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|
//! This modules implements a function to resolve a path `foo::bar::baz` to a
//! def, which is used within the name resolution.
//!
//! When name resolution is finished, the result of resolving a path is either
//! `Some(def)` or `None`. However, when we are in process of resolving imports
//! or macros, there's a third possibility:
//!
//! I can't resolve this path right now, but I might be resolve this path
//! later, when more macros are expanded.
//!
//! `ReachedFixedPoint` signals about this.
use base_db::Edition;
use hir_expand::name;
use hir_expand::name::Name;
use crate::{
db::DefDatabase,
item_scope::BUILTIN_SCOPE,
nameres::{BuiltinShadowMode, DefMap},
path::{ModPath, PathKind},
per_ns::PerNs,
visibility::{RawVisibility, Visibility},
AdtId, CrateId, EnumVariantId, LocalModuleId, ModuleDefId,
};
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub(super) enum ResolveMode {
Import,
Other,
}
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub(super) enum ReachedFixedPoint {
Yes,
No,
}
#[derive(Debug, Clone)]
pub(super) struct ResolvePathResult {
pub(super) resolved_def: PerNs,
pub(super) segment_index: Option<usize>,
pub(super) reached_fixedpoint: ReachedFixedPoint,
pub(super) krate: Option<CrateId>,
}
impl ResolvePathResult {
fn empty(reached_fixedpoint: ReachedFixedPoint) -> ResolvePathResult {
ResolvePathResult::with(PerNs::none(), reached_fixedpoint, None, None)
}
fn with(
resolved_def: PerNs,
reached_fixedpoint: ReachedFixedPoint,
segment_index: Option<usize>,
krate: Option<CrateId>,
) -> ResolvePathResult {
ResolvePathResult { resolved_def, reached_fixedpoint, segment_index, krate }
}
}
impl DefMap {
pub(super) fn resolve_name_in_extern_prelude(&self, name: &Name) -> PerNs {
if name == &name!(self) {
cov_mark::hit!(extern_crate_self_as);
return PerNs::types(self.module_id(self.root).into(), Visibility::Public);
}
self.extern_prelude
.get(name)
.map_or(PerNs::none(), |&it| PerNs::types(it, Visibility::Public))
}
pub(crate) fn resolve_visibility(
&self,
db: &dyn DefDatabase,
original_module: LocalModuleId,
visibility: &RawVisibility,
) -> Option<Visibility> {
let mut vis = match visibility {
RawVisibility::Module(path) => {
let (result, remaining) =
self.resolve_path(db, original_module, &path, BuiltinShadowMode::Module);
if remaining.is_some() {
return None;
}
let types = result.take_types()?;
match types {
ModuleDefId::ModuleId(m) => Visibility::Module(m),
_ => {
// error: visibility needs to refer to module
return None;
}
}
}
RawVisibility::Public => Visibility::Public,
};
// In block expressions, `self` normally refers to the containing non-block module, and
// `super` to its parent (etc.). However, visibilities must only refer to a module in the
// DefMap they're written in, so we restrict them when that happens.
if let Visibility::Module(m) = vis {
if self.block_id() != m.block {
cov_mark::hit!(adjust_vis_in_block_def_map);
vis = Visibility::Module(self.module_id(self.root()));
log::debug!("visibility {:?} points outside DefMap, adjusting to {:?}", m, vis);
}
}
Some(vis)
}
// Returns Yes if we are sure that additions to `ItemMap` wouldn't change
// the result.
pub(super) fn resolve_path_fp_with_macro(
&self,
db: &dyn DefDatabase,
mode: ResolveMode,
mut original_module: LocalModuleId,
path: &ModPath,
shadow: BuiltinShadowMode,
) -> ResolvePathResult {
let mut result = ResolvePathResult::empty(ReachedFixedPoint::No);
let mut arc;
let mut current_map = self;
loop {
let new = current_map.resolve_path_fp_with_macro_single(
db,
mode,
original_module,
path,
shadow,
);
// Merge `new` into `result`.
result.resolved_def = result.resolved_def.or(new.resolved_def);
if result.reached_fixedpoint == ReachedFixedPoint::No {
result.reached_fixedpoint = new.reached_fixedpoint;
}
// FIXME: this doesn't seem right; what if the different namespace resolutions come from different crates?
