use anyhow::Result; use async_trait::async_trait; use language::{LanguageServerName, LspAdapter, LspAdapterDelegate}; use lsp::LanguageServerBinary; use node_runtime::NodeRuntime; use smol::fs; use std::{ any::Any, ffi::OsString, path::{Path, PathBuf}, sync::Arc, }; use util::ResultExt; const SERVER_PATH: &'static str = "node_modules/pyright/langserver.index.js"; fn server_binary_arguments(server_path: &Path) -> Vec { vec![server_path.into(), "--stdio".into()] } pub struct PythonLspAdapter { node: Arc, } impl PythonLspAdapter { pub fn new(node: Arc) -> Self { PythonLspAdapter { node } } } #[async_trait] impl LspAdapter for PythonLspAdapter { async fn name(&self) -> LanguageServerName { LanguageServerName("pyright".into()) } fn short_name(&self) -> &'static str { "pyright" } async fn fetch_latest_server_version( &self, _: &dyn LspAdapterDelegate, ) -> Result> { Ok(Box::new(self.node.npm_package_latest_version("pyright").await?) as Box<_>) } async fn fetch_server_binary( &self, version: Box, container_dir: PathBuf, _: &dyn LspAdapterDelegate, ) -> Result { let version = version.downcast::().unwrap(); let server_path = container_dir.join(SERVER_PATH); if fs::metadata(&server_path).await.is_err() { self.node .npm_install_packages(&container_dir, &[("pyright", version.as_str())]) .await?; } Ok(LanguageServerBinary { path: self.node.binary_path().await?, arguments: server_binary_arguments(&server_path), }) } async fn cached_server_binary( &self, container_dir: PathBuf, _: &dyn LspAdapterDelegate, ) -> Option { get_cached_server_binary(container_dir, &*self.node).await } async fn installation_test_binary( &self, container_dir: PathBuf, ) -> Option { get_cached_server_binary(container_dir, &*self.node).await } async fn process_completion(&self, item: &mut lsp::CompletionItem) { // Pyright assigns each completion item a `sortText` of the form `XX.YYYY.name`. // Where `XX` is the sorting category, `YYYY` is based on most recent usage, // and `name` is the symbol name itself. // // Because the the symbol name is included, there generally are not ties when // sorting by the `sortText`, so the symbol's fuzzy match score is not taken // into account. Here, we remove the symbol name from the sortText in order // to allow our own fuzzy score to be used to break ties. // // see https://github.com/microsoft/pyright/blob/95ef4e103b9b2f129c9320427e51b73ea7cf78bd/packages/pyright-internal/src/languageService/completionProvider.ts#LL2873 let Some(sort_text) = &mut item.sort_text else { return; }; let mut parts = sort_text.split('.'); let Some(first) = parts.next() else { return }; let Some(second) = parts.next() else { return }; let Some(_) = parts.next() else { return }; sort_text.replace_range(first.len() + second.len() + 1.., ""); } async fn label_for_completion( &self, item: &lsp::CompletionItem, language: &Arc, ) -> Option { let label = &item.label; let grammar = language.grammar()?; let highlight_id = match item.kind? { lsp::CompletionItemKind::METHOD => grammar.highlight_id_for_name("function.method")?, lsp::CompletionItemKind::FUNCTION => grammar.highlight_id_for_name("function")?, lsp::CompletionItemKind::CLASS => grammar.highlight_id_for_name("type")?, lsp::CompletionItemKind::CONSTANT => grammar.highlight_id_for_name("constant")?, _ => return None, }; Some(language::CodeLabel { text: label.clone(), runs: vec![(0..label.len(), highlight_id)], filter_range: 0..label.len(), }) } async fn label_for_symbol( &self, name: &str, kind: lsp::SymbolKind, language: &Arc, ) -> Option { let (text, filter_range, display_range) = match kind { lsp::SymbolKind::METHOD | lsp::SymbolKind::FUNCTION => { let text = format!("def {}():\n", name); let filter_range = 4..4 + name.len(); let display_range = 0..filter_range.end; (text, filter_range, display_range) } lsp::SymbolKind::CLASS => { let text = format!