compiler/rustc_ty_utils/src/consts.rs - third_party/rust - Git at Google

 use rustc_errors::ErrorGuaranteed;
 use rustc_hir::def::DefKind;
 use rustc_hir::def_id::LocalDefId;
 use rustc_middle::mir::interpret::{LitToConstError, LitToConstInput};
 use rustc_middle::query::Providers;
 use rustc_middle::thir::visit;
 use rustc_middle::thir::visit::Visitor;
 use rustc_middle::ty::abstract_const::CastKind;
 use rustc_middle::ty::{self, Expr, TyCtxt, TypeVisitableExt};
 use rustc_middle::{mir, thir};
 use rustc_span::Span;
 use rustc_target::abi::{VariantIdx, FIRST_VARIANT};

 use std::iter;

 use crate::errors::{GenericConstantTooComplex, GenericConstantTooComplexSub};

 /// Destructures array, ADT or tuple constants into the constants
 /// of their fields.
 pub(crate) fn destructure_const<'tcx>(
     tcx: TyCtxt<'tcx>,
     const_: ty::Const<'tcx>,
 ) -> ty::DestructuredConst<'tcx> {
     let ty::ConstKind::Value(valtree) = const_.kind() else {
         bug!("cannot destructure constant {:?}", const_)
     };

     let branches = match valtree {
         ty::ValTree::Branch(b) => b,
         _ => bug!("cannot destructure constant {:?}", const_),
     };

     let (fields, variant) = match const_.ty().kind() {
         ty::Array(inner_ty, _) | ty::Slice(inner_ty) => {
             // construct the consts for the elements of the array/slice
             let field_consts =
                 branches.iter().map(|b| tcx.mk_const(*b, *inner_ty)).collect::<Vec<_>>();
             debug!(?field_consts);

             (field_consts, None)
         }
         ty::Adt(def, _) if def.variants().is_empty() => bug!("unreachable"),
         ty::Adt(def, substs) => {
             let (variant_idx, branches) = if def.is_enum() {
                 let (head, rest) = branches.split_first().unwrap();
                 (VariantIdx::from_u32(head.unwrap_leaf().try_to_u32().unwrap()), rest)
             } else {
                 (FIRST_VARIANT, branches)
             };
             let fields = &def.variant(variant_idx).fields;
             let mut field_consts = Vec::with_capacity(fields.len());

             for (field, field_valtree) in iter::zip(fields, branches) {
                 let field_ty = field.ty(tcx, substs);
                 let field_const = tcx.mk_const(*field_valtree, field_ty);
                 field_consts.push(field_const);
             }
             debug!(?field_consts);

             (field_consts, Some(variant_idx))
         }
         ty::Tuple(elem_tys) => {
             let fields = iter::zip(*elem_tys, branches)
                 .map(|(elem_ty, elem_valtree)| tcx.mk_const(*elem_valtree, elem_ty))
                 .collect::<Vec<_>>();

             (fields, None)
         }
         _ => bug!("cannot destructure constant {:?}", const_),
     };

     let fields = tcx.arena.alloc_from_iter(fields.into_iter());

     ty::DestructuredConst { variant, fields }
 }

 /// We do not allow all binary operations in abstract consts, so filter disallowed ones.
 fn check_binop(op: mir::BinOp) -> bool {
     use mir::BinOp::*;
     match op {
         Add | Sub | Mul | Div | Rem | BitXor | BitAnd | BitOr | Shl | Shr | Eq | Lt | Le | Ne
         | Ge | Gt => true,
         Offset => false,
     }
 }

 /// While we currently allow all unary operations, we still want to explicitly guard against
 /// future changes here.
 fn check_unop(op: mir::UnOp) -> bool {
     use mir::UnOp::*;
     match op {
         Not | Neg => true,
     }
 }

 fn recurse_build<'tcx>(
     tcx: TyCtxt<'tcx>,
     body: &thir::Thir<'tcx>,
     node: thir::ExprId,
     root_span: Span,
 ) -> Result<ty::Const<'tcx>, ErrorGuaranteed> {
     use thir::ExprKind;
     let node = &body.exprs[node];

     let maybe_supported_error = |a| maybe_supported_error(tcx, a, root_span);
     let error = |a| error(tcx, a, root_span);

