//! This module contains functions to suggest names for expressions, functions and other items use hir::Semantics; use ide_db::RootDatabase; use itertools::Itertools; use stdx::to_lower_snake_case; use syntax::{ ast::{self, HasName}, match_ast, AstNode, SmolStr, }; /// Trait names, that will be ignored when in `impl Trait` and `dyn Trait` const USELESS_TRAITS: &[&str] = &["Send", "Sync", "Copy", "Clone", "Eq", "PartialEq"]; /// Identifier names that won't be suggested, ever /// /// **NOTE**: they all must be snake lower case const USELESS_NAMES: &[&str] = &["new", "default", "option", "some", "none", "ok", "err", "str", "string"]; /// Generic types replaced by their first argument /// /// # Examples /// `Option` -> `Name` /// `Result` -> `User` const WRAPPER_TYPES: &[&str] = &["Box", "Option", "Result"]; /// Prefixes to strip from methods names /// /// # Examples /// `vec.as_slice()` -> `slice` /// `args.into_config()` -> `config` /// `bytes.to_vec()` -> `vec` const USELESS_METHOD_PREFIXES: &[&str] = &["into_", "as_", "to_"]; /// Useless methods that are stripped from expression /// /// # Examples /// `var.name().to_string()` -> `var.name()` const USELESS_METHODS: &[&str] = &[ "to_string", "as_str", "to_owned", "as_ref", "clone", "cloned", "expect", "expect_none", "unwrap", "unwrap_none", "unwrap_or", "unwrap_or_default", "unwrap_or_else", "unwrap_unchecked", "iter", "into_iter", "iter_mut", "into_future", ]; pub(crate) fn for_generic_parameter(ty: &ast::ImplTraitType) -> SmolStr { let c = ty .type_bound_list() .and_then(|bounds| bounds.syntax().text().char_at(0.into())) .unwrap_or('T'); c.encode_utf8(&mut [0; 4]).into() } /// Suggest name of variable for given expression /// /// **NOTE**: it is caller's responsibility to guarantee uniqueness of the name. /// I.e. it doesn't look for names in scope. /// /// # Current implementation /// /// In current implementation, the function tries to get the name from /// the following sources: /// /// * if expr is an argument to function/method, use parameter name /// * if expr is a function/method call, use function name /// * expression type name if it exists (E.g. `()`, `fn() -> ()` or `!` do not have names) /// * fallback: `var_name` /// /// It also applies heuristics to filter out less informative names /// /// Currently it sticks to the first name found. // FIXME: Microoptimize and return a `SmolStr` here. pub(crate) fn for_variable(expr: &ast::Expr, sema: &Semantics<'_, RootDatabase>) -> String { // `from_param` does not benefit from stripping // it need the largest context possible // so we check firstmost if let Some(name) = from_param(expr, sema) { return name; } let mut next_expr = Some(expr.clone()); while let Some(expr) = next_expr { let name = from_call(&expr).or_else(|| from_type(&expr, sema)).or_else(|| from_field_name(&expr)); if let Some(name) = name { return name; } match expr { ast::Expr::RefExpr(inner) => next_expr = inner.expr(), ast::Expr::BoxExpr(inner) => next_expr = inner.expr(), ast::Expr::AwaitExpr(inner) => next_expr = inner.expr(), // ast::Expr::BlockExpr(block) => expr = block.tail_expr(), ast::Expr::CastExpr(inner) => next_expr = inner.expr(), ast::Expr::MethodCallExpr(method) if is_useless_method(&method) => { next_expr = method.receiver(); } ast::Expr::ParenExpr(inner) => next_expr = inner.expr(), ast::Expr::TryExpr(inner) => next_expr = inner.expr(), ast::Expr::PrefixExpr(prefix) if prefix.op_kind() == Some(ast::UnaryOp::Deref) => { next_expr = prefix.expr() } _ => break, } } "var_name".to_string() } fn normalize(name: &str) -> Option { let name = to_lower_snake_case(name); if USELESS_NAMES.contains(&name.as_str()) { return None; } if !is_valid_name(&name) { return None; } Some(name) } fn is_valid_name(name: &str) -> bool { match ide_db::syntax_helpers::LexedStr::single_token(name) { Some((syntax::SyntaxKind::IDENT, _error)) => true, _ => false, } } fn is_useless_method(method: &ast::MethodCallExpr) -> bool { let ident = method.name_ref().and_then(|it| it.ident_token()); match ident { Some(ident) => USELESS_METHODS.contains(&ident.text()), None => false, } } fn from_call(expr: &ast::Expr) -> Option { from_func_call(expr).or_else(|| from_method_call(expr)) } fn from_func_call(expr: &ast::Expr) -> Option { let call = match expr { ast::Expr::CallExpr(call) => call, _ => return None, }; let func = match call.expr()? { ast::Expr::PathExpr(path) => path, _ => return None, }; let ident = func.path()?.segment()?.name_ref()?.ident_token()?; normalize(ident.text()) } fn from_method_call(expr: &ast::Expr) -> Option { let method = match expr { ast::Expr::MethodCallExpr(call) => call, _ => return None, }; let ident = method.name_ref()?.ident_token()?; let mut name = ident.text(); if USELESS_METHODS.contains(&name) { return None; } for prefix in USELESS_METHOD_PREFIXES { if let Some(suffix) = name.strip_prefix(prefix) { name = suffix; break; } } normalize(name) } fn from_param(expr: &ast::Expr, sema: &Semantics<'_, RootDatabase>) -> Option { let arg_list = expr.syntax().parent().and_then(ast::ArgList::cast)?; let args_parent = arg_list.syntax().parent()?; let func = match_ast! { match args_parent { ast::CallExpr(call) => { let func = call.expr()?; let func_ty = sema.type_of_expr(&func)?.adjusted(); func_ty.as_callable(sema.db)? }, ast::MethodCallExpr(method) => sema.resolve_method_call_as_callable(&method)?, _ => return None, } }; let (idx, _) = arg_list.args().find_position(|it| it == expr).unwrap(); let (pat, _) = func.params(sema.db).into_iter().nth(idx)?; let pat = match pat? { either::Either::Right(pat) => pat, _ => return None, }; let name = var_name_from_pat(&pat)?; normalize(&name.to_string()) } fn var_name_from_pat(pat: &ast::Pat) -> Option { match pat { ast::Pat::IdentPat(var) => var.name(), ast::Pat::RefPat(ref_pat) => var_name_from_pat(&ref_pat.pat()?), ast::Pat::BoxPat(box_pat) => var_name_from_pat(&box_pat.pat()?), _ => None, } } fn from_type(expr: &ast::Expr, sema: &Semantics<'_, RootDatabase>) -> Option { let ty = sema.type_of_expr(expr)?.adjusted(); let ty = ty.remove_ref().unwrap_or(ty); name_of_type(&ty, sema.db) } fn name_of_type(ty: &hir::Type, db: &RootDatabase) -> Option { let name = if let Some(adt) = ty.as_adt() { let name = adt.name(db).to_string(); if WRAPPER_TYPES.contains(&name.as_str()) { let inner_ty = ty.type_arguments().next()?; return name_of_type(&inner_ty, db); } name } else if let Some(trait_) = ty.as_dyn_trait() { trait_name(&trait_, db)? } else if let Some(traits) = ty.as_impl_traits(db) { let mut iter = traits.filter_map(|t| trait_name(&t, db)); let name = iter.next()?; if iter.next().is_some() { return None; } name } else { return None; }; normalize(&name) } fn