("class {}:", name); let filter_range = 6..6 + name.len(); let display_range = 0..filter_range.end; (text, filter_range, display_range) } lsp::SymbolKind::CONSTANT => { let text = format!("{} = 0", name); let filter_range = 0..name.len(); let display_range = 0..filter_range.end; (text, filter_range, display_range) } _ => return None, }; Some(language::CodeLabel { runs: language.highlight_text(&text.as_str().into(), display_range.clone()), text: text[display_range].to_string(), filter_range, }) } } async fn get_cached_server_binary( container_dir: PathBuf, node: &dyn NodeRuntime, ) -> Option { let server_path = container_dir.join(SERVER_PATH); if server_path.exists() { Some(LanguageServerBinary { path: node.binary_path().await.log_err()?, arguments: server_binary_arguments(&server_path), }) } else { log::error!("missing executable in directory {:?}", server_path); None } } #[cfg(test)] mod tests { use gpui::{Context, ModelContext, TestAppContext}; use language::{language_settings::AllLanguageSettings, AutoindentMode, Buffer}; use settings::SettingsStore; use std::num::NonZeroU32; #[gpui::test] async fn test_python_autoindent(cx: &mut TestAppContext) { // cx.executor().set_block_on_ticks(usize::MAX..=usize::MAX); let language = crate::languages::language("python", tree_sitter_python::language(), None).await; cx.update(|cx| { let test_settings = SettingsStore::test(cx); cx.set_global(test_settings); language::init(cx); cx.update_global::(|store, cx| { store.update_user_settings::(cx, |s| { s.defaults.tab_size = NonZeroU32::new(2); }); }); }); cx.build_model(|cx| { let mut buffer = Buffer::new(0, cx.entity_id().as_u64(), "").with_language(language, cx); let append = |buffer: &mut Buffer, text: &str, cx: &mut ModelContext| { let ix = buffer.len(); buffer.edit([(ix..ix, text)], Some(AutoindentMode::EachLine), cx); }; // indent after "def():" append(&mut buffer, "def a():\n", cx); assert_eq!(buffer.text(), "def a():\n "); // preserve indent after blank line append(&mut buffer, "\n ", cx); assert_eq!(buffer.text(), "def a():\n \n "); // indent after "if" append(&mut buffer, "if a:\n ", cx); assert_eq!(buffer.text(), "def a():\n \n if a:\n "); // preserve indent after statement append(&mut buffer, "b()\n", cx); assert_eq!(buffer.text(), "def a():\n \n if a:\n b()\n "); // preserve indent after statement append(&mut buffer, "else", cx); assert_eq!(buffer.text(), "def a():\n \n if a:\n b()\n else"); // dedent "else"" append(&mut buffer, ":", cx); assert_eq!(buffer.text(), "def a():\n \n if a:\n b()\n else:"); // indent lines after else append(&mut buffer, "\n", cx); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n " ); // indent after an open paren. the closing paren is not indented // because there is another token before it on the same line. append(&mut buffer, "foo(\n1)", cx); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n foo(\n 1)" ); // dedent the closing paren if it is shifted to the beginning of the line let argument_ix = buffer.text().find('1').unwrap(); buffer.edit( [(argument_ix..argument_ix + 1, "")], Some(AutoindentMode::EachLine), cx, ); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n foo(\n )" ); // preserve indent after the close paren append(&mut buffer, "\n", cx); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n foo(\n )\n " ); // manually outdent the last line let end_whitespace_ix = buffer.len() - 4; buffer.edit( [(end_whitespace_ix..buffer.len(), "")], Some(AutoindentMode::EachLine), cx, ); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n foo(\n )\n" ); // preserve the newly reduced indentation on the next newline append(&mut buffer, "\n", cx); assert_eq!( buffer.text(), "def a():\n \n if a:\n b()\n else:\n foo(\n )\n\n" ); // reset to a simple if statement buffer.edit([(0..buffer.len(), "if a:\n b(\n )")], None, cx); // dedent "else" on the line after a closing paren append(&mut buffer, "\n else:\n", cx); assert_eq!(buffer.text(), "if a:\n b(\n )\nelse:\n "); buffer }); } }