// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! misc. type-system utilities too small to deserve their own file use hir::svh::Svh; use hir::def_id::DefId; use ty::subst; use infer::InferCtxt; use hir::pat_util; use traits::{self, ProjectionMode}; use ty::{self, Ty, TyCtxt, TypeAndMut, TypeFlags, TypeFoldable}; use ty::{Disr, ParameterEnvironment}; use ty::layout::{Layout, LayoutError}; use ty::TypeVariants::*; use rustc_const_math::{ConstInt, ConstIsize, ConstUsize}; use std::cmp; use std::hash::{Hash, SipHasher, Hasher}; use syntax::ast::{self, Name}; use syntax::attr::{self, SignedInt, UnsignedInt}; use syntax::codemap::Span; use hir; pub trait IntTypeExt { fn to_ty<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>) -> Ty<'tcx>; fn disr_incr<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>, val: Option) -> Option; fn assert_ty_matches(&self, val: Disr); fn initial_discriminant<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>) -> Disr; } impl IntTypeExt for attr::IntType { fn to_ty<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>) -> Ty<'tcx> { match *self { SignedInt(ast::IntTy::I8) => tcx.types.i8, SignedInt(ast::IntTy::I16) => tcx.types.i16, SignedInt(ast::IntTy::I32) => tcx.types.i32, SignedInt(ast::IntTy::I64) => tcx.types.i64, SignedInt(ast::IntTy::Is) => tcx.types.isize, UnsignedInt(ast::UintTy::U8) => tcx.types.u8, UnsignedInt(ast::UintTy::U16) => tcx.types.u16, UnsignedInt(ast::UintTy::U32) => tcx.types.u32, UnsignedInt(ast::UintTy::U64) => tcx.types.u64, UnsignedInt(ast::UintTy::Us) => tcx.types.usize, } } fn initial_discriminant<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>) -> Disr { match *self { SignedInt(ast::IntTy::I8) => ConstInt::I8(0), SignedInt(ast::IntTy::I16) => ConstInt::I16(0), SignedInt(ast::IntTy::I32) => ConstInt::I32(0), SignedInt(ast::IntTy::I64) => ConstInt::I64(0), SignedInt(ast::IntTy::Is) => match tcx.sess.target.int_type { ast::IntTy::I16 => ConstInt::Isize(ConstIsize::Is16(0)), ast::IntTy::I32 => ConstInt::Isize(ConstIsize::Is32(0)), ast::IntTy::I64 => ConstInt::Isize(ConstIsize::Is64(0)), _ => bug!(), }, UnsignedInt(ast::UintTy::U8) => ConstInt::U8(0), UnsignedInt(ast::UintTy::U16) => ConstInt::U16(0), UnsignedInt(ast::UintTy::U32) => ConstInt::U32(0), UnsignedInt(ast::UintTy::U64) => ConstInt::U64(0), UnsignedInt(ast::UintTy::Us) => match tcx.sess.target.uint_type { ast::UintTy::U16 => ConstInt::Usize(ConstUsize::Us16(0)), ast::UintTy::U32 => ConstInt::Usize(ConstUsize::Us32(0)), ast::UintTy::U64 => ConstInt::Usize(ConstUsize::Us64(0)), _ => bug!(), }, } } fn assert_ty_matches(&self, val: Disr) { match (*self, val) { (SignedInt(ast::IntTy::I8), ConstInt::I8(_)) => {}, (SignedInt(ast::IntTy::I16), ConstInt::I16(_)) => {}, (SignedInt(ast::IntTy::I32), ConstInt::I32(_)) => {}, (SignedInt(ast::IntTy::I64), ConstInt::I64(_)) => {}, (SignedInt(ast::IntTy::Is), ConstInt::Isize(_)) => {}, (UnsignedInt(ast::UintTy::U8), ConstInt::U8(_)) => {}, (UnsignedInt(ast::UintTy::U16), ConstInt::U16(_)) => {}, (UnsignedInt(ast::UintTy::U32), ConstInt::U32(_)) => {}, (UnsignedInt(ast::UintTy::U64), ConstInt::U64(_)) => {}, (UnsignedInt(ast::UintTy::Us), ConstInt::Usize(_)) => {}, _ => bug!("disr type mismatch: {:?} vs {:?