(env: NzEnv, body: Hir) -> Self {
+impl<'cx> Thunk<'cx> {
+ fn new(env: NzEnv<'cx>, body: Hir<'cx>) -> Self {
Thunk::Thunk { env, body }
}
- fn from_partial_expr(env: NzEnv, expr: ExprKind<Nir>) -> Self {
- Thunk::PartialExpr { env, expr }
+ fn from_partial_expr(expr: ExprKind<Nir<'cx>>) -> Self {
+ Thunk::PartialExpr { expr }
}
- fn eval(self) -> NirKind {
+ fn eval(self) -> NirKind<'cx> {
match self {
- Thunk::Thunk { env, body } => normalize_hir(&env, &body),
- Thunk::PartialExpr { env, expr } => normalize_one_layer(expr, &env),
+ Thunk::Thunk { env, body, .. } => normalize_hir(&env, &body),
+ Thunk::PartialExpr { expr } => normalize_one_layer(expr),
}
}
}
-impl Closure {
- pub fn new(env: &NzEnv, body: Hir) -> Self {
+impl<'cx> Closure<'cx> {
+ pub fn new(env: &NzEnv<'cx>, body: Hir<'cx>) -> Self {
Closure::Closure {
env: env.clone(),
body,
}
}
/// New closure that ignores its argument
- pub fn new_constant(body: Nir) -> Self {
+ pub fn new_constant(body: Nir<'cx>) -> Self {
Closure::ConstantClosure { body }
}
- pub fn apply(&self, val: Nir) -> Nir {
+ pub fn apply(&self, val: Nir<'cx>) -> Nir<'cx> {
match self {
Closure::Closure { env, body, .. } => {
body.eval(env.insert_value(val, ()))
@@ -329,7 +330,7 @@ impl Closure {
Closure::ConstantClosure { body, .. } => body.clone(),
}
}
- fn apply_var(&self, var: NzVar) -> Nir {
+ fn apply_var(&self, var: NzVar) -> Nir<'cx> {
match self {
Closure::Closure { .. } => {
self.apply(Nir::from_kind(NirKind::Var(var)))
@@ -339,13 +340,13 @@ impl Closure {
}
/// Convert this closure to a Hir expression
- pub fn to_hir(&self, venv: VarEnv) -> Hir {
+ pub fn to_hir(&self, venv: VarEnv) -> Hir<'cx> {
self.apply_var(NzVar::new(venv.size()))
.to_hir(venv.insert())
}
/// If the closure variable is free in the closure, return Err. Otherwise, return the value
/// with that free variable remove.
- pub fn remove_binder(&self) -> Result<Nir, ()> {
+ pub fn remove_binder(&self) -> Result<Nir<'cx>, ()> {
match self {
Closure::Closure { .. } => {
let v = NzVar::fresh();
@@ -358,20 +359,20 @@ impl Closure {
}
}
-impl TextLit {
+impl<'cx> TextLit<'cx> {
pub fn new(
- elts: impl Iterator<Item = InterpolatedTextContents<Nir>>,
+ elts: impl Iterator<Item = InterpolatedTextContents<Nir<'cx>>>,
) -> Self {
TextLit(squash_textlit(elts))
}
- pub fn interpolate(v: Nir) -> TextLit {
+ pub fn interpolate(v: Nir<'cx>) -> Self {
TextLit(vec![InterpolatedTextContents::Expr(v)])
}
- pub fn from_text(s: String) -> TextLit {
+ pub fn from_text(s: String) -> Self {
TextLit(vec![InterpolatedTextContents::Text(s)])
}
- pub fn concat(&self, other: &TextLit) -> TextLit {
+ pub fn concat(&self, other: &Self) -> Self {
TextLit::new(self.iter().chain(other.iter()).cloned())
}
pub fn is_empty(&self) -> bool {
@@ -379,7 +380,7 @@ impl TextLit {
}
/// If the literal consists of only one interpolation and not text, return the interpolated
/// value.
- pub fn as_single_expr(&self) -> Option<&Nir> {
+ pub fn as_single_expr(&self) -> Option<&Nir<'cx>> {
use InterpolatedTextContents::Expr;
if let [Expr(v)] = self.0.as_slice() {
Some(v)
@@ -398,43 +399,45 @@ impl TextLit {
None
}
}
- pub fn iter(&self) -> impl Iterator<Item = &InterpolatedTextContents<Nir>> {
+ pub fn iter(
+ &self,
+ ) -> impl Iterator<Item = &InterpolatedTextContents<Nir<'cx>>> {
self.0.iter()
}
}
-impl lazy::Eval<NirKind> for Thunk {
- fn eval(self) -> NirKind {
+impl<'cx> lazy::Eval<NirKind<'cx>> for Thunk<'cx> {
+ fn eval(self) -> NirKind<'cx> {
self.eval()
}
}
/// Compare two values for equality modulo alpha/beta-equivalence.
-impl std::cmp::PartialEq for Nir {
+impl<'cx> std::cmp::PartialEq for Nir<'cx> {
fn eq(&self, other: &Self) -> bool {
Rc::ptr_eq(&self.0, &other.0) || self.kind() == other.kind()
}
}
-impl std::cmp::Eq for Nir {}
+impl<'cx> std::cmp::Eq for Nir<'cx> {}
-impl std::cmp::PartialEq for Thunk {
+impl<'cx> std::cmp::PartialEq for Thunk<'cx> {
fn eq(&self, _other: &Self) -> bool {
unreachable!(
"Trying to compare thunks but we should only compare WHNFs"
)
}
}
-impl std::cmp::Eq for Thunk {}
+impl<'cx> std::cmp::Eq for Thunk<'cx> {}
-impl std::cmp::PartialEq for Closure {
+impl<'cx> std::cmp::PartialEq for Closure<'cx> {
fn eq(&self, other: &Self) -> bool {
let v = NzVar::fresh();
self.apply_var(v) == other.apply_var(v)
}
}
-impl std::cmp::Eq for Closure {}
+impl<'cx> std::cmp::Eq for Closure<'cx> {}
-impl std::fmt::Debug for Nir {
+impl<'cx> std::fmt::Debug for Nir<'cx> {
fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
if let NirKind::Const(c) = self.kind() {
return write!(fmt, "{:?}", c);
diff --git a/dhall/src/semantics/nze/normalize.rs b/dhall/src/semantics/nze/normalize.rs
index 62efc5f..59710d1 100644
--- a/dhall/src/semantics/nze/normalize.rs
+++ b/dhall/src/semantics/nze/normalize.rs
@@ -5,7 +5,7 @@ use crate::semantics::NzEnv;
use crate::semantics::{Binder, Closure, Hir, HirKind, Nir, NirKind, TextLit};
use crate::syntax::{ExprKind, InterpolatedTextContents};
-pub fn apply_any(f: &Nir, a: Nir) -> NirKind {
+pub fn apply_any<'cx>(f: &Nir<'cx>, a: Nir<'cx>) -> NirKind<'cx> {
match f.kind() {
NirKind::LamClosure { closure, .. } => closure.apply(a).kind().clone(),
