Make add_function generate functions in other modules via qualified path

This commit is contained in:
Timo Freiberg 2020-04-16 23:53:25 +02:00
parent 546f9ee7a7
commit 317fc650d5
4 changed files with 205 additions and 29 deletions

View file

@ -4,7 +4,7 @@ use ra_syntax::{
};
use crate::{Assist, AssistCtx, AssistId};
use ast::{edit::IndentLevel, ArgListOwner, CallExpr, Expr};
use ast::{edit::IndentLevel, ArgListOwner, ModuleItemOwner};
use hir::HirDisplay;
use rustc_hash::{FxHashMap, FxHashSet};
@ -38,16 +38,24 @@ pub(crate) fn add_function(ctx: AssistCtx) -> Option<Assist> {
let call = path_expr.syntax().parent().and_then(ast::CallExpr::cast)?;
let path = path_expr.path()?;
if path.qualifier().is_some() {
return None;
}
if ctx.sema.resolve_path(&path).is_some() {
// The function call already resolves, no need to add a function
return None;
}
let function_builder = FunctionBuilder::from_call(&ctx, &call)?;
let target_module = if let Some(qualifier) = path.qualifier() {
if let Some(hir::PathResolution::Def(hir::ModuleDef::Module(resolved))) =
ctx.sema.resolve_path(&qualifier)
{
Some(resolved.definition_source(ctx.sema.db).value)
} else {
return None;
}
} else {
None
};
let function_builder = FunctionBuilder::from_call(&ctx, &call, &path, target_module)?;
ctx.add_assist(AssistId("add_function"), "Add function", |edit| {
edit.target(call.syntax().text_range());
@ -66,26 +74,54 @@ struct FunctionTemplate {
}
struct FunctionBuilder {
append_fn_at: SyntaxNode,
target: GeneratedFunctionTarget,
fn_name: ast::Name,
type_params: Option<ast::TypeParamList>,
params: ast::ParamList,
}
impl FunctionBuilder {
fn from_call(ctx: &AssistCtx, call: &ast::CallExpr) -> Option<Self> {
let append_fn_at = next_space_for_fn(&call)?;
let fn_name = fn_name(&call)?;
/// Prepares a generated function that matches `call` in `generate_in`
/// (or as close to `call` as possible, if `generate_in` is `None`)
fn from_call(
ctx: &AssistCtx,
call: &ast::CallExpr,
path: &ast::Path,
generate_in: Option<hir::ModuleSource>,
) -> Option<Self> {
let target = if let Some(generate_in_module) = generate_in {
next_space_for_fn_in_module(generate_in_module)?
} else {
next_space_for_fn_after_call_site(&call)?
};
let fn_name = fn_name(&path)?;
let (type_params, params) = fn_args(ctx, &call)?;
Some(Self { append_fn_at, fn_name, type_params, params })
Some(Self { target, fn_name, type_params, params })
}
fn render(self) -> Option<FunctionTemplate> {
let placeholder_expr = ast::make::expr_todo();
let fn_body = ast::make::block_expr(vec![], Some(placeholder_expr));
let fn_def = ast::make::fn_def(self.fn_name, self.type_params, self.params, fn_body);
let fn_def = ast::make::add_newlines(2, fn_def);
let fn_def = IndentLevel::from_node(&self.append_fn_at).increase_indent(fn_def);
let insert_offset = self.append_fn_at.text_range().end();
let (fn_def, insert_offset) = match self.target {
GeneratedFunctionTarget::BehindItem(it) => {
let with_leading_blank_line = ast::make::add_leading_newlines(2, fn_def);
let indented = IndentLevel::from_node(&it).increase_indent(with_leading_blank_line);
(indented, it.text_range().end())
}
GeneratedFunctionTarget::InEmptyItemList(it) => {
let with_leading_newline = ast::make::add_leading_newlines(1, fn_def);
let indent = IndentLevel::from_node(it.syntax()).indented();
let mut indented = indent.increase_indent(with_leading_newline);
if !item_list_has_whitespace(&it) {
// In this case we want to make sure there's a newline between the closing
// function brace and the closing module brace (so it doesn't end in `}}`).
indented = ast::make::add_trailing_newlines(1, indented);
}
(indented, it.syntax().text_range().start() + TextUnit::from_usize(1))
}
};
let cursor_offset_from_fn_start = fn_def
.syntax()
.descendants()
@ -98,15 +134,25 @@ impl FunctionBuilder {
}
}
fn fn_name(call: &CallExpr) -> Option<ast::Name> {
let name = call.expr()?.syntax().to_string();
/// Returns true if the given ItemList contains whitespace.
fn item_list_has_whitespace(it: &ast::ItemList) -> bool {
it.syntax().descendants_with_tokens().find(|it| it.kind() == SyntaxKind::WHITESPACE).is_some()
}
enum GeneratedFunctionTarget {
BehindItem(SyntaxNode),
