//! A module with ide helpers for high-level ide features.
+pub mod famous_defs;
+pub mod generated_lints;
pub mod import_assets;
pub mod insert_use;
pub mod merge_imports;
+pub mod node_ext;
pub mod rust_doc;
-pub mod generated_lints;
-use std::collections::VecDeque;
+use std::{collections::VecDeque, iter};
use base_db::FileId;
use either::Either;
-use hir::{Crate, Enum, ItemInNs, MacroDef, Module, ModuleDef, Name, ScopeDef, Semantics, Trait};
+use hir::{ItemInNs, MacroDef, ModuleDef, Name, PathResolution, Semantics};
+use itertools::Itertools;
use syntax::{
- ast::{self, make, LoopBodyOwner},
- AstNode, Direction, SyntaxElement, SyntaxKind, SyntaxToken, TokenAtOffset, WalkEvent, T,
+ ast::{self, make, HasLoopBody, Ident},
+ AstNode, AstToken, Direction, SyntaxElement, SyntaxKind, SyntaxToken, TokenAtOffset, WalkEvent,
+ T,
};
use crate::RootDatabase;
+pub use self::famous_defs::FamousDefs;
+
pub fn item_name(db: &RootDatabase, item: ItemInNs) -> Option<Name> {
match item {
ItemInNs::Types(module_def_id) => ModuleDef::from(module_def_id).name(db),
}
}
-/// Resolves the path at the cursor token as a derive macro if it inside a token tree of a derive attribute.
-pub fn try_resolve_derive_input_at(
- sema: &Semantics<RootDatabase>,
- derive_attr: &ast::Attr,
- cursor: &SyntaxToken,
-) -> Option<MacroDef> {
- use itertools::Itertools;
- if cursor.kind() != T![ident] {
+/// Parses and returns the derive path at the cursor position in the given attribute, if it is a derive.
+/// This special case is required because the derive macro is a compiler builtin that discards the input derives.
+///
+/// The returned path is synthesized from TokenTree tokens and as such cannot be used with the [`Semantics`].
+pub fn get_path_in_derive_attr(
+ sema: &hir::Semantics<RootDatabase>,
+ attr: &ast::Attr,
+ cursor: &Ident,
+) -> Option<ast::Path> {
+ let cursor = cursor.syntax();
+ let path = attr.path()?;
+ let tt = attr.token_tree()?;
+ if !tt.syntax().text_range().contains_range(cursor.text_range()) {
return None;
}
- let tt = match derive_attr.as_simple_call() {
- Some((name, tt))
- if name == "derive" && tt.syntax().text_range().contains_range(cursor.text_range()) =>
- {
- tt
- }
- _ => return None,
- };
- let tokens: Vec<_> = cursor
+ let scope = sema.scope(attr.syntax());
+ let resolved_attr = sema.resolve_path(&path)?;
+ let derive = FamousDefs(sema, scope.krate()).core_macros_builtin_derive()?;
+ if PathResolution::Macro(derive) != resolved_attr {
+ return None;
+ }
+
+ let first = cursor
.siblings_with_tokens(Direction::Prev)
- .flat_map(SyntaxElement::into_token)
+ .filter_map(SyntaxElement::into_token)
.take_while(|tok| tok.kind() != T!['('] && tok.kind() != T![,])
- .collect();
- let path = ast::Path::parse(&tokens.into_iter().rev().join("")).ok()?;
- match sema.scope(tt.syntax()).speculative_resolve(&path) {
- Some(hir::PathResolution::Macro(makro)) if makro.kind() == hir::MacroKind::Derive => {
- Some(makro)
- }
- _ => None,
+ .last()?;
+ let path_tokens = first
+ .siblings_with_tokens(Direction::Next)
+ .filter_map(SyntaxElement::into_token)
+ .take_while(|tok| tok != cursor);
+
+ ast::Path::parse(&path_tokens.chain(iter::once(cursor.clone())).join("")).ok()
+}
+
+/// Parses and resolves the path at the cursor position in the given attribute, if it is a derive.
+/// This special case is required because the derive macro is a compiler builtin that discards the input derives.
