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//! This module contains the code to instantiate a "query result", and
//! in particular to extract out the resulting region obligations and
//! encode them therein.
//!
//! For an overview of what canonicalization is and how it fits into
//! rustc, check out the [chapter in the rustc dev guide][c].
//!
//! [c]: https://rust-lang.github.io/chalk/book/canonical_queries/canonicalization.html
use crate::infer::canonical::instantiate::{instantiate_value, CanonicalExt};
use crate::infer::canonical::{
Canonical, CanonicalQueryResponse, CanonicalVarValues, Certainty, OriginalQueryValues,
QueryOutlivesConstraint, QueryRegionConstraints, QueryResponse,
};
use crate::infer::region_constraints::{Constraint, RegionConstraintData};
use crate::infer::{DefineOpaqueTypes, InferCtxt, InferOk, InferResult};
use crate::traits::query::NoSolution;
use crate::traits::{Obligation, ObligationCause, PredicateObligation};
use crate::traits::{ScrubbedTraitError, TraitEngine};
use rustc_data_structures::captures::Captures;
use rustc_index::Idx;
use rustc_index::IndexVec;
use rustc_middle::arena::ArenaAllocatable;
use rustc_middle::mir::ConstraintCategory;
use rustc_middle::ty::fold::TypeFoldable;
use rustc_middle::ty::{self, BoundVar, Ty, TyCtxt};
use rustc_middle::ty::{GenericArg, GenericArgKind};
use rustc_middle::{bug, span_bug};
use std::fmt::Debug;
use std::iter;
impl<'tcx> InferCtxt<'tcx> {
/// This method is meant to be invoked as the final step of a canonical query
/// implementation. It is given:
///
/// - the instantiated variables `inference_vars` created from the query key
/// - the result `answer` of the query
/// - a fulfillment context `fulfill_cx` that may contain various obligations which
/// have yet to be proven.
///
/// Given this, the function will process the obligations pending
/// in `fulfill_cx`:
///
/// - If all the obligations can be proven successfully, it will
/// package up any resulting region obligations (extracted from
/// `infcx`) along with the fully resolved value `answer` into a
/// query result (which is then itself canonicalized).
/// - If some obligations can be neither proven nor disproven, then
/// the same thing happens, but the resulting query is marked as ambiguous.
/// - Finally, if any of the obligations result in a hard error,
/// then `Err(NoSolution)` is returned.
#[instrument(skip(self, inference_vars, answer, fulfill_cx), level = "trace")]
pub fn make_canonicalized_query_response<T>(
&self,
inference_vars: CanonicalVarValues<'tcx>,
answer: T,
fulfill_cx: &mut dyn TraitEngine<'tcx, ScrubbedTraitError<'tcx>>,
) -> Result<CanonicalQueryResponse<'tcx, T>, NoSolution>
where
T: Debug + TypeFoldable<TyCtxt<'tcx>>,
Canonical<'tcx, QueryResponse<'tcx, T>>: ArenaAllocatable<'tcx>,
{
let query_response = self.make_query_response(inference_vars, answer, fulfill_cx)?;
debug!("query_response = {:#?}", query_response);
let canonical_result = self.canonicalize_response(query_response);
debug!("canonical_result = {:#?}", canonical_result);
Ok(self.tcx.arena.alloc(canonical_result))
}
/// A version of `make_canonicalized_query_response` that does
/// not pack in obligations, for contexts that want to drop
/// pending obligations instead of treating them as an ambiguity (e.g.
/// typeck "probing" contexts).
///
/// If you DO want to keep track of pending obligations (which
/// include all region obligations, so this includes all cases
/// that care about regions) with this function, you have to
/// do it yourself, by e.g., having them be a part of the answer.
pub fn make_query_response_ignoring_pending_obligations<T>(
&self,
inference_vars: CanonicalVarValues<'tcx>,
answer: T,
) -> Canonical<'tcx, QueryResponse<'tcx, T>>
where
T: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
self.canonicalize_response(QueryResponse {
var_values: inference_vars,
region_constraints: QueryRegionConstraints::default(),
certainty: Certainty::Proven, // Ambiguities are OK!
opaque_types: vec![],
value: answer,
})
}
/// Helper for `make_canonicalized_query_response` that does
/// everything up until the final canonicalization.
