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|
//! Trait Resolution. See the [rustc dev guide] for more information on how this works.
//!
//! [rustc dev guide]: https://rustc-dev-guide.rust-lang.org/traits/resolution.html
mod chalk;
pub mod query;
pub mod select;
pub mod specialization_graph;
mod structural_impls;
pub mod util;
use crate::infer::canonical::Canonical;
use crate::mir::ConstraintCategory;
use crate::ty::abstract_const::NotConstEvaluatable;
use crate::ty::subst::SubstsRef;
use crate::ty::{self, AdtKind, Ty, TyCtxt};
use rustc_data_structures::sync::Lrc;
use rustc_errors::{Applicability, Diagnostic};
use rustc_hir as hir;
use rustc_hir::def_id::{DefId, LocalDefId};
use rustc_span::symbol::Symbol;
use rustc_span::{Span, DUMMY_SP};
use smallvec::SmallVec;
use std::borrow::Cow;
use std::hash::{Hash, Hasher};
pub use self::select::{EvaluationCache, EvaluationResult, OverflowError, SelectionCache};
pub type CanonicalChalkEnvironmentAndGoal<'tcx> = Canonical<'tcx, ChalkEnvironmentAndGoal<'tcx>>;
pub use self::ObligationCauseCode::*;
pub use self::chalk::{ChalkEnvironmentAndGoal, RustInterner as ChalkRustInterner};
/// Depending on the stage of compilation, we want projection to be
/// more or less conservative.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash, HashStable)]
pub enum Reveal {
/// At type-checking time, we refuse to project any associated
/// type that is marked `default`. Non-`default` ("final") types
/// are always projected. This is necessary in general for
/// soundness of specialization. However, we *could* allow
/// projections in fully-monomorphic cases. We choose not to,
/// because we prefer for `default type` to force the type
/// definition to be treated abstractly by any consumers of the
/// impl. Concretely, that means that the following example will
/// fail to compile:
///
/// ```compile_fail,E0308
/// #![feature(specialization)]
/// trait Assoc {
/// type Output;
/// }
///
/// impl<T> Assoc for T {
/// default type Output = bool;
/// }
///
/// fn main() {
/// let x: <() as Assoc>::Output = true;
/// }
/// ```
///
/// We also do not reveal the hidden type of opaque types during
/// type-checking.
UserFacing,
/// At codegen time, all monomorphic projections will succeed.
/// Also, `impl Trait` is normalized to the concrete type,
/// which has to be already collected by type-checking.
///
/// NOTE: as `impl Trait`'s concrete type should *never*
/// be observable directly by the user, `Reveal::All`
/// should not be used by checks which may expose
/// type equality or type contents to the user.
/// There are some exceptions, e.g., around auto traits and
/// transmute-checking, which expose some details, but
/// not the whole concrete type of the `impl Trait`.
All,
}
/// The reason why we incurred this obligation; used for error reporting.
///
/// Non-misc `ObligationCauseCode`s are stored on the heap. This gives the
/// best trade-off between keeping the type small (which makes copies cheaper)
/// while not doing too many heap allocations.
///
/// We do not want to intern this as there are a lot of obligation causes which
/// only live for a short period of time.
#[derive(Clone, Debug, PartialEq, Eq, Lift)]
pub struct ObligationCause<'tcx> {
pub span: Span,
/// The ID of the fn body that triggered this obligation. This is
/// used for region obligations to determine the precise
/// environment in which the region obligation should be evaluated
/// (in particular, closures can add new assumptions). See the
/// field `region_obligations` of the `FulfillmentContext` for more
/// information.
pub body_id: hir::HirId,
code: InternedObligationCauseCode<'tcx>,
}
// This custom hash function speeds up hashing for `Obligation` deduplication
// greatly by skipping the `code` field, which can be large and complex. That
// shouldn't affect hash quality much since there are several other fields in
// `Obligation` which should be unique enough, especially the predicate itself
// which is hashed as an interned pointer. See #90996.
impl Hash for ObligationCause<'_> {
fn hash<H: Hasher>(&self, state: &mut H) {
self.body_id.hash(state);
self.span.hash(state);
}
}
impl<'tcx> ObligationCause<'tcx> {
#[inline]
pub fn new(
span: Span,
body_id: hir::HirId,
code: ObligationCauseCode<'tcx>,
) -> ObligationCause<'tcx> {
ObligationCause { span, body_id, code: code.into() }
}
pub fn misc(span: Span, body_id: hir::HirId) -> ObligationCause<'tcx> {
ObligationCause::new(span, body_id, MiscObligation)
}
#[inline(always)]
pub fn dummy() -> ObligationCause<'tcx> {
ObligationCause::dummy_with_span(DUMMY_SP)
}
#[inline(always)]
pub fn dummy_with_span(span: Span) -> ObligationCause<'tcx> {
ObligationCause { span, body_id: hir::CRATE_HIR_ID, code: Default::default() }
}
pub fn span(&self) -> Span {
match *self.code() {
ObligationCauseCode::MatchExpressionArm(box MatchExpressionArmCause {
arm_span,
..