trait_name(trait_: &hir::Trait, db: &RootDatabase) -> Option { let name = trait_.name(db).to_string(); if USELESS_TRAITS.contains(&name.as_str()) { return None; } Some(name) } fn from_field_name(expr: &ast::Expr) -> Option { let field = match expr { ast::Expr::FieldExpr(field) => field, _ => return None, }; let ident = field.name_ref()?.ident_token()?; normalize(ident.text()) } #[cfg(test)] mod tests { use ide_db::base_db::{fixture::WithFixture, FileRange}; use super::*; #[track_caller] fn check(ra_fixture: &str, expected: &str) { let (db, file_id, range_or_offset) = RootDatabase::with_range_or_offset(ra_fixture); let frange = FileRange { file_id, range: range_or_offset.into() }; let sema = Semantics::new(&db); let source_file = sema.parse(frange.file_id); let element = source_file.syntax().covering_element(frange.range); let expr = element.ancestors().find_map(ast::Expr::cast).expect("selection is not an expression"); assert_eq!( expr.syntax().text_range(), frange.range, "selection is not an expression(yet contained in one)" ); let name = for_variable(&expr, &sema); assert_eq!(&name, expected); } #[test] fn no_args() { check(r#"fn foo() { $0bar()$0 }"#, "bar"); check(r#"fn foo() { $0bar.frobnicate()$0 }"#, "frobnicate"); } #[test] fn single_arg() { check(r#"fn foo() { $0bar(1)$0 }"#, "bar"); } #[test] fn many_args() { check(r#"fn foo() { $0bar(1, 2, 3)$0 }"#, "bar"); } #[test] fn path() { check(r#"fn foo() { $0i32::bar(1, 2, 3)$0 }"#, "bar"); } #[test] fn generic_params() { check(r#"fn foo() { $0bar::(1, 2, 3)$0 }"#, "bar"); check(r#"fn foo() { $0bar.frobnicate::()$0 }"#, "frobnicate"); } #[test] fn to_name() { check( r#" struct Args; struct Config; impl Args { fn to_config(&self) -> Config {} } fn foo() { $0Args.to_config()$0; } "#, "config", ); } #[test] fn plain_func() { check( r#" fn bar(n: i32, m: u32); fn foo() { bar($01$0, 2) } "#, "n", ); } #[test] fn mut_param() { check( r#" fn bar(mut n: i32, m: u32); fn foo() { bar($01$0, 2) } "#, "n", ); } #[test] fn func_does_not_exist() { check(r#"fn foo() { bar($01$0, 2) }"#, "var_name"); } #[test] fn unnamed_param() { check( r#" fn bar(_: i32, m: u32); fn foo() { bar($01$0, 2) } "#, "var_name", ); } #[test] fn tuple_pat() { check( r#" fn bar((n, k): (i32, i32), m: u32); fn foo() { bar($0(1, 2)$0, 3) } "#, "var_name", ); } #[test] fn ref_pat() { check( r#" fn bar(&n: &i32, m: u32); fn foo() { bar($0&1$0, 3) } "#, "n", ); } #[test] fn box_pat() { check( r#" fn bar(box n: &i32, m: u32); fn foo() { bar($01$0, 3) } "#, "n", ); } #[test] fn param_out_of_index() { check( r#" fn bar(n: i32, m: u32); fn foo() { bar(1, 2, $03$0) } "#, "var_name", ); } #[test] fn generic_param_resolved() { check( r#" fn bar(n: T, m: u32); fn foo() { bar($01$0, 2) } "#, "n", ); } #[test] fn generic_param_unresolved() { check( r#" fn bar(n: T, m: u32); fn foo(x: T) { bar($0x$0, 2) } "#, "n", ); } #[test] fn method() { check( r#" struct S; impl S { fn bar(&self, n: i32, m: u32); } fn foo() { S.bar($01$0, 2) } "#, "n", ); } #[test] fn method_on_impl_trait() { check( r#" struct S; trait T { fn bar(&self, n: i32, m: u32); } impl T for S { fn bar(&self, n: i32, m: u32); } fn foo() { S.bar($01$0, 2) } "#, "n", ); } #[test] fn method_ufcs() { check( r#" struct S; impl S { fn bar(&self, n: i32, m: u32); } fn foo() { S::bar(&S, $01$0, 2) } "#, "n", ); } #[test] fn