     Ok(match &node.kind {
         // I dont know if handling of these 3 is correct
         &ExprKind::Scope { value, .. } => recurse_build(tcx, body, value, root_span)?,
         &ExprKind::PlaceTypeAscription { source, .. }
         | &ExprKind::ValueTypeAscription { source, .. } => {
             recurse_build(tcx, body, source, root_span)?
         }
         &ExprKind::Literal { lit, neg } => {
             let sp = node.span;
             match tcx.at(sp).lit_to_const(LitToConstInput { lit: &lit.node, ty: node.ty, neg }) {
                 Ok(c) => c,
                 Err(LitToConstError::Reported(guar)) => tcx.const_error(node.ty, guar),
                 Err(LitToConstError::TypeError) => {
                     bug!("encountered type error in lit_to_const")
                 }
             }
         }
         &ExprKind::NonHirLiteral { lit, user_ty: _ } => {
             let val = ty::ValTree::from_scalar_int(lit);
             tcx.mk_const(val, node.ty)
         }
         &ExprKind::ZstLiteral { user_ty: _ } => {
             let val = ty::ValTree::zst();
             tcx.mk_const(val, node.ty)
         }
         &ExprKind::NamedConst { def_id, substs, user_ty: _ } => {
             let uneval = ty::UnevaluatedConst::new(def_id, substs);
             tcx.mk_const(uneval, node.ty)
         }
         ExprKind::ConstParam { param, .. } => tcx.mk_const(*param, node.ty),

         ExprKind::Call { fun, args, .. } => {
             let fun = recurse_build(tcx, body, *fun, root_span)?;

             let mut new_args = Vec::<ty::Const<'tcx>>::with_capacity(args.len());
             for &id in args.iter() {
                 new_args.push(recurse_build(tcx, body, id, root_span)?);
             }
             let new_args = tcx.mk_const_list(&new_args);
             tcx.mk_const(Expr::FunctionCall(fun, new_args), node.ty)
         }
         &ExprKind::Binary { op, lhs, rhs } if check_binop(op) => {
             let lhs = recurse_build(tcx, body, lhs, root_span)?;
             let rhs = recurse_build(tcx, body, rhs, root_span)?;
             tcx.mk_const(Expr::Binop(op, lhs, rhs), node.ty)
         }
         &ExprKind::Unary { op, arg } if check_unop(op) => {
             let arg = recurse_build(tcx, body, arg, root_span)?;
             tcx.mk_const(Expr::UnOp(op, arg), node.ty)
         }
         // This is necessary so that the following compiles:
         //
         // ```
         // fn foo<const N: usize>(a: [(); N + 1]) {
         //     bar::<{ N + 1 }>();
         // }
         // ```
         ExprKind::Block { block } => {
             if let thir::Block { stmts: box [], expr: Some(e), .. } = &body.blocks[*block] {
                 recurse_build(tcx, body, *e, root_span)?
             } else {
                 maybe_supported_error(GenericConstantTooComplexSub::BlockNotSupported(node.span))?
             }
         }
         // `ExprKind::Use` happens when a `hir::ExprKind::Cast` is a
         // "coercion cast" i.e. using a coercion or is a no-op.
         // This is important so that `N as usize as usize` doesnt unify with `N as usize`. (untested)
         &ExprKind::Use { source } => {
             let arg = recurse_build(tcx, body, source, root_span)?;
             tcx.mk_const(Expr::Cast(CastKind::Use, arg, node.ty), node.ty)
         }
         &ExprKind::Cast { source } => {
             let arg = recurse_build(tcx, body, source, root_span)?;
             tcx.mk_const(Expr::Cast(CastKind::As, arg, node.ty), node.ty)
         }
         ExprKind::Borrow { arg, .. } => {
             let arg_node = &body.exprs[*arg];

