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chromium / external / github.com / rust-lang / rust / f668999153d78903658b6937a099819e0b634a06 / . / src / librustc / traits / project.rs
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// Copyright 2014 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Code for projecting associated types out of trait references.
use super::elaborate_predicates;
use super::specialization_graph;
use super::translate_substs;
use super::Obligation;
use super::ObligationCause;
use super::PredicateObligation;
use super::SelectionContext;
use super::SelectionError;
use super::VtableClosureData;
use super::VtableFnPointerData;
use super::VtableImplData;
use super::util;
use hir::def_id::DefId;
use infer::InferOk;
use infer::type_variable::TypeVariableOrigin;
use rustc_data_structures::snapshot_map::{Snapshot, SnapshotMap};
use syntax::ast;
use syntax::symbol::Symbol;
use ty::subst::Subst;
use ty::{self, ToPredicate, ToPolyTraitRef, Ty, TyCtxt};
use ty::fold::{TypeFoldable, TypeFolder};
use util::common::FN_OUTPUT_NAME;
/// Depending on the stage of compilation, we want projection to be
/// more or less conservative.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
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:
///
/// ```
/// trait Assoc {
/// type Output;
/// }
///
/// impl<T> Assoc for T {
/// default type Output = bool;
/// }
///
/// fn main() {
/// let <() as Assoc>::Output = true;
/// }
UserFacing,
/// At trans 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 OIBITS and
/// transmute-checking, which expose some details, but
/// not the whole concrete type of the `impl Trait`.
All,
}
pub type PolyProjectionObligation<'tcx> =
Obligation<'tcx, ty::PolyProjectionPredicate<'tcx>>;
pub type ProjectionObligation<'tcx> =
Obligation<'tcx, ty::ProjectionPredicate<'tcx>>;
pub type ProjectionTyObligation<'tcx> =
Obligation<'tcx, ty::ProjectionTy<'tcx>>;
/// When attempting to resolve `<T as TraitRef>::Name` ...
#[derive(Debug)]
pub enum ProjectionTyError<'tcx> {
/// ...we found multiple sources of information and couldn't resolve the ambiguity.
TooManyCandidates,
/// ...an error occurred matching `T : TraitRef`
TraitSelectionError(SelectionError<'tcx>),
}
#[derive(Clone)]
pub struct MismatchedProjectionTypes<'tcx> {
pub err: ty::error::TypeError<'tcx>
}
#[derive(PartialEq, Eq, Debug)]
enum ProjectionTyCandidate<'tcx> {
// from a where-clause in the env or object type
ParamEnv(ty::PolyProjectionPredicate<'tcx>),
// from the definition of `Trait` when you have something like <<A as Trait>::B as Trait2>::C
TraitDef(ty::PolyProjectionPredicate<'tcx>),
// from a "impl" (or a "pseudo-impl" returned by select)
Select,
}
struct ProjectionTyCandidateSet<'tcx> {
vec: Vec<ProjectionTyCandidate<'tcx>>,
ambiguous: bool
}
/// Evaluates constraints of the form:
///
/// for<...> <T as Trait>::U == V
///
/// If successful, this may result in additional obligations.
pub fn poly_project_and_unify_type<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &PolyProjectionObligation<'tcx>)
-> Result<Option<Vec<PredicateObligation<'tcx>>>, MismatchedProjectionTypes<'tcx>>
{
debug!("poly_project_and_unify_type(obligation={:?})",
obligation);
let infcx = selcx.infcx();
infcx.commit_if_ok(|snapshot| {
let (skol_predicate, skol_map) =
infcx.skolemize_late_bound_regions(&obligation.predicate, snapshot);
let skol_obligation = obligation.with(skol_predicate);
let r = match project_and_unify_type(selcx, &skol_obligation) {
Ok(result) => {
let span = obligation.cause.span;
match infcx.leak_check(false, span, &skol_map, snapshot) {
Ok(()) => Ok(infcx.plug_leaks(skol_map, snapshot, result)),
Err(e) => Err(MismatchedProjectionTypes { err: e }),
}
}
Err(e) => {
Err(e)
}
};
r
})
}
/// Evaluates constraints of the form:
///
/// <T as Trait>::U == V
///
/// If successful, this may result in additional obligations.
fn project_and_unify_type<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionObligation<'tcx>)
-> Result<Option<Vec<PredicateObligation<'tcx>>>, MismatchedProjectionTypes<'tcx>>
{
debug!("project_and_unify_type(obligation={:?})",
obligation);
let Normalized { value: normalized_ty, mut obligations } =
match opt_normalize_projection_type(selcx,
obligation.param_env,
obligation.predicate.projection_ty,
obligation.cause.clone(),
obligation.recursion_depth) {
Some(n) => n,
None => return Ok(None),
};
debug!("project_and_unify_type: normalized_ty={:?} obligations={:?}",
normalized_ty,
obligations);
let infcx = selcx.infcx();
match infcx.at(&obligation.cause, obligation.param_env)
.eq(normalized_ty, obligation.predicate.ty) {
Ok(InferOk { obligations: inferred_obligations, value: () }) => {
obligations.extend(inferred_obligations);
Ok(Some(obligations))
},
Err(err) => Err(MismatchedProjectionTypes { err: err }),
}
}
/// Normalizes any associated type projections in `value`, replacing
/// them with a fully resolved type where possible. The return value
/// combines the normalized result and any additional obligations that
/// were incurred as result.
pub fn normalize<'a, 'b, 'gcx, 'tcx, T>(selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
cause: ObligationCause<'tcx>,
value: &T)
-> Normalized<'tcx, T>
where T : TypeFoldable<'tcx>
{
normalize_with_depth(selcx, param_env, cause, 0, value)
}
/// As `normalize`, but with a custom depth.
