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|
use std::borrow::Cow;
use std::cmp::max;
use std::collections::HashMap;
use crate::error::{ErrorBuilder, TypeError, TypeMessage};
use crate::semantics::merge_maps;
use crate::semantics::{
type_of_builtin, Binder, BuiltinClosure, Closure, Hir, HirKind, Nir,
NirKind, Tir, TyEnv, Type,
};
use crate::syntax::{
BinOp, Builtin, Const, ExprKind, InterpolatedTextContents, LitKind, Span,
};
fn check_rectymerge(
span: &Span,
env: &TyEnv,
x: Nir,
y: Nir,
) -> Result<(), TypeError> {
let kts_x = match x.kind() {
NirKind::RecordType(kts) => kts,
_ => {
return mk_span_err(
span.clone(),
"RecordTypeMergeRequiresRecordType",
)
}
};
let kts_y = match y.kind() {
NirKind::RecordType(kts) => kts,
_ => {
return mk_span_err(
span.clone(),
"RecordTypeMergeRequiresRecordType",
)
}
};
for (k, tx) in kts_x {
if let Some(ty) = kts_y.get(k) {
// TODO: store Type in RecordType ?
check_rectymerge(span, env, tx.clone(), ty.clone())?;
}
}
Ok(())
}
fn function_check(a: Const, b: Const) -> Const {
if b == Const::Type {
Const::Type
} else {
max(a, b)
}
}
pub(crate) fn mkerr<T, S: ToString>(msg: S) -> Result<T, TypeError> {
Err(TypeError::new(TypeMessage::Custom(msg.to_string())))
}
pub(crate) fn mk_span_err<T, S: ToString>(
span: Span,
msg: S,
) -> Result<T, TypeError> {
mkerr(
ErrorBuilder::new(msg.to_string())
.span_err(span, msg.to_string())
.format(),
)
}
/// When all sub-expressions have been typed, check the remaining toplevel
/// layer.
fn type_one_layer(
env: &TyEnv,
ekind: ExprKind<Tir<'_>>,
span: Span,
) -> Result<Type, TypeError> {
let span_err = |msg: &str| mk_span_err(span.clone(), msg);
let ty = match &ekind {
ExprKind::Import(..) | ExprKind::Completion(..) => {
unreachable!("This case should have been handled in resolution")
}
ExprKind::Var(..)
| ExprKind::Const(Const::Sort)
| ExprKind::Lam(..)
| ExprKind::Pi(..)
| ExprKind::Let(..)
| ExprKind::Annot(..) => {
unreachable!("This case should have been handled in type_with")
}
ExprKind::Const(Const::Type) => Type::from_const(Const::Kind),
ExprKind::Const(Const::Kind) => Type::from_const(Const::Sort),
ExprKind::Builtin(b) => {
let t_hir = type_of_builtin(*b);
typecheck(&t_hir)?.eval_to_type(env)?
}
ExprKind::Lit(LitKind::Bool(_)) => Type::from_builtin(Builtin::Bool),
ExprKind::Lit(LitKind::Natural(_)) => {
Type::from_builtin(Builtin::Natural)
}
ExprKind::Lit(LitKind::Integer(_)) => {
Type::from_builtin(Builtin::Integer)
}
ExprKind::Lit(LitKind::Double(_)) => {
Type::from_builtin(Builtin::Double)
}
ExprKind::TextLit(interpolated) => {
let text_type = Type::from_builtin(Builtin::Text);
for contents in interpolated.iter() {
use InterpolatedTextContents::Expr;
if let Expr(x) = contents {
if *x.ty() != text_type {
return span_err("InvalidTextInterpolation");
}
}
}
text_type
}
ExprKind::EmptyListLit(t) => {
let t = t.eval_to_type(env)?;
match t.kind() {
NirKind::AppliedBuiltin(BuiltinClosure {
b: Builtin::List,
args,
..