             // Skip reborrows for now until we allow Deref/Borrow/AddressOf
             // expressions.
             // FIXME(generic_const_exprs): Verify/explain why this is sound
             if let ExprKind::Deref { arg } = arg_node.kind {
                 recurse_build(tcx, body, arg, root_span)?
             } else {
                 maybe_supported_error(GenericConstantTooComplexSub::BorrowNotSupported(node.span))?
             }
         }
         // FIXME(generic_const_exprs): We may want to support these.
         ExprKind::AddressOf { .. } | ExprKind::Deref { .. } => maybe_supported_error(
             GenericConstantTooComplexSub::AddressAndDerefNotSupported(node.span),
         )?,
         ExprKind::Repeat { .. } | ExprKind::Array { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::ArrayNotSupported(node.span))?
         }
         ExprKind::NeverToAny { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::NeverToAnyNotSupported(node.span))?
         }
         ExprKind::Tuple { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::TupleNotSupported(node.span))?
         }
         ExprKind::Index { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::IndexNotSupported(node.span))?
         }
         ExprKind::Field { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::FieldNotSupported(node.span))?
         }
         ExprKind::ConstBlock { .. } => {
             maybe_supported_error(GenericConstantTooComplexSub::ConstBlockNotSupported(node.span))?
         }
         ExprKind::Adt(_) => {
             maybe_supported_error(GenericConstantTooComplexSub::AdtNotSupported(node.span))?
         }
         // dont know if this is correct
         ExprKind::Pointer { .. } => {
             error(GenericConstantTooComplexSub::PointerNotSupported(node.span))?
         }
         ExprKind::Yield { .. } => {
             error(GenericConstantTooComplexSub::YieldNotSupported(node.span))?
         }
         ExprKind::Continue { .. } | ExprKind::Break { .. } | ExprKind::Loop { .. } => {
             error(GenericConstantTooComplexSub::LoopNotSupported(node.span))?
         }
         ExprKind::Box { .. } => error(GenericConstantTooComplexSub::BoxNotSupported(node.span))?,

         ExprKind::Unary { .. } => unreachable!(),
         // we handle valid unary/binary ops above
         ExprKind::Binary { .. } => {
             error(GenericConstantTooComplexSub::BinaryNotSupported(node.span))?
         }
         ExprKind::LogicalOp { .. } => {
             error(GenericConstantTooComplexSub::LogicalOpNotSupported(node.span))?
         }
         ExprKind::Assign { .. } | ExprKind::AssignOp { .. } => {
             error(GenericConstantTooComplexSub::AssignNotSupported(node.span))?
         }
         ExprKind::Closure { .. } | ExprKind::Return { .. } => {
             error(GenericConstantTooComplexSub::ClosureAndReturnNotSupported(node.span))?
         }
         // let expressions imply control flow
         ExprKind::Match { .. } | ExprKind::If { .. } | ExprKind::Let { .. } => {
             error(GenericConstantTooComplexSub::ControlFlowNotSupported(node.span))?
         }
         ExprKind::InlineAsm { .. } => {
             error(GenericConstantTooComplexSub::InlineAsmNotSupported(node.span))?
         }

         // we dont permit let stmts so `VarRef` and `UpvarRef` cant happen
         ExprKind::VarRef { .. }
         | ExprKind::UpvarRef { .. }
         | ExprKind::StaticRef { .. }
         | ExprKind::OffsetOf { .. }
         | ExprKind::ThreadLocalRef(_) => {
             error(GenericConstantTooComplexSub::OperationNotSupported(node.span))?
         }
     })
 }

 struct IsThirPolymorphic<'a, 'tcx> {
     is_poly: bool,
     thir: &'a thir::Thir<'tcx>,
 }

 fn error(
     tcx: TyCtxt<'_>,
     sub: GenericConstantTooComplexSub,
     root_span: Span,
 ) -> Result<!, ErrorGuaranteed> {
     let reported = tcx.sess.emit_err(GenericConstantTooComplex {
         span: root_span,
         maybe_supported: None,
         sub,
     });

     Err(reported)
 }

 fn maybe_supported_error(
     tcx: TyCtxt<'_>,
     sub: GenericConstantTooComplexSub,
     root_span: Span,
 ) -> Result<!, ErrorGuaranteed> {
     let reported = tcx.sess.emit_err(GenericConstantTooComplex {
         span: root_span,
         maybe_supported: Some(()),
         sub,
     });

     Err(reported)
 }

 impl<'a, 'tcx> IsThirPolymorphic<'a, 'tcx> {
     fn expr_is_poly(&mut self, expr: &thir::Expr<'tcx>) -> bool {
         if expr.ty.has_non_region_param() {
             return true;
         }

