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pub mod ambiguity;
mod fulfillment_errors;
pub mod on_unimplemented;
mod overflow;
pub mod suggestions;

use std::{fmt, iter};

use rustc_data_structures::fx::{FxIndexMap, FxIndexSet};
use rustc_errors::{struct_span_code_err, Applicability, Diag, MultiSpan, E0038, E0276};
use rustc_hir::def_id::{DefId, LocalDefId};
use rustc_hir::intravisit::Visitor;
use rustc_hir::{self as hir, LangItem};
use rustc_infer::traits::{
    ObjectSafetyViolation, Obligation, ObligationCause, ObligationCauseCode, PredicateObligation,
    SelectionError,
};
use rustc_middle::ty::print::{with_no_trimmed_paths, PrintTraitRefExt as _};
use rustc_middle::ty::{self, Ty, TyCtxt};
use rustc_span::{ErrorGuaranteed, ExpnKind, Span};

use crate::error_reporting::TypeErrCtxt;
use crate::traits::{FulfillmentError, FulfillmentErrorCode};

pub use self::overflow::*;

// When outputting impl candidates, prefer showing those that are more similar.
//
// We also compare candidates after skipping lifetimes, which has a lower
// priority than exact matches.
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord)]
pub enum CandidateSimilarity {
    Exact { ignoring_lifetimes: bool },
    Fuzzy { ignoring_lifetimes: bool },
}

#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub struct ImplCandidate<'tcx> {
    pub trait_ref: ty::TraitRef<'tcx>,
    pub similarity: CandidateSimilarity,
    impl_def_id: DefId,
}

enum GetSafeTransmuteErrorAndReason {
    Silent,
    Error { err_msg: String, safe_transmute_explanation: Option<String> },
}

struct UnsatisfiedConst(pub bool);

/// Crude way of getting back an `Expr` from a `Span`.
pub struct FindExprBySpan<'hir> {
    pub span: Span,
    pub result: Option<&'hir hir::Expr<'hir>>,
    pub ty_result: Option<&'hir hir::Ty<'hir>>,
    pub include_closures: bool,
    pub tcx: TyCtxt<'hir>,
}

impl<'hir> FindExprBySpan<'hir> {
    pub fn new(span: Span, tcx: TyCtxt<'hir>) -> Self {
        Self { span, result: None, ty_result: None, tcx, include_closures: false }
    }
}

impl<'v> Visitor<'v> for FindExprBySpan<'v> {
    type NestedFilter = rustc_middle::hir::nested_filter::OnlyBodies;

    fn nested_visit_map(&mut self) -> Self::Map {
        self.tcx.hir()
    }

    fn visit_expr(&mut self, ex: &'v hir::Expr<'v>) {
        if self.span == ex.span {
            self.result = Some(ex);
        } else {
            if let hir::ExprKind::Closure(..) = ex.kind
                && self.include_closures
                && let closure_header_sp = self.span.with_hi(ex.span.hi())
                && closure_header_sp == ex.span
            {
                self.result = Some(ex);
            }
            hir::intravisit::walk_expr(self, ex);
        }
    }

    fn visit_ty(&mut self, ty: &'v hir::Ty<'v>) {
        if self.span == ty.span {
            self.ty_result = Some(ty);
        } else {
            hir::intravisit::walk_ty(self, ty);
        }
    }
}

/// Summarizes information
#[derive(Clone)]
pub enum ArgKind {
    /// An argument of non-tuple type. Parameters are (name, ty)
    Arg(String, String),

    /// An argument of tuple type. For a "found" argument, the span is
    /// the location in the source of the pattern. For an "expected"
    /// argument, it will be None. The vector is a list of (name, ty)
    /// strings for the components of the tuple.
    Tuple(Option<Span>, Vec<(String, String)>),
}

impl ArgKind {
    fn empty() -> ArgKind {
        ArgKind::Arg("_".to_owned(), "_".to_owned())
    }

