rust/clippy_lints/src/lifetimes.rs

use reexport::*;
use rustc::lint::*;
use rustc::hir::def::Def;
use rustc::hir::*;
use rustc::hir::intravisit::{Visitor, walk_ty, walk_ty_param_bound, walk_fn_decl, walk_generics};
use std::collections::{HashSet, HashMap};
use syntax::codemap::Span;
use utils::{in_external_macro, span_lint};

/// **What it does:** This lint checks for lifetime annotations which can be removed by relying on lifetime elision.
///
/// **Why is this bad?** The additional lifetimes make the code look more complicated, while there is nothing out of the ordinary going on. Removing them leads to more readable code.
///
/// **Known problems:** Potential false negatives: we bail out if the function has a `where` clause where lifetimes are mentioned.
///
/// **Example:** `fn in_and_out<'a>(x: &'a u8, y: u8) -> &'a u8 { x }`
declare_lint! {
    pub NEEDLESS_LIFETIMES,
    Warn,
    "using explicit lifetimes for references in function arguments when elision rules \
     would allow omitting them"
}

/// **What it does:** This lint checks for lifetimes in generics that are never used anywhere else.
///
/// **Why is this bad?** The additional lifetimes make the code look more complicated, while there is nothing out of the ordinary going on. Removing them leads to more readable code.
///
/// **Known problems:** None
///
/// **Example:** `fn unused_lifetime<'a>(x: u8) { .. }`
declare_lint! {
    pub UNUSED_LIFETIMES,
    Warn,
    "unused lifetimes in function definitions"
}

#[derive(Copy,Clone)]
pub struct LifetimePass;

impl LintPass for LifetimePass {
    fn get_lints(&self) -> LintArray {
        lint_array!(NEEDLESS_LIFETIMES, UNUSED_LIFETIMES)
    }
}

impl LateLintPass for LifetimePass {
    fn check_item(&mut self, cx: &LateContext, item: &Item) {
        if let ItemFn(ref decl, _, _, _, ref generics, _) = item.node {
            check_fn_inner(cx, decl, generics, item.span);
        }
    }

    fn check_impl_item(&mut self, cx: &LateContext, item: &ImplItem) {
        if let ImplItemKind::Method(ref sig, _) = item.node {
            check_fn_inner(cx, &sig.decl, &sig.generics, item.span);
        }
    }

    fn check_trait_item(&mut self, cx: &LateContext, item: &TraitItem) {
        if let MethodTraitItem(ref sig, _) = item.node {
            check_fn_inner(cx, &sig.decl, &sig.generics, item.span);
        }
    }
}

/// The lifetime of a &-reference.
#[derive(PartialEq, Eq, Hash, Debug)]
enum RefLt {
    Unnamed,
    Static,
    Named(Name),
}

fn bound_lifetimes(bound: &TyParamBound) -> HirVec<&Lifetime> {
    if let TraitTyParamBound(ref trait_ref, _) = *bound {
        trait_ref.trait_ref
                 .path
                 .segments
                 .last()
                 .expect("a path must have at least one segment")
                 .parameters
                 .lifetimes()
    } else {
        HirVec::new()
    }
}

fn check_fn_inner(cx: &LateContext, decl: &FnDecl, generics: &Generics, span: Span) {
    if in_external_macro(cx, span) || has_where_lifetimes(cx, &generics.where_clause) {
        return;
    }

    let bounds_lts = generics.ty_params
                             .iter()
                             .flat_map(|typ| typ.bounds.iter().flat_map(bound_lifetimes));

    if could_use_elision(cx, decl, &generics.lifetimes, bounds_lts) {
        span_lint(cx,
                  NEEDLESS_LIFETIMES,
                  span,
                  "explicit lifetimes given in parameter types where they could be elided");
    }
    report_extra_lifetimes(cx, decl, generics);
}

fn could_use_elision<'a, T: Iterator<Item = &'a Lifetime>>(cx: &LateContext, func: &FnDecl,
                                                           named_lts: &[LifetimeDef], bounds_lts: T)
                                                           -> bool {
    // There are two scenarios where elision works:
    // * no output references, all input references have different LT
    // * output references, exactly one input reference with same LT
    // All lifetimes must be unnamed, 'static or defined without bounds on the
    // level of the current item.