}", self, val), } } fn disr_incr<'a, 'tcx>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>, val: Option) -> Option { if let Some(val) = val { self.assert_ty_matches(val); (val + ConstInt::Infer(1)).ok() } else { Some(self.initial_discriminant(tcx)) } } } #[derive(Copy, Clone)] pub enum CopyImplementationError { InfrigingField(Name), InfrigingVariant(Name), NotAnAdt, HasDestructor } /// Describes whether a type is representable. For types that are not /// representable, 'SelfRecursive' and 'ContainsRecursive' are used to /// distinguish between types that are recursive with themselves and types that /// contain a different recursive type. These cases can therefore be treated /// differently when reporting errors. /// /// The ordering of the cases is significant. They are sorted so that cmp::max /// will keep the "more erroneous" of two values. #[derive(Copy, Clone, PartialOrd, Ord, Eq, PartialEq, Debug)] pub enum Representability { Representable, ContainsRecursive, SelfRecursive, } impl<'tcx> ParameterEnvironment<'tcx> { pub fn can_type_implement_copy<'a>(&self, tcx: TyCtxt<'a, 'tcx, 'tcx>, self_type: Ty<'tcx>, span: Span) -> Result<(),CopyImplementationError> { // FIXME: (@jroesch) float this code up tcx.infer_ctxt(None, Some(self.clone()), ProjectionMode::Topmost).enter(|infcx| { let adt = match self_type.sty { ty::TyStruct(struct_def, substs) => { for field in struct_def.all_fields() { let field_ty = field.ty(tcx, substs); if infcx.type_moves_by_default(field_ty, span) { return Err(CopyImplementationError::InfrigingField( field.name)) } } struct_def } ty::TyEnum(enum_def, substs) => { for variant in &enum_def.variants { for field in &variant.fields { let field_ty = field.ty(tcx, substs); if infcx.type_moves_by_default(field_ty, span) { return Err(CopyImplementationError::InfrigingVariant( variant.name)) } } } enum_def } _ => return Err(CopyImplementationError::NotAnAdt) }; if adt.has_dtor() { return Err(CopyImplementationError::HasDestructor); } Ok(()) }) } } impl<'a, 'gcx, 'tcx> TyCtxt<'a, 'gcx, 'tcx> { pub fn pat_contains_ref_binding(self, pat: &hir::Pat) -> Option { pat_util::pat_contains_ref_binding(pat) } pub fn arm_contains_ref_binding(self, arm: &hir::Arm) -> Option { pat_util::arm_contains_ref_binding(arm) } /// Returns the type of element at index `i` in tuple or tuple-like type `t`. /// For an enum `t`, `variant` is None only if `t` is a univariant enum. pub fn positional_element_ty(self, ty: Ty<'tcx>, i: usize, variant: Option) -> Option> { match (&ty.sty, variant) { (&TyStruct(def, substs), None) => { def.struct_variant().fields.get(i).map(|f| f.ty(self, substs)) } (&TyEnum(def, substs), Some(vid)) => { def.variant_with_id(vid).fields.get(i).map(|f| f.ty(self, substs)) } (&TyEnum(def, substs), None) => { assert!(def.is_univariant()); def.variants[0].fields.get(i).map(|f| f.ty(self, substs)) } (&TyTuple(ref v), None) => v.get(i).cloned(), _ => None } } /// Returns the type of element at field `n` in struct or struct-like type `t`. /// For an enum `t`, `variant` must be some def id. pub fn named_element_ty(self, ty: Ty<'tcx>, n: Name, variant: Option) -> Option> { match (&ty.sty, variant) { (&TyStruct(def, substs), None) => { def.struct_variant().find_field_named(n).map(|f| f.ty(self, substs)) } (&TyEnum(def, substs), Some(vid)) => { def.variant_with_id(vid).find_field_named(n).map(|f| f.ty(self, substs)) } _ => return None } } /// Returns the IntType representation. /// This used to ensure `int_ty` doesn't contain `usize` and `isize` /// by converting them to their actual types. That doesn't happen anymore. pub fn enum_repr_type(self, opt_hint: Option<&attr::ReprAttr>) -> attr::IntType { match opt_hint { // Feed in the given type Some(&attr::ReprInt(_, int_t)) => int_t, // ... but provide sensible default if none provided // // NB. Historically `fn enum_variants` generate i64 here, while // rustc_typeck::check would