pub fn normalize_with_depth<'a, 'b, 'gcx, 'tcx, T>(
selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
cause: ObligationCause<'tcx>,
depth: usize,
value: &T)
-> Normalized<'tcx, T>
where T : TypeFoldable<'tcx>
{
debug!("normalize_with_depth(depth={}, value={:?})", depth, value);
let mut normalizer = AssociatedTypeNormalizer::new(selcx, param_env, cause, depth);
let result = normalizer.fold(value);
debug!("normalize_with_depth: depth={} result={:?} with {} obligations",
depth, result, normalizer.obligations.len());
debug!("normalize_with_depth: depth={} obligations={:?}",
depth, normalizer.obligations);
Normalized {
value: result,
obligations: normalizer.obligations,
}
}
struct AssociatedTypeNormalizer<'a, 'b: 'a, 'gcx: 'b+'tcx, 'tcx: 'b> {
selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
cause: ObligationCause<'tcx>,
obligations: Vec<PredicateObligation<'tcx>>,
depth: usize,
}
impl<'a, 'b, 'gcx, 'tcx> AssociatedTypeNormalizer<'a, 'b, 'gcx, 'tcx> {
fn new(selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
cause: ObligationCause<'tcx>,
depth: usize)
-> AssociatedTypeNormalizer<'a, 'b, 'gcx, 'tcx>
{
AssociatedTypeNormalizer {
selcx,
param_env,
cause,
obligations: vec![],
depth,
}
}
fn fold<T:TypeFoldable<'tcx>>(&mut self, value: &T) -> T {
let value = self.selcx.infcx().resolve_type_vars_if_possible(value);
if !value.has_projection_types() {
value.clone()
} else {
value.fold_with(self)
}
}
}
impl<'a, 'b, 'gcx, 'tcx> TypeFolder<'gcx, 'tcx> for AssociatedTypeNormalizer<'a, 'b, 'gcx, 'tcx> {
fn tcx<'c>(&'c self) -> TyCtxt<'c, 'gcx, 'tcx> {
self.selcx.tcx()
}
fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> {
// We don't want to normalize associated types that occur inside of region
// binders, because they may contain bound regions, and we can't cope with that.
//
// Example:
//
// for<'a> fn(<T as Foo<&'a>>::A)
//
// Instead of normalizing `<T as Foo<&'a>>::A` here, we'll
// normalize it when we instantiate those bound regions (which
// should occur eventually).
let ty = ty.super_fold_with(self);
match ty.sty {
ty::TyAnon(def_id, substs) if !substs.has_escaping_regions() => { // (*)
// Only normalize `impl Trait` after type-checking, usually in trans.
match self.param_env.reveal {
Reveal::UserFacing => ty,
Reveal::All => {
let generic_ty = self.tcx().type_of(def_id);
let concrete_ty = generic_ty.subst(self.tcx(), substs);
self.fold_ty(concrete_ty)
}
}
}
ty::TyProjection(ref data) if !data.has_escaping_regions() => { // (*)
// (*) This is kind of hacky -- we need to be able to
// handle normalization within binders because
// otherwise we wind up a need to normalize when doing
// trait matching (since you can have a trait
// obligation like `for<'a> T::B : Fn(&'a int)`), but
// we can't normalize with bound regions in scope. So
// far now we just ignore binders but only normalize
// if all bound regions are gone (and then we still
// have to renormalize whenever we instantiate a
// binder). It would be better to normalize in a
// binding-aware fashion.
let Normalized { value: normalized_ty, obligations } =
normalize_projection_type(self.selcx,
self.param_env,
data.clone(),
self.cause.clone(),
self.depth);
debug!("AssociatedTypeNormalizer: depth={} normalized {:?} to {:?} \
with {} add'l obligations",
self.depth, ty, normalized_ty, obligations.len());
self.obligations.extend(obligations);
normalized_ty
}
_ => {
ty
}
}
}
}
#[derive(Clone)]
pub struct Normalized<'tcx,T> {
pub value: T,
pub obligations: Vec<PredicateObligation<'tcx>>,
}
pub type NormalizedTy<'tcx> = Normalized<'tcx, Ty<'tcx>>;
impl<'tcx,T> Normalized<'tcx,T> {
pub fn with<U>(self, value: U) -> Normalized<'tcx,U> {
Normalized { value: value, obligations: self.obligations }
}
}
/// The guts of `normalize`: normalize a specific projection like `<T
/// as Trait>::Item`. The result is always a type (and possibly
/// additional obligations). If ambiguity arises, which implies that
/// there are unresolved type variables in the projection, we will
/// substitute a fresh type variable `$X` and generate a new
/// obligation `<T as Trait>::Item == $X` for later.
pub fn normalize_projection_type<'a, 'b, 'gcx, 'tcx>(
selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
projection_ty: ty::ProjectionTy<'tcx>,
cause: ObligationCause<'tcx>,
depth: usize)
-> NormalizedTy<'tcx>
{
opt_normalize_projection_type(selcx, param_env, projection_ty.clone(), cause.clone(), depth)
.unwrap_or_else(move || {
// if we bottom out in ambiguity, create a type variable
// and a deferred predicate to resolve this when more type
// information is available.