}) => arm_span,
_ => self.span,
}
}
#[inline]
pub fn code(&self) -> &ObligationCauseCode<'tcx> {
&self.code
}
pub fn map_code(
&mut self,
f: impl FnOnce(InternedObligationCauseCode<'tcx>) -> ObligationCauseCode<'tcx>,
) {
self.code = f(std::mem::take(&mut self.code)).into();
}
pub fn derived_cause(
mut self,
parent_trait_pred: ty::PolyTraitPredicate<'tcx>,
variant: impl FnOnce(DerivedObligationCause<'tcx>) -> ObligationCauseCode<'tcx>,
) -> ObligationCause<'tcx> {
/*!
* Creates a cause for obligations that are derived from
* `obligation` by a recursive search (e.g., for a builtin
* bound, or eventually a `auto trait Foo`). If `obligation`
* is itself a derived obligation, this is just a clone, but
* otherwise we create a "derived obligation" cause so as to
* keep track of the original root obligation for error
* reporting.
*/
// NOTE(flaper87): As of now, it keeps track of the whole error
// chain. Ideally, we should have a way to configure this either
// by using -Z verbose or just a CLI argument.
self.code =
variant(DerivedObligationCause { parent_trait_pred, parent_code: self.code }).into();
self
}
pub fn to_constraint_category(&self) -> ConstraintCategory<'tcx> {
match self.code() {
MatchImpl(cause, _) => cause.to_constraint_category(),
AscribeUserTypeProvePredicate(predicate_span) => {
ConstraintCategory::Predicate(*predicate_span)
}
_ => ConstraintCategory::BoringNoLocation,
}
}
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift)]
pub struct UnifyReceiverContext<'tcx> {
pub assoc_item: ty::AssocItem,
pub param_env: ty::ParamEnv<'tcx>,
pub substs: SubstsRef<'tcx>,
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift, Default)]
pub struct InternedObligationCauseCode<'tcx> {
/// `None` for `ObligationCauseCode::MiscObligation` (a common case, occurs ~60% of
/// the time). `Some` otherwise.
code: Option<Lrc<ObligationCauseCode<'tcx>>>,
}
impl<'tcx> ObligationCauseCode<'tcx> {
#[inline(always)]
fn into(self) -> InternedObligationCauseCode<'tcx> {
InternedObligationCauseCode {
code: if let ObligationCauseCode::MiscObligation = self {
None
} else {
Some(Lrc::new(self))
},
}
}
}
impl<'tcx> std::ops::Deref for InternedObligationCauseCode<'tcx> {
type Target = ObligationCauseCode<'tcx>;
fn deref(&self) -> &Self::Target {
self.code.as_deref().unwrap_or(&ObligationCauseCode::MiscObligation)
}
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift)]
pub enum ObligationCauseCode<'tcx> {
/// Not well classified or should be obvious from the span.
MiscObligation,
/// A slice or array is WF only if `T: Sized`.
SliceOrArrayElem,
/// A tuple is WF only if its middle elements are `Sized`.
TupleElem,
/// This is the trait reference from the given projection.
ProjectionWf(ty::ProjectionTy<'tcx>),
/// Must satisfy all of the where-clause predicates of the
/// given item.
ItemObligation(DefId),
/// Like `ItemObligation`, but carries the span of the
/// predicate when it can be identified.
BindingObligation(DefId, Span),
/// Like `ItemObligation`, but carries the `HirId` of the
/// expression that caused the obligation, and the `usize`
/// indicates exactly which predicate it is in the list of
/// instantiated predicates.
ExprItemObligation(DefId, rustc_hir::HirId, usize),
/// Combines `ExprItemObligation` and `BindingObligation`.
ExprBindingObligation(DefId, Span, rustc_hir::HirId, usize),
/// A type like `&'a T` is WF only if `T: 'a`.
ReferenceOutlivesReferent(Ty<'tcx>),
/// A type like `Box<Foo<'a> + 'b>` is WF only if `'b: 'a`.
ObjectTypeBound(Ty<'tcx>, ty::Region<'tcx>),
/// Obligation incurred due to an object cast.
ObjectCastObligation(/* Concrete type */ Ty<'tcx>, /* Object type */ Ty<'tcx>),
/// Obligation incurred due to a coercion.