NirKind::AppliedBuiltin(closure) => closure.apply(a),
@@ -16,16 +16,16 @@ pub fn apply_any(f: &Nir, a: Nir) -> NirKind {
}
}
-pub fn squash_textlit(
- elts: impl Iterator<Item = InterpolatedTextContents<Nir>>,
-) -> Vec<InterpolatedTextContents<Nir>> {
+pub fn squash_textlit<'cx>(
+ elts: impl Iterator<Item = InterpolatedTextContents<Nir<'cx>>>,
+) -> Vec<InterpolatedTextContents<Nir<'cx>>> {
use std::mem::replace;
use InterpolatedTextContents::{Expr, Text};
- fn inner(
- elts: impl Iterator<Item = InterpolatedTextContents<Nir>>,
+ fn inner<'cx>(
+ elts: impl Iterator<Item = InterpolatedTextContents<Nir<'cx>>>,
crnt_str: &mut String,
- ret: &mut Vec<InterpolatedTextContents<Nir>>,
+ ret: &mut Vec<InterpolatedTextContents<Nir<'cx>>>,
) {
for contents in elts {
match contents {
@@ -81,22 +81,22 @@ where
kvs
}
-pub type Ret = NirKind;
+pub type Ret<'cx> = NirKind<'cx>;
-pub fn ret_nir(x: Nir) -> Ret {
+pub fn ret_nir<'cx>(x: Nir<'cx>) -> Ret<'cx> {
x.into_kind()
}
-pub fn ret_kind(x: NirKind) -> Ret {
+pub fn ret_kind<'cx>(x: NirKind<'cx>) -> Ret<'cx> {
x
}
-pub fn ret_ref(x: &Nir) -> Ret {
+pub fn ret_ref<'cx>(x: &Nir<'cx>) -> Ret<'cx> {
x.kind().clone()
}
-pub fn ret_op(x: OpKind<Nir>) -> Ret {
+pub fn ret_op<'cx>(x: OpKind<Nir<'cx>>) -> Ret<'cx> {
NirKind::Op(x)
}
-pub fn normalize_one_layer(expr: ExprKind<Nir>, env: &NzEnv) -> NirKind {
+pub fn normalize_one_layer<'cx>(expr: ExprKind<Nir<'cx>>) -> NirKind<'cx> {
use NirKind::{
Assert, Const, NEListLit, NEOptionalLit, Num, RecordLit, RecordType,
UnionType,
@@ -106,15 +106,13 @@ pub fn normalize_one_layer(expr: ExprKind<Nir>, env: &NzEnv) -> NirKind {
ExprKind::Var(..)
| ExprKind::Lam(..)
| ExprKind::Pi(..)
- | ExprKind::Let(..) => {
+ | ExprKind::Let(..)
+ | ExprKind::Builtin(..) => {
unreachable!("This case should have been handled in normalize_hir")
}
ExprKind::Const(c) => ret_kind(Const(c)),
ExprKind::Num(l) => ret_kind(Num(l)),
- ExprKind::Builtin(b) => {
- ret_kind(NirKind::from_builtin_env(b, env.clone()))
- }
ExprKind::TextLit(elts) => {
let tlit = TextLit::new(elts.into_iter());
// Simplify bare interpolation
@@ -154,10 +152,22 @@ pub fn normalize_one_layer(expr: ExprKind<Nir>, env: &NzEnv) -> NirKind {
}
/// Normalize Hir into WHNF
-pub fn normalize_hir(env: &NzEnv, hir: &Hir) -> NirKind {
+pub fn normalize_hir<'cx>(env: &NzEnv<'cx>, hir: &Hir<'cx>) -> NirKind<'cx> {
match hir.kind() {
+ HirKind::MissingVar(..) => unreachable!("ruled out by typechecking"),
HirKind::Var(var) => env.lookup_val(*var),
- HirKind::Import(hir, _) => normalize_hir(env, hir),
+ HirKind::Import(import) => {
+ let typed = env.cx()[import].unwrap_result();
+ normalize_hir(env, &typed.hir)
+ }
+ HirKind::ImportAlternative(alt, left, right) => {
+ let hir = if env.cx()[alt].unwrap_selected() {
+ left
+ } else {
+ right
+ };
+ normalize_hir(env, hir)
+ }
HirKind::Expr(ExprKind::Lam(binder, annot, body)) => {
let annot = annot.eval(env);
NirKind::LamClosure {
@@ -178,9 +188,12 @@ pub fn normalize_hir(env: &NzEnv, hir: &Hir) -> NirKind {
let val = val.eval(env);
body.eval(env.insert_value(val, ())).kind().clone()
}
+ HirKind::Expr(ExprKind::Builtin(b)) => {
+ NirKind::from_builtin_env(*b, env.clone())
+ }
HirKind::Expr(e) => {
let e = e.map_ref(|hir| hir.eval(env));
- normalize_one_layer(e, env)
+ normalize_one_layer(e)
}
}
}
diff --git a/dhall/src/semantics/resolve/cache.rs b/dhall/src/semantics/resolve/cache.rs
index b00a2d5..1fc8dd3 100644
--- a/dhall/src/semantics/resolve/cache.rs
+++ b/dhall/src/semantics/resolve/cache.rs
@@ -5,7 +5,7 @@ use std::path::{Path, PathBuf};
use crate::error::{CacheError, Error};
use crate::parse::parse_binary;
use crate::syntax::{binary, Hash};
-use crate::Typed;
+use crate::{Ctxt, Typed};
use std::ffi::OsStr;
use std::fs::File;
@@ -52,9 +52,13 @@ impl Cache {
self.cache_dir.join(filename_for_hash(hash))
}
- pub fn get(&self, hash: &Hash) -> Result<Typed, Error> {
+ pub fn get<'cx>(
+ &self,
+ cx: Ctxt<'cx>,
+ hash: &Hash,
+ ) -> Result<Typed<'cx>, Error> {
let path = self.entry_path(hash);
- let res = read_cache_file(&path, hash);
+ let res = read_cache_file(cx, &path, hash);
if res.is_err() && path.exists() {
// Delete cache file since it's invalid. We ignore the error.
let _ = std::fs::remove_file(&path);
@@ -62,14 +66,23 @@ impl Cache {
res
}
- pub fn insert(&self, hash: &Hash, expr: &Typed) -> Result<(), Error> {
+ pub fn insert<'cx>(
+ &self,
+ cx: Ctxt<'cx>,
+ hash: &Hash,
+ expr: &Typed<'cx>,
+ ) -> Result<(), Error> {
let path = self.entry_path(hash);
- write_cache_file(&path, expr)
+ write_cache_file(cx, &path, expr)
}
}
/// Read a file from the cache, also checking that its hash is valid.
-fn read_cache_file(path: &Path, hash: &Hash) -> Result<Typed, Error> {
+fn read_cache_file<'cx>(
+ cx: Ctxt<'cx>,
+ path: &Path,
+ hash: &Hash,
+) -> Result<Typed<'cx>, Error> {
let data = crate::utils::read_binary_file(path)?;
match hash {
@@ -81,12 +94,16 @@ fn read_cache_file(path: &Path, hash: &Hash) -> Result<Typed, Error> {
}
}
- Ok(parse_binary(&data)?.skip_resolve()?.typecheck()?)
+ Ok(parse_binary(&data)?.resolve(cx)?.typecheck(cx)?)
}
/// Write a file to the cache.
