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fuchsia / third_party / github.com / rust-lang / rust-analyzer / f8fdf544e4a857baf6bbfb6b41909c67b22f11a6 / . / crates / ide-assists / src / utils.rs
blob: 20e0302b57d705dd1c2a1268fa74eb8f9ad1f467 [file] [log] [blame]
//! Assorted functions shared by several assists.
use std::slice;
pub(crate) use gen_trait_fn_body::gen_trait_fn_body;
use hir::{
DisplayTarget, HasAttrs as HirHasAttrs, HirDisplay, InFile, ModuleDef, PathResolution,
Semantics,
db::{ExpandDatabase, HirDatabase},
};
use ide_db::{
RootDatabase,
assists::ExprFillDefaultMode,
famous_defs::FamousDefs,
path_transform::PathTransform,
syntax_helpers::{node_ext::preorder_expr, prettify_macro_expansion},
};
use stdx::format_to;
use syntax::{
AstNode, AstToken, Direction, NodeOrToken, SourceFile,
SyntaxKind::*,
SyntaxNode, SyntaxToken, T, TextRange, TextSize, WalkEvent,
ast::{
self, HasArgList, HasAttrs, HasGenericParams, HasName, HasTypeBounds, Whitespace,
edit::{AstNodeEdit, IndentLevel},
edit_in_place::AttrsOwnerEdit,
make,
syntax_factory::SyntaxFactory,
},
syntax_editor::{Removable, SyntaxEditor},
};
use crate::{
AssistConfig,
assist_context::{AssistContext, SourceChangeBuilder},
};
mod gen_trait_fn_body;
pub(crate) mod ref_field_expr;
pub(crate) fn unwrap_trivial_block(block_expr: ast::BlockExpr) -> ast::Expr {
extract_trivial_expression(&block_expr)
.filter(|expr| !expr.syntax().text().contains_char('\n'))
.unwrap_or_else(|| block_expr.into())
}
pub fn extract_trivial_expression(block_expr: &ast::BlockExpr) -> Option<ast::Expr> {
if block_expr.modifier().is_some() {
return None;
}
let stmt_list = block_expr.stmt_list()?;
let has_anything_else = |thing: &SyntaxNode| -> bool {
let mut non_trivial_children =
stmt_list.syntax().children_with_tokens().filter(|it| match it.kind() {
WHITESPACE | T!['{'] | T!['}'] => false,
_ => it.as_node() != Some(thing),
});
non_trivial_children.next().is_some()
};
if let Some(expr) = stmt_list.tail_expr() {
if has_anything_else(expr.syntax()) {
return None;
}
return Some(expr);
}
// Unwrap `{ continue; }`
let stmt = stmt_list.statements().next()?;
if let ast::Stmt::ExprStmt(expr_stmt) = stmt {
if has_anything_else(expr_stmt.syntax()) {
return None;
}
let expr = expr_stmt.expr()?;
if matches!(expr.syntax().kind(), CONTINUE_EXPR | BREAK_EXPR | RETURN_EXPR) {
return Some(expr);
}
}
None
}
/// This is a method with a heuristics to support test methods annotated with custom test annotations, such as
/// `#[test_case(...)]`, `#[tokio::test]` and similar.
/// Also a regular `#[test]` annotation is supported.
///
/// It may produce false positives, for example, `#[wasm_bindgen_test]` requires a different command to run the test,
/// but it's better than not to have the runnables for the tests at all.
pub fn test_related_attribute_syn(fn_def: &ast::Fn) -> Option<ast::Attr> {
fn_def.attrs().find_map(|attr| {
let path = attr.path()?;
let text = path.syntax().text().to_string();
if text.starts_with("test") || text.ends_with("test") { Some(attr) } else { None }
})
}
pub fn has_test_related_attribute(attrs: &hir::AttrsWithOwner) -> bool {
attrs.iter().any(|attr| {
let path = attr.path();
(|| {
Some(
path.segments().first()?.as_str().starts_with("test")
|| path.segments().last()?.as_str().ends_with("test"),
)
})()
.unwrap_or_default()
})
}
#[derive(Clone, Copy, PartialEq)]
pub enum IgnoreAssocItems {
DocHiddenAttrPresent,
No,
}
#[derive(Copy, Clone, PartialEq)]
pub enum DefaultMethods {
Only,
No,
}
pub fn filter_assoc_items(
sema: &Semantics<'_, RootDatabase>,
items: &[hir::AssocItem],
default_methods: DefaultMethods,
ignore_items: IgnoreAssocItems,
) -> Vec<InFile<ast::AssocItem>> {
return items
.iter()
.copied()
.filter(|assoc_item| {
if ignore_items == IgnoreAssocItems::DocHiddenAttrPresent
&& assoc_item.attrs(sema.db).has_doc_hidden()
{
if let hir::AssocItem::Function(f) = assoc_item
&& !f.has_body(sema.db)
{
return true;
}
return false;
}
true
})
// Note: This throws away items with no source.