generate isize. _ => SignedInt(ast::IntTy::Is), } } /// Returns the deeply last field of nested structures, or the same type, /// if not a structure at all. Corresponds to the only possible unsized /// field, and its type can be used to determine unsizing strategy. pub fn struct_tail(self, mut ty: Ty<'tcx>) -> Ty<'tcx> { while let TyStruct(def, substs) = ty.sty { match def.struct_variant().fields.last() { Some(f) => ty = f.ty(self, substs), None => break } } ty } /// Same as applying struct_tail on `source` and `target`, but only /// keeps going as long as the two types are instances of the same /// structure definitions. /// For `(Foo>, Foo)`, the result will be `(Foo, Trait)`, /// whereas struct_tail produces `T`, and `Trait`, respectively. pub fn struct_lockstep_tails(self, source: Ty<'tcx>, target: Ty<'tcx>) -> (Ty<'tcx>, Ty<'tcx>) { let (mut a, mut b) = (source, target); while let (&TyStruct(a_def, a_substs), &TyStruct(b_def, b_substs)) = (&a.sty, &b.sty) { if a_def != b_def { break; } if let Some(f) = a_def.struct_variant().fields.last() { a = f.ty(self, a_substs); b = f.ty(self, b_substs); } else { break; } } (a, b) } /// Given a set of predicates that apply to an object type, returns /// the region bounds that the (erased) `Self` type must /// outlive. Precisely *because* the `Self` type is erased, the /// parameter `erased_self_ty` must be supplied to indicate what type /// has been used to represent `Self` in the predicates /// themselves. This should really be a unique type; `FreshTy(0)` is a /// popular choice. /// /// NB: in some cases, particularly around higher-ranked bounds, /// this function returns a kind of conservative approximation. /// That is, all regions returned by this function are definitely /// required, but there may be other region bounds that are not /// returned, as well as requirements like `for<'a> T: 'a`. /// /// Requires that trait definitions have been processed so that we can /// elaborate predicates and walk supertraits. pub fn required_region_bounds(self, erased_self_ty: Ty<'tcx>, predicates: Vec>) -> Vec { debug!("required_region_bounds(erased_self_ty={:?}, predicates={:?})", erased_self_ty, predicates); assert!(!erased_self_ty.has_escaping_regions()); traits::elaborate_predicates(self, predicates) .filter_map(|predicate| { match predicate { ty::Predicate::Projection(..) | ty::Predicate::Trait(..) | ty::Predicate::Rfc1592(..) | ty::Predicate::Equate(..) | ty::Predicate::WellFormed(..) | ty::Predicate::ObjectSafe(..) | ty::Predicate::ClosureKind(..) | ty::Predicate::RegionOutlives(..) => { None } ty::Predicate::TypeOutlives(ty::Binder(ty::OutlivesPredicate(t, r))) => { // Search for a bound of the form `erased_self_ty // : 'a`, but be wary of something like `for<'a> // erased_self_ty : 'a` (we interpret a // higher-ranked bound like that as 'static, // though at present the code in `fulfill.rs` // considers such bounds to be unsatisfiable, so // it's kind of a moot point since you could never // construct such an object, but this seems // correct even if that code changes). if t == erased_self_ty && !r.has_escaping_regions() { Some(r) } else { None } } } }) .collect() } /// Creates a hash of the type `Ty` which will be the same no matter what crate /// context it's calculated within. This is used by the `type_id` intrinsic. pub fn hash_crate_independent(self, ty: Ty<'tcx>, svh: &Svh) -> u64 { let mut state = SipHasher::new(); helper(self, ty, svh, &mut state); return state.finish(); fn helper<'a, 'gcx, 'tcx>(tcx: TyCtxt<'a, 'gcx, 'tcx>, ty: Ty<'tcx>, svh: &Svh, state: &mut SipHasher) { macro_rules! byte { ($b:expr) => { ($b as u8).hash(state) } } macro_rules! hash { ($e:expr) => { $e.hash(state) } } let region = |state: &mut SipHasher, r: ty::Region| { match r { ty::ReStatic | ty::ReErased => {} ty::ReLateBound(db, ty::BrAnon(i)) => { db.hash(state); i.hash(state); } ty::ReEmpty | ty::ReEarlyBound(..) | ty::ReLateBound(..) | ty::ReFree(..) | ty::ReScope(..) | ty::ReVar(..) | ty::ReSkolemized(..) => { bug!