    // check named LTs
    let allowed_lts = allowed_lts_from(named_lts);

    // these will collect all the lifetimes for references in arg/return types
    let mut input_visitor = RefVisitor::new(cx);
    let mut output_visitor = RefVisitor::new(cx);

    // extract lifetimes in input argument types
    for arg in &func.inputs {
        input_visitor.visit_ty(&arg.ty);
    }
    // extract lifetimes in output type
    if let Return(ref ty) = func.output {
        output_visitor.visit_ty(ty);
    }

    let input_lts = lts_from_bounds(input_visitor.into_vec(), bounds_lts);
    let output_lts = output_visitor.into_vec();

    // check for lifetimes from higher scopes
    for lt in input_lts.iter().chain(output_lts.iter()) {
        if !allowed_lts.contains(lt) {
            return false;
        }
    }

    // no input lifetimes? easy case!
    if input_lts.is_empty() {
        false
    } else if output_lts.is_empty() {
        // no output lifetimes, check distinctness of input lifetimes

        // only unnamed and static, ok
        if input_lts.iter().all(|lt| *lt == RefLt::Unnamed || *lt == RefLt::Static) {
            return false;
        }
        // we have no output reference, so we only need all distinct lifetimes
        input_lts.len() == unique_lifetimes(&input_lts)
    } else {
        // we have output references, so we need one input reference,
        // and all output lifetimes must be the same
        if unique_lifetimes(&output_lts) > 1 {
            return false;
        }
        if input_lts.len() == 1 {
            match (&input_lts[0], &output_lts[0]) {
                (&RefLt::Named(n1), &RefLt::Named(n2)) if n1 == n2 => true,
                (&RefLt::Named(_), &RefLt::Unnamed) => true,
                _ => false, // already elided, different named lifetimes
                // or something static going on
            }
        } else {
            false
        }
    }
}

fn allowed_lts_from(named_lts: &[LifetimeDef]) -> HashSet<RefLt> {
    let mut allowed_lts = HashSet::new();
    for lt in named_lts {
        if lt.bounds.is_empty() {
            allowed_lts.insert(RefLt::Named(lt.lifetime.name));
        }
    }
    allowed_lts.insert(RefLt::Unnamed);
    allowed_lts.insert(RefLt::Static);
    allowed_lts
}

fn lts_from_bounds<'a, T: Iterator<Item = &'a Lifetime>>(mut vec: Vec<RefLt>, bounds_lts: T) -> Vec<RefLt> {
    for lt in bounds_lts {
        if lt.name.as_str() != "'static" {
            vec.push(RefLt::Named(lt.name));
        }
    }

    vec
}

/// Number of unique lifetimes in the given vector.
fn unique_lifetimes(lts: &[RefLt]) -> usize {
    lts.iter().collect::<HashSet<_>>().len()
}

/// A visitor usable for `rustc_front::visit::walk_ty()`.
struct RefVisitor<'v, 't: 'v> {
    cx: &'v LateContext<'v, 't>,
    lts: Vec<RefLt>,
}

impl<'v, 't> RefVisitor<'v, 't> {
    fn new(cx: &'v LateContext<'v, 't>) -> RefVisitor<'v, 't> {
        RefVisitor {
            cx: cx,
            lts: Vec::new(),
        }
    }

    fn record(&mut self, lifetime: &Option<Lifetime>) {
        if let Some(ref lt) = *lifetime {
            if lt.name.as_str() == "'static" {
                self.lts.push(RefLt::Static);
            } else {
                self.lts.push(RefLt::Named(lt.name));
            }
        } else {
            self.lts.push(RefLt::Unnamed);
        }
    }