-fn write_cache_file(path: &Path, expr: &Typed) -> Result<(), Error> {
- let data = binary::encode(&expr.to_expr())?;
+fn write_cache_file<'cx>(
+ cx: Ctxt<'cx>,
+ path: &Path,
+ expr: &Typed<'cx>,
+) -> Result<(), Error> {
+ let data = binary::encode(&expr.to_expr(cx))?;
File::create(path)?.write_all(data.as_slice())?;
Ok(())
}
diff --git a/dhall/src/semantics/resolve/env.rs b/dhall/src/semantics/resolve/env.rs
index 29dd16b..bde99d1 100644
--- a/dhall/src/semantics/resolve/env.rs
+++ b/dhall/src/semantics/resolve/env.rs
@@ -1,9 +1,9 @@
use std::collections::HashMap;
use crate::error::{Error, ImportError};
-use crate::semantics::{AlphaVar, Cache, ImportLocation, VarEnv};
+use crate::semantics::{check_hash, AlphaVar, Cache, ImportLocation, VarEnv};
use crate::syntax::{Hash, Label, V};
-use crate::Typed;
+use crate::{Ctxt, ImportId, ImportResultId, Typed};
/// Environment for resolving names.
#[derive(Debug, Clone, Default)]
@@ -11,14 +11,13 @@ pub struct NameEnv {
names: Vec<Label>,
}
-pub type MemCache = HashMap<ImportLocation, Typed>;
pub type CyclesStack = Vec<ImportLocation>;
/// Environment for resolving imports
-#[derive(Debug)]
-pub struct ImportEnv {
- disk_cache: Option<Cache>, // Missing if it failed to initialize
- mem_cache: MemCache,
+pub struct ImportEnv<'cx> {
+ cx: Ctxt<'cx>,
+ disk_cache: Option<Cache>, // `None` if it failed to initialize
+ mem_cache: HashMap<ImportLocation, ImportResultId<'cx>>,
stack: CyclesStack,
}
@@ -66,43 +65,61 @@ impl NameEnv {
}
}
-impl ImportEnv {
- pub fn new() -> Self {
+impl<'cx> ImportEnv<'cx> {
+ pub fn new(cx: Ctxt<'cx>) -> Self {
ImportEnv {
+ cx,
disk_cache: Cache::new().ok(),
mem_cache: Default::default(),
stack: Default::default(),
}
}
+ pub fn cx(&self) -> Ctxt<'cx> {
+ self.cx
+ }
+
pub fn get_from_mem_cache(
- &mut self,
+ &self,
location: &ImportLocation,
- ) -> Option<Typed> {
- Some(self.mem_cache.get(location)?.clone())
+ ) -> Option<ImportResultId<'cx>> {
+ Some(*self.mem_cache.get(location)?)
}
pub fn get_from_disk_cache(
- &mut self,
+ &self,
hash: &Option<Hash>,
- ) -> Option<Typed> {
+ ) -> Option<Typed<'cx>> {
let hash = hash.as_ref()?;
- let expr = self.disk_cache.as_ref()?.get(hash).ok()?;
+ let expr = self.disk_cache.as_ref()?.get(self.cx(), hash).ok()?;
Some(expr)
}
+ pub fn check_hash(
+ &self,
+ import: ImportId<'cx>,
+ result: ImportResultId<'cx>,
+ ) -> Result<(), Error> {
+ check_hash(self.cx(), import, result)
+ }
+
pub fn write_to_mem_cache(
&mut self,
location: ImportLocation,
- expr: Typed,
+ result: ImportResultId<'cx>,
) {
- self.mem_cache.insert(location, expr);
+ self.mem_cache.insert(location, result);
}
- pub fn write_to_disk_cache(&mut self, hash: &Option<Hash>, expr: &Typed) {
+ pub fn write_to_disk_cache(
+ &self,
+ hash: &Option<Hash>,
+ result: ImportResultId<'cx>,
+ ) {
if let Some(disk_cache) = self.disk_cache.as_ref() {
if let Some(hash) = hash {
- let _ = disk_cache.insert(hash, &expr);
+ let expr = &self.cx()[result];
+ let _ = disk_cache.insert(self.cx(), hash, expr);
}
}
}
@@ -110,8 +127,8 @@ impl ImportEnv {
pub fn with_cycle_detection(
&mut self,
location: ImportLocation,
- do_resolve: impl FnOnce(&mut Self) -> Result<Typed, Error>,
- ) -> Result<Typed, Error> {
+ do_resolve: impl FnOnce(&mut Self) -> Result<Typed<'cx>, Error>,
+ ) -> Result<Typed<'cx>, Error> {
if self.stack.contains(&location) {
return Err(
ImportError::ImportCycle(self.stack.clone(), location).into()
diff --git a/dhall/src/semantics/resolve/hir.rs b/dhall/src/semantics/resolve/hir.rs
index 8869915..8baad10 100644
--- a/dhall/src/semantics/resolve/hir.rs
+++ b/dhall/src/semantics/resolve/hir.rs
@@ -1,7 +1,7 @@
use crate::error::TypeError;
-use crate::semantics::{type_with, NameEnv, Nir, NzEnv, Tir, TyEnv, Type};
+use crate::semantics::{type_with, typecheck, NameEnv, Nir, NzEnv, Tir, TyEnv};
use crate::syntax::{Expr, ExprKind, Span, V};
-use crate::ToExprOptions;
+use crate::{Ctxt, ImportAlternativeId, ImportId, ToExprOptions};
/// Stores an alpha-normalized variable.
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
@@ -10,19 +10,23 @@ pub struct AlphaVar {
}
#[derive(Debug, Clone, PartialEq, Eq)]
-pub enum HirKind {
+pub enum HirKind<'cx> {
/// A resolved variable (i.e. a DeBruijn index)
Var(AlphaVar),
- /// Result of resolving an import.
- Import(Hir, Type),
+ /// A variable that couldn't be resolved. Detected during resolution, but causes an error during typeck.
+ MissingVar(V),
+ /// An import. It must have been resolved after resolution.
+ Import(ImportId<'cx>),
+ /// An import alternative. It must have been decided after resolution.
+ ImportAlternative(ImportAlternativeId<'cx>, Hir<'cx>, Hir<'cx>),
// Forbidden ExprKind variants: Var, Import, Completion
- Expr(ExprKind<Hir>),
+ Expr(ExprKind<Hir<'cx>>),
}
// An expression with resolved variables and imports.
#[derive(Debug, Clone)]
-pub struct Hir {
- kind: Box<HirKind>,
+pub struct Hir<'cx> {
+ kind: Box<HirKind<'cx>>,
span: Span,
}
@@ -35,15 +39,15 @@ impl AlphaVar {
}
}
-impl Hir {
- pub fn new(kind: HirKind, span: Span) -> Self {
+impl<'cx> Hir<'cx> {
+ pub fn new(kind: HirKind<'cx>, span: Span) -> Self {
Hir {
kind: Box::new(kind),
span,
}
}
- pub fn kind(&self) -> &HirKind {
+ pub fn kind(&self) -> &HirKind<'cx> {
&*self.kind
}
pub fn span(&self) -> Span {
@@ -51,59 +55,78 @@ impl Hir {
}
/// Converts a closed Hir expr back to the corresponding AST expression.
- pub fn to_expr(&self, opts: ToExprOptions) -> Expr {
- hir_to_expr(self, opts, &mut NameEnv::new())
+ pub fn to_expr(&self, cx: Ctxt<'cx>, opts: ToExprOptions) -> Expr {
+ hir_to_expr(cx, self, opts, &mut NameEnv::new())
}
/// Converts a closed Hir expr back to the corresponding AST expression.