let tcx = selcx.infcx().tcx;
let def_id = tcx.associated_items(projection_ty.trait_ref.def_id).find(|i|
i.name == projection_ty.item_name(tcx) && i.kind == ty::AssociatedKind::Type
).map(|i| i.def_id).unwrap();
let ty_var = selcx.infcx().next_ty_var(
TypeVariableOrigin::NormalizeProjectionType(tcx.def_span(def_id)));
let projection = ty::Binder(ty::ProjectionPredicate {
projection_ty,
ty: ty_var
});
let obligation = Obligation::with_depth(
cause, depth + 1, param_env, projection.to_predicate());
Normalized {
value: ty_var,
obligations: vec![obligation]
}
})
}
/// The guts of `normalize`: normalize a specific projection like `<T
/// as Trait>::Item`. The result is always a type (and possibly
/// additional obligations). Returns `None` in the case of ambiguity,
/// which indicates that there are unbound type variables.
fn opt_normalize_projection_type<'a, 'b, 'gcx, 'tcx>(
selcx: &'a mut SelectionContext<'b, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
projection_ty: ty::ProjectionTy<'tcx>,
cause: ObligationCause<'tcx>,
depth: usize)
-> Option<NormalizedTy<'tcx>>
{
let infcx = selcx.infcx();
let projection_ty = infcx.resolve_type_vars_if_possible(&projection_ty);
debug!("opt_normalize_projection_type(\
projection_ty={:?}, \
depth={})",
projection_ty,
depth);
// FIXME(#20304) For now, I am caching here, which is good, but it
// means we don't capture the type variables that are created in
// the case of ambiguity. Which means we may create a large stream
// of such variables. OTOH, if we move the caching up a level, we
// would not benefit from caching when proving `T: Trait<U=Foo>`
// bounds. It might be the case that we want two distinct caches,
// or else another kind of cache entry.
match infcx.projection_cache.borrow_mut().try_start(projection_ty) {
Ok(()) => { }
Err(ProjectionCacheEntry::Ambiguous) => {
// If we found ambiguity the last time, that generally
// means we will continue to do so until some type in the
// key changes (and we know it hasn't, because we just
// fully resolved it). One exception though is closure
// types, which can transition from having a fixed kind to
// no kind with no visible change in the key.
//
// FIXME(#32286) refactor this so that closure type
// changes
debug!("opt_normalize_projection_type: \
found cache entry: ambiguous");
if !projection_ty.has_closure_types() {
return None;
}
}
Err(ProjectionCacheEntry::InProgress) => {
// If while normalized A::B, we are asked to normalize
// A::B, just return A::B itself. This is a conservative
// answer, in the sense that A::B *is* clearly equivalent
// to A::B, though there may be a better value we can
// find.
// Under lazy normalization, this can arise when
// bootstrapping. That is, imagine an environment with a
// where-clause like `A::B == u32`. Now, if we are asked
// to normalize `A::B`, we will want to check the
// where-clauses in scope. So we will try to unify `A::B`
// with `A::B`, which can trigger a recursive
// normalization. In that case, I think we will want this code:
//
// ```
// let ty = selcx.tcx().mk_projection(projection_ty.trait_ref,
// projection_ty.item_name(tcx);
// return Some(NormalizedTy { value: v, obligations: vec![] });
// ```
debug!("opt_normalize_projection_type: \
found cache entry: in-progress");
// But for now, let's classify this as an overflow:
let recursion_limit = selcx.tcx().sess.recursion_limit.get();
let obligation = Obligation::with_depth(cause.clone(),
recursion_limit,
param_env,
projection_ty);
selcx.infcx().report_overflow_error(&obligation, false);
}
Err(ProjectionCacheEntry::NormalizedTy(ty)) => {
// If we find the value in the cache, then the obligations
// have already been returned from the previous entry (and
// should therefore have been honored).
debug!("opt_normalize_projection_type: \
found normalized ty `{:?}`",
ty);
return Some(NormalizedTy { value: ty, obligations: vec![] });
}
Err(ProjectionCacheEntry::Error) => {
debug!("opt_normalize_projection_type: \
found error");
return Some(normalize_to_error(selcx, param_env, projection_ty, cause, depth));
}
}
let obligation = Obligation::with_depth(cause.clone(), depth, param_env, projection_ty);
match project_type(selcx, &obligation) {
Ok(ProjectedTy::Progress(Progress { ty: projected_ty,
mut obligations,
cacheable })) => {
// if projection succeeded, then what we get out of this
// is also non-normalized (consider: it was derived from
// an impl, where-clause etc) and hence we must
// re-normalize it
debug!("opt_normalize_projection_type: \
projected_ty={:?} \
depth={} \
obligations={:?} \
cacheable={:?}",
projected_ty,
depth,
obligations,
cacheable);
let result = if projected_ty.has_projection_types() {
let mut normalizer = AssociatedTypeNormalizer::new(selcx,
param_env,
cause,
depth+1);
let normalized_ty = normalizer.fold(&projected_ty);
debug!("opt_normalize_projection_type: \
normalized_ty={:?} depth={}",
normalized_ty,
depth);
obligations.extend(normalizer.obligations);
Normalized {
value: normalized_ty,
obligations,
}
} else {
Normalized {
value: projected_ty,
obligations,
}
};
infcx.projection_cache.borrow_mut()
.complete(projection_ty, &result, cacheable);
Some(result)
}
Ok(ProjectedTy::NoProgress(projected_ty)) => {
debug!("opt_normalize_projection_type: \
projected_ty={:?} no progress",
projected_ty);
let result = Normalized {
value: projected_ty,
obligations: vec![]
};
infcx.projection_cache.borrow_mut()
.complete(projection_ty, &result, true);
Some(result)
}
Err(ProjectionTyError::TooManyCandidates) => {
debug!("opt_normalize_projection_type: \
too many candidates");
infcx.projection_cache.borrow_mut()
.ambiguous(projection_ty);
None
}
Err(ProjectionTyError::TraitSelectionError(_)) => {
debug!("opt_normalize_projection_type: ERROR");
// if we got an error processing the `T as Trait` part,
// just return `ty::err` but add the obligation `T :
// Trait`, which when processed will cause the error to be
// reported later
infcx.projection_cache.borrow_mut()
.error(projection_ty);
Some(normalize_to_error(selcx, param_env, projection_ty, cause, depth))
}
}
}
/// If we are projecting `<T as Trait>::Item`, but `T: Trait` does not
/// hold. In various error cases, we cannot generate a valid
/// normalized projection. Therefore, we create an inference variable
/// return an associated obligation that, when fulfilled, will lead to
/// an error.