+pub fn try_resolve_derive_input(
+ sema: &hir::Semantics<RootDatabase>,
+ attr: &ast::Attr,
+ cursor: &Ident,
+) -> Option<PathResolution> {
+ let path = get_path_in_derive_attr(sema, attr, cursor)?;
+ let scope = sema.scope(attr.syntax());
+ // FIXME: This double resolve shouldn't be necessary
+ // It's only here so we prefer macros over other namespaces
+ match scope.speculative_resolve_as_mac(&path) {
+ Some(mac) if mac.kind() == hir::MacroKind::Derive => Some(PathResolution::Macro(mac)),
+ Some(_) => return None,
+ None => scope
+ .speculative_resolve(&path)
+ .filter(|res| matches!(res, PathResolution::Def(ModuleDef::Module(_)))),
}
}
module.impl_defs(db).into_iter().for_each(|impl_| cb(Either::Right(impl_)));
}
-/// Helps with finding well-know things inside the standard library. This is
-/// somewhat similar to the known paths infra inside hir, but it different; We
-/// want to make sure that IDE specific paths don't become interesting inside
-/// the compiler itself as well.
-///
-/// Note that, by default, rust-analyzer tests **do not** include core or std
-/// libraries. If you are writing tests for functionality using [`FamousDefs`],
-/// you'd want to include [minicore](test_utils::MiniCore) declaration at the
-/// start of your tests:
-///
-/// ```
-/// //- minicore: iterator, ord, derive
-/// ```
-pub struct FamousDefs<'a, 'b>(pub &'a Semantics<'b, RootDatabase>, pub Option<Crate>);
-
-#[allow(non_snake_case)]
-impl FamousDefs<'_, '_> {
- pub fn std(&self) -> Option<Crate> {
- self.find_crate("std")
- }
-
- pub fn core(&self) -> Option<Crate> {
- self.find_crate("core")
- }
-
- pub fn core_cmp_Ord(&self) -> Option<Trait> {
- self.find_trait("core:cmp:Ord")
- }
-
- pub fn core_convert_From(&self) -> Option<Trait> {
- self.find_trait("core:convert:From")
- }
-
- pub fn core_convert_Into(&self) -> Option<Trait> {
- self.find_trait("core:convert:Into")
- }
-
- pub fn core_option_Option(&self) -> Option<Enum> {
- self.find_enum("core:option:Option")
- }
-
- pub fn core_result_Result(&self) -> Option<Enum> {
- self.find_enum("core:result:Result")
- }
-
- pub fn core_default_Default(&self) -> Option<Trait> {
- self.find_trait("core:default:Default")
- }
-
- pub fn core_iter_Iterator(&self) -> Option<Trait> {
- self.find_trait("core:iter:traits:iterator:Iterator")
- }
-
- pub fn core_iter_IntoIterator(&self) -> Option<Trait> {
- self.find_trait("core:iter:traits:collect:IntoIterator")
- }
-
- pub fn core_iter(&self) -> Option<Module> {
- self.find_module("core:iter")
- }
-
- pub fn core_ops_Deref(&self) -> Option<Trait> {
- self.find_trait("core:ops:Deref")
- }
-
- fn find_trait(&self, path: &str) -> Option<Trait> {
- match self.find_def(path)? {
- hir::ScopeDef::ModuleDef(hir::ModuleDef::Trait(it)) => Some(it),
- _ => None,
- }
- }
-
- fn find_enum(&self, path: &str) -> Option<Enum> {
- match self.find_def(path)? {
- hir::ScopeDef::ModuleDef(hir::ModuleDef::Adt(hir::Adt::Enum(it))) => Some(it),
- _ => None,
- }
- }
-
- fn find_module(&self, path: &str) -> Option<Module> {
- match self.find_def(path)? {
- hir::ScopeDef::ModuleDef(hir::ModuleDef::Module(it)) => Some(it),
- _ => None,
- }
- }
-
- fn find_crate(&self, name: &str) -> Option<Crate> {
- let krate = self.1?;
- let db = self.0.db;
- let res =
- krate.dependencies(db).into_iter().find(|dep| dep.name.to_string() == name)?.krate;
- Some(res)
- }
-
- fn find_def(&self, path: &str) -> Option<ScopeDef> {
- let db = self.0.db;
- let mut path = path.split(':');
- let trait_ = path.next_back()?;
- let std_crate = path.next()?;
- let std_crate = self.find_crate(std_crate)?;
- let mut module = std_crate.root_module(db);
- for segment in path {
- module = module.children(db).find_map(|child| {
- let name = child.name(db)?;
- if name.to_string() == segment {
- Some(child)
- } else {
- None
- }
- })?;
- }
- let def =
- module.scope(db, None).into_iter().find(|(name, _def)| name.to_string() == trait_)?.1;
- Some(def)
- }
-}
-
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub struct SnippetCap {
_private: (),
/// Calls `cb` on each expression inside `expr` that is at "tail position".