    /// Creates an `ArgKind` from the expected type of an
    /// argument. It has no name (`_`) and an optional source span.
    pub fn from_expected_ty(t: Ty<'_>, span: Option<Span>) -> ArgKind {
        match t.kind() {
            ty::Tuple(tys) => ArgKind::Tuple(
                span,
                tys.iter().map(|ty| ("_".to_owned(), ty.to_string())).collect::<Vec<_>>(),
            ),
            _ => ArgKind::Arg("_".to_owned(), t.to_string()),
        }
    }
}

#[derive(Copy, Clone)]
pub enum DefIdOrName {
    DefId(DefId),
    Name(&'static str),
}

impl<'a, 'tcx> TypeErrCtxt<'a, 'tcx> {
    pub fn report_fulfillment_errors(
        &self,
        mut errors: Vec<FulfillmentError<'tcx>>,
    ) -> ErrorGuaranteed {
        self.sub_relations
            .borrow_mut()
            .add_constraints(self, errors.iter().map(|e| e.obligation.predicate));

        #[derive(Debug)]
        struct ErrorDescriptor<'tcx> {
            predicate: ty::Predicate<'tcx>,
            index: Option<usize>, // None if this is an old error
        }

        let mut error_map: FxIndexMap<_, Vec<_>> = self
            .reported_trait_errors
            .borrow()
            .iter()
            .map(|(&span, predicates)| {
                (
                    span,
                    predicates
                        .0
                        .iter()
                        .map(|&predicate| ErrorDescriptor { predicate, index: None })
                        .collect(),
                )
            })
            .collect();

        // Ensure `T: Sized` and `T: WF` obligations come last. This lets us display diagnostics
        // with more relevant type information and hide redundant E0282 errors.
        errors.sort_by_key(|e| match e.obligation.predicate.kind().skip_binder() {
            ty::PredicateKind::Clause(ty::ClauseKind::Trait(pred))
                if self.tcx.is_lang_item(pred.def_id(), LangItem::Sized) =>
            {
                1
            }
            ty::PredicateKind::Clause(ty::ClauseKind::WellFormed(_)) => 3,
            ty::PredicateKind::Coerce(_) => 2,
            _ => 0,
        });

        for (index, error) in errors.iter().enumerate() {
            // We want to ignore desugarings here: spans are equivalent even
            // if one is the result of a desugaring and the other is not.
            let mut span = error.obligation.cause.span;
            let expn_data = span.ctxt().outer_expn_data();
            if let ExpnKind::Desugaring(_) = expn_data.kind {
                span = expn_data.call_site;
            }

            error_map.entry(span).or_default().push(ErrorDescriptor {
                predicate: error.obligation.predicate,
                index: Some(index),
            });
        }

        // We do this in 2 passes because we want to display errors in order, though
        // maybe it *is* better to sort errors by span or something.
        let mut is_suppressed = vec![false; errors.len()];
        for (_, error_set) in error_map.iter() {
            // We want to suppress "duplicate" errors with the same span.
            for error in error_set {
                if let Some(index) = error.index {
                    // Suppress errors that are either:
                    // 1) strictly implied by another error.
                    // 2) implied by an error with a smaller index.
                    for error2 in error_set {
                        if error2.index.is_some_and(|index2| is_suppressed[index2]) {
                            // Avoid errors being suppressed by already-suppressed
                            // errors, to prevent all errors from being suppressed
                            // at once.
                            continue;
                        }

                        if self.error_implies(error2.predicate, error.predicate)
                            && !(error2.index >= error.index
                                && self.error_implies(error.predicate, error2.predicate))
                        {
                            info!("skipping {:?} (implied by {:?})", error, error2);
                            is_suppressed[index] = true;
                            break;
                        }
                    }
                }
            }
        }

        let mut reported = None;

        for from_expansion in [false, true] {
            for (error, suppressed) in iter::zip(&errors, &is_suppressed) {
                if !suppressed && error.obligation.cause.span.from_expansion() == from_expansion {
                    let guar = self.report_fulfillment_error(error);
                    self.infcx.set_tainted_by_errors(guar);
                    reported = Some(guar);
                    // We want to ignore desugarings here: spans are equivalent even
                    // if one is the result of a desugaring and the other is not.
                    let mut span = error.obligation.cause.span;
                    let expn_data = span.ctxt().outer_expn_data();
                    if let ExpnKind::Desugaring(_) = expn_data.kind {
                        span = expn_data.call_site;
                    }
                    self.reported_trait_errors
                        .borrow_mut()
                        .entry(span)
                        .or_insert_with(|| (vec![], guar))
                        .0
                        .push(error.obligation.predicate);
                }
            }
        }