///
/// Note that we used to return `TyError` here, but that was quite
/// dubious -- the premise was that an error would *eventually* be
/// reported, when the obligation was processed. But in general once
/// you see a `TyError` you are supposed to be able to assume that an
/// error *has been* reported, so that you can take whatever heuristic
/// paths you want to take. To make things worse, it was possible for
/// cycles to arise, where you basically had a setup like `<MyType<$0>
/// as Trait>::Foo == $0`. Here, normalizing `<MyType<$0> as
/// Trait>::Foo> to `[type error]` would lead to an obligation of
/// `<MyType<[type error]> as Trait>::Foo`. We are supposed to report
/// an error for this obligation, but we legitimately should not,
/// because it contains `[type error]`. Yuck! (See issue #29857 for
/// one case where this arose.)
fn normalize_to_error<'a, 'gcx, 'tcx>(selcx: &mut SelectionContext<'a, 'gcx, 'tcx>,
param_env: ty::ParamEnv<'tcx>,
projection_ty: ty::ProjectionTy<'tcx>,
cause: ObligationCause<'tcx>,
depth: usize)
-> NormalizedTy<'tcx>
{
let trait_ref = projection_ty.trait_ref.to_poly_trait_ref();
let trait_obligation = Obligation { cause,
recursion_depth: depth,
param_env,
predicate: trait_ref.to_predicate() };
let tcx = selcx.infcx().tcx;
let def_id = tcx.associated_items(projection_ty.trait_ref.def_id).find(|i|
i.name == projection_ty.item_name(tcx) && i.kind == ty::AssociatedKind::Type
).map(|i| i.def_id).unwrap();
let new_value = selcx.infcx().next_ty_var(
TypeVariableOrigin::NormalizeProjectionType(tcx.def_span(def_id)));
Normalized {
value: new_value,
obligations: vec![trait_obligation]
}
}
enum ProjectedTy<'tcx> {
Progress(Progress<'tcx>),
NoProgress(Ty<'tcx>),
}
struct Progress<'tcx> {
ty: Ty<'tcx>,
obligations: Vec<PredicateObligation<'tcx>>,
cacheable: bool,
}
impl<'tcx> Progress<'tcx> {
fn error<'a,'gcx>(tcx: TyCtxt<'a,'gcx,'tcx>) -> Self {
Progress {
ty: tcx.types.err,
obligations: vec![],
cacheable: true
}
}
fn with_addl_obligations(mut self,
mut obligations: Vec<PredicateObligation<'tcx>>)
-> Self {
debug!("with_addl_obligations: self.obligations.len={} obligations.len={}",
self.obligations.len(), obligations.len());
debug!("with_addl_obligations: self.obligations={:?} obligations={:?}",
self.obligations, obligations);
self.obligations.append(&mut obligations);
self
}
}
/// Compute the result of a projection type (if we can).
///
/// IMPORTANT:
/// - `obligation` must be fully normalized
fn project_type<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>)
-> Result<ProjectedTy<'tcx>, ProjectionTyError<'tcx>>
{
debug!("project(obligation={:?})",
obligation);
let recursion_limit = selcx.tcx().sess.recursion_limit.get();
if obligation.recursion_depth >= recursion_limit {
debug!("project: overflow!");
selcx.infcx().report_overflow_error(&obligation, true);
}
let obligation_trait_ref = &obligation.predicate.trait_ref;
debug!("project: obligation_trait_ref={:?}", obligation_trait_ref);
if obligation_trait_ref.references_error() {
return Ok(ProjectedTy::Progress(Progress::error(selcx.tcx())));
}
let mut candidates = ProjectionTyCandidateSet {
vec: Vec::new(),
ambiguous: false,
};
assemble_candidates_from_param_env(selcx,
obligation,
&obligation_trait_ref,
&mut candidates);
assemble_candidates_from_trait_def(selcx,
obligation,
&obligation_trait_ref,
&mut candidates);
if let Err(e) = assemble_candidates_from_impls(selcx,
obligation,
&obligation_trait_ref,
&mut candidates) {
return Err(ProjectionTyError::TraitSelectionError(e));
}
debug!("{} candidates, ambiguous={}",
candidates.vec.len(),
candidates.ambiguous);
// Inherent ambiguity that prevents us from even enumerating the
// candidates.
if candidates.ambiguous {
return Err(ProjectionTyError::TooManyCandidates);
}
// Drop duplicates.