.filter_map(|assoc_item| {
let item = match assoc_item {
hir::AssocItem::Function(it) => sema.source(it)?.map(ast::AssocItem::Fn),
hir::AssocItem::TypeAlias(it) => sema.source(it)?.map(ast::AssocItem::TypeAlias),
hir::AssocItem::Const(it) => sema.source(it)?.map(ast::AssocItem::Const),
};
Some(item)
})
.filter(has_def_name)
.filter(|it| match &it.value {
ast::AssocItem::Fn(def) => matches!(
(default_methods, def.body()),
(DefaultMethods::Only, Some(_)) | (DefaultMethods::No, None)
),
ast::AssocItem::Const(def) => matches!(
(default_methods, def.body()),
(DefaultMethods::Only, Some(_)) | (DefaultMethods::No, None)
),
_ => default_methods == DefaultMethods::No,
})
.collect();
fn has_def_name(item: &InFile<ast::AssocItem>) -> bool {
match &item.value {
ast::AssocItem::Fn(def) => def.name(),
ast::AssocItem::TypeAlias(def) => def.name(),
ast::AssocItem::Const(def) => def.name(),
ast::AssocItem::MacroCall(_) => None,
}
.is_some()
}
}
/// Given `original_items` retrieved from the trait definition (usually by
/// [`filter_assoc_items()`]), clones each item for update and applies path transformation to it,
/// then inserts into `impl_`. Returns the modified `impl_` and the first associated item that got
/// inserted.
#[must_use]
pub fn add_trait_assoc_items_to_impl(
sema: &Semantics<'_, RootDatabase>,
config: &AssistConfig,
original_items: &[InFile<ast::AssocItem>],
trait_: hir::Trait,
impl_: &ast::Impl,
target_scope: &hir::SemanticsScope<'_>,
) -> Vec<ast::AssocItem> {
let new_indent_level = IndentLevel::from_node(impl_.syntax()) + 1;
original_items
.iter()
.map(|InFile { file_id, value: original_item }| {
let mut cloned_item = {
if let Some(macro_file) = file_id.macro_file() {
let span_map = sema.db.expansion_span_map(macro_file);
let item_prettified = prettify_macro_expansion(
sema.db,
original_item.syntax().clone(),
&span_map,
target_scope.krate().into(),
);
if let Some(formatted) = ast::AssocItem::cast(item_prettified) {
return formatted;
} else {
stdx::never!("formatted `AssocItem` could not be cast back to `AssocItem`");
}
}
original_item
}
.reset_indent();
if let Some(source_scope) = sema.scope(original_item.syntax()) {
// FIXME: Paths in nested macros are not handled well. See
// `add_missing_impl_members::paths_in_nested_macro_should_get_transformed` test.
let transform =
PathTransform::trait_impl(target_scope, &source_scope, trait_, impl_.clone());
cloned_item = ast::AssocItem::cast(transform.apply(cloned_item.syntax())).unwrap();
}
cloned_item.remove_attrs_and_docs();
cloned_item
})
.filter_map(|item| match item {
ast::AssocItem::Fn(fn_) if fn_.body().is_none() => {
let fn_ = fn_.clone_subtree();
let new_body = &make::block_expr(
None,
Some(match config.expr_fill_default {
ExprFillDefaultMode::Todo => make::ext::expr_todo(),
ExprFillDefaultMode::Underscore => make::ext::expr_underscore(),
ExprFillDefaultMode::Default => make::ext::expr_todo(),
}),
);
let new_body = AstNodeEdit::indent(new_body, IndentLevel::single());
let mut fn_editor = SyntaxEditor::new(fn_.syntax().clone());
fn_.replace_or_insert_body(&mut fn_editor, new_body);
let new_fn_ = fn_editor.finish().new_root().clone();
ast::AssocItem::cast(new_fn_)
}
ast::AssocItem::TypeAlias(type_alias) => {
let type_alias = type_alias.clone_subtree();
if let Some(type_bound_list) = type_alias.type_bound_list() {
let mut type_alias_editor = SyntaxEditor::new(type_alias.syntax().clone());
type_bound_list.remove(&mut type_alias_editor);
let type_alias = type_alias_editor.finish().new_root().clone();
ast::AssocItem::cast(type_alias)
} else {
Some(ast::AssocItem::TypeAlias(type_alias))
}
}
item => Some(item),
})
.map(|item| AstNodeEdit::indent(&item, new_indent_level))
.collect()
}
pub(crate) fn vis_offset(node: &SyntaxNode) -> TextSize {
node.children_with_tokens()
.find(|it| !matches!(it.kind(), WHITESPACE | COMMENT | ATTR))
.map(|it| it.text_range().start())
.unwrap_or_else(|| node.text_range().start())
}
pub(crate) fn invert_boolean_expression(make: &SyntaxFactory, expr: ast::Expr) -> ast::Expr {
invert_special_case(make, &expr).unwrap_or_else(|| make.expr_prefix(T![!], expr).into())
}
// FIXME: Migrate usages of this function to the above function and remove this.