}) if args.len() == 1 => {}
_ => return span_err("InvalidListType"),
};
t
}
ExprKind::NEListLit(xs) => {
let mut iter = xs.iter();
let x = iter.next().unwrap();
for y in iter {
if x.ty() != y.ty() {
return span_err("InvalidListElement");
}
}
if x.ty().ty().as_const() != Some(Const::Type) {
return span_err("InvalidListType");
}
let t = x.ty().to_nir();
Nir::from_builtin(Builtin::List).app(t).to_type(Const::Type)
}
ExprKind::SomeLit(x) => {
if x.ty().ty().as_const() != Some(Const::Type) {
return span_err("InvalidOptionalType");
}
let t = x.ty().to_nir();
Nir::from_builtin(Builtin::Optional)
.app(t)
.to_type(Const::Type)
}
ExprKind::RecordLit(kvs) => {
use std::collections::hash_map::Entry;
let mut kts = HashMap::new();
// An empty record type has type Type
let mut k = Const::Type;
for (x, v) in kvs {
// Check for duplicated entries
match kts.entry(x.clone()) {
Entry::Occupied(_) => {
return span_err("RecordTypeDuplicateField")
}
Entry::Vacant(e) => e.insert(v.ty().to_nir()),
};
// Check that the fields have a valid kind
match v.ty().ty().as_const() {
Some(c) => k = max(k, c),
None => return span_err("InvalidFieldType"),
}
}
Nir::from_kind(NirKind::RecordType(kts)).to_type(k)
}
ExprKind::RecordType(kts) => {
use std::collections::hash_map::Entry;
let mut seen_fields = HashMap::new();
// An empty record type has type Type
let mut k = Const::Type;
for (x, t) in kts {
// Check for duplicated entries
match seen_fields.entry(x.clone()) {
Entry::Occupied(_) => {
return span_err("RecordTypeDuplicateField")
}
Entry::Vacant(e) => e.insert(()),
};
// Check the type is a Const and compute final type
match t.ty().as_const() {
Some(c) => k = max(k, c),
None => return span_err("InvalidFieldType"),
}
}
Type::from_const(k)
}
ExprKind::UnionType(kts) => {
use std::collections::hash_map::Entry;
let mut seen_fields = HashMap::new();
// Check that all types are the same const
let mut k = None;
for (x, t) in kts {
if let Some(t) = t {
match (k, t.ty().as_const()) {
(None, Some(k2)) => k = Some(k2),
(Some(k1), Some(k2)) if k1 == k2 => {}
_ => return span_err("InvalidFieldType"),
}
}
match seen_fields.entry(x) {
Entry::Occupied(_) => {
return span_err("UnionTypeDuplicateField")
}
Entry::Vacant(e) => e.insert(()),
};
}
// An empty union type has type Type;
// an union type with only unary variants also has type Type
let k = k.unwrap_or(Const::Type);
Type::from_const(k)
}
ExprKind::Field(scrut, x) => {
match scrut.ty().kind() {
NirKind::RecordType(kts) => match kts.get(&x) {
Some(val) => Type::new_infer_universe(env, val.clone())?,
None => return span_err("MissingRecordField"),
},
NirKind::Const(_) => {
let scrut = scrut.eval_to_type(env)?;
match scrut.kind() {
NirKind::UnionType(kts) => match kts.get(x) {
// Constructor has type T -> < x: T, ... >
Some(Some(ty)) => {
Nir::from_kind(NirKind::PiClosure {
binder: Binder::new(x.clone()),
annot: ty.clone(),
closure: Closure::new_constant(
scrut.to_nir(),
),
})
.to_type(scrut.ty())
}
Some(None) => scrut,
None => return span_err("MissingUnionField"),
},
_ => return span_err("NotARecord"),
}
}
_ => return span_err("NotARecord"),
}
}
ExprKind::Assert(t) => {
let t = t.eval_to_type(env)?;
match t.kind() {
NirKind::Equivalence(x, y) if x == y => {}
NirKind::Equivalence(..) => return span_err("AssertMismatch"),
_ => return span_err("AssertMustTakeEquivalence"),
}
t
}
ExprKind::App(f, arg) => {
match f.ty().kind() {
// TODO: store Type in closure
NirKind::PiClosure { annot, closure, .. } => {
if arg.ty().as_nir() != annot {
return mkerr(
ErrorBuilder::new(format!(
"wrong type of function argument"
))
.span_err(
f.span(),
format!(
"this expects an argument of type: {}",
annot.to_expr_tyenv(env),
),
)
.span_err(
arg.span(),
format!(
"but this has type: {}",
arg.ty().to_expr_tyenv(env),
),
)
.note(format!(
"expected type `{}`\n found type `{}`",
annot.to_expr_tyenv(env),
arg.ty().to_expr_tyenv(env),
))
.format(),
);
}
let arg_nf = arg.eval(env);
Type::new_infer_universe(env, closure.apply(arg_nf))?