//
// Note: `candidates.vec` seems to be on the critical path of the
// compiler. Replacing it with an hash set was also tried, which would
// render the following dedup unnecessary. It led to cleaner code but
// prolonged compiling time of `librustc` from 5m30s to 6m in one test, or
// ~9% performance lost.
if candidates.vec.len() > 1 {
let mut i = 0;
while i < candidates.vec.len() {
let has_dup = (0..i).any(|j| candidates.vec[i] == candidates.vec[j]);
if has_dup {
candidates.vec.swap_remove(i);
} else {
i += 1;
}
}
}
// Prefer where-clauses. As in select, if there are multiple
// candidates, we prefer where-clause candidates over impls. This
// may seem a bit surprising, since impls are the source of
// "truth" in some sense, but in fact some of the impls that SEEM
// applicable are not, because of nested obligations. Where
// clauses are the safer choice. See the comment on
// `select::SelectionCandidate` and #21974 for more details.
if candidates.vec.len() > 1 {
debug!("retaining param-env candidates only from {:?}", candidates.vec);
candidates.vec.retain(|c| match *c {
ProjectionTyCandidate::ParamEnv(..) => true,
ProjectionTyCandidate::TraitDef(..) |
ProjectionTyCandidate::Select => false,
});
debug!("resulting candidate set: {:?}", candidates.vec);
if candidates.vec.len() != 1 {
return Err(ProjectionTyError::TooManyCandidates);
}
}
assert!(candidates.vec.len() <= 1);
match candidates.vec.pop() {
Some(candidate) => {
Ok(ProjectedTy::Progress(
confirm_candidate(selcx,
obligation,
&obligation_trait_ref,
candidate)))
}
None => {
Ok(ProjectedTy::NoProgress(
selcx.tcx().mk_projection(
obligation.predicate.trait_ref.clone(),
obligation.predicate.item_name(selcx.tcx()))))
}
}
}
/// The first thing we have to do is scan through the parameter
/// environment to see whether there are any projection predicates
/// there that can answer this question.
fn assemble_candidates_from_param_env<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>,
candidate_set: &mut ProjectionTyCandidateSet<'tcx>)
{
debug!("assemble_candidates_from_param_env(..)");
assemble_candidates_from_predicates(selcx,
obligation,
obligation_trait_ref,
candidate_set,
ProjectionTyCandidate::ParamEnv,
obligation.param_env.caller_bounds.iter().cloned());
}
/// In the case of a nested projection like <<A as Foo>::FooT as Bar>::BarT, we may find
/// that the definition of `Foo` has some clues:
///
/// ```
/// trait Foo {
/// type FooT : Bar<BarT=i32>
/// }
/// ```
///
/// Here, for example, we could conclude that the result is `i32`.
fn assemble_candidates_from_trait_def<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>,
candidate_set: &mut ProjectionTyCandidateSet<'tcx>)
{
debug!("assemble_candidates_from_trait_def(..)");
// Check whether the self-type is itself a projection.
let (def_id, substs) = match obligation_trait_ref.self_ty().sty {
ty::TyProjection(ref data) => {
(data.trait_ref.def_id, data.trait_ref.substs)
}
ty::TyAnon(def_id, substs) => (def_id, substs),
ty::TyInfer(ty::TyVar(_)) => {
// If the self-type is an inference variable, then it MAY wind up
// being a projected type, so induce an ambiguity.
candidate_set.ambiguous = true;
return;
}
_ => { return; }
};
// If so, extract what we know from the trait and try to come up with a good answer.
let trait_predicates = selcx.tcx().predicates_of(def_id);
let bounds = trait_predicates.instantiate(selcx.tcx(), substs);
let bounds = elaborate_predicates(selcx.tcx(), bounds.predicates);
assemble_candidates_from_predicates(selcx,
obligation,
obligation_trait_ref,
candidate_set,
ProjectionTyCandidate::TraitDef,
bounds)
}
fn assemble_candidates_from_predicates<'cx, 'gcx, 'tcx, I>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>,
candidate_set: &mut ProjectionTyCandidateSet<'tcx>,
ctor: fn(ty::PolyProjectionPredicate<'tcx>) -> ProjectionTyCandidate<'tcx>,
env_predicates: I)
where I: IntoIterator<Item=ty::Predicate<'tcx>>
{
debug!("assemble_candidates_from_predicates(obligation={:?})",
obligation);
let infcx = selcx.infcx();
for predicate in env_predicates {
debug!("assemble_candidates_from_predicates: predicate={:?}",
predicate);
match predicate {
ty::Predicate::Projection(ref data) => {
let tcx = selcx.tcx();
let same_name = data.item_name(tcx) == obligation.predicate.item_name(tcx);
let is_match = same_name && infcx.probe(|_| {
let data_poly_trait_ref =
data.to_poly_trait_ref();
let obligation_poly_trait_ref =
obligation_trait_ref.to_poly_trait_ref();
infcx.at(&obligation.cause, obligation.param_env)
.sup(obligation_poly_trait_ref, data_poly_trait_ref)
.map(|InferOk { obligations: _, value: () }| {
// FIXME(#32730) -- do we need to take obligations
// into account in any way? At the moment, no.
})
.is_ok()
});
debug!("assemble_candidates_from_predicates: candidate={:?} \
is_match={} same_name={}",
data, is_match, same_name);
if is_match {
candidate_set.vec.push(ctor(data.clone()));
}
}
_ => { }
}
}
}
fn assemble_candidates_from_impls<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>,
candidate_set: &mut ProjectionTyCandidateSet<'tcx>)
-> Result<(), SelectionError<'tcx>>
{
// If we are resolving `<T as TraitRef<...>>::Item == Type`,
// start out by selecting the predicate `T as TraitRef<...>`:
let poly_trait_ref = obligation_trait_ref.to_poly_trait_ref();
let trait_obligation = obligation.with(poly_trait_ref.to_poly_trait_predicate());
selcx.infcx().probe(|_| {
let vtable = match selcx.select(&trait_obligation) {
Ok(Some(vtable)) => vtable,
Ok(None) => {
candidate_set.ambiguous = true;
return Ok(());
}
Err(e) => {
debug!("assemble_candidates_from_impls: selection error {:?}",
e);
return Err(e);
}
};
match vtable {
super::VtableClosure(_) |
super::VtableFnPointer(_) |
super::VtableObject(_) => {
debug!("assemble_candidates_from_impls: vtable={:?}",
vtable);
candidate_set.vec.push(ProjectionTyCandidate::Select);
}
super::VtableImpl(ref impl_data) => {
// We have to be careful when projecting out of an
// impl because of specialization. If we are not in
// trans (i.e., projection mode is not "any"), and the
// impl's type is declared as default, then we disable
// projection (even if the trait ref is fully
// monomorphic). In the case where trait ref is not
// fully monomorphic (i.e., includes type parameters),
// this is because those type parameters may
// ultimately be bound to types from other crates that
// may have specialized impls we can't see. In the
// case where the trait ref IS fully monomorphic, this
// is a policy decision that we made in the RFC in
// order to preserve flexibility for the crate that
// defined the specializable impl to specialize later
// for existing types.
