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//! FIXME: write short doc here
mod lower;
pub mod scope;
use std::{ops::Index, sync::Arc};
use hir_expand::{
either::Either, hygiene::Hygiene, AstId, HirFileId, MacroCallLoc, MacroDefId, MacroFileKind,
Source,
};
use ra_arena::{map::ArenaMap, Arena};
use ra_syntax::{ast, AstNode, AstPtr};
use rustc_hash::FxHashMap;
use crate::{
db::DefDatabase2,
expr::{Expr, ExprId, Pat, PatId},
nameres::CrateDefMap,
path::Path,
AstItemDef, DefWithBodyId, HasModule, HasSource, Lookup, ModuleId,
};
pub struct Expander {
crate_def_map: Arc<CrateDefMap>,
current_file_id: HirFileId,
hygiene: Hygiene,
module: ModuleId,
}
impl Expander {
pub fn new(db: &impl DefDatabase2, current_file_id: HirFileId, module: ModuleId) -> Expander {
let crate_def_map = db.crate_def_map(module.krate);
let hygiene = Hygiene::new(db, current_file_id);
Expander { crate_def_map, current_file_id, hygiene, module }
}
fn enter_expand(
&mut self,
db: &impl DefDatabase2,
macro_call: ast::MacroCall,
) -> Option<(Mark, ast::Expr)> {
let ast_id = AstId::new(
self.current_file_id,
db.ast_id_map(self.current_file_id).ast_id(¯o_call),
);
if let Some(path) = macro_call.path().and_then(|path| self.parse_path(path)) {
if let Some(def) = self.resolve_path_as_macro(db, &path) {
let call_id = db.intern_macro(MacroCallLoc { def, ast_id });
let file_id = call_id.as_file(MacroFileKind::Expr);
if let Some(node) = db.parse_or_expand(file_id) {
if let Some(expr) = ast::Expr::cast(node) {
log::debug!("macro expansion {:#?}", expr.syntax());
let mark = Mark { file_id: self.current_file_id };
self.hygiene = Hygiene::new(db, file_id);
self.current_file_id = file_id;
return Some((mark, expr));
}
}
}
}
// FIXME: Instead of just dropping the error from expansion
// report it
None
}
fn exit(&mut self, db: &impl DefDatabase2, mark: Mark) {
self.hygiene = Hygiene::new(db, mark.file_id);
self.current_file_id = mark.file_id;
std::mem::forget(mark);
}
fn to_source<T>(&self, value: T) -> Source<T> {
Source { file_id: self.current_file_id, value }
}
fn parse_path(&mut self, path: ast::Path) -> Option<Path> {
Path::from_src(path, &self.hygiene)
}
fn resolve_path_as_macro(&self, db: &impl DefDatabase2, path: &Path) -> Option<MacroDefId> {
self.crate_def_map.resolve_path(db, self.module.module_id, path).0.get_macros()
}
}
struct Mark {
file_id: HirFileId,
}
impl Drop for Mark {
fn drop(&mut self) {
if !std::thread::panicking() {
panic!("dropped mark")
}
}
}
/// The body of an item (function, const etc.).
#[derive(Debug, Eq, PartialEq)]
pub struct Body {
exprs: Arena<ExprId, Expr>,
pats: Arena<PatId, Pat>,
/// The patterns for the function's parameters. While the parameter types are
/// part of the function signature, the patterns are not (they don't change
/// the external type of the function).
///
/// If this `Body` is for the body of a constant, this will just be
/// empty.
params: Vec<PatId>,
/// The `ExprId` of the actual body expression.
body_expr: ExprId,
}
pub type ExprPtr = Either<AstPtr<ast::Expr>, AstPtr<ast::RecordField>>;
pub type ExprSource = Source<ExprPtr>;
pub type PatPtr = Either<AstPtr<ast::Pat>, AstPtr<ast::SelfParam>>;
pub type PatSource = Source<PatPtr>;
/// An item body together with the mapping from syntax nodes to HIR expression
/// IDs. This is needed to go from e.g. a position in a file to the HIR
/// expression containing it; but for type inference etc., we want to operate on
/// a structure that is agnostic to the actual positions of expressions in the
/// file, so that we don't recompute types whenever some whitespace is typed.