        // It could be that we don't report an error because we have seen an `ErrorReported` from
        // another source. We should probably be able to fix most of these, but some are delayed
        // bugs that get a proper error after this function.
        reported.unwrap_or_else(|| self.dcx().delayed_bug("failed to report fulfillment errors"))
    }

    #[instrument(skip(self), level = "debug")]
    fn report_fulfillment_error(&self, error: &FulfillmentError<'tcx>) -> ErrorGuaranteed {
        let mut error = FulfillmentError {
            obligation: error.obligation.clone(),
            code: error.code.clone(),
            root_obligation: error.root_obligation.clone(),
        };
        if matches!(
            error.code,
            FulfillmentErrorCode::Select(crate::traits::SelectionError::Unimplemented)
                | FulfillmentErrorCode::Project(_)
        ) && self.apply_do_not_recommend(&mut error.obligation)
        {
            error.code = FulfillmentErrorCode::Select(SelectionError::Unimplemented);
        }

        match error.code {
            FulfillmentErrorCode::Select(ref selection_error) => self.report_selection_error(
                error.obligation.clone(),
                &error.root_obligation,
                selection_error,
            ),
            FulfillmentErrorCode::Project(ref e) => {
                self.report_projection_error(&error.obligation, e)
            }
            FulfillmentErrorCode::Ambiguity { overflow: None } => {
                self.maybe_report_ambiguity(&error.obligation)
            }
            FulfillmentErrorCode::Ambiguity { overflow: Some(suggest_increasing_limit) } => {
                self.report_overflow_no_abort(error.obligation.clone(), suggest_increasing_limit)
            }
            FulfillmentErrorCode::Subtype(ref expected_found, ref err) => self
                .report_mismatched_types(
                    &error.obligation.cause,
                    expected_found.expected,
                    expected_found.found,
                    *err,
                )
                .emit(),
            FulfillmentErrorCode::ConstEquate(ref expected_found, ref err) => {
                let mut diag = self.report_mismatched_consts(
                    &error.obligation.cause,
                    expected_found.expected,
                    expected_found.found,
                    *err,
                );
                let code = error.obligation.cause.code().peel_derives().peel_match_impls();
                if let ObligationCauseCode::WhereClause(..)
                | ObligationCauseCode::WhereClauseInExpr(..) = code
                {
                    self.note_obligation_cause_code(
                        error.obligation.cause.body_id,
                        &mut diag,
                        error.obligation.predicate,
                        error.obligation.param_env,
                        code,
                        &mut vec![],
                        &mut Default::default(),
                    );
                }
                diag.emit()
            }
            FulfillmentErrorCode::Cycle(ref cycle) => self.report_overflow_obligation_cycle(cycle),
        }
    }
}

/// Recovers the "impl X for Y" signature from `impl_def_id` and returns it as a
/// string.
pub(crate) fn to_pretty_impl_header(tcx: TyCtxt<'_>, impl_def_id: DefId) -> Option<String> {
    use std::fmt::Write;

    let trait_ref = tcx.impl_trait_ref(impl_def_id)?.instantiate_identity();
    let mut w = "impl".to_owned();

    let args = ty::GenericArgs::identity_for_item(tcx, impl_def_id);