#[instrument(skip(self, fulfill_cx), level = "debug")]
fn make_query_response<T>(
&self,
inference_vars: CanonicalVarValues<'tcx>,
answer: T,
fulfill_cx: &mut dyn TraitEngine<'tcx, ScrubbedTraitError<'tcx>>,
) -> Result<QueryResponse<'tcx, T>, NoSolution>
where
T: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
let tcx = self.tcx;
// Select everything, returning errors.
let errors = fulfill_cx.select_all_or_error(self);
// True error!
if errors.iter().any(|e| e.is_true_error()) {
return Err(NoSolution);
}
let region_obligations = self.take_registered_region_obligations();
debug!(?region_obligations);
let region_constraints = self.with_region_constraints(|region_constraints| {
make_query_region_constraints(
tcx,
region_obligations
.iter()
.map(|r_o| (r_o.sup_type, r_o.sub_region, r_o.origin.to_constraint_category())),
region_constraints,
)
});
debug!(?region_constraints);
let certainty = if errors.is_empty() { Certainty::Proven } else { Certainty::Ambiguous };
let opaque_types = self.take_opaque_types_for_query_response();
Ok(QueryResponse {
var_values: inference_vars,
region_constraints,
certainty,
value: answer,
opaque_types,
})
}
/// Used by the new solver as that one takes the opaque types at the end of a probe
/// to deal with multiple candidates without having to recompute them.
pub fn clone_opaque_types_for_query_response(
&self,
) -> Vec<(ty::OpaqueTypeKey<'tcx>, Ty<'tcx>)> {
self.inner
.borrow()
.opaque_type_storage
.opaque_types
.iter()
.map(|(k, v)| (*k, v.hidden_type.ty))
.collect()
}
fn take_opaque_types_for_query_response(&self) -> Vec<(ty::OpaqueTypeKey<'tcx>, Ty<'tcx>)> {
self.take_opaque_types().into_iter().map(|(k, v)| (k, v.hidden_type.ty)).collect()
}
/// Given the (canonicalized) result to a canonical query,
/// instantiates the result so it can be used, plugging in the
/// values from the canonical query. (Note that the result may
/// have been ambiguous; you should check the certainty level of
/// the query before applying this function.)
///
/// To get a good understanding of what is happening here, check
/// out the [chapter in the rustc dev guide][c].
///
/// [c]: https://rust-lang.github.io/chalk/book/canonical_queries/canonicalization.html#processing-the-canonicalized-query-result
pub fn instantiate_query_response_and_region_obligations<R>(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
original_values: &OriginalQueryValues<'tcx>,
query_response: &Canonical<'tcx, QueryResponse<'tcx, R>>,
) -> InferResult<'tcx, R>
where
R: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
let InferOk { value: result_args, mut obligations } =
self.query_response_instantiation(cause, param_env, original_values, query_response)?;
obligations.extend(self.query_outlives_constraints_into_obligations(
cause,
param_env,
&query_response.value.region_constraints.outlives,
&result_args,
));
let user_result: R =
query_response.instantiate_projected(self.tcx, &result_args, |q_r| q_r.value.clone());
Ok(InferOk { value: user_result, obligations })
}
/// An alternative to
/// `instantiate_query_response_and_region_obligations` that is more
/// efficient for NLL. NLL is a bit more advanced in the
/// "transition to chalk" than the rest of the compiler. During
/// the NLL type check, all of the "processing" of types and
/// things happens in queries -- the NLL checker itself is only
/// interested in the region obligations (`'a: 'b` or `T: 'b`)
/// that come out of these queries, which it wants to convert into
/// MIR-based constraints and solve. Therefore, it is most
/// convenient for the NLL Type Checker to **directly consume**
/// the `QueryOutlivesConstraint` values that arise from doing a
/// query. This is contrast to other parts of the compiler, which
/// would prefer for those `QueryOutlivesConstraint` to be converted
/// into the older infcx-style constraints (e.g., calls to
/// `sub_regions` or `register_region_obligation`).
