use rustc::hir::def_id::DefId;
use rustc::infer::canonical::{Canonical, QueryResponse};
use rustc::traits::query::dropck_outlives::{DropckOutlivesResult, DtorckConstraint};
use rustc::traits::query::{CanonicalTyGoal, NoSolution};
use rustc::traits::{TraitEngine, Normalized, ObligationCause, TraitEngineExt};
use rustc::ty::query::Providers;
use rustc::ty::subst::{Subst, InternalSubsts};
use rustc::ty::{self, ParamEnvAnd, Ty, TyCtxt};
use rustc::util::nodemap::FxHashSet;
use syntax::source_map::{Span, DUMMY_SP};
crate fn provide(p: &mut Providers<'_>) {
*p = Providers {
dropck_outlives,
adt_dtorck_constraint,
..*p
};
}
fn dropck_outlives<'tcx>(
tcx: TyCtxt<'tcx>,
canonical_goal: CanonicalTyGoal<'tcx>,
) -> Result<&'tcx Canonical<'tcx, QueryResponse<'tcx, DropckOutlivesResult<'tcx>>>, NoSolution> {
debug!("dropck_outlives(goal={:#?})", canonical_goal);
tcx.infer_ctxt().enter_with_canonical(
DUMMY_SP,
&canonical_goal,
|ref infcx, goal, canonical_inference_vars| {
let tcx = infcx.tcx;
let ParamEnvAnd {
param_env,
value: for_ty,
} = goal;
let mut result = DropckOutlivesResult {
kinds: vec![],
overflows: vec![],
};
// A stack of types left to process. Each round, we pop
// something from the stack and invoke
// `dtorck_constraint_for_ty`. This may produce new types that
// have to be pushed on the stack. This continues until we have explored
// all the reachable types from the type `for_ty`.
//
// Example: Imagine that we have the following code:
//
// ```rust
// struct A {
// value: B,
// children: Vec,
// }
//
// struct B {
// value: u32
// }
//
// fn f() {
// let a: A = ...;
// ..
// } // here, `a` is dropped
// ```
//
// at the point where `a` is dropped, we need to figure out
// which types inside of `a` contain region data that may be
// accessed by any destructors in `a`. We begin by pushing `A`
// onto the stack, as that is the type of `a`. We will then
// invoke `dtorck_constraint_for_ty` which will expand `A`
// into the types of its fields `(B, Vec)`. These will get
// pushed onto the stack. Eventually, expanding `Vec` will
// lead to us trying to push `A` a second time -- to prevent
// infinite recursion, we notice that `A` was already pushed
// once and stop.
let mut ty_stack = vec![(for_ty, 0)];
// Set used to detect infinite recursion.
let mut ty_set = FxHashSet::default();
let mut fulfill_cx = TraitEngine::new(infcx.tcx);
let cause = ObligationCause::dummy();
while let Some((ty, depth)) = ty_stack.pop() {
let DtorckConstraint {
dtorck_types,
outlives,
overflows,
} = dtorck_constraint_for_ty(tcx, DUMMY_SP, for_ty, depth, ty)?;
// "outlives" represent types/regions that may be touched
// by a destructor.
result.kinds.extend(outlives);
result.overflows.extend(overflows);
// dtorck types are "types that will get dropped but which
// do not themselves define a destructor", more or less. We have
// to push them onto the stack to be expanded.
for ty in dtorck_types {
match infcx.at(&cause, param_env).normalize(&ty) {
Ok(Normalized {
value: ty,
obligations,
}) => {
fulfill_cx.register_predicate_obligations(infcx, obligations);
debug!("dropck_outlives: ty from dtorck_types = {:?}", ty);
match ty.sty {
// All parameters live for the duration of the
// function.
ty::Param(..) => {}
// A projection that we couldn't resolve - it
// might have a destructor.
ty::Projection(..) | ty::Opaque(..) => {
result.kinds.push(ty.into());
}
_ => {
if ty_set.insert(ty) {
ty_stack.push((ty, depth + 1));
}
}
}
}
// We don't actually expect to fail to normalize.
// That implies a WF error somewhere else.
Err(NoSolution) => {
return Err(NoSolution);
}
}
}
}
debug!("dropck_outlives: result = {:#?}", result);
infcx.make_canonicalized_query_response(
canonical_inference_vars,
result,
&mut *fulfill_cx
)
},
)
}
/// Returns a set of constraints that needs to be satisfied in
/// order for `ty` to be valid for destruction.
fn dtorck_constraint_for_ty<'tcx>(
tcx: TyCtxt<'tcx>,
span: Span,
for_ty: Ty<'tcx>,
depth: usize,
ty: Ty<'tcx>,
) -> Result, NoSolution> {
debug!(
"dtorck_constraint_for_ty({:?}, {:?}, {:?}, {:?})",
span, for_ty, depth, ty
);
if depth >= *tcx.sess.recursion_limit.get() {
return Ok(DtorckConstraint {
outlives: vec![],
dtorck_types: vec![],
overflows: vec![ty],
});
}
let result = match ty.sty {
ty::Bool
| ty::Char
| ty::Int(_)
| ty::Uint(_)
| ty::Float(_)
| ty::Str
| ty::Never
| ty::Foreign(..)