//
// In either case, we handle this by not adding a
// candidate for an impl if it contains a `default`
// type.
let node_item = assoc_ty_def(selcx,
impl_data.impl_def_id,
obligation.predicate.item_name(selcx.tcx()));
let is_default = if node_item.node.is_from_trait() {
// If true, the impl inherited a `type Foo = Bar`
// given in the trait, which is implicitly default.
// Otherwise, the impl did not specify `type` and
// neither did the trait:
//
// ```rust
// trait Foo { type T; }
// impl Foo for Bar { }
// ```
//
// This is an error, but it will be
// reported in `check_impl_items_against_trait`.
// We accept it here but will flag it as
// an error when we confirm the candidate
// (which will ultimately lead to `normalize_to_error`
// being invoked).
node_item.item.defaultness.has_value()
} else {
node_item.item.defaultness.is_default() ||
selcx.tcx().impl_is_default(node_item.node.def_id())
};
// Only reveal a specializable default if we're past type-checking
// and the obligations is monomorphic, otherwise passes such as
// transmute checking and polymorphic MIR optimizations could
// get a result which isn't correct for all monomorphizations.
let new_candidate = if !is_default {
Some(ProjectionTyCandidate::Select)
} else if obligation.param_env.reveal == Reveal::All {
assert!(!poly_trait_ref.needs_infer());
if !poly_trait_ref.needs_subst() {
Some(ProjectionTyCandidate::Select)
} else {
None
}
} else {
None
};
candidate_set.vec.extend(new_candidate);
}
super::VtableParam(..) => {
// This case tell us nothing about the value of an
// associated type. Consider:
//
// ```
// trait SomeTrait { type Foo; }
// fn foo<T:SomeTrait>(...) { }
// ```
//
// If the user writes `<T as SomeTrait>::Foo`, then the `T
// : SomeTrait` binding does not help us decide what the
// type `Foo` is (at least, not more specifically than
// what we already knew).
//
// But wait, you say! What about an example like this:
//
// ```
// fn bar<T:SomeTrait<Foo=usize>>(...) { ... }
// ```
//
// Doesn't the `T : Sometrait<Foo=usize>` predicate help
// resolve `T::Foo`? And of course it does, but in fact
// that single predicate is desugared into two predicates
// in the compiler: a trait predicate (`T : SomeTrait`) and a
// projection. And the projection where clause is handled
// in `assemble_candidates_from_param_env`.
}
super::VtableDefaultImpl(..) |
super::VtableBuiltin(..) => {
// These traits have no associated types.
span_bug!(
obligation.cause.span,
"Cannot project an associated type from `{:?}`",
vtable);
}
}
Ok(())
})
}
fn confirm_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>,
candidate: ProjectionTyCandidate<'tcx>)
-> Progress<'tcx>
{
debug!("confirm_candidate(candidate={:?}, obligation={:?})",
candidate,
obligation);
match candidate {
ProjectionTyCandidate::ParamEnv(poly_projection) |
ProjectionTyCandidate::TraitDef(poly_projection) => {
confirm_param_env_candidate(selcx, obligation, poly_projection)
}
ProjectionTyCandidate::Select => {
confirm_select_candidate(selcx, obligation, obligation_trait_ref)
}
}
}
fn confirm_select_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>)
-> Progress<'tcx>
{
let poly_trait_ref = obligation_trait_ref.to_poly_trait_ref();
let trait_obligation = obligation.with(poly_trait_ref.to_poly_trait_predicate());
let vtable = match selcx.select(&trait_obligation) {
Ok(Some(vtable)) => vtable,
_ => {
span_bug!(
obligation.cause.span,
"Failed to select `{:?}`",
trait_obligation);
}
};
match vtable {
super::VtableImpl(data) =>
confirm_impl_candidate(selcx, obligation, data),
super::VtableClosure(data) =>
confirm_closure_candidate(selcx, obligation, data),
super::VtableFnPointer(data) =>
confirm_fn_pointer_candidate(selcx, obligation, data),
super::VtableObject(_) =>
confirm_object_candidate(selcx, obligation, obligation_trait_ref),
super::VtableDefaultImpl(..) |
super::VtableParam(..) |
super::VtableBuiltin(..) =>
// we don't create Select candidates with this kind of resolution
span_bug!(
obligation.cause.span,
"Cannot project an associated type from `{:?}`",
vtable),
}
}
fn confirm_object_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
obligation_trait_ref: &ty::TraitRef<'tcx>)
-> Progress<'tcx>
{
let self_ty = obligation_trait_ref.self_ty();
let object_ty = selcx.infcx().shallow_resolve(self_ty);
debug!("confirm_object_candidate(object_ty={:?})",
object_ty);
let data = match object_ty.sty {
ty::TyDynamic(ref data, ..) => data,
_ => {
span_bug!(
obligation.cause.span,
"confirm_object_candidate called with non-object: {:?}",
object_ty)
}
};
let env_predicates = data.projection_bounds().map(|p| {
p.with_self_ty(selcx.tcx(), object_ty).to_predicate()
}).collect();
let env_predicate = {
let env_predicates = elaborate_predicates(selcx.tcx(), env_predicates);
// select only those projections that are actually projecting an
// item with the correct name
let tcx = selcx.tcx();
let env_predicates = env_predicates.filter_map(|p| match p {
ty::Predicate::Projection(data) =>