    // FIXME: Currently only handles ?Sized.
    //        Needs to support ?Move and ?DynSized when they are implemented.
    let mut types_without_default_bounds = FxIndexSet::default();
    let sized_trait = tcx.lang_items().sized_trait();

    let arg_names = args.iter().map(|k| k.to_string()).filter(|k| k != "'_").collect::<Vec<_>>();
    if !arg_names.is_empty() {
        types_without_default_bounds.extend(args.types());
        w.push('<');
        w.push_str(&arg_names.join(", "));
        w.push('>');
    }

    write!(
        w,
        " {} for {}",
        trait_ref.print_only_trait_path(),
        tcx.type_of(impl_def_id).instantiate_identity()
    )
    .unwrap();

    // The predicates will contain default bounds like `T: Sized`. We need to
    // remove these bounds, and add `T: ?Sized` to any untouched type parameters.
    let predicates = tcx.predicates_of(impl_def_id).predicates;
    let mut pretty_predicates =
        Vec::with_capacity(predicates.len() + types_without_default_bounds.len());

    for (p, _) in predicates {
        if let Some(poly_trait_ref) = p.as_trait_clause() {
            if Some(poly_trait_ref.def_id()) == sized_trait {
                // FIXME(#120456) - is `swap_remove` correct?
                types_without_default_bounds.swap_remove(&poly_trait_ref.self_ty().skip_binder());
                continue;
            }
        }
        pretty_predicates.push(p.to_string());
    }

    pretty_predicates.extend(types_without_default_bounds.iter().map(|ty| format!("{ty}: ?Sized")));

    if !pretty_predicates.is_empty() {
        write!(w, "\n  where {}", pretty_predicates.join(", ")).unwrap();
    }

    w.push(';');
    Some(w)
}

impl<'a, 'tcx> TypeErrCtxt<'a, 'tcx> {
    pub fn report_extra_impl_obligation(
        &self,
        error_span: Span,
        impl_item_def_id: LocalDefId,
        trait_item_def_id: DefId,
        requirement: &dyn fmt::Display,
    ) -> Diag<'a> {
        let mut err = struct_span_code_err!(
            self.dcx(),
            error_span,
            E0276,
            "impl has stricter requirements than trait"
        );

        if !self.tcx.is_impl_trait_in_trait(trait_item_def_id) {
            if let Some(span) = self.tcx.hir().span_if_local(trait_item_def_id) {
                let item_name = self.tcx.item_name(impl_item_def_id.to_def_id());
                err.span_label(span, format!("definition of `{item_name}` from trait"));
            }
        }

        err.span_label(error_span, format!("impl has extra requirement {requirement}"));

        err
    }
}

pub fn report_object_safety_error<'tcx>(
    tcx: TyCtxt<'tcx>,
    span: Span,
    hir_id: Option<hir::HirId>,
    trait_def_id: DefId,
    violations: &[ObjectSafetyViolation],
) -> Diag<'tcx> {
    let trait_str = tcx.def_path_str(trait_def_id);
    let trait_span = tcx.hir().get_if_local(trait_def_id).and_then(|node| match node {
        hir::Node::Item(item) => Some(item.ident.span),
        _ => None,
    });
    let mut err = struct_span_code_err!(
        tcx.dcx(),
        span,
        E0038,
        "the trait `{}` cannot be made into an object",
        trait_str
    );
    err.span_label(span, format!("`{trait_str}` cannot be made into an object"));

