use relative_path::RelativePathBuf; use parking_lot::{RwLock, RwLockReadGuard, RwLockWriteGuard}; use libsyntax2::{ File, ast::{self, AstNode, NameOwner}, SyntaxNode, SmolStr, }; use {FileId, FileResolver}; type SyntaxProvider<'a> = dyn Fn(FileId) -> File + 'a; #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug)] pub struct ModuleId(FileId); #[derive(Debug, Default)] pub struct ModuleMap { state: RwLock, } #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum ChangeKind { Delete, Insert, Update } impl Clone for ModuleMap { fn clone(&self) -> ModuleMap { let state = self.state.read().clone(); ModuleMap { state: RwLock::new(state) } } } #[derive(Clone, Debug, Default)] struct State { changes: Vec<(FileId, ChangeKind)>, links: Vec, } #[derive(Clone, Debug)] struct Link { owner: ModuleId, syntax: SyntaxNode, points_to: Vec, problem: Option, } #[derive(Clone, Debug)] pub enum Problem { UnresolvedModule { candidate: RelativePathBuf, }, NotDirOwner { move_to: RelativePathBuf, candidate: RelativePathBuf, } } impl ModuleMap { pub fn update_file(&mut self, file: FileId, change_kind: ChangeKind) { self.state.get_mut().changes.push((file, change_kind)); } pub fn module2file(&self, m: ModuleId) -> FileId { m.0 } pub fn file2module(&self, file_id: FileId) -> ModuleId { ModuleId(file_id) } pub fn child_module_by_name<'a>( &self, parent_mod: ModuleId, child_mod: &str, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, ) -> Vec { self.links(file_resolver, syntax_provider) .links .iter() .filter(|link| link.owner == parent_mod) .filter(|link| link.name() == child_mod) .filter_map(|it| it.points_to.first()) .map(|&it| it) .collect() } pub fn parent_modules( &self, m: ModuleId, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, ) -> Vec<(ModuleId, SmolStr, SyntaxNode)> { let mut res = Vec::new(); self.for_each_parent_link(m, file_resolver, syntax_provider, |link| { res.push( (link.owner, link.name().clone(), link.syntax.clone()) ) }); res } pub fn parent_module_ids( &self, m: ModuleId, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, ) -> Vec { let mut res = Vec::new(); self.for_each_parent_link(m, file_resolver, syntax_provider, |link| res.push(link.owner)); res } fn for_each_parent_link( &self, m: ModuleId, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, f: impl FnMut(&Link) ) { self.links(file_resolver, syntax_provider) .links .iter() .filter(move |link| link.points_to.iter().any(|&it| it == m)) .for_each(f) } pub fn problems( &self, file: FileId, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, mut cb: impl FnMut(ast::Name, &Problem), ) { let module = self.file2module(file); let links = self.links(file_resolver, syntax_provider); links .links .iter() .filter(|link| link.owner == module) .filter_map(|link| { let problem = link.problem.as_ref()?; Some((link, problem)) }) .for_each(|(link, problem)| cb(link.name_node(), problem)) } fn links( &self, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, ) -> RwLockReadGuard { { let guard = self.state.read(); if guard.changes.is_empty() { return guard; } } let mut guard = self.state.write(); if !guard.changes.is_empty() { guard.apply_changes(file_resolver, syntax_provider); } assert!(guard.changes.is_empty()); RwLockWriteGuard::downgrade(guard) } } impl State { pub fn apply_changes( &mut self, file_resolver: &FileResolver, syntax_provider: &SyntaxProvider, ) { let mut reresolve = false; for (file_id, kind) in self.changes.drain(..) { let mod_id = ModuleId(file_id); self.links.retain(|link| link.owner != mod_id); match kind { ChangeKind::Delete => { for link in self.links.iter_mut() { link.points_to.retain(|&x| x != mod_id); } } ChangeKind::Insert => { let file = syntax_provider(file_id); self.links.extend( file .ast() .modules() .filter_map(|it| Link::new(mod_id, it)) ); reresolve = true; } ChangeKind::Update => { let file = syntax_provider(file_id); self.links.extend( file .ast() .modules() .filter_map(|it| Link::new(mod_id, it)) .map(|mut link| { link.resolve(file_resolver); link }) ); } } } if reresolve { for link in self.links.iter_mut() { link.resolve(file_resolver) } } } } impl Link { fn new(owner: ModuleId, module: ast::Module) -> Option { if module.name().is_none() { return None; } let link = Link { owner, syntax: module.syntax().owned(), points_to: Vec::new(), problem: None, }; Some(link) } fn name(&self) -> SmolStr { self.name_node().text() } fn name_node(&self) -> ast::Name { self.ast().name().unwrap() } fn ast(&self) -> ast::Module { ast::Module::cast(self.syntax.borrowed()) .unwrap() } fn resolve(&mut self, file_resolver: &FileResolver) { if !self.ast().has_semi() { self.problem = None; self.points_to = Vec::new(); return; } let mod_name = file_resolver.file_stem(self.owner.0); let is_dir_owner = mod_name == "mod" || mod_name == "lib" || mod_name == "main"; let file_mod = RelativePathBuf::from(format!("../{}.rs", self.name())); let dir_mod = RelativePathBuf::from(format!("../{}/mod.rs", self.name())); if is_dir_owner { self.points_to = [&file_mod, &dir_mod].iter() .filter_map(|path| file_resolver.resolve(self.owner.0, path)) .map(ModuleId) .collect(); self.problem = if self.points_to.is_empty() { Some(Problem::UnresolvedModule { candidate: file_mod, }) } else { None } } else { self.points_to = Vec::new(); self.problem = Some(Problem::NotDirOwner { move_to: RelativePathBuf::from(format!("../{}/mod.rs", mod_name)), candidate: file_mod, }); } } }