pub(crate) fn invert_boolean_expression_legacy(expr: ast::Expr) -> ast::Expr {
invert_special_case_legacy(&expr).unwrap_or_else(|| make::expr_prefix(T![!], expr).into())
}
fn invert_special_case(make: &SyntaxFactory, expr: &ast::Expr) -> Option<ast::Expr> {
match expr {
ast::Expr::BinExpr(bin) => {
let op_kind = bin.op_kind()?;
let rev_kind = match op_kind {
ast::BinaryOp::CmpOp(ast::CmpOp::Eq { negated }) => {
ast::BinaryOp::CmpOp(ast::CmpOp::Eq { negated: !negated })
}
ast::BinaryOp::CmpOp(ast::CmpOp::Ord { ordering: ast::Ordering::Less, strict }) => {
ast::BinaryOp::CmpOp(ast::CmpOp::Ord {
ordering: ast::Ordering::Greater,
strict: !strict,
})
}
ast::BinaryOp::CmpOp(ast::CmpOp::Ord {
ordering: ast::Ordering::Greater,
strict,
}) => ast::BinaryOp::CmpOp(ast::CmpOp::Ord {
ordering: ast::Ordering::Less,
strict: !strict,
}),
// Parenthesize other expressions before prefixing `!`
_ => {
return Some(
make.expr_prefix(T![!], make.expr_paren(expr.clone()).into()).into(),
);
}
};
Some(make.expr_bin(bin.lhs()?, rev_kind, bin.rhs()?).into())
}
ast::Expr::MethodCallExpr(mce) => {
let receiver = mce.receiver()?;
let method = mce.name_ref()?;
let arg_list = mce.arg_list()?;
let method = match method.text().as_str() {
"is_some" => "is_none",
"is_none" => "is_some",
"is_ok" => "is_err",
"is_err" => "is_ok",
_ => return None,
};
Some(make.expr_method_call(receiver, make.name_ref(method), arg_list).into())
}
ast::Expr::PrefixExpr(pe) if pe.op_kind()? == ast::UnaryOp::Not => match pe.expr()? {
ast::Expr::ParenExpr(parexpr) => {
parexpr.expr().map(|e| e.clone_subtree().clone_for_update())
}
_ => pe.expr().map(|e| e.clone_subtree().clone_for_update()),
},
ast::Expr::Literal(lit) => match lit.kind() {
ast::LiteralKind::Bool(b) => match b {
true => Some(ast::Expr::Literal(make.expr_literal("false"))),
false => Some(ast::Expr::Literal(make.expr_literal("true"))),
},
_ => None,
},
_ => None,
}
}
fn invert_special_case_legacy(expr: &ast::Expr) -> Option<ast::Expr> {
match expr {
ast::Expr::BinExpr(bin) => {
let bin = bin.clone_subtree();
let op_token = bin.op_token()?;
let rev_token = match op_token.kind() {
T![==] => T![!=],
T![!=] => T![==],
T![<] => T![>=],
T![<=] => T![>],
T![>] => T![<=],
T![>=] => T![<],
// Parenthesize other expressions before prefixing `!`
_ => {
return Some(
make::expr_prefix(T![!], make::expr_paren(expr.clone()).into()).into(),
);
}
};
let mut bin_editor = SyntaxEditor::new(bin.syntax().clone());
bin_editor.replace(op_token, make::token(rev_token));
ast::Expr::cast(bin_editor.finish().new_root().clone())
}
ast::Expr::MethodCallExpr(mce) => {
let receiver = mce.receiver()?;
let method = mce.name_ref()?;
let arg_list = mce.arg_list()?;
let method = match method.text().as_str() {
"is_some" => "is_none",
"is_none" => "is_some",
"is_ok" => "is_err",
"is_err" => "is_ok",
_ => return None,
};
Some(make::expr_method_call(receiver, make::name_ref(method), arg_list).into())
}
ast::Expr::PrefixExpr(pe) if pe.op_kind()? == ast::UnaryOp::Not => match pe.expr()? {
ast::Expr::ParenExpr(parexpr) => parexpr.expr(),
_ => pe.expr(),
},
ast::Expr::Literal(lit) => match lit.kind() {
ast::LiteralKind::Bool(b) => match b {
true => Some(ast::Expr::Literal(make::expr_literal("false"))),
false => Some(ast::Expr::Literal(make::expr_literal("true"))),
},
_ => None,
},
_ => None,
}
}
pub(crate) fn next_prev() -> impl Iterator<Item = Direction> {
[Direction::Next, Direction::Prev].into_iter()
}
pub(crate) fn does_pat_match_variant(pat: &ast::Pat, var: &ast::Pat) -> bool {
let first_node_text = |pat: &ast::Pat| pat.syntax().first_child().map(|node| node.text());
let pat_head = match pat {
ast::Pat::IdentPat(bind_pat) => match bind_pat.pat() {
Some(p) => first_node_text(&p),
None => return pat.syntax().text() == var.syntax().text(),
},
pat => first_node_text(pat),
};
let var_head = first_node_text(var);
pat_head == var_head
}
pub(crate) fn does_pat_variant_nested_or_literal(ctx: &AssistContext<'_>, pat: &ast::Pat) -> bool {
check_pat_variant_nested_or_literal_with_depth(ctx, pat, 0)
}
fn check_pat_variant_from_enum(ctx: &AssistContext<'_>, pat: &ast::Pat) -> bool {
ctx.sema.type_of_pat(pat).is_none_or(|ty: hir::TypeInfo<'_>| {
ty.adjusted().as_adt().is_some_and(|adt| matches!(adt, hir::Adt::Enum(_)))