| ty::RawPtr(..)
| ty::Ref(..)
| ty::FnDef(..)
| ty::FnPtr(_)
| ty::GeneratorWitness(..) => {
// these types never have a destructor
Ok(DtorckConstraint::empty())
}
ty::Array(ety, _) | ty::Slice(ety) => {
// single-element containers, behave like their element
dtorck_constraint_for_ty(tcx, span, for_ty, depth + 1, ety)
}
ty::Tuple(tys) => tys.iter()
.map(|ty| dtorck_constraint_for_ty(tcx, span, for_ty, depth + 1, ty.expect_ty()))
.collect(),
ty::Closure(def_id, substs) => substs
.upvar_tys(def_id, tcx)
.map(|ty| dtorck_constraint_for_ty(tcx, span, for_ty, depth + 1, ty))
.collect(),
ty::Generator(def_id, substs, _movability) => {
// rust-lang/rust#49918: types can be constructed, stored
// in the interior, and sit idle when generator yields
// (and is subsequently dropped).
//
// It would be nice to descend into interior of a
// generator to determine what effects dropping it might
// have (by looking at any drop effects associated with
// its interior).
//
// However, the interior's representation uses things like
// GeneratorWitness that explicitly assume they are not
// traversed in such a manner. So instead, we will
// simplify things for now by treating all generators as
// if they were like trait objects, where its upvars must
// all be alive for the generator's (potential)
// destructor.
//
// In particular, skipping over `_interior` is safe
// because any side-effects from dropping `_interior` can
// only take place through references with lifetimes
// derived from lifetimes attached to the upvars, and we
// *do* incorporate the upvars here.
let constraint = DtorckConstraint {
outlives: substs.upvar_tys(def_id, tcx).map(|t| t.into()).collect(),
dtorck_types: vec![],
overflows: vec![],
};
debug!(
"dtorck_constraint: generator {:?} => {:?}",
def_id, constraint
);
Ok(constraint)
}
ty::Adt(def, substs) => {
let DtorckConstraint {
dtorck_types,
outlives,
overflows,
} = tcx.at(span).adt_dtorck_constraint(def.did)?;
Ok(DtorckConstraint {
// FIXME: we can try to recursively `dtorck_constraint_on_ty`
// there, but that needs some way to handle cycles.
dtorck_types: dtorck_types.subst(tcx, substs),
outlives: outlives.subst(tcx, substs),
overflows: overflows.subst(tcx, substs),
})
}
// Objects must be alive in order for their destructor
// to be called.
ty::Dynamic(..) => Ok(DtorckConstraint {
outlives: vec![ty.into()],
dtorck_types: vec![],
overflows: vec![],
}),
// Types that can't be resolved. Pass them forward.
ty::Projection(..) | ty::Opaque(..) | ty::Param(..) => Ok(DtorckConstraint {
outlives: vec![],
dtorck_types: vec![ty],
overflows: vec![],
}),
ty::UnnormalizedProjection(..) => bug!("only used with chalk-engine"),
ty::Placeholder(..) | ty::Bound(..) | ty::Infer(..) | ty::Error => {
// By the time this code runs, all type variables ought to
// be fully resolved.
Err(NoSolution)
}
};
debug!("dtorck_constraint_for_ty({:?}) = {:?}", ty, result);
result
}
/// Calculates the dtorck constraint for a type.
crate fn adt_dtorck_constraint(
tcx: TyCtxt<'_>,
def_id: DefId,
) -> Result, NoSolution> {
let def = tcx.adt_def(def_id);
let span = tcx.def_span(def_id);
debug!("dtorck_constraint: {:?}", def);
if def.is_phantom_data() {
// The first generic parameter here is guaranteed to be a type because it's
// `PhantomData`.
let substs = InternalSubsts::identity_for_item(tcx, def_id);
assert_eq!(substs.len(), 1);
let result = DtorckConstraint {
outlives: vec![],
dtorck_types: vec![substs.type_at(0)],
overflows: vec![],
};
debug!("dtorck_constraint: {:?} => {:?}", def, result);
return Ok(result);
}
let mut result = def.all_fields()
.map(|field| tcx.type_of(field.did))
.map(|fty| dtorck_constraint_for_ty(tcx, span, fty, 0, fty))
.collect::, NoSolution>>()?;
result.outlives.extend(tcx.destructor_constraints(def));
dedup_dtorck_constraint(&mut result);
debug!("dtorck_constraint: {:?} => {:?}", def, result);
Ok(result)
}
fn dedup_dtorck_constraint(c: &mut DtorckConstraint<'_>) {
let mut outlives = FxHashSet::default();
let mut dtorck_types = FxHashSet::default();
c.outlives.retain(|&val| outlives.replace(val).is_none());
c.dtorck_types
.retain(|&val| dtorck_types.replace(val).is_none());
}