- pub fn to_expr_noopts(&self) -> Expr {
+ pub fn to_expr_noopts(&self, cx: Ctxt<'cx>) -> Expr {
let opts = ToExprOptions { alpha: false };
- self.to_expr(opts)
+ self.to_expr(cx, opts)
}
- pub fn to_expr_alpha(&self) -> Expr {
+ pub fn to_expr_alpha(&self, cx: Ctxt<'cx>) -> Expr {
let opts = ToExprOptions { alpha: true };
- self.to_expr(opts)
+ self.to_expr(cx, opts)
}
- pub fn to_expr_tyenv(&self, env: &TyEnv) -> Expr {
+ pub fn to_expr_tyenv(&self, env: &TyEnv<'cx>) -> Expr {
let opts = ToExprOptions { alpha: false };
+ let cx = env.cx();
let mut env = env.as_nameenv().clone();
- hir_to_expr(self, opts, &mut env)
+ hir_to_expr(cx, self, opts, &mut env)
}
/// Typecheck the Hir.
pub fn typecheck<'hir>(
&'hir self,
- env: &TyEnv,
- ) -> Result<Tir<'hir>, TypeError> {
+ env: &TyEnv<'cx>,
+ ) -> Result<Tir<'cx, 'hir>, TypeError> {
type_with(env, self, None)
}
- pub fn typecheck_noenv<'hir>(&'hir self) -> Result<Tir<'hir>, TypeError> {
- self.typecheck(&TyEnv::new())
+ pub fn typecheck_noenv<'hir>(
+ &'hir self,
+ cx: Ctxt<'cx>,
+ ) -> Result<Tir<'cx, 'hir>, TypeError> {
+ typecheck(cx, self)
}
/// Eval the Hir. It will actually get evaluated only as needed on demand.
- pub fn eval(&self, env: impl Into<NzEnv>) -> Nir {
+ pub fn eval(&self, env: impl Into<NzEnv<'cx>>) -> Nir<'cx> {
Nir::new_thunk(env.into(), self.clone())
}
/// Eval a closed Hir (i.e. without free variables). It will actually get evaluated only as
/// needed on demand.
- pub fn eval_closed_expr(&self) -> Nir {
- self.eval(NzEnv::new())
+ pub fn eval_closed_expr(&self, cx: Ctxt<'cx>) -> Nir<'cx> {
+ self.eval(NzEnv::new(cx))
}
}
-fn hir_to_expr(hir: &Hir, opts: ToExprOptions, env: &mut NameEnv) -> Expr {
+fn hir_to_expr<'cx>(
+ cx: Ctxt<'cx>,
+ hir: &Hir<'cx>,
+ opts: ToExprOptions,
+ env: &mut NameEnv,
+) -> Expr {
let kind = match hir.kind() {
HirKind::Var(v) if opts.alpha => ExprKind::Var(V("_".into(), v.idx())),
HirKind::Var(v) => ExprKind::Var(env.label_var(*v)),
- HirKind::Import(hir, _) => {
- return hir_to_expr(hir, opts, &mut NameEnv::new())
+ HirKind::MissingVar(v) => ExprKind::Var(v.clone()),
+ HirKind::Import(import) => {
+ let typed = cx[import].unwrap_result();
+ return hir_to_expr(cx, &typed.hir, opts, &mut NameEnv::new());
+ }
+ HirKind::ImportAlternative(alt, left, right) => {
+ let hir = if cx[alt].unwrap_selected() {
+ left
+ } else {
+ right
+ };
+ return hir_to_expr(cx, hir, opts, env);
}
HirKind::Expr(e) => {
let e = e.map_ref_maybe_binder(|l, hir| {
if let Some(l) = l {
env.insert_mut(l);
}
- let e = hir_to_expr(hir, opts, env);
+ let e = hir_to_expr(cx, hir, opts, env);
if l.is_some() {
env.remove_mut();
}
@@ -124,9 +147,9 @@ fn hir_to_expr(hir: &Hir, opts: ToExprOptions, env: &mut NameEnv) -> Expr {
Expr::new(kind, hir.span())
}
-impl std::cmp::PartialEq for Hir {
+impl<'cx> std::cmp::PartialEq for Hir<'cx> {
fn eq(&self, other: &Self) -> bool {
self.kind == other.kind
}
}
-impl std::cmp::Eq for Hir {}
+impl<'cx> std::cmp::Eq for Hir<'cx> {}
diff --git a/dhall/src/semantics/resolve/resolve.rs b/dhall/src/semantics/resolve/resolve.rs
index 16987de..116e1a5 100644
--- a/dhall/src/semantics/resolve/resolve.rs
+++ b/dhall/src/semantics/resolve/resolve.rs
@@ -15,7 +15,10 @@ use crate::syntax::{
Expr, ExprKind, FilePath, FilePrefix, Hash, ImportMode, ImportTarget, Span,
UnspannedExpr, URL,
};
-use crate::{Parsed, Resolved, Typed};
+use crate::{
+ Ctxt, ImportAlternativeId, ImportId, ImportResultId, Parsed, Resolved,
+ Typed,
+};
// TODO: evaluate import headers
pub type Import = syntax::Import<()>;
@@ -29,8 +32,10 @@ enum ImportLocationKind {
Remote(Url),
/// Environment variable
Env(String),
- /// Data without a location
+ /// Data without a location; chaining will start from current directory.
Missing,
+ /// Token to signal that thi sfile should contain no imports.
+ NoImport,
}
/// The location of some data.
@@ -101,6 +106,7 @@ impl ImportLocationKind {
url = url.join(&path.file_path.join("/"))?;
ImportLocationKind::Remote(url)
}
+ ImportLocationKind::NoImport => unreachable!(),
})
}
@@ -120,6 +126,7 @@ impl ImportLocationKind {
ImportLocationKind::Missing => {
return Err(ImportError::Missing.into())
}
+ ImportLocationKind::NoImport => unreachable!(),
})
}
@@ -134,6 +141,7 @@ impl ImportLocationKind {
ImportLocationKind::Missing => {
return Err(ImportError::Missing.into())
}
+ ImportLocationKind::NoImport => unreachable!(),
})
}
@@ -149,6 +157,7 @@ impl ImportLocationKind {
("Environment", Some(name.clone()))
}
ImportLocationKind::Missing => ("Missing", None),
+ ImportLocationKind::NoImport => unreachable!(),
};
let asloc_ty = make_aslocation_uniontype();
@@ -171,6 +180,12 @@ impl ImportLocation {
mode: ImportMode::Code,
}
}
+ pub fn dhall_code_without_imports() -> Self {
+ ImportLocation {
+ kind: ImportLocationKind::NoImport,
+ mode: ImportMode::Code,
+ }
+ }
pub fn local_dhall_code(path: PathBuf) -> Self {
ImportLocation {
kind: ImportLocationKind::Local(path),
@@ -191,6 +206,10 @@ impl ImportLocation {
fn chain(&self, import: &Import) -> Result<ImportLocation, Error> {
// Makes no sense to chain an import if the current file is not a dhall file.
assert!(matches!(self.mode, ImportMode::Code));
+ if matches!(self.kind, ImportLocationKind::NoImport) {
+ Err(ImportError::UnexpectedImport(import.clone()))?;
+ }
+
let kind = match &import.location {
ImportTarget::Local(prefix, path) => {
self.kind.chain_local(*prefix, path)?
