add_explicit_type is applicable for closure parameters

This commit is contained in:
Lukas Wirth 2021-07-31 14:04:34 +02:00
parent 1f817833e7
commit 778e6e8ba8
3 changed files with 129 additions and 82 deletions

View File

@ -1,8 +1,5 @@
use hir::HirDisplay;
use syntax::{
ast::{self, AstNode, LetStmt},
TextRange,
};
use syntax::ast::{self, AstNode, LetStmt, Param};
use crate::{AssistContext, AssistId, AssistKind, Assists};
@ -22,40 +19,46 @@
// }
// ```
pub(crate) fn add_explicit_type(acc: &mut Assists, ctx: &AssistContext) -> Option<()> {
let let_stmt = ctx.find_node_at_offset::<LetStmt>()?;
let module = ctx.sema.scope(let_stmt.syntax()).module()?;
let expr = let_stmt.initializer()?;
// Must be a binding
let pat = match let_stmt.pat()? {
ast::Pat::IdentPat(bind_pat) => bind_pat,
_ => return None,
let (ascribed_ty, expr, pat) = if let Some(let_stmt) = ctx.find_node_at_offset::<LetStmt>() {
let cursor_in_range = {
let eq_range = let_stmt.eq_token()?.text_range();
ctx.offset() < eq_range.start()
};
if !cursor_in_range {
cov_mark::hit!(add_explicit_type_not_applicable_if_cursor_after_equals);
return None;
}
(let_stmt.ty(), let_stmt.initializer(), let_stmt.pat()?)
} else if let Some(param) = ctx.find_node_at_offset::<Param>() {
if param.syntax().ancestors().nth(2).and_then(ast::ClosureExpr::cast).is_none() {
cov_mark::hit!(add_explicit_type_not_applicable_in_fn_param);
return None;
}
(param.ty(), None, param.pat()?)
} else {
return None;
};
let module = ctx.sema.scope(pat.syntax()).module()?;
let pat_range = pat.syntax().text_range();
// Assist should only be applicable if cursor is between 'let' and '='
let cursor_in_range = {
let stmt_range = let_stmt.syntax().text_range();
let eq_range = let_stmt.eq_token()?.text_range();
let let_range = TextRange::new(stmt_range.start(), eq_range.start());
let_range.contains_range(ctx.frange.range)
};
if !cursor_in_range {
cov_mark::hit!(add_explicit_type_not_applicable_if_cursor_after_equals);
return None;
}
// Assist not applicable if the type has already been specified
// and it has no placeholders
let ascribed_ty = let_stmt.ty();
// Don't enable the assist if there is a type ascription without any placeholders
if let Some(ty) = &ascribed_ty {
if ty.syntax().descendants().find_map(ast::InferType::cast).is_none() {
let mut contains_infer_ty = false;
ty.walk(&mut |ty| contains_infer_ty |= matches!(ty, ast::Type::InferType(_)));
if !contains_infer_ty {
cov_mark::hit!(add_explicit_type_not_applicable_if_ty_already_specified);
return None;
}
}
// Infer type
let (ty, _) = ctx.sema.type_of_expr_with_coercion(&expr)?;
let ty = match (pat, expr) {
(ast::Pat::IdentPat(_), Some(expr)) => ctx.sema.type_of_expr_with_coercion(&expr)?.0,
(pat, _) => ctx.sema.type_of_pat(&pat)?,
};
// Unresolved or unnameable types can't be annotated
if ty.contains_unknown() || ty.is_closure() {
cov_mark::hit!(add_explicit_type_not_applicable_if_ty_not_inferred);
return None;
@ -89,7 +92,7 @@ fn add_explicit_type_target() {
}
#[test]
fn add_explicit_type_works_for_simple_expr() {
fn add_explicit_type_simple() {
check_assist(
add_explicit_type,
r#"fn f() { let a$0 = 1; }"#,
@ -98,7 +101,7 @@ fn add_explicit_type_works_for_simple_expr() {
}
#[test]
fn add_explicit_type_works_for_underscore() {
fn add_explicit_type_simple_on_infer_ty() {
check_assist(
add_explicit_type,
r#"fn f() { let a$0: _ = 1; }"#,
@ -107,19 +110,16 @@ fn add_explicit_type_works_for_underscore() {
}
#[test]
fn add_explicit_type_works_for_nested_underscore() {
fn add_explicit_type_simple_nested_infer_ty() {
check_assist(
add_explicit_type,
r#"
enum Option<T> { Some(T), None }
//- minicore: option
fn f() {
let a$0: Option<_> = Option::Some(1);
}
"#,
r#"
enum Option<T> { Some(T), None }
fn f() {
let a: Option<i32> = Option::Some(1);
}
@ -128,7 +128,7 @@ fn f() {
}
#[test]
fn add_explicit_type_works_for_macro_call() {
fn add_explicit_type_macro_call_expr() {
check_assist(
add_explicit_type,
r"macro_rules! v { () => {0u64} } fn f() { let a$0 = v!(); }",
@ -137,36 +137,24 @@ fn add_explicit_type_works_for_macro_call() {
}
#[test]
fn add_explicit_type_works_for_macro_call_recursive() {
check_assist(
add_explicit_type,
r#"macro_rules! u { () => {0u64} } macro_rules! v { () => {u!()} } fn f() { let a$0 = v!(); }"#,
r#"macro_rules! u { () => {0u64} } macro_rules! v { () => {u!()} } fn f() { let a: u64 = v!(); }"#,
);
}
#[test]
fn add_explicit_type_not_applicable_if_ty_not_inferred() {
fn add_explicit_type_not_applicable_unresolved() {
cov_mark::check!(add_explicit_type_not_applicable_if_ty_not_inferred);
check_assist_not_applicable(add_explicit_type, r#"fn f() { let a$0 = None; }"#);
}
#[test]
fn add_explicit_type_not_applicable_if_ty_already_specified() {
fn add_explicit_type_not_applicable_closure_expr() {
check_assist_not_applicable(add_explicit_type, r#"fn f() { let a$0 = || {}; }"#);
}
#[test]
fn add_explicit_type_not_applicable_ty_already_specified() {
cov_mark::check!(add_explicit_type_not_applicable_if_ty_already_specified);
check_assist_not_applicable(add_explicit_type, r#"fn f() { let a$0: i32 = 1; }"#);
}
#[test]
fn add_explicit_type_not_applicable_if_specified_ty_is_tuple() {
check_assist_not_applicable(
add_explicit_type,
r#"fn f() { let a$0: (i32, i32) = (3, 4); }"#,
);
}
#[test]
fn add_explicit_type_not_applicable_if_cursor_after_equals() {
fn add_explicit_type_not_applicable_cursor_after_equals_of_let() {
cov_mark::check!(add_explicit_type_not_applicable_if_cursor_after_equals);
check_assist_not_applicable(
add_explicit_type,
@ -174,27 +162,6 @@ fn add_explicit_type_not_applicable_if_cursor_after_equals() {
)
}
#[test]
fn add_explicit_type_not_applicable_if_cursor_before_let() {
check_assist_not_applicable(
add_explicit_type,
r#"fn f() $0{let a = match 1 {2 => 3, 3 => 5};}"#,
)
}
#[test]
fn closure_parameters_are_not_added() {
check_assist_not_applicable(
add_explicit_type,
r#"
fn main() {
let multiply_by_two$0 = |i| i * 3;
let six = multiply_by_two(2);
}
"#,
)
}
/// https://github.com/rust-analyzer/rust-analyzer/issues/2922
#[test]
fn regression_issue_2922() {
@ -276,6 +243,55 @@ fn f() {
fn f() {
let x: *const [i32] = &[3];
}
"#,
);
}
#[test]
fn add_explicit_type_not_applicable_fn_param() {
cov_mark::check!(add_explicit_type_not_applicable_in_fn_param);
check_assist_not_applicable(add_explicit_type, r#"fn f(x$0: ()) {}"#);
}
#[test]
fn add_explicit_type_ascribes_closure_param() {
check_assist(
add_explicit_type,
r#"
fn f() {
|y$0| {
let x: i32 = y;
};
}
"#,
r#"
fn f() {
|y: i32| {
let x: i32 = y;
};
}
"#,
);
}
#[test]
fn add_explicit_type_ascribes_closure_param_already_ascribed() {
check_assist(
add_explicit_type,
r#"
//- minicore: option
fn f() {
|mut y$0: Option<_>| {
y = Some(3);
};
}
"#,
r#"
fn f() {
|mut y: Option<i32>| {
y = Some(3);
};
}
"#,
);
}

