diff options
Diffstat (limited to '')
-rw-r--r-- | dhall/src/typecheck.rs | 416 |
1 files changed, 214 insertions, 202 deletions
diff --git a/dhall/src/typecheck.rs b/dhall/src/typecheck.rs index f967aa5..5701800 100644 --- a/dhall/src/typecheck.rs +++ b/dhall/src/typecheck.rs @@ -305,28 +305,37 @@ macro_rules! ensure_is_const { }; } +/// Takes an expression that is meant to contain a Type +/// and turn it into a type, typechecking it along the way. +fn mktype( + ctx: &Context<Label, Type<'static>>, + e: SubExpr<X, Normalized<'static>>, +) -> Result<Type<'static>, TypeError> { + Ok(type_with(ctx, e)?.normalize().into_type()) +} + +fn mksimpletype(e: SubExpr<X, X>) -> Type<'static> { + SimpleType(e, PhantomData).into_type() +} + +/// Intermediary return type +enum Ret { + /// Returns the contained Type as is + RetType(Type<'static>), + /// Returns an expression that must be typechecked and + /// turned into a Type first. + RetExpr(Expr<X, Normalized<'static>>), +} + /// Type-check an expression and return the expression alongside its type if type-checking /// succeeded, or an error if type-checking failed fn type_with( ctx: &Context<Label, Type<'static>>, e: SubExpr<X, Normalized<'static>>, ) -> Result<Typed<'static>, TypeError> { - use dhall_core::BinOp::*; - use dhall_core::Const::*; use dhall_core::ExprF::*; let mkerr = |msg: TypeMessage<'static>| TypeError::new(ctx, e.clone(), msg); - let mktype = |ctx, x: SubExpr<X, Normalized<'static>>| { - Ok(type_with(ctx, x)?.normalize().into_type()) - }; - - let mksimpletype = - |x: SubExpr<X, X>| SimpleType(x, PhantomData).into_type(); - - enum Ret { - RetType(crate::expr::Type<'static>), - RetExpr(Expr<X, Normalized<'static>>), - } use Ret::*; let ret = match e.as_ref() { Lam(x, t, b) => { @@ -407,213 +416,216 @@ fn type_with( Ok(RetType(b.get_type_move()?)) } - _ => match e - .as_ref() - .traverse_ref_simple(|e| type_with(ctx, e.clone()))? - { - Lam(_, _, _) => unreachable!(), - Pi(_, _, _) => unreachable!(), - Let(_, _, _, _) => unreachable!(), - Const(Type) => Ok(RetType(crate::expr::Type::const_kind())), - Const(Kind) => Ok(RetType(crate::expr::Type::const_sort())), - Const(Sort) => { - Ok(RetType(crate::expr::Type(TypeInternal::SuperType))) - } - Var(V(x, n)) => match ctx.lookup(&x, n) { - Some(e) => Ok(RetType(e.clone())), - None => Err(mkerr(UnboundVariable)), - }, - App(f, args) => { - let mut seen_args: Vec<SubExpr<_, _>> = vec![]; - let mut tf = f.get_type()?.into_owned(); - for a in args { - seen_args.push(a.as_expr().clone()); - let (x, tx, tb) = ensure_matches!