///
/// Therefore, `instantiate_nll_query_response_and_region_obligations` performs the same
/// basic operations as `instantiate_query_response_and_region_obligations` but
/// it returns its result differently:
///
/// - It creates an instantiation `S` that maps from the original
/// query variables to the values computed in the query
/// result. If any errors arise, they are propagated back as an
/// `Err` result.
/// - In the case of a successful instantiation, we will append
/// `QueryOutlivesConstraint` values onto the
/// `output_query_region_constraints` vector for the solver to
/// use (if an error arises, some values may also be pushed, but
/// they should be ignored).
/// - It **can happen** (though it rarely does currently) that
/// equating types and things will give rise to subobligations
/// that must be processed. In this case, those subobligations
/// are propagated back in the return value.
/// - Finally, the query result (of type `R`) is propagated back,
/// after applying the instantiation `S`.
pub fn instantiate_nll_query_response_and_region_obligations<R>(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
original_values: &OriginalQueryValues<'tcx>,
query_response: &Canonical<'tcx, QueryResponse<'tcx, R>>,
output_query_region_constraints: &mut QueryRegionConstraints<'tcx>,
) -> InferResult<'tcx, R>
where
R: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
let InferOk { value: result_args, mut obligations } = self
.query_response_instantiation_guess(
cause,
param_env,
original_values,
query_response,
)?;
// Compute `QueryOutlivesConstraint` values that unify each of
// the original values `v_o` that was canonicalized into a
// variable...
let constraint_category = cause.to_constraint_category();
for (index, original_value) in original_values.var_values.iter().enumerate() {
// ...with the value `v_r` of that variable from the query.
let result_value = query_response.instantiate_projected(self.tcx, &result_args, |v| {
v.var_values[BoundVar::new(index)]
});
match (original_value.unpack(), result_value.unpack()) {
(GenericArgKind::Lifetime(re1), GenericArgKind::Lifetime(re2))
if re1.is_erased() && re2.is_erased() =>
{
// No action needed.
}
(GenericArgKind::Lifetime(v_o), GenericArgKind::Lifetime(v_r)) => {
// To make `v_o = v_r`, we emit `v_o: v_r` and `v_r: v_o`.
if v_o != v_r {
output_query_region_constraints
.outlives
.push((ty::OutlivesPredicate(v_o.into(), v_r), constraint_category));
output_query_region_constraints
.outlives
.push((ty::OutlivesPredicate(v_r.into(), v_o), constraint_category));
}
}
(GenericArgKind::Type(v1), GenericArgKind::Type(v2)) => {
obligations.extend(
self.at(&cause, param_env)
.eq(DefineOpaqueTypes::Yes, v1, v2)?
.into_obligations(),
);
}
(GenericArgKind::Const(v1), GenericArgKind::Const(v2)) => {
obligations.extend(
self.at(&cause, param_env)
.eq(DefineOpaqueTypes::Yes, v1, v2)?
.into_obligations(),
);
}
_ => {
bug!("kind mismatch, cannot unify {:?} and {:?}", original_value, result_value);
}
}
}
// ...also include the other query region constraints from the query.
output_query_region_constraints.outlives.extend(
query_response.value.region_constraints.outlives.iter().filter_map(|&r_c| {
let r_c = instantiate_value(self.tcx, &result_args, r_c);
// Screen out `'a: 'a` cases.
let ty::OutlivesPredicate(k1, r2) = r_c.0;
if k1 != r2.into() { Some(r_c) } else { None }
}),
);
// ...also include the query member constraints.
output_query_region_constraints.member_constraints.extend(
query_response
.value
.region_constraints
.member_constraints
.iter()
.map(|p_c| instantiate_value(self.tcx, &result_args, p_c.clone())),
);
let user_result: R =
query_response.instantiate_projected(self.tcx, &result_args, |q_r| q_r.value.clone());
Ok(InferOk { value: user_result, obligations })
}
/// Given the original values and the (canonicalized) result from
/// computing a query, returns an instantiation that can be applied
/// to the query result to convert the result back into the
/// original namespace.