@@ -227,30 +246,42 @@ impl ImportLocation {
}
/// Fetches the expression corresponding to this location.
- fn fetch(&self, env: &mut ImportEnv, span: Span) -> Result<Typed, Error> {
- let (hir, ty) = match self.mode {
+ fn fetch<'cx>(
+ &self,
+ env: &mut ImportEnv<'cx>,
+ span: Span,
+ ) -> Result<Typed<'cx>, Error> {
+ let cx = env.cx();
+ let typed = match self.mode {
ImportMode::Code => {
let parsed = self.kind.fetch_dhall()?;
- let typed = resolve_with_env(env, parsed)?.typecheck()?;
- let hir = typed.normalize().to_hir();
- (hir, typed.ty)
+ let typed = parsed.resolve_with_env(env)?.typecheck(cx)?;
+ Typed {
+ // TODO: manage to keep the Nir around. Will need fixing variables.
+ hir: typed.normalize(cx).to_hir(),
+ ty: typed.ty,
+ }
}
ImportMode::RawText => {
let text = self.kind.fetch_text()?;
- let hir = Hir::new(
- HirKind::Expr(ExprKind::TextLit(text.into())),
- span,
- );
- (hir, Type::from_builtin(Builtin::Text))
+ Typed {
+ hir: Hir::new(
+ HirKind::Expr(ExprKind::TextLit(text.into())),
+ span,
+ ),
+ ty: Type::from_builtin(cx, Builtin::Text),
+ }
}
ImportMode::Location => {
let expr = self.kind.to_location();
- let hir = skip_resolve_expr(&expr)?;
- let ty = hir.typecheck_noenv()?.ty().clone();
- (hir, ty)
+ Parsed::from_expr_without_imports(expr)
+ .resolve(cx)
+ .unwrap()
+ .typecheck(cx)
+ .unwrap()
}
};
- Ok(Typed { hir, ty })
+ Ok(typed)
}
}
@@ -282,15 +313,21 @@ fn make_aslocation_uniontype() -> Expr {
mkexpr(ExprKind::UnionType(union))
}
-fn check_hash(import: &Import, typed: &Typed, span: Span) -> Result<(), Error> {
+pub fn check_hash<'cx>(
+ cx: Ctxt<'cx>,
+ import: ImportId<'cx>,
+ result: ImportResultId<'cx>,
+) -> Result<(), Error> {
+ let import = &cx[import];
if let (ImportMode::Code, Some(Hash::SHA256(hash))) =
- (import.mode, &import.hash)
+ (import.import.mode, &import.import.hash)
{
- let actual_hash = typed.hir.to_expr_alpha().sha256_hash()?;
+ let expr = cx[result].hir.to_expr_alpha(cx);
+ let actual_hash = expr.sha256_hash()?;
if hash[..] != actual_hash[..] {
mkerr(
ErrorBuilder::new("hash mismatch")
- .span_err(span, "hash mismatch")
+ .span_err(import.span.clone(), "hash mismatch")
.note(format!("Expected sha256:{}", hex::encode(hash)))
.note(format!(
"Found sha256:{}",
@@ -332,127 +369,204 @@ fn desugar(expr: &Expr) -> Cow<'_, Expr> {
}
}
-/// Traverse the expression, handling import alternatives and passing
-/// found imports to the provided function. Also resolving names.
-fn traverse_resolve_expr(
+/// Fetch the import and store the result in the global context.
+fn fetch_import<'cx>(
+ env: &mut ImportEnv<'cx>,
+ import_id: ImportId<'cx>,
+) -> Result<ImportResultId<'cx>, Error> {
+ let cx = env.cx();
+ let import = &cx[import_id].import;
+ let span = cx[import_id].span.clone();
+ let location = cx[import_id].base_location.chain(import)?;
+
+ // If the import is in the in-memory cache, or the hash is in the on-disk cache, return
+ // the cached contents.
+ if let Some(res_id) = env.get_from_mem_cache(&location) {
+ // The same location may be used with different or no hashes. Thus we need to check
+ // the hashes every time.
+ env.check_hash(import_id, res_id)?;
+ env.write_to_disk_cache(&import.hash, res_id);
+ return Ok(res_id);
+ }
+ if let Some(typed) = env.get_from_disk_cache(&import.hash) {
+ // No need to check the hash, it was checked before reading the file.
+ // We also don't write to the in-memory cache, because the location might be completely
+ // unrelated to the cached file (e.g. `missing sha256:...` is valid).
+ // This actually means that importing many times a same hashed import will take
+ // longer than importing many times a same non-hashed import.
+ let res_id = cx.push_import_result(typed);
+ return Ok(res_id);
+ }
+
+ // Resolve this import, making sure that recursive imports don't cycle back to the
+ // current one.
+ let res = env.with_cycle_detection(location.clone(), |env| {
+ location.fetch(env, span.clone())
+ });
+ let typed = match res {
+ Ok(typed) => typed,
+ Err(e) => mkerr(
+ ErrorBuilder::new("error")
+ .span_err(span.clone(), e.to_string())
+ .format(),
+ )?,
+ };
+
+ // Add the resolved import to the caches
+ let res_id = cx.push_import_result(typed);
+ env.check_hash(import_id, res_id)?;
+ env.write_to_disk_cache(&import.hash, res_id);
+ // Cache the mapping from this location to the result.
+ env.write_to_mem_cache(location, res_id);
+
+ Ok(res_id)
+}
+
+/// Part of a tree of imports.
+#[derive(Debug, Clone, Copy)]
+pub enum ImportNode<'cx> {
+ Import(ImportId<'cx>),
+ Alternative(ImportAlternativeId<'cx>),
+}
+
+/// Traverse the expression and replace each import and import alternative by an id into the global
+/// context. The ids are also accumulated into `nodes` so that we can resolve them afterwards.