})
}
fn check_pat_variant_nested_or_literal_with_depth(
ctx: &AssistContext<'_>,
pat: &ast::Pat,
depth_after_refutable: usize,
) -> bool {
if depth_after_refutable > 1 {
return true;
}
match pat {
ast::Pat::RestPat(_) | ast::Pat::WildcardPat(_) | ast::Pat::RefPat(_) => false,
ast::Pat::LiteralPat(_)
| ast::Pat::RangePat(_)
| ast::Pat::MacroPat(_)
| ast::Pat::PathPat(_)
| ast::Pat::BoxPat(_)
| ast::Pat::ConstBlockPat(_) => true,
ast::Pat::IdentPat(ident_pat) => ident_pat.pat().is_some_and(|pat| {
check_pat_variant_nested_or_literal_with_depth(ctx, &pat, depth_after_refutable)
}),
ast::Pat::ParenPat(paren_pat) => paren_pat.pat().is_none_or(|pat| {
check_pat_variant_nested_or_literal_with_depth(ctx, &pat, depth_after_refutable)
}),
ast::Pat::TuplePat(tuple_pat) => tuple_pat.fields().any(|pat| {
check_pat_variant_nested_or_literal_with_depth(ctx, &pat, depth_after_refutable)
}),
ast::Pat::RecordPat(record_pat) => {
let adjusted_next_depth =
depth_after_refutable + if check_pat_variant_from_enum(ctx, pat) { 1 } else { 0 };
record_pat.record_pat_field_list().is_none_or(|pat| {
pat.fields().any(|pat| {
pat.pat().is_none_or(|pat| {
check_pat_variant_nested_or_literal_with_depth(
ctx,
&pat,
adjusted_next_depth,
)
})
})
})
}
ast::Pat::OrPat(or_pat) => or_pat.pats().any(|pat| {
check_pat_variant_nested_or_literal_with_depth(ctx, &pat, depth_after_refutable)
}),
ast::Pat::TupleStructPat(tuple_struct_pat) => {
let adjusted_next_depth =
depth_after_refutable + if check_pat_variant_from_enum(ctx, pat) { 1 } else { 0 };
tuple_struct_pat.fields().any(|pat| {
check_pat_variant_nested_or_literal_with_depth(ctx, &pat, adjusted_next_depth)
})
}
ast::Pat::SlicePat(slice_pat) => {
let mut pats = slice_pat.pats();
pats.next()
.is_none_or(|pat| !matches!(pat, ast::Pat::RestPat(_)) || pats.next().is_some())
}
}
}
// Uses a syntax-driven approach to find any impl blocks for the struct that
// exist within the module/file
//
// Returns `None` if we've found an existing fn
//
// FIXME: change the new fn checking to a more semantic approach when that's more
// viable (e.g. we process proc macros, etc)
// FIXME: this partially overlaps with `find_impl_block_*`
/// `find_struct_impl` looks for impl of a struct, but this also has additional feature
/// where it takes a list of function names and check if they exist inside impl_, if
/// even one match is found, it returns None.
///
/// That means this function can have 3 potential return values:
/// - `None`: an impl exists, but one of the function names within the impl matches one of the provided names.
/// - `Some(None)`: no impl exists.
/// - `Some(Some(_))`: an impl exists, with no matching function names.
pub(crate) fn find_struct_impl(
ctx: &AssistContext<'_>,
adt: &ast::Adt,
names: &[String],
) -> Option<Option<ast::Impl>> {
let db = ctx.db();
let module = adt.syntax().parent()?;
let struct_def = ctx.sema.to_def(adt)?;
let block = module.descendants().filter_map(ast::Impl::cast).find_map(|impl_blk| {
let blk = ctx.sema.to_def(&impl_blk)?;
// FIXME: handle e.g. `struct S<T>; impl<U> S<U> {}`
// (we currently use the wrong type parameter)
// also we wouldn't want to use e.g. `impl S<u32>`
let same_ty = match blk.self_ty(db).as_adt() {
Some(def) => def == struct_def,
None => false,
};
let not_trait_impl = blk.trait_(db).is_none();
if !(same_ty && not_trait_impl) { None } else { Some(impl_blk) }
});
if let Some(ref impl_blk) = block
&& has_any_fn(impl_blk, names)
{
return None;
}
Some(block)
}
fn has_any_fn(imp: &ast::Impl, names: &[String]) -> bool {
if let Some(il) = imp.assoc_item_list() {
for item in il.assoc_items() {
if let ast::AssocItem::Fn(f) = item
&& let Some(name) = f.name()
&& names.iter().any(|n| n.eq_ignore_ascii_case(&name.text()))
{
return true;
}
}
}
false
}
/// Find the end of the `impl` block for the given `ast::Impl`.
//
// FIXME: this partially overlaps with `find_struct_impl`
pub(crate) fn find_impl_block_end(impl_def: ast::Impl, buf: &mut String) -> Option<TextSize> {
buf.push('\n');
let end = impl_def
.assoc_item_list()
.and_then(|it| it.r_curly_token())?
.prev_sibling_or_token()?
.text_range()
.end();
Some(end)
}
/// Generates the surrounding `impl Type { <code> }` including type and lifetime
/// parameters.