(tf, - Pi(x, tx, tb) => (x, tx, tb), - mkerr(NotAFunction(Typed( + Embed(p) => return Ok(p.clone().into()), + _ => type_last_layer( + ctx, + // Typecheck recursively all subexpressions + e.as_ref() + .traverse_ref_simple(|e| type_with(ctx, e.clone()))?, + e.clone(), + ), + }?; + match ret { + RetExpr(ret) => Ok(Typed(e, Some(mktype(ctx, rc(ret))?), PhantomData)), + RetType(typ) => Ok(Typed(e, Some(typ), PhantomData)), + } +} + +/// When all sub-expressions have been typed, check the remaining toplevel +/// layer. +fn type_last_layer( + ctx: &Context<Label, Type<'static>>, + e: ExprF<Typed<'static>, Label, X, Normalized<'static>>, + original_e: SubExpr<X, Normalized<'static>>, +) -> Result<Ret, TypeError> { + use dhall_core::BinOp::*; + use dhall_core::Const::*; + use dhall_core::ExprF::*; + let mkerr = |msg: TypeMessage<'static>| { + TypeError::new(ctx, original_e.clone(), msg) + }; + + use Ret::*; + match e { + Lam(_, _, _) => unreachable!(), + Pi(_, _, _) => unreachable!(), + Let(_, _, _, _) => unreachable!(), + Embed(_) => unreachable!(), + Const(Type) => Ok(RetType(crate::expr::Type::const_kind())), + Const(Kind) => Ok(RetType(crate::expr::Type::const_sort())), + Const(Sort) => Ok(RetType(crate::expr::Type(TypeInternal::SuperType))), + Var(V(x, n)) => match ctx.lookup(&x, n) { + Some(e) => Ok(RetType(e.clone())), + None => Err(mkerr(UnboundVariable)), + }, + App(f, args) => { + let mut seen_args: Vec<SubExpr<_, _>> = vec![]; + let mut tf = f.get_type()?.into_owned(); + for a in args { + seen_args.push(a.as_expr().clone()); + let (x, tx, tb) = ensure_matches!(tf, + Pi(x, tx, tb) => (x, tx, tb), + mkerr(NotAFunction(Typed( + rc(App(f.into_expr(), seen_args)), + Some(tf), + PhantomData + ))) + ); + let tx = mktype(ctx, tx.absurd())?; + ensure_equal!( + &tx, + a.get_type()?, + mkerr(TypeMismatch( + Typed( rc(App(f.into_expr(), seen_args)), Some(tf), PhantomData - ))) - ); - let tx = mktype(ctx, tx.absurd())?; - ensure_equal!( - &tx, - a.get_type()?, - mkerr(TypeMismatch( - Typed( - rc(App(f.into_expr(), seen_args)), - Some(tf), - PhantomData - ), - tx.into_normalized()?, - a, - )) - ); - tf = mktype( - ctx, - subst_shift( - &V(x.clone(), 0), - a.as_expr(), - &tb.absurd(), ), - )?; - } - Ok(RetType(tf)) - } - Annot(x, t) => { - let t = t.normalize().into_type(); - ensure_equal!( - &t, - x.get_type()?, - mkerr(AnnotMismatch(x, t.into_normalized()?)) + tx.into_normalized()?, + a, + )) ); - Ok(RetType(x.get_type_move()?)) + tf = mktype( + ctx, + subst_shift(&V(x.clone(), 0), a.as_expr(), &tb.absurd()), + )?; } - BoolIf(x, y, z) => { - ensure_equal!( - x.get_type()?, - &mksimpletype(dhall::subexpr!(Bool)), - mkerr(InvalidPredicate(x)), - ); + Ok(RetType(tf)) + } + Annot(x, t) => { + let t = t.normalize().into_type(); + ensure_equal!( + &t, + x.get_type()?, + mkerr(AnnotMismatch(x, t.into_normalized()?)) + ); + Ok(RetType(x.get_type_move()?)) + } + BoolIf(x, y, z) => { + ensure_equal!( + x.get_type()?, + &mksimpletype(dhall::subexpr!(Bool)), + mkerr(InvalidPredicate(x)), + ); - ensure_simple_type!( - y.get_type()?, - mkerr(IfBranchMustBeTerm(true, y)), - ); + ensure_simple_type!( + y.get_type()?, + mkerr(IfBranchMustBeTerm(true, y)), + ); - ensure_simple_type!( - z.get_type()?, - mkerr(IfBranchMustBeTerm(false, z)), - ); + ensure_simple_type!