         match expr.kind {
             thir::ExprKind::NamedConst { substs, .. }
             | thir::ExprKind::ConstBlock { substs, .. } => substs.has_non_region_param(),
             thir::ExprKind::ConstParam { .. } => true,
             thir::ExprKind::Repeat { value, count } => {
                 self.visit_expr(&self.thir()[value]);
                 count.has_non_region_param()
             }
             thir::ExprKind::Scope { .. }
             | thir::ExprKind::Box { .. }
             | thir::ExprKind::If { .. }
             | thir::ExprKind::Call { .. }
             | thir::ExprKind::Deref { .. }
             | thir::ExprKind::Binary { .. }
             | thir::ExprKind::LogicalOp { .. }
             | thir::ExprKind::Unary { .. }
             | thir::ExprKind::Cast { .. }
             | thir::ExprKind::Use { .. }
             | thir::ExprKind::NeverToAny { .. }
             | thir::ExprKind::Pointer { .. }
             | thir::ExprKind::Loop { .. }
             | thir::ExprKind::Let { .. }
             | thir::ExprKind::Match { .. }
             | thir::ExprKind::Block { .. }
             | thir::ExprKind::Assign { .. }
             | thir::ExprKind::AssignOp { .. }
             | thir::ExprKind::Field { .. }
             | thir::ExprKind::Index { .. }
             | thir::ExprKind::VarRef { .. }
             | thir::ExprKind::UpvarRef { .. }
             | thir::ExprKind::Borrow { .. }
             | thir::ExprKind::AddressOf { .. }
             | thir::ExprKind::Break { .. }
             | thir::ExprKind::Continue { .. }
             | thir::ExprKind::Return { .. }
             | thir::ExprKind::Array { .. }
             | thir::ExprKind::Tuple { .. }
             | thir::ExprKind::Adt(_)
             | thir::ExprKind::PlaceTypeAscription { .. }
             | thir::ExprKind::ValueTypeAscription { .. }
             | thir::ExprKind::Closure(_)
             | thir::ExprKind::Literal { .. }
             | thir::ExprKind::NonHirLiteral { .. }
             | thir::ExprKind::ZstLiteral { .. }
             | thir::ExprKind::StaticRef { .. }
             | thir::ExprKind::InlineAsm(_)
             | thir::ExprKind::OffsetOf { .. }
             | thir::ExprKind::ThreadLocalRef(_)
             | thir::ExprKind::Yield { .. } => false,
         }
     }
     fn pat_is_poly(&mut self, pat: &thir::Pat<'tcx>) -> bool {
         if pat.ty.has_non_region_param() {
             return true;
         }

         match pat.kind {
             thir::PatKind::Constant { value } => value.has_non_region_param(),
             thir::PatKind::Range(box thir::PatRange { lo, hi, .. }) => {
                 lo.has_non_region_param() || hi.has_non_region_param()
             }
             _ => false,
         }
     }
 }

 impl<'a, 'tcx> visit::Visitor<'a, 'tcx> for IsThirPolymorphic<'a, 'tcx> {
     fn thir(&self) -> &'a thir::Thir<'tcx> {
         &self.thir
     }

     #[instrument(skip(self), level = "debug")]
     fn visit_expr(&mut self, expr: &thir::Expr<'tcx>) {
         self.is_poly |= self.expr_is_poly(expr);
         if !self.is_poly {
             visit::walk_expr(self, expr)
         }
     }

     #[instrument(skip(self), level = "debug")]
     fn visit_pat(&mut self, pat: &thir::Pat<'tcx>) {
         self.is_poly |= self.pat_is_poly(pat);
         if !self.is_poly {
             visit::walk_pat(self, pat);
         }
     }
 }

 /// Builds an abstract const, do not use this directly, but use `AbstractConst::new` instead.
 pub fn thir_abstract_const(
     tcx: TyCtxt<'_>,
     def: LocalDefId,
 ) -> Result<Option<ty::EarlyBinder<ty::Const<'_>>>, ErrorGuaranteed> {
     if !tcx.features().generic_const_exprs {
         return Ok(None);
     }

     match tcx.def_kind(def) {
         // FIXME(generic_const_exprs): We currently only do this for anonymous constants,
         // meaning that we do not look into associated constants. I(@lcnr) am not yet sure whether
         // we want to look into them or treat them as opaque projections.
         //
         // Right now we do neither of that and simply always fail to unify them.
         DefKind::AnonConst | DefKind::InlineConst => (),
         _ => return Ok(None),
     }

     let body = tcx.thir_body(def)?;
     let (body, body_id) = (&*body.0.borrow(), body.1);

     let mut is_poly_vis = IsThirPolymorphic { is_poly: false, thir: body };
     visit::walk_expr(&mut is_poly_vis, &body[body_id]);
     if !is_poly_vis.is_poly {
         return Ok(None);
     }

     let root_span = body.exprs[body_id].span;

