use ra_db::SourceDatabase; use ra_syntax::{ AstNode, SyntaxNode, TreeArc, ast::{self, NameOwner, VisibilityOwner, TypeAscriptionOwner}, algo::{find_covering_node, find_node_at_offset, find_leaf_at_offset, visit::{visitor, Visitor}}, }; use hir::HirDisplay; use crate::{db::RootDatabase, RangeInfo, FilePosition, FileRange, NavigationTarget}; /// Contains the results when hovering over an item #[derive(Debug, Clone)] pub struct HoverResult { results: Vec, exact: bool, } impl HoverResult { pub fn new() -> HoverResult { HoverResult { results: Vec::new(), // We assume exact by default exact: true, } } pub fn extend(&mut self, item: Option) { self.results.extend(item); } pub fn is_exact(&self) -> bool { self.exact } pub fn is_empty(&self) -> bool { self.results.is_empty() } pub fn len(&self) -> usize { self.results.len() } pub fn first(&self) -> Option<&str> { self.results.first().map(String::as_str) } pub fn results(&self) -> &[String] { &self.results } /// Returns the results converted into markup /// for displaying in a UI pub fn to_markup(&self) -> String { let mut markup = if !self.exact { let mut msg = String::from("Failed to exactly resolve the symbol. This is probably because rust_analyzer does not yet support traits."); if !self.results.is_empty() { msg.push_str(" \nThese items were found instead:"); } msg.push_str("\n\n---\n"); msg } else { String::new() }; markup.push_str(&self.results.join("\n\n---\n")); markup } } pub(crate) fn hover(db: &RootDatabase, position: FilePosition) -> Option> { let file = db.parse(position.file_id); let mut res = HoverResult::new(); let mut range = None; if let Some(name_ref) = find_node_at_offset::(file.syntax(), position.offset) { use crate::goto_definition::{ReferenceResult::*, reference_definition}; let ref_result = reference_definition(db, position.file_id, name_ref); match ref_result { Exact(nav) => res.extend(doc_text_for(db, nav)), Approximate(navs) => { // We are no longer exact res.exact = false; for nav in navs { res.extend(doc_text_for(db, nav)) } } } if !res.is_empty() { range = Some(name_ref.syntax().range()) } } else if let Some(name) = find_node_at_offset::(file.syntax(), position.offset) { let navs = crate::goto_definition::name_definition(db, position.file_id, name); if let Some(navs) = navs { for nav in navs { res.extend(doc_text_for(db, nav)) } } if !res.is_empty() && range.is_none() { range = Some(name.syntax().range()); } } if range.is_none() { let node = find_leaf_at_offset(file.syntax(), position.offset).find_map(|leaf| { leaf.ancestors().find(|n| ast::Expr::cast(*n).is_some() || ast::Pat::cast(*n).is_some()) })?; let frange = FileRange { file_id: position.file_id, range: node.range() }; res.extend(type_of(db, frange).map(rust_code_markup)); range = Some(node.range()); } let range = range?; if res.is_empty() { return None; } let res = RangeInfo::new(range, res); Some(res) } pub(crate) fn type_of(db: &RootDatabase, frange: FileRange) -> Option { let file = db.parse(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 = node.ancestors().find_map(ast::FnDef::cast)?; let function = hir::source_binder::function_from_source(db, frange.file_id, parent_fn)?; let infer = function.infer(db); let source_map = function.body_source_map(db); if let Some(expr) = ast::Expr::cast(node).and_then(|e| source_map.node_expr(e)) { Some(infer[expr].display(db).to_string()) } else if let Some(pat) = ast::Pat::cast(node).and_then(|p| source_map.node_pat(p)) { Some(infer[pat].display(db).to_string()) } else { None } } fn rust_code_markup>(val: CODE) -> String { rust_code_markup_with_doc::<_, &str>(val, None) } fn rust_code_markup_with_doc(val: CODE, doc: Option) -> String where CODE: AsRef, DOC: AsRef, { if let Some(doc) = doc { format!("```rust\n{}\n```\n\n{}", val.as_ref(), doc.as_ref()) } else { format!