( + z.get_type()?, + mkerr(IfBranchMustBeTerm(false, z)), + ); + ensure_equal!( + y.get_type()?, + z.get_type()?, + mkerr(IfBranchMismatch(y, z)) + ); + + Ok(RetType(y.get_type_move()?)) + } + EmptyListLit(t) => { + let t = t.normalize().into_type(); + ensure_simple_type!( + t, + mkerr(InvalidListType(t.into_normalized()?)), + ); + let t = t.into_normalized()?.into_expr(); + Ok(RetExpr(dhall::expr!(List t))) + } + NEListLit(xs) => { + let mut iter = xs.into_iter().enumerate(); + let (_, x) = iter.next().unwrap(); + ensure_simple_type!( + x.get_type()?, + mkerr(InvalidListType(x.get_type_move()?.into_normalized()?)), + ); + for (i, y) in iter { ensure_equal!( + x.get_type()?, y.get_type()?, - z.get_type()?, - mkerr(IfBranchMismatch(y, z)) + mkerr(InvalidListElement( + i, + x.get_type_move()?.into_normalized()?, + y + )) ); - - Ok(RetType(y.get_type_move()?)) } - EmptyListLit(t) => { - let t = t.normalize().into_type(); - ensure_simple_type!( - t, - mkerr(InvalidListType(t.into_normalized()?)), - ); - let t = t.into_normalized()?.into_expr(); - Ok(RetExpr(dhall::expr!(List t))) + let t = x.get_type_move()?.into_normalized()?.into_expr(); + Ok(RetExpr(dhall::expr!(List t))) + } + EmptyOptionalLit(t) => { + let t = t.normalize().into_type(); + ensure_simple_type!( + t, + mkerr(InvalidOptionalType(t.into_normalized()?)), + ); + let t = t.into_normalized()?.into_expr(); + Ok(RetExpr(dhall::expr!(Optional t))) + } + NEOptionalLit(x) => { + let tx = x.get_type_move()?; + ensure_simple_type!( + tx, + mkerr(InvalidOptionalType(tx.into_normalized()?,)), + ); + let t = tx.into_normalized()?.into_expr(); + Ok(RetExpr(dhall::expr!(Optional t))) + } + RecordType(kts) => { + for (k, t) in kts { + ensure_simple_type!(t, mkerr(InvalidFieldType(k, t)),); } - NEListLit(xs) => { - let mut iter = xs.into_iter().enumerate(); - let (_, x) = iter.next().unwrap(); - ensure_simple_type!( - x.get_type()?, - mkerr(InvalidListType( - x.get_type_move()?.into_normalized()? - )), - ); - for (i, y) in iter { - ensure_equal!( - x.get_type()?, - y.get_type()?, - mkerr(InvalidListElement( - i, - x.get_type_move()?.into_normalized()?, - y - )) + Ok(RetExpr(dhall::expr!(Type))) + } + RecordLit(kvs) => { + let kts = kvs + .into_iter() + .map(|(k, v)| { + ensure_simple_type!( + v.get_type()?, + mkerr(InvalidField(k, v)), ); - } - let t = x.get_type_move()?.into_normalized()?.into_expr(); - Ok(RetExpr(dhall::expr!(List t))) - } - EmptyOptionalLit(t) => { - let t = t.normalize().into_type(); - ensure_simple_type!( - t, - mkerr(InvalidOptionalType(t.into_normalized()?)), - ); - let t = t.into_normalized()?.into_expr(); - Ok(RetExpr(dhall::expr!(Optional t))) - } - NEOptionalLit(x) => { - let tx = x.get_type_move()?; - ensure_simple_type!( - tx, - mkerr(InvalidOptionalType(tx.into_normalized()?,)), - ); - let t = tx.into_normalized()?.into_expr(); - Ok(RetExpr(dhall::expr!(Optional t))) - } - RecordType(kts) => { - for (k, t) in kts { - ensure_simple_type!