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|
pub(super) mod imp;
pub(super) mod nameres;
use std::sync::Arc;
use ra_syntax::{
algo::generate,
ast::{self, AstNode, NameOwner},
SmolStr, SyntaxNode,
};
use ra_db::{SourceRootId, FileId, Cancelable};
use relative_path::RelativePathBuf;
use crate::{
DefKind, DefLoc, DefId, Path, PathKind, HirDatabase, SourceItemId, SourceFileItemId,
arena::{Arena, Id},
};
pub use self::nameres::ModuleScope;
/// `Module` is API entry point to get all the information
/// about a particular module.
#[derive(Debug, Clone)]
pub struct Module {
tree: Arc<ModuleTree>,
pub(crate) source_root_id: SourceRootId,
pub(crate) module_id: ModuleId,
}
impl Module {
pub(super) fn new(
db: &impl HirDatabase,
source_root_id: SourceRootId,
module_id: ModuleId,
) -> Cancelable<Module> {
let module_tree = db.module_tree(source_root_id)?;
let res = Module {
tree: module_tree,
source_root_id,
module_id,
};
Ok(res)
}
/// Returns `mod foo;` or `mod foo {}` node whihc declared this module.
/// Returns `None` for the root module
pub fn parent_link_source(&self, db: &impl HirDatabase) -> Option<(FileId, ast::ModuleNode)> {
let link = self.module_id.parent_link(&self.tree)?;
let file_id = link.owner(&self.tree).source(&self.tree).file_id();
let src = link.bind_source(&self.tree, db);
Some((file_id, src))
}
pub fn source(&self) -> ModuleSource {
self.module_id.source(&self.tree)
}
/// Parent module. Returns `None` if this is a root module.
pub fn parent(&self) -> Option<Module> {
let parent_id = self.module_id.parent(&self.tree)?;
Some(Module {
module_id: parent_id,
..self.clone()
})
}
/// The root of the tree this module is part of
pub fn crate_root(&self) -> Module {
let root_id = self.module_id.crate_root(&self.tree);
Module {
module_id: root_id,
..self.clone()
}
}
/// `name` is `None` for the crate's root module
pub fn name(&self) -> Option<SmolStr> {
let link = self.module_id.parent_link(&self.tree)?;
Some(link.name(&self.tree))
}
pub fn def_id(&self, db: &impl HirDatabase) -> DefId {
let def_loc = DefLoc {
kind: DefKind::Module,
source_root_id: self.source_root_id,
module_id: self.module_id,
source_item_id: self.module_id.source(&self.tree).0,
};
def_loc.id(db)
}
/// Finds a child module with the specified name.
pub fn child(&self, name: &str) -> Option<Module> {
let child_id = self.module_id.child(&self.tree, name)?;
Some(Module {
module_id: child_id,
..self.clone()
})
}
/// Returns a `ModuleScope`: a set of items, visible in this module.
pub fn scope(&self, db: &impl HirDatabase) -> Cancelable<ModuleScope> {
let item_map = db.item_map(self.source_root_id)?;
let res = item_map.per_module[&self.module_id].clone();
Ok(res)
}
pub fn resolve_path(&self, db: &impl HirDatabase, path: Path) -> Cancelable<Option<DefId>> {
let mut curr = match path.kind {
PathKind::Crate => self.crate_root(),
PathKind::Self_ | PathKind::Plain => self.clone(),
PathKind::Super => ctry!(self.parent()),
}
.def_id(db);
let segments = path.segments;
for name in segments.iter() {
let module = match curr.loc(db) {
DefLoc {
kind: DefKind::Module,
source_root_id,
module_id,
..
} => Module::new(db, source_root_id, module_id)?,
_ => return Ok(None),
};
let scope = module.scope(db)?;
curr = ctry!(ctry!(scope.get(&name)).def_id);
}
Ok(Some(curr))
}
pub fn problems(&self, db: &impl HirDatabase) -> Vec<(SyntaxNode, Problem)> {
self.module_id.problems(&self.tree, db)
}
}
/// Phisically, rust source is organized as a set of files, but logically it is
/// organized as a tree of modules. Usually, a single file corresponds to a
/// single module, but it is not nessary the case.
///
/// Module encapsulate the logic of transitioning from the fuzzy world of files
/// (which can have multiple parents) to the precise world of modules (which
/// always have one parent).
#[derive(Default, Debug, PartialEq, Eq)]
pub struct ModuleTree {
mods: Arena<ModuleData>,
links: Arena<LinkData>,
}
impl ModuleTree {
pub(crate) fn modules<'a>(&'a self) -> impl Iterator<Item = ModuleId> + 'a {
self.mods.iter().map(|(id, _)| id)
}
pub(crate) fn modules_with_sources<'a>(
&'a self,
) -> impl Iterator<Item = (ModuleId, ModuleSource)> + 'a {
self.mods.iter().map(|(id, m)| (id, m.source))
}
}
/// `ModuleSource` is the syntax tree element that produced this module:
/// either a file, or an inlinde module.
