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|
//! FIXME: write short doc here
use std::iter;
use hir::{Adt, HasSource, Semantics};
use ra_syntax::ast::{self, edit::IndentLevel, make, AstNode, NameOwner};
use crate::{Assist, AssistCtx, AssistId};
use ra_ide_db::RootDatabase;
// Assist: fill_match_arms
//
// Adds missing clauses to a `match` expression.
//
// ```
// enum Action { Move { distance: u32 }, Stop }
//
// fn handle(action: Action) {
// match action {
// <|>
// }
// }
// ```
// ->
// ```
// enum Action { Move { distance: u32 }, Stop }
//
// fn handle(action: Action) {
// match action {
// Action::Move { distance } => (),
// Action::Stop => (),
// }
// }
// ```
pub(crate) fn fill_match_arms(ctx: AssistCtx) -> Option<Assist> {
let match_expr = ctx.find_node_at_offset::<ast::MatchExpr>()?;
let match_arm_list = match_expr.match_arm_list()?;
// We already have some match arms, so we don't provide any assists.
// Unless if there is only one trivial match arm possibly created
// by match postfix complete. Trivial match arm is the catch all arm.
let mut existing_arms = match_arm_list.arms();
if let Some(arm) = existing_arms.next() {
if !is_trivial(&arm) || existing_arms.next().is_some() {
return None;
}
};
let expr = match_expr.expr()?;
let enum_def = resolve_enum_def(&ctx.sema, &expr)?;
let module = ctx.sema.scope(expr.syntax()).module()?;
let variants = enum_def.variants(ctx.db);
if variants.is_empty() {
return None;
}
let db = ctx.db;
ctx.add_assist(AssistId("fill_match_arms"), "Fill match arms", |edit| {
let indent_level = IndentLevel::from_node(match_arm_list.syntax());
let new_arm_list = {
let arms = variants
.into_iter()
.filter_map(|variant| build_pat(db, module, variant))
.map(|pat| make::match_arm(iter::once(pat), make::expr_unit()));
indent_level.increase_indent(make::match_arm_list(arms))
};
edit.target(match_expr.syntax().text_range());
edit.set_cursor(expr.syntax().text_range().start());
edit.replace_ast(match_arm_list, new_arm_list);
})
}
fn is_trivial(arm: &ast::MatchArm) -> bool {
match arm.pat() {
Some(ast::Pat::PlaceholderPat(..)) => true,
_ => false,
}
}
fn resolve_enum_def(sema: &Semantics<RootDatabase>, expr: &ast::Expr) -> Option<hir::Enum> {
sema.type_of_expr(&expr)?.autoderef(sema.db).find_map(|ty| match ty.as_adt() {
Some(Adt::Enum(e)) => Some(e),
_ => None,
})
}
fn build_pat(db: &RootDatabase, module: hir::Module, var: hir::EnumVariant) -> Option<ast::Pat> {
let path = crate::ast_transform::path_to_ast(module.find_use_path(db, var.into())?);
// FIXME: use HIR for this; it doesn't currently expose struct vs. tuple vs. unit variants though
let pat: ast::Pat = match var.source(db).value.kind() {
ast::StructKind::Tuple(field_list) => {
let pats =
iter::repeat(make::placeholder_pat().into()).take(field_list.fields().count());
make::tuple_struct_pat(path, pats).into()
}
ast::StructKind::Record(field_list) => {
let pats = field_list.fields().map(|f| make::bind_pat(f.name().unwrap()).into());
make::record_pat(path, pats).into()
}
ast::StructKind::Unit => make::path_pat(path),
};
Some(pat)
}
#[cfg(test)]
mod tests {
use crate::helpers::{check_assist, check_assist_target};
use super::fill_match_arms;
#[test]
fn fill_match_arms_empty_body() {
check_assist(
fill_match_arms,
r#"
enum A {
As,
Bs,
Cs(String),
Ds(String, String),
Es{ x: usize, y: usize }
}
fn main() {
let a = A::As;
match a<|> {}
}
"#,
r#"
enum A {
As,
Bs,
Cs(String),
Ds(String, String),
Es{ x: usize, y: usize }
}
fn main() {
let a = A::As;
match <|>a {
A::As => (),
A::Bs => (),
A::Cs(_) => (),
A::Ds(_, _) => (),
A::Es { x, y } => (),
}
}
"#,
);
}
#[test]
fn test_fill_match_arm_refs() {
check_assist(
fill_match_arms,
r#"
enum A {
As,
}
fn foo(a: &A) {
match a<|> {
}
}
"#,
r#"
enum A {
As,
}
fn foo(a: &A) {
match <|>a {
A::As => (),
}
}
"#,
);
check_assist(
fill_match_arms,
r#"
enum A {
Es{ x: usize, y: usize }
}
fn foo(a: &mut A) {
match a<|> {
}
}
"#,
r#"
enum A {
Es{ x: usize, y: usize }
}
fn foo(a: &mut A) {
match <|>a {
A::Es { x, y } => (),
}
}
"#,
);
}
#[test]
fn fill_match_arms_target() {
check_assist_target(
fill_match_arms,
r#"
enum E { X, Y }
fn main() {
match E::X<|> {}
}
"#,
"match E::X {}",
);
}
#[test]
fn fill_match_arms_trivial_arm() {
check_assist(
fill_match_arms,
r#"
enum E { X, Y }
fn main() {
match E::X {
<|>_ => {},
}
}
"#,
r#"
enum E { X, Y }
fn main() {
match <|>E::X {
E::X => (),
E::Y => (),
}
}
"#,
);
}
#[test]
fn fill_match_arms_qualifies_path() {
check_assist(
fill_match_arms,
r#"
mod foo { pub enum E { X, Y } }
use foo::E::X;
fn main() {
match X {
<|>
}
}
"#,
r#"
mod foo { pub enum E { X, Y } }
use foo::E::X;
fn main() {
match <|>X {
X => (),
foo::E::Y => (),
}
}
"#,
);
}
}
|