(t, mkerr(InvalidFieldType(k, t)),); - } - Ok(RetExpr(dhall::expr!(Type))) - } - RecordLit(kvs) => { - let kts = kvs - .into_iter() - .map(|(k, v)| { - ensure_simple_type!( - v.get_type()?, - mkerr(InvalidField(k, v)), - ); - Ok(( - k, - v.get_type_move()?.into_normalized()?.into_expr(), - )) - }) - .collect::<Result<_, _>>()?; - Ok(RetExpr(RecordType(kts))) - } - Field(r, x) => ensure_matches!(r.get_type()?, - RecordType(kts) => match kts.get(&x) { - Some(e) => Ok(RetExpr(e.unroll().absurd_rec())), - None => Err(mkerr(MissingField(x, r))), - }, - mkerr(NotARecord(x, r)) - ), - Builtin(b) => Ok(RetExpr(type_of_builtin(b))), - BoolLit(_) => Ok(RetExpr(dhall::expr!(Bool))), - NaturalLit(_) => Ok(RetExpr(dhall::expr!(Natural))), - IntegerLit(_) => Ok(RetExpr(dhall::expr!(Integer))), - DoubleLit(_) => Ok(RetExpr(dhall::expr!(Double))), - // TODO: check type of interpolations - TextLit(_) => Ok(RetExpr(dhall::expr!(Text))), - BinOp(o, l, r) => { - let t = mksimpletype(match o { - BoolAnd => dhall::subexpr!(Bool), - BoolOr => dhall::subexpr!(Bool), - BoolEQ => dhall::subexpr!(Bool), - BoolNE => dhall::subexpr!(Bool), - NaturalPlus => dhall::subexpr!(Natural), - NaturalTimes => dhall::subexpr!(Natural), - TextAppend => dhall::subexpr!(Text), - _ => Err(mkerr(Unimplemented))?, - }); + Ok((k, v.get_type_move()?.into_normalized()?.into_expr())) + }) + .collect::<Result<_, _>>()?; + Ok(RetExpr(RecordType(kts))) + } + Field(r, x) => ensure_matches!(r.get_type()?, + RecordType(kts) => match kts.get(&x) { + Some(e) => Ok(RetExpr(e.unroll().absurd_rec())), + None => Err(mkerr(MissingField(x, r))), + }, + mkerr(NotARecord(x, r)) + ), + Builtin(b) => Ok(RetExpr(type_of_builtin(b))), + BoolLit(_) => Ok(RetExpr(dhall::expr!(Bool))), + NaturalLit(_) => Ok(RetExpr(dhall::expr!(Natural))), + IntegerLit(_) => Ok(RetExpr(dhall::expr!(Integer))), + DoubleLit(_) => Ok(RetExpr(dhall::expr!(Double))), + // TODO: check type of interpolations + TextLit(_) => Ok(RetExpr(dhall::expr!(Text))), + BinOp(o, l, r) => { + let t = mksimpletype(match o { + BoolAnd => dhall::subexpr!(Bool), + BoolOr => dhall::subexpr!(Bool), + BoolEQ => dhall::subexpr!(Bool), + BoolNE => dhall::subexpr!(Bool), + NaturalPlus => dhall::subexpr!(Natural), + NaturalTimes => dhall::subexpr!(Natural), + TextAppend => dhall::subexpr!(Text), + _ => return Err(mkerr(Unimplemented)), + }); - ensure_equal!( - l.get_type()?, - &t, - mkerr(BinOpTypeMismatch(o, l)) - ); + ensure_equal!(l.get_type()?, &t, mkerr(BinOpTypeMismatch(o, l))); - ensure_equal!( - r.get_type()?, - &t, - mkerr(BinOpTypeMismatch(o, r)) - ); + ensure_equal!(r.get_type()?, &t, mkerr(BinOpTypeMismatch(o, r))); - Ok(RetType(t)) - } - Embed(p) => return Ok(p.into()), - _ => Err(mkerr(Unimplemented))?, - }, - }?; - match ret { - RetExpr(ret) => Ok(Typed(e, Some(mktype(ctx, rc(ret))?), PhantomData)), - RetType(typ) => Ok(Typed(e, Some(typ), PhantomData)), + Ok(RetType(t)) + } + _ => Err(mkerr(Unimplemented)), } } |