InEmptyItemList(ast::ItemList),
}
fn fn_name(call: &ast::Path) -> Option<ast::Name> {
let name = call.segment()?.syntax().to_string();
Some(ast::make::name(&name))
}
/// Computes the type variables and arguments required for the generated function
fn fn_args(
ctx: &AssistCtx,
call: &CallExpr,
call: &ast::CallExpr,
) -> Option<(Option<ast::TypeParamList>, ast::ParamList)> {
let mut arg_names = Vec::new();
let mut arg_types = Vec::new();
@ -158,9 +204,9 @@ fn deduplicate_arg_names(arg_names: &mut Vec<String>) {
}
}
fn fn_arg_name(fn_arg: &Expr) -> Option<String> {
fn fn_arg_name(fn_arg: &ast::Expr) -> Option<String> {
match fn_arg {
Expr::CastExpr(cast_expr) => fn_arg_name(&cast_expr.expr()?),
ast::Expr::CastExpr(cast_expr) => fn_arg_name(&cast_expr.expr()?),
_ => Some(
fn_arg
.syntax()
@ -172,7 +218,7 @@ fn fn_arg_name(fn_arg: &Expr) -> Option<String> {
}
}
fn fn_arg_type(ctx: &AssistCtx, fn_arg: &Expr) -> Option<String> {
fn fn_arg_type(ctx: &AssistCtx, fn_arg: &ast::Expr) -> Option<String> {
let ty = ctx.sema.type_of_expr(fn_arg)?;
if ty.is_unknown() {
return None;
@ -184,7 +230,7 @@ fn fn_arg_type(ctx: &AssistCtx, fn_arg: &Expr) -> Option<String> {
/// directly after the current block
/// We want to write the generated function directly after
/// fns, impls or macro calls, but inside mods
fn next_space_for_fn(expr: &CallExpr) -> Option<SyntaxNode> {
fn next_space_for_fn_after_call_site(expr: &ast::CallExpr) -> Option<GeneratedFunctionTarget> {
let mut ancestors = expr.syntax().ancestors().peekable();
let mut last_ancestor: Option<SyntaxNode> = None;
while let Some(next_ancestor) = ancestors.next() {
@ -201,7 +247,26 @@ fn next_space_for_fn(expr: &CallExpr) -> Option<SyntaxNode> {
}
last_ancestor = Some(next_ancestor);
}
last_ancestor
last_ancestor.map(GeneratedFunctionTarget::BehindItem)
}
fn next_space_for_fn_in_module(module: hir::ModuleSource) -> Option<GeneratedFunctionTarget> {
match module {
hir::ModuleSource::SourceFile(it) => {
if let Some(last_item) = it.items().last() {
Some(GeneratedFunctionTarget::BehindItem(last_item.syntax().clone()))
} else {
Some(GeneratedFunctionTarget::BehindItem(it.syntax().clone()))
}
}
hir::ModuleSource::Module(it) => {
if let Some(last_item) = it.item_list().and_then(|it| it.items().last()) {
Some(GeneratedFunctionTarget::BehindItem(last_item.syntax().clone()))
} else {
it.item_list().map(GeneratedFunctionTarget::InEmptyItemList)
}
}
}
}
#[cfg(test)]
@ -713,6 +778,112 @@ fn bar(baz_1: Baz, baz_2: Baz, arg_1: &str, arg_2: &str) {
)
}
#[test]
fn add_function_in_module() {
check_assist(
add_function,
r"
mod bar {}
fn foo() {
bar::my_fn<|>()
}
",
r"
mod bar {
fn my_fn() {
<|>todo!()
}
}
fn foo() {
bar::my_fn()
}
",
);
check_assist(
add_function,
r"
mod bar {
}
fn foo() {
bar::my_fn<|>()
}
",
r"
mod bar {
fn my_fn() {
<|>todo!()
}
}
fn foo() {
bar::my_fn()
}
",
)
}
#[test]
fn add_function_in_module_containing_other_items() {
check_assist(
add_function,
r"
mod bar {
fn something_else() {}
}
fn foo() {
bar::my_fn<|>()
}
",
r"
mod bar {
fn something_else() {}
fn my_fn() {
<|>todo!()
}
}
fn foo() {
bar::my_fn()
}
",
)
}
#[test]
fn add_function_in_nested_module() {
check_assist(
add_function,
r"
mod bar {
mod baz {
}
}
fn foo() {
bar::baz::my_fn<|>()
}
",
r"
mod bar {
mod baz {
fn my_fn() {
<|>todo!()
}
}
}
fn foo() {
bar::baz::my_fn()
}
",
)
}
#[test]
fn add_function_not_applicable_if_function_already_exists() {
check_assist_not_applicable(

View file

@ -293,11 +293,16 @@ pub fn fn_def(
ast_from_text(&format!("fn {}{}{} {}", fn_name, type_params, params, body))
}
pub fn add_newlines(amount_of_newlines: usize, t: impl AstNode) -> ast::SourceFile {
pub fn add_leading_newlines(amount_of_newlines: usize, t: impl AstNode) -> ast::SourceFile {
let newlines = "\n".repeat(amount_of_newlines);
ast_from_text(&format!("{}{}", newlines, t.syntax()))
}
pub fn add_trailing_newlines(amount_of_newlines: usize, t: impl AstNode) -> ast::SourceFile {
let newlines = "\n".repeat(amount_of_newlines);
ast_from_text(&format!("{}{}", t.syntax(), newlines))
}
fn ast_from_text<N: AstNode>(text: &str) -> N {
let parse = SourceFile::parse(text);
let node = parse.tree().syntax().descendants().find_map(N::cast).unwrap();