compiler/rustc_trait_selection/src/traits/codegen/mod.rs - third_party/rust - Git at Google

 // This file contains various trait resolution methods used by codegen.
 // They all assume regions can be erased and monomorphic types.  It
 // seems likely that they should eventually be merged into more
 // general routines.

 use crate::infer::{InferCtxt, TyCtxtInferExt};
 use crate::traits::{
     FulfillmentContext, ImplSource, Obligation, ObligationCause, SelectionContext, TraitEngine,
     Unimplemented,
 };
 use rustc_errors::ErrorReported;
 use rustc_middle::ty::fold::TypeFoldable;
 use rustc_middle::ty::{self, TyCtxt};

 /// Attempts to resolve an obligation to a `ImplSource`. The result is
 /// a shallow `ImplSource` resolution, meaning that we do not
 /// (necessarily) resolve all nested obligations on the impl. Note
 /// that type check should guarantee to us that all nested
 /// obligations *could be* resolved if we wanted to.
 /// Assumes that this is run after the entire crate has been successfully type-checked.
 pub fn codegen_fulfill_obligation<'tcx>(
     ty: TyCtxt<'tcx>,
     (param_env, trait_ref): (ty::ParamEnv<'tcx>, ty::PolyTraitRef<'tcx>),
 ) -> Result<ImplSource<'tcx, ()>, ErrorReported> {
     // Remove any references to regions; this helps improve caching.
     let trait_ref = ty.erase_regions(&trait_ref);

     debug!(
         "codegen_fulfill_obligation(trait_ref={:?}, def_id={:?})",
         (param_env, trait_ref),
         trait_ref.def_id()
     );

     // Do the initial selection for the obligation. This yields the
     // shallow result we are looking for -- that is, what specific impl.
     ty.infer_ctxt().enter(|infcx| {
         let mut selcx = SelectionContext::new(&infcx);

         let obligation_cause = ObligationCause::dummy();
         let obligation =
             Obligation::new(obligation_cause, param_env, trait_ref.to_poly_trait_predicate());

         let selection = match selcx.select(&obligation) {
             Ok(Some(selection)) => selection,
             Ok(None) => {
                 // Ambiguity can happen when monomorphizing during trans
                 // expands to some humongo type that never occurred
                 // statically -- this humongo 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.
                 infcx.tcx.sess.delay_span_bug(
                     rustc_span::DUMMY_SP,
                     &format!(
                         "encountered ambiguity selecting `{:?}` during codegen, presuming due to \
                          overflow or prior type error",
                         trait_ref
                     ),
                 );
                 return Err(ErrorReported);
             }
             Err(Unimplemented) => {
                 // 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.
                 infcx.tcx.sess.delay_span_bug(
                     rustc_span::DUMMY_SP,
                     &format!(
                         "Encountered error `Unimplemented` selecting `{:?}` during codegen",
                         trait_ref
                     ),
                 );
                 return Err(ErrorReported);
             }
             Err(e) => {
                 bug!("Encountered error `{:?}` selecting `{:?}` during codegen", e, trait_ref)
             }
         };

         debug!("fulfill_obligation: selection={:?}", selection);

         // Currently, we use a fulfillment context to completely resolve
         // all nested obligations. This is because they can inform the
         // inference of the impl's type parameters.
         let mut fulfill_cx = FulfillmentContext::new();
         let impl_source = selection.map(|predicate| {
             debug!("fulfill_obligation: register_predicate_obligation {:?}", predicate);
             fulfill_cx.register_predicate_obligation(&infcx, predicate);
         });
         let impl_source = drain_fulfillment_cx_or_panic(&infcx, &mut fulfill_cx, &impl_source);

         info!("Cache miss: {:?} => {:?}", trait_ref, impl_source);
         Ok(impl_source)
     })
 }

 // # Global Cache

 /// Finishes processes any obligations that remain in the
 /// fulfillment context, and then returns the result with all type
 /// variables removed and regions erased. Because this is intended
 /// for use after type-check has completed, if any errors occur,
 /// it will panic. It is used during normalization and other cases
 /// where processing the obligations in `fulfill_cx` may cause
 /// type inference variables that appear in `result` to be
 /// unified, and hence we need to process those obligations to get
 /// the complete picture of the type.
 fn drain_fulfillment_cx_or_panic<T>(
     infcx: &InferCtxt<'_, 'tcx>,
     fulfill_cx: &mut FulfillmentContext<'tcx>,
     result: &T,
 ) -> T
 where
     T: TypeFoldable<'tcx>,
 {
     debug!("drain_fulfillment_cx_or_panic()");

     // In principle, we only need to do this so long as `result`
     // contains unbound type parameters. It could be a slight
     // optimization to stop iterating early.
     if let Err(errors) = fulfill_cx.select_all_or_error(infcx) {
         bug!("Encountered errors `{:?}` resolving bounds after type-checking", errors);
     }

     let result = infcx.resolve_vars_if_possible(result);
     infcx.tcx.erase_regions(&result)
 }
	// This file contains various trait resolution methods used by codegen.
	// They all assume regions can be erased and monomorphic types. It
	// seems likely that they should eventually be merged into more
	// general routines.