("unexpected region found when hashing a type") } } }; let did = |state: &mut SipHasher, did: DefId| { let h = if did.is_local() { svh.clone() } else { tcx.sess.cstore.crate_hash(did.krate) }; h.hash(state); did.index.hash(state); }; let mt = |state: &mut SipHasher, mt: TypeAndMut| { mt.mutbl.hash(state); }; let fn_sig = |state: &mut SipHasher, sig: &ty::Binder>| { let sig = tcx.anonymize_late_bound_regions(sig).0; for a in &sig.inputs { helper(tcx, *a, svh, state); } if let ty::FnConverging(output) = sig.output { helper(tcx, output, svh, state); } }; ty.maybe_walk(|ty| { match ty.sty { TyBool => byte!(2), TyChar => byte!(3), TyInt(i) => { byte!(4); hash!(i); } TyUint(u) => { byte!(5); hash!(u); } TyFloat(f) => { byte!(6); hash!(f); } TyStr => { byte!(7); } TyEnum(d, _) => { byte!(8); did(state, d.did); } TyBox(_) => { byte!(9); } TyArray(_, n) => { byte!(10); n.hash(state); } TySlice(_) => { byte!(11); } TyRawPtr(m) => { byte!(12); mt(state, m); } TyRef(r, m) => { byte!(13); region(state, *r); mt(state, m); } TyFnDef(def_id, _, _) => { byte!(14); hash!(def_id); } TyFnPtr(ref b) => { byte!(15); hash!(b.unsafety); hash!(b.abi); fn_sig(state, &b.sig); return false; } TyTrait(ref data) => { byte!(17); did(state, data.principal_def_id()); hash!(data.bounds); let principal = tcx.anonymize_late_bound_regions(&data.principal).0; for subty in &principal.substs.types { helper(tcx, subty, svh, state); } return false; } TyStruct(d, _) => { byte!(18); did(state, d.did); } TyTuple(ref inner) => { byte!(19); hash!(inner.len()); } TyParam(p) => { byte!(20); hash!(p.space); hash!(p.idx); hash!(p.name.as_str()); } TyInfer(_) => bug!(), TyError => byte!(21), TyClosure(d, _) => { byte!(22); did(state, d); } TyProjection(ref data) => { byte!(23); did(state, data.trait_ref.def_id); hash!(data.item_name.as_str()); } } true }); } } /// Returns true if this ADT is a dtorck type. /// /// Invoking the destructor of a dtorck type during usual cleanup /// (e.g. the glue emitted for stack unwinding) requires all /// lifetimes in the type-structure of `adt` to strictly outlive /// the adt value itself. /// /// If `adt` is not dtorck, then the adt's destructor can be /// invoked even when there are lifetimes in the type-structure of /// `adt` that do not strictly outlive the adt value itself. /// (This allows programs to make cyclic structures without /// resorting to unasfe means; see RFCs 769 and 1238). pub fn is_adt_dtorck(self, adt: ty::AdtDef) -> bool { let dtor_method = match adt.destructor() { Some(dtor) => dtor, None => return false }; // RFC 1238: if the destructor method is tagged with the // attribute `unsafe_destructor_blind_to_params`, then the // compiler is being instructed to *assume* that the // destructor will not access borrowed data, // even if such data is otherwise reachable. // // Such access can be in plain sight (e.g. dereferencing // `*foo.0` of `Foo<'a>(&'a u32)`) or indirectly hidden // (e.g. calling `foo.0.clone()` of `Foo`). return !self.has_attr(dtor_method, "unsafe_destructor_blind_to_params"); } } impl<'a, 'tcx> ty::TyS<'tcx> { fn impls_bound(&'tcx self, tcx: TyCtxt<'a, 'tcx, 