("```rust\n{}\n```", val.as_ref()) } } // FIXME: this should not really use navigation target. Rather, approximately // resolved symbol should return a `DefId`. fn doc_text_for(db: &RootDatabase, nav: NavigationTarget) -> Option { match (nav.description(db), nav.docs(db)) { (Some(desc), docs) => Some(rust_code_markup_with_doc(desc, docs)), (None, Some(docs)) => Some(docs), _ => None, } } impl NavigationTarget { fn node(&self, db: &RootDatabase) -> Option> { let source_file = db.parse(self.file_id()); let source_file = source_file.syntax(); let node = source_file .descendants() .find(|node| node.kind() == self.kind() && node.range() == self.full_range())? .to_owned(); Some(node) } fn docs(&self, db: &RootDatabase) -> Option { let node = self.node(db)?; fn doc_comments(node: &N) -> Option { node.doc_comment_text() } 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::) .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 { // FIXME: After type inference is done, add type information to improve the output let node = self.node(db)?; fn visit_ascribed_node(node: &T, prefix: &str) -> Option where T: NameOwner + VisibilityOwner + TypeAscriptionOwner, { let mut string = visit_node(node, prefix)?; if let Some(type_ref) = node.ascribed_type() { string.push_str(": "); type_ref.syntax().text().push_to(&mut string); } Some(string) } fn visit_node(node: &T, label: &str) -> Option where T: NameOwner + VisibilityOwner, { let mut string = node.visibility().map(|v| format!("{} ", v.syntax().text())).unwrap_or_default(); string.push_str(label); string.push_str(node.name()?.text().as_str()); Some(string) } visitor() .visit(crate::completion::function_label) .visit(|node: &ast::StructDef| visit_node(node, "struct ")) .visit(|node: &ast::EnumDef| visit_node(node, "enum ")) .visit(|node: &ast::TraitDef| visit_node(node, "trait ")) .visit(|node: &ast::Module| visit_node(node, "mod ")) .visit(|node: &ast::TypeAliasDef| visit_node(node, "type ")) .visit(|node: &ast::ConstDef| visit_ascribed_node(node, "const ")) .visit(|node: &ast::StaticDef| visit_ascribed_node(node, "static ")) .visit(|node: &ast::NamedFieldDef| visit_ascribed_node(node, "")) .visit(|node: &ast::EnumVariant| Some(node.name()?.text().to_string())) .accept(&node)? } } #[cfg(test)] mod tests { use ra_syntax::TextRange; use crate::mock_analysis::{single_file_with_position, single_file_with_range, analysis_and_position}; fn trim_markup(s: &str) -> &str { s.trim_start_matches("```rust\n").trim_end_matches("\n```") } fn trim_markup_opt(s: Option<&str>) -> Option<&str> { s.map(trim_markup) } fn check_hover_result(fixture: &str, expected: &[&str]) { let (analysis, position) = analysis_and_position(fixture); let hover = analysis.hover(position).unwrap().unwrap(); for (markup, expected) in hover.info.results().iter().zip(expected.iter().chain(std::iter::repeat(&""))) { assert_eq!(trim_markup(&markup), *expected); } assert_eq!(hover.info.len(), expected.len()); } #[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!(trim_markup_opt(hover.info.first()), Some("u32")); } #[test] fn hover_shows_fn_signature() { // Single file with result check_hover_result( r#" //- /main.rs pub fn foo() -> u32 { 1 } fn main() { let foo_test = fo<|>o(); } "#, &["pub fn foo() -> u32"], ); // Multiple results check_hover_result( r#" //- /a.rs pub fn foo() -> u32 { 1 } //- /b.rs pub fn foo() -> &str { "" } //- /c.rs pub fn foo(a: u32, b: u32) {} //- /main.rs mod a; mod b; mod c; fn main() { let foo_test = fo<|>o(); } "#, &["pub fn foo() -> &str", "pub fn foo() -> u32", "pub fn foo(a: u32, b: u32)"], ); } #[test] fn hover_shows_fn_signature_with_type_params() { check_hover_result( r#" //- /main.rs pub fn foo<'a, T: AsRef>(b: &'a T) -> &'a str { } fn main() { let foo_test = fo<|>o(); } "#, &["pub fn foo<'a, T: AsRef>(b: &'a T) -> &'a str"], ); } #[test] fn hover_shows_fn_signature_on_fn_name() { check_hover_result( r#" //- /main.rs pub fn foo<|>(a: u32, b: u32) -> u32 {} fn main() { } "#, &["pub fn foo(a: u32, b: u32) -> u32"], ); } #[test] fn hover_shows_struct_field_info() { // Hovering over the field when instantiating