     Ok(Some(ty::EarlyBinder::new(recurse_build(tcx, body, body_id, root_span)?)))
 }

 pub fn provide(providers: &mut Providers) {
     *providers = Providers { destructure_const, thir_abstract_const, ..*providers };
 }
	use rustc_errors::ErrorGuaranteed;
	use rustc_hir::def::DefKind;
	use rustc_hir::def_id::LocalDefId;
	use rustc_middle::mir::interpret::{LitToConstError, LitToConstInput};
	use rustc_middle::query::Providers;
	use rustc_middle::thir::visit;
	use rustc_middle::thir::visit::Visitor;
	use rustc_middle::ty::abstract_const::CastKind;
	use rustc_middle::ty::{self, Expr, TyCtxt, TypeVisitableExt};
	use rustc_middle::{mir, thir};
	use rustc_span::Span;
	use rustc_target::abi::{VariantIdx, FIRST_VARIANT};

	use std::iter;

	use crate::errors::{GenericConstantTooComplex, GenericConstantTooComplexSub};

	/// Destructures array, ADT or tuple constants into the constants
	/// of their fields.
	pub(crate) fn destructure_const<'tcx>(
	tcx: TyCtxt<'tcx>,
	const_: ty::Const<'tcx>,
	) -> ty::DestructuredConst<'tcx> {
	let ty::ConstKind::Value(valtree) = const_.kind() else {
	bug!("cannot destructure constant {:?}", const_)
	};

	let branches = match valtree {
	ty::ValTree::Branch(b) => b,
	_ => bug!("cannot destructure constant {:?}", const_),
	};

	let (fields, variant) = match const_.ty().kind() {
	ty::Array(inner_ty, _) \| ty::Slice(inner_ty) => {
	// construct the consts for the elements of the array/slice
	let field_consts =
	branches.iter().map(\|b\| tcx.mk_const(b, inner_ty)).collect::<Vec<_>>();
	debug!(?field_consts);

	(field_consts, None)
	}
	ty::Adt(def, _) if def.variants().is_empty() => bug!("unreachable"),
	ty::Adt(def, substs) => {
	let (variant_idx, branches) = if def.is_enum() {
	let (head, rest) = branches.split_first().unwrap();
	(VariantIdx::from_u32(head.unwrap_leaf().try_to_u32().unwrap()), rest)
	} else {
	(FIRST_VARIANT, branches)
	};
	let fields = &def.variant(variant_idx).fields;
	let mut field_consts = Vec::with_capacity(fields.len());

	for (field, field_valtree) in iter::zip(fields, branches) {
	let field_ty = field.ty(tcx, substs);
	let field_const = tcx.mk_const(*field_valtree, field_ty);
	field_consts.push(field_const);
	}
	debug!(?field_consts);

	(field_consts, Some(variant_idx))
	}
	ty::Tuple(elem_tys) => {
	let fields = iter::zip(*elem_tys, branches)
	.map(\|(elem_ty, elem_valtree)\| tcx.mk_const(*elem_valtree, elem_ty))
	.collect::<Vec<_>>();

	(fields, None)
	}
	_ => bug!("cannot destructure constant {:?}", const_),
	};

	let fields = tcx.arena.alloc_from_iter(fields.into_iter());

	ty::DestructuredConst { variant, fields }
	}

	/// We do not allow all binary operations in abstract consts, so filter disallowed ones.
	fn check_binop(op: mir::BinOp) -> bool {
	use mir::BinOp::*;
	match op {
	Add \| Sub \| Mul \| Div \| Rem \| BitXor \| BitAnd \| BitOr \| Shl \| Shr \| Eq \| Lt \| Le \| Ne
	\| Ge \| Gt => true,
	Offset => false,
	}
	}

	/// While we currently allow all unary operations, we still want to explicitly guard against
	/// future changes here.
	fn check_unop(op: mir::UnOp) -> bool {
	use mir::UnOp::*;
	match op {
	Not \| Neg => true,
	}
	}

	fn recurse_build<'tcx>(
	tcx: TyCtxt<'tcx>,
	body: &thir::Thir<'tcx>,
	node: thir::ExprId,
	root_span: Span,
	) -> Result<ty::Const<'tcx>, ErrorGuaranteed> {
	use thir::ExprKind;
	let node = &body.exprs[node];

	let maybe_supported_error = \|a\| maybe_supported_error(tcx, a, root_span);
	let error = \|a\| error(tcx, a, root_span);