///
/// The instantiation also comes accompanied with subobligations
/// that arose from unification; these might occur if (for
/// example) we are doing lazy normalization and the value
/// assigned to a type variable is unified with an unnormalized
/// projection.
fn query_response_instantiation<R>(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
original_values: &OriginalQueryValues<'tcx>,
query_response: &Canonical<'tcx, QueryResponse<'tcx, R>>,
) -> InferResult<'tcx, CanonicalVarValues<'tcx>>
where
R: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
debug!(
"query_response_instantiation(original_values={:#?}, query_response={:#?})",
original_values, query_response,
);
let mut value = self.query_response_instantiation_guess(
cause,
param_env,
original_values,
query_response,
)?;
value.obligations.extend(
self.unify_query_response_instantiation_guess(
cause,
param_env,
original_values,
&value.value,
query_response,
)?
.into_obligations(),
);
Ok(value)
}
/// Given the original values and the (canonicalized) result from
/// computing a query, returns a **guess** at an instantiation that
/// can be applied to the query result to convert the result back
/// into the original namespace. This is called a **guess**
/// because it uses a quick heuristic to find the values for each
/// canonical variable; if that quick heuristic fails, then we
/// will instantiate fresh inference variables for each canonical
/// variable instead. Therefore, the result of this method must be
/// properly unified
#[instrument(level = "debug", skip(self, param_env))]
fn query_response_instantiation_guess<R>(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
original_values: &OriginalQueryValues<'tcx>,
query_response: &Canonical<'tcx, QueryResponse<'tcx, R>>,
) -> InferResult<'tcx, CanonicalVarValues<'tcx>>
where
R: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
// For each new universe created in the query result that did
// not appear in the original query, create a local
// superuniverse.
let mut universe_map = original_values.universe_map.clone();
let num_universes_in_query = original_values.universe_map.len();
let num_universes_in_response = query_response.max_universe.as_usize() + 1;
for _ in num_universes_in_query..num_universes_in_response {
universe_map.push(self.create_next_universe());
}
assert!(!universe_map.is_empty()); // always have the root universe
assert_eq!(universe_map[ty::UniverseIndex::ROOT.as_usize()], ty::UniverseIndex::ROOT);
// Every canonical query result includes values for each of
// the inputs to the query. Therefore, we begin by unifying
// these values with the original inputs that were
// canonicalized.
let result_values = &query_response.value.var_values;
assert_eq!(original_values.var_values.len(), result_values.len());
// Quickly try to find initial values for the canonical
// variables in the result in terms of the query. We do this
// by iterating down the values that the query gave to each of
// the canonical inputs. If we find that one of those values
// is directly equal to one of the canonical variables in the
// result, then we can type the corresponding value from the
// input. See the example above.
let mut opt_values: IndexVec<BoundVar, Option<GenericArg<'tcx>>> =
IndexVec::from_elem_n(None, query_response.variables.len());
// In terms of our example above, we are iterating over pairs like:
// [(?A, Vec<?0>), ('static, '?1), (?B, ?0)]
for (original_value, result_value) in iter::zip(&original_values.var_values, result_values)
{
match result_value.unpack() {
GenericArgKind::Type(result_value) => {
// e.g., here `result_value` might be `?0` in the example above...
if let ty::Bound(debruijn, b) = *result_value.kind() {
// ...in which case we would set `canonical_vars[0]` to `Some(?U)`.
// We only allow a `ty::INNERMOST` index in generic parameters.
assert_eq!(debruijn, ty::INNERMOST);
opt_values[b.var] = Some(*original_value);
}
}
GenericArgKind::Lifetime(result_value) => {
// e.g., here `result_value` might be `'?1` in the example above...
if let ty::ReBound(debruijn, br) = *result_value {
// ... in which case we would set `canonical_vars[0]` to `Some('static)`.
// We only allow a `ty::INNERMOST` index in generic parameters.
assert_eq!(debruijn, ty::INNERMOST);
opt_values[br.var] = Some(*original_value);
}
}
GenericArgKind::Const(result_value) => {
if let ty::ConstKind::Bound(debruijn, b) = result_value.kind() {
// ...in which case we would set `canonical_vars[0]` to `Some(const X)`.
