rust-analyzer/crates/ra_hir/src/ty/method_resolution.rs

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//! This module is concerned with finding methods that a given type provides.
//! For details about how this works in rustc, see the method lookup page in the
//! [rustc guide](https://rust-lang.github.io/rustc-guide/method-lookup.html)
//! and the corresponding code mostly in librustc_typeck/check/method/probe.rs.
use std::sync::Arc;
use rustc_hash::FxHashMap;
use crate::{
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HirDatabase, Module, Crate, Name, Function, Trait,
impl_block::{ImplId, ImplBlock, ImplItem},
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ty::{Ty, TypeCtor},
nameres::CrateModuleId,
resolve::Resolver,
traits::TraitItem,
generics::HasGenericParams,
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ty::primitive::{UncertainIntTy, UncertainFloatTy}
};
use super::{TraitRef, infer::Canonical, Substs};
/// This is used as a key for indexing impls.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub enum TyFingerprint {
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Apply(TypeCtor),
}
impl TyFingerprint {
/// Creates a TyFingerprint for looking up an impl. Only certain types can
/// have impls: if we have some `struct S`, we can have an `impl S`, but not
/// `impl &S`. Hence, this will return `None` for reference types and such.
fn for_impl(ty: &Ty) -> Option<TyFingerprint> {
match ty {
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Ty::Apply(a_ty) => Some(TyFingerprint::Apply(a_ty.ctor)),
_ => None,
}
}
}
#[derive(Debug, PartialEq, Eq)]
pub struct CrateImplBlocks {
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/// To make sense of the CrateModuleIds, we need the source root.
krate: Crate,
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impls: FxHashMap<TyFingerprint, Vec<(CrateModuleId, ImplId)>>,
impls_by_trait: FxHashMap<Trait, Vec<(CrateModuleId, ImplId)>>,
}
impl CrateImplBlocks {
pub fn lookup_impl_blocks<'a>(&'a self, ty: &Ty) -> impl Iterator<Item = ImplBlock> + 'a {
let fingerprint = TyFingerprint::for_impl(ty);
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fingerprint.and_then(|f| self.impls.get(&f)).into_iter().flat_map(|i| i.iter()).map(
move |(module_id, impl_id)| {
let module = Module { krate: self.krate, module_id: *module_id };
ImplBlock::from_id(module, *impl_id)
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},
)
}
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pub fn lookup_impl_blocks_for_trait<'a>(
&'a self,
tr: &Trait,
) -> impl Iterator<Item = ImplBlock> + 'a {
self.impls_by_trait.get(&tr).into_iter().flat_map(|i| i.iter()).map(
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move |(module_id, impl_id)| {
let module = Module { krate: self.krate, module_id: *module_id };
ImplBlock::from_id(module, *impl_id)
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},
)
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}
fn collect_recursive(&mut self, db: &impl HirDatabase, module: &Module) {
let module_impl_blocks = db.impls_in_module(module.clone());
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for (impl_id, _) in module_impl_blocks.impls.iter() {
let impl_block = ImplBlock::from_id(module_impl_blocks.module, impl_id);
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let target_ty = impl_block.target_ty(db);
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if let Some(tr) = impl_block.target_trait_ref(db) {
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self.impls_by_trait
.entry(tr.trait_)
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.or_insert_with(Vec::new)
.push((module.module_id, impl_id));
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} else {
if let Some(target_ty_fp) = TyFingerprint::for_impl(&target_ty) {
self.impls
.entry(target_ty_fp)
.or_insert_with(Vec::new)
.push((module.module_id, impl_id));
}
}
}
for child in module.children(db) {
self.collect_recursive(db, &child);
}
}
pub(crate) fn impls_in_crate_query(
db: &impl HirDatabase,
krate: Crate,
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) -> Arc<CrateImplBlocks> {
let mut crate_impl_blocks = CrateImplBlocks {
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krate,
impls: FxHashMap::default(),
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impls_by_trait: FxHashMap::default(),
};
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if let Some(module) = krate.root_module(db) {
crate_impl_blocks.collect_recursive(db, &module);
}
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Arc::new(crate_impl_blocks)
}
}
fn def_crate(db: &impl HirDatabase, cur_crate: Crate, ty: &Ty) -> Option<Crate> {
match ty {
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Ty::Apply(a_ty) => match a_ty.ctor {
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TypeCtor::Adt(def_id) => def_id.krate(db),
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TypeCtor::Bool => db.lang_item(cur_crate, "bool".into())?.krate(db),
TypeCtor::Char => db.lang_item(cur_crate, "char".into())?.krate(db),
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TypeCtor::Float(UncertainFloatTy::Known(f)) => {
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db.lang_item(cur_crate, f.ty_to_string().into())?.krate(db)
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}
TypeCtor::Int(UncertainIntTy::Known(i)) => {
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db.lang_item(cur_crate, i.ty_to_string().into())?.krate(db)
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}
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TypeCtor::Str => db.lang_item(cur_crate, "str".into())?.krate(db),
_ => None,
},
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_ => None,
}
}
impl Ty {
/// Look up the method with the given name, returning the actual autoderefed
/// receiver type (but without autoref applied yet).