result.krate = result.krate.or(new.krate);
result.segment_index = match (result.segment_index, new.segment_index) {
(Some(idx), None) => Some(idx),
(Some(old), Some(new)) => Some(old.max(new)),
(None, new) => new,
};
match ¤t_map.block {
Some(block) => {
original_module = block.parent.local_id;
arc = block.parent.def_map(db);
current_map = &*arc;
}
None => return result,
}
}
}
pub(super) fn resolve_path_fp_with_macro_single(
&self,
db: &dyn DefDatabase,
mode: ResolveMode,
original_module: LocalModuleId,
path: &ModPath,
shadow: BuiltinShadowMode,
) -> ResolvePathResult {
let mut segments = path.segments().iter().enumerate();
let mut curr_per_ns: PerNs = match path.kind {
PathKind::DollarCrate(krate) => {
if krate == self.krate {
cov_mark::hit!(macro_dollar_crate_self);
PerNs::types(self.crate_root(db).into(), Visibility::Public)
} else {
let def_map = db.crate_def_map(krate);
let module = def_map.module_id(def_map.root);
cov_mark::hit!(macro_dollar_crate_other);
PerNs::types(module.into(), Visibility::Public)
}
}
PathKind::Crate => PerNs::types(self.crate_root(db).into(), Visibility::Public),
// plain import or absolute path in 2015: crate-relative with
// fallback to extern prelude (with the simplification in
// rust-lang/rust#57745)
// FIXME there must be a nicer way to write this condition
PathKind::Plain | PathKind::Abs
if self.edition == Edition::Edition2015
&& (path.kind == PathKind::Abs || mode == ResolveMode::Import) =>
{
let (_, segment) = match segments.next() {
Some((idx, segment)) => (idx, segment),
None => return ResolvePathResult::empty(ReachedFixedPoint::Yes),
};
log::debug!("resolving {:?} in crate root (+ extern prelude)", segment);
self.resolve_name_in_crate_root_or_extern_prelude(&segment)
}
PathKind::Plain => {
let (_, segment) = match segments.next() {
Some((idx, segment)) => (idx, segment),
None => return ResolvePathResult::empty(ReachedFixedPoint::Yes),
};
// The first segment may be a builtin type. If the path has more
// than one segment, we first try resolving it as a module
// anyway.
// FIXME: If the next segment doesn't resolve in the module and
// BuiltinShadowMode wasn't Module, then we need to try
// resolving it as a builtin.
let prefer_module =
if path.segments().len() == 1 { shadow } else { BuiltinShadowMode::Module };
log::debug!("resolving {:?} in module", segment);
self.resolve_name_in_module(db, original_module, &segment, prefer_module)
}
PathKind::Super(lvl) => {
let mut module = original_module;
for i in 0..lvl {
match self.modules[module].parent {
Some(it) => module = it,
None => match &self.block {
Some(block) => {
// Look up remaining path in parent `DefMap`
let new_path = ModPath::from_segments(
PathKind::Super(lvl - i),
path.segments().to_vec(),
);
log::debug!("`super` path: {} -> {} in parent map", path, new_path);
return block.parent.def_map(db).resolve_path_fp_with_macro(
db,
mode,
block.parent.local_id,
&new_path,
shadow,
);
}
None => {
log::debug!("super path in root module");
return ResolvePathResult::empty(ReachedFixedPoint::Yes);
}
},
}
}
// Resolve `self` to the containing crate-rooted module if we're a block
self.with_ancestor_maps(db, module, &mut |def_map, module| {
if def_map.block.is_some() {
None // keep ascending
} else {
Some(PerNs::types(def_map.module_id(module).into(), Visibility::Public))
}
})
.expect("block DefMap not rooted in crate DefMap")
}
PathKind::Abs => {
// 2018-style absolute path -- only extern prelude
let segment = match segments.next() {
Some((_, segment)) => segment,
None => return ResolvePathResult::empty(ReachedFixedPoint::Yes),
};
if let Some(def) = self.extern_prelude.get(&segment) {
log::debug!("absolute path {:?} resolved to crate {:?}", path, def);
PerNs::types(*def, Visibility::Public)
} else {
return ResolvePathResult::empty(ReachedFixedPoint::No); // extern crate declarations can add to the extern prelude