// We only allow a `ty::INNERMOST` index in generic parameters.
assert_eq!(debruijn, ty::INNERMOST);
opt_values[b] = Some(*original_value);
}
}
}
}
// Create result arguments: if we found a value for a
// given variable in the loop above, use that. Otherwise, use
// a fresh inference variable.
let result_args = CanonicalVarValues {
var_values: self.tcx.mk_args_from_iter(
query_response.variables.iter().enumerate().map(|(index, info)| {
if info.universe() != ty::UniverseIndex::ROOT {
// A variable from inside a binder of the query. While ideally these shouldn't
// exist at all, we have to deal with them for now.
self.instantiate_canonical_var(cause.span, info, |u| {
universe_map[u.as_usize()]
})
} else if info.is_existential() {
match opt_values[BoundVar::new(index)] {
Some(k) => k,
None => self.instantiate_canonical_var(cause.span, info, |u| {
universe_map[u.as_usize()]
}),
}
} else {
// For placeholders which were already part of the input, we simply map this
// universal bound variable back the placeholder of the input.
opt_values[BoundVar::new(index)].expect(
"expected placeholder to be unified with itself during response",
)
}
}),
),
};
let mut obligations = vec![];
// Carry all newly resolved opaque types to the caller's scope
for &(a, b) in &query_response.value.opaque_types {
let a = instantiate_value(self.tcx, &result_args, a);
let b = instantiate_value(self.tcx, &result_args, b);
debug!(?a, ?b, "constrain opaque type");
// We use equate here instead of, for example, just registering the
// opaque type's hidden value directly, because the hidden type may have been an inference
// variable that got constrained to the opaque type itself. In that case we want to equate
// the generic args of the opaque with the generic params of its hidden type version.
obligations.extend(
self.at(cause, param_env)
.eq(
DefineOpaqueTypes::Yes,
Ty::new_opaque(self.tcx, a.def_id.to_def_id(), a.args),
b,
)?
.obligations,
);
}
Ok(InferOk { value: result_args, obligations })
}
/// Given a "guess" at the values for the canonical variables in
/// the input, try to unify with the *actual* values found in the
/// query result. Often, but not always, this is a no-op, because
/// we already found the mapping in the "guessing" step.
///
/// See also: [`Self::query_response_instantiation_guess`]
fn unify_query_response_instantiation_guess<R>(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
original_values: &OriginalQueryValues<'tcx>,
result_args: &CanonicalVarValues<'tcx>,
query_response: &Canonical<'tcx, QueryResponse<'tcx, R>>,
) -> InferResult<'tcx, ()>
where
R: Debug + TypeFoldable<TyCtxt<'tcx>>,
{
// A closure that yields the result value for the given
// canonical variable; this is taken from
// `query_response.var_values` after applying the instantiation
// by `result_args`.
let instantiated_query_response = |index: BoundVar| -> GenericArg<'tcx> {
query_response.instantiate_projected(self.tcx, result_args, |v| v.var_values[index])
};
// Unify the original value for each variable with the value
// taken from `query_response` (after applying `result_args`).
self.unify_canonical_vars(cause, param_env, original_values, instantiated_query_response)
}
/// Converts the region constraints resulting from a query into an
/// iterator of obligations.
fn query_outlives_constraints_into_obligations<'a>(
&'a self,
cause: &'a ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
uninstantiated_region_constraints: &'a [QueryOutlivesConstraint<'tcx>],
result_args: &'a CanonicalVarValues<'tcx>,
) -> impl Iterator<Item = PredicateObligation<'tcx>> + 'a + Captures<'tcx> {
uninstantiated_region_constraints.iter().map(move |&constraint| {
let predicate = instantiate_value(self.tcx, result_args, constraint);
self.query_outlives_constraint_to_obligation(predicate, cause.clone(), param_env)
})
}
pub fn query_outlives_constraint_to_obligation(
&self,
(predicate, _): QueryOutlivesConstraint<'tcx>,
cause: ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
) -> Obligation<'tcx, ty::Predicate<'tcx>> {
let ty::OutlivesPredicate(k1, r2) = predicate;
let atom = match k1.unpack() {
GenericArgKind::Lifetime(r1) => ty::PredicateKind::Clause(
ty::ClauseKind::RegionOutlives(ty::OutlivesPredicate(r1, r2)),
),
GenericArgKind::Type(t1) => ty::PredicateKind::Clause(ty::ClauseKind::TypeOutlives(
ty::OutlivesPredicate(t1, r2),
)),
GenericArgKind::Const(..) => {
// Consts cannot outlive one another, so we don't expect to
// encounter this branch.