Coercion {
source: Ty<'tcx>,
target: Ty<'tcx>,
},
/// Various cases where expressions must be `Sized` / `Copy` / etc.
/// `L = X` implies that `L` is `Sized`.
AssignmentLhsSized,
/// `(x1, .., xn)` must be `Sized`.
TupleInitializerSized,
/// `S { ... }` must be `Sized`.
StructInitializerSized,
/// Type of each variable must be `Sized`.
VariableType(hir::HirId),
/// Argument type must be `Sized`.
SizedArgumentType(Option<Span>),
/// Return type must be `Sized`.
SizedReturnType,
/// Yield type must be `Sized`.
SizedYieldType,
/// Box expression result type must be `Sized`.
SizedBoxType,
/// Inline asm operand type must be `Sized`.
InlineAsmSized,
/// `[expr; N]` requires `type_of(expr): Copy`.
RepeatElementCopy {
/// If element is a `const fn` we display a help message suggesting to move the
/// function call to a new `const` item while saying that `T` doesn't implement `Copy`.
is_const_fn: bool,
},
/// Types of fields (other than the last, except for packed structs) in a struct must be sized.
FieldSized {
adt_kind: AdtKind,
span: Span,
last: bool,
},
/// Constant expressions must be sized.
ConstSized,
/// `static` items must have `Sync` type.
SharedStatic,
BuiltinDerivedObligation(DerivedObligationCause<'tcx>),
ImplDerivedObligation(Box<ImplDerivedObligationCause<'tcx>>),
DerivedObligation(DerivedObligationCause<'tcx>),
FunctionArgumentObligation {
/// The node of the relevant argument in the function call.
arg_hir_id: hir::HirId,
/// The node of the function call.
call_hir_id: hir::HirId,
/// The obligation introduced by this argument.
parent_code: InternedObligationCauseCode<'tcx>,
},
/// Error derived when matching traits/impls; see ObligationCause for more details
CompareImplItemObligation {
impl_item_def_id: LocalDefId,
trait_item_def_id: DefId,
kind: ty::AssocKind,
},
/// Checking that the bounds of a trait's associated type hold for a given impl
CheckAssociatedTypeBounds {
impl_item_def_id: LocalDefId,
trait_item_def_id: DefId,
},
/// Checking that this expression can be assigned to its target.
ExprAssignable,
/// Computing common supertype in the arms of a match expression
MatchExpressionArm(Box<MatchExpressionArmCause<'tcx>>),
/// Type error arising from type checking a pattern against an expected type.
Pattern {
/// The span of the scrutinee or type expression which caused the `root_ty` type.
span: Option<Span>,
/// The root expected type induced by a scrutinee or type expression.
root_ty: Ty<'tcx>,
/// Whether the `Span` came from an expression or a type expression.
origin_expr: bool,
},
/// Constants in patterns must have `Structural` type.
ConstPatternStructural,
/// Computing common supertype in an if expression
IfExpression(Box<IfExpressionCause<'tcx>>),
/// Computing common supertype of an if expression with no else counter-part
IfExpressionWithNoElse,
/// `main` has wrong type
MainFunctionType,
/// `start` has wrong type
StartFunctionType,
/// Intrinsic has wrong type
IntrinsicType,
/// A let else block does not diverge
LetElse,
/// Method receiver
MethodReceiver,
UnifyReceiver(Box<UnifyReceiverContext<'tcx>>),
/// `return` with no expression
ReturnNoExpression,
/// `return` with an expression
ReturnValue(hir::HirId),
/// Return type of this function
ReturnType,
/// Opaque return type of this function
OpaqueReturnType(Option<(Ty<'tcx>, Span)>),
/// Block implicit return
BlockTailExpression(hir::HirId),
/// #[feature(trivial_bounds)] is not enabled
TrivialBound,
/// If `X` is the concrete type of an opaque type `impl Y`, then `X` must implement `Y`
OpaqueType,
AwaitableExpr(Option<hir::HirId>),
ForLoopIterator,
QuestionMark,
/// Well-formed checking. If a `WellFormedLoc` is provided,
/// then it will be used to perform HIR-based wf checking
/// after an error occurs, in order to generate a more precise error span.
/// This is purely for diagnostic purposes - it is always
/// correct to use `MiscObligation` instead, or to specify
/// `WellFormed(None)`
WellFormed(Option<WellFormedLoc>),
/// From `match_impl`. The cause for us having to match an impl, and the DefId we are matching against.
MatchImpl(ObligationCause<'tcx>, DefId),
BinOp {
rhs_span: Option<Span>,
is_lit: bool,
output_ty: Option<Ty<'tcx>>,
},
AscribeUserTypeProvePredicate(Span),
}
/// The 'location' at which we try to perform HIR-based wf checking.