method_self() { check( r#" struct S; impl S { fn bar(&self, n: i32, m: u32); } fn foo() { S::bar($0&S$0, 1, 2) } "#, "s", ); } #[test] fn method_self_named() { check( r#" struct S; impl S { fn bar(strukt: &Self, n: i32, m: u32); } fn foo() { S::bar($0&S$0, 1, 2) } "#, "strukt", ); } #[test] fn i32() { check(r#"fn foo() { let _: i32 = $01$0; }"#, "var_name"); } #[test] fn u64() { check(r#"fn foo() { let _: u64 = $01$0; }"#, "var_name"); } #[test] fn bool() { check(r#"fn foo() { let _: bool = $0true$0; }"#, "var_name"); } #[test] fn struct_unit() { check( r#" struct Seed; fn foo() { let _ = $0Seed$0; } "#, "seed", ); } #[test] fn struct_unit_to_snake() { check( r#" struct SeedState; fn foo() { let _ = $0SeedState$0; } "#, "seed_state", ); } #[test] fn struct_single_arg() { check( r#" struct Seed(u32); fn foo() { let _ = $0Seed(0)$0; } "#, "seed", ); } #[test] fn struct_with_fields() { check( r#" struct Seed { value: u32 } fn foo() { let _ = $0Seed { value: 0 }$0; } "#, "seed", ); } #[test] fn enum_() { check( r#" enum Kind { A, B } fn foo() { let _ = $0Kind::A$0; } "#, "kind", ); } #[test] fn enum_generic_resolved() { check( r#" enum Kind { A { x: T }, B } fn foo() { let _ = $0Kind::A { x:1 }$0; } "#, "kind", ); } #[test] fn enum_generic_unresolved() { check( r#" enum Kind { A { x: T }, B } fn foo(x: T) { let _ = $0Kind::A { x }$0; } "#, "kind", ); } #[test] fn dyn_trait() { check( r#" trait DynHandler {} fn bar() -> dyn DynHandler {} fn foo() { $0(bar())$0; } "#, "dyn_handler", ); } #[test] fn impl_trait() { check( r#" trait StaticHandler {} fn bar() -> impl StaticHandler {} fn foo() { $0(bar())$0; } "#, "static_handler", ); } #[test] fn impl_trait_plus_clone() { check( r#" trait StaticHandler {} trait Clone {} fn bar() -> impl StaticHandler + Clone {} fn foo() { $0(bar())$0; } "#, "static_handler", ); } #[test] fn impl_trait_plus_lifetime() { check( r#" trait StaticHandler {} trait Clone {} fn bar<'a>(&'a i32) -> impl StaticHandler + 'a {} fn foo() { $0(bar(&1))$0; } "#, "static_handler", ); } #[test] fn impl_trait_plus_trait() { check( r#" trait Handler {} trait StaticHandler {} fn bar() -> impl StaticHandler + Handler {} fn foo() { $0(bar())$0; } "#, "bar", ); } #[test] fn ref_value() { check( r#" struct Seed; fn bar() -> &Seed {} fn foo() { $0(bar())$0; } "#, "seed", ); } #[test] fn box_value() { check( r#" struct Box(*const T); struct Seed; fn bar() -> Box {} fn foo() { $0(bar())$0; } "#, "seed", ); } #[test] fn box_generic() { check( r#" struct Box(*const T); fn bar() -> Box {} fn foo() { $0(bar::())$0; } "#, "bar", ); } #[test] fn option_value() { check( r#" enum Option { Some(T) } struct Seed; fn bar() -> Option {} fn foo() { $0(bar())$0; } "#, "seed", ); } #[test] fn result_value() { check( r#" enum Result { Ok(T), Err(E) } struct Seed; struct Error; fn bar() -> Result {} fn foo() { $0(bar())$0; } "#, "seed", ); } #[test] fn ref_call() { check( r#" fn foo() { $0&bar(1, 3)$0 } "#, "bar", ); } #[test] fn name_to_string() { check( r#" fn foo() { $0function.name().to_string()$0 } "#, "name", ); } #[test] fn nested_useless_method() { check( r#" fn foo() { $0function.name().as_ref().unwrap().to_string()$0 } "#, "name", ); } #[test] fn struct_field_name() { check( r#" struct S { some_field: T; } fn foo(some_struct: S) { $0some_struct.some_field$0 } "#, "some_field", ); } }