span_bug!(cause.span, "unexpected const outlives {:?}", predicate);
}
};
let predicate = ty::Binder::dummy(atom);
Obligation::new(self.tcx, cause, param_env, predicate)
}
/// Given two sets of values for the same set of canonical variables, unify them.
/// The second set is produced lazily by supplying indices from the first set.
fn unify_canonical_vars(
&self,
cause: &ObligationCause<'tcx>,
param_env: ty::ParamEnv<'tcx>,
variables1: &OriginalQueryValues<'tcx>,
variables2: impl Fn(BoundVar) -> GenericArg<'tcx>,
) -> InferResult<'tcx, ()> {
let mut obligations = vec![];
for (index, value1) in variables1.var_values.iter().enumerate() {
let value2 = variables2(BoundVar::new(index));
match (value1.unpack(), value2.unpack()) {
(GenericArgKind::Type(v1), GenericArgKind::Type(v2)) => {
obligations.extend(
self.at(cause, param_env)
.eq(DefineOpaqueTypes::Yes, v1, v2)?
.into_obligations(),
);
}
(GenericArgKind::Lifetime(re1), GenericArgKind::Lifetime(re2))
if re1.is_erased() && re2.is_erased() =>
{
// no action needed
}
(GenericArgKind::Lifetime(v1), GenericArgKind::Lifetime(v2)) => {
obligations.extend(
self.at(cause, param_env)
.eq(DefineOpaqueTypes::Yes, v1, v2)?
.into_obligations(),
);
}
(GenericArgKind::Const(v1), GenericArgKind::Const(v2)) => {
let ok = self.at(cause, param_env).eq(DefineOpaqueTypes::Yes, v1, v2)?;
obligations.extend(ok.into_obligations());
}
_ => {
bug!("kind mismatch, cannot unify {:?} and {:?}", value1, value2,);
}
}
}
Ok(InferOk { value: (), obligations })
}
}
/// Given the region obligations and constraints scraped from the infcx,
/// creates query region constraints.
pub fn make_query_region_constraints<'tcx>(
tcx: TyCtxt<'tcx>,
outlives_obligations: impl Iterator<Item = (Ty<'tcx>, ty::Region<'tcx>, ConstraintCategory<'tcx>)>,
region_constraints: &RegionConstraintData<'tcx>,
) -> QueryRegionConstraints<'tcx> {
let RegionConstraintData { constraints, verifys, member_constraints } = region_constraints;
assert!(verifys.is_empty());
debug!(?constraints);
let outlives: Vec<_> = constraints
.iter()
.map(|(k, origin)| {
let constraint = match *k {
// Swap regions because we are going from sub (<=) to outlives
// (>=).
Constraint::VarSubVar(v1, v2) => ty::OutlivesPredicate(
ty::Region::new_var(tcx, v2).into(),
ty::Region::new_var(tcx, v1),
),
Constraint::VarSubReg(v1, r2) => {
ty::OutlivesPredicate(r2.into(), ty::Region::new_var(tcx, v1))
}
Constraint::RegSubVar(r1, v2) => {
ty::OutlivesPredicate(ty::Region::new_var(tcx, v2).into(), r1)
}
Constraint::RegSubReg(r1, r2) => ty::OutlivesPredicate(r2.into(), r1),
};
(constraint, origin.to_constraint_category())
})
.chain(outlives_obligations.map(|(ty, r, constraint_category)| {
(ty::OutlivesPredicate(ty.into(), r), constraint_category)
}))
.collect();
QueryRegionConstraints { outlives, member_constraints: member_constraints.clone() }
}