/// This information is used to obtain an `hir::Ty`, which
/// we can walk in order to obtain precise spans for any
/// 'nested' types (e.g. `Foo` in `Option<Foo>`).
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash, HashStable)]
pub enum WellFormedLoc {
/// Use the type of the provided definition.
Ty(LocalDefId),
/// Use the type of the parameter of the provided function.
/// We cannot use `hir::Param`, since the function may
/// not have a body (e.g. a trait method definition)
Param {
/// The function to lookup the parameter in
function: LocalDefId,
/// The index of the parameter to use.
/// Parameters are indexed from 0, with the return type
/// being the last 'parameter'
param_idx: u16,
},
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift)]
pub struct ImplDerivedObligationCause<'tcx> {
pub derived: DerivedObligationCause<'tcx>,
pub impl_def_id: DefId,
pub span: Span,
}
impl<'tcx> ObligationCauseCode<'tcx> {
// Return the base obligation, ignoring derived obligations.
pub fn peel_derives(&self) -> &Self {
let mut base_cause = self;
while let Some((parent_code, _)) = base_cause.parent() {
base_cause = parent_code;
}
base_cause
}
pub fn parent(&self) -> Option<(&Self, Option<ty::PolyTraitPredicate<'tcx>>)> {
match self {
FunctionArgumentObligation { parent_code, .. } => Some((parent_code, None)),
BuiltinDerivedObligation(derived)
| DerivedObligation(derived)
| ImplDerivedObligation(box ImplDerivedObligationCause { derived, .. }) => {
Some((&derived.parent_code, Some(derived.parent_trait_pred)))
}
_ => None,
}
}
pub fn peel_match_impls(&self) -> &Self {
match self {
MatchImpl(cause, _) => cause.code(),
_ => self,
}
}
}
// `ObligationCauseCode` is used a lot. Make sure it doesn't unintentionally get bigger.
#[cfg(all(target_arch = "x86_64", target_pointer_width = "64"))]
static_assert_size!(ObligationCauseCode<'_>, 48);
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
pub enum StatementAsExpression {
CorrectType,
NeedsBoxing,
}
impl<'tcx> ty::Lift<'tcx> for StatementAsExpression {
type Lifted = StatementAsExpression;
fn lift_to_tcx(self, _tcx: TyCtxt<'tcx>) -> Option<StatementAsExpression> {
Some(self)
}
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift)]
pub struct MatchExpressionArmCause<'tcx> {
pub arm_block_id: Option<hir::HirId>,
pub arm_ty: Ty<'tcx>,
pub arm_span: Span,
pub prior_arm_block_id: Option<hir::HirId>,
pub prior_arm_ty: Ty<'tcx>,
pub prior_arm_span: Span,
pub scrut_span: Span,
pub source: hir::MatchSource,
pub prior_arms: Vec<Span>,
pub scrut_hir_id: hir::HirId,
pub opt_suggest_box_span: Option<Span>,
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
#[derive(Lift, TypeFoldable, TypeVisitable)]
pub struct IfExpressionCause<'tcx> {
pub then_id: hir::HirId,
pub else_id: hir::HirId,
pub then_ty: Ty<'tcx>,
pub else_ty: Ty<'tcx>,
pub outer_span: Option<Span>,
pub opt_suggest_box_span: Option<Span>,
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, Lift)]
pub struct DerivedObligationCause<'tcx> {
/// The trait predicate of the parent obligation that led to the
/// current obligation. Note that only trait obligations lead to
/// derived obligations, so we just store the trait predicate here
/// directly.
pub parent_trait_pred: ty::PolyTraitPredicate<'tcx>,
/// The parent trait had this cause.
pub parent_code: InternedObligationCauseCode<'tcx>,
}
#[derive(Clone, Debug, TypeFoldable, TypeVisitable, Lift)]
pub enum SelectionError<'tcx> {
/// The trait is not implemented.
Unimplemented,
/// After a closure impl has selected, its "outputs" were evaluated
/// (which for closures includes the "input" type params) and they
/// didn't resolve. See `confirm_poly_trait_refs` for more.
OutputTypeParameterMismatch(
ty::PolyTraitRef<'tcx>,
ty::PolyTraitRef<'tcx>,
ty::error::TypeError<'tcx>,
),
/// The trait pointed by `DefId` is not object safe.
TraitNotObjectSafe(DefId),
/// A given constant couldn't be evaluated.
NotConstEvaluatable(NotConstEvaluatable),
/// Exceeded the recursion depth during type projection.
Overflow(OverflowError),
/// Signaling that an error has already been emitted, to avoid
/// multiple errors being shown.