	Ok(match &node.kind {
	// I dont know if handling of these 3 is correct
	&ExprKind::Scope { value, .. } => recurse_build(tcx, body, value, root_span)?,
	&ExprKind::PlaceTypeAscription { source, .. }
	\| &ExprKind::ValueTypeAscription { source, .. } => {
	recurse_build(tcx, body, source, root_span)?
	}
	&ExprKind::Literal { lit, neg } => {
	let sp = node.span;
	match tcx.at(sp).lit_to_const(LitToConstInput { lit: &lit.node, ty: node.ty, neg }) {
	Ok(c) => c,
	Err(LitToConstError::Reported(guar)) => tcx.const_error(node.ty, guar),
	Err(LitToConstError::TypeError) => {
	bug!("encountered type error in lit_to_const")
	}
	}
	}
	&ExprKind::NonHirLiteral { lit, user_ty: _ } => {
	let val = ty::ValTree::from_scalar_int(lit);
	tcx.mk_const(val, node.ty)
	}
	&ExprKind::ZstLiteral { user_ty: _ } => {
	let val = ty::ValTree::zst();
	tcx.mk_const(val, node.ty)
	}
	&ExprKind::NamedConst { def_id, substs, user_ty: _ } => {
	let uneval = ty::UnevaluatedConst::new(def_id, substs);
	tcx.mk_const(uneval, node.ty)
	}
	ExprKind::ConstParam { param, .. } => tcx.mk_const(*param, node.ty),

	ExprKind::Call { fun, args, .. } => {
	let fun = recurse_build(tcx, body, *fun, root_span)?;

	let mut new_args = Vec::<ty::Const<'tcx>>::with_capacity(args.len());
	for &id in args.iter() {
	new_args.push(recurse_build(tcx, body, id, root_span)?);
	}
	let new_args = tcx.mk_const_list(&new_args);
	tcx.mk_const(Expr::FunctionCall(fun, new_args), node.ty)
	}
	&ExprKind::Binary { op, lhs, rhs } if check_binop(op) => {
	let lhs = recurse_build(tcx, body, lhs, root_span)?;
	let rhs = recurse_build(tcx, body, rhs, root_span)?;
	tcx.mk_const(Expr::Binop(op, lhs, rhs), node.ty)
	}
	&ExprKind::Unary { op, arg } if check_unop(op) => {
	let arg = recurse_build(tcx, body, arg, root_span)?;
	tcx.mk_const(Expr::UnOp(op, arg), node.ty)
	}
	// This is necessary so that the following compiles:
	//
	// ```
	// fn foo<const N: usize>(a: [(); N + 1]) {
	// bar::<{ N + 1 }>();
	// }
	// ```
	ExprKind::Block { block } => {
	if let thir::Block { stmts: box [], expr: Some(e), .. } = &body.blocks[*block] {
	recurse_build(tcx, body, *e, root_span)?
	} else {
	maybe_supported_error(GenericConstantTooComplexSub::BlockNotSupported(node.span))?
	}
	}
	// `ExprKind::Use` happens when a `hir::ExprKind::Cast` is a
	// "coercion cast" i.e. using a coercion or is a no-op.
	// This is important so that `N as usize as usize` doesnt unify with `N as usize`. (untested)
	&ExprKind::Use { source } => {
	let arg = recurse_build(tcx, body, source, root_span)?;
	tcx.mk_const(Expr::Cast(CastKind::Use, arg, node.ty), node.ty)
	}
	&ExprKind::Cast { source } => {
	let arg = recurse_build(tcx, body, source, root_span)?;
	tcx.mk_const(Expr::Cast(CastKind::As, arg, node.ty), node.ty)
	}
	ExprKind::Borrow { arg, .. } => {
	let arg_node = &body.exprs[*arg];

	// Skip reborrows for now until we allow Deref/Borrow/AddressOf
	// expressions.
	// FIXME(generic_const_exprs): Verify/explain why this is sound
	if let ExprKind::Deref { arg } = arg_node.kind {
	recurse_build(tcx, body, arg, root_span)?
	} else {
	maybe_supported_error(GenericConstantTooComplexSub::BorrowNotSupported(node.span))?
	}
	}
	// FIXME(generic_const_exprs): We may want to support these.
	ExprKind::AddressOf { .. } \| ExprKind::Deref { .. } => maybe_supported_error(
	GenericConstantTooComplexSub::AddressAndDerefNotSupported(node.span),
	)?,
	ExprKind::Repeat { .. } \| ExprKind::Array { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::ArrayNotSupported(node.span))?
	}
	ExprKind::NeverToAny { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::NeverToAnyNotSupported(node.span))?
	}
	ExprKind::Tuple { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::TupleNotSupported(node.span))?
	}
	ExprKind::Index { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::IndexNotSupported(node.span))?
	}
	ExprKind::Field { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::FieldNotSupported(node.span))?
	}
	ExprKind::ConstBlock { .. } => {
	maybe_supported_error(GenericConstantTooComplexSub::ConstBlockNotSupported(node.span))?
	}
	ExprKind::Adt(_) => {
	maybe_supported_error(GenericConstantTooComplexSub::AdtNotSupported(node.span))?
	}
	// dont know if this is correct
	ExprKind::Pointer { .. } => {
	error(GenericConstantTooComplexSub::PointerNotSupported(node.span))?
	}
	ExprKind::Yield { .. } => {
	error(GenericConstantTooComplexSub::YieldNotSupported(node.span))?
	}
	ExprKind::Continue { .. } \| ExprKind::Break { .. } \| ExprKind::Loop { .. } => {
	error(GenericConstantTooComplexSub::LoopNotSupported(node.span))?
	}
	ExprKind::Box { .. } => error(GenericConstantTooComplexSub::BoxNotSupported(node.span))?,