+fn traverse_accumulate<'cx>(
+ env: &mut ImportEnv<'cx>,
name_env: &mut NameEnv,
+ nodes: &mut Vec<ImportNode<'cx>>,
+ base_location: &ImportLocation,
expr: &Expr,
- f: &mut impl FnMut(Import, Span) -> Result<Typed, Error>,
-) -> Result<Hir, Error> {
+) -> Hir<'cx> {
+ let cx = env.cx();
let expr = desugar(expr);
- Ok(match expr.kind() {
+ let kind = match expr.kind() {
ExprKind::Var(var) => match name_env.unlabel_var(&var) {
- Some(v) => Hir::new(HirKind::Var(v), expr.span()),
- None => mkerr(
- ErrorBuilder::new(format!("unbound variable `{}`", var))
- .span_err(expr.span(), "not found in this scope")
- .format(),
- )?,
+ Some(v) => HirKind::Var(v),
+ None => HirKind::MissingVar(var.clone()),
},
ExprKind::Op(OpKind::BinOp(BinOp::ImportAlt, l, r)) => {
- match traverse_resolve_expr(name_env, l, f) {
- Ok(l) => l,
- Err(_) => {
- match traverse_resolve_expr(name_env, r, f) {
- Ok(r) => r,
- // TODO: keep track of the other error too
- Err(e) => return Err(e),
- }
- }
- }
+ let mut imports_l = Vec::new();
+ let l = traverse_accumulate(
+ env,
+ name_env,
+ &mut imports_l,
+ base_location,
+ l,
+ );
+ let mut imports_r = Vec::new();
+ let r = traverse_accumulate(
+ env,
+ name_env,
+ &mut imports_r,
+ base_location,
+ r,
+ );
+ let alt =
+ cx.push_import_alternative(imports_l.into(), imports_r.into());
+ nodes.push(ImportNode::Alternative(alt));
+ HirKind::ImportAlternative(alt, l, r)
}
kind => {
- let kind = kind.traverse_ref_maybe_binder(|l, e| {
+ let kind = kind.map_ref_maybe_binder(|l, e| {
if let Some(l) = l {
name_env.insert_mut(l);
}
- let hir = traverse_resolve_expr(name_env, e, f)?;
+ let hir =
+ traverse_accumulate(env, name_env, nodes, base_location, e);
if l.is_some() {
name_env.remove_mut();
}
- Ok::<_, Error>(hir)
- })?;
- let kind = match kind {
+ hir
+ });
+ match kind {
ExprKind::Import(import) => {
// TODO: evaluate import headers
- let import = import.traverse_ref(|_| Ok::<_, Error>(()))?;
- let imported = f(import, expr.span())?;
- HirKind::Import(imported.hir, imported.ty)
+ let import = import.map_ref(|_| ());
+ let import_id = cx.push_import(
+ base_location.clone(),
+ import,
+ expr.span(),
+ );
+ nodes.push(ImportNode::Import(import_id));
+ HirKind::Import(import_id)
}
kind => HirKind::Expr(kind),
- };
- Hir::new(kind, expr.span())
+ }
}
- })
+ };
+ Hir::new(kind, expr.span())
}
-fn resolve_with_env(
- env: &mut ImportEnv,
+/// Take a list of nodes and recursively resolve them.
+fn resolve_nodes<'cx>(
+ env: &mut ImportEnv<'cx>,
+ nodes: &[ImportNode<'cx>],
+) -> Result<(), Error> {
+ for &node in nodes {
+ match node {
+ ImportNode::Import(import) => {
+ let res_id = fetch_import(env, import)?;
+ env.cx()[import].set_resultid(res_id);
+ }
+ ImportNode::Alternative(alt) => {
+ let alt = &env.cx()[alt];
+ if resolve_nodes(env, &alt.left_imports).is_ok() {
+ alt.set_selected(true);
+ } else {
+ resolve_nodes(env, &alt.right_imports)?;
+ alt.set_selected(false);
+ }
+ }
+ }
+ }
+ Ok(())
+}
+
+fn resolve_with_env<'cx>(
+ env: &mut ImportEnv<'cx>,
parsed: Parsed,
-) -> Result<Resolved, Error> {
+) -> Result<Resolved<'cx>, Error> {
let Parsed(expr, base_location) = parsed;
- let resolved = traverse_resolve_expr(
+ let mut nodes = Vec::new();
+ // First we collect all imports.
+ let resolved = traverse_accumulate(
+ env,
&mut NameEnv::new(),
+ &mut nodes,
+ &base_location,
&expr,
- &mut |import, span| {
- let location = base_location.chain(&import)?;
-
- // If the import is in the in-memory cache, or the hash is in the on-disk cache, return
- // the cached contents.
- if let Some(typed) = env.get_from_mem_cache(&location) {
- // The same location may be used with different or no hashes. Thus we need to check
- // the hashes every time.
- check_hash(&import, &typed, span)?;
- env.write_to_disk_cache(&import.hash, &typed);
- return Ok(typed);
- }
- if let Some(typed) = env.get_from_disk_cache(&import.hash) {
- // No need to check the hash, it was checked before reading the file. We also don't
- // write to the in-memory cache, because the location might be completely unrelated
- // to the cached file (e.g. `missing sha256:...` is valid).
- // This actually means that importing many times a same hashed import will take
- // longer than importing many times a same non-hashed import.
- return Ok(typed);
- }
-
- // Resolve this import, making sure that recursive imports don't cycle back to the
- // current one.
- let res = env.with_cycle_detection(location.clone(), |env| {
- location.fetch(env, span.clone())
- });
- let typed = match res {
- Ok(typed) => typed,
- Err(e) => mkerr(
- ErrorBuilder::new("error")
- .span_err(span.clone(), e.to_string())
- .format(),
- )?,
- };
-
- // Add the resolved import to the caches
- check_hash(&import, &typed, span)?;
- env.write_to_disk_cache(&import.hash, &typed);
- env.write_to_mem_cache(location, typed.clone());
- Ok(typed)
- },
- )?;
+ );
+ // Then we resolve them and choose sides for the alternatives.
+ resolve_nodes(env, &nodes)?;
Ok(Resolved(resolved))
}
-pub fn resolve(parsed: Parsed) -> Result<Resolved, Error> {
- resolve_with_env(&mut ImportEnv::new(), parsed)
+/// Resolves all imports and names. Returns errors if importing failed. Name errors are deferred to
+/// typechecking.
+pub fn resolve<'cx>(
+ cx: Ctxt<'cx>,
+ parsed: Parsed,
+) -> Result<Resolved<'cx>, Error> {
+ parsed.resolve_with_env(&mut ImportEnv::new(cx))
}
-pub fn skip_resolve_expr(expr: &Expr) -> Result<Hir, Error> {
- traverse_resolve_expr(&mut NameEnv::new(), expr, &mut |import, _span| {
- Err(ImportError::UnexpectedImport(import).into())
- })
+/// Resolves names, and errors if we find any imports.
+pub fn skip_resolve<'cx>(
+ cx: Ctxt<'cx>,
+ parsed: Parsed,
+) -> Result<Resolved<'cx>, Error> {
+ let parsed = Parsed::from_expr_without_imports(parsed.0);
+ Ok(resolve(cx, parsed)?)
}
-pub fn skip_resolve(parsed: Parsed) -> Result<Resolved, Error> {
- let Parsed(expr, _) = parsed;
- let resolved = skip_resolve_expr(&expr)?;
- Ok(Resolved(resolved))
+impl Parsed {
+ fn resolve_with_env<'cx>(
+ self,
+ env: &mut ImportEnv<'cx>,
+ ) -> Result<Resolved<'cx>, Error> {
+ resolve_with_env(env, self)
+ }
}
pub trait Canonicalize {
diff --git a/dhall/src/semantics/tck/env.rs b/dhall/src/semantics/tck/env.rs
index 1fa66f0..fdcc62d 100644
--- a/dhall/src/semantics/tck/env.rs
+++ b/dhall/src/semantics/tck/env.rs
@@ -1,5 +1,6 @@
use crate::semantics::{AlphaVar, NameEnv, Nir, NzEnv, NzVar, Type, ValEnv};
use crate::syntax::Label;
+use crate::Ctxt;
/// Environment for indexing variables.
#[derive(Debug, Clone, Copy, Default)]
@@ -9,9 +10,10 @@ pub struct VarEnv {
/// Environment for typing expressions.