ErrorReporting,
/// Multiple applicable `impl`s where found. The `DefId`s correspond to
/// all the `impl`s' Items.
Ambiguous(Vec<DefId>),
}
/// When performing resolution, it is typically the case that there
/// can be one of three outcomes:
///
/// - `Ok(Some(r))`: success occurred with result `r`
/// - `Ok(None)`: could not definitely determine anything, usually due
/// to inconclusive type inference.
/// - `Err(e)`: error `e` occurred
pub type SelectionResult<'tcx, T> = Result<Option<T>, SelectionError<'tcx>>;
/// Given the successful resolution of an obligation, the `ImplSource`
/// indicates where the impl comes from.
///
/// For example, the obligation may be satisfied by a specific impl (case A),
/// or it may be relative to some bound that is in scope (case B).
///
/// ```ignore (illustrative)
/// impl<T:Clone> Clone<T> for Option<T> { ... } // Impl_1
/// impl<T:Clone> Clone<T> for Box<T> { ... } // Impl_2
/// impl Clone for i32 { ... } // Impl_3
///
/// fn foo<T: Clone>(concrete: Option<Box<i32>>, param: T, mixed: Option<T>) {
/// // Case A: ImplSource points at a specific impl. Only possible when
/// // type is concretely known. If the impl itself has bounded
/// // type parameters, ImplSource will carry resolutions for those as well:
/// concrete.clone(); // ImplSource(Impl_1, [ImplSource(Impl_2, [ImplSource(Impl_3)])])
///
/// // Case A: ImplSource points at a specific impl. Only possible when
/// // type is concretely known. If the impl itself has bounded
/// // type parameters, ImplSource will carry resolutions for those as well:
/// concrete.clone(); // ImplSource(Impl_1, [ImplSource(Impl_2, [ImplSource(Impl_3)])])
///
/// // Case B: ImplSource must be provided by caller. This applies when
/// // type is a type parameter.
/// param.clone(); // ImplSource::Param
///
/// // Case C: A mix of cases A and B.
/// mixed.clone(); // ImplSource(Impl_1, [ImplSource::Param])
/// }
/// ```
///
/// ### The type parameter `N`
///
/// See explanation on `ImplSourceUserDefinedData`.
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub enum ImplSource<'tcx, N> {
/// ImplSource identifying a particular impl.
UserDefined(ImplSourceUserDefinedData<'tcx, N>),
/// ImplSource for auto trait implementations.
/// This carries the information and nested obligations with regards
/// to an auto implementation for a trait `Trait`. The nested obligations
/// ensure the trait implementation holds for all the constituent types.
AutoImpl(ImplSourceAutoImplData<N>),
/// Successful resolution to an obligation provided by the caller
/// for some type parameter. The `Vec<N>` represents the
/// obligations incurred from normalizing the where-clause (if
/// any).
Param(Vec<N>, ty::BoundConstness),
/// Virtual calls through an object.
Object(ImplSourceObjectData<'tcx, N>),
/// Successful resolution for a builtin trait.
Builtin(ImplSourceBuiltinData<N>),
/// ImplSource for trait upcasting coercion
TraitUpcasting(ImplSourceTraitUpcastingData<'tcx, N>),
/// ImplSource automatically generated for a closure. The `DefId` is the ID
/// of the closure expression. This is an `ImplSource::UserDefined` in spirit, but the
/// impl is generated by the compiler and does not appear in the source.
Closure(ImplSourceClosureData<'tcx, N>),
/// Same as above, but for a function pointer type with the given signature.
FnPointer(ImplSourceFnPointerData<'tcx, N>),
/// ImplSource for a builtin `DeterminantKind` trait implementation.
DiscriminantKind(ImplSourceDiscriminantKindData),
/// ImplSource for a builtin `Pointee` trait implementation.
Pointee(ImplSourcePointeeData),
/// ImplSource automatically generated for a generator.
Generator(ImplSourceGeneratorData<'tcx, N>),
/// ImplSource for a trait alias.
TraitAlias(ImplSourceTraitAliasData<'tcx, N>),
/// ImplSource for a `const Drop` implementation.
ConstDestruct(ImplSourceConstDestructData<N>),
/// ImplSource for a `std::marker::Tuple` implementation.
/// This has no nested predicates ever, so no data.