	ExprKind::Unary { .. } => unreachable!(),
	// we handle valid unary/binary ops above
	ExprKind::Binary { .. } => {
	error(GenericConstantTooComplexSub::BinaryNotSupported(node.span))?
	}
	ExprKind::LogicalOp { .. } => {
	error(GenericConstantTooComplexSub::LogicalOpNotSupported(node.span))?
	}
	ExprKind::Assign { .. } \| ExprKind::AssignOp { .. } => {
	error(GenericConstantTooComplexSub::AssignNotSupported(node.span))?
	}
	ExprKind::Closure { .. } \| ExprKind::Return { .. } => {
	error(GenericConstantTooComplexSub::ClosureAndReturnNotSupported(node.span))?
	}
	// let expressions imply control flow
	ExprKind::Match { .. } \| ExprKind::If { .. } \| ExprKind::Let { .. } => {
	error(GenericConstantTooComplexSub::ControlFlowNotSupported(node.span))?
	}
	ExprKind::InlineAsm { .. } => {
	error(GenericConstantTooComplexSub::InlineAsmNotSupported(node.span))?
	}

	// we dont permit let stmts so `VarRef` and `UpvarRef` cant happen
	ExprKind::VarRef { .. }
	\| ExprKind::UpvarRef { .. }
	\| ExprKind::StaticRef { .. }
	\| ExprKind::OffsetOf { .. }
	\| ExprKind::ThreadLocalRef(_) => {
	error(GenericConstantTooComplexSub::OperationNotSupported(node.span))?
	}
	})
	}

	struct IsThirPolymorphic<'a, 'tcx> {
	is_poly: bool,
	thir: &'a thir::Thir<'tcx>,
	}

	fn error(
	tcx: TyCtxt<'_>,
	sub: GenericConstantTooComplexSub,
	root_span: Span,
	) -> Result<!, ErrorGuaranteed> {
	let reported = tcx.sess.emit_err(GenericConstantTooComplex {
	span: root_span,
	maybe_supported: None,
	sub,
	});

	Err(reported)
	}

	fn maybe_supported_error(
	tcx: TyCtxt<'_>,
	sub: GenericConstantTooComplexSub,
	root_span: Span,
	) -> Result<!, ErrorGuaranteed> {
	let reported = tcx.sess.emit_err(GenericConstantTooComplex {
	span: root_span,
	maybe_supported: Some(()),
	sub,
	});

	Err(reported)
	}

	impl<'a, 'tcx> IsThirPolymorphic<'a, 'tcx> {
	fn expr_is_poly(&mut self, expr: &thir::Expr<'tcx>) -> bool {
	if expr.ty.has_non_region_param() {
	return true;
	}