#[derive(Debug, Clone)]
-pub struct TyEnv {
+pub struct TyEnv<'cx> {
+ cx: Ctxt<'cx>,
names: NameEnv,
- items: ValEnv<Type>,
+ items: ValEnv<'cx, Type<'cx>>,
}
impl VarEnv {
@@ -38,42 +40,48 @@ impl VarEnv {
}
}
-impl TyEnv {
- pub fn new() -> Self {
+impl<'cx> TyEnv<'cx> {
+ pub fn new(cx: Ctxt<'cx>) -> Self {
TyEnv {
+ cx,
names: NameEnv::new(),
- items: ValEnv::new(),
+ items: ValEnv::new(cx),
}
}
+ pub fn cx(&self) -> Ctxt<'cx> {
+ self.cx
+ }
pub fn as_varenv(&self) -> VarEnv {
self.names.as_varenv()
}
- pub fn to_nzenv(&self) -> NzEnv {
+ pub fn to_nzenv(&self) -> NzEnv<'cx> {
self.items.discard_types()
}
pub fn as_nameenv(&self) -> &NameEnv {
&self.names
}
- pub fn insert_type(&self, x: &Label, ty: Type) -> Self {
+ pub fn insert_type(&self, x: &Label, ty: Type<'cx>) -> Self {
TyEnv {
+ cx: self.cx,
names: self.names.insert(x),
items: self.items.insert_type(ty),
}
}
- pub fn insert_value(&self, x: &Label, e: Nir, ty: Type) -> Self {
+ pub fn insert_value(&self, x: &Label, e: Nir<'cx>, ty: Type<'cx>) -> Self {
TyEnv {
+ cx: self.cx,
names: self.names.insert(x),
items: self.items.insert_value(e, ty),
}
}
- pub fn lookup(&self, var: AlphaVar) -> Type {
+ pub fn lookup(&self, var: AlphaVar) -> Type<'cx> {
self.items.lookup_ty(var)
}
}
-impl<'a> From<&'a TyEnv> for NzEnv {
- fn from(x: &'a TyEnv) -> Self {
+impl<'a, 'cx> From<&'a TyEnv<'cx>> for NzEnv<'cx> {
+ fn from(x: &'a TyEnv<'cx>) -> Self {
x.to_nzenv()
}
}
diff --git a/dhall/src/semantics/tck/tir.rs b/dhall/src/semantics/tck/tir.rs
index f34802c..7b04f57 100644
--- a/dhall/src/semantics/tck/tir.rs
+++ b/dhall/src/semantics/tck/tir.rs
@@ -2,6 +2,7 @@ use crate::builtins::Builtin;
use crate::error::{ErrorBuilder, TypeError};
use crate::semantics::{mkerr, Hir, Nir, NirKind, NzEnv, TyEnv, VarEnv};
use crate::syntax::{Const, Expr, Span};
+use crate::Ctxt;
/// The type of a type. 0 is `Type`, 1 is `Kind`, etc...
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Default)]
@@ -9,17 +10,17 @@ pub struct Universe(u8);
/// An expression representing a type
#[derive(Debug, Clone, PartialEq, Eq)]
-pub struct Type {
- val: Nir,
+pub struct Type<'cx> {
+ val: Nir<'cx>,
univ: Universe,
}
/// A hir expression plus its inferred type.
/// Stands for "Typed intermediate representation"
#[derive(Debug, Clone)]
-pub struct Tir<'hir> {
- hir: &'hir Hir,
- ty: Type,
+pub struct Tir<'cx, 'hir> {
+ hir: &'hir Hir<'cx>,
+ ty: Type<'cx>,
}
impl Universe {
@@ -43,16 +44,16 @@ impl Universe {
}
}
-impl Type {
- pub fn new(val: Nir, univ: Universe) -> Self {
+impl<'cx> Type<'cx> {
+ pub fn new(val: Nir<'cx>, univ: Universe) -> Self {
Type { val, univ }
}
/// Creates a new Type and infers its universe by re-typechecking its value.
/// TODO: ideally avoid this function altogether. Would need to store types in RecordType and
/// PiClosure.
pub fn new_infer_universe(
- env: &TyEnv,
- val: Nir,
+ env: &TyEnv<'cx>,
+ val: Nir<'cx>,
) -> Result<Self, TypeError> {
let c = val.to_hir(env.as_varenv()).typecheck(env)?.ty().as_const();
let u = match c {
@@ -67,14 +68,14 @@ impl Type {
pub fn from_const(c: Const) -> Self {
Self::new(Nir::from_const(c), c.to_universe().next())
}
- pub fn from_builtin(b: Builtin) -> Self {
+ pub fn from_builtin(cx: Ctxt<'cx>, b: Builtin) -> Self {
use Builtin::*;
match b {
Bool | Natural | Integer | Double | Text => {}
_ => unreachable!("this builtin is not a type: {}", b),
}
- Self::new(Nir::from_builtin(b), Universe::from_const(Const::Type))
+ Self::new(Nir::from_builtin(cx, b), Universe::from_const(Const::Type))
}
/// Get the type of this type
@@ -82,60 +83,60 @@ impl Type {
self.univ
}
- pub fn to_nir(&self) -> Nir {
+ pub fn to_nir(&self) -> Nir<'cx> {
self.val.clone()
}
- pub fn as_nir(&self) -> &Nir {
+ pub fn as_nir(&self) -> &Nir<'cx> {
&self.val
}
- pub fn into_nir(self) -> Nir {
+ pub fn into_nir(self) -> Nir<'cx> {
self.val
}
pub fn as_const(&self) -> Option<Const> {
self.val.as_const()
}
- pub fn kind(&self) -> &NirKind {
+ pub fn kind(&self) -> &NirKind<'cx> {
self.val.kind()
}
- pub fn to_hir(&self, venv: VarEnv) -> Hir {
+ pub fn to_hir(&self, venv: VarEnv) -> Hir<'cx> {
self.val.to_hir(venv)
}
- pub fn to_expr_tyenv(&self, tyenv: &TyEnv) -> Expr {
+ pub fn to_expr_tyenv(&self, tyenv: &TyEnv<'cx>) -> Expr {
self.val.to_hir(tyenv.as_varenv()).to_expr_tyenv(tyenv)
}
}
-impl<'hir> Tir<'hir> {
- pub fn from_hir(hir: &'hir Hir, ty: Type) -> Self {
+impl<'cx, 'hir> Tir<'cx, 'hir> {
+ pub fn from_hir(hir: &'hir Hir<'cx>, ty: Type<'cx>) -> Self {
Tir { hir, ty }
}
pub fn span(&self) -> Span {
self.as_hir().span()
}
- pub fn ty(&self) -> &Type {
+ pub fn ty(&self) -> &Type<'cx> {
&self.ty
}
- pub fn into_ty(self) -> Type {
+ pub fn into_ty(self) -> Type<'cx> {
self.ty
}
- pub fn to_hir(&self) -> Hir {
+ pub fn to_hir(&self) -> Hir<'cx> {
self.as_hir().clone()
}
- pub fn as_hir(&self) -> &Hir {
- &self.hir
+ pub fn as_hir(&self) -> &'hir Hir<'cx> {
+ self.hir
}
- pub fn to_expr_tyenv(&self, env: &TyEnv) -> Expr {
+ pub fn to_expr_tyenv(&self, env: &TyEnv<'cx>) -> Expr {
self.as_hir().to_expr_tyenv(env)
}
/// Eval the Tir. It will actually get evaluated only as needed on demand.
