use ra_db::{Cancelable, SyntaxDatabase}; use ra_editor::find_node_at_offset; use ra_syntax::{ AstNode, SyntaxNode, ast::{self, NameOwner}, algo::{find_covering_node, visit::{visitor, Visitor}}, }; use crate::{db::RootDatabase, RangeInfo, FilePosition, FileRange, NavigationTarget}; pub(crate) fn hover( db: &RootDatabase, position: FilePosition, ) -> Cancelable>> { let file = db.source_file(position.file_id); let mut res = Vec::new(); let mut range = None; if let Some(name_ref) = find_node_at_offset::(file.syntax(), position.offset) { let navs = crate::goto_defenition::reference_defenition(db, position.file_id, name_ref)?; for nav in navs { res.extend(doc_text_for(db, nav)?) } if !res.is_empty() { range = Some(name_ref.syntax().range()) } } if range.is_none() { let expr: ast::Expr = ctry!(find_node_at_offset(file.syntax(), position.offset)); let frange = FileRange { file_id: position.file_id, range: expr.syntax().range(), }; res.extend(type_of(db, frange)?); range = Some(expr.syntax().range()); }; let range = ctry!(range); if res.is_empty() { return Ok(None); } let res = RangeInfo::new(range, res.join("\n\n---\n")); Ok(Some(res)) } pub(crate) fn type_of(db: &RootDatabase, frange: FileRange) -> Cancelable> { let file = db.source_file(frange.file_id); let syntax = file.syntax(); let leaf_node = find_covering_node(syntax, frange.range); // if we picked identifier, expand to pattern/expression let node = leaf_node .ancestors() .take_while(|it| it.range() == leaf_node.range()) .find(|&it| ast::Expr::cast(it).is_some() || ast::Pat::cast(it).is_some()) .unwrap_or(leaf_node); let parent_fn = ctry!(node.ancestors().find_map(ast::FnDef::cast)); let function = ctry!(hir::source_binder::function_from_source( db, frange.file_id, parent_fn )?); let infer = function.infer(db)?; Ok(infer.type_of_node(node).map(|t| t.to_string())) } // FIXME: this should not really use navigation target. Rather, approximatelly // resovled symbol should return a `DefId`. fn doc_text_for(db: &RootDatabase, nav: NavigationTarget) -> Cancelable> { let result = match (nav.description(db), nav.docs(db)) { (Some(desc), Some(docs)) => Some("```rust\n".to_string() + &*desc + "\n```\n\n" + &*docs), (Some(desc), None) => Some("```rust\n".to_string() + &*desc + "\n```"), (None, Some(docs)) => Some(docs), _ => None, }; Ok(result) } impl NavigationTarget { fn node(&self, db: &RootDatabase) -> Option { let source_file = db.source_file(self.file_id); let source_file = source_file.syntax(); let node = source_file .descendants() .find(|node| node.kind() == self.kind && node.range() == self.range)? .owned(); Some(node) } fn docs(&self, db: &RootDatabase) -> Option { let node = self.node(db)?; let node = node.borrowed(); fn doc_comments<'a, N: ast::DocCommentsOwner<'a>>(node: N) -> Option { let comments = node.doc_comment_text(); if comments.is_empty() { None } else { Some(comments) } } visitor() .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .visit(doc_comments::) .accept(node)? } /// Get a description of this node. /// /// e.g. `struct Name`, `enum Name`, `fn Name` fn description(&self, db: &RootDatabase) -> Option { // TODO: After type inference is done, add type information to improve the output let node = self.node(db)?; let node = node.borrowed(); // TODO: Refactor to be have less repetition visitor() .visit(|node: ast::FnDef| { let mut string = "fn ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::StructDef| { let mut string = "struct ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::EnumDef| { let mut string = "enum ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::TraitDef| { let mut string = "trait ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::Module| { let mut string = "mod ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::TypeDef| { let mut string = "type ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::ConstDef| { let mut string = "const ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .visit(|node: ast::StaticDef| { let mut string = "static ".to_string(); node.name()?.syntax().text().push_to(&mut string); Some(string) }) .accept(node)? } } #[cfg(test)] mod tests { use ra_syntax::TextRange; use crate::mock_analysis::{single_file_with_position, single_file_with_range}; #[test] fn hover_shows_type_of_an_expression() { let (analysis, position) = single_file_with_position( " pub fn foo() -> u32 { 1 } fn main() { let foo_test = foo()<|>; } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(hover.range, TextRange::from_to(95.into(), 100.into())); assert_eq!(hover.info, "u32"); } #[test] fn hover_for_local_variable() { let (analysis, position) = single_file_with_position("fn func(foo: i32) { fo<|>o; }"); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(hover.info, "i32"); } #[test] fn test_type_of_for_function() { let (analysis, range) = single_file_with_range( " pub fn foo() -> u32 { 1 }; fn main() { let foo_test = <|>foo()<|>; } ", ); let type_name = analysis.type_of(range).unwrap().unwrap(); assert_eq!("u32", &type_name); } // FIXME: improve type_of to make this work #[test] fn test_type_of_for_expr_1() { let (analysis, range) = single_file_with_range( " fn main() { let foo = <|>1 + foo_test<|>; } ", ); let type_name = analysis.type_of(range).unwrap().unwrap(); assert_eq!("[unknown]", &type_name); } // FIXME: improve type_of to make this work #[test] fn test_type_of_for_expr_2() { let (analysis, range) = single_file_with_range( " fn main() { let foo: usize = 1; let bar = <|>1 + foo_test<|>; } ", ); let type_name = analysis.type_of(range).unwrap().unwrap(); assert_eq!("[unknown]", &type_name); } }