if data.item_name(tcx) == obligation.predicate.item_name(tcx) {
Some(data)
} else {
None
},
_ => None
});
// select those with a relevant trait-ref
let mut env_predicates = env_predicates.filter(|data| {
let data_poly_trait_ref = data.to_poly_trait_ref();
let obligation_poly_trait_ref = obligation_trait_ref.to_poly_trait_ref();
selcx.infcx().probe(|_| {
selcx.infcx().at(&obligation.cause, obligation.param_env)
.sup(obligation_poly_trait_ref, data_poly_trait_ref)
.is_ok()
})
});
// select the first matching one; there really ought to be one or
// else the object type is not WF, since an object type should
// include all of its projections explicitly
match env_predicates.next() {
Some(env_predicate) => env_predicate,
None => {
debug!("confirm_object_candidate: no env-predicate \
found in object type `{:?}`; ill-formed",
object_ty);
return Progress::error(selcx.tcx());
}
}
};
confirm_param_env_candidate(selcx, obligation, env_predicate)
}
fn confirm_fn_pointer_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
fn_pointer_vtable: VtableFnPointerData<'tcx, PredicateObligation<'tcx>>)
-> Progress<'tcx>
{
let fn_type = selcx.infcx().shallow_resolve(fn_pointer_vtable.fn_ty);
let sig = fn_type.fn_sig(selcx.tcx());
let Normalized {
value: sig,
obligations
} = normalize_with_depth(selcx,
obligation.param_env,
obligation.cause.clone(),
obligation.recursion_depth+1,
&sig);
confirm_callable_candidate(selcx, obligation, sig, util::TupleArgumentsFlag::Yes)
.with_addl_obligations(fn_pointer_vtable.nested)
.with_addl_obligations(obligations)
}
fn confirm_closure_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
vtable: VtableClosureData<'tcx, PredicateObligation<'tcx>>)
-> Progress<'tcx>
{
let closure_typer = selcx.closure_typer();
let closure_type = closure_typer.fn_sig(vtable.closure_def_id)
.subst(selcx.tcx(), vtable.substs.substs);
let Normalized {
value: closure_type,
obligations
} = normalize_with_depth(selcx,
obligation.param_env,
obligation.cause.clone(),
obligation.recursion_depth+1,
&closure_type);
debug!("confirm_closure_candidate: obligation={:?},closure_type={:?},obligations={:?}",
obligation,
closure_type,
obligations);
confirm_callable_candidate(selcx,
obligation,
closure_type,
util::TupleArgumentsFlag::No)
.with_addl_obligations(vtable.nested)
.with_addl_obligations(obligations)
}
fn confirm_callable_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
fn_sig: ty::PolyFnSig<'tcx>,
flag: util::TupleArgumentsFlag)
-> Progress<'tcx>
{
let tcx = selcx.tcx();
debug!("confirm_callable_candidate({:?},{:?})",
obligation,
fn_sig);
// the `Output` associated type is declared on `FnOnce`
let fn_once_def_id = tcx.lang_items.fn_once_trait().unwrap();
// Note: we unwrap the binder here but re-create it below (1)
let ty::Binder((trait_ref, ret_type)) =
tcx.closure_trait_ref_and_return_type(fn_once_def_id,
obligation.predicate.trait_ref.self_ty(),
fn_sig,
flag);
let predicate = ty::Binder(ty::ProjectionPredicate { // (1) recreate binder here
projection_ty: ty::ProjectionTy::from_ref_and_name(
tcx,
trait_ref,
Symbol::intern(FN_OUTPUT_NAME),
),
ty: ret_type
});
confirm_param_env_candidate(selcx, obligation, predicate)
}
fn confirm_param_env_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
poly_projection: ty::PolyProjectionPredicate<'tcx>)
-> Progress<'tcx>
{
let infcx = selcx.infcx();
let cause = obligation.cause.clone();
let param_env = obligation.param_env;
let trait_ref = obligation.predicate.trait_ref;
match infcx.match_poly_projection_predicate(cause, param_env, poly_projection, trait_ref) {
Ok(InferOk { value: ty_match, obligations }) => {
Progress {
ty: ty_match.value,
obligations,
cacheable: ty_match.unconstrained_regions.is_empty(),
}
}
Err(e) => {
span_bug!(
obligation.cause.span,
"Failed to unify obligation `{:?}` \
with poly_projection `{:?}`: {:?}",
obligation,
poly_projection,
e);
}
}
}
fn confirm_impl_candidate<'cx, 'gcx, 'tcx>(
selcx: &mut SelectionContext<'cx, 'gcx, 'tcx>,
obligation: &ProjectionTyObligation<'tcx>,
impl_vtable: VtableImplData<'tcx, PredicateObligation<'tcx>>)
-> Progress<'tcx>
{
let VtableImplData { substs, nested, impl_def_id } = impl_vtable;
let tcx = selcx.tcx();
let param_env = obligation.param_env;
let assoc_ty = assoc_ty_def(selcx, impl_def_id, obligation.predicate.item_name(tcx));
let ty = if !assoc_ty.item.defaultness.has_value() {
// This means that the impl is missing a definition for the
// associated type. This error will be reported by the type
// checker method `check_impl_items_against_trait`, so here we
// just return TyError.
debug!("confirm_impl_candidate: no associated type {:?} for {:?}",
assoc_ty.item.name,
obligation.predicate.trait_ref);
tcx.types.err
} else {
tcx.type_of(assoc_ty.item.def_id)
};
let substs = translate_substs(selcx.infcx(), param_env, impl_def_id, substs, assoc_ty.node);
Progress {
ty: ty.subst(tcx, substs),
obligations: nested,
cacheable: true
}
}
/// Locate the definition of an associated type in the specialization hierarchy,
/// starting from the given impl.