}
_ => return mkerr(
ErrorBuilder::new(format!(
"expected function, found `{}`",
f.ty().to_expr_tyenv(env)
))
.span_err(
f.span(),
format!("function application requires a function",),
)
.format(),
),
}
}
ExprKind::BoolIf(x, y, z) => {
if *x.ty().kind() != NirKind::from_builtin(Builtin::Bool) {
return span_err("InvalidPredicate");
}
if y.ty().ty().as_const() != Some(Const::Type) {
return span_err("IfBranchMustBeTerm");
}
if y.ty() != z.ty() {
return span_err("IfBranchMismatch");
}
y.ty().clone()
}
ExprKind::BinOp(BinOp::RightBiasedRecordMerge, x, y) => {
let x_type = x.ty();
let y_type = y.ty();
// Extract the LHS record type
let kts_x = match x_type.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("MustCombineRecord"),
};
// Extract the RHS record type
let kts_y = match y_type.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("MustCombineRecord"),
};
// Union the two records, prefering
// the values found in the RHS.
let kts = merge_maps(kts_x, kts_y, |_, _, r_t| r_t.clone());
let u = max(x.ty().ty(), y.ty().ty());
Nir::from_kind(NirKind::RecordType(kts)).to_type(u)
}
ExprKind::BinOp(BinOp::RecursiveRecordMerge, x, y) => {
check_rectymerge(&span, env, x.ty().to_nir(), y.ty().to_nir())?;
let hir = Hir::new(
HirKind::Expr(ExprKind::BinOp(
BinOp::RecursiveRecordTypeMerge,
x.ty().to_hir(env.as_varenv()),
y.ty().to_hir(env.as_varenv()),
)),
span.clone(),
);
let x_u = x.ty().ty();
let y_u = y.ty().ty();
Type::new(hir.eval(env), max(x_u, y_u))
}
ExprKind::BinOp(BinOp::RecursiveRecordTypeMerge, x, y) => {
check_rectymerge(&span, env, x.eval(env), y.eval(env))?;
// A RecordType's type is always a const
let xk = x.ty().as_const().unwrap();
let yk = y.ty().as_const().unwrap();
Type::from_const(max(xk, yk))
}
ExprKind::BinOp(BinOp::ListAppend, l, r) => {
match l.ty().kind() {
NirKind::AppliedBuiltin(BuiltinClosure {
b: Builtin::List,
..
}) => {}
_ => return span_err("BinOpTypeMismatch"),
}
if l.ty() != r.ty() {
return span_err("BinOpTypeMismatch");
}
l.ty().clone()
}
ExprKind::BinOp(BinOp::Equivalence, l, r) => {
if l.ty() != r.ty() {
return span_err("EquivalenceTypeMismatch");
}
if l.ty().ty().as_const() != Some(Const::Type) {
return span_err("EquivalenceArgumentsMustBeTerms");
}
Type::from_const(Const::Type)
}
ExprKind::BinOp(o, l, r) => {
let t = Type::from_builtin(match o {
BinOp::BoolAnd
| BinOp::BoolOr
| BinOp::BoolEQ
| BinOp::BoolNE => Builtin::Bool,
BinOp::NaturalPlus | BinOp::NaturalTimes => Builtin::Natural,
BinOp::TextAppend => Builtin::Text,
BinOp::ListAppend
| BinOp::RightBiasedRecordMerge
| BinOp::RecursiveRecordMerge
| BinOp::RecursiveRecordTypeMerge
| BinOp::Equivalence => unreachable!(),
BinOp::ImportAlt => unreachable!("ImportAlt leftover in tck"),
});
if *l.ty() != t {
return span_err("BinOpTypeMismatch");
}
if *r.ty() != t {
return span_err("BinOpTypeMismatch");
}
t
}
ExprKind::Merge(record, union, type_annot) => {
let record_type = record.ty();
let handlers = match record_type.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("Merge1ArgMustBeRecord"),
};
let union_type = union.ty();
let variants = match union_type.kind() {
NirKind::UnionType(kts) => Cow::Borrowed(kts),
NirKind::AppliedBuiltin(BuiltinClosure {
b: Builtin::Optional,
args,
..
}) if args.len() == 1 => {
let ty = &args[0];
let mut kts = HashMap::new();
kts.insert("None".into(), None);
kts.insert("Some".into(), Some(ty.clone()));
Cow::Owned(kts)
}
_ => return span_err("Merge2ArgMustBeUnionOrOptional"),
};
let mut inferred_type = None;
for (x, handler_type) in handlers {
let handler_return_type: Type = match variants.get(x) {
// Union alternative with type
Some(Some(variant_type)) => match handler_type.kind() {
NirKind::PiClosure { closure, annot, .. } => {
if variant_type != annot {
return mkerr(
ErrorBuilder::new(format!(
"Wrong handler input type"
))
.span_err(
span,
format!("in this merge expression",),
)
.span_err(
record.span(),
format!(
"the handler for `{}` expects a \
value of type: `{}`",
x,
annot.to_expr_tyenv(env)
),
)
.span_err(
union.span(),
format!(
"but the corresponding variant \
has type: `{}`",
variant_type.to_expr_tyenv(env)
),
)
.format(),
);
}
// TODO: this actually doesn't check anything yet
match closure.remove_binder() {
Ok(v) => {
Type::new_infer_universe(env, v.clone())?