'tcx>, param_env: &ParameterEnvironment<'tcx>, bound: ty::BuiltinBound, span: Span) -> bool { tcx.infer_ctxt(None, Some(param_env.clone()), ProjectionMode::Topmost).enter(|infcx| { traits::type_known_to_meet_builtin_bound(&infcx, self, bound, span) }) } // FIXME (@jroesch): I made this public to use it, not sure if should be private pub fn moves_by_default(&'tcx self, tcx: TyCtxt<'a, 'tcx, 'tcx>, param_env: &ParameterEnvironment<'tcx>, span: Span) -> bool { if self.flags.get().intersects(TypeFlags::MOVENESS_CACHED) { return self.flags.get().intersects(TypeFlags::MOVES_BY_DEFAULT); } assert!(!self.needs_infer()); // Fast-path for primitive types let result = match self.sty { TyBool | TyChar | TyInt(..) | TyUint(..) | TyFloat(..) | TyRawPtr(..) | TyFnDef(..) | TyFnPtr(_) | TyRef(_, TypeAndMut { mutbl: hir::MutImmutable, .. }) => Some(false), TyStr | TyBox(..) | TyRef(_, TypeAndMut { mutbl: hir::MutMutable, .. }) => Some(true), TyArray(..) | TySlice(_) | TyTrait(..) | TyTuple(..) | TyClosure(..) | TyEnum(..) | TyStruct(..) | TyProjection(..) | TyParam(..) | TyInfer(..) | TyError => None }.unwrap_or_else(|| !self.impls_bound(tcx, param_env, ty::BoundCopy, span)); if !self.has_param_types() && !self.has_self_ty() { self.flags.set(self.flags.get() | if result { TypeFlags::MOVENESS_CACHED | TypeFlags::MOVES_BY_DEFAULT } else { TypeFlags::MOVENESS_CACHED }); } result } #[inline] pub fn is_sized(&'tcx self, tcx: TyCtxt<'a, 'tcx, 'tcx>, param_env: &ParameterEnvironment<'tcx>, span: Span) -> bool { if self.flags.get().intersects(TypeFlags::SIZEDNESS_CACHED) { return self.flags.get().intersects(TypeFlags::IS_SIZED); } self.is_sized_uncached(tcx, param_env, span) } fn is_sized_uncached(&'tcx self, tcx: TyCtxt<'a, 'tcx, 'tcx>, param_env: &ParameterEnvironment<'tcx>, span: Span) -> bool { assert!(!self.needs_infer()); // Fast-path for primitive types let result = match self.sty { TyBool | TyChar | TyInt(..) | TyUint(..) | TyFloat(..) | TyBox(..) | TyRawPtr(..) | TyRef(..) | TyFnDef(..) | TyFnPtr(_) | TyArray(..) | TyTuple(..) | TyClosure(..) => Some(true), TyStr | TyTrait(..) | TySlice(_) => Some(false), TyEnum(..) | TyStruct(..) | TyProjection(..) | TyParam(..) | TyInfer(..) | TyError => None }.unwrap_or_else(|| self.impls_bound(tcx, param_env, ty::BoundSized, span)); if !self.has_param_types() && !self.has_self_ty() { self.flags.set(self.flags.get() | if result { TypeFlags::SIZEDNESS_CACHED | TypeFlags::IS_SIZED } else { TypeFlags::SIZEDNESS_CACHED }); } result } #[inline] pub fn layout<'lcx>(&'tcx self, infcx: &InferCtxt<'a, 'tcx, 'lcx>) -> Result<&'tcx Layout, LayoutError<'tcx>> { let tcx = infcx.tcx.global_tcx(); let can_cache = !self.has_param_types() && !self.has_self_ty(); if can_cache { if let Some(&cached) = tcx.layout_cache.borrow().get(&self) { return Ok(cached); } } let layout = Layout::compute_uncached(self, infcx)?; let layout = tcx.intern_layout(layout); if can_cache { tcx.layout_cache.borrow_mut().insert(self, layout); } Ok(layout) } /// Check whether a type is representable. This means it cannot contain unboxed /// structural recursion. This check is needed for structs and enums. pub fn is_representable(&'tcx self, tcx: TyCtxt<'a, 'tcx, 'tcx>, sp: Span) -> Representability { // Iterate until something non-representable is found fn find_nonrepresentable<'a, 'tcx, It>(tcx: TyCtxt<'a, 'tcx, 'tcx>, sp: Span, seen: &mut Vec>, iter: It) -> Representability where It: Iterator> { iter.fold(Representability::Representable, |r, ty| cmp::max(r, is_type_structurally_recursive(tcx, sp, seen, ty))) } fn