// FIXME: migrate remaining uses to `generate_impl`
pub(crate) fn generate_impl_text(adt: &ast::Adt, code: &str) -> String {
generate_impl_text_inner(adt, None, true, code)
}
/// Generates the surrounding `impl <trait> for Type { <code> }` including type
/// and lifetime parameters, with `<trait>` appended to `impl`'s generic parameters' bounds.
///
/// This is useful for traits like `PartialEq`, since `impl<T> PartialEq for U<T>` often requires `T: PartialEq`.
// FIXME: migrate remaining uses to `generate_trait_impl`
#[allow(dead_code)]
pub(crate) fn generate_trait_impl_text(adt: &ast::Adt, trait_text: &str, code: &str) -> String {
generate_impl_text_inner(adt, Some(trait_text), true, code)
}
/// Generates the surrounding `impl <trait> for Type { <code> }` including type
/// and lifetime parameters, with `impl`'s generic parameters' bounds kept as-is.
///
/// This is useful for traits like `From<T>`, since `impl<T> From<T> for U<T>` doesn't require `T: From<T>`.
// FIXME: migrate remaining uses to `generate_trait_impl_intransitive`
pub(crate) fn generate_trait_impl_text_intransitive(
adt: &ast::Adt,
trait_text: &str,
code: &str,
) -> String {
generate_impl_text_inner(adt, Some(trait_text), false, code)
}
fn generate_impl_text_inner(
adt: &ast::Adt,
trait_text: Option<&str>,
trait_is_transitive: bool,
code: &str,
) -> String {
// Ensure lifetime params are before type & const params
let generic_params = adt.generic_param_list().map(|generic_params| {
let lifetime_params =
generic_params.lifetime_params().map(ast::GenericParam::LifetimeParam);
let ty_or_const_params = generic_params.type_or_const_params().filter_map(|param| {
let param = match param {
ast::TypeOrConstParam::Type(param) => {
// remove defaults since they can't be specified in impls
let mut bounds =
param.type_bound_list().map_or_else(Vec::new, |it| it.bounds().collect());
if let Some(trait_) = trait_text {
// Add the current trait to `bounds` if the trait is transitive,
// meaning `impl<T> Trait for U<T>` requires `T: Trait`.
if trait_is_transitive {
bounds.push(make::type_bound_text(trait_));
}
};
// `{ty_param}: {bounds}`
let param = make::type_param(param.name()?, make::type_bound_list(bounds));
ast::GenericParam::TypeParam(param)
}
ast::TypeOrConstParam::Const(param) => {
// remove defaults since they can't be specified in impls
let param = make::const_param(param.name()?, param.ty()?);
ast::GenericParam::ConstParam(param)
}
};
Some(param)
});
make::generic_param_list(itertools::chain(lifetime_params, ty_or_const_params))
});
// FIXME: use syntax::make & mutable AST apis instead
// `trait_text` and `code` can't be opaque blobs of text
let mut buf = String::with_capacity(code.len());
// Copy any cfg attrs from the original adt
buf.push_str("\n\n");
let cfg_attrs = adt
.attrs()
.filter(|attr| attr.as_simple_call().map(|(name, _arg)| name == "cfg").unwrap_or(false));
cfg_attrs.for_each(|attr| buf.push_str(&format!("{attr}\n")));
// `impl{generic_params} {trait_text} for {name}{generic_params.to_generic_args()}`
buf.push_str("impl");
if let Some(generic_params) = &generic_params {
format_to!(buf, "{generic_params}");
}
buf.push(' ');
if let Some(trait_text) = trait_text {
buf.push_str(trait_text);
buf.push_str(" for ");
}
buf.push_str(&adt.name().unwrap().text());
if let Some(generic_params) = generic_params {
format_to!(buf, "{}", generic_params.to_generic_args());
}
match adt.where_clause() {
Some(where_clause) => {
format_to!(buf, "\n{where_clause}\n{{\n{code}\n}}");
}
None => {
format_to!(buf, " {{\n{code}\n}}");
}
}
buf
}
/// Generates the corresponding `impl Type {}` including type and lifetime
/// parameters.
pub(crate) fn generate_impl_with_item(
adt: &ast::Adt,
body: Option<ast::AssocItemList>,
) -> ast::Impl {
generate_impl_inner(false, adt, None, true, body)
}
pub(crate) fn generate_impl(adt: &ast::Adt) -> ast::Impl {
generate_impl_inner(false, adt, None, true, None)
}
/// Generates the corresponding `impl <trait> for Type {}` including type
/// and lifetime parameters, with `<trait>` appended to `impl`'s generic parameters' bounds.
///
/// This is useful for traits like `PartialEq`, since `impl<T> PartialEq for U<T>` often requires `T: PartialEq`.
pub(crate) fn generate_trait_impl(is_unsafe: bool, adt: &ast::Adt, trait_: ast::Type) -> ast::Impl {
generate_impl_inner(is_unsafe, adt, Some(trait_), true, None)
}
/// Generates the corresponding `impl <trait> for Type {}` including type
/// and lifetime parameters, with `impl`'s generic parameters' bounds kept as-is.