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub struct ModuleSource(SourceItemId);
/// An owned syntax node for a module. Unlike `ModuleSource`,
/// this holds onto the AST for the whole file.
pub(crate) enum ModuleSourceNode {
SourceFile(ast::SourceFileNode),
Module(ast::ModuleNode),
}
pub type ModuleId = Id<ModuleData>;
type LinkId = Id<LinkData>;
#[derive(Clone, Debug, Hash, PartialEq, Eq)]
pub enum Problem {
UnresolvedModule {
candidate: RelativePathBuf,
},
NotDirOwner {
move_to: RelativePathBuf,
candidate: RelativePathBuf,
},
}
impl ModuleId {
pub(crate) fn source(self, tree: &ModuleTree) -> ModuleSource {
tree.mods[self].source
}
fn parent_link(self, tree: &ModuleTree) -> Option<LinkId> {
tree.mods[self].parent
}
fn parent(self, tree: &ModuleTree) -> Option<ModuleId> {
let link = self.parent_link(tree)?;
Some(tree.links[link].owner)
}
fn crate_root(self, tree: &ModuleTree) -> ModuleId {
generate(Some(self), move |it| it.parent(tree))
.last()
.unwrap()
}
fn child(self, tree: &ModuleTree, name: &str) -> Option<ModuleId> {
let link = tree.mods[self]
.children
.iter()
.map(|&it| &tree.links[it])
.find(|it| it.name == name)?;
Some(*link.points_to.first()?)
}
fn children<'a>(self, tree: &'a ModuleTree) -> impl Iterator<Item = (SmolStr, ModuleId)> + 'a {
tree.mods[self].children.iter().filter_map(move |&it| {
let link = &tree.links[it];
let module = *link.points_to.first()?;
Some((link.name.clone(), module))
})
}
fn problems(self, tree: &ModuleTree, db: &impl HirDatabase) -> Vec<(SyntaxNode, Problem)> {
tree.mods[self]
.children
.iter()
.filter_map(|&it| {
let p = tree.links[it].problem.clone()?;
let s = it.bind_source(tree, db);
let s = s.borrowed().name().unwrap().syntax().owned();
Some((s, p))
})
.collect()
}
}
impl LinkId {
fn owner(self, tree: &ModuleTree) -> ModuleId {
tree.links[self].owner
}
fn name(self, tree: &ModuleTree) -> SmolStr {
tree.links[self].name.clone()
}
fn bind_source<'a>(self, tree: &ModuleTree, db: &impl HirDatabase) -> ast::ModuleNode {
let owner = self.owner(tree);
match owner.source(tree).resolve(db) {
ModuleSourceNode::SourceFile(root) => {
let ast = imp::modules(root.borrowed())
.find(|(name, _)| name == &tree.links[self].name)
.unwrap()
.1;
ast.owned()
}
ModuleSourceNode::Module(it) => it,
}
}
}
#[derive(Debug, PartialEq, Eq, Hash)]
pub struct ModuleData {
source: ModuleSource,
parent: Option<LinkId>,
children: Vec<LinkId>,
}
impl ModuleSource {
// precondition: item_id **must** point to module
fn new(file_id: FileId, item_id: SourceFileItemId) -> ModuleSource {
let source_item_id = SourceItemId { file_id, item_id };
ModuleSource(source_item_id)
}
pub(crate) fn new_file(db: &impl HirDatabase, file_id: FileId) -> ModuleSource {
let file_items = db.file_items(file_id);
let item_id = file_items.id_of_source_file();
ModuleSource::new(file_id, item_id)
}
pub(crate) fn new_inline(
db: &impl HirDatabase,
file_id: FileId,
m: ast::Module,
) -> ModuleSource {
assert!(!m.has_semi());
let file_items = db.file_items(file_id);
let item_id = file_items.id_of(m.syntax());
ModuleSource::new(file_id, item_id)
}
pub fn file_id(self) -> FileId {
self.0.file_id
}
pub(crate) fn resolve(self, db: &impl HirDatabase) -> ModuleSourceNode {
let syntax_node = db.file_item(self.0);
let syntax_node = syntax_node.borrowed();
if let Some(file) = ast::SourceFile::cast(syntax_node) {
return ModuleSourceNode::SourceFile(file.owned());
}
let module = ast::Module::cast(syntax_node).unwrap();
ModuleSourceNode::Module(module.owned())
}
}
#[derive(Hash, Debug, PartialEq, Eq)]
struct LinkData {
owner: ModuleId,
name: SmolStr,
points_to: Vec<ModuleId>,
problem: Option<Problem>,
}
impl ModuleTree {
fn push_mod(&mut self, data: ModuleData) -> ModuleId {
self.mods.alloc(data)
}
fn push_link(&mut self, data: LinkData) -> LinkId {
let owner = data.owner;
let id = self.links.alloc(data);
self.mods[owner].children.push(id);
id
}
}
|