View File

@ -26,7 +26,6 @@
// if y { B } else { A }
// }
// ```
pub(crate) fn invert_if(acc: &mut Assists, ctx: &AssistContext) -> Option<()> {
let if_keyword = ctx.find_token_syntax_at_offset(T![if])?;
let expr = ast::IfExpr::cast(if_keyword.parent()?)?;

View File

@ -64,13 +64,45 @@ pub fn walk(&self, cb: &mut dyn FnMut(ast::Pat)) {
WalkEvent::Enter(node) => node,
WalkEvent::Leave(_) => continue,
};
match ast::Pat::cast(node.clone()) {
Some(ast::Pat::ConstBlockPat(_)) => preorder.skip_subtree(),
let kind = node.kind();
match ast::Pat::cast(node) {
Some(pat @ ast::Pat::ConstBlockPat(_)) => {
preorder.skip_subtree();
cb(pat);
}
Some(pat) => {
cb(pat);
}
// skip const args
None if ast::GenericArg::can_cast(node.kind()) => {
None if ast::GenericArg::can_cast(kind) => {
preorder.skip_subtree();
}
None => (),
}
}
}
}
impl ast::Type {
/// Preorder walk all the type's sub types.
pub fn walk(&self, cb: &mut dyn FnMut(ast::Type)) {
let mut preorder = self.syntax().preorder();
while let Some(event) = preorder.next() {
let node = match event {
WalkEvent::Enter(node) => node,
WalkEvent::Leave(_) => continue,
};
let kind = node.kind();
match ast::Type::cast(node) {
Some(ty @ ast::Type::MacroType(_)) => {
preorder.skip_subtree();
cb(ty)
}
Some(ty) => {
cb(ty);
}
// skip const args
None if ast::ConstArg::can_cast(kind) => {
preorder.skip_subtree();
}
None => (),