	match expr.kind {
	thir::ExprKind::NamedConst { substs, .. }
	\| thir::ExprKind::ConstBlock { substs, .. } => substs.has_non_region_param(),
	thir::ExprKind::ConstParam { .. } => true,
	thir::ExprKind::Repeat { value, count } => {
	self.visit_expr(&self.thir()[value]);
	count.has_non_region_param()
	}
	thir::ExprKind::Scope { .. }
	\| thir::ExprKind::Box { .. }
	\| thir::ExprKind::If { .. }
	\| thir::ExprKind::Call { .. }
	\| thir::ExprKind::Deref { .. }
	\| thir::ExprKind::Binary { .. }
	\| thir::ExprKind::LogicalOp { .. }
	\| thir::ExprKind::Unary { .. }
	\| thir::ExprKind::Cast { .. }
	\| thir::ExprKind::Use { .. }
	\| thir::ExprKind::NeverToAny { .. }
	\| thir::ExprKind::Pointer { .. }
	\| thir::ExprKind::Loop { .. }
	\| thir::ExprKind::Let { .. }
	\| thir::ExprKind::Match { .. }
	\| thir::ExprKind::Block { .. }
	\| thir::ExprKind::Assign { .. }
	\| thir::ExprKind::AssignOp { .. }
	\| thir::ExprKind::Field { .. }
	\| thir::ExprKind::Index { .. }
	\| thir::ExprKind::VarRef { .. }
	\| thir::ExprKind::UpvarRef { .. }
	\| thir::ExprKind::Borrow { .. }
	\| thir::ExprKind::AddressOf { .. }
	\| thir::ExprKind::Break { .. }
	\| thir::ExprKind::Continue { .. }
	\| thir::ExprKind::Return { .. }
	\| thir::ExprKind::Array { .. }
	\| thir::ExprKind::Tuple { .. }
	\| thir::ExprKind::Adt(_)
	\| thir::ExprKind::PlaceTypeAscription { .. }
	\| thir::ExprKind::ValueTypeAscription { .. }
	\| thir::ExprKind::Closure(_)
	\| thir::ExprKind::Literal { .. }
	\| thir::ExprKind::NonHirLiteral { .. }
	\| thir::ExprKind::ZstLiteral { .. }
	\| thir::ExprKind::StaticRef { .. }
	\| thir::ExprKind::InlineAsm(_)
	\| thir::ExprKind::OffsetOf { .. }
	\| thir::ExprKind::ThreadLocalRef(_)
	\| thir::ExprKind::Yield { .. } => false,
	}
	}
	fn pat_is_poly(&mut self, pat: &thir::Pat<'tcx>) -> bool {
	if pat.ty.has_non_region_param() {
	return true;
	}

	match pat.kind {
	thir::PatKind::Constant { value } => value.has_non_region_param(),
	thir::PatKind::Range(box thir::PatRange { lo, hi, .. }) => {
	lo.has_non_region_param() \|\| hi.has_non_region_param()
	}
	_ => false,
	}
	}
	}

	impl<'a, 'tcx> visit::Visitor<'a, 'tcx> for IsThirPolymorphic<'a, 'tcx> {
	fn thir(&self) -> &'a thir::Thir<'tcx> {
	&self.thir
	}

	#[instrument(skip(self), level = "debug")]
	fn visit_expr(&mut self, expr: &thir::Expr<'tcx>) {
	self.is_poly \|= self.expr_is_poly(expr);
	if !self.is_poly {
	visit::walk_expr(self, expr)
	}
	}

	#[instrument(skip(self), level = "debug")]
	fn visit_pat(&mut self, pat: &thir::Pat<'tcx>) {
	self.is_poly \|= self.pat_is_poly(pat);
	if !self.is_poly {
	visit::walk_pat(self, pat);
	}
	}
	}

	/// Builds an abstract const, do not use this directly, but use `AbstractConst::new` instead.
	pub fn thir_abstract_const(
	tcx: TyCtxt<'_>,
	def: LocalDefId,
	) -> Result<Option<ty::EarlyBinder<ty::Const<'_>>>, ErrorGuaranteed> {
	if !tcx.features().generic_const_exprs {
	return Ok(None);
	}

	match tcx.def_kind(def) {
	// FIXME(generic_const_exprs): We currently only do this for anonymous constants,
	// meaning that we do not look into associated constants. I(@lcnr) am not yet sure whether
	// we want to look into them or treat them as opaque projections.
	//
	// Right now we do neither of that and simply always fail to unify them.
	DefKind::AnonConst \| DefKind::InlineConst => (),
	_ => return Ok(None),
	}

	let body = tcx.thir_body(def)?;
	let (body, body_id) = (&*body.0.borrow(), body.1);

	let mut is_poly_vis = IsThirPolymorphic { is_poly: false, thir: body };
	visit::walk_expr(&mut is_poly_vis, &body[body_id]);
	if !is_poly_vis.is_poly {
	return Ok(None);
	}

	let root_span = body.exprs[body_id].span;

	Ok(Some(ty::EarlyBinder::new(recurse_build(tcx, body, body_id, root_span)?)))
	}

	pub fn provide(providers: &mut Providers) {
	providers = Providers { destructure_const, thir_abstract_const, ..providers };
	}