}
Err(()) => {
return span_err(
"MergeReturnTypeIsDependent",
)
}
}
}
_ => {
return mkerr(
ErrorBuilder::new(format!(
"merge handler is not a function"
))
.span_err(
span,
format!("in this merge expression"),
)
.span_err(
record.span(),
format!(
"the handler for `{}` has type: `{}`",
x,
handler_type.to_expr_tyenv(env)
),
)
.span_help(
union.span(),
format!(
"the corresponding variant has type: \
`{}`",
variant_type.to_expr_tyenv(env)
),
)
.help(format!(
"a handler for this variant must be a \
function that takes an input of type: \
`{}`",
variant_type.to_expr_tyenv(env)
))
.format(),
)
}
},
// Union alternative without type
Some(None) => {
Type::new_infer_universe(env, handler_type.clone())?
}
None => return span_err("MergeHandlerMissingVariant"),
};
match &inferred_type {
None => inferred_type = Some(handler_return_type),
Some(t) => {
if t != &handler_return_type {
return span_err("MergeHandlerTypeMismatch");
}
}
}
}
for x in variants.keys() {
if !handlers.contains_key(x) {
return span_err("MergeVariantMissingHandler");
}
}
let type_annot = type_annot
.as_ref()
.map(|t| t.eval_to_type(env))
.transpose()?;
match (inferred_type, type_annot) {
(Some(t1), Some(t2)) => {
if t1 != t2 {
return span_err("MergeAnnotMismatch");
}
t1
}
(Some(t), None) => t,
(None, Some(t)) => t,
(None, None) => return span_err("MergeEmptyNeedsAnnotation"),
}
}
ExprKind::ToMap(record, annot) => {
if record.ty().ty().as_const() != Some(Const::Type) {
return span_err("`toMap` only accepts records of type `Type`");
}
let record_t = record.ty();
let kts = match record_t.kind() {
NirKind::RecordType(kts) => kts,
_ => {
return span_err("The argument to `toMap` must be a record")
}
};
if kts.is_empty() {
let annot = if let Some(annot) = annot {
annot
} else {
return span_err(
"`toMap` applied to an empty record requires a type \
annotation",
);
};
let annot_val = annot.eval_to_type(env)?;
let err_msg = "The type of `toMap x` must be of the form \
`List { mapKey : Text, mapValue : T }`";
let arg = match annot_val.kind() {
NirKind::AppliedBuiltin(BuiltinClosure {
b: Builtin::List,
args,
..
}) if args.len() == 1 => &args[0],
_ => return span_err(err_msg),
};
let kts = match arg.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err(err_msg),
};
if kts.len() != 2 {
return span_err(err_msg);
}
match kts.get(&"mapKey".into()) {
Some(t) if *t == Nir::from_builtin(Builtin::Text) => {}
_ => return span_err(err_msg),
}
match kts.get(&"mapValue".into()) {
Some(_) => {}
None => return span_err(err_msg),
}
annot_val
} else {
let entry_type = kts.iter().next().unwrap().1.clone();
for (_, t) in kts.iter() {
if *t != entry_type {
return span_err(
"Every field of the record must have the same type",
);
}
}
let mut kts = HashMap::new();
kts.insert("mapKey".into(), Nir::from_builtin(Builtin::Text));
kts.insert("mapValue".into(), entry_type);
let output_type: Type = Nir::from_builtin(Builtin::List)
.app(Nir::from_kind(NirKind::RecordType(kts)))
.to_type(Const::Type);
if let Some(annot) = annot {
let annot_val = annot.eval_to_type(env)?;
if output_type != annot_val {
return span_err("Annotation mismatch");
}
}
output_type
}
}
ExprKind::Projection(record, labels) => {
let record_type = record.ty();
let kts = match record_type.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("ProjectionMustBeRecord"),
};
let mut new_kts = HashMap::new();
for l in labels {
match kts.get(l) {
None => return span_err("ProjectionMissingEntry"),
Some(t) => {
use std::collections::hash_map::Entry;
match new_kts.entry(l.clone()) {
Entry::Occupied(_) => {
return span_err("ProjectionDuplicateField")
}
Entry::Vacant(e) => e.insert(t.clone()),
}
}
};
}
Type::new_infer_universe(
env,
Nir::from_kind(NirKind::RecordType(new_kts)),
)?