///
/// This is useful for traits like `From<T>`, since `impl<T> From<T> for U<T>` doesn't require `T: From<T>`.
pub(crate) fn generate_trait_impl_intransitive(adt: &ast::Adt, trait_: ast::Type) -> ast::Impl {
generate_impl_inner(false, adt, Some(trait_), false, None)
}
fn generate_impl_inner(
is_unsafe: bool,
adt: &ast::Adt,
trait_: Option<ast::Type>,
trait_is_transitive: bool,
body: Option<ast::AssocItemList>,
) -> ast::Impl {
// Ensure lifetime params are before type & const params
let generic_params = adt.generic_param_list().map(|generic_params| {
let lifetime_params =
generic_params.lifetime_params().map(ast::GenericParam::LifetimeParam);
let ty_or_const_params = generic_params.type_or_const_params().filter_map(|param| {
let param = match param {
ast::TypeOrConstParam::Type(param) => {
// remove defaults since they can't be specified in impls
let mut bounds =
param.type_bound_list().map_or_else(Vec::new, |it| it.bounds().collect());
if let Some(trait_) = &trait_ {
// Add the current trait to `bounds` if the trait is transitive,
// meaning `impl<T> Trait for U<T>` requires `T: Trait`.
if trait_is_transitive {
bounds.push(make::type_bound(trait_.clone()));
}
};
// `{ty_param}: {bounds}`
let param = make::type_param(param.name()?, make::type_bound_list(bounds));
ast::GenericParam::TypeParam(param)
}
ast::TypeOrConstParam::Const(param) => {
// remove defaults since they can't be specified in impls
let param = make::const_param(param.name()?, param.ty()?);
ast::GenericParam::ConstParam(param)
}
};
Some(param)
});
make::generic_param_list(itertools::chain(lifetime_params, ty_or_const_params))
});
let generic_args =
generic_params.as_ref().map(|params| params.to_generic_args().clone_for_update());
let ty = make::ty_path(make::ext::ident_path(&adt.name().unwrap().text()));
let cfg_attrs =
adt.attrs().filter(|attr| attr.as_simple_call().is_some_and(|(name, _arg)| name == "cfg"));
match trait_ {
Some(trait_) => make::impl_trait(
cfg_attrs,
is_unsafe,
None,
None,
generic_params,
generic_args,
false,
trait_,
ty,
None,
adt.where_clause(),
body,
),
None => make::impl_(cfg_attrs, generic_params, generic_args, ty, adt.where_clause(), body),
}
.clone_for_update()
}
pub(crate) fn add_method_to_adt(
builder: &mut SourceChangeBuilder,
adt: &ast::Adt,
impl_def: Option<ast::Impl>,
method: &str,
) {
let mut buf = String::with_capacity(method.len() + 2);
if impl_def.is_some() {
buf.push('\n');
}
buf.push_str(method);
let start_offset = impl_def
.and_then(|impl_def| find_impl_block_end(impl_def, &mut buf))
.unwrap_or_else(|| {
buf = generate_impl_text(adt, &buf);
adt.syntax().text_range().end()
});
builder.insert(start_offset, buf);
}
#[derive(Debug)]
pub(crate) struct ReferenceConversion<'db> {
conversion: ReferenceConversionType,
ty: hir::Type<'db>,
impls_deref: bool,
}
#[derive(Debug)]
enum ReferenceConversionType {
// reference can be stripped if the type is Copy
Copy,
// &String -> &str
AsRefStr,
// &Vec<T> -> &[T]
AsRefSlice,
// &Box<T> -> &T
Dereferenced,
// &Option<T> -> Option<&T>
Option,
// &Result<T, E> -> Result<&T, &E>
Result,
}
impl<'db> ReferenceConversion<'db> {
pub(crate) fn convert_type(
&self,
db: &'db dyn HirDatabase,
display_target: DisplayTarget,
) -> ast::Type {
let ty = match self.conversion {
ReferenceConversionType::Copy => self.ty.display(db, display_target).to_string(),
ReferenceConversionType::AsRefStr => "&str".to_owned(),
ReferenceConversionType::AsRefSlice => {
let type_argument_name = self
.ty
.type_arguments()
.next()
.unwrap()
.display(db, display_target)
.to_string();
format!("&[{type_argument_name}]")
}
ReferenceConversionType::Dereferenced => {
let type_argument_name = self
.ty
.type_arguments()
.next()
.unwrap()
.display(db, display_target)
.to_string();
format!("&{type_argument_name}")
}
ReferenceConversionType::Option => {
let type_argument_name = self
.ty
.type_arguments()
.next()
.unwrap()
.display(db, display_target)
.to_string();
format!("Option<&{type_argument_name}>")
}
ReferenceConversionType::Result => {
let mut type_arguments = self.ty.type_arguments();
let first_type_argument_name =
type_arguments.next().unwrap().display(db, display_target).to_string();
let second_type_argument_name =
type_arguments.next().unwrap().display(db, display_target).to_string();
format!("Result<&{first_type_argument_name}, &{second_type_argument_name}>")
}
};
make::ty(&ty)
}
pub(crate) fn getter(&self, field_name: String) -> ast::Expr {
let expr = make::expr_field(make::ext::expr_self(), &field_name);
match self.conversion {
ReferenceConversionType::Copy => expr,
ReferenceConversionType::AsRefStr
| ReferenceConversionType::AsRefSlice
| ReferenceConversionType::Dereferenced
| ReferenceConversionType::Option
| ReferenceConversionType::Result => {
if self.impls_deref {
make::expr_ref(expr, false)
} else {
make::expr_method_call(expr, make::name_ref("as_ref"), make::arg_list([]))
.into()
}
}
}
}
}
// FIXME: It should return a new hir::Type, but currently constructing new types is too cumbersome
// and all users of this function operate on string type names, so they can do the conversion
// itself themselves.