}
}
};
for (i, segment) in segments {
let (curr, vis) = match curr_per_ns.take_types_vis() {
Some(r) => r,
None => {
// we still have path segments left, but the path so far
// didn't resolve in the types namespace => no resolution
// (don't break here because `curr_per_ns` might contain
// something in the value namespace, and it would be wrong
// to return that)
return ResolvePathResult::empty(ReachedFixedPoint::No);
}
};
// resolve segment in curr
curr_per_ns = match curr {
ModuleDefId::ModuleId(module) => {
if module.krate != self.krate {
let path = ModPath::from_segments(
PathKind::Super(0),
path.segments()[i..].iter().cloned(),
);
log::debug!("resolving {:?} in other crate", path);
let defp_map = module.def_map(db);
let (def, s) = defp_map.resolve_path(db, module.local_id, &path, shadow);
return ResolvePathResult::with(
def,
ReachedFixedPoint::Yes,
s.map(|s| s + i),
Some(module.krate),
);
}
let def_map;
let module_data = if module.block == self.block_id() {
&self[module.local_id]
} else {
def_map = module.def_map(db);
&def_map[module.local_id]
};
// Since it is a qualified path here, it should not contains legacy macros
module_data.scope.get(&segment)
}
ModuleDefId::AdtId(AdtId::EnumId(e)) => {
// enum variant
cov_mark::hit!(can_import_enum_variant);
let enum_data = db.enum_data(e);
match enum_data.variant(&segment) {
Some(local_id) => {
let variant = EnumVariantId { parent: e, local_id };
match &*enum_data.variants[local_id].variant_data {
crate::adt::VariantData::Record(_) => {
PerNs::types(variant.into(), Visibility::Public)
}
crate::adt::VariantData::Tuple(_)
| crate::adt::VariantData::Unit => {
PerNs::both(variant.into(), variant.into(), Visibility::Public)
}
}
}
None => {
return ResolvePathResult::with(
PerNs::types(e.into(), vis),
ReachedFixedPoint::Yes,
Some(i),
Some(self.krate),
);
}
}
}
s => {
// could be an inherent method call in UFCS form
// (`Struct::method`), or some other kind of associated item
log::debug!(
"path segment {:?} resolved to non-module {:?}, but is not last",
segment,
curr,
);
return ResolvePathResult::with(
PerNs::types(s, vis),
ReachedFixedPoint::Yes,
Some(i),
Some(self.krate),
);
}
};
}
ResolvePathResult::with(curr_per_ns, ReachedFixedPoint::Yes, None, Some(self.krate))
}
fn resolve_name_in_module(
&self,
db: &dyn DefDatabase,
module: LocalModuleId,
name: &Name,
shadow: BuiltinShadowMode,
) -> PerNs {
// Resolve in:
// - legacy scope of macro
// - current module / scope
// - extern prelude
// - std prelude
let from_legacy_macro = self[module]
.scope
.get_legacy_macro(name)
.map_or_else(PerNs::none, |m| PerNs::macros(m, Visibility::Public));
let from_scope = self[module].scope.get(name);
let from_builtin = BUILTIN_SCOPE.get(name).copied().unwrap_or_else(PerNs::none);
let from_scope_or_builtin = match shadow {
BuiltinShadowMode::Module => from_scope.or(from_builtin),
BuiltinShadowMode::Other => {
if let Some(ModuleDefId::ModuleId(_)) = from_scope.take_types() {
from_builtin.or(from_scope)
} else {
from_scope.or(from_builtin)
}
}
};
let from_extern_prelude = self
.extern_prelude
.get(name)
.map_or(PerNs::none(), |&it| PerNs::types(it, Visibility::Public));
let from_prelude = self.resolve_in_prelude(db, name);
from_legacy_macro.or(from_scope_or_builtin).or(from_extern_prelude).or(from_prelude)
}
fn resolve_name_in_crate_root_or_extern_prelude(&self, name: &Name) -> PerNs {
let from_crate_root = self[self.root].scope.get(name);
let from_extern_prelude = self.resolve_name_in_extern_prelude(name);
from_crate_root.or(from_extern_prelude)
}
fn resolve_in_prelude(&self, db: &dyn DefDatabase, name: &Name) -> PerNs {
if let Some(prelude) = self.prelude {
let keep;
let def_map = if prelude.krate == self.krate {
self
} else {
// Extend lifetime
keep = prelude.def_map(db);
&keep
};
def_map[prelude.local_id].scope.get(name)
} else {
PerNs::none()
}
}
}
|