Tuple,
}
impl<'tcx, N> ImplSource<'tcx, N> {
pub fn nested_obligations(self) -> Vec<N> {
match self {
ImplSource::UserDefined(i) => i.nested,
ImplSource::Param(n, _) => n,
ImplSource::Builtin(i) => i.nested,
ImplSource::AutoImpl(d) => d.nested,
ImplSource::Closure(c) => c.nested,
ImplSource::Generator(c) => c.nested,
ImplSource::Object(d) => d.nested,
ImplSource::FnPointer(d) => d.nested,
ImplSource::DiscriminantKind(ImplSourceDiscriminantKindData)
| ImplSource::Pointee(ImplSourcePointeeData)
| ImplSource::Tuple => Vec::new(),
ImplSource::TraitAlias(d) => d.nested,
ImplSource::TraitUpcasting(d) => d.nested,
ImplSource::ConstDestruct(i) => i.nested,
}
}
pub fn borrow_nested_obligations(&self) -> &[N] {
match &self {
ImplSource::UserDefined(i) => &i.nested[..],
ImplSource::Param(n, _) => &n,
ImplSource::Builtin(i) => &i.nested,
ImplSource::AutoImpl(d) => &d.nested,
ImplSource::Closure(c) => &c.nested,
ImplSource::Generator(c) => &c.nested,
ImplSource::Object(d) => &d.nested,
ImplSource::FnPointer(d) => &d.nested,
ImplSource::DiscriminantKind(ImplSourceDiscriminantKindData)
| ImplSource::Pointee(ImplSourcePointeeData)
| ImplSource::Tuple => &[],
ImplSource::TraitAlias(d) => &d.nested,
ImplSource::TraitUpcasting(d) => &d.nested,
ImplSource::ConstDestruct(i) => &i.nested,
}
}
pub fn map<M, F>(self, f: F) -> ImplSource<'tcx, M>
where
F: FnMut(N) -> M,
{
match self {
ImplSource::UserDefined(i) => ImplSource::UserDefined(ImplSourceUserDefinedData {
impl_def_id: i.impl_def_id,
substs: i.substs,
nested: i.nested.into_iter().map(f).collect(),
}),
ImplSource::Param(n, ct) => ImplSource::Param(n.into_iter().map(f).collect(), ct),
ImplSource::Builtin(i) => ImplSource::Builtin(ImplSourceBuiltinData {
nested: i.nested.into_iter().map(f).collect(),
}),
ImplSource::Object(o) => ImplSource::Object(ImplSourceObjectData {
upcast_trait_ref: o.upcast_trait_ref,
vtable_base: o.vtable_base,
nested: o.nested.into_iter().map(f).collect(),
}),
ImplSource::AutoImpl(d) => ImplSource::AutoImpl(ImplSourceAutoImplData {
trait_def_id: d.trait_def_id,
nested: d.nested.into_iter().map(f).collect(),
}),
ImplSource::Closure(c) => ImplSource::Closure(ImplSourceClosureData {
closure_def_id: c.closure_def_id,
substs: c.substs,
nested: c.nested.into_iter().map(f).collect(),
}),
ImplSource::Generator(c) => ImplSource::Generator(ImplSourceGeneratorData {
generator_def_id: c.generator_def_id,
substs: c.substs,
nested: c.nested.into_iter().map(f).collect(),
}),
ImplSource::FnPointer(p) => ImplSource::FnPointer(ImplSourceFnPointerData {
fn_ty: p.fn_ty,
nested: p.nested.into_iter().map(f).collect(),
}),
ImplSource::DiscriminantKind(ImplSourceDiscriminantKindData) => {
ImplSource::DiscriminantKind(ImplSourceDiscriminantKindData)
}
ImplSource::Pointee(ImplSourcePointeeData) => {
ImplSource::Pointee(ImplSourcePointeeData)
}
ImplSource::TraitAlias(d) => ImplSource::TraitAlias(ImplSourceTraitAliasData {
alias_def_id: d.alias_def_id,
substs: d.substs,
nested: d.nested.into_iter().map(f).collect(),
}),
ImplSource::TraitUpcasting(d) => {
ImplSource::TraitUpcasting(ImplSourceTraitUpcastingData {
upcast_trait_ref: d.upcast_trait_ref,
vtable_vptr_slot: d.vtable_vptr_slot,
nested: d.nested.into_iter().map(f).collect(),
})
}
ImplSource::ConstDestruct(i) => {
ImplSource::ConstDestruct(ImplSourceConstDestructData {
nested: i.nested.into_iter().map(f).collect(),
})
}
ImplSource::Tuple => ImplSource::Tuple,
}
}
}
/// Identifies a particular impl in the source, along with a set of
/// substitutions from the impl's type/lifetime parameters. The
/// `nested` vector corresponds to the nested obligations attached to
/// the impl's type parameters.
///
/// The type parameter `N` indicates the type used for "nested
/// obligations" that are required by the impl. During type-check, this
/// is `Obligation`, as one might expect. During codegen, however, this
/// is `()`, because codegen only requires a shallow resolution of an
/// impl, and nested obligations are satisfied later.