- pub fn eval(&self, env: impl Into<NzEnv>) -> Nir {
+ pub fn eval(&self, env: impl Into<NzEnv<'cx>>) -> Nir<'cx> {
self.as_hir().eval(env.into())
}
- pub fn ensure_is_type(&self, env: &TyEnv) -> Result<(), TypeError> {
+ pub fn ensure_is_type(&self, env: &TyEnv<'cx>) -> Result<(), TypeError> {
if self.ty().as_const().is_none() {
return mkerr(
ErrorBuilder::new(format!(
@@ -159,7 +160,10 @@ impl<'hir> Tir<'hir> {
Ok(())
}
/// Evaluate to a Type.
- pub fn eval_to_type(&self, env: &TyEnv) -> Result<Type, TypeError> {
+ pub fn eval_to_type(
+ &self,
+ env: &TyEnv<'cx>,
+ ) -> Result<Type<'cx>, TypeError> {
self.ensure_is_type(env)?;
Ok(Type::new(
self.eval(env),
diff --git a/dhall/src/semantics/tck/typecheck.rs b/dhall/src/semantics/tck/typecheck.rs
index 498bd76..23c2bd2 100644
--- a/dhall/src/semantics/tck/typecheck.rs
+++ b/dhall/src/semantics/tck/typecheck.rs
@@ -5,6 +5,7 @@ use crate::error::{ErrorBuilder, TypeError, TypeMessage};
use crate::operations::typecheck_operation;
use crate::semantics::{Hir, HirKind, Nir, NirKind, Tir, TyEnv, Type};
use crate::syntax::{Const, ExprKind, InterpolatedTextContents, NumKind, Span};
+use crate::Ctxt;
fn function_check(a: Const, b: Const) -> Const {
if b == Const::Type {
@@ -28,11 +29,12 @@ pub fn mk_span_err<T, S: ToString>(span: Span, msg: S) -> Result<T, TypeError> {
/// When all sub-expressions have been typed, check the remaining toplevel
/// layer.
-fn type_one_layer(
- env: &TyEnv,
- ekind: ExprKind<Tir<'_>>,
+fn type_one_layer<'cx>(
+ env: &TyEnv<'cx>,
+ ekind: ExprKind<Tir<'cx, '_>>,
span: Span,
-) -> Result<Type, TypeError> {
+) -> Result<Type<'cx>, TypeError> {
+ let cx = env.cx();
let span_err = |msg: &str| mk_span_err(span.clone(), msg);
Ok(match ekind {
@@ -50,18 +52,21 @@ fn type_one_layer(
ExprKind::Const(Const::Type) => Type::from_const(Const::Kind),
ExprKind::Const(Const::Kind) => Type::from_const(Const::Sort),
- ExprKind::Num(num) => Type::from_builtin(match num {
- NumKind::Bool(_) => Builtin::Bool,
- NumKind::Natural(_) => Builtin::Natural,
- NumKind::Integer(_) => Builtin::Integer,
- NumKind::Double(_) => Builtin::Double,
- }),
+ ExprKind::Num(num) => Type::from_builtin(
+ cx,
+ match num {
+ NumKind::Bool(_) => Builtin::Bool,
+ NumKind::Natural(_) => Builtin::Natural,
+ NumKind::Integer(_) => Builtin::Integer,
+ NumKind::Double(_) => Builtin::Double,
+ },
+ ),
ExprKind::Builtin(b) => {
- let t_hir = type_of_builtin(b);
- typecheck(&t_hir)?.eval_to_type(env)?
+ let t_hir = type_of_builtin(cx, b);
+ typecheck(cx, &t_hir)?.eval_to_type(env)?
}
ExprKind::TextLit(interpolated) => {
- let text_type = Type::from_builtin(Builtin::Text);
+ let text_type = Type::from_builtin(cx, Builtin::Text);
for contents in interpolated.iter() {
use InterpolatedTextContents::Expr;
if let Expr(x) = contents {
@@ -78,7 +83,7 @@ fn type_one_layer(
}
let t = x.ty().to_nir();
- Nir::from_builtin(Builtin::Optional)
+ Nir::from_builtin(cx, Builtin::Optional)
.app(t)
.to_type(Const::Type)
}
@@ -103,7 +108,9 @@ fn type_one_layer(
}
let t = x.ty().to_nir();
- Nir::from_builtin(Builtin::List).app(t).to_type(Const::Type)
+ Nir::from_builtin(cx, Builtin::List)
+ .app(t)
+ .to_type(Const::Type)
}
ExprKind::RecordLit(kvs) => {
// An empty record type has type Type
@@ -170,14 +177,30 @@ fn type_one_layer(
/// to compare with.
// We pass the annotation to avoid duplicating the annot checking logic. I hope one day we can use
// it to handle the annotations in merge/toMap/etc. uniformly.
-pub fn type_with<'hir>(
- env: &TyEnv,
- hir: &'hir Hir,
- annot: Option<Type>,
-) -> Result<Tir<'hir>, TypeError> {
+pub fn type_with<'cx, 'hir>(
+ env: &TyEnv<'cx>,
+ hir: &'hir Hir<'cx>,
+ annot: Option<Type<'cx>>,
+) -> Result<Tir<'cx, 'hir>, TypeError> {
let tir = match hir.kind() {
HirKind::Var(var) => Tir::from_hir(hir, env.lookup(*var)),
- HirKind::Import(_, ty) => Tir::from_hir(hir, ty.clone()),
+ HirKind::MissingVar(var) => mkerr(
+ ErrorBuilder::new(format!("unbound variable `{}`", var))
+ .span_err(hir.span(), "not found in this scope")
+ .format(),
+ )?,
+ HirKind::Import(import) => {
+ let typed = env.cx()[import].unwrap_result();
+ Tir::from_hir(hir, typed.ty.clone())
+ }
+ HirKind::ImportAlternative(alt, left, right) => {
+ let hir = if env.cx()[alt].unwrap_selected() {
+ left
+ } else {
+ right
+ };
+ return type_with(env, hir, annot);
+ }
HirKind::Expr(ExprKind::Var(_)) => {
unreachable!("Hir should contain no unresolved variables")
}
@@ -267,15 +290,19 @@ pub fn type_with<'hir>(
/// Typecheck an expression and return the expression annotated with its type if type-checking
/// succeeded, or an error if type-checking failed.
-pub fn typecheck<'hir>(hir: &'hir Hir) -> Result<Tir<'hir>, TypeError> {
- type_with(&TyEnv::new(), hir, None)
+pub fn typecheck<'cx, 'hir>(
+ cx: Ctxt<'cx>,
+ hir: &'hir Hir<'cx>,
+) -> Result<Tir<'cx, 'hir>, TypeError> {
+ type_with(&TyEnv::new(cx), hir, None)
}
/// Like `typecheck`, but additionally checks that the expression's type matches the provided type.
-pub fn typecheck_with<'hir>(
- hir: &'hir Hir,
- ty: &Hir,
-) -> Result<Tir<'hir>, TypeError> {
- let ty = typecheck(ty)?.eval_to_type(&TyEnv::new())?;
- type_with(&TyEnv::new(), hir, Some(ty))
+pub fn typecheck_with<'cx, 'hir>(
+ cx: Ctxt<'cx>,
+ hir: &'hir Hir<'cx>,
+ ty: &Hir<'cx>,
+) -> Result<Tir<'cx, 'hir>, TypeError> {
+ let ty = typecheck(cx, ty)?.eval_to_type(&TyEnv::new(cx))?;
+ type_with(&TyEnv::new(cx), hir, Some(ty))
}