pub(crate) fn convert_reference_type<'db>(
ty: hir::Type<'db>,
db: &'db RootDatabase,
famous_defs: &FamousDefs<'_, 'db>,
) -> Option<ReferenceConversion<'db>> {
handle_copy(&ty, db)
.or_else(|| handle_as_ref_str(&ty, db, famous_defs))
.or_else(|| handle_as_ref_slice(&ty, db, famous_defs))
.or_else(|| handle_dereferenced(&ty, db, famous_defs))
.or_else(|| handle_option_as_ref(&ty, db, famous_defs))
.or_else(|| handle_result_as_ref(&ty, db, famous_defs))
.map(|(conversion, impls_deref)| ReferenceConversion { ty, conversion, impls_deref })
}
fn could_deref_to_target(ty: &hir::Type<'_>, target: &hir::Type<'_>, db: &dyn HirDatabase) -> bool {
let ty_ref = ty.add_reference(hir::Mutability::Shared);
let target_ref = target.add_reference(hir::Mutability::Shared);
ty_ref.could_coerce_to(db, &target_ref)
}
fn handle_copy(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
) -> Option<(ReferenceConversionType, bool)> {
ty.is_copy(db).then_some((ReferenceConversionType::Copy, true))
}
fn handle_as_ref_str(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
famous_defs: &FamousDefs<'_, '_>,
) -> Option<(ReferenceConversionType, bool)> {
let str_type = hir::BuiltinType::str().ty(db);
ty.impls_trait(db, famous_defs.core_convert_AsRef()?, slice::from_ref(&str_type))
.then_some((ReferenceConversionType::AsRefStr, could_deref_to_target(ty, &str_type, db)))
}
fn handle_as_ref_slice(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
famous_defs: &FamousDefs<'_, '_>,
) -> Option<(ReferenceConversionType, bool)> {
let type_argument = ty.type_arguments().next()?;
let slice_type = hir::Type::new_slice(type_argument);
ty.impls_trait(db, famous_defs.core_convert_AsRef()?, slice::from_ref(&slice_type)).then_some((
ReferenceConversionType::AsRefSlice,
could_deref_to_target(ty, &slice_type, db),
))
}
fn handle_dereferenced(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
famous_defs: &FamousDefs<'_, '_>,
) -> Option<(ReferenceConversionType, bool)> {
let type_argument = ty.type_arguments().next()?;
ty.impls_trait(db, famous_defs.core_convert_AsRef()?, slice::from_ref(&type_argument))
.then_some((
ReferenceConversionType::Dereferenced,
could_deref_to_target(ty, &type_argument, db),
))
}
fn handle_option_as_ref(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
famous_defs: &FamousDefs<'_, '_>,
) -> Option<(ReferenceConversionType, bool)> {
if ty.as_adt() == famous_defs.core_option_Option()?.ty(db).as_adt() {
Some((ReferenceConversionType::Option, false))
} else {
None
}
}
fn handle_result_as_ref(
ty: &hir::Type<'_>,
db: &dyn HirDatabase,
famous_defs: &FamousDefs<'_, '_>,
) -> Option<(ReferenceConversionType, bool)> {
if ty.as_adt() == famous_defs.core_result_Result()?.ty(db).as_adt() {
Some((ReferenceConversionType::Result, false))
} else {
None
}
}
pub(crate) fn get_methods(items: &ast::AssocItemList) -> Vec<ast::Fn> {
items
.assoc_items()
.flat_map(|i| match i {
ast::AssocItem::Fn(f) => Some(f),
_ => None,
})
.filter(|f| f.name().is_some())
.collect()
}
/// Trim(remove leading and trailing whitespace) `initial_range` in `source_file`, return the trimmed range.
pub(crate) fn trimmed_text_range(source_file: &SourceFile, initial_range: TextRange) -> TextRange {
let mut trimmed_range = initial_range;
while source_file
.syntax()
.token_at_offset(trimmed_range.start())
.find_map(Whitespace::cast)
.is_some()
&& trimmed_range.start() < trimmed_range.end()
{
let start = trimmed_range.start() + TextSize::from(1);
trimmed_range = TextRange::new(start, trimmed_range.end());
}
while source_file
.syntax()
.token_at_offset(trimmed_range.end())
.find_map(Whitespace::cast)
.is_some()
&& trimmed_range.start() < trimmed_range.end()
{
let end = trimmed_range.end() - TextSize::from(1);
trimmed_range = TextRange::new(trimmed_range.start(), end);
}
trimmed_range
}
/// Convert a list of function params to a list of arguments that can be passed
/// into a function call.