///
/// One complication here is that, due to macro expansion, a single `Body` might
/// be spread across several files. So, for each ExprId and PatId, we record
/// both the HirFileId and the position inside the file. However, we only store
/// AST -> ExprId mapping for non-macro files, as it is not clear how to handle
/// this properly for macros.
#[derive(Default, Debug, Eq, PartialEq)]
pub struct BodySourceMap {
expr_map: FxHashMap<ExprSource, ExprId>,
expr_map_back: ArenaMap<ExprId, ExprSource>,
pat_map: FxHashMap<PatSource, PatId>,
pat_map_back: ArenaMap<PatId, PatSource>,
field_map: FxHashMap<(ExprId, usize), AstPtr<ast::RecordField>>,
}
impl Body {
pub(crate) fn body_with_source_map_query(
db: &impl DefDatabase2,
def: DefWithBodyId,
) -> (Arc<Body>, Arc<BodySourceMap>) {
let mut params = None;
let (file_id, module, body) = match def {
DefWithBodyId::FunctionId(f) => {
let f = f.lookup(db);
let src = f.source(db);
params = src.value.param_list();
(src.file_id, f.module(db), src.value.body().map(ast::Expr::from))
}
DefWithBodyId::ConstId(c) => {
let c = c.lookup(db);
let src = c.source(db);
(src.file_id, c.module(db), src.value.body())
}
DefWithBodyId::StaticId(s) => {
let src = s.source(db);
(src.file_id, s.module(db), src.value.body())
}
};
let expander = Expander::new(db, file_id, module);
let (body, source_map) = Body::new(db, expander, params, body);
(Arc::new(body), Arc::new(source_map))
}
pub(crate) fn body_query(db: &impl DefDatabase2, def: DefWithBodyId) -> Arc<Body> {
db.body_with_source_map(def).0
}
fn new(
db: &impl DefDatabase2,
expander: Expander,
params: Option<ast::ParamList>,
body: Option<ast::Expr>,
) -> (Body, BodySourceMap) {
lower::lower(db, expander, params, body)
}
pub fn params(&self) -> &[PatId] {
&self.params
}
pub fn body_expr(&self) -> ExprId {
self.body_expr
}
pub fn exprs(&self) -> impl Iterator<Item = (ExprId, &Expr)> {
self.exprs.iter()
}
pub fn pats(&self) -> impl Iterator<Item = (PatId, &Pat)> {
self.pats.iter()
}
}
impl Index<ExprId> for Body {
type Output = Expr;
fn index(&self, expr: ExprId) -> &Expr {
&self.exprs[expr]
}
}
impl Index<PatId> for Body {
type Output = Pat;
fn index(&self, pat: PatId) -> &Pat {
&self.pats[pat]
}
}
impl BodySourceMap {
pub fn expr_syntax(&self, expr: ExprId) -> Option<ExprSource> {
self.expr_map_back.get(expr).copied()
}
pub fn node_expr(&self, node: Source<&ast::Expr>) -> Option<ExprId> {
let src = node.map(|it| Either::A(AstPtr::new(it)));
self.expr_map.get(&src).cloned()
}
pub fn pat_syntax(&self, pat: PatId) -> Option<PatSource> {
self.pat_map_back.get(pat).copied()
}
pub fn node_pat(&self, node: Source<&ast::Pat>) -> Option<PatId> {
let src = node.map(|it| Either::A(AstPtr::new(it)));
self.pat_map.get(&src).cloned()
}
pub fn field_syntax(&self, expr: ExprId, field: usize) -> AstPtr<ast::RecordField> {
self.field_map[&(expr, field)]
}
}
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