    fn into_vec(self) -> Vec<RefLt> {
        self.lts
    }

    fn collect_anonymous_lifetimes(&mut self, path: &Path, ty: &Ty) {
        let last_path_segment = path.segments.last().map(|s| &s.parameters);
        if let Some(&AngleBracketedParameters(ref params)) = last_path_segment {
            if params.lifetimes.is_empty() {
                if let Some(def) = self.cx.tcx.def_map.borrow().get(&ty.id).map(|r| r.full_def()) {
                    match def {
                        Def::TyAlias(def_id) |
                        Def::Struct(def_id) => {
                            let type_scheme = self.cx.tcx.lookup_item_type(def_id);
                            for _ in type_scheme.generics.regions.as_slice() {
                                self.record(&None);
                            }
                        }
                        Def::Trait(def_id) => {
                            let trait_def = self.cx.tcx.trait_defs.borrow()[&def_id];
                            for _ in &trait_def.generics.regions {
                                self.record(&None);
                            }
                        }
                        _ => (),
                    }
                }
            }
        }
    }
}

impl<'v, 't> Visitor<'v> for RefVisitor<'v, 't> {
    // for lifetimes as parameters of generics
    fn visit_lifetime(&mut self, lifetime: &'v Lifetime) {
        self.record(&Some(*lifetime));
    }

    fn visit_ty(&mut self, ty: &'v Ty) {
        match ty.node {
            TyRptr(None, _) => {
                self.record(&None);
            }
            TyPath(_, ref path) => {
                self.collect_anonymous_lifetimes(path, ty);
            }
            _ => (),
        }
        walk_ty(self, ty);
    }
}

/// Are any lifetimes mentioned in the `where` clause? If yes, we don't try to
/// reason about elision.
fn has_where_lifetimes(cx: &LateContext, where_clause: &WhereClause) -> bool {
    for predicate in &where_clause.predicates {
        match *predicate {
            WherePredicate::RegionPredicate(..) => return true,
            WherePredicate::BoundPredicate(ref pred) => {
                // a predicate like F: Trait or F: for<'a> Trait<'a>
                let mut visitor = RefVisitor::new(cx);
                // walk the type F, it may not contain LT refs
                walk_ty(&mut visitor, &pred.bounded_ty);
                if !visitor.lts.is_empty() {
                    return true;
                }
                // if the bounds define new lifetimes, they are fine to occur
                let allowed_lts = allowed_lts_from(&pred.bound_lifetimes);
                // now walk the bounds
                for bound in pred.bounds.iter() {
                    walk_ty_param_bound(&mut visitor, bound);
                }
                // and check that all lifetimes are allowed
                for lt in visitor.into_vec() {
                    if !allowed_lts.contains(&lt) {
                        return true;
                    }
                }
            }
            WherePredicate::EqPredicate(ref pred) => {
                let mut visitor = RefVisitor::new(cx);
                walk_ty(&mut visitor, &pred.ty);
                if !visitor.lts.is_empty() {
                    return true;
                }
            }
        }
    }
    false
}

struct LifetimeChecker(HashMap<Name, Span>);

impl<'v> Visitor<'v> for LifetimeChecker {
    // for lifetimes as parameters of generics
    fn visit_lifetime(&mut self, lifetime: &'v Lifetime) {
        self.0.remove(&lifetime.name);
    }

    fn visit_lifetime_def(&mut self, _: &'v LifetimeDef) {
        // don't actually visit `<'a>` or `<'a: 'b>`
        // we've already visited the `'a` declarations and
        // don't want to spuriously remove them
        // `'b` in `'a: 'b` is useless unless used elsewhere in
        // a non-lifetime bound
    }
}

fn report_extra_lifetimes(cx: &LateContext, func: &FnDecl, generics: &Generics) {
    let hs = generics.lifetimes
                     .iter()
                     .map(|lt| (lt.lifetime.name, lt.lifetime.span))
                     .collect();
    let mut checker = LifetimeChecker(hs);

    walk_generics(&mut checker, generics);
    walk_fn_decl(&mut checker, func);

    for &v in checker.0.values() {
        span_lint(cx, UNUSED_LIFETIMES, v, "this lifetime isn't used in the function definition");
    }
}