pub(crate) fn convert_param_list_to_arg_list(list: ast::ParamList) -> ast::ArgList {
let mut args = vec![];
for param in list.params() {
if let Some(ast::Pat::IdentPat(pat)) = param.pat()
&& let Some(name) = pat.name()
{
let name = name.to_string();
let expr = make::expr_path(make::ext::ident_path(&name));
args.push(expr);
}
}
make::arg_list(args)
}
/// Calculate the number of hashes required for a raw string containing `s`
pub(crate) fn required_hashes(s: &str) -> usize {
let mut res = 0usize;
for idx in s.match_indices('"').map(|(i, _)| i) {
let (_, sub) = s.split_at(idx + 1);
let n_hashes = sub.chars().take_while(|c| *c == '#').count();
res = res.max(n_hashes + 1)
}
res
}
#[test]
fn test_required_hashes() {
assert_eq!(0, required_hashes("abc"));
assert_eq!(0, required_hashes("###"));
assert_eq!(1, required_hashes("\""));
assert_eq!(2, required_hashes("\"#abc"));
assert_eq!(0, required_hashes("#abc"));
assert_eq!(3, required_hashes("#ab\"##c"));
assert_eq!(5, required_hashes("#ab\"##\"####c"));
}
/// Calculate the string literal suffix length
pub(crate) fn string_suffix(s: &str) -> Option<&str> {
s.rfind(['"', '\'', '#']).map(|i| &s[i + 1..])
}
#[test]
fn test_string_suffix() {
assert_eq!(Some(""), string_suffix(r#""abc""#));
assert_eq!(Some(""), string_suffix(r#""""#));
assert_eq!(Some("a"), string_suffix(r#"""a"#));
assert_eq!(Some("i32"), string_suffix(r#"""i32"#));
assert_eq!(Some("i32"), string_suffix(r#"r""i32"#));
assert_eq!(Some("i32"), string_suffix(r##"r#""#i32"##));
}
/// Replaces the record expression, handling field shorthands including inside macros.
pub(crate) fn replace_record_field_expr(
ctx: &AssistContext<'_>,
edit: &mut SourceChangeBuilder,
record_field: ast::RecordExprField,
initializer: ast::Expr,
) {
if let Some(ast::Expr::PathExpr(path_expr)) = record_field.expr() {
// replace field shorthand
let file_range = ctx.sema.original_range(path_expr.syntax());
edit.insert(file_range.range.end(), format!(": {}", initializer.syntax().text()))
} else if let Some(expr) = record_field.expr() {
// just replace expr
let file_range = ctx.sema.original_range(expr.syntax());
edit.replace(file_range.range, initializer.syntax().text());
}
}
/// Creates a token tree list from a syntax node, creating the needed delimited sub token trees.
/// Assumes that the input syntax node is a valid syntax tree.
pub(crate) fn tt_from_syntax(node: SyntaxNode) -> Vec<NodeOrToken<ast::TokenTree, SyntaxToken>> {
let mut tt_stack = vec![(None, vec![])];
for element in node.descendants_with_tokens() {
let NodeOrToken::Token(token) = element else { continue };
match token.kind() {
T!['('] | T!['{'] | T!['['] => {
// Found an opening delimiter, start a new sub token tree
tt_stack.push((Some(token.kind()), vec![]));
}
T![')'] | T!['}'] | T![']'] => {
// Closing a subtree
let (delimiter, tt) = tt_stack.pop().expect("unbalanced delimiters");
let (_, parent_tt) = tt_stack
.last_mut()
.expect("parent token tree was closed before it was completed");
let closing_delimiter = delimiter.map(|it| match it {
T!['('] => T![')'],
T!['{'] => T!['}'],
T!['['] => T![']'],
_ => unreachable!(),
});
stdx::always!(
closing_delimiter == Some(token.kind()),
"mismatched opening and closing delimiters"
);
let sub_tt = make::token_tree(delimiter.expect("unbalanced delimiters"), tt);
parent_tt.push(NodeOrToken::Node(sub_tt));
}
_ => {
let (_, current_tt) = tt_stack.last_mut().expect("unmatched delimiters");
current_tt.push(NodeOrToken::Token(token))
}
}
}
tt_stack.pop().expect("parent token tree was closed before it was completed").1
}
pub fn is_body_const(sema: &Semantics<'_, RootDatabase>, expr: &ast::Expr) -> bool {
let mut is_const = true;
preorder_expr(expr, &mut |ev| {
let expr = match ev {
WalkEvent::Enter(_) if !is_const => return true,
WalkEvent::Enter(expr) => expr,
WalkEvent::Leave(_) => return false,
};
match expr {
ast::Expr::CallExpr(call) => {
if let Some(ast::Expr::PathExpr(path_expr)) = call.expr()
&& let Some(PathResolution::Def(ModuleDef::Function(func))) =
path_expr.path().and_then(|path| sema.resolve_path(&path))
{
is_const &= func.is_const(sema.db);
}
}
ast::Expr::MethodCallExpr(call) => {
is_const &=
sema.resolve_method_call(&call).map(|it| it.is_const(sema.db)).unwrap_or(true)
}
ast::Expr::ForExpr(_)
| ast::Expr::ReturnExpr(_)
| ast::Expr::TryExpr(_)
| ast::Expr::YieldExpr(_)
| ast::Expr::AwaitExpr(_) => is_const = false,
_ => (),
}
!is_const
});
is_const
}