}
ExprKind::ProjectionByExpr(record, selection) => {
let record_type = record.ty();
let rec_kts = match record_type.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("ProjectionMustBeRecord"),
};
let selection_val = selection.eval_to_type(env)?;
let sel_kts = match selection_val.kind() {
NirKind::RecordType(kts) => kts,
_ => return span_err("ProjectionByExprTakesRecordType"),
};
for (l, sel_ty) in sel_kts {
match rec_kts.get(l) {
Some(rec_ty) => {
if rec_ty != sel_ty {
return span_err("ProjectionWrongType");
}
}
None => return span_err("ProjectionMissingEntry"),
}
}
selection_val
}
};
Ok(ty)
}
/// `type_with` typechecks an expression in the provided environment. Optionally pass an annotation
/// to compare with.
pub(crate) fn type_with<'hir>(
env: &TyEnv,
hir: &'hir Hir,
annot: Option<Type>,
) -> Result<Tir<'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::Expr(ExprKind::Var(_)) => {
unreachable!("Hir should contain no unresolved variables")
}
HirKind::Expr(ExprKind::Const(Const::Sort)) => {
return mk_span_err(hir.span(), "Sort does not have a type")
}
HirKind::Expr(ExprKind::Annot(x, t)) => {
let t = match t.kind() {
HirKind::Expr(ExprKind::Const(Const::Sort)) => {
Type::from_const(Const::Sort)
}
_ => type_with(env, t, None)?.eval_to_type(env)?,
};
type_with(env, x, Some(t))?
}
HirKind::Expr(ExprKind::Lam(binder, annot, body)) => {
let annot = type_with(env, annot, None)?;
let annot_nf = annot.eval_to_type(env)?;
let body_env = env.insert_type(binder, annot_nf);
let body = type_with(&body_env, body, None)?;
let u_annot = annot.ty().as_const().unwrap();
let u_body = match body.ty().ty().as_const() {
Some(k) => k,
_ => return mk_span_err(hir.span(), "Invalid output type"),
};
let u = function_check(u_annot, u_body).to_universe();
let ty_hir = Hir::new(
HirKind::Expr(ExprKind::Pi(
binder.clone(),
annot.to_hir(),
body.ty().to_hir(body_env.as_varenv()),
)),
hir.span(),
);
let ty = Type::new(ty_hir.eval(env), u);
Tir::from_hir(hir, ty)
}
HirKind::Expr(ExprKind::Pi(binder, annot, body)) => {
let annot = type_with(env, annot, None)?;
let annot_val = annot.eval_to_type(env)?;
let body_env = env.insert_type(binder, annot_val);
let body = type_with(&body_env, body, None)?;
body.ensure_is_type(env)?;
let ks = annot.ty().as_const().unwrap();
let kt = body.ty().as_const().unwrap();
let ty = Type::from_const(function_check(ks, kt));
Tir::from_hir(hir, ty)
}
HirKind::Expr(ExprKind::Let(binder, annot, val, body)) => {
let val_annot = annot
.as_ref()
.map(|t| Ok(type_with(env, t, None)?.eval_to_type(env)?))
.transpose()?;
let val = type_with(env, &val, val_annot)?;
let val_nf = val.eval(env);
let body_env = env.insert_value(&binder, val_nf, val.ty().clone());
let body = type_with(&body_env, body, None)?;
let ty = body.ty().clone();
Tir::from_hir(hir, ty)
}
HirKind::Expr(ekind) => {
let ekind = ekind.traverse_ref(|e| type_with(env, e, None))?;
let ty = type_one_layer(env, ekind, hir.span())?;
Tir::from_hir(hir, ty)
}
};
if let Some(annot) = annot {
if *tir.ty() != annot {
return mk_span_err(
hir.span(),
&format!(
"annot mismatch: {} != {}",
tir.ty().to_expr_tyenv(env),
annot.to_expr_tyenv(env)
),
);
}
}
Ok(tir)
}
/// Typecheck an expression and return the expression annotated with types if type-checking
/// succeeded, or an error if type-checking failed.
pub(crate) fn typecheck<'hir>(hir: &'hir Hir) -> Result<Tir<'hir>, TypeError> {
type_with(&TyEnv::new(), hir, None)
}
/// Like `typecheck`, but additionally checks that the expression's type matches the provided type.
pub(crate) 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))
}
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