do not leak auto traits in item bounds

compiler/rustc_next_trait_solver/src/solve/trait_goals.rs

@@ -164,6 +164,7 @@ where
         ecx: &mut EvalCtxt<'_, D>,
         goal: Goal<I, Self>,
     ) -> Result<Candidate<I>, NoSolution> {
+        let cx = ecx.cx();
         if goal.predicate.polarity != ty::PredicatePolarity::Positive {
             return Err(NoSolution);
         }
@@ -174,20 +175,37 @@ where
 
         // Only consider auto impls of unsafe traits when there are no unsafe
         // fields.
-        if ecx.cx().trait_is_unsafe(goal.predicate.def_id())
+        if cx.trait_is_unsafe(goal.predicate.def_id())
             && goal.predicate.self_ty().has_unsafe_fields()
         {
             return Err(NoSolution);
         }
 
-        // We only look into opaque types during analysis for opaque types
-        // outside of their defining scope. Doing so for opaques in the
-        // defining scope may require calling `typeck` on the same item we're
-        // currently type checking, which will result in a fatal cycle that
-        // ideally we want to avoid, since we can make progress on this goal
-        // via an alias bound or a locally-inferred hidden type instead.
+        // We leak the implemented auto traits of opaques outside of their defining scope.
+        // This depends on `typeck` of the defining scope of that opaque, which may result in
+        // fatal query cycles.
+        //
+        // We only get to this point if we're outside of the defining scope as we'd otherwise
+        // be able to normalize the opaque type. We may also cycle in case `typeck` of a defining
+        // scope relies on the current context, e.g. either because it also leaks auto trait
+        // bounds of opaques defined in the current context or by evaluating the current item.
+        //
+        // To avoid this we don't try to leak auto trait bounds if they can also be proven via
+        // item bounds of the opaque. These bounds are always applicable as auto traits must not
+        // have any generic parameters. They would also get preferred over the impl candidate
+        // when merging candidates anyways.
+        //
+        // See tests/ui/impl-trait/auto-trait-leakage/avoid-query-cycle-via-item-bound.rs.
         if let ty::Alias(ty::Opaque, opaque_ty) = goal.predicate.self_ty().kind() {
             debug_assert!(ecx.opaque_type_is_rigid(opaque_ty.def_id));
+            for item_bound in cx.item_self_bounds(opaque_ty.def_id).skip_binder() {
+                if item_bound
+                    .as_trait_clause()
+                    .is_some_and(|b| b.def_id() == goal.predicate.def_id())
+                {
+                    return Err(NoSolution);
+                }
+            }
         }
 
         ecx.probe_and_evaluate_goal_for_constituent_tys(

tests/ui/impl-trait/auto-trait-leakage/avoid-query-cycle-via-item-bound.rs

@@ -0,0 +1,33 @@
+//@ check-pass
+//@ revisions: current next
+//@[next] compile-flags: -Znext-solver
+//@ ignore-compare-mode-next-solver (explicit revisions)
+
+// When proving auto trait bounds, make sure that we depend on auto trait
+// leakage if we can also prove it via an item bound.
+fn is_send<T: Send>(_: T) {}
+
+fn direct() -> impl Send {
+    is_send(check(false)); // leaks auto traits, depends on `check`
+    1u16
+}
+
+trait Indir: Send {}
+impl Indir for u32 {}
+fn indir() -> impl Indir {
+    is_send(check(false)); // leaks auto traits, depends on `check`
+    1u32
+}
+
+fn check(b: bool) -> impl Sized {
+    if b {
+        // must not leak auto traits, as we otherwise get a query cycle.
+        is_send(direct());
+        is_send(indir());
+    }
+    1u64
+}
+
+fn main() {
+    check(true);
+}

tests/ui/impl-trait/in-trait/refine-cycle.rs

@@ -1,4 +1,7 @@
 //@ check-pass
+//@ revisions: current next
+//@[next] compile-flags: -Znext-solver
+//@ ignore-compare-mode-next-solver (explicit revisions)
 
 // Make sure that refinement checking doesn't cause a cycle in `Instance::resolve`
 // which calls `compare_impl_item`.