check_hover_result( r#" //- /main.rs struct Foo { field_a: u32, } fn main() { let foo = Foo { field_a<|>: 0, }; } "#, &["field_a: u32"], ); // Hovering over the field in the definition check_hover_result( r#" //- /main.rs struct Foo { field_a<|>: u32, } fn main() { let foo = Foo { field_a: 0, }; } "#, &["field_a: u32"], ); } #[test] fn hover_const_static() { check_hover_result( r#" //- /main.rs fn main() { const foo<|>: u32 = 0; } "#, &["const foo: u32"], ); check_hover_result( r#" //- /main.rs fn main() { static foo<|>: u32 = 0; } "#, &["static foo: u32"], ); } #[test] fn hover_some() { let (analysis, position) = single_file_with_position( " enum Option { Some(T) } use Option::Some; fn main() { So<|>me(12); } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("Some")); let (analysis, position) = single_file_with_position( " enum Option { Some(T) } use Option::Some; fn main() { let b<|>ar = Some(12); } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("Option")); } #[test] fn hover_enum_variant() { check_hover_result( r#" //- /main.rs enum Option { /// The None variant Non<|>e } "#, &[" None ``` The None variant " .trim()], ); check_hover_result( r#" //- /main.rs enum Option { /// The Some variant Some(T) } fn main() { let s = Option::Som<|>e(12); } "#, &[" Some ``` The Some variant " .trim()], ); } #[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!(trim_markup_opt(hover.info.first()), Some("i32")); } #[test] fn hover_for_local_variable_pat() { let (analysis, position) = single_file_with_position("fn func(fo<|>o: i32) {}"); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("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); } #[test] fn test_type_of_for_expr() { let (analysis, range) = single_file_with_range( " fn main() { let foo: usize = 1; let bar = <|>1 + foo<|>; } ", ); let type_name = analysis.type_of(range).unwrap().unwrap(); assert_eq!("usize", &type_name); } #[test] fn test_hover_infer_associated_method_result() { let (analysis, position) = single_file_with_position( " struct Thing { x: u32 } impl Thing { fn new() -> Thing { Thing { x: 0 } } } fn main() { let foo_<|>test = Thing::new(); } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("Thing")); } #[test] fn test_hover_infer_associated_method_exact() { let (analysis, position) = single_file_with_position( " struct Thing { x: u32 } impl Thing { fn new() -> Thing { Thing { x: 0 } } } fn main() { let foo_test = Thing::new<|>(); } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("fn new() -> Thing")); assert_eq!(hover.info.is_exact(), true); } #[test] fn test_hover_infer_associated_const_in_pattern() { let (analysis, position) = single_file_with_position( " struct X; impl X { const C: u32 = 1; } fn main() { match 1 { X::C<|> => {}, 2 => {}, _ => {} }; } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("const C: u32")); assert_eq!(hover.info.is_exact(), true); } #[test] fn test_hover_self() { let (analysis, position) = single_file_with_position( " struct Thing { x: u32 } impl Thing { fn new() -> Self { Self<|> { x: 0 } } } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("struct Thing")); assert_eq!(hover.info.is_exact(), true); let (analysis, position) = single_file_with_position( " struct Thing { x: u32 } impl Thing { fn new() -> Self<|> { Self { x: 0 } } } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("struct Thing")); assert_eq!(hover.info.is_exact(), true); let (analysis, position) = single_file_with_position( " enum Thing { A } impl Thing { pub fn new() -> Self<|> { Thing::A } } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("enum Thing")); assert_eq!(hover.info.is_exact(), true); let (analysis, position) = single_file_with_position( " enum Thing { A } impl Thing { pub fn thing(a: Self<|>) { } } ", ); let hover = analysis.hover(position).unwrap().unwrap(); assert_eq!(trim_markup_opt(hover.info.first()), Some("enum Thing")); assert_eq!(hover.info.is_exact(), true); } }