///
/// Based on the "projection mode", this lookup may in fact only examine the
/// topmost impl. See the comments for `Reveal` for more details.
fn assoc_ty_def<'cx, 'gcx, 'tcx>(
selcx: &SelectionContext<'cx, 'gcx, 'tcx>,
impl_def_id: DefId,
assoc_ty_name: ast::Name)
-> specialization_graph::NodeItem<ty::AssociatedItem>
{
let tcx = selcx.tcx();
let trait_def_id = tcx.impl_trait_ref(impl_def_id).unwrap().def_id;
let trait_def = tcx.trait_def(trait_def_id);
// This function may be called while we are still building the
// specialization graph that is queried below (via TraidDef::ancestors()),
// so, in order to avoid unnecessary infinite recursion, we manually look
// for the associated item at the given impl.
// If there is no such item in that impl, this function will fail with a
// cycle error if the specialization graph is currently being built.
let impl_node = specialization_graph::Node::Impl(impl_def_id);
for item in impl_node.items(tcx) {
if item.kind == ty::AssociatedKind::Type && item.name == assoc_ty_name {
return specialization_graph::NodeItem {
node: specialization_graph::Node::Impl(impl_def_id),
item,
};
}
}
if let Some(assoc_item) = trait_def
.ancestors(tcx, impl_def_id)
.defs(tcx, assoc_ty_name, ty::AssociatedKind::Type)
.next() {
assoc_item
} else {
// This is saying that neither the trait nor
// the impl contain a definition for this
// associated type. Normally this situation
// could only arise through a compiler bug --
// if the user wrote a bad item name, it
// should have failed in astconv.
bug!("No associated type `{}` for {}",
assoc_ty_name,
tcx.item_path_str(impl_def_id))
}
}
// # Cache
pub struct ProjectionCache<'tcx> {
map: SnapshotMap<ty::ProjectionTy<'tcx>, ProjectionCacheEntry<'tcx>>,
}
#[derive(Clone, Debug)]
enum ProjectionCacheEntry<'tcx> {
InProgress,
Ambiguous,
Error,
NormalizedTy(Ty<'tcx>),
}
// NB: intentionally not Clone
pub struct ProjectionCacheSnapshot {
snapshot: Snapshot
}
impl<'tcx> ProjectionCache<'tcx> {
pub fn new() -> Self {
ProjectionCache {
map: SnapshotMap::new()
}
}
pub fn snapshot(&mut self) -> ProjectionCacheSnapshot {
ProjectionCacheSnapshot { snapshot: self.map.snapshot() }
}
pub fn rollback_to(&mut self, snapshot: ProjectionCacheSnapshot) {
self.map.rollback_to(snapshot.snapshot);
}
pub fn rollback_skolemized(&mut self, snapshot: &ProjectionCacheSnapshot) {
self.map.partial_rollback(&snapshot.snapshot, &|k| k.has_re_skol());
}
pub fn commit(&mut self, snapshot: ProjectionCacheSnapshot) {
self.map.commit(snapshot.snapshot);
}
/// Try to start normalize `key`; returns an error if
/// normalization already occured (this error corresponds to a
/// cache hit, so it's actually a good thing).
fn try_start(&mut self, key: ty::ProjectionTy<'tcx>)
-> Result<(), ProjectionCacheEntry<'tcx>> {
if let Some(entry) = self.map.get(&key) {
return Err(entry.clone());
}
self.map.insert(key, ProjectionCacheEntry::InProgress);
Ok(())
}
/// Indicates that `key` was normalized to `value`. If `cacheable` is false,
/// then this result is sadly not cacheable.
fn complete(&mut self,
key: ty::ProjectionTy<'tcx>,
value: &NormalizedTy<'tcx>,
cacheable: bool) {
let fresh_key = if cacheable {
debug!("ProjectionCacheEntry::complete: adding cache entry: key={:?}, value={:?}",
key, value);
self.map.insert(key, ProjectionCacheEntry::NormalizedTy(value.value))
} else {
debug!("ProjectionCacheEntry::complete: cannot cache: key={:?}, value={:?}",
key, value);
!self.map.remove(key)
};
assert!(!fresh_key, "never started projecting `{:?}`", key);
}
/// Indicates that trying to normalize `key` resulted in
/// ambiguity. No point in trying it again then until we gain more
/// type information (in which case, the "fully resolved" key will
/// be different).
fn ambiguous(&mut self, key: ty::ProjectionTy<'tcx>) {
let fresh = self.map.insert(key, ProjectionCacheEntry::Ambiguous);
assert!(!fresh, "never started projecting `{:?}`", key);
}
/// Indicates that trying to normalize `key` resulted in
/// error.
fn error(&mut self, key: ty::ProjectionTy<'tcx>) {
let fresh = self.map.insert(key, ProjectionCacheEntry::Error);
assert!(!fresh, "never started projecting `{:?}`", key);
}
}