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceUserDefinedData<'tcx, N> {
pub impl_def_id: DefId,
pub substs: SubstsRef<'tcx>,
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceGeneratorData<'tcx, N> {
pub generator_def_id: DefId,
pub substs: SubstsRef<'tcx>,
/// Nested obligations. This can be non-empty if the generator
/// signature contains associated types.
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceClosureData<'tcx, N> {
pub closure_def_id: DefId,
pub substs: SubstsRef<'tcx>,
/// Nested obligations. This can be non-empty if the closure
/// signature contains associated types.
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceAutoImplData<N> {
pub trait_def_id: DefId,
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceTraitUpcastingData<'tcx, N> {
/// `Foo` upcast to the obligation trait. This will be some supertrait of `Foo`.
pub upcast_trait_ref: ty::PolyTraitRef<'tcx>,
/// The vtable is formed by concatenating together the method lists of
/// the base object trait and all supertraits, pointers to supertrait vtable will
/// be provided when necessary; this is the position of `upcast_trait_ref`'s vtable
/// within that vtable.
pub vtable_vptr_slot: Option<usize>,
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceBuiltinData<N> {
pub nested: Vec<N>,
}
#[derive(PartialEq, Eq, Clone, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceObjectData<'tcx, N> {
/// `Foo` upcast to the obligation trait. This will be some supertrait of `Foo`.
pub upcast_trait_ref: ty::PolyTraitRef<'tcx>,
/// The vtable is formed by concatenating together the method lists of
/// the base object trait and all supertraits, pointers to supertrait vtable will
/// be provided when necessary; this is the start of `upcast_trait_ref`'s methods
/// in that vtable.
pub vtable_base: usize,
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceFnPointerData<'tcx, N> {
pub fn_ty: Ty<'tcx>,
pub nested: Vec<N>,
}
// FIXME(@lcnr): This should be refactored and merged with other builtin vtables.
#[derive(Clone, Debug, PartialEq, Eq, TyEncodable, TyDecodable, HashStable)]
pub struct ImplSourceDiscriminantKindData;
#[derive(Clone, Debug, PartialEq, Eq, TyEncodable, TyDecodable, HashStable)]
pub struct ImplSourcePointeeData;
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceConstDestructData<N> {
pub nested: Vec<N>,
}
#[derive(Clone, PartialEq, Eq, TyEncodable, TyDecodable, HashStable, Lift)]
#[derive(TypeFoldable, TypeVisitable)]
pub struct ImplSourceTraitAliasData<'tcx, N> {
pub alias_def_id: DefId,
pub substs: SubstsRef<'tcx>,
pub nested: Vec<N>,
}
#[derive(Clone, Debug, PartialEq, Eq, Hash, HashStable, PartialOrd, Ord)]
pub enum ObjectSafetyViolation {
/// `Self: Sized` declared on the trait.
SizedSelf(SmallVec<[Span; 1]>),
/// Supertrait reference references `Self` an in illegal location
/// (e.g., `trait Foo : Bar<Self>`).
SupertraitSelf(SmallVec<[Span; 1]>),
/// Method has something illegal.
Method(Symbol, MethodViolationCode, Span),
/// Associated const.
AssocConst(Symbol, Span),
/// GAT
GAT(Symbol, Span),
}
impl ObjectSafetyViolation {
pub fn error_msg(&self) -> Cow<'static, str> {
match self {
ObjectSafetyViolation::SizedSelf(_) => "it requires `Self: Sized`".into(),
ObjectSafetyViolation::SupertraitSelf(ref spans) => {
if spans.iter().any(|sp| *sp != DUMMY_SP) {
"it uses `Self` as a type parameter".into()
} else {
"it cannot use `Self` as a type parameter in a supertrait or `where`-clause"
.into()
}
}
ObjectSafetyViolation::Method(name, MethodViolationCode::StaticMethod(_), _) => {
format!("associated function `{}` has no `self` parameter", name).into()
}
ObjectSafetyViolation::Method(
name,
MethodViolationCode::ReferencesSelfInput(_),
DUMMY_SP,
) => format!("method `{}` references the `Self` type in its parameters", name).into(),
ObjectSafetyViolation::Method(name, MethodViolationCode::ReferencesSelfInput(_), _) => {
format!("method `{}` references the `Self` type in this parameter", name).into()
}
ObjectSafetyViolation::Method(name, MethodViolationCode::ReferencesSelfOutput, _) => {
format!("method `{}` references the `Self` type in its return type", name).into()