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pub(crate) fn lookup_method(
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self,
db: &impl HirDatabase,
name: &Name,
resolver: &Resolver,
) -> Option<(Ty, Function)> {
self.iterate_method_candidates(db, resolver, Some(name), |ty, f| Some((ty.clone(), f)))
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}
// This would be nicer if it just returned an iterator, but that runs into
// lifetime problems, because we need to borrow temp `CrateImplBlocks`.
pub(crate) fn iterate_method_candidates<T>(
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self,
db: &impl HirDatabase,
resolver: &Resolver,
name: Option<&Name>,
mut callback: impl FnMut(&Ty, Function) -> Option<T>,
) -> Option<T> {
// For method calls, rust first does any number of autoderef, and then one
// autoref (i.e. when the method takes &self or &mut self). We just ignore
// the autoref currently -- when we find a method matching the given name,
// we assume it fits.
// Also note that when we've got a receiver like &S, even if the method we
// find in the end takes &self, we still do the autoderef step (just as
// rustc does an autoderef and then autoref again).
let krate = resolver.krate()?;
for derefed_ty in self.autoderef(db) {
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if let Some(result) =
derefed_ty.iterate_inherent_methods(db, name, krate, &mut callback)
{
return Some(result);
}
if let Some(result) =
derefed_ty.iterate_trait_method_candidates(db, resolver, name, &mut callback)
{
return Some(result);
}
}
None
}
fn iterate_trait_method_candidates<T>(
&self,
db: &impl HirDatabase,
resolver: &Resolver,
name: Option<&Name>,
mut callback: impl FnMut(&Ty, Function) -> Option<T>,
) -> Option<T> {
let krate = resolver.krate()?;
'traits: for t in resolver.traits_in_scope() {
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let data = t.trait_data(db);
// we'll be lazy about checking whether the type implements the
// trait, but if we find out it doesn't, we'll skip the rest of the
// iteration
let mut known_implemented = false;
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for item in data.items() {
match item {
&TraitItem::Function(m) => {
let sig = m.signature(db);
if name.map_or(true, |name| sig.name() == name) && sig.has_self_param() {
if !known_implemented {
// TODO the self type may contain type
// variables, so we need to do proper
// canonicalization here
let trait_ref = TraitRef {
trait_: t,
substs: fresh_substs_for_trait(db, t, self.clone()),
};
let canonical = Canonical {
num_vars: trait_ref.substs.len(),
value: trait_ref,
};
// FIXME cache this implements check (without solution) in a query?
if super::traits::implements(db, krate, canonical).is_none() {
continue 'traits;
}
}
known_implemented = true;
if let Some(result) = callback(self, m) {
return Some(result);
}
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}
}
_ => {}
}
}
}
None
}
fn iterate_inherent_methods<T>(
&self,
db: &impl HirDatabase,
name: Option<&Name>,
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krate: Crate,
mut callback: impl FnMut(&Ty, Function) -> Option<T>,
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) -> Option<T> {
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let krate = match def_crate(db, krate, self) {
Some(krate) => krate,
None => return None,
};
let impls = db.impls_in_crate(krate);
for impl_block in impls.lookup_impl_blocks(self) {
for item in impl_block.items(db) {
match item {
ImplItem::Method(f) => {
let sig = f.signature(db);
if name.map_or(true, |name| sig.name() == name) && sig.has_self_param() {
if let Some(result) = callback(self, f) {
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return Some(result);
}
}
}
_ => {}
}
}
}
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None
}
// This would be nicer if it just returned an iterator, but that runs into
// lifetime problems, because we need to borrow temp `CrateImplBlocks`.
pub fn iterate_impl_items<T>(
self,
db: &impl HirDatabase,
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krate: Crate,
mut callback: impl FnMut(ImplItem) -> Option<T>,
) -> Option<T> {
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let krate = def_crate(db, krate, &self)?;
let impls = db.impls_in_crate(krate);
for impl_block in impls.lookup_impl_blocks(&self) {
for item in impl_block.items(db) {
if let Some(result) = callback(item) {
return Some(result);
}
}
}
None
}
}
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/// This creates Substs for a trait with the given Self type and type variables
/// for all other parameters, to query Chalk with it.
fn fresh_substs_for_trait(db: &impl HirDatabase, tr: Trait, self_ty: Ty) -> Substs {
let mut substs = Vec::new();
let generics = tr.generic_params(db);
substs.push(self_ty);
substs.extend(
generics
.params_including_parent()
.into_iter()
.skip(1)
.enumerate()
.map(|(i, _p)| Ty::Bound(i as u32)),
);
substs.into()
}