    if let Some(hir_id) = hir_id
        && let hir::Node::Ty(ty) = tcx.hir_node(hir_id)
        && let hir::TyKind::TraitObject([trait_ref, ..], ..) = ty.kind
    {
        let mut hir_id = hir_id;
        while let hir::Node::Ty(ty) = tcx.parent_hir_node(hir_id) {
            hir_id = ty.hir_id;
        }
        if tcx.parent_hir_node(hir_id).fn_sig().is_some() {
            // Do not suggest `impl Trait` when dealing with things like super-traits.
            err.span_suggestion_verbose(
                ty.span.until(trait_ref.span),
                "consider using an opaque type instead",
                "impl ",
                Applicability::MaybeIncorrect,
            );
        }
    }
    let mut reported_violations = FxIndexSet::default();
    let mut multi_span = vec![];
    let mut messages = vec![];
    for violation in violations {
        if let ObjectSafetyViolation::SizedSelf(sp) = &violation
            && !sp.is_empty()
        {
            // Do not report `SizedSelf` without spans pointing at `SizedSelf` obligations
            // with a `Span`.
            reported_violations.insert(ObjectSafetyViolation::SizedSelf(vec![].into()));
        }
        if reported_violations.insert(violation.clone()) {
            let spans = violation.spans();
            let msg = if trait_span.is_none() || spans.is_empty() {
                format!("the trait cannot be made into an object because {}", violation.error_msg())
            } else {
                format!("...because {}", violation.error_msg())
            };
            if spans.is_empty() {
                err.note(msg);
            } else {
                for span in spans {
                    multi_span.push(span);
                    messages.push(msg.clone());
                }
            }
        }
    }
    let has_multi_span = !multi_span.is_empty();
    let mut note_span = MultiSpan::from_spans(multi_span.clone());
    if let (Some(trait_span), true) = (trait_span, has_multi_span) {
        note_span.push_span_label(trait_span, "this trait cannot be made into an object...");
    }
    for (span, msg) in iter::zip(multi_span, messages) {
        note_span.push_span_label(span, msg);
    }
    err.span_note(
        note_span,
        "for a trait to be \"object safe\" it needs to allow building a vtable to allow the call \
         to be resolvable dynamically; for more information visit \
         <https://doc.rust-lang.org/reference/items/traits.html#object-safety>",
    );

    // Only provide the help if its a local trait, otherwise it's not actionable.
    if trait_span.is_some() {
        let mut reported_violations: Vec<_> = reported_violations.into_iter().collect();
        reported_violations.sort();

        let mut potential_solutions: Vec<_> =
            reported_violations.into_iter().map(|violation| violation.solution()).collect();
        potential_solutions.sort();
        // Allows us to skip suggesting that the same item should be moved to another trait multiple times.
        potential_solutions.dedup();
        for solution in potential_solutions {
            solution.add_to(&mut err);
        }
    }

    let impls_of = tcx.trait_impls_of(trait_def_id);
    let impls = if impls_of.blanket_impls().is_empty() {
        impls_of
            .non_blanket_impls()
            .values()
            .flatten()
            .filter(|def_id| {
                !matches!(tcx.type_of(*def_id).instantiate_identity().kind(), ty::Dynamic(..))
            })
            .collect::<Vec<_>>()
    } else {
        vec![]
    };
    let externally_visible = if !impls.is_empty()
        && let Some(def_id) = trait_def_id.as_local()
        // We may be executing this during typeck, which would result in cycle
        // if we used effective_visibilities query, which looks into opaque types
        // (and therefore calls typeck).
        && tcx.resolutions(()).effective_visibilities.is_exported(def_id)
    {
        true
    } else {
        false
    };
    match &impls[..] {
        [] => {}
        _ if impls.len() > 9 => {}
        [only] if externally_visible => {
            err.help(with_no_trimmed_paths!(format!(
                "only type `{}` is seen to implement the trait in this crate, consider using it \
                 directly instead",
                tcx.type_of(*only).instantiate_identity(),
            )));
        }
        [only] => {
            err.help(with_no_trimmed_paths!(format!(
                "only type `{}` implements the trait, consider using it directly instead",
                tcx.type_of(*only).instantiate_identity(),
            )));
        }
        impls => {
            let types = impls
                .iter()
                .map(|t| {
                    with_no_trimmed_paths!(format!("  {}", tcx.type_of(*t).instantiate_identity(),))
                })
                .collect::<Vec<_>>();
            err.help(format!(
                "the following types implement the trait, consider defining an enum where each \
                 variant holds one of these types, implementing `{}` for this new enum and using \
                 it instead:\n{}",
                trait_str,
                types.join("\n"),
            ));
        }
    }
    if externally_visible {
        err.note(format!(
            "`{trait_str}` can be implemented in other crates; if you want to support your users \
             passing their own types here, you can't refer to a specific type",
        ));
    }

    err
}