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use crate::error::TypeError;
use crate::semantics::{Hir, HirKind, NzEnv, TyEnv, Value};
use crate::syntax::{Const, Span};
use crate::{NormalizedExpr, ToExprOptions};
pub(crate) type Type = Value;
// A hir expression plus its inferred type.
#[derive(Debug, Clone)]
pub(crate) struct TyExpr {
hir: Hir,
ty: Type,
}
impl TyExpr {
pub fn new(kind: HirKind, ty: Type, span: Span) -> Self {
TyExpr {
hir: Hir::new(kind, span),
ty,
}
}
pub fn span(&self) -> Span {
self.as_hir().span()
}
pub fn ty(&self) -> &Type {
&self.ty
}
/// Get the kind (the type of the type) of this value
// TODO: avoid recomputing so much
pub fn get_kind(&self, env: &TyEnv) -> Result<Option<Const>, TypeError> {
Ok(self
.ty()
.to_hir(env.as_varenv())
.typecheck(env)?
.ty()
.as_const())
}
pub fn to_hir(&self) -> Hir {
self.as_hir().clone()
}
pub fn as_hir(&self) -> &Hir {
&self.hir
}
/// Converts a value back to the corresponding AST expression.
pub fn to_expr(&self, opts: ToExprOptions) -> NormalizedExpr {
self.as_hir().to_expr(opts)
}
/// Eval the TyExpr. It will actually get evaluated only as needed on demand.
pub fn eval(&self, env: impl Into<NzEnv>) -> Value {
self.as_hir().eval(env.into())
}
/// Eval a closed TyExpr (i.e. without free variables). It will actually get evaluated only as
/// needed on demand.
pub fn eval_closed_expr(&self) -> Value {
self.eval(NzEnv::new())
}
/// Eval a closed TyExpr fully and recursively;
pub fn rec_eval_closed_expr(&self) -> Value {
let val = self.eval_closed_expr();
val.normalize();
val
}
}
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