}
ObjectSafetyViolation::Method(
name,
MethodViolationCode::ReferencesImplTraitInTrait,
_,
) => format!("method `{}` references an `impl Trait` type in its return type", name)
.into(),
ObjectSafetyViolation::Method(
name,
MethodViolationCode::WhereClauseReferencesSelf,
_,
) => {
format!("method `{}` references the `Self` type in its `where` clause", name).into()
}
ObjectSafetyViolation::Method(name, MethodViolationCode::Generic, _) => {
format!("method `{}` has generic type parameters", name).into()
}
ObjectSafetyViolation::Method(
name,
MethodViolationCode::UndispatchableReceiver(_),
_,
) => format!("method `{}`'s `self` parameter cannot be dispatched on", name).into(),
ObjectSafetyViolation::AssocConst(name, DUMMY_SP) => {
format!("it contains associated `const` `{}`", name).into()
}
ObjectSafetyViolation::AssocConst(..) => "it contains this associated `const`".into(),
ObjectSafetyViolation::GAT(name, _) => {
format!("it contains the generic associated type `{}`", name).into()
}
}
}
pub fn solution(&self, err: &mut Diagnostic) {
match self {
ObjectSafetyViolation::SizedSelf(_) | ObjectSafetyViolation::SupertraitSelf(_) => {}
ObjectSafetyViolation::Method(
name,
MethodViolationCode::StaticMethod(Some((add_self_sugg, make_sized_sugg))),
_,
) => {
err.span_suggestion(
add_self_sugg.1,
format!(
"consider turning `{}` into a method by giving it a `&self` argument",
name
),
add_self_sugg.0.to_string(),
Applicability::MaybeIncorrect,
);
err.span_suggestion(
make_sized_sugg.1,
format!(
"alternatively, consider constraining `{}` so it does not apply to \
trait objects",
name
),
make_sized_sugg.0.to_string(),
Applicability::MaybeIncorrect,
);
}
ObjectSafetyViolation::Method(
name,
MethodViolationCode::UndispatchableReceiver(Some(span)),
_,
) => {
err.span_suggestion(
*span,
&format!(
"consider changing method `{}`'s `self` parameter to be `&self`",
name
),
"&Self",
Applicability::MachineApplicable,
);
}
ObjectSafetyViolation::AssocConst(name, _)
| ObjectSafetyViolation::GAT(name, _)
| ObjectSafetyViolation::Method(name, ..) => {
err.help(&format!("consider moving `{}` to another trait", name));
}
}
}
pub fn spans(&self) -> SmallVec<[Span; 1]> {
// When `span` comes from a separate crate, it'll be `DUMMY_SP`. Treat it as `None` so
// diagnostics use a `note` instead of a `span_label`.
match self {
ObjectSafetyViolation::SupertraitSelf(spans)
| ObjectSafetyViolation::SizedSelf(spans) => spans.clone(),
ObjectSafetyViolation::AssocConst(_, span)
| ObjectSafetyViolation::GAT(_, span)
| ObjectSafetyViolation::Method(_, _, span)
if *span != DUMMY_SP =>
{
smallvec![*span]
}
_ => smallvec![],
}
}
}
/// Reasons a method might not be object-safe.
#[derive(Clone, Debug, PartialEq, Eq, Hash, HashStable, PartialOrd, Ord)]
pub enum MethodViolationCode {
/// e.g., `fn foo()`
StaticMethod(Option<(/* add &self */ (String, Span), /* add Self: Sized */ (String, Span))>),
/// e.g., `fn foo(&self, x: Self)`
ReferencesSelfInput(Option<Span>),
/// e.g., `fn foo(&self) -> Self`
ReferencesSelfOutput,
/// e.g., `fn foo(&self) -> impl Sized`
ReferencesImplTraitInTrait,
/// e.g., `fn foo(&self) where Self: Clone`
WhereClauseReferencesSelf,
/// e.g., `fn foo<A>()`
Generic,
/// the method's receiver (`self` argument) can't be dispatched on
UndispatchableReceiver(Option<Span>),
}
/// These are the error cases for `codegen_select_candidate`.
#[derive(Copy, Clone, Debug, Hash, HashStable, Encodable, Decodable)]
pub enum CodegenObligationError {
/// Ambiguity can happen when monomorphizing during trans
/// expands to some humongous type that never occurred
/// statically -- this humongous type can then overflow,
/// leading to an ambiguous result. So report this as an
/// overflow bug, since I believe this is the only case
/// where ambiguity can result.
Ambiguity,
/// This can trigger when we probe for the source of a `'static` lifetime requirement
/// on a trait object: `impl Foo for dyn Trait {}` has an implicit `'static` bound.
/// This can also trigger when we have a global bound that is not actually satisfied,
/// but was included during typeck due to the trivial_bounds feature.
Unimplemented,
FulfillmentError,
}
|