are_inner_types_recursive<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, sp: Span, seen: &mut Vec>, ty: Ty<'tcx>) -> Representability { match ty.sty { TyTuple(ref ts) => { find_nonrepresentable(tcx, sp, seen, ts.iter().cloned()) } // Fixed-length vectors. // FIXME(#11924) Behavior undecided for zero-length vectors. TyArray(ty, _) => { is_type_structurally_recursive(tcx, sp, seen, ty) } TyStruct(def, substs) | TyEnum(def, substs) => { find_nonrepresentable(tcx, sp, seen, def.all_fields().map(|f| f.ty(tcx, substs))) } TyClosure(..) => { // this check is run on type definitions, so we don't expect // to see closure types bug!("requires check invoked on inapplicable type: {:?}", ty) } _ => Representability::Representable, } } fn same_struct_or_enum<'tcx>(ty: Ty<'tcx>, def: ty::AdtDef<'tcx>) -> bool { match ty.sty { TyStruct(ty_def, _) | TyEnum(ty_def, _) => { ty_def == def } _ => false } } fn same_type<'tcx>(a: Ty<'tcx>, b: Ty<'tcx>) -> bool { match (&a.sty, &b.sty) { (&TyStruct(did_a, ref substs_a), &TyStruct(did_b, ref substs_b)) | (&TyEnum(did_a, ref substs_a), &TyEnum(did_b, ref substs_b)) => { if did_a != did_b { return false; } let types_a = substs_a.types.get_slice(subst::TypeSpace); let types_b = substs_b.types.get_slice(subst::TypeSpace); let mut pairs = types_a.iter().zip(types_b); pairs.all(|(&a, &b)| same_type(a, b)) } _ => { a == b } } } // Does the type `ty` directly (without indirection through a pointer) // contain any types on stack `seen`? fn is_type_structurally_recursive<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, sp: Span, seen: &mut Vec>, ty: Ty<'tcx>) -> Representability { debug!("is_type_structurally_recursive: {:?}", ty); match ty.sty { TyStruct(def, _) | TyEnum(def, _) => { { // Iterate through stack of previously seen types. let mut iter = seen.iter(); // The first item in `seen` is the type we are actually curious about. // We want to return SelfRecursive if this type contains itself. // It is important that we DON'T take generic parameters into account // for this check, so that Bar in this example counts as SelfRecursive: // // struct Foo; // struct Bar { x: Bar } match iter.next() { Some(&seen_type) => { if same_struct_or_enum(seen_type, def) { debug!("SelfRecursive: {:?} contains {:?}", seen_type, ty); return Representability::SelfRecursive; } } None => {} } // We also need to know whether the first item contains other types // that are structurally recursive. If we don't catch this case, we // will recurse infinitely for some inputs. // // It is important that we DO take generic parameters into account // here, so that code like this is considered SelfRecursive, not // ContainsRecursive: // // struct Foo { Option> } for &seen_type in iter { if same_type(ty, seen_type) { debug!("ContainsRecursive: {:?} contains {:?}", seen_type, ty); return Representability::ContainsRecursive; } } } // For structs and enums, track all previously seen types by pushing them // onto the 'seen' stack. seen.push(ty); let out = are_inner_types_recursive(tcx, sp, seen, ty); seen.pop(); out } _ => { // No need to push in other cases. are_inner_types_recursive(tcx, sp, seen, ty) } } } debug!("is_type_representable: {:?}", self); // To avoid a stack overflow when checking an enum variant or struct that // contains a different, structurally recursive type, maintain a stack // of seen types and check recursion for each of them (issues #3008, #3779). let mut seen: Vec = Vec::new(); let r = is_type_structurally_recursive(tcx, sp, &mut seen, self); debug!("is_type_representable: {:?} is {:?}", self, r); r } }