	use crate::infer::{InferCtxt, TyCtxtInferExt};
	use crate::traits::{
	FulfillmentContext, ImplSource, Obligation, ObligationCause, SelectionContext, TraitEngine,
	Unimplemented,
	};
	use rustc_errors::ErrorReported;
	use rustc_middle::ty::fold::TypeFoldable;
	use rustc_middle::ty::{self, TyCtxt};

	/// Attempts to resolve an obligation to a `ImplSource`. The result is
	/// a shallow `ImplSource` resolution, meaning that we do not
	/// (necessarily) resolve all nested obligations on the impl. Note
	/// that type check should guarantee to us that all nested
	/// obligations could be resolved if we wanted to.
	/// Assumes that this is run after the entire crate has been successfully type-checked.
	pub fn codegen_fulfill_obligation<'tcx>(
	ty: TyCtxt<'tcx>,
	(param_env, trait_ref): (ty::ParamEnv<'tcx>, ty::PolyTraitRef<'tcx>),
	) -> Result<ImplSource<'tcx, ()>, ErrorReported> {
	// Remove any references to regions; this helps improve caching.
	let trait_ref = ty.erase_regions(&trait_ref);

	debug!(
	"codegen_fulfill_obligation(trait_ref={:?}, def_id={:?})",
	(param_env, trait_ref),
	trait_ref.def_id()
	);

	// Do the initial selection for the obligation. This yields the
	// shallow result we are looking for -- that is, what specific impl.
	ty.infer_ctxt().enter(\|infcx\| {
	let mut selcx = SelectionContext::new(&infcx);

	let obligation_cause = ObligationCause::dummy();
	let obligation =
	Obligation::new(obligation_cause, param_env, trait_ref.to_poly_trait_predicate());

	let selection = match selcx.select(&obligation) {
	Ok(Some(selection)) => selection,
	Ok(None) => {
	// Ambiguity can happen when monomorphizing during trans
	// expands to some humongo type that never occurred
	// statically -- this humongo 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.
	infcx.tcx.sess.delay_span_bug(
	rustc_span::DUMMY_SP,
	&format!(
	"encountered ambiguity selecting `{:?}` during codegen, presuming due to \
	overflow or prior type error",
	trait_ref
	),
	);
	return Err(ErrorReported);
	}
	Err(Unimplemented) => {
	// 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.
	infcx.tcx.sess.delay_span_bug(
	rustc_span::DUMMY_SP,
	&format!(
	"Encountered error `Unimplemented` selecting `{:?}` during codegen",
	trait_ref
	),
	);
	return Err(ErrorReported);
	}
	Err(e) => {
	bug!("Encountered error `{:?}` selecting `{:?}` during codegen", e, trait_ref)
	}
	};

	debug!("fulfill_obligation: selection={:?}", selection);

	// Currently, we use a fulfillment context to completely resolve
	// all nested obligations. This is because they can inform the
	// inference of the impl's type parameters.
	let mut fulfill_cx = FulfillmentContext::new();
	let impl_source = selection.map(\|predicate\| {
	debug!("fulfill_obligation: register_predicate_obligation {:?}", predicate);
	fulfill_cx.register_predicate_obligation(&infcx, predicate);
	});
	let impl_source = drain_fulfillment_cx_or_panic(&infcx, &mut fulfill_cx, &impl_source);

	info!("Cache miss: {:?} => {:?}", trait_ref, impl_source);
	Ok(impl_source)
	})
	}

	// # Global Cache

	/// Finishes processes any obligations that remain in the
	/// fulfillment context, and then returns the result with all type
	/// variables removed and regions erased. Because this is intended
	/// for use after type-check has completed, if any errors occur,
	/// it will panic. It is used during normalization and other cases
	/// where processing the obligations in `fulfill_cx` may cause
	/// type inference variables that appear in `result` to be
	/// unified, and hence we need to process those obligations to get
	/// the complete picture of the type.
	fn drain_fulfillment_cx_or_panic<T>(
	infcx: &InferCtxt<'_, 'tcx>,
	fulfill_cx: &mut FulfillmentContext<'tcx>,
	result: &T,
	) -> T
	where
	T: TypeFoldable<'tcx>,
	{
	debug!("drain_fulfillment_cx_or_panic()");

	// In principle, we only need to do this so long as `result`
	// contains unbound type parameters. It could be a slight
	// optimization to stop iterating early.
	if let Err(errors) = fulfill_cx.select_all_or_error(infcx) {
	bug!("Encountered errors `{:?}` resolving bounds after type-checking", errors);
	}

	let result = infcx.resolve_vars_if_possible(result);
	infcx.tcx.erase_regions(&result)
	}