/// Does not walk into `break` or `return` expressions.
+/// Note that modifying the tree while iterating it will cause undefined iteration which might
+/// potentially results in an out of bounds panic.
pub fn for_each_tail_expr(expr: &ast::Expr, cb: &mut dyn FnMut(&ast::Expr)) {
match expr {
ast::Expr::BlockExpr(b) => {
- if let Some(e) = b.tail_expr() {
- for_each_tail_expr(&e, cb);
- }
- }
- ast::Expr::EffectExpr(e) => match e.effect() {
- ast::Effect::Label(label) => {
- for_each_break_expr(Some(label), e.block_expr(), &mut |b| {
- cb(&ast::Expr::BreakExpr(b))
- });
- if let Some(b) = e.block_expr() {
- for_each_tail_expr(&ast::Expr::BlockExpr(b), cb);
+ match b.modifier() {
+ Some(
+ ast::BlockModifier::Async(_)
+ | ast::BlockModifier::Try(_)
+ | ast::BlockModifier::Const(_),
+ ) => return cb(expr),
+
+ Some(ast::BlockModifier::Label(label)) => {
+ for_each_break_expr(Some(label), b.stmt_list(), &mut |b| {
+ cb(&ast::Expr::BreakExpr(b))
+ });
}
+ Some(ast::BlockModifier::Unsafe(_)) => (),
+ None => (),
}
- ast::Effect::Unsafe(_) => {
- if let Some(e) = e.block_expr().and_then(|b| b.tail_expr()) {
+ if let Some(stmt_list) = b.stmt_list() {
+ if let Some(e) = stmt_list.tail_expr() {
for_each_tail_expr(&e, cb);
}
}
- ast::Effect::Async(_) | ast::Effect::Try(_) | ast::Effect::Const(_) => cb(expr),
- },
+ }
ast::Expr::IfExpr(if_) => {
let mut if_ = if_.clone();
loop {
}
}
ast::Expr::LoopExpr(l) => {
- for_each_break_expr(l.label(), l.loop_body(), &mut |b| cb(&ast::Expr::BreakExpr(b)))
+ for_each_break_expr(l.label(), l.loop_body().and_then(|it| it.stmt_list()), &mut |b| {
+ cb(&ast::Expr::BreakExpr(b))
+ })
}
ast::Expr::MatchExpr(m) => {
if let Some(arms) = m.match_arm_list() {
/// Calls `cb` on each break expr inside of `body` that is applicable for the given label.
pub fn for_each_break_expr(
label: Option<ast::Label>,
- body: Option<ast::BlockExpr>,
+ body: Option<ast::StmtList>,
cb: &mut dyn FnMut(ast::BreakExpr),
) {
let label = label.and_then(|lbl| lbl.lifetime());
ast::Expr::LoopExpr(_) | ast::Expr::WhileExpr(_) | ast::Expr::ForExpr(_) => {
depth += 1
}
- ast::Expr::EffectExpr(e) if e.label().is_some() => depth += 1,
+ ast::Expr::BlockExpr(e) if e.label().is_some() => depth += 1,
ast::Expr::BreakExpr(b)
if (depth == 0 && b.lifetime().is_none()) || eq_label(b.lifetime()) =>
{
ast::Expr::LoopExpr(_) | ast::Expr::WhileExpr(_) | ast::Expr::ForExpr(_) => {
depth -= 1
}
- ast::Expr::EffectExpr(e) if e.label().is_some() => depth -= 1,
+ ast::Expr::BlockExpr(e) if e.label().is_some() => depth -= 1,
_ => (),
},
}